Theory HOL.BNF_Wellorder_Embedding
section ‹Well-Order Embeddings as Needed by Bounded Natural Functors›
theory BNF_Wellorder_Embedding
imports Hilbert_Choice BNF_Wellorder_Relation
begin
text‹In this section, we introduce well-order {\em embeddings} and {\em isomorphisms} and
prove their basic properties. The notion of embedding is considered from the point
of view of the theory of ordinals, and therefore requires the source to be injected
as an {\em initial segment} (i.e., {\em order filter}) of the target. A main result
of this section is the existence of embeddings (in one direction or another) between
any two well-orders, having as a consequence the fact that, given any two sets on
any two types, one is smaller than (i.e., can be injected into) the other.›
subsection ‹Auxiliaries›
lemma UNION_inj_on_ofilter:
assumes WELL: "Well_order r" and
OF: "⋀ i. i ∈ I ⟹ wo_rel.ofilter r (A i)" and
INJ: "⋀ i. i ∈ I ⟹ inj_on f (A i)"
shows "inj_on f (⋃i ∈ I. A i)"
proof-
have "wo_rel r" using WELL by (simp add: wo_rel_def)
hence "⋀ i j. ⟦i ∈ I; j ∈ I⟧ ⟹ A i <= A j ∨ A j <= A i"
using wo_rel.ofilter_linord[of r] OF by blast
with WELL INJ show ?thesis
by (auto simp add: inj_on_UNION_chain)
qed
lemma under_underS_bij_betw:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
IN: "a ∈ Field r" and IN': "f a ∈ Field r'" and
BIJ: "bij_betw f (underS r a) (underS r' (f a))"
shows "bij_betw f (under r a) (under r' (f a))"
proof-
have "a ∉ underS r a ∧ f a ∉ underS r' (f a)"
unfolding underS_def by auto
moreover
{have "Refl r ∧ Refl r'" using WELL WELL'
by (auto simp add: order_on_defs)
hence "under r a = underS r a ∪ {a} ∧
under r' (f a) = underS r' (f a) ∪ {f a}"
using IN IN' by(auto simp add: Refl_under_underS)
}
ultimately show ?thesis
using BIJ notIn_Un_bij_betw[of a "underS r a" f "underS r' (f a)"] by auto
qed
subsection ‹(Well-order) embeddings, strict embeddings, isomorphisms and order-compatible
functions›
text‹Standardly, a function is an embedding of a well-order in another if it injectively and
order-compatibly maps the former into an order filter of the latter.
Here we opt for a more succinct definition (operator ‹embed›),
asking that, for any element in the source, the function should be a bijection
between the set of strict lower bounds of that element
and the set of strict lower bounds of its image. (Later we prove equivalence with
the standard definition -- lemma ‹embed_iff_compat_inj_on_ofilter›.)
A {\em strict embedding} (operator ‹embedS›) is a non-bijective embedding
and an isomorphism (operator ‹iso›) is a bijective embedding.›
definition embed :: "'a rel ⇒ 'a' rel ⇒ ('a ⇒ 'a') ⇒ bool"
where
"embed r r' f ≡ ∀a ∈ Field r. bij_betw f (under r a) (under r' (f a))"
lemmas embed_defs = embed_def embed_def[abs_def]
text ‹Strict embeddings:›
definition embedS :: "'a rel ⇒ 'a' rel ⇒ ('a ⇒ 'a') ⇒ bool"
where
"embedS r r' f ≡ embed r r' f ∧ ¬ bij_betw f (Field r) (Field r')"
lemmas embedS_defs = embedS_def embedS_def[abs_def]
definition iso :: "'a rel ⇒ 'a' rel ⇒ ('a ⇒ 'a') ⇒ bool"
where
"iso r r' f ≡ embed r r' f ∧ bij_betw f (Field r) (Field r')"
lemmas iso_defs = iso_def iso_def[abs_def]
definition compat :: "'a rel ⇒ 'a' rel ⇒ ('a ⇒ 'a') ⇒ bool"
where
"compat r r' f ≡ ∀a b. (a,b) ∈ r ⟶ (f a, f b) ∈ r'"
lemma compat_wf:
assumes CMP: "compat r r' f" and WF: "wf r'"
shows "wf r"
proof-
have "r ≤ inv_image r' f"
unfolding inv_image_def using CMP
by (auto simp add: compat_def)
with WF show ?thesis
using wf_inv_image[of r' f] wf_subset[of "inv_image r' f"] by auto
qed
lemma id_embed: "embed r r id"
by(auto simp add: id_def embed_def bij_betw_def)
lemma id_iso: "iso r r id"
by(auto simp add: id_def embed_def iso_def bij_betw_def)
lemma embed_compat:
assumes EMB: "embed r r' f"
shows "compat r r' f"
unfolding compat_def
proof clarify
fix a b
assume *: "(a,b) ∈ r"
hence 1: "b ∈ Field r" using Field_def[of r] by blast
have "a ∈ under r b"
using * under_def[of r] by simp
hence "f a ∈ under r' (f b)"
using EMB embed_def[of r r' f]
bij_betw_def[of f "under r b" "under r' (f b)"]
image_def[of f "under r b"] 1 by auto
thus "(f a, f b) ∈ r'"
by (auto simp add: under_def)
qed
lemma embed_in_Field:
assumes EMB: "embed r r' f" and IN: "a ∈ Field r"
shows "f a ∈ Field r'"
proof -
have "a ∈ Domain r ∨ a ∈ Range r"
using IN unfolding Field_def by blast
then show ?thesis
using embed_compat [OF EMB]
unfolding Field_def compat_def by force
qed
lemma comp_embed:
assumes EMB: "embed r r' f" and EMB': "embed r' r'' f'"
shows "embed r r'' (f' ∘ f)"
proof(unfold embed_def, auto)
fix a assume *: "a ∈ Field r"
hence "bij_betw f (under r a) (under r' (f a))"
using embed_def[of r] EMB by auto
moreover
{have "f a ∈ Field r'"
using EMB * by (auto simp add: embed_in_Field)
hence "bij_betw f' (under r' (f a)) (under r'' (f' (f a)))"
using embed_def[of r'] EMB' by auto
}
ultimately
show "bij_betw (f' ∘ f) (under r a) (under r'' (f'(f a)))"
by(auto simp add: bij_betw_trans)
qed
lemma comp_iso:
assumes EMB: "iso r r' f" and EMB': "iso r' r'' f'"
shows "iso r r'' (f' ∘ f)"
using assms unfolding iso_def
by (auto simp add: comp_embed bij_betw_trans)
text‹That ‹embedS› is also preserved by function composition shall be proved only later.›
lemma embed_Field: "embed r r' f ⟹ f`(Field r) ≤ Field r'"
by (auto simp add: embed_in_Field)
lemma embed_preserves_ofilter:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
EMB: "embed r r' f" and OF: "wo_rel.ofilter r A"
shows "wo_rel.ofilter r' (f`A)"
proof-
from WELL have Well: "wo_rel r" unfolding wo_rel_def .
from WELL' have Well': "wo_rel r'" unfolding wo_rel_def .
from OF have 0: "A ≤ Field r" by(auto simp add: Well wo_rel.ofilter_def)
show ?thesis using Well' WELL EMB 0 embed_Field[of r r' f]
proof(unfold wo_rel.ofilter_def, auto simp add: image_def)
fix a b'
assume *: "a ∈ A" and **: "b' ∈ under r' (f a)"
hence "a ∈ Field r" using 0 by auto
hence "bij_betw f (under r a) (under r' (f a))"
using * EMB by (auto simp add: embed_def)
hence "f`(under r a) = under r' (f a)"
by (simp add: bij_betw_def)
with ** image_def[of f "under r a"] obtain b where
1: "b ∈ under r a ∧ b' = f b" by blast
hence "b ∈ A" using Well * OF
by (auto simp add: wo_rel.ofilter_def)
with 1 show "∃b ∈ A. b' = f b" by blast
qed
qed
lemma embed_Field_ofilter:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
EMB: "embed r r' f"
shows "wo_rel.ofilter r' (f`(Field r))"
proof-
have "wo_rel.ofilter r (Field r)"
using WELL by (auto simp add: wo_rel_def wo_rel.Field_ofilter)
with WELL WELL' EMB
show ?thesis by (auto simp add: embed_preserves_ofilter)
qed
lemma embed_inj_on:
assumes WELL: "Well_order r" and EMB: "embed r r' f"
shows "inj_on f (Field r)"
proof(unfold inj_on_def, clarify)
from WELL have Well: "wo_rel r" unfolding wo_rel_def .
with wo_rel.TOTAL[of r]
have Total: "Total r" by simp
from Well wo_rel.REFL[of r]
have Refl: "Refl r" by simp
fix a b
assume *: "a ∈ Field r" and **: "b ∈ Field r" and
***: "f a = f b"
hence 1: "a ∈ Field r ∧ b ∈ Field r"
unfolding Field_def by auto
{assume "(a,b) ∈ r"
hence "a ∈ under r b ∧ b ∈ under r b"
using Refl by(auto simp add: under_def refl_on_def)
hence "a = b"
using EMB 1 ***
by (auto simp add: embed_def bij_betw_def inj_on_def)
}
moreover
{assume "(b,a) ∈ r"
hence "a ∈ under r a ∧ b ∈ under r a"
using Refl by(auto simp add: under_def refl_on_def)
hence "a = b"
using EMB 1 ***
by (auto simp add: embed_def bij_betw_def inj_on_def)
}
ultimately
show "a = b" using Total 1
by (auto simp add: total_on_def)
qed
lemma embed_underS:
assumes WELL: "Well_order r" and
EMB: "embed r r' f" and IN: "a ∈ Field r"
shows "bij_betw f (underS r a) (underS r' (f a))"
proof-
have "f a ∈ Field r'" using assms embed_Field[of r r' f] by auto
then have 0: "under r a = underS r a ∪ {a}"
by (simp add: IN Refl_under_underS WELL wo_rel.REFL wo_rel.intro)
moreover have 1: "bij_betw f (under r a) (under r' (f a))"
using assms by (auto simp add: embed_def)
moreover have "under r' (f a) = underS r' (f a) ∪ {f a}"
proof
show "under r' (f a) ⊆ underS r' (f a) ∪ {f a}"
using underS_def under_def by fastforce
show "underS r' (f a) ∪ {f a} ⊆ under r' (f a)"
using bij_betwE 0 1 underS_subset_under by fastforce
qed
moreover have "a ∉ underS r a ∧ f a ∉ underS r' (f a)"
unfolding underS_def by blast
ultimately show ?thesis
by (auto simp add: notIn_Un_bij_betw3)
qed
lemma embed_iff_compat_inj_on_ofilter:
assumes WELL: "Well_order r" and WELL': "Well_order r'"
shows "embed r r' f = (compat r r' f ∧ inj_on f (Field r) ∧ wo_rel.ofilter r' (f`(Field r)))"
using assms
proof(auto simp add: embed_compat embed_inj_on embed_Field_ofilter,
unfold embed_def, auto)
fix a
assume *: "inj_on f (Field r)" and
**: "compat r r' f" and
***: "wo_rel.ofilter r' (f`(Field r))" and
****: "a ∈ Field r"
have Well: "wo_rel r"
using WELL wo_rel_def[of r] by simp
hence Refl: "Refl r"
using wo_rel.REFL[of r] by simp
have Total: "Total r"
using Well wo_rel.TOTAL[of r] by simp
have Well': "wo_rel r'"
using WELL' wo_rel_def[of r'] by simp
hence Antisym': "antisym r'"
using wo_rel.ANTISYM[of r'] by simp
have "(a,a) ∈ r"
using **** Well wo_rel.REFL[of r]
refl_on_def[of _ r] by auto
hence "(f a, f a) ∈ r'"
using ** by(auto simp add: compat_def)
hence 0: "f a ∈ Field r'"
unfolding Field_def by auto
have "f a ∈ f`(Field r)"
using **** by auto
hence 2: "under r' (f a) ≤ f`(Field r)"
using Well' *** wo_rel.ofilter_def[of r' "f`(Field r)"] by fastforce
show "bij_betw f (under r a) (under r' (f a))"
proof(unfold bij_betw_def, auto)
show "inj_on f (under r a)" by (rule subset_inj_on[OF * under_Field])
next
fix b assume "b ∈ under r a"
thus "f b ∈ under r' (f a)"
unfolding under_def using **
by (auto simp add: compat_def)
next
fix b' assume *****: "b' ∈ under r' (f a)"
hence "b' ∈ f`(Field r)"
using 2 by auto
with Field_def[of r] obtain b where
3: "b ∈ Field r" and 4: "b' = f b" by auto
have "(b,a) ∈ r"
proof-
{assume "(a,b) ∈ r"
with ** 4 have "(f a, b') ∈ r'"
by (auto simp add: compat_def)
with ***** Antisym' have "f a = b'"
by(auto simp add: under_def antisym_def)
with 3 **** 4 * have "a = b"
by(auto simp add: inj_on_def)
}
moreover
{assume "a = b"
hence "(b,a) ∈ r" using Refl **** 3
by (auto simp add: refl_on_def)
}
ultimately
show ?thesis using Total **** 3 by (fastforce simp add: total_on_def)
qed
with 4 show "b' ∈ f`(under r a)"
unfolding under_def by auto
qed
qed
lemma inv_into_ofilter_embed:
assumes WELL: "Well_order r" and OF: "wo_rel.ofilter r A" and
BIJ: "∀b ∈ A. bij_betw f (under r b) (under r' (f b))" and
IMAGE: "f ` A = Field r'"
shows "embed r' r (inv_into A f)"
proof-
have Well: "wo_rel r"
using WELL wo_rel_def[of r] by simp
have Refl: "Refl r"
using Well wo_rel.REFL[of r] by simp
have Total: "Total r"
using Well wo_rel.TOTAL[of r] by simp
have 1: "bij_betw f A (Field r')"
proof(unfold bij_betw_def inj_on_def, auto simp add: IMAGE)
fix b1 b2
assume *: "b1 ∈ A" and **: "b2 ∈ A" and
***: "f b1 = f b2"
have 11: "b1 ∈ Field r ∧ b2 ∈ Field r"
using * ** Well OF by (auto simp add: wo_rel.ofilter_def)
moreover
{assume "(b1,b2) ∈ r"
hence "b1 ∈ under r b2 ∧ b2 ∈ under r b2"
unfolding under_def using 11 Refl
by (auto simp add: refl_on_def)
hence "b1 = b2" using BIJ * ** ***
by (simp add: bij_betw_def inj_on_def)
}
moreover
{assume "(b2,b1) ∈ r"
hence "b1 ∈ under r b1 ∧ b2 ∈ under r b1"
unfolding under_def using 11 Refl
by (auto simp add: refl_on_def)
hence "b1 = b2" using BIJ * ** ***
by (simp add: bij_betw_def inj_on_def)
}
ultimately
show "b1 = b2"
using Total by (auto simp add: total_on_def)
qed
let ?f' = "(inv_into A f)"
have 2: "∀b ∈ A. bij_betw ?f' (under r' (f b)) (under r b)"
proof(clarify)
fix b assume *: "b ∈ A"
hence "under r b ≤ A"
using Well OF by(auto simp add: wo_rel.ofilter_def)
moreover
have "f ` (under r b) = under r' (f b)"
using * BIJ by (auto simp add: bij_betw_def)
ultimately
show "bij_betw ?f' (under r' (f b)) (under r b)"
using 1 by (auto simp add: bij_betw_inv_into_subset)
qed
have 3: "∀b' ∈ Field r'. bij_betw ?f' (under r' b') (under r (?f' b'))"
proof(clarify)
fix b' assume *: "b' ∈ Field r'"
have "b' = f (?f' b')" using * 1
by (auto simp add: bij_betw_inv_into_right)
moreover
{obtain b where 31: "b ∈ A" and "f b = b'" using IMAGE * by force
hence "?f' b' = b" using 1 by (auto simp add: bij_betw_inv_into_left)
with 31 have "?f' b' ∈ A" by auto
}
ultimately
show "bij_betw ?f' (under r' b') (under r (?f' b'))"
using 2 by auto
qed
thus ?thesis unfolding embed_def .
qed
lemma inv_into_underS_embed:
assumes WELL: "Well_order r" and
BIJ: "∀b ∈ underS r a. bij_betw f (under r b) (under r' (f b))" and
IN: "a ∈ Field r" and
IMAGE: "f ` (underS r a) = Field r'"
shows "embed r' r (inv_into (underS r a) f)"
using assms
by(auto simp add: wo_rel_def wo_rel.underS_ofilter inv_into_ofilter_embed)
lemma inv_into_Field_embed:
assumes WELL: "Well_order r" and EMB: "embed r r' f" and
IMAGE: "Field r' ≤ f ` (Field r)"
shows "embed r' r (inv_into (Field r) f)"
proof-
have "(∀b ∈ Field r. bij_betw f (under r b) (under r' (f b)))"
using EMB by (auto simp add: embed_def)
moreover
have "f ` (Field r) ≤ Field r'"
using EMB WELL by (auto simp add: embed_Field)
ultimately
show ?thesis using assms
by(auto simp add: wo_rel_def wo_rel.Field_ofilter inv_into_ofilter_embed)
qed
lemma inv_into_Field_embed_bij_betw:
assumes EMB: "embed r r' f" and BIJ: "bij_betw f (Field r) (Field r')"
shows "embed r' r (inv_into (Field r) f)"
proof-
have "Field r' ≤ f ` (Field r)"
using BIJ by (auto simp add: bij_betw_def)
then have iso: "iso r r' f"
by (simp add: BIJ EMB iso_def)
have *: "∀a. a ∈ Field r ⟶ bij_betw f (under r a) (under r' (f a))"
using EMB embed_def by fastforce
show ?thesis
proof (clarsimp simp add: embed_def)
fix a
assume a: "a ∈ Field r'"
then have ar: "a ∈ f ` Field r"
using BIJ bij_betw_imp_surj_on by blast
have [simp]: "f (inv_into (Field r) f a) = a"
by (simp add: ar f_inv_into_f)
show "bij_betw (inv_into (Field r) f) (under r' a) (under r (inv_into (Field r) f a))"
proof (rule bij_betw_inv_into_subset [OF BIJ])
show "under r (inv_into (Field r) f a) ⊆ Field r"
by (simp add: under_Field)
have "inv_into (Field r) f a ∈ Field r"
by (simp add: ar inv_into_into)
then show "f ` under r (inv_into (Field r) f a) = under r' a"
using bij_betw_imp_surj_on * by fastforce
qed
qed
qed
subsection ‹Given any two well-orders, one can be embedded in the other›
text‹Here is an overview of the proof of of this fact, stated in theorem
‹wellorders_totally_ordered›:
Fix the well-orders ‹r::'a rel› and ‹r'::'a' rel›.
Attempt to define an embedding ‹f::'a ⇒ 'a'› from ‹r› to ‹r'› in the
natural way by well-order recursion ("hoping" that ‹Field r› turns out to be smaller
than ‹Field r'›), but also record, at the recursive step, in a function
‹g::'a ⇒ bool›, the extra information of whether ‹Field r'›
gets exhausted or not.
If ‹Field r'› does not get exhausted, then ‹Field r› is indeed smaller
and ‹f› is the desired embedding from ‹r› to ‹r'›
(lemma ‹wellorders_totally_ordered_aux›).
Otherwise, it means that ‹Field r'› is the smaller one, and the inverse of
(the "good" segment of) ‹f› is the desired embedding from ‹r'› to ‹r›
(lemma ‹wellorders_totally_ordered_aux2›).
›
lemma wellorders_totally_ordered_aux:
fixes r ::"'a rel" and r'::"'a' rel" and
f :: "'a ⇒ 'a'" and a::'a
assumes WELL: "Well_order r" and WELL': "Well_order r'" and IN: "a ∈ Field r" and
IH: "∀b ∈ underS r a. bij_betw f (under r b) (under r' (f b))" and
NOT: "f ` (underS r a) ≠ Field r'" and SUC: "f a = wo_rel.suc r' (f`(underS r a))"
shows "bij_betw f (under r a) (under r' (f a))"
proof-
have Well: "wo_rel r" using WELL unfolding wo_rel_def .
hence Refl: "Refl r" using wo_rel.REFL[of r] by auto
have Trans: "trans r" using Well wo_rel.TRANS[of r] by auto
have Well': "wo_rel r'" using WELL' unfolding wo_rel_def .
have OF: "wo_rel.ofilter r (underS r a)"
by (auto simp add: Well wo_rel.underS_ofilter)
hence UN: "underS r a = (⋃b ∈ underS r a. under r b)"
using Well wo_rel.ofilter_under_UNION[of r "underS r a"] by blast
{fix b assume *: "b ∈ underS r a"
hence t0: "(b,a) ∈ r ∧ b ≠ a" unfolding underS_def by auto
have t1: "b ∈ Field r"
using * underS_Field[of r a] by auto
have t2: "f`(under r b) = under r' (f b)"
using IH * by (auto simp add: bij_betw_def)
hence t3: "wo_rel.ofilter r' (f`(under r b))"
using Well' by (auto simp add: wo_rel.under_ofilter)
have "f`(under r b) ≤ Field r'"
using t2 by (auto simp add: under_Field)
moreover
have "b ∈ under r b"
using t1 by(auto simp add: Refl Refl_under_in)
ultimately
have t4: "f b ∈ Field r'" by auto
have "f`(under r b) = under r' (f b) ∧
wo_rel.ofilter r' (f`(under r b)) ∧
f b ∈ Field r'"
using t2 t3 t4 by auto
}
hence bFact:
"∀b ∈ underS r a. f`(under r b) = under r' (f b) ∧
wo_rel.ofilter r' (f`(under r b)) ∧
f b ∈ Field r'" by blast
have subField: "f`(underS r a) ≤ Field r'"
using bFact by blast
have OF': "wo_rel.ofilter r' (f`(underS r a))"
proof-
have "f`(underS r a) = f`(⋃b ∈ underS r a. under r b)"
using UN by auto
also have "… = (⋃b ∈ underS r a. f`(under r b))" by blast
also have "… = (⋃b ∈ underS r a. (under r' (f b)))"
using bFact by auto
finally
have "f`(underS r a) = (⋃b ∈ underS r a. (under r' (f b)))" .
thus ?thesis
using Well' bFact
wo_rel.ofilter_UNION[of r' "underS r a" "λ b. under r' (f b)"] by fastforce
qed
have "f`(underS r a) ∪ AboveS r' (f`(underS r a)) = Field r'"
using Well' OF' by (auto simp add: wo_rel.ofilter_AboveS_Field)
hence NE: "AboveS r' (f`(underS r a)) ≠ {}"
using subField NOT by blast
have INCL1: "f`(underS r a) ≤ underS r' (f a) "
proof(auto)
fix b assume *: "b ∈ underS r a"
have "f b ≠ f a ∧ (f b, f a) ∈ r'"
using subField Well' SUC NE *
wo_rel.suc_greater[of r' "f`(underS r a)" "f b"] by force
thus "f b ∈ underS r' (f a)"
unfolding underS_def by simp
qed
have INCL2: "underS r' (f a) ≤ f`(underS r a)"
proof
fix b' assume "b' ∈ underS r' (f a)"
hence "b' ≠ f a ∧ (b', f a) ∈ r'"
unfolding underS_def by simp
thus "b' ∈ f`(underS r a)"
using Well' SUC NE OF'
wo_rel.suc_ofilter_in[of r' "f ` underS r a" b'] by auto
qed
have INJ: "inj_on f (underS r a)"
proof-
have "∀b ∈ underS r a. inj_on f (under r b)"
using IH by (auto simp add: bij_betw_def)
moreover
have "∀b. wo_rel.ofilter r (under r b)"
using Well by (auto simp add: wo_rel.under_ofilter)
ultimately show ?thesis
using WELL bFact UN
UNION_inj_on_ofilter[of r "underS r a" "λb. under r b" f]
by auto
qed
have BIJ: "bij_betw f (underS r a) (underS r' (f a))"
unfolding bij_betw_def
using INJ INCL1 INCL2 by auto
have "f a ∈ Field r'"
using Well' subField NE SUC
by (auto simp add: wo_rel.suc_inField)
thus ?thesis
using WELL WELL' IN BIJ under_underS_bij_betw[of r r' a f] by auto
qed
lemma wellorders_totally_ordered_aux2:
fixes r ::"'a rel" and r'::"'a' rel" and
f :: "'a ⇒ 'a'" and g :: "'a ⇒ bool" and a::'a
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
MAIN1:
"⋀ a. (False ∉ g`(underS r a) ∧ f`(underS r a) ≠ Field r'
⟶ f a = wo_rel.suc r' (f`(underS r a)) ∧ g a = True)
∧
(¬(False ∉ (g`(underS r a)) ∧ f`(underS r a) ≠ Field r')
⟶ g a = False)" and
MAIN2: "⋀ a. a ∈ Field r ∧ False ∉ g`(under r a) ⟶
bij_betw f (under r a) (under r' (f a))" and
Case: "a ∈ Field r ∧ False ∈ g`(under r a)"
shows "∃f'. embed r' r f'"
proof-
have Well: "wo_rel r" using WELL unfolding wo_rel_def .
hence Refl: "Refl r" using wo_rel.REFL[of r] by auto
have Trans: "trans r" using Well wo_rel.TRANS[of r] by auto
have Antisym: "antisym r" using Well wo_rel.ANTISYM[of r] by auto
have Well': "wo_rel r'" using WELL' unfolding wo_rel_def .
have 0: "under r a = underS r a ∪ {a}"
using Refl Case by(auto simp add: Refl_under_underS)
have 1: "g a = False"
proof-
{assume "g a ≠ False"
with 0 Case have "False ∈ g`(underS r a)" by blast
with MAIN1 have "g a = False" by blast}
thus ?thesis by blast
qed
let ?A = "{a ∈ Field r. g a = False}"
let ?a = "(wo_rel.minim r ?A)"
have 2: "?A ≠ {} ∧ ?A ≤ Field r" using Case 1 by blast
have 3: "False ∉ g`(underS r ?a)"
proof
assume "False ∈ g`(underS r ?a)"
then obtain b where "b ∈ underS r ?a" and 31: "g b = False" by auto
hence 32: "(b,?a) ∈ r ∧ b ≠ ?a"
by (auto simp add: underS_def)
hence "b ∈ Field r" unfolding Field_def by auto
with 31 have "b ∈ ?A" by auto
hence "(?a,b) ∈ r" using wo_rel.minim_least 2 Well by fastforce
with 32 Antisym show False
by (auto simp add: antisym_def)
qed
have temp: "?a ∈ ?A"
using Well 2 wo_rel.minim_in[of r ?A] by auto
hence 4: "?a ∈ Field r" by auto
have 5: "g ?a = False" using temp by blast
have 6: "f`(underS r ?a) = Field r'"
using MAIN1[of ?a] 3 5 by blast
have 7: "∀b ∈ underS r ?a. bij_betw f (under r b) (under r' (f b))"
proof
fix b assume as: "b ∈ underS r ?a"
moreover
have "wo_rel.ofilter r (underS r ?a)"
using Well by (auto simp add: wo_rel.underS_ofilter)
ultimately
have "False ∉ g`(under r b)" using 3 Well by (subst (asm) wo_rel.ofilter_def) fast+
moreover have "b ∈ Field r"
unfolding Field_def using as by (auto simp add: underS_def)
ultimately
show "bij_betw f (under r b) (under r' (f b))"
using MAIN2 by auto
qed
have "embed r' r (inv_into (underS r ?a) f)"
using WELL WELL' 7 4 6 inv_into_underS_embed[of r ?a f r'] by auto
thus ?thesis
unfolding embed_def by blast
qed
theorem wellorders_totally_ordered:
fixes r ::"'a rel" and r'::"'a' rel"
assumes WELL: "Well_order r" and WELL': "Well_order r'"
shows "(∃f. embed r r' f) ∨ (∃f'. embed r' r f')"
proof-
have Well: "wo_rel r" using WELL unfolding wo_rel_def .
hence Refl: "Refl r" using wo_rel.REFL[of r] by auto
have Trans: "trans r" using Well wo_rel.TRANS[of r] by auto
have Well': "wo_rel r'" using WELL' unfolding wo_rel_def .
obtain H where H_def: "H =
(λh a. if False ∉ (snd ∘ h)`(underS r a) ∧ (fst ∘ h)`(underS r a) ≠ Field r'
then (wo_rel.suc r' ((fst ∘ h)`(underS r a)), True)
else (undefined, False))" by blast
have Adm: "wo_rel.adm_wo r H"
using Well
proof(unfold wo_rel.adm_wo_def, clarify)
fix h1::"'a ⇒ 'a' * bool" and h2::"'a ⇒ 'a' * bool" and x
assume "∀y∈underS r x. h1 y = h2 y"
hence "∀y∈underS r x. (fst ∘ h1) y = (fst ∘ h2) y ∧
(snd ∘ h1) y = (snd ∘ h2) y" by auto
hence "(fst ∘ h1)`(underS r x) = (fst ∘ h2)`(underS r x) ∧
(snd ∘ h1)`(underS r x) = (snd ∘ h2)`(underS r x)"
by (auto simp add: image_def)
thus "H h1 x = H h2 x" by (simp add: H_def del: not_False_in_image_Ball)
qed
obtain h::"'a ⇒ 'a' * bool" and f::"'a ⇒ 'a'" and g::"'a ⇒ bool"
where h_def: "h = wo_rel.worec r H" and
f_def: "f = fst ∘ h" and g_def: "g = snd ∘ h" by blast
obtain test where test_def:
"test = (λ a. False ∉ (g`(underS r a)) ∧ f`(underS r a) ≠ Field r')" by blast
have *: "⋀ a. h a = H h a"
using Adm Well wo_rel.worec_fixpoint[of r H] by (simp add: h_def)
have Main1:
"⋀ a. (test a ⟶ f a = wo_rel.suc r' (f`(underS r a)) ∧ g a = True) ∧
(¬(test a) ⟶ g a = False)"
proof-
fix a show "(test a ⟶ f a = wo_rel.suc r' (f`(underS r a)) ∧ g a = True) ∧
(¬(test a) ⟶ g a = False)"
using *[of a] test_def f_def g_def H_def by auto
qed
let ?phi = "λ a. a ∈ Field r ∧ False ∉ g`(under r a) ⟶
bij_betw f (under r a) (under r' (f a))"
have Main2: "⋀ a. ?phi a"
proof-
fix a show "?phi a"
proof(rule wo_rel.well_order_induct[of r ?phi],
simp only: Well, clarify)
fix a
assume IH: "∀b. b ≠ a ∧ (b,a) ∈ r ⟶ ?phi b" and
*: "a ∈ Field r" and
**: "False ∉ g`(under r a)"
have 1: "∀b ∈ underS r a. bij_betw f (under r b) (under r' (f b))"
proof(clarify)
fix b assume ***: "b ∈ underS r a"
hence 0: "(b,a) ∈ r ∧ b ≠ a" unfolding underS_def by auto
moreover have "b ∈ Field r"
using *** underS_Field[of r a] by auto
moreover have "False ∉ g`(under r b)"
using 0 ** Trans under_incr[of r b a] by auto
ultimately show "bij_betw f (under r b) (under r' (f b))"
using IH by auto
qed
have 21: "False ∉ g`(underS r a)"
using ** underS_subset_under[of r a] by auto
have 22: "g`(under r a) ≤ {True}" using ** by auto
moreover have 23: "a ∈ under r a"
using Refl * by (auto simp add: Refl_under_in)
ultimately have 24: "g a = True" by blast
have 2: "f`(underS r a) ≠ Field r'"
proof
assume "f`(underS r a) = Field r'"
hence "g a = False" using Main1 test_def by blast
with 24 show False using ** by blast
qed
have 3: "f a = wo_rel.suc r' (f`(underS r a))"
using 21 2 Main1 test_def by blast
show "bij_betw f (under r a) (under r' (f a))"
using WELL WELL' 1 2 3 *
wellorders_totally_ordered_aux[of r r' a f] by auto
qed
qed
let ?chi = "(λ a. a ∈ Field r ∧ False ∈ g`(under r a))"
show ?thesis
proof(cases "∃a. ?chi a")
assume "¬ (∃a. ?chi a)"
hence "∀a ∈ Field r. bij_betw f (under r a) (under r' (f a))"
using Main2 by blast
thus ?thesis unfolding embed_def by blast
next
assume "∃a. ?chi a"
then obtain a where "?chi a" by blast
hence "∃f'. embed r' r f'"
using wellorders_totally_ordered_aux2[of r r' g f a]
WELL WELL' Main1 Main2 test_def by fast
thus ?thesis by blast
qed
qed
subsection ‹Uniqueness of embeddings›
text‹Here we show a fact complementary to the one from the previous subsection -- namely,
that between any two well-orders there is {\em at most} one embedding, and is the one
definable by the expected well-order recursive equation. As a consequence, any two
embeddings of opposite directions are mutually inverse.›
lemma embed_determined:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
EMB: "embed r r' f" and IN: "a ∈ Field r"
shows "f a = wo_rel.suc r' (f`(underS r a))"
proof-
have "bij_betw f (underS r a) (underS r' (f a))"
using assms by (auto simp add: embed_underS)
hence "f`(underS r a) = underS r' (f a)"
by (auto simp add: bij_betw_def)
moreover
{have "f a ∈ Field r'" using IN
using EMB WELL embed_Field[of r r' f] by auto
hence "f a = wo_rel.suc r' (underS r' (f a))"
using WELL' by (auto simp add: wo_rel_def wo_rel.suc_underS)
}
ultimately show ?thesis by simp
qed
lemma embed_unique:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
EMBf: "embed r r' f" and EMBg: "embed r r' g"
shows "a ∈ Field r ⟶ f a = g a"
proof(rule wo_rel.well_order_induct[of r], auto simp add: WELL wo_rel_def)
fix a
assume IH: "∀b. b ≠ a ∧ (b,a) ∈ r ⟶ b ∈ Field r ⟶ f b = g b" and
*: "a ∈ Field r"
hence "∀b ∈ underS r a. f b = g b"
unfolding underS_def by (auto simp add: Field_def)
hence "f`(underS r a) = g`(underS r a)" by force
thus "f a = g a"
using assms * embed_determined[of r r' f a] embed_determined[of r r' g a] by auto
qed
lemma embed_bothWays_inverse:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
EMB: "embed r r' f" and EMB': "embed r' r f'"
shows "(∀a ∈ Field r. f'(f a) = a) ∧ (∀a' ∈ Field r'. f(f' a') = a')"
proof-
have "embed r r (f' ∘ f)" using assms
by(auto simp add: comp_embed)
moreover have "embed r r id" using assms
by (auto simp add: id_embed)
ultimately have "∀a ∈ Field r. f'(f a) = a"
using assms embed_unique[of r r "f' ∘ f" id] id_def by auto
moreover
{have "embed r' r' (f ∘ f')" using assms
by(auto simp add: comp_embed)
moreover have "embed r' r' id" using assms
by (auto simp add: id_embed)
ultimately have "∀a' ∈ Field r'. f(f' a') = a'"
using assms embed_unique[of r' r' "f ∘ f'" id] id_def by auto
}
ultimately show ?thesis by blast
qed
lemma embed_bothWays_bij_betw:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
EMB: "embed r r' f" and EMB': "embed r' r g"
shows "bij_betw f (Field r) (Field r')"
proof-
let ?A = "Field r" let ?A' = "Field r'"
have "embed r r (g ∘ f) ∧ embed r' r' (f ∘ g)"
using assms by (auto simp add: comp_embed)
hence 1: "(∀a ∈ ?A. g(f a) = a) ∧ (∀a' ∈ ?A'. f(g a') = a')"
using WELL id_embed[of r] embed_unique[of r r "g ∘ f" id]
WELL' id_embed[of r'] embed_unique[of r' r' "f ∘ g" id]
id_def by auto
have 2: "(∀a ∈ ?A. f a ∈ ?A') ∧ (∀a' ∈ ?A'. g a' ∈ ?A)"
using assms embed_Field[of r r' f] embed_Field[of r' r g] by blast
show ?thesis
proof(unfold bij_betw_def inj_on_def, auto simp add: 2)
fix a b assume *: "a ∈ ?A" "b ∈ ?A" and **: "f a = f b"
have "a = g(f a) ∧ b = g(f b)" using * 1 by auto
with ** show "a = b" by auto
next
fix a' assume *: "a' ∈ ?A'"
hence "g a' ∈ ?A ∧ f(g a') = a'" using 1 2 by auto
thus "a' ∈ f ` ?A" by force
qed
qed
lemma embed_bothWays_iso:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
EMB: "embed r r' f" and EMB': "embed r' r g"
shows "iso r r' f"
unfolding iso_def using assms by (auto simp add: embed_bothWays_bij_betw)
subsection ‹More properties of embeddings, strict embeddings and isomorphisms›
lemma embed_bothWays_Field_bij_betw:
assumes WELL: "Well_order r" and WELL': "Well_order r'" and
EMB: "embed r r' f" and EMB': "embed r' r f'"
shows "bij_betw f (Field r) (Field r')"
proof-
have "(∀a ∈ Field r. f'(f a) = a) ∧ (∀a' ∈ Field r'. f(f' a') = a')"
using assms by (auto simp add: embed_bothWays_inverse)
moreover
have "f`(Field r) ≤ Field r' ∧ f' ` (Field r') ≤ Field r"
using assms by (auto simp add: embed_Field)
ultimately
show ?thesis using bij_betw_byWitness[of "Field r" f' f "Field r'"] by auto
qed
lemma embedS_comp_embed:
assumes WELL: "Well_order r" and WELL': "Well_order r'"
and EMB: "embedS r r' f" and EMB': "embed r' r'' f'"
shows "embedS r r'' (f' ∘ f)"
proof-
let ?g = "(f' ∘ f)" let ?h = "inv_into (Field r) ?g"
have 1: "embed r r' f ∧ ¬ (bij_betw f (Field r) (Field r'))"
using EMB by (auto simp add: embedS_def)
hence 2: "embed r r'' ?g"
using EMB' comp_embed[of r r' f r'' f'] by auto
moreover
{assume "bij_betw ?g (Field r) (Field r'')"
hence "embed r'' r ?h" using 2
by (auto simp add: inv_into_Field_embed_bij_betw)
hence "embed r' r (?h ∘ f')" using EMB'
by (auto simp add: comp_embed)
hence "bij_betw f (Field r) (Field r')" using WELL WELL' 1
by (auto simp add: embed_bothWays_Field_bij_betw)
with 1 have False by blast
}
ultimately show ?thesis unfolding embedS_def by auto
qed
lemma embed_comp_embedS:
assumes WELL: "Well_order r" and WELL': "Well_order r'"
and EMB: "embed r r' f" and EMB': "embedS r' r'' f'"
shows "embedS r r'' (f' ∘ f)"
proof-
let ?g = "(f' ∘ f)" let ?h = "inv_into (Field r) ?g"
have 1: "embed r' r'' f' ∧ ¬ (bij_betw f' (Field r') (Field r''))"
using EMB' by (auto simp add: embedS_def)
hence 2: "embed r r'' ?g"
using WELL EMB comp_embed[of r r' f r'' f'] by auto
moreover have §: "f' ` Field r' ⊆ Field r''"
by (simp add: "1" embed_Field)
{assume §: "bij_betw ?g (Field r) (Field r'')"
hence "embed r'' r ?h" using 2 WELL
by (auto simp add: inv_into_Field_embed_bij_betw)
hence "embed r' r (inv_into (Field r) ?g ∘ f')"
using "1" BNF_Wellorder_Embedding.comp_embed WELL' by blast
then have "bij_betw f' (Field r') (Field r'')"
using EMB WELL WELL' § bij_betw_comp_iff by (blast intro: embed_bothWays_Field_bij_betw)
with 1 have False by blast
}
ultimately show ?thesis unfolding embedS_def by auto
qed
lemma embed_comp_iso:
assumes EMB: "embed r r' f" and EMB': "iso r' r'' f'"
shows "embed r r'' (f' ∘ f)" using assms unfolding iso_def
by (auto simp add: comp_embed)
lemma iso_comp_embed:
assumes EMB: "iso r r' f" and EMB': "embed r' r'' f'"
shows "embed r r'' (f' ∘ f)"
using assms unfolding iso_def by (auto simp add: comp_embed)
lemma embedS_comp_iso:
assumes EMB: "embedS r r' f" and EMB': "iso r' r'' f'"
shows "embedS r r'' (f' ∘ f)"
proof -
have §: "embed r r' f ∧ ¬ bij_betw f (Field r) (Field r')"
using EMB embedS_def by blast
then have "embed r r'' (f' ∘ f)"
using embed_comp_iso EMB' by blast
then have "f ` Field r ⊆ Field r'"
by (simp add: embed_Field §)
then have "¬ bij_betw (f' ∘ f) (Field r) (Field r'')"
using "§" EMB' by (auto simp: bij_betw_comp_iff2 iso_def)
then show ?thesis
by (simp add: ‹embed r r'' (f' ∘ f)› embedS_def)
qed
lemma iso_comp_embedS:
assumes WELL: "Well_order r" and WELL': "Well_order r'"
and EMB: "iso r r' f" and EMB': "embedS r' r'' f'"
shows "embedS r r'' (f' ∘ f)"
using assms unfolding iso_def by (auto simp add: embed_comp_embedS)
lemma embedS_Field:
assumes WELL: "Well_order r" and EMB: "embedS r r' f"
shows "f ` (Field r) < Field r'"
proof-
have "f`(Field r) ≤ Field r'" using assms
by (auto simp add: embed_Field embedS_def)
moreover
{have "inj_on f (Field r)" using assms
by (auto simp add: embedS_def embed_inj_on)
hence "f`(Field r) ≠ Field r'" using EMB
by (auto simp add: embedS_def bij_betw_def)
}
ultimately show ?thesis by blast
qed
lemma embedS_iff:
assumes WELL: "Well_order r" and ISO: "embed r r' f"
shows "embedS r r' f = (f ` (Field r) < Field r')"
proof
assume "embedS r r' f"
thus "f ` Field r ⊂ Field r'"
using WELL by (auto simp add: embedS_Field)
next
assume "f ` Field r ⊂ Field r'"
hence "¬ bij_betw f (Field r) (Field r')"
unfolding bij_betw_def by blast
thus "embedS r r' f" unfolding embedS_def
using ISO by auto
qed
lemma iso_Field: "iso r r' f ⟹ f ` (Field r) = Field r'"
by (auto simp add: iso_def bij_betw_def)
lemma iso_iff:
assumes "Well_order r"
shows "iso r r' f = (embed r r' f ∧ f ` (Field r) = Field r')"
proof
assume "iso r r' f"
thus "embed r r' f ∧ f ` (Field r) = Field r'"
by (auto simp add: iso_Field iso_def)
next
assume *: "embed r r' f ∧ f ` Field r = Field r'"
hence "inj_on f (Field r)" using assms by (auto simp add: embed_inj_on)
with * have "bij_betw f (Field r) (Field r')"
unfolding bij_betw_def by simp
with * show "iso r r' f" unfolding iso_def by auto
qed
lemma iso_iff2: "iso r r' f ⟷
bij_betw f (Field r) (Field r') ∧
(∀a ∈ Field r. ∀b ∈ Field r. (a, b) ∈ r ⟷ (f a, f b) ∈ r')"
(is "?lhs = ?rhs")
proof
assume L: ?lhs
then have "bij_betw f (Field r) (Field r')" and emb: "embed r r' f"
by (auto simp: bij_betw_def iso_def)
then obtain g where g: "⋀x. x ∈ Field r ⟹ g (f x) = x"
by (auto simp: bij_betw_iff_bijections)
moreover
have "(a, b) ∈ r" if "a ∈ Field r" "b ∈ Field r" "(f a, f b) ∈ r'" for a b
using that emb g g [OF FieldI1]
by (force simp add: embed_def under_def bij_betw_iff_bijections)
ultimately show ?rhs
using L by (auto simp: compat_def iso_def dest: embed_compat)
next
assume R: ?rhs
then show ?lhs
apply (clarsimp simp add: iso_def embed_def under_def bij_betw_iff_bijections)
apply (rule_tac x="g" in exI)
apply (fastforce simp add: intro: FieldI1)+
done
qed
lemma iso_iff3:
assumes WELL: "Well_order r" and WELL': "Well_order r'"
shows "iso r r' f = (bij_betw f (Field r) (Field r') ∧ compat r r' f)"
proof
assume "iso r r' f"
thus "bij_betw f (Field r) (Field r') ∧ compat r r' f"
unfolding compat_def using WELL by (auto simp add: iso_iff2 Field_def)
next
have Well: "wo_rel r ∧ wo_rel r'" using WELL WELL'
by (auto simp add: wo_rel_def)
assume *: "bij_betw f (Field r) (Field r') ∧ compat r r' f"
thus "iso r r' f"
unfolding "compat_def" using assms
proof(auto simp add: iso_iff2)
fix a b assume **: "a ∈ Field r" "b ∈ Field r" and
***: "(f a, f b) ∈ r'"
{assume "(b,a) ∈ r ∨ b = a"
hence "(b,a) ∈ r"using Well ** wo_rel.REFL[of r] refl_on_def[of _ r] by blast
hence "(f b, f a) ∈ r'" using * unfolding compat_def by auto
hence "f a = f b"
using Well *** wo_rel.ANTISYM[of r'] antisym_def[of r'] by blast
hence "a = b" using * ** unfolding bij_betw_def inj_on_def by auto
hence "(a,b) ∈ r" using Well ** wo_rel.REFL[of r] refl_on_def[of _ r] by blast
}
thus "(a,b) ∈ r"
using Well ** wo_rel.TOTAL[of r] total_on_def[of _ r] by blast
qed
qed
lemma iso_imp_inj_on:
assumes "iso r r' f" shows "inj_on f (Field r)"
using assms unfolding iso_iff2 bij_betw_def by blast
lemma iso_backward_Field:
assumes "x ∈ Field r'" "iso r r' f"
shows "inv_into (Field r) f x ∈ Field r"
using assms iso_Field by (blast intro!: inv_into_into)
lemma iso_backward:
assumes "(x,y) ∈ r'" and iso: "iso r r' f"
shows "(inv_into (Field r) f x, inv_into (Field r) f y) ∈ r"
proof -
have §: "⋀x. (∃xa∈Field r. x = f xa) = (x ∈ Field r')"
using assms iso_Field [OF iso] by (force simp add: )
have "x ∈ Field r'" "y ∈ Field r'"
using assms by (auto simp: Field_def)
with § [of x] § [of y] assms show ?thesis
by (auto simp add: iso_iff2 bij_betw_inv_into_left)
qed
lemma iso_forward:
assumes "(x,y) ∈ r" "iso r r' f" shows "(f x,f y) ∈ r'"
using assms by (auto simp: Field_def iso_iff2)
lemma iso_trans:
assumes "trans r" and iso: "iso r r' f" shows "trans r'"
unfolding trans_def
proof clarify
fix x y z
assume xyz: "(x, y) ∈ r'" "(y, z) ∈ r'"
then have *: "(inv_into (Field r) f x, inv_into (Field r) f y) ∈ r"
"(inv_into (Field r) f y, inv_into (Field r) f z) ∈ r"
using iso_backward [OF _ iso] by blast+
then have "inv_into (Field r) f x ∈ Field r" "inv_into (Field r) f y ∈ Field r"
by (auto simp: Field_def)
with * have "(inv_into (Field r) f x, inv_into (Field r) f z) ∈ r"
using assms(1) by (blast intro: transD)
then have "(f (inv_into (Field r) f x), f (inv_into (Field r) f z)) ∈ r'"
by (blast intro: iso iso_forward)
moreover have "x ∈ f ` Field r" "z ∈ f ` Field r"
using xyz iso iso_Field by (blast intro: FieldI1 FieldI2)+
ultimately show "(x, z) ∈ r'"
by (simp add: f_inv_into_f)
qed
lemma iso_Total:
assumes "Total r" and iso: "iso r r' f" shows "Total r'"
unfolding total_on_def
proof clarify
fix x y
assume xy: "x ∈ Field r'" "y ∈ Field r'" "x ≠ y" "(y,x) ∉ r'"
then have §: "inv_into (Field r) f x ∈ Field r" "inv_into (Field r) f y ∈ Field r"
using iso_backward_Field [OF _ iso] by auto
moreover have "x ∈ f ` Field r" "y ∈ f ` Field r"
using xy iso iso_Field by (blast intro: FieldI1 FieldI2)+
ultimately have False if "inv_into (Field r) f x = inv_into (Field r) f y"
using inv_into_injective [OF that] ‹x ≠ y› by simp
then have "(inv_into (Field r) f x, inv_into (Field r) f y) ∈ r ∨ (inv_into (Field r) f y, inv_into (Field r) f x) ∈ r"
using assms § by (auto simp: total_on_def)
then show "(x, y) ∈ r'"
using assms xy by (auto simp: iso_Field f_inv_into_f dest!: iso_forward [OF _ iso])
qed
lemma iso_wf:
assumes "wf r" and iso: "iso r r' f" shows "wf r'"
proof -
have "bij_betw f (Field r) (Field r')"
and iff: "(∀a ∈ Field r. ∀b ∈ Field r. (a, b) ∈ r ⟷ (f a, f b) ∈ r')"
using assms by (auto simp: iso_iff2)
show ?thesis
proof (rule wfI_min)
fix x::'b and Q
assume "x ∈ Q"
let ?g = "inv_into (Field r) f"
obtain z0 where "z0 ∈ ?g ` Q"
using ‹x ∈ Q› by blast
then obtain z where z: "z ∈ ?g ` Q" and "⋀x y. ⟦(y, z) ∈ r; x ∈ Q⟧ ⟹ y ≠ ?g x"
by (rule wfE_min [OF ‹wf r›]) auto
then have "∀y. (y, inv_into Q ?g z) ∈ r' ⟶ y ∉ Q"
by (clarsimp simp: f_inv_into_f[OF z] z dest!: iso_backward [OF _ iso]) blast
moreover have "inv_into Q ?g z ∈ Q"
by (simp add: inv_into_into z)
ultimately show "∃z∈Q. ∀y. (y, z) ∈ r' ⟶ y ∉ Q" ..
qed
qed
end