src/ZF/Constructible/Rank_Separation.thy
 author wenzelm Wed, 27 Mar 2013 16:38:25 +0100 changeset 51553 63327f679cff parent 46823 57bf0cecb366 child 58871 c399ae4b836f permissions -rw-r--r--
more ambitious Goal.skip_proofs: covers Goal.prove forms as well, and do not insist in quick_and_dirty (for the sake of Isabelle/jEdit);
```
(*  Title:      ZF/Constructible/Rank_Separation.thy
Author:     Lawrence C Paulson, Cambridge University Computer Laboratory
*)

Well-Founded Relations*}

theory Rank_Separation imports Rank Rec_Separation begin

text{*This theory proves all instances needed for locales
@{text "M_ordertype"} and  @{text "M_wfrank"}.  But the material is not
needed for proving the relative consistency of AC.*}

subsection{*The Locale @{text "M_ordertype"}*}

subsubsection{*Separation for Order-Isomorphisms*}

lemma well_ord_iso_Reflects:
"REFLECTS[\<lambda>x. x\<in>A \<longrightarrow>
(\<exists>y[L]. \<exists>p[L]. fun_apply(L,f,x,y) & pair(L,y,x,p) & p \<in> r),
\<lambda>i x. x\<in>A \<longrightarrow> (\<exists>y \<in> Lset(i). \<exists>p \<in> Lset(i).
fun_apply(##Lset(i),f,x,y) & pair(##Lset(i),y,x,p) & p \<in> r)]"
by (intro FOL_reflections function_reflections)

lemma well_ord_iso_separation:
"[| L(A); L(f); L(r) |]
==> separation (L, \<lambda>x. x\<in>A \<longrightarrow> (\<exists>y[L]. (\<exists>p[L].
fun_apply(L,f,x,y) & pair(L,y,x,p) & p \<in> r)))"
apply (rule gen_separation_multi [OF well_ord_iso_Reflects, of "{A,f,r}"],
auto)
apply (rule_tac env="[A,f,r]" in DPow_LsetI)
apply (rule sep_rules | simp)+
done

subsubsection{*Separation for @{term "obase"}*}

lemma obase_reflects:
"REFLECTS[\<lambda>a. \<exists>x[L]. \<exists>g[L]. \<exists>mx[L]. \<exists>par[L].
ordinal(L,x) & membership(L,x,mx) & pred_set(L,A,a,r,par) &
order_isomorphism(L,par,r,x,mx,g),
\<lambda>i a. \<exists>x \<in> Lset(i). \<exists>g \<in> Lset(i). \<exists>mx \<in> Lset(i). \<exists>par \<in> Lset(i).
ordinal(##Lset(i),x) & membership(##Lset(i),x,mx) & pred_set(##Lset(i),A,a,r,par) &
order_isomorphism(##Lset(i),par,r,x,mx,g)]"
by (intro FOL_reflections function_reflections fun_plus_reflections)

lemma obase_separation:
--{*part of the order type formalization*}
"[| L(A); L(r) |]
==> separation(L, \<lambda>a. \<exists>x[L]. \<exists>g[L]. \<exists>mx[L]. \<exists>par[L].
ordinal(L,x) & membership(L,x,mx) & pred_set(L,A,a,r,par) &
order_isomorphism(L,par,r,x,mx,g))"
apply (rule gen_separation_multi [OF obase_reflects, of "{A,r}"], auto)
apply (rule_tac env="[A,r]" in DPow_LsetI)
apply (rule ordinal_iff_sats sep_rules | simp)+
done

subsubsection{*Separation for a Theorem about @{term "obase"}*}

lemma obase_equals_reflects:
"REFLECTS[\<lambda>x. x\<in>A \<longrightarrow> ~(\<exists>y[L]. \<exists>g[L].
ordinal(L,y) & (\<exists>my[L]. \<exists>pxr[L].
membership(L,y,my) & pred_set(L,A,x,r,pxr) &
order_isomorphism(L,pxr,r,y,my,g))),
\<lambda>i x. x\<in>A \<longrightarrow> ~(\<exists>y \<in> Lset(i). \<exists>g \<in> Lset(i).
ordinal(##Lset(i),y) & (\<exists>my \<in> Lset(i). \<exists>pxr \<in> Lset(i).
membership(##Lset(i),y,my) & pred_set(##Lset(i),A,x,r,pxr) &
order_isomorphism(##Lset(i),pxr,r,y,my,g)))]"
by (intro FOL_reflections function_reflections fun_plus_reflections)

lemma obase_equals_separation:
"[| L(A); L(r) |]
==> separation (L, \<lambda>x. x\<in>A \<longrightarrow> ~(\<exists>y[L]. \<exists>g[L].
ordinal(L,y) & (\<exists>my[L]. \<exists>pxr[L].
membership(L,y,my) & pred_set(L,A,x,r,pxr) &
order_isomorphism(L,pxr,r,y,my,g))))"
apply (rule gen_separation_multi [OF obase_equals_reflects, of "{A,r}"], auto)
apply (rule_tac env="[A,r]" in DPow_LsetI)
apply (rule sep_rules | simp)+
done

subsubsection{*Replacement for @{term "omap"}*}

lemma omap_reflects:
"REFLECTS[\<lambda>z. \<exists>a[L]. a\<in>B & (\<exists>x[L]. \<exists>g[L]. \<exists>mx[L]. \<exists>par[L].
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)),
\<lambda>i z. \<exists>a \<in> Lset(i). a\<in>B & (\<exists>x \<in> Lset(i). \<exists>g \<in> Lset(i). \<exists>mx \<in> Lset(i).
\<exists>par \<in> Lset(i).
ordinal(##Lset(i),x) & pair(##Lset(i),a,x,z) &
membership(##Lset(i),x,mx) & pred_set(##Lset(i),A,a,r,par) &
order_isomorphism(##Lset(i),par,r,x,mx,g))]"
by (intro FOL_reflections function_reflections fun_plus_reflections)

lemma omap_replacement:
"[| L(A); L(r) |]
==> strong_replacement(L,
\<lambda>a z. \<exists>x[L]. \<exists>g[L]. \<exists>mx[L]. \<exists>par[L].
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))"
apply (rule strong_replacementI)
apply (rule_tac u="{A,r,B}" in gen_separation_multi [OF omap_reflects], auto)
apply (rule_tac env="[A,B,r]" in DPow_LsetI)
apply (rule sep_rules | simp)+
done

subsection{*Instantiating the locale @{text M_ordertype}*}
text{*Separation (and Strong Replacement) for basic set-theoretic constructions
such as intersection, Cartesian Product and image.*}

lemma M_ordertype_axioms_L: "M_ordertype_axioms(L)"
apply (rule M_ordertype_axioms.intro)
apply (assumption | rule well_ord_iso_separation
obase_separation obase_equals_separation
omap_replacement)+
done

theorem M_ordertype_L: "PROP M_ordertype(L)"
apply (rule M_ordertype.intro)
apply (rule M_basic_L)
apply (rule M_ordertype_axioms_L)
done

subsection{*The Locale @{text "M_wfrank"}*}

subsubsection{*Separation for @{term "wfrank"}*}

lemma wfrank_Reflects:
"REFLECTS[\<lambda>x. \<forall>rplus[L]. tran_closure(L,r,rplus) \<longrightarrow>
~ (\<exists>f[L]. M_is_recfun(L, %x f y. is_range(L,f,y), rplus, x, f)),
\<lambda>i x. \<forall>rplus \<in> Lset(i). tran_closure(##Lset(i),r,rplus) \<longrightarrow>
~ (\<exists>f \<in> Lset(i).
M_is_recfun(##Lset(i), %x f y. is_range(##Lset(i),f,y),
rplus, x, f))]"
by (intro FOL_reflections function_reflections is_recfun_reflection tran_closure_reflection)

lemma wfrank_separation:
"L(r) ==>
separation (L, \<lambda>x. \<forall>rplus[L]. tran_closure(L,r,rplus) \<longrightarrow>
~ (\<exists>f[L]. M_is_recfun(L, %x f y. is_range(L,f,y), rplus, x, f)))"
apply (rule gen_separation [OF wfrank_Reflects], simp)
apply (rule_tac env="[r]" in DPow_LsetI)
apply (rule sep_rules tran_closure_iff_sats is_recfun_iff_sats | simp)+
done

subsubsection{*Replacement for @{term "wfrank"}*}

lemma wfrank_replacement_Reflects:
"REFLECTS[\<lambda>z. \<exists>x[L]. x \<in> A &
(\<forall>rplus[L]. tran_closure(L,r,rplus) \<longrightarrow>
(\<exists>y[L]. \<exists>f[L]. pair(L,x,y,z)  &
M_is_recfun(L, %x f y. is_range(L,f,y), rplus, x, f) &
is_range(L,f,y))),
\<lambda>i z. \<exists>x \<in> Lset(i). x \<in> A &
(\<forall>rplus \<in> Lset(i). tran_closure(##Lset(i),r,rplus) \<longrightarrow>
(\<exists>y \<in> Lset(i). \<exists>f \<in> Lset(i). pair(##Lset(i),x,y,z)  &
M_is_recfun(##Lset(i), %x f y. is_range(##Lset(i),f,y), rplus, x, f) &
is_range(##Lset(i),f,y)))]"
by (intro FOL_reflections function_reflections fun_plus_reflections
is_recfun_reflection tran_closure_reflection)

lemma wfrank_strong_replacement:
"L(r) ==>
strong_replacement(L, \<lambda>x z.
\<forall>rplus[L]. tran_closure(L,r,rplus) \<longrightarrow>
(\<exists>y[L]. \<exists>f[L]. pair(L,x,y,z)  &
M_is_recfun(L, %x f y. is_range(L,f,y), rplus, x, f) &
is_range(L,f,y)))"
apply (rule strong_replacementI)
apply (rule_tac u="{r,B}"
in gen_separation_multi [OF wfrank_replacement_Reflects],
auto)
apply (rule_tac env="[r,B]" in DPow_LsetI)
apply (rule sep_rules tran_closure_iff_sats is_recfun_iff_sats | simp)+
done

subsubsection{*Separation for Proving @{text Ord_wfrank_range}*}

lemma Ord_wfrank_Reflects:
"REFLECTS[\<lambda>x. \<forall>rplus[L]. tran_closure(L,r,rplus) \<longrightarrow>
~ (\<forall>f[L]. \<forall>rangef[L].
is_range(L,f,rangef) \<longrightarrow>
M_is_recfun(L, \<lambda>x f y. is_range(L,f,y), rplus, x, f) \<longrightarrow>
ordinal(L,rangef)),
\<lambda>i x. \<forall>rplus \<in> Lset(i). tran_closure(##Lset(i),r,rplus) \<longrightarrow>
~ (\<forall>f \<in> Lset(i). \<forall>rangef \<in> Lset(i).
is_range(##Lset(i),f,rangef) \<longrightarrow>
M_is_recfun(##Lset(i), \<lambda>x f y. is_range(##Lset(i),f,y),
rplus, x, f) \<longrightarrow>
ordinal(##Lset(i),rangef))]"
by (intro FOL_reflections function_reflections is_recfun_reflection
tran_closure_reflection ordinal_reflection)

lemma  Ord_wfrank_separation:
"L(r) ==>
separation (L, \<lambda>x.
\<forall>rplus[L]. tran_closure(L,r,rplus) \<longrightarrow>
~ (\<forall>f[L]. \<forall>rangef[L].
is_range(L,f,rangef) \<longrightarrow>
M_is_recfun(L, \<lambda>x f y. is_range(L,f,y), rplus, x, f) \<longrightarrow>
ordinal(L,rangef)))"
apply (rule gen_separation [OF Ord_wfrank_Reflects], simp)
apply (rule_tac env="[r]" in DPow_LsetI)
apply (rule sep_rules tran_closure_iff_sats is_recfun_iff_sats | simp)+
done

subsubsection{*Instantiating the locale @{text M_wfrank}*}

lemma M_wfrank_axioms_L: "M_wfrank_axioms(L)"
apply (rule M_wfrank_axioms.intro)
apply (assumption | rule
wfrank_separation wfrank_strong_replacement Ord_wfrank_separation)+
done

theorem M_wfrank_L: "PROP M_wfrank(L)"
apply (rule M_wfrank.intro)
apply (rule M_trancl_L)
apply (rule M_wfrank_axioms_L)
done

lemmas exists_wfrank = M_wfrank.exists_wfrank [OF M_wfrank_L]
and M_wellfoundedrank = M_wfrank.M_wellfoundedrank [OF M_wfrank_L]
and Ord_wfrank_range = M_wfrank.Ord_wfrank_range [OF M_wfrank_L]
and Ord_range_wellfoundedrank = M_wfrank.Ord_range_wellfoundedrank [OF M_wfrank_L]
and function_wellfoundedrank = M_wfrank.function_wellfoundedrank [OF M_wfrank_L]
and domain_wellfoundedrank = M_wfrank.domain_wellfoundedrank [OF M_wfrank_L]
and wellfoundedrank_type = M_wfrank.wellfoundedrank_type [OF M_wfrank_L]
and Ord_wellfoundedrank = M_wfrank.Ord_wellfoundedrank [OF M_wfrank_L]
and wellfoundedrank_eq = M_wfrank.wellfoundedrank_eq [OF M_wfrank_L]
and wellfoundedrank_lt = M_wfrank.wellfoundedrank_lt [OF M_wfrank_L]
and wellfounded_imp_subset_rvimage = M_wfrank.wellfounded_imp_subset_rvimage [OF M_wfrank_L]
and wellfounded_imp_wf = M_wfrank.wellfounded_imp_wf [OF M_wfrank_L]
and wellfounded_on_imp_wf_on = M_wfrank.wellfounded_on_imp_wf_on [OF M_wfrank_L]
and wf_abs = M_wfrank.wf_abs [OF M_wfrank_L]
and wf_on_abs = M_wfrank.wf_on_abs [OF M_wfrank_L]

end
```