header {* The class L satisfies the axioms of ZF*}
theory L_axioms = Formula + Relative + Reflection:
text {* The class L satisfies the premises of locale @{text M_axioms} *}
lemma transL: "[| y\<in>x; L(x) |] ==> L(y)"
apply (insert Transset_Lset)
apply (simp add: Transset_def L_def, blast)
done
lemma nonempty: "L(0)"
apply (simp add: L_def)
apply (blast intro: zero_in_Lset)
done
lemma upair_ax: "upair_ax(L)"
apply (simp add: upair_ax_def upair_def, clarify)
apply (rule_tac x="{x,y}" in exI)
apply (simp add: doubleton_in_L)
done
lemma Union_ax: "Union_ax(L)"
apply (simp add: Union_ax_def big_union_def, clarify)
apply (rule_tac x="Union(x)" in exI)
apply (simp add: Union_in_L, auto)
apply (blast intro: transL)
done
lemma power_ax: "power_ax(L)"
apply (simp add: power_ax_def powerset_def Relative.subset_def, clarify)
apply (rule_tac x="{y \<in> Pow(x). L(y)}" in exI)
apply (simp add: LPow_in_L, auto)
apply (blast intro: transL)
done
subsubsection{*For L to satisfy Replacement *}
(*Can't move these to Formula unless the definition of univalent is moved
there too!*)
lemma LReplace_in_Lset:
"[|X \<in> Lset(i); univalent(L,X,Q); Ord(i)|]
==> \<exists>j. Ord(j) & Replace(X, %x y. Q(x,y) & L(y)) \<subseteq> Lset(j)"
apply (rule_tac x="\<Union>y \<in> Replace(X, %x y. Q(x,y) & L(y)). succ(lrank(y))"
in exI)
apply simp
apply clarify
apply (rule_tac a="x" in UN_I)
apply (simp_all add: Replace_iff univalent_def)
apply (blast dest: transL L_I)
done
lemma LReplace_in_L:
"[|L(X); univalent(L,X,Q)|]
==> \<exists>Y. L(Y) & Replace(X, %x y. Q(x,y) & L(y)) \<subseteq> Y"
apply (drule L_D, clarify)
apply (drule LReplace_in_Lset, assumption+)
apply (blast intro: L_I Lset_in_Lset_succ)
done
lemma replacement: "replacement(L,P)"
apply (simp add: replacement_def, clarify)
apply (frule LReplace_in_L, assumption+, clarify)
apply (rule_tac x=Y in exI)
apply (simp add: Replace_iff univalent_def, blast)
done
subsection{*Instantiation of the locale @{text M_triv_axioms}*}
lemma Lset_mono_le: "mono_le_subset(Lset)"
by (simp add: mono_le_subset_def le_imp_subset Lset_mono)
lemma Lset_cont: "cont_Ord(Lset)"
by (simp add: cont_Ord_def Limit_Lset_eq OUnion_def Limit_is_Ord)
lemmas Pair_in_Lset = Formula.Pair_in_LLimit;
lemmas L_nat = Ord_in_L [OF Ord_nat];
ML
{*
val transL = thm "transL";
val nonempty = thm "nonempty";
val upair_ax = thm "upair_ax";
val Union_ax = thm "Union_ax";
val power_ax = thm "power_ax";
val replacement = thm "replacement";
val L_nat = thm "L_nat";
fun kill_flex_triv_prems st = Seq.hd ((REPEAT_FIRST assume_tac) st);
fun trivaxL th =
kill_flex_triv_prems
([transL, nonempty, upair_ax, Union_ax, power_ax, replacement, L_nat]
MRS (inst "M" "L" th));
bind_thm ("ball_abs", trivaxL (thm "M_triv_axioms.ball_abs"));
bind_thm ("rall_abs", trivaxL (thm "M_triv_axioms.rall_abs"));
bind_thm ("bex_abs", trivaxL (thm "M_triv_axioms.bex_abs"));
bind_thm ("rex_abs", trivaxL (thm "M_triv_axioms.rex_abs"));
bind_thm ("ball_iff_equiv", trivaxL (thm "M_triv_axioms.ball_iff_equiv"));
bind_thm ("M_equalityI", trivaxL (thm "M_triv_axioms.M_equalityI"));
bind_thm ("empty_abs", trivaxL (thm "M_triv_axioms.empty_abs"));
bind_thm ("subset_abs", trivaxL (thm "M_triv_axioms.subset_abs"));
bind_thm ("upair_abs", trivaxL (thm "M_triv_axioms.upair_abs"));
bind_thm ("upair_in_M_iff", trivaxL (thm "M_triv_axioms.upair_in_M_iff"));
bind_thm ("singleton_in_M_iff", trivaxL (thm "M_triv_axioms.singleton_in_M_iff"));
bind_thm ("pair_abs", trivaxL (thm "M_triv_axioms.pair_abs"));
bind_thm ("pair_in_M_iff", trivaxL (thm "M_triv_axioms.pair_in_M_iff"));
bind_thm ("pair_components_in_M", trivaxL (thm "M_triv_axioms.pair_components_in_M"));
bind_thm ("cartprod_abs", trivaxL (thm "M_triv_axioms.cartprod_abs"));
bind_thm ("union_abs", trivaxL (thm "M_triv_axioms.union_abs"));
bind_thm ("inter_abs", trivaxL (thm "M_triv_axioms.inter_abs"));
bind_thm ("setdiff_abs", trivaxL (thm "M_triv_axioms.setdiff_abs"));
bind_thm ("Union_abs", trivaxL (thm "M_triv_axioms.Union_abs"));
bind_thm ("Union_closed", trivaxL (thm "M_triv_axioms.Union_closed"));
bind_thm ("Un_closed", trivaxL (thm "M_triv_axioms.Un_closed"));
bind_thm ("cons_closed", trivaxL (thm "M_triv_axioms.cons_closed"));
bind_thm ("successor_abs", trivaxL (thm "M_triv_axioms.successor_abs"));
bind_thm ("succ_in_M_iff", trivaxL (thm "M_triv_axioms.succ_in_M_iff"));
bind_thm ("separation_closed", trivaxL (thm "M_triv_axioms.separation_closed"));
bind_thm ("strong_replacementI", trivaxL (thm "M_triv_axioms.strong_replacementI"));
bind_thm ("strong_replacement_closed", trivaxL (thm "M_triv_axioms.strong_replacement_closed"));
bind_thm ("RepFun_closed", trivaxL (thm "M_triv_axioms.RepFun_closed"));
bind_thm ("lam_closed", trivaxL (thm "M_triv_axioms.lam_closed"));
bind_thm ("image_abs", trivaxL (thm "M_triv_axioms.image_abs"));
bind_thm ("powerset_Pow", trivaxL (thm "M_triv_axioms.powerset_Pow"));
bind_thm ("powerset_imp_subset_Pow", trivaxL (thm "M_triv_axioms.powerset_imp_subset_Pow"));
bind_thm ("nat_into_M", trivaxL (thm "M_triv_axioms.nat_into_M"));
bind_thm ("nat_case_closed", trivaxL (thm "M_triv_axioms.nat_case_closed"));
bind_thm ("Inl_in_M_iff", trivaxL (thm "M_triv_axioms.Inl_in_M_iff"));
bind_thm ("Inr_in_M_iff", trivaxL (thm "M_triv_axioms.Inr_in_M_iff"));
bind_thm ("lt_closed", trivaxL (thm "M_triv_axioms.lt_closed"));
bind_thm ("transitive_set_abs", trivaxL (thm "M_triv_axioms.transitive_set_abs"));
bind_thm ("ordinal_abs", trivaxL (thm "M_triv_axioms.ordinal_abs"));
bind_thm ("limit_ordinal_abs", trivaxL (thm "M_triv_axioms.limit_ordinal_abs"));
bind_thm ("successor_ordinal_abs", trivaxL (thm "M_triv_axioms.successor_ordinal_abs"));
bind_thm ("finite_ordinal_abs", trivaxL (thm "M_triv_axioms.finite_ordinal_abs"));
bind_thm ("omega_abs", trivaxL (thm "M_triv_axioms.omega_abs"));
bind_thm ("number1_abs", trivaxL (thm "M_triv_axioms.number1_abs"));
bind_thm ("number1_abs", trivaxL (thm "M_triv_axioms.number1_abs"));
bind_thm ("number3_abs", trivaxL (thm "M_triv_axioms.number3_abs"));
*}
declare ball_abs [simp]
declare rall_abs [simp]
declare bex_abs [simp]
declare rex_abs [simp]
declare empty_abs [simp]
declare subset_abs [simp]
declare upair_abs [simp]
declare upair_in_M_iff [iff]
declare singleton_in_M_iff [iff]
declare pair_abs [simp]
declare pair_in_M_iff [iff]
declare cartprod_abs [simp]
declare union_abs [simp]
declare inter_abs [simp]
declare setdiff_abs [simp]
declare Union_abs [simp]
declare Union_closed [intro,simp]
declare Un_closed [intro,simp]
declare cons_closed [intro,simp]
declare successor_abs [simp]
declare succ_in_M_iff [iff]
declare separation_closed [intro,simp]
declare strong_replacementI [rule_format]
declare strong_replacement_closed [intro,simp]
declare RepFun_closed [intro,simp]
declare lam_closed [intro,simp]
declare image_abs [simp]
declare nat_into_M [intro]
declare Inl_in_M_iff [iff]
declare Inr_in_M_iff [iff]
declare transitive_set_abs [simp]
declare ordinal_abs [simp]
declare limit_ordinal_abs [simp]
declare successor_ordinal_abs [simp]
declare finite_ordinal_abs [simp]
declare omega_abs [simp]
declare number1_abs [simp]
declare number1_abs [simp]
declare number3_abs [simp]
subsection{*Instantiation of the locale @{text reflection}*}
text{*instances of locale constants*}
constdefs
L_Reflects :: "[i=>o,i=>o,[i,i]=>o] => o"
"L_Reflects(Cl,P,Q) == Closed_Unbounded(Cl) &
(\<forall>a. Cl(a) --> (\<forall>x \<in> Lset(a). P(x) <-> Q(a,x)))"
L_F0 :: "[i=>o,i] => i"
"L_F0(P,y) == \<mu>b. (\<exists>z. L(z) \<and> P(<y,z>)) --> (\<exists>z\<in>Lset(b). P(<y,z>))"
L_FF :: "[i=>o,i] => i"
"L_FF(P) == \<lambda>a. \<Union>y\<in>Lset(a). L_F0(P,y)"
L_ClEx :: "[i=>o,i] => o"
"L_ClEx(P) == \<lambda>a. Limit(a) \<and> normalize(L_FF(P),a) = a"
theorem Triv_reflection [intro]:
"L_Reflects(Ord, P, \<lambda>a x. P(x))"
by (simp add: L_Reflects_def)
theorem Not_reflection [intro]:
"L_Reflects(Cl,P,Q) ==> L_Reflects(Cl, \<lambda>x. ~P(x), \<lambda>a x. ~Q(a,x))"
by (simp add: L_Reflects_def)
theorem And_reflection [intro]:
"[| L_Reflects(Cl,P,Q); L_Reflects(C',P',Q') |]
==> L_Reflects(\<lambda>a. Cl(a) \<and> C'(a), \<lambda>x. P(x) \<and> P'(x),
\<lambda>a x. Q(a,x) \<and> Q'(a,x))"
by (simp add: L_Reflects_def Closed_Unbounded_Int, blast)
theorem Or_reflection [intro]:
"[| L_Reflects(Cl,P,Q); L_Reflects(C',P',Q') |]
==> L_Reflects(\<lambda>a. Cl(a) \<and> C'(a), \<lambda>x. P(x) \<or> P'(x),
\<lambda>a x. Q(a,x) \<or> Q'(a,x))"
by (simp add: L_Reflects_def Closed_Unbounded_Int, blast)
theorem Imp_reflection [intro]:
"[| L_Reflects(Cl,P,Q); L_Reflects(C',P',Q') |]
==> L_Reflects(\<lambda>a. Cl(a) \<and> C'(a),
\<lambda>x. P(x) --> P'(x),
\<lambda>a x. Q(a,x) --> Q'(a,x))"
by (simp add: L_Reflects_def Closed_Unbounded_Int, blast)
theorem Iff_reflection [intro]:
"[| L_Reflects(Cl,P,Q); L_Reflects(C',P',Q') |]
==> L_Reflects(\<lambda>a. Cl(a) \<and> C'(a),
\<lambda>x. P(x) <-> P'(x),
\<lambda>a x. Q(a,x) <-> Q'(a,x))"
by (simp add: L_Reflects_def Closed_Unbounded_Int, blast)
theorem Ex_reflection [intro]:
"L_Reflects(Cl, \<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x)))
==> L_Reflects(\<lambda>a. Cl(a) \<and> L_ClEx(\<lambda>x. P(fst(x),snd(x)), a),
\<lambda>x. \<exists>z. L(z) \<and> P(x,z),
\<lambda>a x. \<exists>z\<in>Lset(a). Q(a,x,z))"
apply (unfold L_Reflects_def L_ClEx_def L_FF_def L_F0_def L_def)
apply (rule reflection.Ex_reflection [OF Lset_mono_le Lset_cont Pair_in_Lset],
assumption+)
done
theorem All_reflection [intro]:
"L_Reflects(Cl, \<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x)))
==> L_Reflects(\<lambda>a. Cl(a) \<and> L_ClEx(\<lambda>x. ~P(fst(x),snd(x)), a),
\<lambda>x. \<forall>z. L(z) --> P(x,z),
\<lambda>a x. \<forall>z\<in>Lset(a). Q(a,x,z))"
apply (unfold L_Reflects_def L_ClEx_def L_FF_def L_F0_def L_def)
apply (rule reflection.All_reflection [OF Lset_mono_le Lset_cont Pair_in_Lset],
assumption+)
done
theorem Rex_reflection [intro]:
"L_Reflects(Cl, \<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x)))
==> L_Reflects(\<lambda>a. Cl(a) \<and> L_ClEx(\<lambda>x. P(fst(x),snd(x)), a),
\<lambda>x. \<exists>z[L]. P(x,z),
\<lambda>a x. \<exists>z\<in>Lset(a). Q(a,x,z))"
by (unfold rex_def, blast)
theorem Rall_reflection [intro]:
"L_Reflects(Cl, \<lambda>x. P(fst(x),snd(x)), \<lambda>a x. Q(a,fst(x),snd(x)))
==> L_Reflects(\<lambda>a. Cl(a) \<and> L_ClEx(\<lambda>x. ~P(fst(x),snd(x)), a),
\<lambda>x. \<forall>z[L]. P(x,z),
\<lambda>a x. \<forall>z\<in>Lset(a). Q(a,x,z))"
by (unfold rall_def, blast)
lemma ReflectsD:
"[|L_Reflects(Cl,P,Q); Ord(i)|]
==> \<exists>j. i<j & (\<forall>x \<in> Lset(j). P(x) <-> Q(j,x))"
apply (simp add: L_Reflects_def Closed_Unbounded_def, clarify)
apply (blast dest!: UnboundedD)
done
lemma ReflectsE:
"[| L_Reflects(Cl,P,Q); Ord(i);
!!j. [|i<j; \<forall>x \<in> Lset(j). P(x) <-> Q(j,x)|] ==> R |]
==> R"
by (blast dest!: ReflectsD)
lemma Collect_mem_eq: "{x\<in>A. x\<in>B} = A \<inter> B";
by blast
subsection{*Internalized formulas for some relativized ones*}
subsubsection{*Unordered pairs*}
constdefs upair_fm :: "[i,i,i]=>i"
"upair_fm(x,y,z) ==
And(Member(x,z),
And(Member(y,z),
Forall(Implies(Member(0,succ(z)),
Or(Equal(0,succ(x)), Equal(0,succ(y)))))))"
lemma upair_type [TC]:
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> upair_fm(x,y,z) \<in> formula"
by (simp add: upair_fm_def)
lemma arity_upair_fm [simp]:
"[| x \<in> nat; y \<in> nat; z \<in> nat |]
==> arity(upair_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)"
by (simp add: upair_fm_def succ_Un_distrib [symmetric] Un_ac)
lemma sats_upair_fm [simp]:
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|]
==> sats(A, upair_fm(x,y,z), env) <->
upair(**A, nth(x,env), nth(y,env), nth(z,env))"
by (simp add: upair_fm_def upair_def)
lemma upair_iff_sats:
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z;
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|]
==> upair(**A, x, y, z) <-> sats(A, upair_fm(i,j,k), env)"
by (simp add: sats_upair_fm)
text{*Useful? At least it refers to "real" unordered pairs*}
lemma sats_upair_fm2 [simp]:
"[| x \<in> nat; y \<in> nat; z < length(env); env \<in> list(A); Transset(A)|]
==> sats(A, upair_fm(x,y,z), env) <->
nth(z,env) = {nth(x,env), nth(y,env)}"
apply (frule lt_length_in_nat, assumption)
apply (simp add: upair_fm_def Transset_def, auto)
apply (blast intro: nth_type)
done
subsubsection{*Ordered pairs*}
constdefs pair_fm :: "[i,i,i]=>i"
"pair_fm(x,y,z) ==
Exists(And(upair_fm(succ(x),succ(x),0),
Exists(And(upair_fm(succ(succ(x)),succ(succ(y)),0),
upair_fm(1,0,succ(succ(z)))))))"
lemma pair_type [TC]:
"[| x \<in> nat; y \<in> nat; z \<in> nat |] ==> pair_fm(x,y,z) \<in> formula"
by (simp add: pair_fm_def)
lemma arity_pair_fm [simp]:
"[| x \<in> nat; y \<in> nat; z \<in> nat |]
==> arity(pair_fm(x,y,z)) = succ(x) \<union> succ(y) \<union> succ(z)"
by (simp add: pair_fm_def succ_Un_distrib [symmetric] Un_ac)
lemma sats_pair_fm [simp]:
"[| x \<in> nat; y \<in> nat; z \<in> nat; env \<in> list(A)|]
==> sats(A, pair_fm(x,y,z), env) <->
pair(**A, nth(x,env), nth(y,env), nth(z,env))"
by (simp add: pair_fm_def pair_def)
lemma pair_iff_sats:
"[| nth(i,env) = x; nth(j,env) = y; nth(k,env) = z;
i \<in> nat; j \<in> nat; k \<in> nat; env \<in> list(A)|]
==> pair(**A, x, y, z) <-> sats(A, pair_fm(i,j,k), env)"
by (simp add: sats_pair_fm)
subsection{*Proving instances of Separation using Reflection!*}
text{*Helps us solve for de Bruijn indices!*}
lemma nth_ConsI: "[|nth(n,l) = x; n \<in> nat|] ==> nth(succ(n), Cons(a,l)) = x"
by simp
lemma Collect_conj_in_DPow:
"[| {x\<in>A. P(x)} \<in> DPow(A); {x\<in>A. Q(x)} \<in> DPow(A) |]
==> {x\<in>A. P(x) & Q(x)} \<in> DPow(A)"
by (simp add: Int_in_DPow Collect_Int_Collect_eq [symmetric])
lemma Collect_conj_in_DPow_Lset:
"[|z \<in> Lset(j); {x \<in> Lset(j). P(x)} \<in> DPow(Lset(j))|]
==> {x \<in> Lset(j). x \<in> z & P(x)} \<in> DPow(Lset(j))"
apply (frule mem_Lset_imp_subset_Lset)
apply (simp add: Collect_conj_in_DPow Collect_mem_eq
subset_Int_iff2 elem_subset_in_DPow)
done
lemma separation_CollectI:
"(\<And>z. L(z) ==> L({x \<in> z . P(x)})) ==> separation(L, \<lambda>x. P(x))"
apply (unfold separation_def, clarify)
apply (rule_tac x="{x\<in>z. P(x)}" in rexI)
apply simp_all
done
text{*Reduces the original comprehension to the reflected one*}
lemma reflection_imp_L_separation:
"[| \<forall>x\<in>Lset(j). P(x) <-> Q(x);
{x \<in> Lset(j) . Q(x)} \<in> DPow(Lset(j));
Ord(j); z \<in> Lset(j)|] ==> L({x \<in> z . P(x)})"
apply (rule_tac i = "succ(j)" in L_I)
prefer 2 apply simp
apply (subgoal_tac "{x \<in> z. P(x)} = {x \<in> Lset(j). x \<in> z & (Q(x))}")
prefer 2
apply (blast dest: mem_Lset_imp_subset_Lset)
apply (simp add: Lset_succ Collect_conj_in_DPow_Lset)
done
subsubsection{*Separation for Intersection*}
lemma Inter_Reflects:
"L_Reflects(?Cl, \<lambda>x. \<forall>y[L]. y\<in>A --> x \<in> y,
\<lambda>i x. \<forall>y\<in>Lset(i). y\<in>A --> x \<in> y)"
by fast
lemma Inter_separation:
"L(A) ==> separation(L, \<lambda>x. \<forall>y[L]. y\<in>A --> x\<in>y)"
apply (rule separation_CollectI)
apply (rule_tac A="{A,z}" in subset_LsetE, blast )
apply (rule ReflectsE [OF Inter_Reflects], assumption)
apply (drule subset_Lset_ltD, assumption)
apply (erule reflection_imp_L_separation)
apply (simp_all add: lt_Ord2, clarify)
apply (rule DPowI2)
apply (rule ball_iff_sats)
apply (rule imp_iff_sats)
apply (rule_tac [2] i=1 and j=0 and env="[y,x,A]" in mem_iff_sats)
apply (rule_tac i=0 and j=2 in mem_iff_sats)
apply (simp_all add: succ_Un_distrib [symmetric])
done
subsubsection{*Separation for Cartesian Product*}
text{*The @{text simplified} attribute tidies up the reflecting class.*}
theorem upair_reflection [simplified,intro]:
"L_Reflects(?Cl, \<lambda>x. upair(L,f(x),g(x),h(x)),
\<lambda>i x. upair(**Lset(i),f(x),g(x),h(x)))"
by (simp add: upair_def, fast)
theorem pair_reflection [simplified,intro]:
"L_Reflects(?Cl, \<lambda>x. pair(L,f(x),g(x),h(x)),
\<lambda>i x. pair(**Lset(i),f(x),g(x),h(x)))"
by (simp only: pair_def rex_setclass_is_bex, fast)
lemma cartprod_Reflects [simplified]:
"L_Reflects(?Cl, \<lambda>z. \<exists>x[L]. x\<in>A & (\<exists>y[L]. y\<in>B & pair(L,x,y,z)),
\<lambda>i z. \<exists>x\<in>Lset(i). x\<in>A & (\<exists>y\<in>Lset(i). y\<in>B &
pair(**Lset(i),x,y,z)))"
by fast
lemma cartprod_separation:
"[| L(A); L(B) |]
==> separation(L, \<lambda>z. \<exists>x[L]. x\<in>A & (\<exists>y[L]. y\<in>B & pair(L,x,y,z)))"
apply (rule separation_CollectI)
apply (rule_tac A="{A,B,z}" in subset_LsetE, blast )
apply (rule ReflectsE [OF cartprod_Reflects], assumption)
apply (drule subset_Lset_ltD, assumption)
apply (erule reflection_imp_L_separation)
apply (simp_all add: lt_Ord2, clarify)
apply (rule DPowI2)
apply (rename_tac u)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule_tac i=0 and j=2 and env="[x,u,A,B]" in mem_iff_sats, simp_all)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule mem_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI, simp_all)
apply (rule_tac i=1 and j=0 and k=2 in pair_iff_sats)
apply (simp_all add: succ_Un_distrib [symmetric])
done
subsubsection{*Separation for Image*}
text{*No @{text simplified} here: it simplifies the occurrence of
the predicate @{term pair}!*}
lemma image_Reflects:
"L_Reflects(?Cl, \<lambda>y. \<exists>p[L]. p\<in>r & (\<exists>x[L]. x\<in>A & pair(L,x,y,p)),
\<lambda>i y. \<exists>p\<in>Lset(i). p\<in>r & (\<exists>x\<in>Lset(i). x\<in>A & pair(**Lset(i),x,y,p)))"
by fast
lemma image_separation:
"[| L(A); L(r) |]
==> separation(L, \<lambda>y. \<exists>p[L]. p\<in>r & (\<exists>x[L]. x\<in>A & pair(L,x,y,p)))"
apply (rule separation_CollectI)
apply (rule_tac A="{A,r,z}" in subset_LsetE, blast )
apply (rule ReflectsE [OF image_Reflects], assumption)
apply (drule subset_Lset_ltD, assumption)
apply (erule reflection_imp_L_separation)
apply (simp_all add: lt_Ord2, clarify)
apply (rule DPowI2)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule_tac env="[p,y,A,r]" in mem_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI, simp_all)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule mem_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI, simp_all)
apply (rule pair_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI)
apply (simp_all add: succ_Un_distrib [symmetric])
done
subsubsection{*Separation for Converse*}
lemma converse_Reflects:
"L_Reflects(?Cl,
\<lambda>z. \<exists>p[L]. p\<in>r & (\<exists>x[L]. \<exists>y[L]. pair(L,x,y,p) & pair(L,y,x,z)),
\<lambda>i z. \<exists>p\<in>Lset(i). p\<in>r & (\<exists>x\<in>Lset(i). \<exists>y\<in>Lset(i).
pair(**Lset(i),x,y,p) & pair(**Lset(i),y,x,z)))"
by fast
lemma converse_separation:
"L(r) ==> separation(L,
\<lambda>z. \<exists>p[L]. p\<in>r & (\<exists>x[L]. \<exists>y[L]. pair(L,x,y,p) & pair(L,y,x,z)))"
apply (rule separation_CollectI)
apply (rule_tac A="{r,z}" in subset_LsetE, blast )
apply (rule ReflectsE [OF converse_Reflects], assumption)
apply (drule subset_Lset_ltD, assumption)
apply (erule reflection_imp_L_separation)
apply (simp_all add: lt_Ord2, clarify)
apply (rule DPowI2)
apply (rename_tac u)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule_tac i=0 and j="2" and env="[p,u,r]" in mem_iff_sats, simp_all)
apply (rule bex_iff_sats)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule_tac i=1 and j=0 and k=2 in pair_iff_sats, simp_all)
apply (rule pair_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI)
apply (simp_all add: succ_Un_distrib [symmetric])
done
subsubsection{*Separation for Restriction*}
lemma restrict_Reflects:
"L_Reflects(?Cl, \<lambda>z. \<exists>x[L]. x\<in>A & (\<exists>y[L]. pair(L,x,y,z)),
\<lambda>i z. \<exists>x\<in>Lset(i). x\<in>A & (\<exists>y\<in>Lset(i). pair(**Lset(i),x,y,z)))"
by fast
lemma restrict_separation:
"L(A) ==> separation(L, \<lambda>z. \<exists>x[L]. x\<in>A & (\<exists>y[L]. pair(L,x,y,z)))"
apply (rule separation_CollectI)
apply (rule_tac A="{A,z}" in subset_LsetE, blast )
apply (rule ReflectsE [OF restrict_Reflects], assumption)
apply (drule subset_Lset_ltD, assumption)
apply (erule reflection_imp_L_separation)
apply (simp_all add: lt_Ord2, clarify)
apply (rule DPowI2)
apply (rename_tac u)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule_tac i=0 and j="2" and env="[x,u,A]" in mem_iff_sats, simp_all)
apply (rule bex_iff_sats)
apply (rule_tac i=1 and j=0 and k=2 in pair_iff_sats)
apply (simp_all add: succ_Un_distrib [symmetric])
done
subsubsection{*Separation for Composition*}
lemma comp_Reflects:
"L_Reflects(?Cl, \<lambda>xz. \<exists>x[L]. \<exists>y[L]. \<exists>z[L]. \<exists>xy[L]. \<exists>yz[L].
pair(L,x,z,xz) & pair(L,x,y,xy) & pair(L,y,z,yz) &
xy\<in>s & yz\<in>r,
\<lambda>i xz. \<exists>x\<in>Lset(i). \<exists>y\<in>Lset(i). \<exists>z\<in>Lset(i). \<exists>xy\<in>Lset(i). \<exists>yz\<in>Lset(i).
pair(**Lset(i),x,z,xz) & pair(**Lset(i),x,y,xy) &
pair(**Lset(i),y,z,yz) & xy\<in>s & yz\<in>r)"
by fast
lemma comp_separation:
"[| L(r); L(s) |]
==> separation(L, \<lambda>xz. \<exists>x[L]. \<exists>y[L]. \<exists>z[L]. \<exists>xy[L]. \<exists>yz[L].
pair(L,x,z,xz) & pair(L,x,y,xy) & pair(L,y,z,yz) &
xy\<in>s & yz\<in>r)"
apply (rule separation_CollectI)
apply (rule_tac A="{r,s,z}" in subset_LsetE, blast )
apply (rule ReflectsE [OF comp_Reflects], assumption)
apply (drule subset_Lset_ltD, assumption)
apply (erule reflection_imp_L_separation)
apply (simp_all add: lt_Ord2, clarify)
apply (rule DPowI2)
apply (rename_tac u)
apply (rule bex_iff_sats)+
apply (rename_tac x y z)
apply (rule conj_iff_sats)
apply (rule_tac env="[z,y,x,u,r,s]" in pair_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI, simp_all)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule pair_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI, simp_all)
apply (rule bex_iff_sats)
apply (rule conj_iff_sats)
apply (rule pair_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI, simp_all)
apply (rule conj_iff_sats)
apply (rule mem_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI, simp)
apply (rule mem_iff_sats)
apply (blast intro: nth_0 nth_ConsI)
apply (blast intro: nth_0 nth_ConsI)
apply (simp_all add: succ_Un_distrib [symmetric])
done
end
(*
and pred_separation:
"[| L(r); L(x) |] ==> separation(L, \<lambda>y. \<exists>p\<in>r. L(p) & pair(L,y,x,p))"
and Memrel_separation:
"separation(L, \<lambda>z. \<exists>x y. L(x) & L(y) & pair(L,x,y,z) \<and> x \<in> y)"
and obase_separation:
--{*part of the order type formalization*}
"[| L(A); L(r) |]
==> separation(L, \<lambda>a. \<exists>x g mx par. L(x) & L(g) & L(mx) & L(par) &
ordinal(L,x) & membership(L,x,mx) & pred_set(L,A,a,r,par) &
order_isomorphism(L,par,r,x,mx,g))"
and well_ord_iso_separation:
"[| L(A); L(f); L(r) |]
==> separation (L, \<lambda>x. x\<in>A --> (\<exists>y. L(y) \<and> (\<exists>p. L(p) \<and>
fun_apply(L,f,x,y) \<and> pair(L,y,x,p) \<and> p \<in> r)))"
and obase_equals_separation:
"[| L(A); L(r) |]
==> separation
(L, \<lambda>x. x\<in>A --> ~(\<exists>y. L(y) & (\<exists>g. L(g) &
ordinal(L,y) & (\<exists>my pxr. L(my) & L(pxr) &
membership(L,y,my) & pred_set(L,A,x,r,pxr) &
order_isomorphism(L,pxr,r,y,my,g)))))"
and is_recfun_separation:
--{*for well-founded recursion. NEEDS RELATIVIZATION*}
"[| L(A); L(f); L(g); L(a); L(b) |]
==> separation(L, \<lambda>x. x \<in> A --> \<langle>x,a\<rangle> \<in> r \<and> \<langle>x,b\<rangle> \<in> r \<and> f`x \<noteq> g`x)"
and omap_replacement:
"[| L(A); L(r) |]
==> strong_replacement(L,
\<lambda>a z. \<exists>x g mx par. L(x) & L(g) & L(mx) & L(par) &
ordinal(L,x) & pair(L,a,x,z) & membership(L,x,mx) &
pred_set(L,A,a,r,par) & order_isomorphism(L,par,r,x,mx,g))"
*)