author | paulson |
Tue, 13 Aug 2002 17:42:34 +0200 | |
changeset 13496 | 6f0c57def6d5 |
parent 13493 | 5aa68c051725 |
child 13505 | 52a16cb7fefb |
permissions | -rw-r--r-- |
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header {* The ZF Axioms (Except Separation) in L *} |
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theory L_axioms = Formula + Relative + Reflection + MetaExists: |
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13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
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diff
changeset
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text {* The class L satisfies the premises of locale @{text M_triv_axioms} *} |
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lemma transL: "[| y\<in>x; L(x) |] ==> L(y)" |
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apply (insert Transset_Lset) |
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apply (simp add: Transset_def L_def, blast) |
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done |
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lemma nonempty: "L(0)" |
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apply (simp add: L_def) |
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apply (blast intro: zero_in_Lset) |
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done |
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lemma upair_ax: "upair_ax(L)" |
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apply (simp add: upair_ax_def upair_def, clarify) |
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apply (rule_tac x="{x,y}" in rexI) |
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apply (simp_all add: doubleton_in_L) |
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done |
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lemma Union_ax: "Union_ax(L)" |
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apply (simp add: Union_ax_def big_union_def, clarify) |
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apply (rule_tac x="Union(x)" in rexI) |
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apply (simp_all add: Union_in_L, auto) |
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apply (blast intro: transL) |
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done |
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lemma power_ax: "power_ax(L)" |
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apply (simp add: power_ax_def powerset_def Relative.subset_def, clarify) |
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apply (rule_tac x="{y \<in> Pow(x). L(y)}" in rexI) |
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apply (simp_all add: LPow_in_L, auto) |
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apply (blast intro: transL) |
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done |
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subsubsection{*For L to satisfy Replacement *} |
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(*Can't move these to Formula unless the definition of univalent is moved |
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there too!*) |
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lemma LReplace_in_Lset: |
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"[|X \<in> Lset(i); univalent(L,X,Q); Ord(i)|] |
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==> \<exists>j. Ord(j) & Replace(X, %x y. Q(x,y) & L(y)) \<subseteq> Lset(j)" |
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apply (rule_tac x="\<Union>y \<in> Replace(X, %x y. Q(x,y) & L(y)). succ(lrank(y))" |
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in exI) |
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apply simp |
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apply clarify |
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apply (rule_tac a=x in UN_I) |
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apply (simp_all add: Replace_iff univalent_def) |
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apply (blast dest: transL L_I) |
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done |
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lemma LReplace_in_L: |
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"[|L(X); univalent(L,X,Q)|] |
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==> \<exists>Y. L(Y) & Replace(X, %x y. Q(x,y) & L(y)) \<subseteq> Y" |
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apply (drule L_D, clarify) |
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apply (drule LReplace_in_Lset, assumption+) |
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apply (blast intro: L_I Lset_in_Lset_succ) |
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done |
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lemma replacement: "replacement(L,P)" |
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apply (simp add: replacement_def, clarify) |
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apply (frule LReplace_in_L, assumption+, clarify) |
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apply (rule_tac x=Y in rexI) |
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apply (simp_all add: Replace_iff univalent_def, blast) |
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done |
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subsection{*Instantiating the locale @{text M_triv_axioms}*} |
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text{*No instances of Separation yet.*} |
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lemma Lset_mono_le: "mono_le_subset(Lset)" |
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by (simp add: mono_le_subset_def le_imp_subset Lset_mono) |
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lemma Lset_cont: "cont_Ord(Lset)" |
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by (simp add: cont_Ord_def Limit_Lset_eq OUnion_def Limit_is_Ord) |
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lemmas Pair_in_Lset = Formula.Pair_in_LLimit |
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lemmas L_nat = Ord_in_L [OF Ord_nat] |
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theorem M_triv_axioms_L: "PROP M_triv_axioms(L)" |
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apply (rule M_triv_axioms.intro) |
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apply (erule (1) transL) |
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apply (rule nonempty) |
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apply (rule upair_ax) |
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apply (rule Union_ax) |
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apply (rule power_ax) |
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apply (rule replacement) |
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apply (rule L_nat) |
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done |
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lemmas rall_abs = M_triv_axioms.rall_abs [OF M_triv_axioms_L] |
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and rex_abs = M_triv_axioms.rex_abs [OF M_triv_axioms_L] |
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and ball_iff_equiv = M_triv_axioms.ball_iff_equiv [OF M_triv_axioms_L] |
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and M_equalityI = M_triv_axioms.M_equalityI [OF M_triv_axioms_L] |
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and empty_abs = M_triv_axioms.empty_abs [OF M_triv_axioms_L] |
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and subset_abs = M_triv_axioms.subset_abs [OF M_triv_axioms_L] |
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and upair_abs = M_triv_axioms.upair_abs [OF M_triv_axioms_L] |
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and upair_in_M_iff = M_triv_axioms.upair_in_M_iff [OF M_triv_axioms_L] |
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and singleton_in_M_iff = M_triv_axioms.singleton_in_M_iff [OF M_triv_axioms_L] |
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and pair_abs = M_triv_axioms.pair_abs [OF M_triv_axioms_L] |
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and pair_in_M_iff = M_triv_axioms.pair_in_M_iff [OF M_triv_axioms_L] |
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and pair_components_in_M = M_triv_axioms.pair_components_in_M [OF M_triv_axioms_L] |
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and cartprod_abs = M_triv_axioms.cartprod_abs [OF M_triv_axioms_L] |
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and union_abs = M_triv_axioms.union_abs [OF M_triv_axioms_L] |
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and inter_abs = M_triv_axioms.inter_abs [OF M_triv_axioms_L] |
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and setdiff_abs = M_triv_axioms.setdiff_abs [OF M_triv_axioms_L] |
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and Union_abs = M_triv_axioms.Union_abs [OF M_triv_axioms_L] |
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and Union_closed = M_triv_axioms.Union_closed [OF M_triv_axioms_L] |
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and Un_closed = M_triv_axioms.Un_closed [OF M_triv_axioms_L] |
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and cons_closed = M_triv_axioms.cons_closed [OF M_triv_axioms_L] |
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and successor_abs = M_triv_axioms.successor_abs [OF M_triv_axioms_L] |
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and succ_in_M_iff = M_triv_axioms.succ_in_M_iff [OF M_triv_axioms_L] |
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and separation_closed = M_triv_axioms.separation_closed [OF M_triv_axioms_L] |
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and strong_replacementI = M_triv_axioms.strong_replacementI [OF M_triv_axioms_L] |
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and strong_replacement_closed = M_triv_axioms.strong_replacement_closed [OF M_triv_axioms_L] |
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and RepFun_closed = M_triv_axioms.RepFun_closed [OF M_triv_axioms_L] |
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and lam_closed = M_triv_axioms.lam_closed [OF M_triv_axioms_L] |
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and image_abs = M_triv_axioms.image_abs [OF M_triv_axioms_L] |
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and powerset_Pow = M_triv_axioms.powerset_Pow [OF M_triv_axioms_L] |
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and powerset_imp_subset_Pow = M_triv_axioms.powerset_imp_subset_Pow [OF M_triv_axioms_L] |
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and nat_into_M = M_triv_axioms.nat_into_M [OF M_triv_axioms_L] |
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and nat_case_closed = M_triv_axioms.nat_case_closed [OF M_triv_axioms_L] |
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and Inl_in_M_iff = M_triv_axioms.Inl_in_M_iff [OF M_triv_axioms_L] |
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and Inr_in_M_iff = M_triv_axioms.Inr_in_M_iff [OF M_triv_axioms_L] |
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and lt_closed = M_triv_axioms.lt_closed [OF M_triv_axioms_L] |
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and transitive_set_abs = M_triv_axioms.transitive_set_abs [OF M_triv_axioms_L] |
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and ordinal_abs = M_triv_axioms.ordinal_abs [OF M_triv_axioms_L] |
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and limit_ordinal_abs = M_triv_axioms.limit_ordinal_abs [OF M_triv_axioms_L] |
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and successor_ordinal_abs = M_triv_axioms.successor_ordinal_abs [OF M_triv_axioms_L] |
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and finite_ordinal_abs = M_triv_axioms.finite_ordinal_abs [OF M_triv_axioms_L] |
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and omega_abs = M_triv_axioms.omega_abs [OF M_triv_axioms_L] |
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and number1_abs = M_triv_axioms.number1_abs [OF M_triv_axioms_L] |
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and number2_abs = M_triv_axioms.number2_abs [OF M_triv_axioms_L] |
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and number3_abs = M_triv_axioms.number3_abs [OF M_triv_axioms_L] |
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declare rall_abs [simp] |
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declare rex_abs [simp] |
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declare empty_abs [simp] |
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declare subset_abs [simp] |
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declare upair_abs [simp] |
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declare upair_in_M_iff [iff] |
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declare singleton_in_M_iff [iff] |
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declare pair_abs [simp] |
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declare pair_in_M_iff [iff] |
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declare cartprod_abs [simp] |
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declare union_abs [simp] |
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declare inter_abs [simp] |
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declare setdiff_abs [simp] |
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declare Union_abs [simp] |
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declare Union_closed [intro, simp] |
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declare Un_closed [intro, simp] |
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declare cons_closed [intro, simp] |
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declare successor_abs [simp] |
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declare succ_in_M_iff [iff] |
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declare separation_closed [intro, simp] |
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declare strong_replacementI |
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declare strong_replacement_closed [intro, simp] |
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declare RepFun_closed [intro, simp] |
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declare lam_closed [intro, simp] |
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declare image_abs [simp] |
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declare nat_into_M [intro] |
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declare Inl_in_M_iff [iff] |
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declare Inr_in_M_iff [iff] |
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declare transitive_set_abs [simp] |
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declare ordinal_abs [simp] |
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declare limit_ordinal_abs [simp] |
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declare successor_ordinal_abs [simp] |
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declare finite_ordinal_abs [simp] |
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declare omega_abs [simp] |
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declare number1_abs [simp] |
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declare number2_abs [simp] |
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declare number3_abs [simp] |
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subsection{*Instantiation of the locale @{text reflection}*} |
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text{*instances of locale constants*} |
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181 |
constdefs |
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L_F0 :: "[i=>o,i] => i" |
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"L_F0(P,y) == \<mu>b. (\<exists>z. L(z) \<and> P(<y,z>)) --> (\<exists>z\<in>Lset(b). P(<y,z>))" |
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L_FF :: "[i=>o,i] => i" |
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"L_FF(P) == \<lambda>a. \<Union>y\<in>Lset(a). L_F0(P,y)" |
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187 |
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L_ClEx :: "[i=>o,i] => o" |
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"L_ClEx(P) == \<lambda>a. Limit(a) \<and> normalize(L_FF(P),a) = a" |
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190 |
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191 |
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text{*We must use the meta-existential quantifier; otherwise the reflection |
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terms become enormous!*} |
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constdefs |
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L_Reflects :: "[i=>o,[i,i]=>o] => prop" ("(3REFLECTS/ [_,/ _])") |
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"REFLECTS[P,Q] == (??Cl. Closed_Unbounded(Cl) & |
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(\<forall>a. Cl(a) --> (\<forall>x \<in> Lset(a). P(x) <-> Q(a,x))))" |
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199 |
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theorem Triv_reflection: |
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"REFLECTS[P, \<lambda>a x. P(x)]" |
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apply (simp add: L_Reflects_def) |
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apply (rule meta_exI) |
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204 |
apply (rule Closed_Unbounded_Ord) |
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done |
206 |
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theorem Not_reflection: |
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208 |
"REFLECTS[P,Q] ==> REFLECTS[\<lambda>x. ~P(x), \<lambda>a x. ~Q(a,x)]" |
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apply (unfold L_Reflects_def) |
210 |
apply (erule meta_exE) |
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211 |
apply (rule_tac x=Cl in meta_exI, simp) |
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done |
213 |
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theorem And_reflection: |
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"[| REFLECTS[P,Q]; REFLECTS[P',Q'] |] |
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==> REFLECTS[\<lambda>x. P(x) \<and> P'(x), \<lambda>a x. Q(a,x) \<and> Q'(a,x)]" |
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apply (unfold L_Reflects_def) |
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apply (elim meta_exE) |
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apply (rule_tac x="\<lambda>a. Cl(a) \<and> Cla(a)" in meta_exI) |
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apply (simp add: Closed_Unbounded_Int, blast) |
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13314 | 221 |
done |
222 |
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223 |
theorem Or_reflection: |
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"[| REFLECTS[P,Q]; REFLECTS[P',Q'] |] |
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==> REFLECTS[\<lambda>x. P(x) \<or> P'(x), \<lambda>a x. Q(a,x) \<or> Q'(a,x)]" |
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apply (unfold L_Reflects_def) |
227 |
apply (elim meta_exE) |
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228 |
apply (rule_tac x="\<lambda>a. Cl(a) \<and> Cla(a)" in meta_exI) |
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apply (simp add: Closed_Unbounded_Int, blast) |
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13314 | 230 |
done |
231 |
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232 |
theorem Imp_reflection: |
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"[| REFLECTS[P,Q]; REFLECTS[P',Q'] |] |
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==> REFLECTS[\<lambda>x. P(x) --> P'(x), \<lambda>a x. Q(a,x) --> Q'(a,x)]" |
13429 | 235 |
apply (unfold L_Reflects_def) |
236 |
apply (elim meta_exE) |
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237 |
apply (rule_tac x="\<lambda>a. Cl(a) \<and> Cla(a)" in meta_exI) |
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238 |
apply (simp add: Closed_Unbounded_Int, blast) |
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done |
240 |
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241 |
theorem Iff_reflection: |
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13429 | 242 |
"[| REFLECTS[P,Q]; REFLECTS[P',Q'] |] |
13314 | 243 |
==> REFLECTS[\<lambda>x. P(x) <-> P'(x), \<lambda>a x. Q(a,x) <-> Q'(a,x)]" |
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apply (unfold L_Reflects_def) |
245 |
apply (elim meta_exE) |
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246 |
apply (rule_tac x="\<lambda>a. Cl(a) \<and> Cla(a)" in meta_exI) |
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247 |
apply (simp add: Closed_Unbounded_Int, blast) |
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13314 | 248 |
done |
249 |
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250 |
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13434 | 251 |
lemma reflection_Lset: "reflection(Lset)" |
252 |
apply (blast intro: reflection.intro Lset_mono_le Lset_cont Pair_in_Lset) + |
|
253 |
done |
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254 |
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13314 | 255 |
theorem Ex_reflection: |
256 |
"REFLECTS[\<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x))] |
|
257 |
==> REFLECTS[\<lambda>x. \<exists>z. L(z) \<and> P(x,z), \<lambda>a x. \<exists>z\<in>Lset(a). Q(a,x,z)]" |
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13429 | 258 |
apply (unfold L_Reflects_def L_ClEx_def L_FF_def L_F0_def L_def) |
259 |
apply (elim meta_exE) |
|
13314 | 260 |
apply (rule meta_exI) |
13434 | 261 |
apply (erule reflection.Ex_reflection [OF reflection_Lset]) |
13291 | 262 |
done |
263 |
||
13314 | 264 |
theorem All_reflection: |
265 |
"REFLECTS[\<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x))] |
|
13429 | 266 |
==> REFLECTS[\<lambda>x. \<forall>z. L(z) --> P(x,z), \<lambda>a x. \<forall>z\<in>Lset(a). Q(a,x,z)]" |
267 |
apply (unfold L_Reflects_def L_ClEx_def L_FF_def L_F0_def L_def) |
|
268 |
apply (elim meta_exE) |
|
13314 | 269 |
apply (rule meta_exI) |
13434 | 270 |
apply (erule reflection.All_reflection [OF reflection_Lset]) |
13291 | 271 |
done |
272 |
||
13314 | 273 |
theorem Rex_reflection: |
274 |
"REFLECTS[ \<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x))] |
|
275 |
==> REFLECTS[\<lambda>x. \<exists>z[L]. P(x,z), \<lambda>a x. \<exists>z\<in>Lset(a). Q(a,x,z)]" |
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13429 | 276 |
apply (unfold rex_def) |
13314 | 277 |
apply (intro And_reflection Ex_reflection, assumption) |
278 |
done |
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13291 | 279 |
|
13314 | 280 |
theorem Rall_reflection: |
281 |
"REFLECTS[\<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x))] |
|
13429 | 282 |
==> REFLECTS[\<lambda>x. \<forall>z[L]. P(x,z), \<lambda>a x. \<forall>z\<in>Lset(a). Q(a,x,z)]" |
283 |
apply (unfold rall_def) |
|
13314 | 284 |
apply (intro Imp_reflection All_reflection, assumption) |
285 |
done |
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286 |
||
13440 | 287 |
text{*This version handles an alternative form of the bounded quantifier |
288 |
in the second argument of @{text REFLECTS}.*} |
|
289 |
theorem Rex_reflection': |
|
290 |
"REFLECTS[ \<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x))] |
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291 |
==> REFLECTS[\<lambda>x. \<exists>z[L]. P(x,z), \<lambda>a x. \<exists>z[**Lset(a)]. Q(a,x,z)]" |
|
292 |
apply (unfold setclass_def rex_def) |
|
293 |
apply (erule Rex_reflection [unfolded rex_def Bex_def]) |
|
294 |
done |
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295 |
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296 |
text{*As above.*} |
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297 |
theorem Rall_reflection': |
|
298 |
"REFLECTS[\<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x))] |
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299 |
==> REFLECTS[\<lambda>x. \<forall>z[L]. P(x,z), \<lambda>a x. \<forall>z[**Lset(a)]. Q(a,x,z)]" |
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300 |
apply (unfold setclass_def rall_def) |
|
301 |
apply (erule Rall_reflection [unfolded rall_def Ball_def]) |
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302 |
done |
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303 |
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13429 | 304 |
lemmas FOL_reflections = |
13314 | 305 |
Triv_reflection Not_reflection And_reflection Or_reflection |
306 |
Imp_reflection Iff_reflection Ex_reflection All_reflection |
|
13440 | 307 |
Rex_reflection Rall_reflection Rex_reflection' Rall_reflection' |
13291 | 308 |
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309 |
lemma ReflectsD: |
|
13429 | 310 |
"[|REFLECTS[P,Q]; Ord(i)|] |
13291 | 311 |
==> \<exists>j. i<j & (\<forall>x \<in> Lset(j). P(x) <-> Q(j,x))" |
13429 | 312 |
apply (unfold L_Reflects_def Closed_Unbounded_def) |
313 |
apply (elim meta_exE, clarify) |
|
314 |
apply (blast dest!: UnboundedD) |
|
13291 | 315 |
done |
316 |
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317 |
lemma ReflectsE: |
|
13314 | 318 |
"[| REFLECTS[P,Q]; Ord(i); |
13291 | 319 |
!!j. [|i<j; \<forall>x \<in> Lset(j). P(x) <-> Q(j,x)|] ==> R |] |
320 |
==> R" |
|
13429 | 321 |
apply (drule ReflectsD, assumption, blast) |
13314 | 322 |
done |
13291 | 323 |
|
13428 | 324 |
lemma Collect_mem_eq: "{x\<in>A. x\<in>B} = A \<inter> B" |
13291 | 325 |
by blast |
326 |
||
327 |
||
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328 |
subsection{*Internalized Formulas for some Set-Theoretic Concepts*} |
13298 | 329 |
|
13306 | 330 |
lemmas setclass_simps = rall_setclass_is_ball rex_setclass_is_bex |
331 |
||
332 |
subsubsection{*Some numbers to help write de Bruijn indices*} |
|
333 |
||
334 |
syntax |
|
335 |
"3" :: i ("3") |
|
336 |
"4" :: i ("4") |
|
337 |
"5" :: i ("5") |
|
338 |
"6" :: i ("6") |
|
339 |
"7" :: i ("7") |
|
340 |
"8" :: i ("8") |
|
341 |
"9" :: i ("9") |
|
342 |
||
343 |
translations |
|
344 |
"3" == "succ(2)" |
|
345 |
"4" == "succ(3)" |
|
346 |
"5" == "succ(4)" |
|
347 |
"6" == "succ(5)" |
|
348 |
"7" == "succ(6)" |
|
349 |
"8" == "succ(7)" |
|
350 |
"9" == "succ(8)" |
|
351 |
||
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352 |
|
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|
353 |
subsubsection{*The Empty Set, Internalized*} |
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|
354 |
|
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355 |
constdefs empty_fm :: "i=>i" |
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356 |
"empty_fm(x) == Forall(Neg(Member(0,succ(x))))" |
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|
357 |
|
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|
358 |
lemma empty_type [TC]: |
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|
359 |
"x \<in> nat ==> empty_fm(x) \<in> formula" |
13429 | 360 |
by (simp add: empty_fm_def) |
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|
361 |
|
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|
362 |
lemma arity_empty_fm [simp]: |
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|
363 |
"x \<in> nat ==> arity(empty_fm(x)) = succ(x)" |
13429 | 364 |
by (simp add: empty_fm_def succ_Un_distrib [symmetric] Un_ac) |
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|
365 |
|
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|
366 |
lemma sats_empty_fm [simp]: |
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|
367 |
"[| x \<in> nat; env \<in> list(A)|] |
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|
368 |
==> sats(A, empty_fm(x), env) <-> empty(**A, nth(x,env))" |
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|
369 |
by (simp add: empty_fm_def empty_def) |
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|
370 |
|
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|
371 |
lemma empty_iff_sats: |
13429 | 372 |
"[| nth(i,env) = x; nth(j,env) = y; |
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373 |
i \<in> nat; env \<in> list(A)|] |
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|
374 |
==> empty(**A, x) <-> sats(A, empty_fm(i), env)" |
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|
375 |
by simp |
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|
376 |
|
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|
377 |
theorem empty_reflection: |
13429 | 378 |
"REFLECTS[\<lambda>x. empty(L,f(x)), |
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|
379 |
\<lambda>i x. empty(**Lset(i),f(x))]" |
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|
380 |
apply (simp only: empty_def setclass_simps) |
13429 | 381 |
apply (intro FOL_reflections) |
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|
382 |
done |
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|
383 |
|
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|
384 |
text{*Not used. But maybe useful?*} |
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|
385 |
lemma Transset_sats_empty_fm_eq_0: |
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|
386 |
"[| n \<in> nat; env \<in> list(A); Transset(A)|] |
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|
387 |
==> sats(A, empty_fm(n), env) <-> nth(n,env) = 0" |
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|
388 |
apply (simp add: empty_fm_def empty_def Transset_def, auto) |
13429 | 389 |
apply (case_tac "n < length(env)") |
390 |
apply (frule nth_type, assumption+, blast) |
|
391 |
apply (simp_all add: not_lt_iff_le nth_eq_0) |
|
13385
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|
392 |
done |
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|
393 |
|
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|
394 |
|
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|
395 |
subsubsection{*Unordered Pairs, Internalized*} |
13298 | 396 |
|
397 |
constdefs upair_fm :: "[i,i,i]=>i" |
|
13429 | 398 |
"upair_fm(x,y,z) == |
399 |
And(Member(x,z), |
|
13298 | 400 |
And(Member(y,z), |
13429 | 401 |
Forall(Implies(Member(0,succ(z)), |
13298 | 402 |
Or(Equal(0,succ(x)), Equal(0,succ(y)))))))" |
403 |
||
404 |
lemma upair_type [TC]: |
|
405 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> upair_fm(x,y,z) \<in> formula" |
|
13429 | 406 |
by (simp add: upair_fm_def) |
13298 | 407 |
|
408 |
lemma arity_upair_fm [simp]: |
|
13429 | 409 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13298 | 410 |
==> arity(upair_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 411 |
by (simp add: upair_fm_def succ_Un_distrib [symmetric] Un_ac) |
13298 | 412 |
|
413 |
lemma sats_upair_fm [simp]: |
|
414 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 415 |
==> sats(A, upair_fm(x,y,z), env) <-> |
13298 | 416 |
upair(**A, nth(x,env), nth(y,env), nth(z,env))" |
417 |
by (simp add: upair_fm_def upair_def) |
|
418 |
||
419 |
lemma upair_iff_sats: |
|
13429 | 420 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13298 | 421 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
422 |
==> upair(**A, x, y, z) <-> sats(A, upair_fm(i,j,k), env)" |
|
423 |
by (simp add: sats_upair_fm) |
|
424 |
||
425 |
text{*Useful? At least it refers to "real" unordered pairs*} |
|
426 |
lemma sats_upair_fm2 [simp]: |
|
427 |
"[| x \<in> nat; y \<in> nat; z < length(env); env \<in> list(A); Transset(A)|] |
|
13429 | 428 |
==> sats(A, upair_fm(x,y,z), env) <-> |
13298 | 429 |
nth(z,env) = {nth(x,env), nth(y,env)}" |
13429 | 430 |
apply (frule lt_length_in_nat, assumption) |
431 |
apply (simp add: upair_fm_def Transset_def, auto) |
|
432 |
apply (blast intro: nth_type) |
|
13298 | 433 |
done |
434 |
||
13314 | 435 |
theorem upair_reflection: |
13429 | 436 |
"REFLECTS[\<lambda>x. upair(L,f(x),g(x),h(x)), |
437 |
\<lambda>i x. upair(**Lset(i),f(x),g(x),h(x))]" |
|
13314 | 438 |
apply (simp add: upair_def) |
13429 | 439 |
apply (intro FOL_reflections) |
13314 | 440 |
done |
13306 | 441 |
|
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|
442 |
subsubsection{*Ordered pairs, Internalized*} |
13298 | 443 |
|
444 |
constdefs pair_fm :: "[i,i,i]=>i" |
|
13429 | 445 |
"pair_fm(x,y,z) == |
13298 | 446 |
Exists(And(upair_fm(succ(x),succ(x),0), |
447 |
Exists(And(upair_fm(succ(succ(x)),succ(succ(y)),0), |
|
448 |
upair_fm(1,0,succ(succ(z)))))))" |
|
449 |
||
450 |
lemma pair_type [TC]: |
|
451 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> pair_fm(x,y,z) \<in> formula" |
|
13429 | 452 |
by (simp add: pair_fm_def) |
13298 | 453 |
|
454 |
lemma arity_pair_fm [simp]: |
|
13429 | 455 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13298 | 456 |
==> arity(pair_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 457 |
by (simp add: pair_fm_def succ_Un_distrib [symmetric] Un_ac) |
13298 | 458 |
|
459 |
lemma sats_pair_fm [simp]: |
|
460 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 461 |
==> sats(A, pair_fm(x,y,z), env) <-> |
13298 | 462 |
pair(**A, nth(x,env), nth(y,env), nth(z,env))" |
463 |
by (simp add: pair_fm_def pair_def) |
|
464 |
||
465 |
lemma pair_iff_sats: |
|
13429 | 466 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13298 | 467 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
468 |
==> pair(**A, x, y, z) <-> sats(A, pair_fm(i,j,k), env)" |
|
469 |
by (simp add: sats_pair_fm) |
|
470 |
||
13314 | 471 |
theorem pair_reflection: |
13429 | 472 |
"REFLECTS[\<lambda>x. pair(L,f(x),g(x),h(x)), |
13314 | 473 |
\<lambda>i x. pair(**Lset(i),f(x),g(x),h(x))]" |
474 |
apply (simp only: pair_def setclass_simps) |
|
13429 | 475 |
apply (intro FOL_reflections upair_reflection) |
13314 | 476 |
done |
13306 | 477 |
|
478 |
||
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|
479 |
subsubsection{*Binary Unions, Internalized*} |
13298 | 480 |
|
13306 | 481 |
constdefs union_fm :: "[i,i,i]=>i" |
13429 | 482 |
"union_fm(x,y,z) == |
13306 | 483 |
Forall(Iff(Member(0,succ(z)), |
484 |
Or(Member(0,succ(x)),Member(0,succ(y)))))" |
|
485 |
||
486 |
lemma union_type [TC]: |
|
487 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> union_fm(x,y,z) \<in> formula" |
|
13429 | 488 |
by (simp add: union_fm_def) |
13306 | 489 |
|
490 |
lemma arity_union_fm [simp]: |
|
13429 | 491 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13306 | 492 |
==> arity(union_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 493 |
by (simp add: union_fm_def succ_Un_distrib [symmetric] Un_ac) |
13298 | 494 |
|
13306 | 495 |
lemma sats_union_fm [simp]: |
496 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 497 |
==> sats(A, union_fm(x,y,z), env) <-> |
13306 | 498 |
union(**A, nth(x,env), nth(y,env), nth(z,env))" |
499 |
by (simp add: union_fm_def union_def) |
|
500 |
||
501 |
lemma union_iff_sats: |
|
13429 | 502 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13306 | 503 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
504 |
==> union(**A, x, y, z) <-> sats(A, union_fm(i,j,k), env)" |
|
505 |
by (simp add: sats_union_fm) |
|
13298 | 506 |
|
13314 | 507 |
theorem union_reflection: |
13429 | 508 |
"REFLECTS[\<lambda>x. union(L,f(x),g(x),h(x)), |
13314 | 509 |
\<lambda>i x. union(**Lset(i),f(x),g(x),h(x))]" |
510 |
apply (simp only: union_def setclass_simps) |
|
13429 | 511 |
apply (intro FOL_reflections) |
13314 | 512 |
done |
13306 | 513 |
|
13298 | 514 |
|
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|
515 |
subsubsection{*Set ``Cons,'' Internalized*} |
13306 | 516 |
|
517 |
constdefs cons_fm :: "[i,i,i]=>i" |
|
13429 | 518 |
"cons_fm(x,y,z) == |
13306 | 519 |
Exists(And(upair_fm(succ(x),succ(x),0), |
520 |
union_fm(0,succ(y),succ(z))))" |
|
13298 | 521 |
|
522 |
||
13306 | 523 |
lemma cons_type [TC]: |
524 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> cons_fm(x,y,z) \<in> formula" |
|
13429 | 525 |
by (simp add: cons_fm_def) |
13306 | 526 |
|
527 |
lemma arity_cons_fm [simp]: |
|
13429 | 528 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13306 | 529 |
==> arity(cons_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 530 |
by (simp add: cons_fm_def succ_Un_distrib [symmetric] Un_ac) |
13306 | 531 |
|
532 |
lemma sats_cons_fm [simp]: |
|
533 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 534 |
==> sats(A, cons_fm(x,y,z), env) <-> |
13306 | 535 |
is_cons(**A, nth(x,env), nth(y,env), nth(z,env))" |
536 |
by (simp add: cons_fm_def is_cons_def) |
|
537 |
||
538 |
lemma cons_iff_sats: |
|
13429 | 539 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13306 | 540 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
541 |
==> is_cons(**A, x, y, z) <-> sats(A, cons_fm(i,j,k), env)" |
|
542 |
by simp |
|
543 |
||
13314 | 544 |
theorem cons_reflection: |
13429 | 545 |
"REFLECTS[\<lambda>x. is_cons(L,f(x),g(x),h(x)), |
13314 | 546 |
\<lambda>i x. is_cons(**Lset(i),f(x),g(x),h(x))]" |
547 |
apply (simp only: is_cons_def setclass_simps) |
|
13429 | 548 |
apply (intro FOL_reflections upair_reflection union_reflection) |
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|
549 |
done |
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|
550 |
|
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|
551 |
|
13339
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|
552 |
subsubsection{*Successor Function, Internalized*} |
13323
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|
553 |
|
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|
554 |
constdefs succ_fm :: "[i,i]=>i" |
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|
555 |
"succ_fm(x,y) == cons_fm(x,x,y)" |
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|
556 |
|
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|
557 |
lemma succ_type [TC]: |
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|
558 |
"[| x \<in> nat; y \<in> nat |] ==> succ_fm(x,y) \<in> formula" |
13429 | 559 |
by (simp add: succ_fm_def) |
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|
560 |
|
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|
561 |
lemma arity_succ_fm [simp]: |
13429 | 562 |
"[| x \<in> nat; y \<in> nat |] |
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|
563 |
==> arity(succ_fm(x,y)) = succ(x) \<union> succ(y)" |
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diff
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|
564 |
by (simp add: succ_fm_def) |
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diff
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|
565 |
|
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|
566 |
lemma sats_succ_fm [simp]: |
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|
567 |
"[| x \<in> nat; y \<in> nat; env \<in> list(A)|] |
13429 | 568 |
==> sats(A, succ_fm(x,y), env) <-> |
13323
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|
569 |
successor(**A, nth(x,env), nth(y,env))" |
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|
570 |
by (simp add: succ_fm_def successor_def) |
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More relativization, reflection and proofs of separation
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|
571 |
|
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|
572 |
lemma successor_iff_sats: |
13429 | 573 |
"[| nth(i,env) = x; nth(j,env) = y; |
13323
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More relativization, reflection and proofs of separation
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|
574 |
i \<in> nat; j \<in> nat; env \<in> list(A)|] |
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More relativization, reflection and proofs of separation
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|
575 |
==> successor(**A, x, y) <-> sats(A, succ_fm(i,j), env)" |
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|
576 |
by simp |
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More relativization, reflection and proofs of separation
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changeset
|
577 |
|
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More relativization, reflection and proofs of separation
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|
578 |
theorem successor_reflection: |
13429 | 579 |
"REFLECTS[\<lambda>x. successor(L,f(x),g(x)), |
13323
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More relativization, reflection and proofs of separation
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|
580 |
\<lambda>i x. successor(**Lset(i),f(x),g(x))]" |
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More relativization, reflection and proofs of separation
paulson
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diff
changeset
|
581 |
apply (simp only: successor_def setclass_simps) |
13429 | 582 |
apply (intro cons_reflection) |
13314 | 583 |
done |
13298 | 584 |
|
585 |
||
13363 | 586 |
subsubsection{*The Number 1, Internalized*} |
587 |
||
588 |
(* "number1(M,a) == (\<exists>x[M]. empty(M,x) & successor(M,x,a))" *) |
|
589 |
constdefs number1_fm :: "i=>i" |
|
590 |
"number1_fm(a) == Exists(And(empty_fm(0), succ_fm(0,succ(a))))" |
|
591 |
||
592 |
lemma number1_type [TC]: |
|
593 |
"x \<in> nat ==> number1_fm(x) \<in> formula" |
|
13429 | 594 |
by (simp add: number1_fm_def) |
13363 | 595 |
|
596 |
lemma arity_number1_fm [simp]: |
|
597 |
"x \<in> nat ==> arity(number1_fm(x)) = succ(x)" |
|
13429 | 598 |
by (simp add: number1_fm_def succ_Un_distrib [symmetric] Un_ac) |
13363 | 599 |
|
600 |
lemma sats_number1_fm [simp]: |
|
601 |
"[| x \<in> nat; env \<in> list(A)|] |
|
602 |
==> sats(A, number1_fm(x), env) <-> number1(**A, nth(x,env))" |
|
603 |
by (simp add: number1_fm_def number1_def) |
|
604 |
||
605 |
lemma number1_iff_sats: |
|
13429 | 606 |
"[| nth(i,env) = x; nth(j,env) = y; |
13363 | 607 |
i \<in> nat; env \<in> list(A)|] |
608 |
==> number1(**A, x) <-> sats(A, number1_fm(i), env)" |
|
609 |
by simp |
|
610 |
||
611 |
theorem number1_reflection: |
|
13429 | 612 |
"REFLECTS[\<lambda>x. number1(L,f(x)), |
13363 | 613 |
\<lambda>i x. number1(**Lset(i),f(x))]" |
614 |
apply (simp only: number1_def setclass_simps) |
|
615 |
apply (intro FOL_reflections empty_reflection successor_reflection) |
|
616 |
done |
|
617 |
||
618 |
||
13352 | 619 |
subsubsection{*Big Union, Internalized*} |
13306 | 620 |
|
13352 | 621 |
(* "big_union(M,A,z) == \<forall>x[M]. x \<in> z <-> (\<exists>y[M]. y\<in>A & x \<in> y)" *) |
622 |
constdefs big_union_fm :: "[i,i]=>i" |
|
13429 | 623 |
"big_union_fm(A,z) == |
13352 | 624 |
Forall(Iff(Member(0,succ(z)), |
625 |
Exists(And(Member(0,succ(succ(A))), Member(1,0)))))" |
|
13298 | 626 |
|
13352 | 627 |
lemma big_union_type [TC]: |
628 |
"[| x \<in> nat; y \<in> nat |] ==> big_union_fm(x,y) \<in> formula" |
|
13429 | 629 |
by (simp add: big_union_fm_def) |
13306 | 630 |
|
13352 | 631 |
lemma arity_big_union_fm [simp]: |
13429 | 632 |
"[| x \<in> nat; y \<in> nat |] |
13352 | 633 |
==> arity(big_union_fm(x,y)) = succ(x) \<union> succ(y)" |
634 |
by (simp add: big_union_fm_def succ_Un_distrib [symmetric] Un_ac) |
|
13298 | 635 |
|
13352 | 636 |
lemma sats_big_union_fm [simp]: |
637 |
"[| x \<in> nat; y \<in> nat; env \<in> list(A)|] |
|
13429 | 638 |
==> sats(A, big_union_fm(x,y), env) <-> |
13352 | 639 |
big_union(**A, nth(x,env), nth(y,env))" |
640 |
by (simp add: big_union_fm_def big_union_def) |
|
13306 | 641 |
|
13352 | 642 |
lemma big_union_iff_sats: |
13429 | 643 |
"[| nth(i,env) = x; nth(j,env) = y; |
13352 | 644 |
i \<in> nat; j \<in> nat; env \<in> list(A)|] |
645 |
==> big_union(**A, x, y) <-> sats(A, big_union_fm(i,j), env)" |
|
13306 | 646 |
by simp |
647 |
||
13352 | 648 |
theorem big_union_reflection: |
13429 | 649 |
"REFLECTS[\<lambda>x. big_union(L,f(x),g(x)), |
13352 | 650 |
\<lambda>i x. big_union(**Lset(i),f(x),g(x))]" |
651 |
apply (simp only: big_union_def setclass_simps) |
|
13429 | 652 |
apply (intro FOL_reflections) |
13314 | 653 |
done |
13298 | 654 |
|
655 |
||
13306 | 656 |
subsubsection{*Variants of Satisfaction Definitions for Ordinals, etc.*} |
657 |
||
658 |
text{*Differs from the one in Formula by using "ordinal" rather than "Ord"*} |
|
659 |
||
660 |
||
661 |
lemma sats_subset_fm': |
|
662 |
"[|x \<in> nat; y \<in> nat; env \<in> list(A)|] |
|
13429 | 663 |
==> sats(A, subset_fm(x,y), env) <-> subset(**A, nth(x,env), nth(y,env))" |
664 |
by (simp add: subset_fm_def Relative.subset_def) |
|
13298 | 665 |
|
13314 | 666 |
theorem subset_reflection: |
13429 | 667 |
"REFLECTS[\<lambda>x. subset(L,f(x),g(x)), |
668 |
\<lambda>i x. subset(**Lset(i),f(x),g(x))]" |
|
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More relativization, reflection and proofs of separation
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changeset
|
669 |
apply (simp only: Relative.subset_def setclass_simps) |
13429 | 670 |
apply (intro FOL_reflections) |
13314 | 671 |
done |
13306 | 672 |
|
673 |
lemma sats_transset_fm': |
|
674 |
"[|x \<in> nat; env \<in> list(A)|] |
|
675 |
==> sats(A, transset_fm(x), env) <-> transitive_set(**A, nth(x,env))" |
|
13429 | 676 |
by (simp add: sats_subset_fm' transset_fm_def transitive_set_def) |
13298 | 677 |
|
13314 | 678 |
theorem transitive_set_reflection: |
679 |
"REFLECTS[\<lambda>x. transitive_set(L,f(x)), |
|
680 |
\<lambda>i x. transitive_set(**Lset(i),f(x))]" |
|
681 |
apply (simp only: transitive_set_def setclass_simps) |
|
13429 | 682 |
apply (intro FOL_reflections subset_reflection) |
13314 | 683 |
done |
13306 | 684 |
|
685 |
lemma sats_ordinal_fm': |
|
686 |
"[|x \<in> nat; env \<in> list(A)|] |
|
687 |
==> sats(A, ordinal_fm(x), env) <-> ordinal(**A,nth(x,env))" |
|
688 |
by (simp add: sats_transset_fm' ordinal_fm_def ordinal_def) |
|
689 |
||
690 |
lemma ordinal_iff_sats: |
|
691 |
"[| nth(i,env) = x; i \<in> nat; env \<in> list(A)|] |
|
692 |
==> ordinal(**A, x) <-> sats(A, ordinal_fm(i), env)" |
|
693 |
by (simp add: sats_ordinal_fm') |
|
694 |
||
13314 | 695 |
theorem ordinal_reflection: |
696 |
"REFLECTS[\<lambda>x. ordinal(L,f(x)), \<lambda>i x. ordinal(**Lset(i),f(x))]" |
|
697 |
apply (simp only: ordinal_def setclass_simps) |
|
13429 | 698 |
apply (intro FOL_reflections transitive_set_reflection) |
13314 | 699 |
done |
13298 | 700 |
|
701 |
||
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Fixed quantified variable name preservation for ball and bex (bounded quants)
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13323
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changeset
|
702 |
subsubsection{*Membership Relation, Internalized*} |
13298 | 703 |
|
13306 | 704 |
constdefs Memrel_fm :: "[i,i]=>i" |
13429 | 705 |
"Memrel_fm(A,r) == |
13306 | 706 |
Forall(Iff(Member(0,succ(r)), |
707 |
Exists(And(Member(0,succ(succ(A))), |
|
708 |
Exists(And(Member(0,succ(succ(succ(A)))), |
|
709 |
And(Member(1,0), |
|
710 |
pair_fm(1,0,2))))))))" |
|
711 |
||
712 |
lemma Memrel_type [TC]: |
|
713 |
"[| x \<in> nat; y \<in> nat |] ==> Memrel_fm(x,y) \<in> formula" |
|
13429 | 714 |
by (simp add: Memrel_fm_def) |
13298 | 715 |
|
13306 | 716 |
lemma arity_Memrel_fm [simp]: |
13429 | 717 |
"[| x \<in> nat; y \<in> nat |] |
13306 | 718 |
==> arity(Memrel_fm(x,y)) = succ(x) \<union> succ(y)" |
13429 | 719 |
by (simp add: Memrel_fm_def succ_Un_distrib [symmetric] Un_ac) |
13306 | 720 |
|
721 |
lemma sats_Memrel_fm [simp]: |
|
722 |
"[| x \<in> nat; y \<in> nat; env \<in> list(A)|] |
|
13429 | 723 |
==> sats(A, Memrel_fm(x,y), env) <-> |
13306 | 724 |
membership(**A, nth(x,env), nth(y,env))" |
725 |
by (simp add: Memrel_fm_def membership_def) |
|
13298 | 726 |
|
13306 | 727 |
lemma Memrel_iff_sats: |
13429 | 728 |
"[| nth(i,env) = x; nth(j,env) = y; |
13306 | 729 |
i \<in> nat; j \<in> nat; env \<in> list(A)|] |
730 |
==> membership(**A, x, y) <-> sats(A, Memrel_fm(i,j), env)" |
|
731 |
by simp |
|
13304 | 732 |
|
13314 | 733 |
theorem membership_reflection: |
13429 | 734 |
"REFLECTS[\<lambda>x. membership(L,f(x),g(x)), |
13314 | 735 |
\<lambda>i x. membership(**Lset(i),f(x),g(x))]" |
736 |
apply (simp only: membership_def setclass_simps) |
|
13429 | 737 |
apply (intro FOL_reflections pair_reflection) |
13314 | 738 |
done |
13304 | 739 |
|
13339
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Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
740 |
subsubsection{*Predecessor Set, Internalized*} |
13304 | 741 |
|
13306 | 742 |
constdefs pred_set_fm :: "[i,i,i,i]=>i" |
13429 | 743 |
"pred_set_fm(A,x,r,B) == |
13306 | 744 |
Forall(Iff(Member(0,succ(B)), |
745 |
Exists(And(Member(0,succ(succ(r))), |
|
746 |
And(Member(1,succ(succ(A))), |
|
747 |
pair_fm(1,succ(succ(x)),0))))))" |
|
748 |
||
749 |
||
750 |
lemma pred_set_type [TC]: |
|
13429 | 751 |
"[| A \<in> nat; x \<in> nat; r \<in> nat; B \<in> nat |] |
13306 | 752 |
==> pred_set_fm(A,x,r,B) \<in> formula" |
13429 | 753 |
by (simp add: pred_set_fm_def) |
13304 | 754 |
|
13306 | 755 |
lemma arity_pred_set_fm [simp]: |
13429 | 756 |
"[| A \<in> nat; x \<in> nat; r \<in> nat; B \<in> nat |] |
13306 | 757 |
==> arity(pred_set_fm(A,x,r,B)) = succ(A) \<union> succ(x) \<union> succ(r) \<union> succ(B)" |
13429 | 758 |
by (simp add: pred_set_fm_def succ_Un_distrib [symmetric] Un_ac) |
13306 | 759 |
|
760 |
lemma sats_pred_set_fm [simp]: |
|
761 |
"[| U \<in> nat; x \<in> nat; r \<in> nat; B \<in> nat; env \<in> list(A)|] |
|
13429 | 762 |
==> sats(A, pred_set_fm(U,x,r,B), env) <-> |
13306 | 763 |
pred_set(**A, nth(U,env), nth(x,env), nth(r,env), nth(B,env))" |
764 |
by (simp add: pred_set_fm_def pred_set_def) |
|
765 |
||
766 |
lemma pred_set_iff_sats: |
|
13429 | 767 |
"[| nth(i,env) = U; nth(j,env) = x; nth(k,env) = r; nth(l,env) = B; |
13306 | 768 |
i \<in> nat; j \<in> nat; k \<in> nat; l \<in> nat; env \<in> list(A)|] |
769 |
==> pred_set(**A,U,x,r,B) <-> sats(A, pred_set_fm(i,j,k,l), env)" |
|
770 |
by (simp add: sats_pred_set_fm) |
|
771 |
||
13314 | 772 |
theorem pred_set_reflection: |
13429 | 773 |
"REFLECTS[\<lambda>x. pred_set(L,f(x),g(x),h(x),b(x)), |
774 |
\<lambda>i x. pred_set(**Lset(i),f(x),g(x),h(x),b(x))]" |
|
13314 | 775 |
apply (simp only: pred_set_def setclass_simps) |
13429 | 776 |
apply (intro FOL_reflections pair_reflection) |
13314 | 777 |
done |
13304 | 778 |
|
779 |
||
13298 | 780 |
|
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
781 |
subsubsection{*Domain of a Relation, Internalized*} |
13306 | 782 |
|
13429 | 783 |
(* "is_domain(M,r,z) == |
784 |
\<forall>x[M]. (x \<in> z <-> (\<exists>w[M]. w\<in>r & (\<exists>y[M]. pair(M,x,y,w))))" *) |
|
13306 | 785 |
constdefs domain_fm :: "[i,i]=>i" |
13429 | 786 |
"domain_fm(r,z) == |
13306 | 787 |
Forall(Iff(Member(0,succ(z)), |
788 |
Exists(And(Member(0,succ(succ(r))), |
|
789 |
Exists(pair_fm(2,0,1))))))" |
|
790 |
||
791 |
lemma domain_type [TC]: |
|
792 |
"[| x \<in> nat; y \<in> nat |] ==> domain_fm(x,y) \<in> formula" |
|
13429 | 793 |
by (simp add: domain_fm_def) |
13306 | 794 |
|
795 |
lemma arity_domain_fm [simp]: |
|
13429 | 796 |
"[| x \<in> nat; y \<in> nat |] |
13306 | 797 |
==> arity(domain_fm(x,y)) = succ(x) \<union> succ(y)" |
13429 | 798 |
by (simp add: domain_fm_def succ_Un_distrib [symmetric] Un_ac) |
13306 | 799 |
|
800 |
lemma sats_domain_fm [simp]: |
|
801 |
"[| x \<in> nat; y \<in> nat; env \<in> list(A)|] |
|
13429 | 802 |
==> sats(A, domain_fm(x,y), env) <-> |
13306 | 803 |
is_domain(**A, nth(x,env), nth(y,env))" |
804 |
by (simp add: domain_fm_def is_domain_def) |
|
805 |
||
806 |
lemma domain_iff_sats: |
|
13429 | 807 |
"[| nth(i,env) = x; nth(j,env) = y; |
13306 | 808 |
i \<in> nat; j \<in> nat; env \<in> list(A)|] |
809 |
==> is_domain(**A, x, y) <-> sats(A, domain_fm(i,j), env)" |
|
810 |
by simp |
|
811 |
||
13314 | 812 |
theorem domain_reflection: |
13429 | 813 |
"REFLECTS[\<lambda>x. is_domain(L,f(x),g(x)), |
13314 | 814 |
\<lambda>i x. is_domain(**Lset(i),f(x),g(x))]" |
815 |
apply (simp only: is_domain_def setclass_simps) |
|
13429 | 816 |
apply (intro FOL_reflections pair_reflection) |
13314 | 817 |
done |
13306 | 818 |
|
819 |
||
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
820 |
subsubsection{*Range of a Relation, Internalized*} |
13306 | 821 |
|
13429 | 822 |
(* "is_range(M,r,z) == |
823 |
\<forall>y[M]. (y \<in> z <-> (\<exists>w[M]. w\<in>r & (\<exists>x[M]. pair(M,x,y,w))))" *) |
|
13306 | 824 |
constdefs range_fm :: "[i,i]=>i" |
13429 | 825 |
"range_fm(r,z) == |
13306 | 826 |
Forall(Iff(Member(0,succ(z)), |
827 |
Exists(And(Member(0,succ(succ(r))), |
|
828 |
Exists(pair_fm(0,2,1))))))" |
|
829 |
||
830 |
lemma range_type [TC]: |
|
831 |
"[| x \<in> nat; y \<in> nat |] ==> range_fm(x,y) \<in> formula" |
|
13429 | 832 |
by (simp add: range_fm_def) |
13306 | 833 |
|
834 |
lemma arity_range_fm [simp]: |
|
13429 | 835 |
"[| x \<in> nat; y \<in> nat |] |
13306 | 836 |
==> arity(range_fm(x,y)) = succ(x) \<union> succ(y)" |
13429 | 837 |
by (simp add: range_fm_def succ_Un_distrib [symmetric] Un_ac) |
13306 | 838 |
|
839 |
lemma sats_range_fm [simp]: |
|
840 |
"[| x \<in> nat; y \<in> nat; env \<in> list(A)|] |
|
13429 | 841 |
==> sats(A, range_fm(x,y), env) <-> |
13306 | 842 |
is_range(**A, nth(x,env), nth(y,env))" |
843 |
by (simp add: range_fm_def is_range_def) |
|
844 |
||
845 |
lemma range_iff_sats: |
|
13429 | 846 |
"[| nth(i,env) = x; nth(j,env) = y; |
13306 | 847 |
i \<in> nat; j \<in> nat; env \<in> list(A)|] |
848 |
==> is_range(**A, x, y) <-> sats(A, range_fm(i,j), env)" |
|
849 |
by simp |
|
850 |
||
13314 | 851 |
theorem range_reflection: |
13429 | 852 |
"REFLECTS[\<lambda>x. is_range(L,f(x),g(x)), |
13314 | 853 |
\<lambda>i x. is_range(**Lset(i),f(x),g(x))]" |
854 |
apply (simp only: is_range_def setclass_simps) |
|
13429 | 855 |
apply (intro FOL_reflections pair_reflection) |
13314 | 856 |
done |
13306 | 857 |
|
13429 | 858 |
|
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
859 |
subsubsection{*Field of a Relation, Internalized*} |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
860 |
|
13429 | 861 |
(* "is_field(M,r,z) == |
862 |
\<exists>dr[M]. is_domain(M,r,dr) & |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
863 |
(\<exists>rr[M]. is_range(M,r,rr) & union(M,dr,rr,z))" *) |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
864 |
constdefs field_fm :: "[i,i]=>i" |
13429 | 865 |
"field_fm(r,z) == |
866 |
Exists(And(domain_fm(succ(r),0), |
|
867 |
Exists(And(range_fm(succ(succ(r)),0), |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
868 |
union_fm(1,0,succ(succ(z)))))))" |
2c287f50c9f3
More relativization, reflection and proofs of separation
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diff
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|
869 |
|
2c287f50c9f3
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diff
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|
870 |
lemma field_type [TC]: |
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parents:
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diff
changeset
|
871 |
"[| x \<in> nat; y \<in> nat |] ==> field_fm(x,y) \<in> formula" |
13429 | 872 |
by (simp add: field_fm_def) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
873 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
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diff
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|
874 |
lemma arity_field_fm [simp]: |
13429 | 875 |
"[| x \<in> nat; y \<in> nat |] |
13323
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More relativization, reflection and proofs of separation
paulson
parents:
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diff
changeset
|
876 |
==> arity(field_fm(x,y)) = succ(x) \<union> succ(y)" |
13429 | 877 |
by (simp add: field_fm_def succ_Un_distrib [symmetric] Un_ac) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
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diff
changeset
|
878 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
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parents:
13316
diff
changeset
|
879 |
lemma sats_field_fm [simp]: |
2c287f50c9f3
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parents:
13316
diff
changeset
|
880 |
"[| x \<in> nat; y \<in> nat; env \<in> list(A)|] |
13429 | 881 |
==> sats(A, field_fm(x,y), env) <-> |
13323
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More relativization, reflection and proofs of separation
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parents:
13316
diff
changeset
|
882 |
is_field(**A, nth(x,env), nth(y,env))" |
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paulson
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diff
changeset
|
883 |
by (simp add: field_fm_def is_field_def) |
2c287f50c9f3
More relativization, reflection and proofs of separation
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diff
changeset
|
884 |
|
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More relativization, reflection and proofs of separation
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parents:
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diff
changeset
|
885 |
lemma field_iff_sats: |
13429 | 886 |
"[| nth(i,env) = x; nth(j,env) = y; |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
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diff
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|
887 |
i \<in> nat; j \<in> nat; env \<in> list(A)|] |
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More relativization, reflection and proofs of separation
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parents:
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diff
changeset
|
888 |
==> is_field(**A, x, y) <-> sats(A, field_fm(i,j), env)" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
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diff
changeset
|
889 |
by simp |
2c287f50c9f3
More relativization, reflection and proofs of separation
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parents:
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diff
changeset
|
890 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
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parents:
13316
diff
changeset
|
891 |
theorem field_reflection: |
13429 | 892 |
"REFLECTS[\<lambda>x. is_field(L,f(x),g(x)), |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
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parents:
13316
diff
changeset
|
893 |
\<lambda>i x. is_field(**Lset(i),f(x),g(x))]" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
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diff
changeset
|
894 |
apply (simp only: is_field_def setclass_simps) |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
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diff
changeset
|
895 |
apply (intro FOL_reflections domain_reflection range_reflection |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
896 |
union_reflection) |
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More relativization, reflection and proofs of separation
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parents:
13316
diff
changeset
|
897 |
done |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
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diff
changeset
|
898 |
|
2c287f50c9f3
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parents:
13316
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changeset
|
899 |
|
13339
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Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
900 |
subsubsection{*Image under a Relation, Internalized*} |
13306 | 901 |
|
13429 | 902 |
(* "image(M,r,A,z) == |
13306 | 903 |
\<forall>y[M]. (y \<in> z <-> (\<exists>w[M]. w\<in>r & (\<exists>x[M]. x\<in>A & pair(M,x,y,w))))" *) |
904 |
constdefs image_fm :: "[i,i,i]=>i" |
|
13429 | 905 |
"image_fm(r,A,z) == |
13306 | 906 |
Forall(Iff(Member(0,succ(z)), |
907 |
Exists(And(Member(0,succ(succ(r))), |
|
908 |
Exists(And(Member(0,succ(succ(succ(A)))), |
|
13429 | 909 |
pair_fm(0,2,1)))))))" |
13306 | 910 |
|
911 |
lemma image_type [TC]: |
|
912 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> image_fm(x,y,z) \<in> formula" |
|
13429 | 913 |
by (simp add: image_fm_def) |
13306 | 914 |
|
915 |
lemma arity_image_fm [simp]: |
|
13429 | 916 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13306 | 917 |
==> arity(image_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 918 |
by (simp add: image_fm_def succ_Un_distrib [symmetric] Un_ac) |
13306 | 919 |
|
920 |
lemma sats_image_fm [simp]: |
|
921 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 922 |
==> sats(A, image_fm(x,y,z), env) <-> |
13306 | 923 |
image(**A, nth(x,env), nth(y,env), nth(z,env))" |
13323
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More relativization, reflection and proofs of separation
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13316
diff
changeset
|
924 |
by (simp add: image_fm_def Relative.image_def) |
13306 | 925 |
|
926 |
lemma image_iff_sats: |
|
13429 | 927 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13306 | 928 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
929 |
==> image(**A, x, y, z) <-> sats(A, image_fm(i,j,k), env)" |
|
930 |
by (simp add: sats_image_fm) |
|
931 |
||
13314 | 932 |
theorem image_reflection: |
13429 | 933 |
"REFLECTS[\<lambda>x. image(L,f(x),g(x),h(x)), |
13314 | 934 |
\<lambda>i x. image(**Lset(i),f(x),g(x),h(x))]" |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
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parents:
13316
diff
changeset
|
935 |
apply (simp only: Relative.image_def setclass_simps) |
13429 | 936 |
apply (intro FOL_reflections pair_reflection) |
13314 | 937 |
done |
13306 | 938 |
|
939 |
||
13348 | 940 |
subsubsection{*Pre-Image under a Relation, Internalized*} |
941 |
||
13429 | 942 |
(* "pre_image(M,r,A,z) == |
943 |
\<forall>x[M]. x \<in> z <-> (\<exists>w[M]. w\<in>r & (\<exists>y[M]. y\<in>A & pair(M,x,y,w)))" *) |
|
13348 | 944 |
constdefs pre_image_fm :: "[i,i,i]=>i" |
13429 | 945 |
"pre_image_fm(r,A,z) == |
13348 | 946 |
Forall(Iff(Member(0,succ(z)), |
947 |
Exists(And(Member(0,succ(succ(r))), |
|
948 |
Exists(And(Member(0,succ(succ(succ(A)))), |
|
13429 | 949 |
pair_fm(2,0,1)))))))" |
13348 | 950 |
|
951 |
lemma pre_image_type [TC]: |
|
952 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> pre_image_fm(x,y,z) \<in> formula" |
|
13429 | 953 |
by (simp add: pre_image_fm_def) |
13348 | 954 |
|
955 |
lemma arity_pre_image_fm [simp]: |
|
13429 | 956 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13348 | 957 |
==> arity(pre_image_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 958 |
by (simp add: pre_image_fm_def succ_Un_distrib [symmetric] Un_ac) |
13348 | 959 |
|
960 |
lemma sats_pre_image_fm [simp]: |
|
961 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 962 |
==> sats(A, pre_image_fm(x,y,z), env) <-> |
13348 | 963 |
pre_image(**A, nth(x,env), nth(y,env), nth(z,env))" |
964 |
by (simp add: pre_image_fm_def Relative.pre_image_def) |
|
965 |
||
966 |
lemma pre_image_iff_sats: |
|
13429 | 967 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13348 | 968 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
969 |
==> pre_image(**A, x, y, z) <-> sats(A, pre_image_fm(i,j,k), env)" |
|
970 |
by (simp add: sats_pre_image_fm) |
|
971 |
||
972 |
theorem pre_image_reflection: |
|
13429 | 973 |
"REFLECTS[\<lambda>x. pre_image(L,f(x),g(x),h(x)), |
13348 | 974 |
\<lambda>i x. pre_image(**Lset(i),f(x),g(x),h(x))]" |
975 |
apply (simp only: Relative.pre_image_def setclass_simps) |
|
13429 | 976 |
apply (intro FOL_reflections pair_reflection) |
13348 | 977 |
done |
978 |
||
979 |
||
13352 | 980 |
subsubsection{*Function Application, Internalized*} |
981 |
||
13429 | 982 |
(* "fun_apply(M,f,x,y) == |
983 |
(\<exists>xs[M]. \<exists>fxs[M]. |
|
13352 | 984 |
upair(M,x,x,xs) & image(M,f,xs,fxs) & big_union(M,fxs,y))" *) |
985 |
constdefs fun_apply_fm :: "[i,i,i]=>i" |
|
13429 | 986 |
"fun_apply_fm(f,x,y) == |
13352 | 987 |
Exists(Exists(And(upair_fm(succ(succ(x)), succ(succ(x)), 1), |
13429 | 988 |
And(image_fm(succ(succ(f)), 1, 0), |
13352 | 989 |
big_union_fm(0,succ(succ(y)))))))" |
990 |
||
991 |
lemma fun_apply_type [TC]: |
|
992 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> fun_apply_fm(x,y,z) \<in> formula" |
|
13429 | 993 |
by (simp add: fun_apply_fm_def) |
13352 | 994 |
|
995 |
lemma arity_fun_apply_fm [simp]: |
|
13429 | 996 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13352 | 997 |
==> arity(fun_apply_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 998 |
by (simp add: fun_apply_fm_def succ_Un_distrib [symmetric] Un_ac) |
13352 | 999 |
|
1000 |
lemma sats_fun_apply_fm [simp]: |
|
1001 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 1002 |
==> sats(A, fun_apply_fm(x,y,z), env) <-> |
13352 | 1003 |
fun_apply(**A, nth(x,env), nth(y,env), nth(z,env))" |
1004 |
by (simp add: fun_apply_fm_def fun_apply_def) |
|
1005 |
||
1006 |
lemma fun_apply_iff_sats: |
|
13429 | 1007 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13352 | 1008 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
1009 |
==> fun_apply(**A, x, y, z) <-> sats(A, fun_apply_fm(i,j,k), env)" |
|
1010 |
by simp |
|
1011 |
||
1012 |
theorem fun_apply_reflection: |
|
13429 | 1013 |
"REFLECTS[\<lambda>x. fun_apply(L,f(x),g(x),h(x)), |
1014 |
\<lambda>i x. fun_apply(**Lset(i),f(x),g(x),h(x))]" |
|
13352 | 1015 |
apply (simp only: fun_apply_def setclass_simps) |
1016 |
apply (intro FOL_reflections upair_reflection image_reflection |
|
13429 | 1017 |
big_union_reflection) |
13352 | 1018 |
done |
1019 |
||
1020 |
||
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
1021 |
subsubsection{*The Concept of Relation, Internalized*} |
13306 | 1022 |
|
13429 | 1023 |
(* "is_relation(M,r) == |
13306 | 1024 |
(\<forall>z[M]. z\<in>r --> (\<exists>x[M]. \<exists>y[M]. pair(M,x,y,z)))" *) |
1025 |
constdefs relation_fm :: "i=>i" |
|
13429 | 1026 |
"relation_fm(r) == |
13306 | 1027 |
Forall(Implies(Member(0,succ(r)), Exists(Exists(pair_fm(1,0,2)))))" |
1028 |
||
1029 |
lemma relation_type [TC]: |
|
1030 |
"[| x \<in> nat |] ==> relation_fm(x) \<in> formula" |
|
13429 | 1031 |
by (simp add: relation_fm_def) |
13306 | 1032 |
|
1033 |
lemma arity_relation_fm [simp]: |
|
1034 |
"x \<in> nat ==> arity(relation_fm(x)) = succ(x)" |
|
13429 | 1035 |
by (simp add: relation_fm_def succ_Un_distrib [symmetric] Un_ac) |
13306 | 1036 |
|
1037 |
lemma sats_relation_fm [simp]: |
|
1038 |
"[| x \<in> nat; env \<in> list(A)|] |
|
1039 |
==> sats(A, relation_fm(x), env) <-> is_relation(**A, nth(x,env))" |
|
1040 |
by (simp add: relation_fm_def is_relation_def) |
|
1041 |
||
1042 |
lemma relation_iff_sats: |
|
13429 | 1043 |
"[| nth(i,env) = x; nth(j,env) = y; |
13306 | 1044 |
i \<in> nat; env \<in> list(A)|] |
1045 |
==> is_relation(**A, x) <-> sats(A, relation_fm(i), env)" |
|
1046 |
by simp |
|
1047 |
||
13314 | 1048 |
theorem is_relation_reflection: |
13429 | 1049 |
"REFLECTS[\<lambda>x. is_relation(L,f(x)), |
13314 | 1050 |
\<lambda>i x. is_relation(**Lset(i),f(x))]" |
1051 |
apply (simp only: is_relation_def setclass_simps) |
|
13429 | 1052 |
apply (intro FOL_reflections pair_reflection) |
13314 | 1053 |
done |
13306 | 1054 |
|
1055 |
||
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
1056 |
subsubsection{*The Concept of Function, Internalized*} |
13306 | 1057 |
|
13429 | 1058 |
(* "is_function(M,r) == |
1059 |
\<forall>x[M]. \<forall>y[M]. \<forall>y'[M]. \<forall>p[M]. \<forall>p'[M]. |
|
13306 | 1060 |
pair(M,x,y,p) --> pair(M,x,y',p') --> p\<in>r --> p'\<in>r --> y=y'" *) |
1061 |
constdefs function_fm :: "i=>i" |
|
13429 | 1062 |
"function_fm(r) == |
13306 | 1063 |
Forall(Forall(Forall(Forall(Forall( |
1064 |
Implies(pair_fm(4,3,1), |
|
1065 |
Implies(pair_fm(4,2,0), |
|
1066 |
Implies(Member(1,r#+5), |
|
1067 |
Implies(Member(0,r#+5), Equal(3,2))))))))))" |
|
1068 |
||
1069 |
lemma function_type [TC]: |
|
1070 |
"[| x \<in> nat |] ==> function_fm(x) \<in> formula" |
|
13429 | 1071 |
by (simp add: function_fm_def) |
13306 | 1072 |
|
1073 |
lemma arity_function_fm [simp]: |
|
1074 |
"x \<in> nat ==> arity(function_fm(x)) = succ(x)" |
|
13429 | 1075 |
by (simp add: function_fm_def succ_Un_distrib [symmetric] Un_ac) |
13306 | 1076 |
|
1077 |
lemma sats_function_fm [simp]: |
|
1078 |
"[| x \<in> nat; env \<in> list(A)|] |
|
1079 |
==> sats(A, function_fm(x), env) <-> is_function(**A, nth(x,env))" |
|
1080 |
by (simp add: function_fm_def is_function_def) |
|
1081 |
||
1082 |
lemma function_iff_sats: |
|
13429 | 1083 |
"[| nth(i,env) = x; nth(j,env) = y; |
13306 | 1084 |
i \<in> nat; env \<in> list(A)|] |
1085 |
==> is_function(**A, x) <-> sats(A, function_fm(i), env)" |
|
1086 |
by simp |
|
1087 |
||
13314 | 1088 |
theorem is_function_reflection: |
13429 | 1089 |
"REFLECTS[\<lambda>x. is_function(L,f(x)), |
13314 | 1090 |
\<lambda>i x. is_function(**Lset(i),f(x))]" |
1091 |
apply (simp only: is_function_def setclass_simps) |
|
13429 | 1092 |
apply (intro FOL_reflections pair_reflection) |
13314 | 1093 |
done |
13298 | 1094 |
|
1095 |
||
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
1096 |
subsubsection{*Typed Functions, Internalized*} |
13309 | 1097 |
|
13429 | 1098 |
(* "typed_function(M,A,B,r) == |
13309 | 1099 |
is_function(M,r) & is_relation(M,r) & is_domain(M,r,A) & |
1100 |
(\<forall>u[M]. u\<in>r --> (\<forall>x[M]. \<forall>y[M]. pair(M,x,y,u) --> y\<in>B))" *) |
|
1101 |
||
1102 |
constdefs typed_function_fm :: "[i,i,i]=>i" |
|
13429 | 1103 |
"typed_function_fm(A,B,r) == |
13309 | 1104 |
And(function_fm(r), |
1105 |
And(relation_fm(r), |
|
1106 |
And(domain_fm(r,A), |
|
1107 |
Forall(Implies(Member(0,succ(r)), |
|
1108 |
Forall(Forall(Implies(pair_fm(1,0,2),Member(0,B#+3)))))))))" |
|
1109 |
||
1110 |
lemma typed_function_type [TC]: |
|
1111 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> typed_function_fm(x,y,z) \<in> formula" |
|
13429 | 1112 |
by (simp add: typed_function_fm_def) |
13309 | 1113 |
|
1114 |
lemma arity_typed_function_fm [simp]: |
|
13429 | 1115 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13309 | 1116 |
==> arity(typed_function_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 1117 |
by (simp add: typed_function_fm_def succ_Un_distrib [symmetric] Un_ac) |
13309 | 1118 |
|
1119 |
lemma sats_typed_function_fm [simp]: |
|
1120 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 1121 |
==> sats(A, typed_function_fm(x,y,z), env) <-> |
13309 | 1122 |
typed_function(**A, nth(x,env), nth(y,env), nth(z,env))" |
1123 |
by (simp add: typed_function_fm_def typed_function_def) |
|
1124 |
||
1125 |
lemma typed_function_iff_sats: |
|
13429 | 1126 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13309 | 1127 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
1128 |
==> typed_function(**A, x, y, z) <-> sats(A, typed_function_fm(i,j,k), env)" |
|
1129 |
by simp |
|
1130 |
||
13429 | 1131 |
lemmas function_reflections = |
13363 | 1132 |
empty_reflection number1_reflection |
13429 | 1133 |
upair_reflection pair_reflection union_reflection |
1134 |
big_union_reflection cons_reflection successor_reflection |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1135 |
fun_apply_reflection subset_reflection |
13429 | 1136 |
transitive_set_reflection membership_reflection |
1137 |
pred_set_reflection domain_reflection range_reflection field_reflection |
|
13348 | 1138 |
image_reflection pre_image_reflection |
13429 | 1139 |
is_relation_reflection is_function_reflection |
13309 | 1140 |
|
13429 | 1141 |
lemmas function_iff_sats = |
1142 |
empty_iff_sats number1_iff_sats |
|
1143 |
upair_iff_sats pair_iff_sats union_iff_sats |
|
1144 |
cons_iff_sats successor_iff_sats |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
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13316
diff
changeset
|
1145 |
fun_apply_iff_sats Memrel_iff_sats |
13429 | 1146 |
pred_set_iff_sats domain_iff_sats range_iff_sats field_iff_sats |
1147 |
image_iff_sats pre_image_iff_sats |
|
1148 |
relation_iff_sats function_iff_sats |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
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13316
diff
changeset
|
1149 |
|
13309 | 1150 |
|
13314 | 1151 |
theorem typed_function_reflection: |
13429 | 1152 |
"REFLECTS[\<lambda>x. typed_function(L,f(x),g(x),h(x)), |
13314 | 1153 |
\<lambda>i x. typed_function(**Lset(i),f(x),g(x),h(x))]" |
1154 |
apply (simp only: typed_function_def setclass_simps) |
|
13429 | 1155 |
apply (intro FOL_reflections function_reflections) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1156 |
done |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1157 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1158 |
|
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
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parents:
13323
diff
changeset
|
1159 |
subsubsection{*Composition of Relations, Internalized*} |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
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13316
diff
changeset
|
1160 |
|
13429 | 1161 |
(* "composition(M,r,s,t) == |
1162 |
\<forall>p[M]. p \<in> t <-> |
|
1163 |
(\<exists>x[M]. \<exists>y[M]. \<exists>z[M]. \<exists>xy[M]. \<exists>yz[M]. |
|
1164 |
pair(M,x,z,p) & pair(M,x,y,xy) & pair(M,y,z,yz) & |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
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13316
diff
changeset
|
1165 |
xy \<in> s & yz \<in> r)" *) |
2c287f50c9f3
More relativization, reflection and proofs of separation
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13316
diff
changeset
|
1166 |
constdefs composition_fm :: "[i,i,i]=>i" |
13429 | 1167 |
"composition_fm(r,s,t) == |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1168 |
Forall(Iff(Member(0,succ(t)), |
13429 | 1169 |
Exists(Exists(Exists(Exists(Exists( |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1170 |
And(pair_fm(4,2,5), |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1171 |
And(pair_fm(4,3,1), |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1172 |
And(pair_fm(3,2,0), |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1173 |
And(Member(1,s#+6), Member(0,r#+6))))))))))))" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1174 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1175 |
lemma composition_type [TC]: |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1176 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> composition_fm(x,y,z) \<in> formula" |
13429 | 1177 |
by (simp add: composition_fm_def) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1178 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1179 |
lemma arity_composition_fm [simp]: |
13429 | 1180 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1181 |
==> arity(composition_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 1182 |
by (simp add: composition_fm_def succ_Un_distrib [symmetric] Un_ac) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1183 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1184 |
lemma sats_composition_fm [simp]: |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1185 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
13429 | 1186 |
==> sats(A, composition_fm(x,y,z), env) <-> |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1187 |
composition(**A, nth(x,env), nth(y,env), nth(z,env))" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1188 |
by (simp add: composition_fm_def composition_def) |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1189 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1190 |
lemma composition_iff_sats: |
13429 | 1191 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1192 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1193 |
==> composition(**A, x, y, z) <-> sats(A, composition_fm(i,j,k), env)" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1194 |
by simp |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1195 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1196 |
theorem composition_reflection: |
13429 | 1197 |
"REFLECTS[\<lambda>x. composition(L,f(x),g(x),h(x)), |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1198 |
\<lambda>i x. composition(**Lset(i),f(x),g(x),h(x))]" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1199 |
apply (simp only: composition_def setclass_simps) |
13429 | 1200 |
apply (intro FOL_reflections pair_reflection) |
13314 | 1201 |
done |
1202 |
||
13309 | 1203 |
|
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
1204 |
subsubsection{*Injections, Internalized*} |
13309 | 1205 |
|
13429 | 1206 |
(* "injection(M,A,B,f) == |
1207 |
typed_function(M,A,B,f) & |
|
1208 |
(\<forall>x[M]. \<forall>x'[M]. \<forall>y[M]. \<forall>p[M]. \<forall>p'[M]. |
|
13309 | 1209 |
pair(M,x,y,p) --> pair(M,x',y,p') --> p\<in>f --> p'\<in>f --> x=x')" *) |
1210 |
constdefs injection_fm :: "[i,i,i]=>i" |
|
13429 | 1211 |
"injection_fm(A,B,f) == |
13309 | 1212 |
And(typed_function_fm(A,B,f), |
1213 |
Forall(Forall(Forall(Forall(Forall( |
|
1214 |
Implies(pair_fm(4,2,1), |
|
1215 |
Implies(pair_fm(3,2,0), |
|
1216 |
Implies(Member(1,f#+5), |
|
1217 |
Implies(Member(0,f#+5), Equal(4,3)))))))))))" |
|
1218 |
||
1219 |
||
1220 |
lemma injection_type [TC]: |
|
1221 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> injection_fm(x,y,z) \<in> formula" |
|
13429 | 1222 |
by (simp add: injection_fm_def) |
13309 | 1223 |
|
1224 |
lemma arity_injection_fm [simp]: |
|
13429 | 1225 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13309 | 1226 |
==> arity(injection_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 1227 |
by (simp add: injection_fm_def succ_Un_distrib [symmetric] Un_ac) |
13309 | 1228 |
|
1229 |
lemma sats_injection_fm [simp]: |
|
1230 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 1231 |
==> sats(A, injection_fm(x,y,z), env) <-> |
13309 | 1232 |
injection(**A, nth(x,env), nth(y,env), nth(z,env))" |
1233 |
by (simp add: injection_fm_def injection_def) |
|
1234 |
||
1235 |
lemma injection_iff_sats: |
|
13429 | 1236 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13309 | 1237 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
1238 |
==> injection(**A, x, y, z) <-> sats(A, injection_fm(i,j,k), env)" |
|
1239 |
by simp |
|
1240 |
||
13314 | 1241 |
theorem injection_reflection: |
13429 | 1242 |
"REFLECTS[\<lambda>x. injection(L,f(x),g(x),h(x)), |
13314 | 1243 |
\<lambda>i x. injection(**Lset(i),f(x),g(x),h(x))]" |
1244 |
apply (simp only: injection_def setclass_simps) |
|
13429 | 1245 |
apply (intro FOL_reflections function_reflections typed_function_reflection) |
13314 | 1246 |
done |
13309 | 1247 |
|
1248 |
||
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
1249 |
subsubsection{*Surjections, Internalized*} |
13309 | 1250 |
|
1251 |
(* surjection :: "[i=>o,i,i,i] => o" |
|
13429 | 1252 |
"surjection(M,A,B,f) == |
13309 | 1253 |
typed_function(M,A,B,f) & |
1254 |
(\<forall>y[M]. y\<in>B --> (\<exists>x[M]. x\<in>A & fun_apply(M,f,x,y)))" *) |
|
1255 |
constdefs surjection_fm :: "[i,i,i]=>i" |
|
13429 | 1256 |
"surjection_fm(A,B,f) == |
13309 | 1257 |
And(typed_function_fm(A,B,f), |
1258 |
Forall(Implies(Member(0,succ(B)), |
|
1259 |
Exists(And(Member(0,succ(succ(A))), |
|
1260 |
fun_apply_fm(succ(succ(f)),0,1))))))" |
|
1261 |
||
1262 |
lemma surjection_type [TC]: |
|
1263 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> surjection_fm(x,y,z) \<in> formula" |
|
13429 | 1264 |
by (simp add: surjection_fm_def) |
13309 | 1265 |
|
1266 |
lemma arity_surjection_fm [simp]: |
|
13429 | 1267 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13309 | 1268 |
==> arity(surjection_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 1269 |
by (simp add: surjection_fm_def succ_Un_distrib [symmetric] Un_ac) |
13309 | 1270 |
|
1271 |
lemma sats_surjection_fm [simp]: |
|
1272 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 1273 |
==> sats(A, surjection_fm(x,y,z), env) <-> |
13309 | 1274 |
surjection(**A, nth(x,env), nth(y,env), nth(z,env))" |
1275 |
by (simp add: surjection_fm_def surjection_def) |
|
1276 |
||
1277 |
lemma surjection_iff_sats: |
|
13429 | 1278 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13309 | 1279 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
1280 |
==> surjection(**A, x, y, z) <-> sats(A, surjection_fm(i,j,k), env)" |
|
1281 |
by simp |
|
1282 |
||
13314 | 1283 |
theorem surjection_reflection: |
13429 | 1284 |
"REFLECTS[\<lambda>x. surjection(L,f(x),g(x),h(x)), |
13314 | 1285 |
\<lambda>i x. surjection(**Lset(i),f(x),g(x),h(x))]" |
1286 |
apply (simp only: surjection_def setclass_simps) |
|
13429 | 1287 |
apply (intro FOL_reflections function_reflections typed_function_reflection) |
13314 | 1288 |
done |
13309 | 1289 |
|
1290 |
||
1291 |
||
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
1292 |
subsubsection{*Bijections, Internalized*} |
13309 | 1293 |
|
1294 |
(* bijection :: "[i=>o,i,i,i] => o" |
|
1295 |
"bijection(M,A,B,f) == injection(M,A,B,f) & surjection(M,A,B,f)" *) |
|
1296 |
constdefs bijection_fm :: "[i,i,i]=>i" |
|
1297 |
"bijection_fm(A,B,f) == And(injection_fm(A,B,f), surjection_fm(A,B,f))" |
|
1298 |
||
1299 |
lemma bijection_type [TC]: |
|
1300 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> bijection_fm(x,y,z) \<in> formula" |
|
13429 | 1301 |
by (simp add: bijection_fm_def) |
13309 | 1302 |
|
1303 |
lemma arity_bijection_fm [simp]: |
|
13429 | 1304 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13309 | 1305 |
==> arity(bijection_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 1306 |
by (simp add: bijection_fm_def succ_Un_distrib [symmetric] Un_ac) |
13309 | 1307 |
|
1308 |
lemma sats_bijection_fm [simp]: |
|
1309 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 1310 |
==> sats(A, bijection_fm(x,y,z), env) <-> |
13309 | 1311 |
bijection(**A, nth(x,env), nth(y,env), nth(z,env))" |
1312 |
by (simp add: bijection_fm_def bijection_def) |
|
1313 |
||
1314 |
lemma bijection_iff_sats: |
|
13429 | 1315 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13309 | 1316 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
1317 |
==> bijection(**A, x, y, z) <-> sats(A, bijection_fm(i,j,k), env)" |
|
1318 |
by simp |
|
1319 |
||
13314 | 1320 |
theorem bijection_reflection: |
13429 | 1321 |
"REFLECTS[\<lambda>x. bijection(L,f(x),g(x),h(x)), |
13314 | 1322 |
\<lambda>i x. bijection(**Lset(i),f(x),g(x),h(x))]" |
1323 |
apply (simp only: bijection_def setclass_simps) |
|
13429 | 1324 |
apply (intro And_reflection injection_reflection surjection_reflection) |
13314 | 1325 |
done |
13309 | 1326 |
|
1327 |
||
13348 | 1328 |
subsubsection{*Restriction of a Relation, Internalized*} |
1329 |
||
1330 |
||
13429 | 1331 |
(* "restriction(M,r,A,z) == |
1332 |
\<forall>x[M]. x \<in> z <-> (x \<in> r & (\<exists>u[M]. u\<in>A & (\<exists>v[M]. pair(M,u,v,x))))" *) |
|
13348 | 1333 |
constdefs restriction_fm :: "[i,i,i]=>i" |
13429 | 1334 |
"restriction_fm(r,A,z) == |
13348 | 1335 |
Forall(Iff(Member(0,succ(z)), |
1336 |
And(Member(0,succ(r)), |
|
1337 |
Exists(And(Member(0,succ(succ(A))), |
|
1338 |
Exists(pair_fm(1,0,2)))))))" |
|
1339 |
||
1340 |
lemma restriction_type [TC]: |
|
1341 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> restriction_fm(x,y,z) \<in> formula" |
|
13429 | 1342 |
by (simp add: restriction_fm_def) |
13348 | 1343 |
|
1344 |
lemma arity_restriction_fm [simp]: |
|
13429 | 1345 |
"[| x \<in> nat; y \<in> nat; z \<in> nat |] |
13348 | 1346 |
==> arity(restriction_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)" |
13429 | 1347 |
by (simp add: restriction_fm_def succ_Un_distrib [symmetric] Un_ac) |
13348 | 1348 |
|
1349 |
lemma sats_restriction_fm [simp]: |
|
1350 |
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|] |
|
13429 | 1351 |
==> sats(A, restriction_fm(x,y,z), env) <-> |
13348 | 1352 |
restriction(**A, nth(x,env), nth(y,env), nth(z,env))" |
1353 |
by (simp add: restriction_fm_def restriction_def) |
|
1354 |
||
1355 |
lemma restriction_iff_sats: |
|
13429 | 1356 |
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z; |
13348 | 1357 |
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|] |
1358 |
==> restriction(**A, x, y, z) <-> sats(A, restriction_fm(i,j,k), env)" |
|
1359 |
by simp |
|
1360 |
||
1361 |
theorem restriction_reflection: |
|
13429 | 1362 |
"REFLECTS[\<lambda>x. restriction(L,f(x),g(x),h(x)), |
13348 | 1363 |
\<lambda>i x. restriction(**Lset(i),f(x),g(x),h(x))]" |
1364 |
apply (simp only: restriction_def setclass_simps) |
|
13429 | 1365 |
apply (intro FOL_reflections pair_reflection) |
13348 | 1366 |
done |
1367 |
||
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
1368 |
subsubsection{*Order-Isomorphisms, Internalized*} |
13309 | 1369 |
|
1370 |
(* order_isomorphism :: "[i=>o,i,i,i,i,i] => o" |
|
13429 | 1371 |
"order_isomorphism(M,A,r,B,s,f) == |
1372 |
bijection(M,A,B,f) & |
|
13309 | 1373 |
(\<forall>x[M]. x\<in>A --> (\<forall>y[M]. y\<in>A --> |
1374 |
(\<forall>p[M]. \<forall>fx[M]. \<forall>fy[M]. \<forall>q[M]. |
|
13429 | 1375 |
pair(M,x,y,p) --> fun_apply(M,f,x,fx) --> fun_apply(M,f,y,fy) --> |
13309 | 1376 |
pair(M,fx,fy,q) --> (p\<in>r <-> q\<in>s))))" |
1377 |
*) |
|
1378 |
||
1379 |
constdefs order_isomorphism_fm :: "[i,i,i,i,i]=>i" |
|
13429 | 1380 |
"order_isomorphism_fm(A,r,B,s,f) == |
1381 |
And(bijection_fm(A,B,f), |
|
13309 | 1382 |
Forall(Implies(Member(0,succ(A)), |
1383 |
Forall(Implies(Member(0,succ(succ(A))), |
|
1384 |
Forall(Forall(Forall(Forall( |
|
1385 |
Implies(pair_fm(5,4,3), |
|
1386 |
Implies(fun_apply_fm(f#+6,5,2), |
|
1387 |
Implies(fun_apply_fm(f#+6,4,1), |
|
13429 | 1388 |
Implies(pair_fm(2,1,0), |
13309 | 1389 |
Iff(Member(3,r#+6), Member(0,s#+6)))))))))))))))" |
1390 |
||
1391 |
lemma order_isomorphism_type [TC]: |
|
13429 | 1392 |
"[| A \<in> nat; r \<in> nat; B \<in> nat; s \<in> nat; f \<in> nat |] |
13309 | 1393 |
==> order_isomorphism_fm(A,r,B,s,f) \<in> formula" |
13429 | 1394 |
by (simp add: order_isomorphism_fm_def) |
13309 | 1395 |
|
1396 |
lemma arity_order_isomorphism_fm [simp]: |
|
13429 | 1397 |
"[| A \<in> nat; r \<in> nat; B \<in> nat; s \<in> nat; f \<in> nat |] |
1398 |
==> arity(order_isomorphism_fm(A,r,B,s,f)) = |
|
1399 |
succ(A) \<union> succ(r) \<union> succ(B) \<union> succ(s) \<union> succ(f)" |
|
1400 |
by (simp add: order_isomorphism_fm_def succ_Un_distrib [symmetric] Un_ac) |
|
13309 | 1401 |
|
1402 |
lemma sats_order_isomorphism_fm [simp]: |
|
1403 |
"[| U \<in> nat; r \<in> nat; B \<in> nat; s \<in> nat; f \<in> nat; env \<in> list(A)|] |
|
13429 | 1404 |
==> sats(A, order_isomorphism_fm(U,r,B,s,f), env) <-> |
1405 |
order_isomorphism(**A, nth(U,env), nth(r,env), nth(B,env), |
|
13309 | 1406 |
nth(s,env), nth(f,env))" |
1407 |
by (simp add: order_isomorphism_fm_def order_isomorphism_def) |
|
1408 |
||
1409 |
lemma order_isomorphism_iff_sats: |
|
13429 | 1410 |
"[| nth(i,env) = U; nth(j,env) = r; nth(k,env) = B; nth(j',env) = s; |
1411 |
nth(k',env) = f; |
|
13309 | 1412 |
i \<in> nat; j \<in> nat; k \<in> nat; j' \<in> nat; k' \<in> nat; env \<in> list(A)|] |
13429 | 1413 |
==> order_isomorphism(**A,U,r,B,s,f) <-> |
1414 |
sats(A, order_isomorphism_fm(i,j,k,j',k'), env)" |
|
13309 | 1415 |
by simp |
1416 |
||
13314 | 1417 |
theorem order_isomorphism_reflection: |
13429 | 1418 |
"REFLECTS[\<lambda>x. order_isomorphism(L,f(x),g(x),h(x),g'(x),h'(x)), |
13314 | 1419 |
\<lambda>i x. order_isomorphism(**Lset(i),f(x),g(x),h(x),g'(x),h'(x))]" |
1420 |
apply (simp only: order_isomorphism_def setclass_simps) |
|
13429 | 1421 |
apply (intro FOL_reflections function_reflections bijection_reflection) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1422 |
done |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1423 |
|
13339
0f89104dd377
Fixed quantified variable name preservation for ball and bex (bounded quants)
paulson
parents:
13323
diff
changeset
|
1424 |
subsubsection{*Limit Ordinals, Internalized*} |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1425 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1426 |
text{*A limit ordinal is a non-empty, successor-closed ordinal*} |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1427 |
|
13429 | 1428 |
(* "limit_ordinal(M,a) == |
1429 |
ordinal(M,a) & ~ empty(M,a) & |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1430 |
(\<forall>x[M]. x\<in>a --> (\<exists>y[M]. y\<in>a & successor(M,x,y)))" *) |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1431 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1432 |
constdefs limit_ordinal_fm :: "i=>i" |
13429 | 1433 |
"limit_ordinal_fm(x) == |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1434 |
And(ordinal_fm(x), |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1435 |
And(Neg(empty_fm(x)), |
13429 | 1436 |
Forall(Implies(Member(0,succ(x)), |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1437 |
Exists(And(Member(0,succ(succ(x))), |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1438 |
succ_fm(1,0)))))))" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1439 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1440 |
lemma limit_ordinal_type [TC]: |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1441 |
"x \<in> nat ==> limit_ordinal_fm(x) \<in> formula" |
13429 | 1442 |
by (simp add: limit_ordinal_fm_def) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1443 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1444 |
lemma arity_limit_ordinal_fm [simp]: |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1445 |
"x \<in> nat ==> arity(limit_ordinal_fm(x)) = succ(x)" |
13429 | 1446 |
by (simp add: limit_ordinal_fm_def succ_Un_distrib [symmetric] Un_ac) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1447 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1448 |
lemma sats_limit_ordinal_fm [simp]: |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1449 |
"[| x \<in> nat; env \<in> list(A)|] |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1450 |
==> sats(A, limit_ordinal_fm(x), env) <-> limit_ordinal(**A, nth(x,env))" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1451 |
by (simp add: limit_ordinal_fm_def limit_ordinal_def sats_ordinal_fm') |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1452 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1453 |
lemma limit_ordinal_iff_sats: |
13429 | 1454 |
"[| nth(i,env) = x; nth(j,env) = y; |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1455 |
i \<in> nat; env \<in> list(A)|] |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1456 |
==> limit_ordinal(**A, x) <-> sats(A, limit_ordinal_fm(i), env)" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1457 |
by simp |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1458 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1459 |
theorem limit_ordinal_reflection: |
13429 | 1460 |
"REFLECTS[\<lambda>x. limit_ordinal(L,f(x)), |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1461 |
\<lambda>i x. limit_ordinal(**Lset(i),f(x))]" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1462 |
apply (simp only: limit_ordinal_def setclass_simps) |
13429 | 1463 |
apply (intro FOL_reflections ordinal_reflection |
1464 |
empty_reflection successor_reflection) |
|
13314 | 1465 |
done |
13309 | 1466 |
|
13493
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1467 |
subsubsection{*Finite Ordinals: The Predicate ``Is A Natural Number''*} |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1468 |
|
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1469 |
(* "finite_ordinal(M,a) == |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1470 |
ordinal(M,a) & ~ limit_ordinal(M,a) & |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1471 |
(\<forall>x[M]. x\<in>a --> ~ limit_ordinal(M,x))" *) |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1472 |
constdefs finite_ordinal_fm :: "i=>i" |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1473 |
"finite_ordinal_fm(x) == |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1474 |
And(ordinal_fm(x), |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1475 |
And(Neg(limit_ordinal_fm(x)), |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1476 |
Forall(Implies(Member(0,succ(x)), |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1477 |
Neg(limit_ordinal_fm(0))))))" |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1478 |
|
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1479 |
lemma finite_ordinal_type [TC]: |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1480 |
"x \<in> nat ==> finite_ordinal_fm(x) \<in> formula" |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1481 |
by (simp add: finite_ordinal_fm_def) |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1482 |
|
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1483 |
lemma sats_finite_ordinal_fm [simp]: |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1484 |
"[| x \<in> nat; env \<in> list(A)|] |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1485 |
==> sats(A, finite_ordinal_fm(x), env) <-> finite_ordinal(**A, nth(x,env))" |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1486 |
by (simp add: finite_ordinal_fm_def sats_ordinal_fm' finite_ordinal_def) |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1487 |
|
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1488 |
lemma finite_ordinal_iff_sats: |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1489 |
"[| nth(i,env) = x; nth(j,env) = y; |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1490 |
i \<in> nat; env \<in> list(A)|] |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1491 |
==> finite_ordinal(**A, x) <-> sats(A, finite_ordinal_fm(i), env)" |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1492 |
by simp |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1493 |
|
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1494 |
theorem finite_ordinal_reflection: |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1495 |
"REFLECTS[\<lambda>x. finite_ordinal(L,f(x)), |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1496 |
\<lambda>i x. finite_ordinal(**Lset(i),f(x))]" |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1497 |
apply (simp only: finite_ordinal_def setclass_simps) |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1498 |
apply (intro FOL_reflections ordinal_reflection limit_ordinal_reflection) |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1499 |
done |
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1500 |
|
5aa68c051725
Lots of new results concerning recursive datatypes, towards absoluteness of
paulson
parents:
13440
diff
changeset
|
1501 |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1502 |
subsubsection{*Omega: The Set of Natural Numbers*} |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1503 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1504 |
(* omega(M,a) == limit_ordinal(M,a) & (\<forall>x[M]. x\<in>a --> ~ limit_ordinal(M,x)) *) |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1505 |
constdefs omega_fm :: "i=>i" |
13429 | 1506 |
"omega_fm(x) == |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1507 |
And(limit_ordinal_fm(x), |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1508 |
Forall(Implies(Member(0,succ(x)), |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1509 |
Neg(limit_ordinal_fm(0)))))" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1510 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1511 |
lemma omega_type [TC]: |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1512 |
"x \<in> nat ==> omega_fm(x) \<in> formula" |
13429 | 1513 |
by (simp add: omega_fm_def) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1514 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1515 |
lemma arity_omega_fm [simp]: |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1516 |
"x \<in> nat ==> arity(omega_fm(x)) = succ(x)" |
13429 | 1517 |
by (simp add: omega_fm_def succ_Un_distrib [symmetric] Un_ac) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1518 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1519 |
lemma sats_omega_fm [simp]: |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1520 |
"[| x \<in> nat; env \<in> list(A)|] |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1521 |
==> sats(A, omega_fm(x), env) <-> omega(**A, nth(x,env))" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1522 |
by (simp add: omega_fm_def omega_def) |
13316 | 1523 |
|
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1524 |
lemma omega_iff_sats: |
13429 | 1525 |
"[| nth(i,env) = x; nth(j,env) = y; |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1526 |
i \<in> nat; env \<in> list(A)|] |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1527 |
==> omega(**A, x) <-> sats(A, omega_fm(i), env)" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1528 |
by simp |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1529 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1530 |
theorem omega_reflection: |
13429 | 1531 |
"REFLECTS[\<lambda>x. omega(L,f(x)), |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1532 |
\<lambda>i x. omega(**Lset(i),f(x))]" |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1533 |
apply (simp only: omega_def setclass_simps) |
13429 | 1534 |
apply (intro FOL_reflections limit_ordinal_reflection) |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1535 |
done |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1536 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1537 |
|
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1538 |
lemmas fun_plus_reflections = |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1539 |
typed_function_reflection composition_reflection |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1540 |
injection_reflection surjection_reflection |
13348 | 1541 |
bijection_reflection restriction_reflection |
13496
6f0c57def6d5
In ZF/Constructible, moved many results from Satisfies_absolute, etc., to
paulson
parents:
13493
diff
changeset
|
1542 |
order_isomorphism_reflection finite_ordinal_reflection |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1543 |
ordinal_reflection limit_ordinal_reflection omega_reflection |
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1544 |
|
13429 | 1545 |
lemmas fun_plus_iff_sats = |
1546 |
typed_function_iff_sats composition_iff_sats |
|
1547 |
injection_iff_sats surjection_iff_sats |
|
1548 |
bijection_iff_sats restriction_iff_sats |
|
13496
6f0c57def6d5
In ZF/Constructible, moved many results from Satisfies_absolute, etc., to
paulson
parents:
13493
diff
changeset
|
1549 |
order_isomorphism_iff_sats finite_ordinal_iff_sats |
13323
2c287f50c9f3
More relativization, reflection and proofs of separation
paulson
parents:
13316
diff
changeset
|
1550 |
ordinal_iff_sats limit_ordinal_iff_sats omega_iff_sats |
13316 | 1551 |
|
13223 | 1552 |
end |