(* Author: John Harrison
Author: Robert Himmelmann, TU Muenchen (Translation from HOL light)
*)
(* ========================================================================= *)
(* Results connected with topological dimension. *)
(* *)
(* At the moment this is just Brouwer's fixpoint theorem. The proof is from *)
(* Kuhn: "some combinatorial lemmas in topology", IBM J. v4. (1960) p. 518 *)
(* See "http://www.research.ibm.com/journal/rd/045/ibmrd0405K.pdf". *)
(* *)
(* The script below is quite messy, but at least we avoid formalizing any *)
(* topological machinery; we don't even use barycentric subdivision; this is *)
(* the big advantage of Kuhn's proof over the usual Sperner's lemma one. *)
(* *)
(* (c) Copyright, John Harrison 1998-2008 *)
(* ========================================================================= *)
header {* Results connected with topological dimension. *}
theory Brouwer_Fixpoint
imports Convex_Euclidean_Space
begin
(** move this **)
lemma divide_nonneg_nonneg:
fixes a b :: real
assumes "a \<ge> 0"
and "b \<ge> 0"
shows "0 \<le> a / b"
proof (cases "b = 0")
case True
then show ?thesis by auto
next
case False
show ?thesis
apply (rule divide_nonneg_pos)
using assms False
apply auto
done
qed
lemma brouwer_compactness_lemma:
fixes f :: "'a::metric_space \<Rightarrow> 'b::euclidean_space"
assumes "compact s"
and "continuous_on s f"
and "\<not> (\<exists>x\<in>s. f x = 0)"
obtains d where "0 < d" and "\<forall>x\<in>s. d \<le> norm (f x)"
proof (cases "s = {}")
case True
show thesis
by (rule that [of 1]) (auto simp: True)
next
case False
have "continuous_on s (norm \<circ> f)"
by (rule continuous_on_intros continuous_on_norm assms(2))+
with False obtain x where x: "x \<in> s" "\<forall>y\<in>s. (norm \<circ> f) x \<le> (norm \<circ> f) y"
using continuous_attains_inf[OF assms(1), of "norm \<circ> f"]
unfolding o_def
by auto
have "(norm \<circ> f) x > 0"
using assms(3) and x(1)
by auto
then show ?thesis
by (rule that) (insert x(2), auto simp: o_def)
qed
lemma kuhn_labelling_lemma:
fixes P Q :: "'a::euclidean_space \<Rightarrow> bool"
assumes "(\<forall>x. P x \<longrightarrow> P (f x))"
and "\<forall>x. P x \<longrightarrow> (\<forall>i\<in>Basis. Q i \<longrightarrow> 0 \<le> x\<bullet>i \<and> x\<bullet>i \<le> 1)"
shows "\<exists>l. (\<forall>x.\<forall>i\<in>Basis. l x i \<le> (1::nat)) \<and>
(\<forall>x.\<forall>i\<in>Basis. P x \<and> Q i \<and> (x\<bullet>i = 0) \<longrightarrow> (l x i = 0)) \<and>
(\<forall>x.\<forall>i\<in>Basis. P x \<and> Q i \<and> (x\<bullet>i = 1) \<longrightarrow> (l x i = 1)) \<and>
(\<forall>x.\<forall>i\<in>Basis. P x \<and> Q i \<and> (l x i = 0) \<longrightarrow> x\<bullet>i \<le> f(x)\<bullet>i) \<and>
(\<forall>x.\<forall>i\<in>Basis. P x \<and> Q i \<and> (l x i = 1) \<longrightarrow> f(x)\<bullet>i \<le> x\<bullet>i)"
proof -
have and_forall_thm:"\<And>P Q. (\<forall>x. P x) \<and> (\<forall>x. Q x) \<longleftrightarrow> (\<forall>x. P x \<and> Q x)"
by auto
have *: "\<forall>x y::real. 0 \<le> x \<and> x \<le> 1 \<and> 0 \<le> y \<and> y \<le> 1 \<longrightarrow> (x \<noteq> 1 \<and> x \<le> y \<or> x \<noteq> 0 \<and> y \<le> x)"
by auto
show ?thesis
unfolding and_forall_thm Ball_def
apply (subst choice_iff[symmetric])+
apply rule
apply rule
proof -
case (goal1 x)
let ?R = "\<lambda>y. (P x \<and> Q xa \<and> x \<bullet> xa = 0 \<longrightarrow> y = (0::nat)) \<and>
(P x \<and> Q xa \<and> x \<bullet> xa = 1 \<longrightarrow> y = 1) \<and>
(P x \<and> Q xa \<and> y = 0 \<longrightarrow> x \<bullet> xa \<le> f x \<bullet> xa) \<and>
(P x \<and> Q xa \<and> y = 1 \<longrightarrow> f x \<bullet> xa \<le> x \<bullet> xa)"
{
assume "P x" "Q xa" "xa \<in> Basis"
then have "0 \<le> f x \<bullet> xa \<and> f x \<bullet> xa \<le> 1"
using assms(2)[rule_format,of "f x" xa]
apply (drule_tac assms(1)[rule_format])
apply auto
done
}
then have "xa \<in> Basis \<Longrightarrow> ?R 0 \<or> ?R 1" by auto
then show ?case by auto
qed
qed
subsection {* The key "counting" observation, somewhat abstracted. *}
lemma setsum_Un_disjoint':
assumes "finite A"
and "finite B"
and "A \<inter> B = {}"
and "A \<union> B = C"
shows "setsum g C = setsum g A + setsum g B"
using setsum_Un_disjoint[OF assms(1-3)] and assms(4) by auto
lemma kuhn_counting_lemma:
assumes "finite faces"
and "finite simplices"
and "\<forall>f\<in>faces. bnd f \<longrightarrow> (card {s \<in> simplices. face f s} = 1)"
and "\<forall>f\<in>faces. \<not> bnd f \<longrightarrow> (card {s \<in> simplices. face f s} = 2)"
and "\<forall>s\<in>simplices. compo s \<longrightarrow> (card {f \<in> faces. face f s \<and> compo' f} = 1)"
and "\<forall>s\<in>simplices. \<not> compo s \<longrightarrow>
(card {f \<in> faces. face f s \<and> compo' f} = 0) \<or> (card {f \<in> faces. face f s \<and> compo' f} = 2)"
and "odd(card {f \<in> faces. compo' f \<and> bnd f})"
shows "odd(card {s \<in> simplices. compo s})"
proof -
have "\<And>x. {f\<in>faces. compo' f \<and> bnd f \<and> face f x} \<union> {f\<in>faces. compo' f \<and> \<not>bnd f \<and> face f x} =
{f\<in>faces. compo' f \<and> face f x}"
"\<And>x. {f \<in> faces. compo' f \<and> bnd f \<and> face f x} \<inter> {f \<in> faces. compo' f \<and> \<not> bnd f \<and> face f x} = {}"
by auto
then have lem1: "setsum (\<lambda>s. (card {f \<in> faces. face f s \<and> compo' f})) simplices =
setsum (\<lambda>s. card {f \<in> {f \<in> faces. compo' f \<and> bnd f}. face f s}) simplices +
setsum (\<lambda>s. card {f \<in> {f \<in> faces. compo' f \<and> \<not> (bnd f)}. face f s}) simplices"
unfolding setsum_addf[symmetric]
apply -
apply (rule setsum_cong2)
using assms(1)
apply (auto simp add: card_Un_Int, auto simp add:conj_commute)
done
have lem2:
"setsum (\<lambda>j. card {f \<in> {f \<in> faces. compo' f \<and> bnd f}. face f j}) simplices =
1 * card {f \<in> faces. compo' f \<and> bnd f}"
"setsum (\<lambda>j. card {f \<in> {f \<in> faces. compo' f \<and> \<not> bnd f}. face f j}) simplices =
2 * card {f \<in> faces. compo' f \<and> \<not> bnd f}"
apply (rule_tac[!] setsum_multicount)
using assms
apply auto
done
have lem3:
"setsum (\<lambda>s. card {f \<in> faces. face f s \<and> compo' f}) simplices =
setsum (\<lambda>s. card {f \<in> faces. face f s \<and> compo' f}) {s \<in> simplices. compo s}+
setsum (\<lambda>s. card {f \<in> faces. face f s \<and> compo' f}) {s \<in> simplices. \<not> compo s}"
apply (rule setsum_Un_disjoint')
using assms(2)
apply auto
done
have lem4: "setsum (\<lambda>s. card {f \<in> faces. face f s \<and> compo' f}) {s \<in> simplices. compo s} =
setsum (\<lambda>s. 1) {s \<in> simplices. compo s}"
apply (rule setsum_cong2)
using assms(5)
apply auto
done
have lem5: "setsum (\<lambda>s. card {f \<in> faces. face f s \<and> compo' f}) {s \<in> simplices. \<not> compo s} =
setsum (\<lambda>s. card {f \<in> faces. face f s \<and> compo' f})
{s \<in> simplices. (\<not> compo s) \<and> (card {f \<in> faces. face f s \<and> compo' f} = 0)} +
setsum (\<lambda>s. card {f \<in> faces. face f s \<and> compo' f})
{s \<in> simplices. (\<not> compo s) \<and> (card {f \<in> faces. face f s \<and> compo' f} = 2)}"
apply (rule setsum_Un_disjoint')
using assms(2,6)
apply auto
done
have *: "int (\<Sum>s\<in>{s \<in> simplices. compo s}. card {f \<in> faces. face f s \<and> compo' f}) =
int (card {f \<in> faces. compo' f \<and> bnd f} + 2 * card {f \<in> faces. compo' f \<and> \<not> bnd f}) -
int (card {s \<in> simplices. \<not> compo s \<and> card {f \<in> faces. face f s \<and> compo' f} = 2} * 2)"
using lem1[unfolded lem3 lem2 lem5] by auto
have even_minus_odd:"\<And>x y. even x \<Longrightarrow> odd (y::int) \<Longrightarrow> odd (x - y)"
using assms by auto
have odd_minus_even:"\<And>x y. odd x \<Longrightarrow> even (y::int) \<Longrightarrow> odd (x - y)"
using assms by auto
show ?thesis
unfolding even_nat_def card_eq_setsum and lem4[symmetric] and *[unfolded card_eq_setsum]
unfolding card_eq_setsum[symmetric]
apply (rule odd_minus_even)
unfolding of_nat_add
apply(rule odd_plus_even)
apply(rule assms(7)[unfolded even_nat_def])
unfolding int_mult
apply auto
done
qed
subsection {* The odd/even result for faces of complete vertices, generalized. *}
lemma card_1_exists: "card s = 1 \<longleftrightarrow> (\<exists>!x. x \<in> s)"
unfolding One_nat_def
apply rule
apply (drule card_eq_SucD)
defer
apply (erule ex1E)
proof -
fix x
assume as: "x \<in> s" "\<forall>y. y \<in> s \<longrightarrow> y = x"
have *: "s = insert x {}"
apply (rule set_eqI, rule) unfolding singleton_iff
apply (rule as(2)[rule_format]) using as(1)
apply auto
done
show "card s = Suc 0"
unfolding * using card_insert by auto
qed auto
lemma card_2_exists: "card s = 2 \<longleftrightarrow> (\<exists>x\<in>s. \<exists>y\<in>s. x \<noteq> y \<and> (\<forall>z\<in>s. z = x \<or> z = y))"
proof
assume "card s = 2"
then obtain x y where s: "s = {x, y}" "x \<noteq> y"
unfolding numeral_2_eq_2
apply -
apply (erule exE conjE | drule card_eq_SucD)+
apply auto
done
show "\<exists>x\<in>s. \<exists>y\<in>s. x \<noteq> y \<and> (\<forall>z\<in>s. z = x \<or> z = y)"
using s by auto
next
assume "\<exists>x\<in>s. \<exists>y\<in>s. x \<noteq> y \<and> (\<forall>z\<in>s. z = x \<or> z = y)"
then obtain x y where "x \<in> s" "y \<in> s" "x \<noteq> y" "\<forall>z\<in>s. z = x \<or> z = y"
by auto
then have "s = {x, y}"
by auto
with `x \<noteq> y` show "card s = 2"
by auto
qed
lemma image_lemma_0:
assumes "card {a\<in>s. f ` (s - {a}) = t - {b}} = n"
shows "card {s'. \<exists>a\<in>s. (s' = s - {a}) \<and> (f ` s' = t - {b})} = n"
proof -
have *: "{s'. \<exists>a\<in>s. (s' = s - {a}) \<and> (f ` s' = t - {b})} =
(\<lambda>a. s - {a}) ` {a\<in>s. f ` (s - {a}) = t - {b}}"
by auto
show ?thesis
unfolding *
unfolding assms[symmetric]
apply (rule card_image)
unfolding inj_on_def
apply (rule, rule, rule)
unfolding mem_Collect_eq
apply auto
done
qed
lemma image_lemma_1:
assumes "finite s"
and "finite t"
and "card s = card t"
and "f ` s = t"
and "b \<in> t"
shows "card {s'. \<exists>a\<in>s. s' = s - {a} \<and> f ` s' = t - {b}} = 1"
proof -
obtain a where a: "b = f a" "a \<in> s"
using assms(4-5) by auto
have inj: "inj_on f s"
apply (rule eq_card_imp_inj_on)
using assms(1-4)
apply auto
done
have *: "{a \<in> s. f ` (s - {a}) = t - {b}} = {a}"
apply (rule set_eqI)
unfolding singleton_iff
apply (rule, rule inj[unfolded inj_on_def, rule_format])
unfolding a
using a(2) and assms and inj[unfolded inj_on_def]
apply auto
done
show ?thesis
apply (rule image_lemma_0)
unfolding *
apply auto
done
qed
lemma image_lemma_2:
assumes "finite s" "finite t" "card s = card t" "f ` s \<subseteq> t" "f ` s \<noteq> t" "b \<in> t"
shows "card {s'. \<exists>a\<in>s. (s' = s - {a}) \<and> f ` s' = t - {b}} = 0 \<or>
card {s'. \<exists>a\<in>s. (s' = s - {a}) \<and> f ` s' = t - {b}} = 2"
proof (cases "{a\<in>s. f ` (s - {a}) = t - {b}} = {}")
case True
then show ?thesis
apply -
apply (rule disjI1, rule image_lemma_0)
using assms(1)
apply auto
done
next
let ?M = "{a\<in>s. f ` (s - {a}) = t - {b}}"
case False
then obtain a where "a \<in> ?M"
by auto
then have a: "a \<in> s" "f ` (s - {a}) = t - {b}"
by auto
have "f a \<in> t - {b}"
using a and assms by auto
then have "\<exists>c \<in> s - {a}. f a = f c"
unfolding image_iff[symmetric] and a
by auto
then obtain c where c: "c \<in> s" "a \<noteq> c" "f a = f c"
by auto
then have *: "f ` (s - {c}) = f ` (s - {a})"
apply -
apply (rule set_eqI)
apply rule
proof -
fix x
assume "x \<in> f ` (s - {a})"
then obtain y where y: "f y = x" "y \<in> s - {a}"
by auto
then show "x \<in> f ` (s - {c})"
unfolding image_iff
apply (rule_tac x = "if y = c then a else y" in bexI)
using c a
apply auto
done
qed auto
have "c \<in> ?M"
unfolding mem_Collect_eq and *
using a and c(1)
by auto
show ?thesis
apply (rule disjI2)
apply (rule image_lemma_0)
unfolding card_2_exists
apply (rule bexI[OF _ `a\<in>?M`])
apply (rule bexI[OF _ `c\<in>?M`])
apply rule
apply (rule `a \<noteq> c`)
apply rule
apply (unfold mem_Collect_eq)
apply (erule conjE)
proof -
fix z
assume as: "z \<in> s" "f ` (s - {z}) = t - {b}"
have inj: "inj_on f (s - {z})"
apply (rule eq_card_imp_inj_on)
unfolding as
using as(1) and assms
apply auto
done
show "z = a \<or> z = c"
proof (rule ccontr)
assume "\<not> ?thesis"
then show False
using inj[unfolded inj_on_def, THEN bspec[where x=a], THEN bspec[where x=c]]
using `a \<in> s` `c \<in> s` `f a = f c` `a \<noteq> c`
apply auto
done
qed
qed
qed
subsection {* Combine this with the basic counting lemma. *}
lemma kuhn_complete_lemma:
assumes "finite simplices"
and "\<forall>f s. face f s \<longleftrightarrow> (\<exists>a\<in>s. f = s - {a})"
and "\<forall>s\<in>simplices. card s = n + 2"
and "\<forall>s\<in>simplices. (rl ` s) \<subseteq> {0..n+1}"
and "\<forall>f\<in>{f. \<exists>s\<in>simplices. face f s}. bnd f \<longrightarrow> card {s\<in>simplices. face f s} = 1"
and "\<forall>f\<in>{f. \<exists>s\<in>simplices. face f s}. \<not> bnd f \<longrightarrow> card {s\<in>simplices. face f s} = 2"
and "odd (card {f\<in>{f. \<exists>s\<in>simplices. face f s}. rl ` f = {0..n} \<and> bnd f})"
shows "odd (card {s\<in>simplices. (rl ` s = {0..n+1})})"
apply (rule kuhn_counting_lemma)
defer
apply (rule assms)+
prefer 3
apply (rule assms)
apply (rule_tac[1-2] ballI impI)+
proof -
have *: "{f. \<exists>s\<in>simplices. \<exists>a\<in>s. f = s - {a}} = (\<Union>s\<in>simplices. {f. \<exists>a\<in>s. (f = s - {a})})"
by auto
have **: "\<forall>s\<in>simplices. card s = n + 2 \<and> finite s"
using assms(3) by (auto intro: card_ge_0_finite)
show "finite {f. \<exists>s\<in>simplices. face f s}"
unfolding assms(2)[rule_format] and *
apply (rule finite_UN_I[OF assms(1)])
using **
apply auto
done
have *: "\<And>P f s. s\<in>simplices \<Longrightarrow> (f \<in> {f. \<exists>s\<in>simplices. \<exists>a\<in>s. f = s - {a}}) \<and>
(\<exists>a\<in>s. (f = s - {a})) \<and> P f \<longleftrightarrow> (\<exists>a\<in>s. (f = s - {a}) \<and> P f)"
by auto
fix s
assume s: "s \<in> simplices"
let ?S = "{f \<in> {f. \<exists>s\<in>simplices. face f s}. face f s \<and> rl ` f = {0..n}}"
have "{0..n + 1} - {n + 1} = {0..n}"
by auto
then have S: "?S = {s'. \<exists>a\<in>s. s' = s - {a} \<and> rl ` s' = {0..n + 1} - {n + 1}}"
apply -
apply (rule set_eqI)
unfolding assms(2)[rule_format] mem_Collect_eq
unfolding *[OF s, unfolded mem_Collect_eq, where P="\<lambda>x. rl ` x = {0..n}"]
apply auto
done
show "rl ` s = {0..n+1} \<Longrightarrow> card ?S = 1" and "rl ` s \<noteq> {0..n+1} \<Longrightarrow> card ?S = 0 \<or> card ?S = 2"
unfolding S
apply (rule_tac[!] image_lemma_1 image_lemma_2)
using ** assms(4) and s
apply auto
done
qed
subsection {*We use the following notion of ordering rather than pointwise indexing. *}
definition "kle n x y \<longleftrightarrow> (\<exists>k\<subseteq>{1..n::nat}. \<forall>j. y j = x j + (if j \<in> k then (1::nat) else 0))"
lemma kle_refl [intro]: "kle n x x"
unfolding kle_def by auto
lemma kle_antisym: "kle n x y \<and> kle n y x \<longleftrightarrow> x = y"
unfolding kle_def
apply rule
apply auto
done
lemma pointwise_minimal_pointwise_maximal:
fixes s :: "(nat \<Rightarrow> nat) set"
assumes "finite s"
and "s \<noteq> {}"
and "\<forall>x\<in>s. \<forall>y\<in>s. (\<forall>j. x j \<le> y j) \<or> (\<forall>j. y j \<le> x j)"
shows "\<exists>a\<in>s. \<forall>x\<in>s. \<forall>j. a j \<le> x j"
and "\<exists>a\<in>s. \<forall>x\<in>s. \<forall>j. x j \<le> a j"
using assms
unfolding atomize_conj
proof (induct s rule: finite_induct)
fix x
fix F :: "(nat \<Rightarrow> nat) set"
assume as: "finite F" "x \<notin> F"
"\<lbrakk>F \<noteq> {}; \<forall>x\<in>F. \<forall>y\<in>F. (\<forall>j. x j \<le> y j) \<or> (\<forall>j. y j \<le> x j)\<rbrakk>
\<Longrightarrow> (\<exists>a\<in>F. \<forall>x\<in>F. \<forall>j. a j \<le> x j) \<and> (\<exists>a\<in>F. \<forall>x\<in>F. \<forall>j. x j \<le> a j)" "insert x F \<noteq> {}"
"\<forall>xa\<in>insert x F. \<forall>y\<in>insert x F. (\<forall>j. xa j \<le> y j) \<or> (\<forall>j. y j \<le> xa j)"
show "(\<exists>a\<in>insert x F. \<forall>x\<in>insert x F. \<forall>j. a j \<le> x j) \<and> (\<exists>a\<in>insert x F. \<forall>x\<in>insert x F. \<forall>j. x j \<le> a j)"
proof (cases "F = {}")
case True
then show ?thesis
apply -
apply (rule, rule_tac[!] x=x in bexI)
apply auto
done
next
case False
obtain a b where a: "a\<in>insert x F" "\<forall>x\<in>F. \<forall>j. a j \<le> x j"
and b: "b \<in> insert x F" "\<forall>x\<in>F. \<forall>j. x j \<le> b j"
using as(3)[OF False] using as(5) by auto
have "\<exists>a \<in> insert x F. \<forall>x \<in> insert x F. \<forall>j. a j \<le> x j"
using as(5)[rule_format,OF a(1) insertI1]
apply -
proof (erule disjE)
assume "\<forall>j. a j \<le> x j"
then show ?thesis
apply (rule_tac x=a in bexI)
using a
apply auto
done
next
assume "\<forall>j. x j \<le> a j"
then show ?thesis
apply (rule_tac x=x in bexI)
apply (rule, rule)
apply (insert a)
apply (erule_tac x=xa in ballE)
apply (erule_tac x=j in allE)+
apply auto
done
qed
moreover
have "\<exists>b\<in>insert x F. \<forall>x\<in>insert x F. \<forall>j. x j \<le> b j"
using as(5)[rule_format,OF b(1) insertI1]
apply -
proof (erule disjE)
assume "\<forall>j. x j \<le> b j"
then show ?thesis
apply(rule_tac x=b in bexI) using b
apply auto
done
next
assume "\<forall>j. b j \<le> x j"
then show ?thesis
apply (rule_tac x=x in bexI)
apply (rule, rule)
apply (insert b)
apply (erule_tac x=xa in ballE)
apply (erule_tac x=j in allE)+
apply auto
done
qed
ultimately show ?thesis by auto
qed
qed auto
lemma kle_imp_pointwise: "kle n x y \<Longrightarrow> \<forall>j. x j \<le> y j"
unfolding kle_def by auto
lemma pointwise_antisym:
fixes x :: "nat \<Rightarrow> nat"
shows "(\<forall>j. x j \<le> y j) \<and> (\<forall>j. y j \<le> x j) \<longleftrightarrow> x = y"
apply rule
apply (rule ext)
apply (erule conjE)
apply (erule_tac x = xa in allE)+
apply auto
done
lemma kle_trans:
assumes "kle n x y"
and "kle n y z"
and "kle n x z \<or> kle n z x"
shows "kle n x z"
using assms
apply -
apply (erule disjE)
apply assumption
proof -
case goal1
then have "x = z"
apply -
apply (rule ext)
apply (drule kle_imp_pointwise)+
apply (erule_tac x=xa in allE)+
apply auto
done
then show ?case by auto
qed
lemma kle_strict:
assumes "kle n x y"
and "x \<noteq> y"
shows "\<forall>j. x j \<le> y j"
and "\<exists>k. 1 \<le> k \<and> k \<le> n \<and> x k < y k"
apply (rule kle_imp_pointwise[OF assms(1)])
proof -
obtain k where k: "k \<subseteq> {1..n} \<and> (\<forall>j. y j = x j + (if j \<in> k then 1 else 0))"
using assms(1)[unfolded kle_def] ..
show "\<exists>k. 1 \<le> k \<and> k \<le> n \<and> x k < y k"
proof (cases "k = {}")
case True
then have "x = y"
apply -
apply (rule ext)
using k
apply auto
done
then show ?thesis
using assms(2) by auto
next
case False
then have "(SOME k'. k' \<in> k) \<in> k"
apply -
apply (rule someI_ex)
apply auto
done
then show ?thesis
apply (rule_tac x = "SOME k'. k' \<in> k" in exI)
using k
apply auto
done
qed
qed
lemma kle_minimal:
assumes "finite s"
and "s \<noteq> {}"
and "\<forall>x\<in>s. \<forall>y\<in>s. kle n x y \<or> kle n y x"
shows "\<exists>a\<in>s. \<forall>x\<in>s. kle n a x"
proof -
have "\<exists>a\<in>s. \<forall>x\<in>s. \<forall>j. a j \<le> x j"
apply (rule pointwise_minimal_pointwise_maximal(1)[OF assms(1-2)])
apply rule
apply rule
apply (drule_tac assms(3)[rule_format])
apply assumption
using kle_imp_pointwise
apply auto
done
then obtain a where a: "a \<in> s" "\<forall>x\<in>s. \<forall>j. a j \<le> x j" ..
show ?thesis
apply (rule_tac x = a in bexI)
proof
fix x
assume "x \<in> s"
show "kle n a x"
using assms(3)[rule_format,OF a(1) `x\<in>s`]
apply -
proof (erule disjE)
assume "kle n x a"
then have "x = a"
apply -
unfolding pointwise_antisym[symmetric]
apply (drule kle_imp_pointwise)
using a(2)[rule_format,OF `x\<in>s`]
apply auto
done
then show ?thesis using kle_refl by auto
qed
qed (insert a, auto)
qed
lemma kle_maximal:
assumes "finite s"
and "s \<noteq> {}"
and "\<forall>x\<in>s. \<forall>y\<in>s. kle n x y \<or> kle n y x"
shows "\<exists>a\<in>s. \<forall>x\<in>s. kle n x a"
proof -
have "\<exists>a\<in>s. \<forall>x\<in>s. \<forall>j. a j \<ge> x j"
apply (rule pointwise_minimal_pointwise_maximal(2)[OF assms(1-2)])
apply rule
apply rule
apply (drule_tac assms(3)[rule_format],assumption)
using kle_imp_pointwise
apply auto
done
then obtain a where a: "a \<in> s" "\<forall>x\<in>s. \<forall>j. x j \<le> a j" ..
show ?thesis
apply (rule_tac x = a in bexI)
proof
fix x
assume "x \<in> s"
show "kle n x a"
using assms(3)[rule_format,OF a(1) `x\<in>s`]
apply -
proof (erule disjE)
assume "kle n a x"
then have "x = a"
apply -
unfolding pointwise_antisym[symmetric]
apply (drule kle_imp_pointwise)
using a(2)[rule_format,OF `x\<in>s`]
apply auto
done
then show ?thesis
using kle_refl by auto
qed
qed (insert a, auto)
qed
lemma kle_strict_set:
assumes "kle n x y"
and "x \<noteq> y"
shows "1 \<le> card {k\<in>{1..n}. x k < y k}"
proof -
obtain i where "1 \<le> i" "i \<le> n" "x i < y i"
using kle_strict(2)[OF assms] by blast
then have "card {i} \<le> card {k\<in>{1..n}. x k < y k}"
apply -
apply (rule card_mono)
apply auto
done
then show ?thesis
by auto
qed
lemma kle_range_combine:
assumes "kle n x y"
and "kle n y z"
and "kle n x z \<or> kle n z x"
and "m1 \<le> card {k\<in>{1..n}. x k < y k}"
and "m2 \<le> card {k\<in>{1..n}. y k < z k}"
shows "kle n x z \<and> m1 + m2 \<le> card {k\<in>{1..n}. x k < z k}"
apply rule
apply (rule kle_trans[OF assms(1-3)])
proof -
have "\<And>j. x j < y j \<Longrightarrow> x j < z j"
apply (rule less_le_trans)
using kle_imp_pointwise[OF assms(2)]
apply auto
done
moreover
have "\<And>j. y j < z j \<Longrightarrow> x j < z j"
apply (rule le_less_trans)
using kle_imp_pointwise[OF assms(1)]
apply auto
done
ultimately
have *: "{k\<in>{1..n}. x k < y k} \<union> {k\<in>{1..n}. y k < z k} = {k\<in>{1..n}. x k < z k}"
by auto
have **: "{k \<in> {1..n}. x k < y k} \<inter> {k \<in> {1..n}. y k < z k} = {}"
unfolding disjoint_iff_not_equal
apply rule
apply rule
apply (unfold mem_Collect_eq)
apply (rule notI)
apply (erule conjE)+
proof -
fix i j
assume as: "i \<in> {1..n}" "x i < y i" "j \<in> {1..n}" "y j < z j" "i = j"
obtain kx where kx: "kx \<subseteq> {1..n} \<and> (\<forall>j. y j = x j + (if j \<in> kx then 1 else 0))"
using assms(1)[unfolded kle_def] ..
have "x i < y i"
using as by auto
then have "i \<in> kx"
using as(1) kx
apply -
apply (rule ccontr)
apply auto
done
then have "x i + 1 = y i"
using kx by auto
moreover
obtain ky where ky: "ky \<subseteq> {1..n} \<and> (\<forall>j. z j = y j + (if j \<in> ky then 1 else 0))"
using assms(2)[unfolded kle_def] ..
have "y i < z i"
using as by auto
then have "i \<in> ky"
using as(1) ky
apply -
apply (rule ccontr)
apply auto
done
then have "y i + 1 = z i"
using ky by auto
ultimately
have "z i = x i + 2"
by auto
then show False
using assms(3)
unfolding kle_def
by (auto simp add: split_if_eq1)
qed
have fin: "\<And>P. finite {x\<in>{1..n::nat}. P x}"
by auto
have "m1 + m2 \<le> card {k\<in>{1..n}. x k < y k} + card {k\<in>{1..n}. y k < z k}"
using assms(4-5) by auto
also have "\<dots> \<le> card {k\<in>{1..n}. x k < z k}"
unfolding card_Un_Int[OF fin fin]
unfolding * **
by auto
finally show "m1 + m2 \<le> card {k \<in> {1..n}. x k < z k}"
by auto
qed
lemma kle_range_combine_l:
assumes "kle n x y"
and "kle n y z"
and "kle n x z \<or> kle n z x"
and "m \<le> card {k\<in>{1..n}. y(k) < z(k)}"
shows "kle n x z \<and> m \<le> card {k\<in>{1..n}. x(k) < z(k)}"
using kle_range_combine[OF assms(1-3) _ assms(4), of 0] by auto
lemma kle_range_combine_r:
assumes "kle n x y"
and "kle n y z"
and "kle n x z \<or> kle n z x" "m \<le> card {k\<in>{1..n}. x k < y k}"
shows "kle n x z \<and> m \<le> card {k\<in>{1..n}. x(k) < z(k)}"
using kle_range_combine[OF assms(1-3) assms(4), of 0] by auto
lemma kle_range_induct:
assumes "card s = Suc m"
and "\<forall>x\<in>s. \<forall>y\<in>s. kle n x y \<or> kle n y x"
shows "\<exists>x\<in>s. \<exists>y\<in>s. kle n x y \<and> m \<le> card {k\<in>{1..n}. x k < y k}"
proof -
have "finite s" and "s \<noteq> {}"
using assms(1)
by (auto intro: card_ge_0_finite)
then show ?thesis
using assms
proof (induct m arbitrary: s)
case 0
then show ?case
using kle_refl by auto
next
case (Suc m)
then obtain a where a: "a \<in> s" "\<forall>x\<in>s. kle n a x"
using kle_minimal[of s n] by auto
show ?case
proof (cases "s \<subseteq> {a}")
case False
then have "card (s - {a}) = Suc m" and "s - {a} \<noteq> {}"
using card_Diff_singleton[OF _ a(1)] Suc(4) `finite s`
by auto
then obtain x b where xb:
"x \<in> s - {a}"
"b \<in> s - {a}"
"kle n x b"
"m \<le> card {k \<in> {1..n}. x k < b k}"
using Suc(1)[of "s - {a}"]
using Suc(5) `finite s`
by auto
have "1 \<le> card {k \<in> {1..n}. a k < x k}" and "m \<le> card {k \<in> {1..n}. x k < b k}"
apply (rule kle_strict_set)
apply (rule a(2)[rule_format])
using a and xb
apply auto
done
then show ?thesis
apply (rule_tac x=a in bexI)
apply (rule_tac x=b in bexI)
using kle_range_combine[OF a(2)[rule_format] xb(3) Suc(5)[rule_format], of 1 "m"]
using a(1) xb(1-2)
apply auto
done
next
case True
then have "s = {a}"
using Suc(3) by auto
then have "card s = 1"
by auto
then have False
using Suc(4) `finite s` by auto
then show ?thesis
by auto
qed
qed
qed
lemma kle_Suc: "kle n x y \<Longrightarrow> kle (n + 1) x y"
unfolding kle_def
apply (erule exE)
apply (rule_tac x=k in exI)
apply auto
done
lemma kle_trans_1:
assumes "kle n x y"
shows "x j \<le> y j"
and "y j \<le> x j + 1"
using assms[unfolded kle_def] by auto
lemma kle_trans_2:
assumes "kle n a b"
and "kle n b c"
and "\<forall>j. c j \<le> a j + 1"
shows "kle n a c"
proof -
obtain kk1 where kk1: "kk1 \<subseteq> {1..n} \<and> (\<forall>j. b j = a j + (if j \<in> kk1 then 1 else 0))"
using assms(1)[unfolded kle_def] ..
obtain kk2 where kk2: "kk2 \<subseteq> {1..n} \<and> (\<forall>j. c j = b j + (if j \<in> kk2 then 1 else 0))"
using assms(2)[unfolded kle_def] ..
show ?thesis
unfolding kle_def
apply (rule_tac x="kk1 \<union> kk2" in exI)
apply rule
defer
proof
fix i
show "c i = a i + (if i \<in> kk1 \<union> kk2 then 1 else 0)"
proof (cases "i \<in> kk1 \<union> kk2")
case True
then have "c i \<ge> a i + (if i \<in> kk1 \<union> kk2 then 1 else 0)"
unfolding kk1[THEN conjunct2,rule_format,of i] kk2[THEN conjunct2,rule_format,of i]
by auto
moreover
have "c i \<le> a i + (if i \<in> kk1 \<union> kk2 then 1 else 0)"
using True assms(3) by auto
ultimately show ?thesis by auto
next
case False
then show ?thesis
using kk1 kk2 by auto
qed
qed (insert kk1 kk2, auto)
qed
lemma kle_between_r:
assumes "kle n a b"
and "kle n b c"
and "kle n a x"
and "kle n c x"
shows "kle n b x"
apply (rule kle_trans_2[OF assms(2,4)])
proof
have *: "\<And>c b x::nat. x \<le> c + 1 \<Longrightarrow> c \<le> b \<Longrightarrow> x \<le> b + 1"
by auto
fix j
show "x j \<le> b j + 1"
apply (rule *)
using kle_trans_1[OF assms(1),of j] kle_trans_1[OF assms(3), of j]
apply auto
done
qed
lemma kle_between_l:
assumes "kle n a b"
and "kle n b c"
and "kle n x a"
and "kle n x c"
shows "kle n x b"
apply (rule kle_trans_2[OF assms(3,1)])
proof
have *: "\<And>c b x::nat. c \<le> x + 1 \<Longrightarrow> b \<le> c \<Longrightarrow> b \<le> x + 1"
by auto
fix j
show "b j \<le> x j + 1"
apply (rule *)
using kle_trans_1[OF assms(2),of j] kle_trans_1[OF assms(4), of j]
apply auto
done
qed
lemma kle_adjacent:
assumes "\<forall>j. b j = (if j = k then a(j) + 1 else a j)"
and "kle n a x"
and "kle n x b"
shows "x = a \<or> x = b"
proof (cases "x k = a k")
case True
show ?thesis
apply (rule disjI1)
apply (rule ext)
proof -
fix j
have "x j \<le> a j"
using kle_imp_pointwise[OF assms(3),THEN spec[where x=j]]
unfolding assms(1)[rule_format]
apply -
apply(cases "j = k")
using True
apply auto
done
then show "x j = a j"
using kle_imp_pointwise[OF assms(2),THEN spec[where x=j]]
by auto
qed
next
case False
show ?thesis
apply (rule disjI2)
apply (rule ext)
proof -
fix j
have "x j \<ge> b j"
using kle_imp_pointwise[OF assms(2),THEN spec[where x=j]]
unfolding assms(1)[rule_format]
apply -
apply (cases "j = k")
using False
apply auto
done
then show "x j = b j"
using kle_imp_pointwise[OF assms(3),THEN spec[where x=j]]
by auto
qed
qed
subsection {* Kuhn's notion of a simplex (a reformulation to avoid so much indexing) *}
definition "ksimplex p n (s::(nat \<Rightarrow> nat) set) \<longleftrightarrow>
card s = n + 1 \<and>
(\<forall>x\<in>s. \<forall>j. x j \<le> p) \<and>
(\<forall>x\<in>s. \<forall>j. j \<notin> {1..n} \<longrightarrow> x j = p) \<and>
(\<forall>x\<in>s. \<forall>y\<in>s. kle n x y \<or> kle n y x)"
lemma ksimplexI:
"card s = n + 1 \<Longrightarrow>
\<forall>x\<in>s. \<forall>j. x j \<le> p \<Longrightarrow>
\<forall>x\<in>s. \<forall>j. j \<notin> {1..n} \<longrightarrow> x j = p \<Longrightarrow>
\<forall>x\<in>s. \<forall>y\<in>s. kle n x y \<or> kle n y x \<Longrightarrow>
ksimplex p n s"
unfolding ksimplex_def by auto
lemma ksimplex_eq:
"ksimplex p n (s::(nat \<Rightarrow> nat) set) \<longleftrightarrow>
card s = n + 1 \<and>
finite s \<and>
(\<forall>x\<in>s. \<forall>j. x(j) \<le> p) \<and>
(\<forall>x\<in>s. \<forall>j. j\<notin>{1..n} \<longrightarrow> x j = p) \<and>
(\<forall>x\<in>s. \<forall>y\<in>s. kle n x y \<or> kle n y x)"
unfolding ksimplex_def by (auto intro: card_ge_0_finite)
lemma ksimplex_extrema:
assumes "ksimplex p n s"
obtains a b where "a \<in> s"
and "b \<in> s"
and "\<forall>x\<in>s. kle n a x \<and> kle n x b"
and "\<forall>i. b i = (if i \<in> {1..n} then a i + 1 else a i)"
proof (cases "n = 0")
case True
obtain x where *: "s = {x}"
using assms[unfolded ksimplex_eq True,THEN conjunct1]
unfolding add_0_left card_1_exists
by auto
show ?thesis
apply (rule that[of x x])
unfolding * True
apply auto
done
next
note assm = assms[unfolded ksimplex_eq]
case False
have "s \<noteq> {}"
using assm by auto
obtain a where a: "a \<in> s" "\<forall>x\<in>s. kle n a x"
using `s \<noteq> {}` assm
using kle_minimal[of s n]
by auto
obtain b where b: "b \<in> s" "\<forall>x\<in>s. kle n x b"
using `s \<noteq> {}` assm
using kle_maximal[of s n]
by auto
obtain c d where c_d: "c \<in> s" "d \<in> s" "kle n c d" "n \<le> card {k \<in> {1..n}. c k < d k}"
using kle_range_induct[of s n n]
using assm
by auto
have "kle n c b \<and> n \<le> card {k \<in> {1..n}. c k < b k}"
apply (rule kle_range_combine_r[where y=d])
using c_d a b
apply auto
done
then have "kle n a b \<and> n \<le> card {k\<in>{1..n}. a(k) < b(k)}"
apply -
apply (rule kle_range_combine_l[where y=c])
using a `c \<in> s` `b \<in> s`
apply auto
done
moreover
have "card {1..n} \<ge> card {k\<in>{1..n}. a(k) < b(k)}"
by (rule card_mono) auto
ultimately
have *: "{k\<in>{1 .. n}. a k < b k} = {1..n}"
apply -
apply (rule card_subset_eq)
apply auto
done
show ?thesis
apply (rule that[OF a(1) b(1)])
defer
apply (subst *[symmetric])
unfolding mem_Collect_eq
proof
obtain k where k: "k \<subseteq> {1..n} \<and> (\<forall>j. b j = a j + (if j \<in> k then 1 else 0))"
using a(2)[rule_format, OF b(1), unfolded kle_def] ..
fix i
show "b i = (if i \<in> {1..n} \<and> a i < b i then a i + 1 else a i)"
proof (cases "i \<in> {1..n}")
case True
then show ?thesis
unfolding k[THEN conjunct2,rule_format] by auto
next
case False
have "a i = p"
using assm and False `a\<in>s` by auto
moreover have "b i = p"
using assm and False `b\<in>s` by auto
ultimately show ?thesis
by auto
qed
qed (insert a(2) b(2) assm, auto)
qed
lemma ksimplex_extrema_strong:
assumes "ksimplex p n s"
and "n \<noteq> 0"
obtains a b where "a \<in> s"
and "b \<in> s"
and "a \<noteq> b"
and "\<forall>x\<in>s. kle n a x \<and> kle n x b"
and "\<forall>i. b i = (if i \<in> {1..n} then a(i) + 1 else a i)"
proof -
obtain a b where ab: "a \<in> s" "b \<in> s"
"\<forall>x\<in>s. kle n a x \<and> kle n x b" "\<forall>i. b(i) = (if i \<in> {1..n} then a(i) + 1 else a(i))"
apply (rule ksimplex_extrema[OF assms(1)])
apply auto
done
have "a \<noteq> b"
apply (rule notI)
apply (drule cong[of _ _ 1 1])
using ab(4) assms(2)
apply auto
done
then show ?thesis
apply (rule_tac that[of a b])
using ab
apply auto
done
qed
lemma ksimplexD:
assumes "ksimplex p n s"
shows "card s = n + 1"
and "finite s"
and "card s = n + 1"
and "\<forall>x\<in>s. \<forall>j. x j \<le> p"
and "\<forall>x\<in>s. \<forall>j. j \<notin> {1..n} \<longrightarrow> x j = p"
and "\<forall>x\<in>s. \<forall>y\<in>s. kle n x y \<or> kle n y x"
using assms unfolding ksimplex_eq by auto
lemma ksimplex_successor:
assumes "ksimplex p n s"
and "a \<in> s"
shows "(\<forall>x\<in>s. kle n x a) \<or> (\<exists>y\<in>s. \<exists>k\<in>{1..n}. \<forall>j. y j = (if j = k then a j + 1 else a j))"
proof (cases "\<forall>x\<in>s. kle n x a")
case True
then show ?thesis by auto
next
note assm = ksimplexD[OF assms(1)]
case False
then obtain b where b: "b \<in> s" "\<not> kle n b a" "\<forall>x\<in>{x \<in> s. \<not> kle n x a}. kle n b x"
using kle_minimal[of "{x\<in>s. \<not> kle n x a}" n] and assm
by auto
then have **: "1 \<le> card {k\<in>{1..n}. a k < b k}"
apply -
apply (rule kle_strict_set)
using assm(6) and `a\<in>s`
apply (auto simp add: kle_refl)
done
let ?kle1 = "{x \<in> s. \<not> kle n x a}"
have "card ?kle1 > 0"
apply (rule ccontr)
using assm(2) and False
apply auto
done
then have sizekle1: "card ?kle1 = Suc (card ?kle1 - 1)"
using assm(2) by auto
obtain c d where c_d: "c \<in> s" "\<not> kle n c a" "d \<in> s" "\<not> kle n d a"
"kle n c d" "card ?kle1 - 1 \<le> card {k \<in> {1..n}. c k < d k}"
using kle_range_induct[OF sizekle1, of n] using assm by auto
let ?kle2 = "{x \<in> s. kle n x a}"
have "card ?kle2 > 0"
apply (rule ccontr)
using assm(6)[rule_format,of a a] and `a\<in>s` and assm(2)
apply auto
done
then have sizekle2: "card ?kle2 = Suc (card ?kle2 - 1)"
using assm(2) by auto
obtain e f where e_f: "e \<in> s" "kle n e a" "f \<in> s" "kle n f a"
"kle n e f" "card ?kle2 - 1 \<le> card {k \<in> {1..n}. e k < f k}"
using kle_range_induct[OF sizekle2, of n]
using assm
by auto
have "card {k\<in>{1..n}. a k < b k} = 1"
proof (rule ccontr)
assume "\<not> ?thesis"
then have as: "card {k\<in>{1..n}. a k < b k} \<ge> 2"
using ** by auto
have *: "finite ?kle2" "finite ?kle1" "?kle2 \<union> ?kle1 = s" "?kle2 \<inter> ?kle1 = {}"
using assm(2) by auto
have "(card ?kle2 - 1) + 2 + (card ?kle1 - 1) = card ?kle2 + card ?kle1"
using sizekle1 sizekle2 by auto
also have "\<dots> = n + 1"
unfolding card_Un_Int[OF *(1-2)] *(3-)
using assm(3)
by auto
finally have n: "(card ?kle2 - 1) + (2 + (card ?kle1 - 1)) = n + 1"
by auto
have "kle n e a \<and> card {x \<in> s. kle n x a} - 1 \<le> card {k \<in> {1..n}. e k < a k}"
apply (rule kle_range_combine_r[where y=f])
using e_f using `a \<in> s` assm(6)
apply auto
done
moreover have "kle n b d \<and> card {x \<in> s. \<not> kle n x a} - 1 \<le> card {k \<in> {1..n}. b k < d k}"
apply (rule kle_range_combine_l[where y=c])
using c_d using assm(6) and b
apply auto
done
then have "kle n a d \<and> 2 + (card {x \<in> s. \<not> kle n x a} - 1) \<le> card {k \<in> {1..n}. a k < d k}"
apply -
apply (rule kle_range_combine[where y=b]) using as and b assm(6) `a \<in> s` `d \<in> s`
apply blast+
done
ultimately
have "kle n e d \<and> (card ?kle2 - 1) + (2 + (card ?kle1 - 1)) \<le> card {k\<in>{1..n}. e k < d k}"
apply -
apply (rule kle_range_combine[where y=a]) using assm(6)[rule_format, OF `e \<in> s` `d \<in> s`]
apply blast+
done
moreover have "card {k \<in> {1..n}. e k < d k} \<le> card {1..n}"
by (rule card_mono) auto
ultimately show False
unfolding n by auto
qed
then obtain k where k:
"k \<in> {1..n} \<and> a k < b k"
"\<And>y y'. (y \<in> {1..n} \<and> a y < b y) \<and> y' \<in> {1..n} \<and> a y' < b y' \<Longrightarrow> y = y'"
unfolding card_1_exists by blast
show ?thesis
apply (rule disjI2)
apply (rule_tac x=b in bexI)
apply (rule_tac x=k in bexI)
proof
fix j :: nat
have "kle n a b"
using b and assm(6)[rule_format, OF `a\<in>s` `b\<in>s`]
by auto
then obtain kk where kk: "kk \<subseteq> {1..n}" "\<And>j. b j = a j + (if j \<in> kk then 1 else 0)"
unfolding kle_def by blast
have kkk: "k \<in> kk"
apply (rule ccontr)
using k(1)
unfolding kk(2)
apply auto
done
show "b j = (if j = k then a j + 1 else a j)"
proof (cases "j \<in> kk")
case True
then have "j = k"
apply -
apply (rule k(2))
using kk kkk
apply auto
done
then show ?thesis
unfolding kk(2) using kkk by auto
next
case False
then have "j \<noteq> k"
using k(2)[of j k] and kkk
by auto
then show ?thesis
unfolding kk(2)
using kkk and False
by auto
qed
qed (insert k(1) `b \<in> s`, auto)
qed
lemma ksimplex_predecessor:
assumes "ksimplex p n s"
and "a \<in> s"
shows "(\<forall>x\<in>s. kle n a x) \<or> (\<exists>y\<in>s. \<exists>k\<in>{1..n}. \<forall>j. a j = (if j = k then y j + 1 else y j))"
proof (cases "\<forall>x\<in>s. kle n a x")
case True
then show ?thesis by auto
next
note assm = ksimplexD[OF assms(1)]
case False
then obtain b where b: "b \<in> s" "\<not> kle n a b" "\<forall>x\<in>{x \<in> s. \<not> kle n a x}. kle n x b"
using kle_maximal[of "{x\<in>s. \<not> kle n a x}" n] and assm
by auto
then have **: "1 \<le> card {k\<in>{1..n}. a k > b k}"
apply -
apply (rule kle_strict_set)
using assm(6) and `a \<in> s`
apply (auto simp add: kle_refl)
done
let ?kle1 = "{x \<in> s. \<not> kle n a x}"
have "card ?kle1 > 0"
apply (rule ccontr)
using assm(2) and False
apply auto
done
then have sizekle1: "card ?kle1 = Suc (card ?kle1 - 1)"
using assm(2) by auto
obtain c d where c_d: "c \<in> s" "\<not> kle n a c" "d \<in> s" "\<not> kle n a d"
"kle n d c" "card ?kle1 - 1 \<le> card {k \<in> {1..n}. c k > d k}"
using kle_range_induct[OF sizekle1, of n]
using assm
by auto
let ?kle2 = "{x \<in> s. kle n a x}"
have "card ?kle2 > 0"
apply (rule ccontr)
using assm(6)[rule_format,of a a] and `a \<in> s` and assm(2)
apply auto
done
then have sizekle2: "card ?kle2 = Suc (card ?kle2 - 1)"
using assm(2)
by auto
obtain e f where e_f: "e \<in> s" "kle n a e" "f \<in> s" "kle n a f"
"kle n f e" "card ?kle2 - 1 \<le> card {k \<in> {1..n}. e k > f k}"
using kle_range_induct[OF sizekle2, of n]
using assm
by auto
have "card {k\<in>{1..n}. a k > b k} = 1"
proof (rule ccontr)
assume "\<not> ?thesis"
then have as: "card {k\<in>{1..n}. a k > b k} \<ge> 2"
using ** by auto
have *: "finite ?kle2" "finite ?kle1" "?kle2 \<union> ?kle1 = s" "?kle2 \<inter> ?kle1 = {}"
using assm(2) by auto
have "(card ?kle2 - 1) + 2 + (card ?kle1 - 1) = card ?kle2 + card ?kle1"
using sizekle1 sizekle2 by auto
also have "\<dots> = n + 1"
unfolding card_Un_Int[OF *(1-2)] *(3-)
using assm(3) by auto
finally have n: "(card ?kle1 - 1) + 2 + (card ?kle2 - 1) = n + 1"
by auto
have "kle n a e \<and> card {x \<in> s. kle n a x} - 1 \<le> card {k \<in> {1..n}. e k > a k}"
apply (rule kle_range_combine_l[where y=f])
using e_f and `a\<in>s` assm(6)
apply auto
done
moreover have "kle n d b \<and> card {x \<in> s. \<not> kle n a x} - 1 \<le> card {k \<in> {1..n}. b k > d k}"
apply (rule kle_range_combine_r[where y=c])
using c_d and assm(6) and b
apply auto
done
then have "kle n d a \<and> (card {x \<in> s. \<not> kle n a x} - 1) + 2 \<le> card {k \<in> {1..n}. a k > d k}"
apply -
apply (rule kle_range_combine[where y=b]) using as and b assm(6) `a \<in> s` `d \<in> s`
apply blast+
done
ultimately have "kle n d e \<and> (card ?kle1 - 1 + 2) + (card ?kle2 - 1) \<le> card {k\<in>{1..n}. e k > d k}"
apply -
apply (rule kle_range_combine[where y=a])
using assm(6)[rule_format,OF `e\<in>s` `d\<in>s`]
apply blast+
done
moreover have "card {k \<in> {1..n}. e k > d k} \<le> card {1..n}"
by (rule card_mono) auto
ultimately show False
unfolding n by auto
qed
then obtain k where k:
"k \<in> {1..n} \<and> b k < a k"
"\<And>y y'. (y \<in> {1..n} \<and> b y < a y) \<and> y' \<in> {1..n} \<and> b y' < a y' \<Longrightarrow> y = y'"
unfolding card_1_exists by blast
show ?thesis
apply (rule disjI2)
apply (rule_tac x=b in bexI)
apply (rule_tac x=k in bexI)
proof
fix j :: nat
have "kle n b a"
using b and assm(6)[rule_format, OF `a\<in>s` `b\<in>s`] by auto
then obtain kk where kk: "kk \<subseteq> {1..n}" "\<And>j. a j = b j + (if j \<in> kk then 1 else 0)"
unfolding kle_def by blast
have kkk: "k \<in> kk"
apply (rule ccontr)
using k(1)
unfolding kk(2)
apply auto
done
show "a j = (if j = k then b j + 1 else b j)"
proof (cases "j \<in> kk")
case True
then have "j = k"
apply -
apply (rule k(2))
using kk kkk
apply auto
done
then show ?thesis
unfolding kk(2) using kkk by auto
next
case False
then have "j \<noteq> k"
using k(2)[of j k]
using kkk
by auto
then show ?thesis
unfolding kk(2)
using kkk and False
by auto
qed
qed (insert k(1) `b\<in>s`, auto)
qed
subsection {* The lemmas about simplices that we need. *}
(* FIXME: These are clones of lemmas in Library/FuncSet *)
lemma card_funspace':
assumes "finite s"
and "finite t"
and "card s = m"
and "card t = n"
shows "card {f. (\<forall>x\<in>s. f x \<in> t) \<and> (\<forall>x\<in>UNIV - s. f x = d)} = n ^ m"
(is "card (?M s) = _")
using assms
proof (induct m arbitrary: s)
case 0
have [simp]: "{f. \<forall>x. f x = d} = {\<lambda>x. d}"
apply (rule set_eqI)
apply rule
unfolding mem_Collect_eq
apply rule
apply (rule ext)
apply auto
done
from 0 show ?case
by auto
next
case (Suc m)
obtain a s0 where as0:
"s = insert a s0"
"a \<notin> s0"
"card s0 = m"
"m = 0 \<longrightarrow> s0 = {}"
using card_eq_SucD[OF Suc(4)] by auto
have **: "card s0 = m"
using as0 using Suc(2) Suc(4)
by auto
let ?l = "(\<lambda>(b, g) x. if x = a then b else g x)"
have *: "?M (insert a s0) = ?l ` {(b,g). b\<in>t \<and> g\<in>?M s0}"
apply (rule set_eqI, rule)
unfolding mem_Collect_eq image_iff
apply (erule conjE)
apply (rule_tac x="(x a, \<lambda>y. if y\<in>s0 then x y else d)" in bexI)
apply (rule ext)
prefer 3
apply rule
defer
apply (erule bexE)
apply rule
unfolding mem_Collect_eq
apply (erule splitE)+
apply (erule conjE)+
proof -
fix x xa xb xc y
assume as:
"x = (\<lambda>(b, g) x. if x = a then b else g x) xa"
"xb \<in> UNIV - insert a s0"
"xa = (xc, y)"
"xc \<in> t"
"\<forall>x\<in>s0. y x \<in> t"
"\<forall>x\<in>UNIV - s0. y x = d"
then show "x xb = d"
unfolding as by auto
qed auto
have inj: "inj_on ?l {(b,g). b\<in>t \<and> g\<in>?M s0}"
unfolding inj_on_def
apply rule
apply rule
apply rule
unfolding mem_Collect_eq
apply (erule splitE conjE)+
proof -
case goal1 note as = this(1,4-)[unfolded goal1 split_conv]
have "xa = xb"
using as(1)[THEN cong[of _ _ a]] by auto
moreover have "ya = yb"
proof (rule ext)
fix x
show "ya x = yb x"
proof (cases "x = a")
case False
then show ?thesis
using as(1)[THEN cong[of _ _ x x]] by auto
next
case True
then show ?thesis
using as(5,7) using as0(2) by auto
qed
qed
ultimately show ?case
unfolding goal1 by auto
qed
have "finite s0"
using `finite s` unfolding as0 by simp
show ?case
unfolding as0 * card_image[OF inj]
using assms
unfolding SetCompr_Sigma_eq
unfolding card_cartesian_product
using Suc(1)[OF `finite s0` `finite t` ** `card t = n`]
by auto
qed
lemma card_funspace:
assumes "finite s"
and "finite t"
shows "card {f. (\<forall>x\<in>s. f x \<in> t) \<and> (\<forall>x\<in>UNIV - s. f x = d)} = card t ^ card s"
using assms by (auto intro: card_funspace')
lemma finite_funspace:
assumes "finite s"
and "finite t"
shows "finite {f. (\<forall>x\<in>s. f x \<in> t) \<and> (\<forall>x\<in>UNIV - s. f x = d)}"
(is "finite ?S")
proof (cases "card t > 0")
case True
have "card ?S = card t ^ card s"
using assms by (auto intro!: card_funspace)
then show ?thesis
using True by (rule_tac card_ge_0_finite) simp
next
case False
then have "t = {}"
using `finite t` by auto
show ?thesis
proof (cases "s = {}")
case True
have *: "{f. \<forall>x. f x = d} = {\<lambda>x. d}"
by auto
from True show ?thesis
using `t = {}` by (auto simp: *)
next
case False
then show ?thesis
using `t = {}` by simp
qed
qed
lemma finite_simplices: "finite {s. ksimplex p n s}"
apply (rule finite_subset[of _ "{s. s\<subseteq>{f. (\<forall>i\<in>{1..n}. f i \<in> {0..p}) \<and> (\<forall>i\<in>UNIV-{1..n}. f i = p)}}"])
unfolding ksimplex_def
defer
apply (rule finite_Collect_subsets)
apply (rule finite_funspace)
apply auto
done
lemma simplex_top_face:
assumes "0 < p"
and "\<forall>x\<in>f. x (n + 1) = p"
shows "(\<exists>s a. ksimplex p (n + 1) s \<and> a \<in> s \<and> (f = s - {a})) \<longleftrightarrow> ksimplex p n f"
(is "?ls = ?rs")
proof
assume ?ls
then obtain s a where sa:
"ksimplex p (n + 1) s"
"a \<in> s"
"f = s - {a}"
by auto
show ?rs
unfolding ksimplex_def sa(3)
apply rule
defer
apply rule
defer
apply (rule, rule, rule, rule)
defer
apply (rule, rule)
proof -
fix x y
assume as: "x \<in>s - {a}" "y \<in>s - {a}"
have xyp: "x (n + 1) = y (n + 1)"
using as(1)[unfolded sa(3)[symmetric], THEN assms(2)[rule_format]]
using as(2)[unfolded sa(3)[symmetric], THEN assms(2)[rule_format]]
by auto
show "kle n x y \<or> kle n y x"
proof (cases "kle (n + 1) x y")
case True
then obtain k where k: "k \<subseteq> {1..n + 1}" "\<And>j. y j = x j + (if j \<in> k then 1 else 0)"
unfolding kle_def by blast
then have *: "n + 1 \<notin> k" using xyp by auto
have "\<not> (\<exists>x\<in>k. x \<notin> {1..n})"
apply (rule notI)
apply (erule bexE)
proof -
fix x
assume as: "x \<in> k" "x \<notin> {1..n}"
have "x \<noteq> n + 1"
using as and * by auto
then show False
using as and k(1) by auto
qed
then show ?thesis
apply -
apply (rule disjI1)
unfolding kle_def
using k(2)
apply (rule_tac x=k in exI)
apply auto
done
next
case False
then have "kle (n + 1) y x"
using ksimplexD(6)[OF sa(1),rule_format, of x y] and as
by auto
then obtain k where k: "k \<subseteq> {1..n + 1}" "\<And>j. x j = y j + (if j \<in> k then 1 else 0)"
unfolding kle_def by auto
then have *: "n + 1 \<notin> k"
using xyp by auto
then have "\<not> (\<exists>x\<in>k. x \<notin> {1..n})"
apply -
apply (rule notI)
apply (erule bexE)
proof -
fix x
assume as: "x \<in> k" "x \<notin> {1..n}"
have "x \<noteq> n + 1"
using as and * by auto
then show False
using as and k(1)
by auto
qed
then show ?thesis
apply -
apply (rule disjI2)
unfolding kle_def
using k(2)
apply (rule_tac x = k in exI)
apply auto
done
qed
next
fix x j
assume as: "x \<in> s - {a}" "j \<notin> {1..n}"
then show "x j = p"
using as(1)[unfolded sa(3)[symmetric], THEN assms(2)[rule_format]]
apply (cases "j = n + 1")
using sa(1)[unfolded ksimplex_def]
apply auto
done
qed (insert sa ksimplexD[OF sa(1)], auto)
next
assume ?rs note rs=ksimplexD[OF this]
obtain a b where ab:
"a \<in> f"
"b \<in> f"
"\<forall>x\<in>f. kle n a x \<and> kle n x b"
"\<forall>i. b i = (if i \<in> {1..n} then a i + 1 else a i)"
by (rule ksimplex_extrema[OF `?rs`])
def c \<equiv> "\<lambda>i. if i = (n + 1) then p - 1 else a i"
have "c \<notin> f"
apply (rule notI)
apply (drule assms(2)[rule_format])
unfolding c_def
using assms(1)
apply auto
done
then show ?ls
apply (rule_tac x = "insert c f" in exI)
apply (rule_tac x = c in exI)
unfolding ksimplex_def conj_assoc
apply (rule conjI)
defer
apply (rule conjI)
defer
apply (rule conjI)
defer
apply (rule conjI)
defer
proof (rule_tac[3-5] ballI allI)+
fix x j
assume x: "x \<in> insert c f"
then show "x j \<le> p"
proof (cases "x = c")
case True
show ?thesis
unfolding True c_def
apply (cases "j = n + 1")
using ab(1) and rs(4)
apply auto
done
next
case False
with insert x rs(4) show ?thesis
by (auto simp add: c_def)
qed
show "j \<notin> {1..n + 1} \<longrightarrow> x j = p"
apply (cases "x = c")
using x ab(1) rs(5)
unfolding c_def
apply auto
done
{
fix z
assume z: "z \<in> insert c f"
then have "kle (n + 1) c z"
proof (cases "z = c")
case False
then have "z \<in> f"
using z by auto
with ab(3) have "kle n a z" by blast
then obtain k where "k \<subseteq> {1..n}" "\<And>j. z j = a j + (if j \<in> k then 1 else 0)"
unfolding kle_def by blast
then show "kle (n + 1) c z"
unfolding kle_def
apply (rule_tac x="insert (n + 1) k" in exI)
unfolding c_def
using ab
using rs(5)[rule_format,OF ab(1),of "n + 1"] assms(1)
apply auto
done
next
case True
then show ?thesis by auto
qed
} note * = this
fix y
assume y: "y \<in> insert c f"
show "kle (n + 1) x y \<or> kle (n + 1) y x"
proof (cases "x = c \<or> y = c")
case False
then have **: "x \<in> f" "y \<in> f"
using x y by auto
show ?thesis
using rs(6)[rule_format,OF **]
by (auto dest: kle_Suc)
qed (insert * x y, auto)
qed (insert rs, auto)
qed
lemma ksimplex_fix_plane:
fixes a a0 a1 :: "nat \<Rightarrow> nat"
assumes "a \<in> s"
and "j \<in> {1..n}"
and "\<forall>x\<in>s - {a}. x j = q"
and "a0 \<in> s"
and "a1 \<in> s"
and "\<forall>i. a1 i = (if i \<in> {1..n} then a0 i + 1 else a0 i)"
shows "a = a0 \<or> a = a1"
proof -
have *: "\<And>P A x y. \<forall>x\<in>A. P x \<Longrightarrow> x\<in>A \<Longrightarrow> y\<in>A \<Longrightarrow> P x \<and> P y"
by auto
show ?thesis
apply (rule ccontr)
using *[OF assms(3), of a0 a1]
unfolding assms(6)[THEN spec[where x=j]]
using assms(1-2,4-5)
apply auto
done
qed
lemma ksimplex_fix_plane_0:
fixes a a0 a1 :: "nat \<Rightarrow> nat"
assumes "a \<in> s"
and "j \<in> {1..n}"
and "\<forall>x\<in>s - {a}. x j = 0"
and "a0 \<in> s"
and "a1 \<in> s"
and "\<forall>i. a1 i = (if i\<in>{1..n} then a0 i + 1 else a0 i)"
shows "a = a1"
apply (rule ccontr)
using ksimplex_fix_plane[OF assms]
using assms(3)[THEN bspec[where x=a1]]
using assms(2,5)
unfolding assms(6)[THEN spec[where x=j]]
apply simp
done
lemma ksimplex_fix_plane_p:
assumes "ksimplex p n s"
and "a \<in> s"
and "j \<in> {1..n}"
and "\<forall>x\<in>s - {a}. x j = p"
and "a0 \<in> s"
and "a1 \<in> s"
and "\<forall>i. a1 i = (if i\<in>{1..n} then a0 i + 1 else a0 i)"
shows "a = a0"
proof (rule ccontr)
note s = ksimplexD[OF assms(1),rule_format]
assume as: "\<not> ?thesis"
then have *: "a0 \<in> s - {a}"
using assms(5) by auto
then have "a1 = a"
using ksimplex_fix_plane[OF assms(2-)] by auto
then show False
using as and assms(3,5) and assms(7)[rule_format,of j]
unfolding assms(4)[rule_format,OF *]
using s(4)[OF assms(6), of j]
by auto
qed
lemma ksimplex_replace_0:
assumes "ksimplex p n s" "a \<in> s"
and "n \<noteq> 0"
and "j \<in> {1..n}"
and "\<forall>x\<in>s - {a}. x j = 0"
shows "card {s'. ksimplex p n s' \<and> (\<exists>b\<in>s'. s' - {b} = s - {a})} = 1"
proof -
have *: "\<And>s' a a'. s' - {a'} = s - {a} \<Longrightarrow> a' = a \<Longrightarrow> a' \<in> s' \<Longrightarrow> a \<in> s \<Longrightarrow> s' = s"
by auto
have **: "\<And>s' a'. ksimplex p n s' \<Longrightarrow> a' \<in> s' \<Longrightarrow> s' - {a'} = s - {a} \<Longrightarrow> s' = s"
proof -
case goal1
guess a0 a1 by (rule ksimplex_extrema_strong[OF assms(1,3)]) note exta = this[rule_format]
have a: "a = a1"
apply (rule ksimplex_fix_plane_0[OF assms(2,4-5)])
using exta(1-2,5)
apply auto
done
moreover
guess b0 b1 by (rule ksimplex_extrema_strong[OF goal1(1) assms(3)])
note extb = this[rule_format]
have a': "a' = b1"
apply (rule ksimplex_fix_plane_0[OF goal1(2) assms(4), of b0])
unfolding goal1(3)
using assms extb goal1
apply auto
done
moreover
have "b0 = a0"
unfolding kle_antisym[symmetric, of b0 a0 n]
using exta extb and goal1(3)
unfolding a a' by blast
then have "b1 = a1"
apply -
apply (rule ext)
unfolding exta(5) extb(5)
apply auto
done
ultimately
show "s' = s"
apply -
apply (rule *[of _ a1 b1])
using exta(1-2) extb(1-2) goal1
apply auto
done
qed
show ?thesis
unfolding card_1_exists
apply -
apply(rule ex1I[of _ s])
unfolding mem_Collect_eq
defer
apply (erule conjE bexE)+
apply (rule_tac a'=b in **)
using assms(1,2)
apply auto
done
qed
lemma ksimplex_replace_1:
assumes "ksimplex p n s"
and "a \<in> s"
and "n \<noteq> 0"
and "j \<in> {1..n}"
and "\<forall>x\<in>s - {a}. x j = p"
shows "card {s'. ksimplex p n s' \<and> (\<exists>b\<in>s'. s' - {b} = s - {a})} = 1"
proof -
have lem: "\<And>a a' s'. s' - {a'} = s - {a} \<Longrightarrow> a' = a \<Longrightarrow> a' \<in> s' \<Longrightarrow> a \<in> s \<Longrightarrow> s' = s"
by auto
have lem: "\<And>s' a'. ksimplex p n s' \<Longrightarrow> a'\<in>s' \<Longrightarrow> s' - {a'} = s - {a} \<Longrightarrow> s' = s"
proof -
case goal1
guess a0 a1 by (rule ksimplex_extrema_strong[OF assms(1,3)]) note exta = this [rule_format]
have a: "a = a0"
apply (rule ksimplex_fix_plane_p[OF assms(1-2,4-5) exta(1,2)])
unfolding exta
apply auto
done
moreover
guess b0 b1 by (rule ksimplex_extrema_strong[OF goal1(1) assms(3)])
note extb = this [rule_format]
have a': "a' = b0"
apply (rule ksimplex_fix_plane_p[OF goal1(1-2) assms(4), of _ b1])
unfolding goal1 extb
using extb(1,2) assms(5)
apply auto
done
moreover
have *: "b1 = a1"
unfolding kle_antisym[symmetric, of b1 a1 n]
using exta extb
using goal1(3)
unfolding a a'
by blast
moreover
have "a0 = b0"
proof (rule ext)
fix x
show "a0 x = b0 x"
using *[THEN cong, of x x]
unfolding exta extb
by (cases "x \<in> {1..n}") auto
qed
ultimately
show "s' = s"
apply -
apply (rule lem[OF goal1(3) _ goal1(2) assms(2)])
apply auto
done
qed
show ?thesis
unfolding card_1_exists
apply (rule ex1I[of _ s])
unfolding mem_Collect_eq
apply rule
apply (rule assms(1))
apply (rule_tac x = a in bexI)
prefer 3
apply (erule conjE bexE)+
apply (rule_tac a'=b in lem)
using assms(1-2)
apply auto
done
qed
lemma ksimplex_replace_2:
assumes "ksimplex p n s"
and "a \<in> s"
and "n \<noteq> 0"
and "\<not> (\<exists>j\<in>{1..n}. \<forall>x\<in>s - {a}. x j = 0)"
and "\<not> (\<exists>j\<in>{1..n}. \<forall>x\<in>s - {a}. x j = p)"
shows "card {s'. ksimplex p n s' \<and> (\<exists>b\<in>s'. s' - {b} = s - {a})} = 2"
(is "card ?A = 2")
proof -
have lem1: "\<And>a a' s s'. s' - {a'} = s - {a} \<Longrightarrow> a' = a \<Longrightarrow> a' \<in> s' \<Longrightarrow> a \<in> s \<Longrightarrow> s' = s"
by auto
have lem2: "\<And>a b. a \<in> s \<Longrightarrow> b \<noteq> a \<Longrightarrow> s \<noteq> insert b (s - {a})"
proof
case goal1
then have "a \<in> insert b (s - {a})"
by auto
then have "a \<in> s - {a}"
unfolding insert_iff
using goal1
by auto
then show False
by auto
qed
guess a0 a1 by (rule ksimplex_extrema_strong[OF assms(1,3)]) note a0a1 = this
{
assume "a = a0"
have *: "\<And>P Q. P \<or> Q \<Longrightarrow> \<not> P \<Longrightarrow> Q"
by auto
have "\<exists>x\<in>s. \<not> kle n x a0"
apply (rule_tac x=a1 in bexI)
proof
assume as: "kle n a1 a0"
show False
using kle_imp_pointwise[OF as,THEN spec[where x=1]]
unfolding a0a1(5)[THEN spec[where x=1]]
using assms(3)
by auto
qed (insert a0a1, auto)
then have "\<exists>y\<in>s. \<exists>k\<in>{1..n}. \<forall>j. y j = (if j = k then a0 j + 1 else a0 j)"
apply (rule_tac *[OF ksimplex_successor[OF assms(1-2),unfolded `a=a0`]])
apply auto
done
then guess a2 ..
from this(2) guess k .. note k = this note a2 =`a2 \<in> s`
def a3 \<equiv> "\<lambda>j. if j = k then a1 j + 1 else a1 j"
have "a3 \<notin> s"
proof
assume "a3\<in>s"
then have "kle n a3 a1"
using a0a1(4) by auto
then show False
apply (drule_tac kle_imp_pointwise)
unfolding a3_def
apply (erule_tac x = k in allE)
apply auto
done
qed
then have "a3 \<noteq> a0" and "a3 \<noteq> a1"
using a0a1 by auto
have "a2 \<noteq> a0"
using k(2)[THEN spec[where x=k]] by auto
have lem3: "\<And>x. x \<in> (s - {a0}) \<Longrightarrow> kle n a2 x"
proof (rule ccontr)
case goal1
then have as: "x \<in> s" "x \<noteq> a0"
by auto
have "kle n a2 x \<or> kle n x a2"
using ksimplexD(6)[OF assms(1)] and as `a2 \<in> s`
by auto
moreover
have "kle n a0 x"
using a0a1(4) as by auto
ultimately have "x = a0 \<or> x = a2"
apply -
apply (rule kle_adjacent[OF k(2)])
using goal1(2)
apply auto
done
then have "x = a2"
using as by auto
then show False
using goal1(2)
using kle_refl
by auto
qed
let ?s = "insert a3 (s - {a0})"
have "ksimplex p n ?s"
apply (rule ksimplexI)
apply (rule_tac[2-] ballI)
apply (rule_tac[4] ballI)
proof -
show "card ?s = n + 1"
using ksimplexD(2-3)[OF assms(1)]
using `a3 \<noteq> a0` `a3 \<notin> s` `a0 \<in> s`
by (auto simp add: card_insert_if)
fix x
assume x: "x \<in> insert a3 (s - {a0})"
show "\<forall>j. x j \<le> p"
proof
fix j
show "x j \<le> p"
proof (cases "x = a3")
case False
then show ?thesis
using x ksimplexD(4)[OF assms(1)] by auto
next
case True
show ?thesis unfolding True
proof (cases "j = k")
case False
then show "a3 j \<le> p"
unfolding True a3_def
using `a1 \<in> s` ksimplexD(4)[OF assms(1)]
by auto
next
guess a4 using assms(5)[unfolded bex_simps ball_simps,rule_format,OF k(1)] ..
note a4 = this
have "a2 k \<le> a4 k"
using lem3[OF a4(1)[unfolded `a = a0`],THEN kle_imp_pointwise]
by auto
also have "\<dots> < p"
using ksimplexD(4)[OF assms(1),rule_format,of a4 k]
using a4 by auto
finally have *: "a0 k + 1 < p"
unfolding k(2)[rule_format]
by auto
case True
then show "a3 j \<le>p"
unfolding a3_def
unfolding a0a1(5)[rule_format]
using k(1) k(2)assms(5)
using *
by simp
qed
qed
qed
show "\<forall>j. j \<notin> {1..n} \<longrightarrow> x j = p"
proof (rule, rule)
fix j :: nat
assume j: "j \<notin> {1..n}"
show "x j = p"
proof (cases "x = a3")
case False
then show ?thesis
using j x ksimplexD(5)[OF assms(1)]
by auto
next
case True
show ?thesis
unfolding True a3_def
using j k(1)
using ksimplexD(5)[OF assms(1),rule_format,OF `a1\<in>s` j]
by auto
qed
qed
fix y
assume y: "y \<in> insert a3 (s - {a0})"
have lem4: "\<And>x. x\<in>s \<Longrightarrow> x \<noteq> a0 \<Longrightarrow> kle n x a3"
proof -
case goal1
guess kk using a0a1(4)[rule_format, OF `x\<in>s`,THEN conjunct2,unfolded kle_def]
by (elim exE conjE)
note kk = this
have "k \<notin> kk"
proof
assume "k \<in> kk"
then have "a1 k = x k + 1"
using kk by auto
then have "a0 k = x k"
unfolding a0a1(5)[rule_format] using k(1) by auto
then have "a2 k = x k + 1"
unfolding k(2)[rule_format] by auto
moreover
have "a2 k \<le> x k"
using lem3[of x,THEN kle_imp_pointwise] goal1 by auto
ultimately show False
by auto
qed
then show ?case
unfolding kle_def
apply (rule_tac x="insert k kk" in exI)
using kk(1)
unfolding a3_def kle_def kk(2)[rule_format]
using k(1)
apply auto
done
qed
show "kle n x y \<or> kle n y x"
proof (cases "y = a3")
case True
show ?thesis
unfolding True
apply (cases "x = a3")
defer
apply (rule disjI1, rule lem4)
using x
apply auto
done
next
case False
show ?thesis
proof (cases "x = a3")
case True
show ?thesis
unfolding True
apply (rule disjI2)
apply (rule lem4)
using y False
apply auto
done
next
case False
then show ?thesis
apply (rule_tac ksimplexD(6)[OF assms(1),rule_format])
using x y `y \<noteq> a3`
apply auto
done
qed
qed
qed
then have "insert a3 (s - {a0}) \<in> ?A"
unfolding mem_Collect_eq
apply -
apply rule
apply assumption
apply (rule_tac x = "a3" in bexI)
unfolding `a = a0`
using `a3 \<notin> s`
apply auto
done
moreover
have "s \<in> ?A"
using assms(1,2) by auto
ultimately have "?A \<supseteq> {s, insert a3 (s - {a0})}"
by auto
moreover
have "?A \<subseteq> {s, insert a3 (s - {a0})}"
apply rule
unfolding mem_Collect_eq
proof (erule conjE)
fix s'
assume as: "ksimplex p n s'" and "\<exists>b\<in>s'. s' - {b} = s - {a}"
from this(2) guess a' .. note a' = this
guess a_min a_max by (rule ksimplex_extrema_strong[OF as assms(3)]) note min_max = this
have *: "\<forall>x\<in>s' - {a'}. x k = a2 k"
unfolding a'
proof
fix x
assume x: "x \<in> s - {a}"
then have "kle n a2 x"
apply -
apply (rule lem3)
using `a = a0`
apply auto
done
then have "a2 k \<le> x k"
apply (drule_tac kle_imp_pointwise)
apply auto
done
moreover
have "x k \<le> a2 k"
unfolding k(2)[rule_format]
using a0a1(4)[rule_format,of x, THEN conjunct1]
unfolding kle_def using x
by auto
ultimately show "x k = a2 k"
by auto
qed
have **: "a' = a_min \<or> a' = a_max"
apply (rule ksimplex_fix_plane[OF a'(1) k(1) *])
using min_max
apply auto
done
show "s' \<in> {s, insert a3 (s - {a0})}"
proof (cases "a' = a_min")
case True
have "a_max = a1"
unfolding kle_antisym[symmetric,of a_max a1 n]
apply rule
apply (rule a0a1(4)[rule_format,THEN conjunct2])
defer
proof (rule min_max(4)[rule_format,THEN conjunct2])
show "a1 \<in> s'"
using a'
unfolding `a = a0`
using a0a1
by auto
show "a_max \<in> s"
proof (rule ccontr)
assume "\<not> ?thesis"
then have "a_max = a'"
using a' min_max by auto
then show False
unfolding True using min_max by auto
qed
qed
then have "\<forall>i. a_max i = a1 i"
by auto
then have "a' = a"
unfolding True `a = a0`
apply -
apply (subst fun_eq_iff)
apply rule
apply (erule_tac x=x in allE)
unfolding a0a1(5)[rule_format] min_max(5)[rule_format]
proof -
case goal1
then show ?case
by (cases "x \<in> {1..n}") auto
qed
then have "s' = s"
apply -
apply (rule lem1[OF a'(2)])
using `a \<in> s` `a' \<in> s'`
apply auto
done
then show ?thesis
by auto
next
case False
then have as: "a' = a_max"
using ** by auto
have "a_min = a2"
unfolding kle_antisym[symmetric, of _ _ n]
apply rule
apply (rule min_max(4)[rule_format,THEN conjunct1])
defer
proof (rule lem3)
show "a_min \<in> s - {a0}"
unfolding a'(2)[symmetric,unfolded `a = a0`]
unfolding as
using min_max(1-3)
by auto
have "a2 \<noteq> a"
unfolding `a = a0`
using k(2)[rule_format,of k]
by auto
then have "a2 \<in> s - {a}"
using a2 by auto
then show "a2 \<in> s'"
unfolding a'(2)[symmetric] by auto
qed
then have "\<forall>i. a_min i = a2 i"
by auto
then have "a' = a3"
unfolding as `a = a0`
apply (subst fun_eq_iff)
apply rule
apply (erule_tac x=x in allE)
unfolding a0a1(5)[rule_format] min_max(5)[rule_format]
unfolding a3_def k(2)[rule_format]
unfolding a0a1(5)[rule_format]
proof -
case goal1
show ?case
unfolding goal1
apply (cases "x \<in> {1..n}")
defer
apply (cases "x = k")
using `k \<in> {1..n}`
apply auto
done
qed
then have "s' = insert a3 (s - {a0})"
apply -
apply (rule lem1)
defer
apply assumption
apply (rule a'(1))
unfolding a' `a = a0`
using `a3 \<notin> s`
apply auto
done
then show ?thesis by auto
qed
qed
ultimately have *: "?A = {s, insert a3 (s - {a0})}"
by blast
have "s \<noteq> insert a3 (s - {a0})"
using `a3 \<notin> s` by auto
then have ?thesis
unfolding * by auto
}
moreover
{
assume "a = a1"
have *: "\<And>P Q. P \<or> Q \<Longrightarrow> \<not> P \<Longrightarrow> Q"
by auto
have "\<exists>x\<in>s. \<not> kle n a1 x"
apply (rule_tac x=a0 in bexI)
proof
assume as: "kle n a1 a0"
show False
using kle_imp_pointwise[OF as,THEN spec[where x=1]]
unfolding a0a1(5)[THEN spec[where x=1]]
using assms(3)
by auto
qed (insert a0a1, auto)
then have "\<exists>y\<in>s. \<exists>k\<in>{1..n}. \<forall>j. a1 j = (if j = k then y j + 1 else y j)"
apply (rule_tac *[OF ksimplex_predecessor[OF assms(1-2),unfolded `a=a1`]])
apply auto
done
then guess a2 .. from this(2) guess k .. note k=this note a2 = `a2 \<in> s`
def a3 \<equiv> "\<lambda>j. if j = k then a0 j - 1 else a0 j"
have "a2 \<noteq> a1"
using k(2)[THEN spec[where x=k]] by auto
have lem3: "\<And>x. x \<in> s - {a1} \<Longrightarrow> kle n x a2"
proof (rule ccontr)
case goal1
then have as: "x \<in> s" "x \<noteq> a1" by auto
have "kle n a2 x \<or> kle n x a2"
using ksimplexD(6)[OF assms(1)] and as `a2\<in>s`
by auto
moreover
have "kle n x a1"
using a0a1(4) as by auto
ultimately have "x = a2 \<or> x = a1"
apply -
apply (rule kle_adjacent[OF k(2)])
using goal1(2)
apply auto
done
then have "x = a2"
using as by auto
then show False
using goal1(2) using kle_refl by auto
qed
have "a0 k \<noteq> 0"
proof -
guess a4 using assms(4)[unfolded bex_simps ball_simps,rule_format,OF `k\<in>{1..n}`] ..
note a4 = this
have "a4 k \<le> a2 k"
using lem3[OF a4(1)[unfolded `a=a1`],THEN kle_imp_pointwise]
by auto
moreover have "a4 k > 0"
using a4 by auto
ultimately have "a2 k > 0"
by auto
then have "a1 k > 1"
unfolding k(2)[rule_format] by simp
then show ?thesis
unfolding a0a1(5)[rule_format] using k(1) by simp
qed
then have lem4: "\<forall>j. a0 j = (if j = k then a3 j + 1 else a3 j)"
unfolding a3_def by simp
have "\<not> kle n a0 a3"
apply (rule notI)
apply (drule kle_imp_pointwise)
unfolding lem4[rule_format]
apply (erule_tac x=k in allE)
apply auto
done
then have "a3 \<notin> s"
using a0a1(4) by auto
then have "a3 \<noteq> a1" "a3 \<noteq> a0"
using a0a1 by auto
let ?s = "insert a3 (s - {a1})"
have "ksimplex p n ?s"
apply (rule ksimplexI)
proof (rule_tac[2-] ballI,rule_tac[4] ballI)
show "card ?s = n+1"
using ksimplexD(2-3)[OF assms(1)]
using `a3 \<noteq> a0` `a3 \<notin> s` `a1 \<in> s`
by (auto simp add:card_insert_if)
fix x
assume x: "x \<in> insert a3 (s - {a1})"
show "\<forall>j. x j \<le> p"
proof
fix j
show "x j \<le> p"
proof (cases "x = a3")
case False
then show ?thesis
using x ksimplexD(4)[OF assms(1)] by auto
next
case True
show ?thesis
unfolding True
proof (cases "j = k")
case False
then show "a3 j \<le> p"
unfolding True a3_def
using `a0 \<in> s` ksimplexD(4)[OF assms(1)]
by auto
next
guess a4 using assms(5)[unfolded bex_simps ball_simps,rule_format,OF k(1)] ..
note a4 = this
case True have "a3 k \<le> a0 k"
unfolding lem4[rule_format] by auto
also have "\<dots> \<le> p"
using ksimplexD(4)[OF assms(1),rule_format, of a0 k] a0a1
by auto
finally show "a3 j \<le> p"
unfolding True by auto
qed
qed
qed
show "\<forall>j. j \<notin> {1..n} \<longrightarrow> x j = p"
proof (rule, rule)
fix j :: nat
assume j: "j \<notin> {1..n}"
show "x j = p"
proof (cases "x = a3")
case False
then show ?thesis
using j x ksimplexD(5)[OF assms(1)] by auto
next
case True
show ?thesis
unfolding True a3_def
using j k(1)
using ksimplexD(5)[OF assms(1),rule_format,OF `a0\<in>s` j]
by auto
qed
qed
fix y
assume y: "y \<in> insert a3 (s - {a1})"
have lem4: "\<And>x. x \<in> s \<Longrightarrow> x \<noteq> a1 \<Longrightarrow> kle n a3 x"
proof -
case goal1
then have *: "x\<in>s - {a1}"
by auto
have "kle n a3 a2"
proof -
have "kle n a0 a1"
using a0a1 by auto then guess kk unfolding kle_def ..
then show ?thesis
unfolding kle_def
apply (rule_tac x=kk in exI)
unfolding lem4[rule_format] k(2)[rule_format]
apply rule
defer
proof rule
case goal1
then show ?case
apply -
apply (erule conjE)
apply (erule_tac[!] x=j in allE)
apply (cases "j \<in> kk")
apply (case_tac[!] "j=k")
apply auto
done
qed auto
qed
moreover
have "kle n a3 a0"
unfolding kle_def lem4[rule_format]
apply (rule_tac x="{k}" in exI)
using k(1)
apply auto
done
ultimately
show ?case
apply -
apply (rule kle_between_l[of _ a0 _ a2])
using lem3[OF *]
using a0a1(4)[rule_format,OF goal1(1)]
apply auto
done
qed
show "kle n x y \<or> kle n y x"
proof (cases "y = a3")
case True
show ?thesis
unfolding True
apply (cases "x = a3")
defer
apply (rule disjI2)
apply (rule lem4)
using x
apply auto
done
next
case False
show ?thesis
proof (cases "x = a3")
case True
show ?thesis
unfolding True
apply (rule disjI1)
apply (rule lem4)
using y False
apply auto
done
next
case False
then show ?thesis
apply (rule_tac ksimplexD(6)[OF assms(1),rule_format])
using x y `y \<noteq> a3`
apply auto
done
qed
qed
qed
then have "insert a3 (s - {a1}) \<in> ?A"
unfolding mem_Collect_eq
apply -
apply (rule, assumption)
apply (rule_tac x = "a3" in bexI)
unfolding `a = a1`
using `a3 \<notin> s`
apply auto
done
moreover
have "s \<in> ?A"
using assms(1,2) by auto
ultimately have "?A \<supseteq> {s, insert a3 (s - {a1})}"
by auto
moreover have "?A \<subseteq> {s, insert a3 (s - {a1})}"
apply rule
unfolding mem_Collect_eq
proof (erule conjE)
fix s'
assume as: "ksimplex p n s'" and "\<exists>b\<in>s'. s' - {b} = s - {a}"
from this(2) guess a' .. note a' = this
guess a_min a_max by (rule ksimplex_extrema_strong[OF as assms(3)]) note min_max = this
have *: "\<forall>x\<in>s' - {a'}. x k = a2 k" unfolding a'
proof
fix x
assume x: "x \<in> s - {a}"
then have "kle n x a2"
apply -
apply (rule lem3)
using `a = a1`
apply auto
done
then have "x k \<le> a2 k"
apply (drule_tac kle_imp_pointwise)
apply auto
done
moreover
{
have "a2 k \<le> a0 k"
using k(2)[rule_format,of k]
unfolding a0a1(5)[rule_format]
using k(1)
by simp
also have "\<dots> \<le> x k"
using a0a1(4)[rule_format,of x,THEN conjunct1,THEN kle_imp_pointwise] x
by auto
finally have "a2 k \<le> x k" .
}
ultimately show "x k = a2 k"
by auto
qed
have **: "a' = a_min \<or> a' = a_max"
apply (rule ksimplex_fix_plane[OF a'(1) k(1) *])
using min_max
apply auto
done
have "a2 \<noteq> a1"
proof
assume as: "a2 = a1"
show False
using k(2)
unfolding as
apply (erule_tac x = k in allE)
apply auto
done
qed
then have a2': "a2 \<in> s' - {a'}"
unfolding a'
using a2
unfolding `a = a1`
by auto
show "s' \<in> {s, insert a3 (s - {a1})}"
proof (cases "a' = a_min")
case True
have "a_max \<in> s - {a1}"
using min_max
unfolding a'(2)[unfolded `a=a1`,symmetric] True
by auto
then have "a_max = a2"
unfolding kle_antisym[symmetric,of a_max a2 n]
apply -
apply rule
apply (rule lem3)
apply assumption
apply (rule min_max(4)[rule_format,THEN conjunct2])
using a2'
apply auto
done
then have a_max: "\<forall>i. a_max i = a2 i"
by auto
have *: "\<forall>j. a2 j = (if j \<in> {1..n} then a3 j + 1 else a3 j)"
using k(2)
unfolding lem4[rule_format] a0a1(5)[rule_format]
apply -
apply rule
apply (erule_tac x=j in allE)
proof -
case goal1
then show ?case by (cases "j \<in> {1..n}", case_tac[!] "j = k") auto
qed
have "\<forall>i. a_min i = a3 i"
using a_max
apply -
apply rule
apply (erule_tac x=i in allE)
unfolding min_max(5)[rule_format] *[rule_format]
proof -
case goal1
then show ?case
by (cases "i \<in> {1..n}") auto
qed
then have "a_min = a3"
unfolding fun_eq_iff .
then have "s' = insert a3 (s - {a1})"
using a'
unfolding `a = a1` True
by auto
then show ?thesis
by auto
next
case False
then have as: "a' = a_max"
using ** by auto
have "a_min = a0"
unfolding kle_antisym[symmetric,of _ _ n]
apply rule
apply (rule min_max(4)[rule_format,THEN conjunct1])
defer
apply (rule a0a1(4)[rule_format,THEN conjunct1])
proof -
have "a_min \<in> s - {a1}"
using min_max(1,3)
unfolding a'(2)[symmetric,unfolded `a=a1`] as
by auto
then show "a_min \<in> s"
by auto
have "a0 \<in> s - {a1}"
using a0a1(1-3) by auto
then show "a0 \<in> s'"
unfolding a'(2)[symmetric,unfolded `a=a1`]
by auto
qed
then have "\<forall>i. a_max i = a1 i"
unfolding a0a1(5)[rule_format] min_max(5)[rule_format]
by auto
then have "s' = s"
apply -
apply (rule lem1[OF a'(2)])
using `a \<in> s` `a' \<in> s'`
unfolding as `a = a1`
unfolding fun_eq_iff
apply auto
done
then show ?thesis
by auto
qed
qed
ultimately have *: "?A = {s, insert a3 (s - {a1})}"
by blast
have "s \<noteq> insert a3 (s - {a1})"
using `a3\<notin>s` by auto
then have ?thesis
unfolding * by auto
}
moreover
{
assume as: "a \<noteq> a0" "a \<noteq> a1"
have "\<not> (\<forall>x\<in>s. kle n a x)"
proof
case goal1
have "a = a0"
unfolding kle_antisym[symmetric,of _ _ n]
apply rule
using goal1 a0a1 assms(2)
apply auto
done
then show False
using as by auto
qed
then have "\<exists>y\<in>s. \<exists>k\<in>{1..n}. \<forall>j. a j = (if j = k then y j + 1 else y j)"
using ksimplex_predecessor[OF assms(1-2)]
by blast
then guess u .. from this(2) guess k .. note k = this[rule_format]
note u = `u \<in> s`
have "\<not> (\<forall>x\<in>s. kle n x a)"
proof
case goal1
have "a = a1"
unfolding kle_antisym[symmetric,of _ _ n]
apply rule
using goal1 a0a1 assms(2)
apply auto
done
then show False
using as by auto
qed
then have "\<exists>y\<in>s. \<exists>k\<in>{1..n}. \<forall>j. y j = (if j = k then a j + 1 else a j)"
using ksimplex_successor[OF assms(1-2)] by blast
then guess v .. from this(2) guess l ..
note l = this[rule_format]
note v = `v \<in> s`
def a' \<equiv> "\<lambda>j. if j = l then u j + 1 else u j"
have kl: "k \<noteq> l"
proof
assume "k = l"
have *: "\<And>P. (if P then (1::nat) else 0) \<noteq> 2"
by auto
then show False
using ksimplexD(6)[OF assms(1),rule_format,OF u v]
unfolding kle_def
unfolding l(2) k(2) `k = l`
apply -
apply (erule disjE)
apply (erule_tac[!] exE conjE)+
apply (erule_tac[!] x = l in allE)+
apply (auto simp add: *)
done
qed
then have aa': "a' \<noteq> a"
apply -
apply rule
unfolding fun_eq_iff
unfolding a'_def k(2)
apply (erule_tac x=l in allE)
apply auto
done
have "a' \<notin> s"
apply rule
apply (drule ksimplexD(6)[OF assms(1),rule_format,OF `a\<in>s`])
proof (cases "kle n a a'")
case goal2
then have "kle n a' a"
by auto
then show False
apply (drule_tac kle_imp_pointwise)
apply (erule_tac x=l in allE)
unfolding a'_def k(2)
using kl
apply auto
done
next
case True
then show False
apply (drule_tac kle_imp_pointwise)
apply (erule_tac x=k in allE)
unfolding a'_def k(2)
using kl
apply auto
done
qed
have kle_uv: "kle n u a" "kle n u a'" "kle n a v" "kle n a' v"
unfolding kle_def
apply -
apply (rule_tac[1] x="{k}" in exI,rule_tac[2] x="{l}" in exI)
apply (rule_tac[3] x="{l}" in exI,rule_tac[4] x="{k}" in exI)
unfolding l(2) k(2) a'_def
using l(1) k(1)
apply auto
done
have uxv: "\<And>x. kle n u x \<Longrightarrow> kle n x v \<Longrightarrow> x = u \<or> x = a \<or> x = a' \<or> x = v"
proof -
case goal1
then show ?case
proof (cases "x k = u k", case_tac[!] "x l = u l")
assume as: "x l = u l" "x k = u k"
have "x = u"
unfolding fun_eq_iff
using goal1(2)[THEN kle_imp_pointwise,unfolded l(2)]
unfolding k(2)
apply -
using goal1(1)[THEN kle_imp_pointwise]
apply -
apply rule
apply (erule_tac x=xa in allE)+
proof -
case goal1
then show ?case
apply (cases "x = l")
apply (case_tac[!] "x = k")
using as
by auto
qed
then show ?case
by auto
next
assume as: "x l \<noteq> u l" "x k = u k"
have "x = a'"
unfolding fun_eq_iff
unfolding a'_def
using goal1(2)[THEN kle_imp_pointwise]
unfolding l(2) k(2)
using goal1(1)[THEN kle_imp_pointwise]
apply -
apply rule
apply (erule_tac x = xa in allE)+
proof -
case goal1
then show ?case
apply (cases "x = l")
apply (case_tac[!] "x = k")
using as
apply auto
done
qed
then show ?case by auto
next
assume as: "x l = u l" "x k \<noteq> u k"
have "x = a"
unfolding fun_eq_iff
using goal1(2)[THEN kle_imp_pointwise]
unfolding l(2) k(2)
using goal1(1)[THEN kle_imp_pointwise]
apply -
apply rule
apply (erule_tac x=xa in allE)+
proof -
case goal1
then show ?case
apply (cases "x = l")
apply (case_tac[!] "x = k")
using as
apply auto
done
qed
then show ?case
by auto
next
assume as: "x l \<noteq> u l" "x k \<noteq> u k"
have "x = v"
unfolding fun_eq_iff
using goal1(2)[THEN kle_imp_pointwise]
unfolding l(2) k(2)
using goal1(1)[THEN kle_imp_pointwise]
apply -
apply rule
apply (erule_tac x=xa in allE)+
proof -
case goal1
then show ?case
apply (cases "x = l")
apply (case_tac[!] "x = k")
using as `k \<noteq> l`
apply auto
done
qed
then show ?case by auto
qed
qed
have uv: "kle n u v"
apply (rule kle_trans[OF kle_uv(1,3)])
using ksimplexD(6)[OF assms(1)]
using u v
apply auto
done
have lem3: "\<And>x. x \<in> s \<Longrightarrow> kle n v x \<Longrightarrow> kle n a' x"
apply (rule kle_between_r[of _ u _ v])
prefer 3
apply (rule kle_trans[OF uv])
defer
apply (rule ksimplexD(6)[OF assms(1), rule_format])
using kle_uv `u \<in> s`
apply auto
done
have lem4: "\<And>x. x \<in> s \<Longrightarrow> kle n x u \<Longrightarrow> kle n x a'"
apply (rule kle_between_l[of _ u _ v])
prefer 4
apply (rule kle_trans[OF _ uv])
defer
apply (rule ksimplexD(6)[OF assms(1), rule_format])
using kle_uv `v \<in> s`
apply auto
done
have lem5: "\<And>x. x \<in> s \<Longrightarrow> x \<noteq> a \<Longrightarrow> kle n x a' \<or> kle n a' x"
proof -
case goal1
then show ?case
proof (cases "kle n v x \<or> kle n x u")
case True
then show ?thesis
using goal1 by (auto intro: lem3 lem4)
next
case False
then have *: "kle n u x" "kle n x v"
using ksimplexD(6)[OF assms(1)]
using goal1 `u \<in> s` `v \<in> s`
by auto
show ?thesis
using uxv[OF *]
using kle_uv
using goal1
by auto
qed
qed
have "ksimplex p n (insert a' (s - {a}))"
apply (rule ksimplexI)
apply (rule_tac[2-] ballI)
apply (rule_tac[4] ballI)
proof -
show "card (insert a' (s - {a})) = n + 1"
using ksimplexD(2-3)[OF assms(1)]
using `a' \<noteq> a` `a' \<notin> s` `a \<in> s`
by (auto simp add:card_insert_if)
fix x
assume x: "x \<in> insert a' (s - {a})"
show "\<forall>j. x j \<le> p"
proof
fix j
show "x j \<le> p"
proof (cases "x = a'")
case False
then show ?thesis
using x ksimplexD(4)[OF assms(1)] by auto
next
case True
show ?thesis
unfolding True
proof (cases "j = l")
case False
then show "a' j \<le>p"
unfolding True a'_def
using `u\<in>s` ksimplexD(4)[OF assms(1)]
by auto
next
case True
have *: "a l = u l" "v l = a l + 1"
using k(2)[of l] l(2)[of l] `k \<noteq> l`
by auto
have "u l + 1 \<le> p"
unfolding *[symmetric]
using ksimplexD(4)[OF assms(1)]
using `v \<in> s`
by auto
then show "a' j \<le>p"
unfolding a'_def True
by auto
qed
qed
qed
show "\<forall>j. j \<notin> {1..n} \<longrightarrow> x j = p"
proof (rule, rule)
fix j :: nat
assume j: "j \<notin> {1..n}"
show "x j = p"
proof (cases "x = a'")
case False
then show ?thesis
using j x ksimplexD(5)[OF assms(1)] by auto
next
case True
show ?thesis
unfolding True a'_def
using j l(1)
using ksimplexD(5)[OF assms(1),rule_format,OF `u\<in>s` j]
by auto
qed
qed
fix y
assume y: "y \<in> insert a' (s - {a})"
show "kle n x y \<or> kle n y x"
proof (cases "y = a'")
case True
show ?thesis
unfolding True
apply (cases "x = a'")
defer
apply (rule lem5)
using x
apply auto
done
next
case False
show ?thesis
proof (cases "x = a'")
case True
show ?thesis
unfolding True
using lem5[of y] using y by auto
next
case False
then show ?thesis
apply (rule_tac ksimplexD(6)[OF assms(1),rule_format])
using x y `y \<noteq> a'`
apply auto
done
qed
qed
qed
then have "insert a' (s - {a}) \<in> ?A"
unfolding mem_Collect_eq
apply -
apply rule
apply assumption
apply (rule_tac x = "a'" in bexI)
using aa' `a' \<notin> s`
apply auto
done
moreover
have "s \<in> ?A"
using assms(1,2) by auto
ultimately have "?A \<supseteq> {s, insert a' (s - {a})}"
by auto
moreover
have "?A \<subseteq> {s, insert a' (s - {a})}"
apply rule
unfolding mem_Collect_eq
proof (erule conjE)
fix s'
assume as: "ksimplex p n s'" and "\<exists>b\<in>s'. s' - {b} = s - {a}"
from this(2) guess a'' .. note a'' = this
have "u \<noteq> v"
unfolding fun_eq_iff unfolding l(2) k(2) by auto
then have uv': "\<not> kle n v u"
using uv using kle_antisym by auto
have "u \<noteq> a" "v \<noteq> a"
unfolding fun_eq_iff k(2) l(2) by auto
then have uvs': "u \<in> s'" "v \<in> s'"
using `u \<in> s` `v \<in> s` using a'' by auto
have lem6: "a \<in> s' \<or> a' \<in> s'"
proof (cases "\<forall>x\<in>s'. kle n x u \<or> kle n v x")
case False
then guess w unfolding ball_simps .. note w = this
then have "kle n u w" "kle n w v"
using ksimplexD(6)[OF as] uvs' by auto
then have "w = a' \<or> w = a"
using uxv[of w] uvs' w by auto
then show ?thesis
using w by auto
next
case True
have "\<not> (\<forall>x\<in>s'. kle n x u)"
unfolding ball_simps
apply (rule_tac x=v in bexI)
using uv `u \<noteq> v`
unfolding kle_antisym [of n u v,symmetric]
using `v \<in> s'`
apply auto
done
then have "\<exists>y\<in>s'. \<exists>k\<in>{1..n}. \<forall>j. y j = (if j = k then u j + 1 else u j)"
using ksimplex_successor[OF as `u\<in>s'`]
by blast
then guess w .. note w = this
from this(2) guess kk .. note kk = this[rule_format]
have "\<not> kle n w u"
apply -
apply rule
apply (drule kle_imp_pointwise)
apply (erule_tac x = kk in allE)
unfolding kk
apply auto
done
then have *: "kle n v w"
using True[rule_format,OF w(1)]
by auto
then have False
proof (cases "kk = l")
case False
then show False using *[THEN kle_imp_pointwise, unfolded l(2) kk k(2)]
apply (erule_tac x=l in allE)
using `k \<noteq> l`
apply auto
done
next
case True
then have "kk \<noteq> k" using `k \<noteq> l` by auto
then show False
using *[THEN kle_imp_pointwise, unfolded l(2) kk k(2)]
apply (erule_tac x=k in allE)
using `k \<noteq> l`
apply auto
done
qed
then show ?thesis
by auto
qed
then show "s' \<in> {s, insert a' (s - {a})}"
proof (cases "a \<in> s'")
case True
then have "s' = s"
apply -
apply (rule lem1[OF a''(2)])
using a'' `a \<in> s`
apply auto
done
then show ?thesis
by auto
next
case False
then have "a' \<in> s'"
using lem6 by auto
then have "s' = insert a' (s - {a})"
apply -
apply (rule lem1[of _ a'' _ a'])
unfolding a''(2)[symmetric]
using a'' and `a' \<notin> s`
by auto
then show ?thesis
by auto
qed
qed
ultimately have *: "?A = {s, insert a' (s - {a})}"
by blast
have "s \<noteq> insert a' (s - {a})"
using `a'\<notin>s` by auto
then have ?thesis
unfolding * by auto
}
ultimately show ?thesis
by auto
qed
text {* Hence another step towards concreteness. *}
lemma kuhn_simplex_lemma:
assumes "\<forall>s. ksimplex p (n + 1) s \<longrightarrow> rl ` s \<subseteq> {0..n+1}"
and "odd (card {f. \<exists>s a. ksimplex p (n + 1) s \<and> a \<in> s \<and> (f = s - {a}) \<and>
rl ` f = {0 .. n} \<and> ((\<exists>j\<in>{1..n+1}. \<forall>x\<in>f. x j = 0) \<or> (\<exists>j\<in>{1..n+1}. \<forall>x\<in>f. x j = p))})"
shows "odd (card {s \<in> {s. ksimplex p (n + 1) s}. rl ` s = {0..n+1}})"
proof -
have *: "\<And>x y. x = y \<Longrightarrow> odd (card x) \<Longrightarrow> odd (card y)"
by auto
have *: "odd (card {f \<in> {f. \<exists>s\<in>{s. ksimplex p (n + 1) s}. (\<exists>a\<in>s. f = s - {a})}.
rl ` f = {0..n} \<and> ((\<exists>j\<in>{1..n+1}. \<forall>x\<in>f. x j = 0) \<or> (\<exists>j\<in>{1..n+1}. \<forall>x\<in>f. x j = p))})"
apply (rule *[OF _ assms(2)])
apply auto
done
show ?thesis
apply (rule kuhn_complete_lemma[OF finite_simplices])
prefer 6
apply (rule *)
apply rule
apply rule
apply rule
apply (subst ksimplex_def)
defer
apply rule
apply (rule assms(1)[rule_format])
unfolding mem_Collect_eq
apply assumption
apply default+
unfolding mem_Collect_eq
apply (erule disjE bexE)+
defer
apply (erule disjE bexE)+
defer
apply default+
unfolding mem_Collect_eq
apply (erule disjE bexE)+
unfolding mem_Collect_eq
proof -
fix f s a
assume as: "ksimplex p (n + 1) s" "a \<in> s" "f = s - {a}"
let ?S = "{s. ksimplex p (n + 1) s \<and> (\<exists>a\<in>s. f = s - {a})}"
have S: "?S = {s'. ksimplex p (n + 1) s' \<and> (\<exists>b\<in>s'. s' - {b} = s - {a})}"
unfolding as by blast
{
fix j
assume j: "j \<in> {1..n + 1}" "\<forall>x\<in>f. x j = 0"
then show "card {s. ksimplex p (n + 1) s \<and> (\<exists>a\<in>s. f = s - {a})} = 1"
unfolding S
apply -
apply (rule ksimplex_replace_0)
apply (rule as)+
unfolding as
apply auto
done
}
{
fix j
assume j: "j \<in> {1..n + 1}" "\<forall>x\<in>f. x j = p"
then show "card {s. ksimplex p (n + 1) s \<and> (\<exists>a\<in>s. f = s - {a})} = 1"
unfolding S
apply -
apply (rule ksimplex_replace_1)
apply (rule as)+
unfolding as
apply auto
done
}
show "\<not> ((\<exists>j\<in>{1..n+1}. \<forall>x\<in>f. x j = 0) \<or> (\<exists>j\<in>{1..n+1}. \<forall>x\<in>f. x j = p)) \<Longrightarrow> card ?S = 2"
unfolding S
apply (rule ksimplex_replace_2)
apply (rule as)+
unfolding as
apply auto
done
qed auto
qed
subsection {* Reduced labelling *}
definition "reduced label (n::nat) (x::nat \<Rightarrow> nat) =
(SOME k. k \<le> n \<and> (\<forall>i. 1 \<le> i \<and> i < k + 1 \<longrightarrow> label x i = 0) \<and>
(k = n \<or> label x (k + 1) \<noteq> (0::nat)))"
lemma reduced_labelling:
shows "reduced label n x \<le> n" (is ?t1)
and "\<forall>i. 1 \<le> i \<and> i < reduced label n x + 1 \<longrightarrow> label x i = 0" (is ?t2)
and "reduced label n x = n \<or> label x (reduced label n x + 1) \<noteq> 0" (is ?t3)
proof -
have num_WOP: "\<And>P k. P (k::nat) \<Longrightarrow> \<exists>n. P n \<and> (\<forall>m<n. \<not> P m)"
apply (drule ex_has_least_nat[where m="\<lambda>x. x"])
apply (erule exE)
apply (rule_tac x=x in exI)
apply auto
done
have *: "n \<le> n \<and> (label x (n + 1) \<noteq> 0 \<or> n = n)"
by auto
then guess N
apply (drule_tac num_WOP[of "\<lambda>j. j\<le>n \<and> (label x (j+1) \<noteq> 0 \<or> n = j)"])
apply (erule exE)
done
note N = this
have N': "N \<le> n"
"\<forall>i. 1 \<le> i \<and> i < N + 1 \<longrightarrow> label x i = 0" "N = n \<or> label x (N + 1) \<noteq> 0"
defer
proof (rule, rule)
fix i
assume i: "1 \<le> i \<and> i < N + 1"
then show "label x i = 0"
using N[THEN conjunct2,THEN spec[where x="i - 1"]]
using N
by auto
qed (insert N, auto)
show ?t1 ?t2 ?t3
unfolding reduced_def
apply (rule_tac[!] someI2_ex)
using N'
apply (auto intro!: exI[where x=N])
done
qed
lemma reduced_labelling_unique:
fixes x :: "nat \<Rightarrow> nat"
assumes "r \<le> n"
and "\<forall>i. 1 \<le> i \<and> i < r + 1 \<longrightarrow> label x i = 0"
and "r = n \<or> label x (r + 1) \<noteq> 0"
shows "reduced label n x = r"
apply (rule le_antisym)
apply (rule_tac[!] ccontr)
unfolding not_le
using reduced_labelling[of label n x]
using assms
apply auto
done
lemma reduced_labelling_zero:
assumes "j \<in> {1..n}"
and "label x j = 0"
shows "reduced label n x \<noteq> j - 1"
using reduced_labelling[of label n x]
using assms
by fastforce
lemma reduced_labelling_nonzero:
assumes "j\<in>{1..n}"
and "label x j \<noteq> 0"
shows "reduced label n x < j"
using assms and reduced_labelling[of label n x]
apply (erule_tac x=j in allE)
apply auto
done
lemma reduced_labelling_Suc:
assumes "reduced lab (n + 1) x \<noteq> n + 1"
shows "reduced lab (n + 1) x = reduced lab n x"
apply (subst eq_commute)
apply (rule reduced_labelling_unique)
using reduced_labelling[of lab "n+1" x] and assms
apply auto
done
lemma complete_face_top:
assumes "\<forall>x\<in>f. \<forall>j\<in>{1..n+1}. x j = 0 \<longrightarrow> lab x j = 0"
and "\<forall>x\<in>f. \<forall>j\<in>{1..n+1}. x j = p \<longrightarrow> lab x j = 1"
shows "reduced lab (n + 1) ` f = {0..n} \<and>
((\<exists>j\<in>{1..n+1}. \<forall>x\<in>f. x j = 0) \<or> (\<exists>j\<in>{1..n+1}. \<forall>x\<in>f. x j = p)) \<longleftrightarrow>
reduced lab (n + 1) ` f = {0..n} \<and> (\<forall>x\<in>f. x (n + 1) = p)"
(is "?l = ?r")
proof
assume ?l (is "?as \<and> (?a \<or> ?b)")
then show ?r
apply -
apply rule
apply (erule conjE)
apply assumption
proof (cases ?a)
case True
then guess j .. note j = this
{
fix x
assume x: "x \<in> f"
have "reduced lab (n + 1) x \<noteq> j - 1"
using j
apply -
apply (rule reduced_labelling_zero)
defer
apply (rule assms(1)[rule_format])
using x
apply auto
done
}
moreover have "j - 1 \<in> {0..n}"
using j by auto
then guess y unfolding `?l`[THEN conjunct1,symmetric] and image_iff .. note y = this
ultimately have False
by auto
then show "\<forall>x\<in>f. x (n + 1) = p"
by auto
next
case False
then have ?b using `?l`
by blast
then guess j .. note j = this
{
fix x
assume x: "x \<in> f"
have "reduced lab (n + 1) x < j"
using j
apply -
apply (rule reduced_labelling_nonzero)
using assms(2)[rule_format,of x j] and x
apply auto
done
} note * = this
have "j = n + 1"
proof (rule ccontr)
assume "\<not> ?thesis"
then have "j < n + 1"
using j by auto
moreover
have "n \<in> {0..n}"
by auto
then guess y unfolding `?l`[THEN conjunct1,symmetric] image_iff ..
ultimately show False
using *[of y] by auto
qed
then show "\<forall>x\<in>f. x (n + 1) = p"
using j by auto
qed
qed auto
text {* Hence we get just about the nice induction. *}
lemma kuhn_induction:
assumes "0 < p"
and "\<forall>x. \<forall>j\<in>{1..n+1}. (\<forall>j. x j \<le> p) \<and> x j = 0 \<longrightarrow> lab x j = 0"
and "\<forall>x. \<forall>j\<in>{1..n+1}. (\<forall>j. x j \<le> p) \<and> x j = p \<longrightarrow> lab x j = 1"
and "odd (card {f. ksimplex p n f \<and> reduced lab n ` f = {0..n}})"
shows "odd (card {s. ksimplex p (n + 1) s \<and> reduced lab (n + 1) ` s = {0..n+1}})"
proof -
have *: "\<And>s t. odd (card s) \<Longrightarrow> s = t \<Longrightarrow> odd (card t)"
"\<And>s f. (\<And>x. f x \<le> n + 1) \<Longrightarrow> f ` s \<subseteq> {0..n+1}"
by auto
show ?thesis
apply (rule kuhn_simplex_lemma[unfolded mem_Collect_eq])
apply rule
apply rule
apply (rule *)
apply (rule reduced_labelling)
apply (rule *(1)[OF assms(4)])
apply (rule set_eqI)
unfolding mem_Collect_eq
apply rule
apply (erule conjE)
defer
apply rule
proof -
fix f
assume as: "ksimplex p n f" "reduced lab n ` f = {0..n}"
have *: "\<forall>x\<in>f. \<forall>j\<in>{1..n + 1}. x j = 0 \<longrightarrow> lab x j = 0"
"\<forall>x\<in>f. \<forall>j\<in>{1..n + 1}. x j = p \<longrightarrow> lab x j = 1"
using assms(2-3)
using as(1)[unfolded ksimplex_def]
by auto
have allp: "\<forall>x\<in>f. x (n + 1) = p"
using assms(2)
using as(1)[unfolded ksimplex_def]
by auto
{
fix x
assume "x \<in> f"
then have "reduced lab (n + 1) x < n + 1"
apply -
apply (rule reduced_labelling_nonzero)
defer
using assms(3)
using as(1)[unfolded ksimplex_def]
apply auto
done
then have "reduced lab (n + 1) x = reduced lab n x"
apply -
apply (rule reduced_labelling_Suc)
using reduced_labelling(1)
apply auto
done
}
then have "reduced lab (n + 1) ` f = {0..n}"
unfolding as(2)[symmetric]
apply -
apply (rule set_eqI)
unfolding image_iff
apply auto
done
moreover guess s using as(1)[unfolded simplex_top_face[OF assms(1) allp,symmetric]] ..
then guess a ..
ultimately show "\<exists>s a. ksimplex p (n + 1) s \<and>
a \<in> s \<and> f = s - {a} \<and>
reduced lab (n + 1) ` f = {0..n} \<and>
((\<exists>j\<in>{1..n + 1}. \<forall>x\<in>f. x j = 0) \<or> (\<exists>j\<in>{1..n + 1}. \<forall>x\<in>f. x j = p))"
apply (rule_tac x = s in exI)
apply (rule_tac x = a in exI)
unfolding complete_face_top[OF *]
using allp as(1)
apply auto
done
next
fix f
assume as: "\<exists>s a. ksimplex p (n + 1) s \<and>
a \<in> s \<and> f = s - {a} \<and> reduced lab (n + 1) ` f = {0..n} \<and>
((\<exists>j\<in>{1..n + 1}. \<forall>x\<in>f. x j = 0) \<or> (\<exists>j\<in>{1..n + 1}. \<forall>x\<in>f. x j = p))"
then guess s ..
then guess a by (elim exE conjE) note sa = this
{
fix x
assume "x \<in> f"
then have "reduced lab (n + 1) x \<in> reduced lab (n + 1) ` f"
by auto
then have "reduced lab (n + 1) x < n + 1"
using sa(4) by auto
then have "reduced lab (n + 1) x = reduced lab n x"
apply -
apply (rule reduced_labelling_Suc)
using reduced_labelling(1)
apply auto
done
}
then show part1: "reduced lab n ` f = {0..n}"
unfolding sa(4)[symmetric]
apply -
apply (rule set_eqI)
unfolding image_iff
apply auto
done
have *: "\<forall>x\<in>f. x (n + 1) = p"
proof (cases "\<exists>j\<in>{1..n + 1}. \<forall>x\<in>f. x j = 0")
case True
then guess j ..
then have "\<And>x. x \<in> f \<Longrightarrow> reduced lab (n + 1) x \<noteq> j - 1"
apply -
apply (rule reduced_labelling_zero)
apply assumption
apply (rule assms(2)[rule_format])
using sa(1)[unfolded ksimplex_def]
unfolding sa
apply auto
done
moreover
have "j - 1 \<in> {0..n}"
using `j\<in>{1..n+1}` by auto
ultimately have False
unfolding sa(4)[symmetric]
unfolding image_iff
by fastforce
then show ?thesis
by auto
next
case False
then have "\<exists>j\<in>{1..n + 1}. \<forall>x\<in>f. x j = p"
using sa(5) by fastforce then guess j .. note j=this
then show ?thesis
proof (cases "j = n + 1")
case False
then have *: "j \<in> {1..n}"
using j by auto
then have "\<And>x. x \<in> f \<Longrightarrow> reduced lab n x < j"
apply (rule reduced_labelling_nonzero)
proof -
fix x
assume "x \<in> f"
then have "lab x j = 1"
apply -
apply (rule assms(3)[rule_format,OF j(1)])
using sa(1)[unfolded ksimplex_def]
using j
unfolding sa
apply auto
done
then show "lab x j \<noteq> 0"
by auto
qed
moreover have "j \<in> {0..n}"
using * by auto
ultimately have False
unfolding part1[symmetric]
using * unfolding image_iff
by auto
then show ?thesis
by auto
qed auto
qed
then show "ksimplex p n f"
using as
unfolding simplex_top_face[OF assms(1) *,symmetric]
by auto
qed
qed
lemma kuhn_induction_Suc:
assumes "0 < p"
and "\<forall>x. \<forall>j\<in>{1..Suc n}. (\<forall>j. x j \<le> p) \<and> x j = 0 \<longrightarrow> lab x j = 0"
and "\<forall>x. \<forall>j\<in>{1..Suc n}. (\<forall>j. x j \<le> p) \<and> x j = p \<longrightarrow> lab x j = 1"
and "odd (card {f. ksimplex p n f \<and> reduced lab n ` f = {0..n}})"
shows "odd (card {s. ksimplex p (Suc n) s \<and> reduced lab (Suc n) ` s = {0..Suc n}})"
using assms
unfolding Suc_eq_plus1
by (rule kuhn_induction)
text {* And so we get the final combinatorial result. *}
lemma ksimplex_0: "ksimplex p 0 s \<longleftrightarrow> s = {(\<lambda>x. p)}"
(is "?l = ?r")
proof
assume l: ?l
guess a using ksimplexD(3)[OF l, unfolded add_0] unfolding card_1_exists .. note a = this
have "a = (\<lambda>x. p)"
using ksimplexD(5)[OF l, rule_format, OF a(1)]
by rule auto
then show ?r
using a by auto
next
assume r: ?r
show ?l
unfolding r ksimplex_eq by auto
qed
lemma reduce_labelling_zero[simp]: "reduced lab 0 x = 0"
by (rule reduced_labelling_unique) auto
lemma kuhn_combinatorial:
assumes "0 < p"
and "\<forall>x j. (\<forall>j. x j \<le> p) \<and> 1 \<le> j \<and> j \<le> n \<and> x j = 0 \<longrightarrow> lab x j = 0"
and "\<forall>x j. (\<forall>j. x j \<le> p) \<and> 1 \<le> j \<and> j \<le> n \<and> x j = p \<longrightarrow> lab x j = 1"
shows "odd (card {s. ksimplex p n s \<and> reduced lab n ` s = {0..n}})"
using assms
proof (induct n)
let ?M = "\<lambda>n. {s. ksimplex p n s \<and> reduced lab n ` s = {0..n}}"
{
case 0
have *: "?M 0 = {{\<lambda>x. p}}"
unfolding ksimplex_0 by auto
show ?case
unfolding * by auto
next
case (Suc n)
have "odd (card (?M n))"
apply (rule Suc(1)[OF Suc(2)])
using Suc(3-)
apply auto
done
then show ?case
apply -
apply (rule kuhn_induction_Suc)
using Suc(2-)
apply auto
done
}
qed
lemma kuhn_lemma:
fixes n p :: nat
assumes "0 < p"
and "0 < n"
and "\<forall>x. (\<forall>i\<in>{1..n}. x i \<le> p) \<longrightarrow> (\<forall>i\<in>{1..n}. label x i = (0::nat) \<or> label x i = 1)"
and "\<forall>x. (\<forall>i\<in>{1..n}. x i \<le> p) \<longrightarrow> (\<forall>i\<in>{1..n}. x i = 0 \<longrightarrow> label x i = 0)"
and "\<forall>x. (\<forall>i\<in>{1..n}. x i \<le> p) \<longrightarrow> (\<forall>i\<in>{1..n}. x i = p \<longrightarrow> label x i = 1)"
obtains q where "\<forall>i\<in>{1..n}. q i < p"
and "\<forall>i\<in>{1..n}. \<exists>r s.
(\<forall>j\<in>{1..n}. q j \<le> r j \<and> r j \<le> q j + 1) \<and>
(\<forall>j\<in>{1..n}. q j \<le> s j \<and> s j \<le> q j + 1) \<and>
label r i \<noteq> label s i"
proof -
let ?A = "{s. ksimplex p n s \<and> reduced label n ` s = {0..n}}"
have "n \<noteq> 0"
using assms by auto
have conjD: "\<And>P Q. P \<and> Q \<Longrightarrow> P" "\<And>P Q. P \<and> Q \<Longrightarrow> Q"
by auto
have "odd (card ?A)"
apply (rule kuhn_combinatorial[of p n label])
using assms
apply auto
done
then have "card ?A \<noteq> 0"
apply -
apply (rule ccontr)
apply auto
done
then have "?A \<noteq> {}"
unfolding card_eq_0_iff by auto
then obtain s where "s \<in> ?A"
by auto note s=conjD[OF this[unfolded mem_Collect_eq]]
guess a b by (rule ksimplex_extrema_strong[OF s(1) `n \<noteq> 0`]) note ab = this
show ?thesis
apply (rule that[of a])
apply (rule_tac[!] ballI)
proof -
fix i
assume "i \<in> {1..n}"
then have "a i + 1 \<le> p"
apply -
apply (rule order_trans[of _ "b i"])
apply (subst ab(5)[THEN spec[where x=i]])
using s(1)[unfolded ksimplex_def]
defer
apply -
apply (erule conjE)+
apply (drule_tac bspec[OF _ ab(2)])+
apply auto
done
then show "a i < p"
by auto
next
case goal2
then have "i \<in> reduced label n ` s"
using s by auto
then guess u unfolding image_iff .. note u = this
from goal2 have "i - 1 \<in> reduced label n ` s"
using s by auto
then guess v unfolding image_iff .. note v = this
show ?case
apply (rule_tac x = u in exI)
apply (rule_tac x = v in exI)
apply (rule conjI)
defer
apply (rule conjI)
defer 2
apply (rule_tac[1-2] ballI)
proof -
show "label u i \<noteq> label v i"
using reduced_labelling [of label n u] reduced_labelling [of label n v]
unfolding u(2)[symmetric] v(2)[symmetric]
using goal2
apply auto
done
fix j
assume j: "j \<in> {1..n}"
show "a j \<le> u j \<and> u j \<le> a j + 1" and "a j \<le> v j \<and> v j \<le> a j + 1"
using conjD[OF ab(4)[rule_format, OF u(1)]]
and conjD[OF ab(4)[rule_format, OF v(1)]]
apply -
apply (drule_tac[!] kle_imp_pointwise)+
apply (erule_tac[!] x=j in allE)+
unfolding ab(5)[rule_format]
using j
apply auto
done
qed
qed
qed
subsection {* The main result for the unit cube *}
lemma kuhn_labelling_lemma':
assumes "(\<forall>x::nat\<Rightarrow>real. P x \<longrightarrow> P (f x))"
and "\<forall>x. P x \<longrightarrow> (\<forall>i::nat. Q i \<longrightarrow> 0 \<le> x i \<and> x i \<le> 1)"
shows "\<exists>l. (\<forall>x i. l x i \<le> (1::nat)) \<and>
(\<forall>x i. P x \<and> Q i \<and> x i = 0 \<longrightarrow> l x i = 0) \<and>
(\<forall>x i. P x \<and> Q i \<and> x i = 1 \<longrightarrow> l x i = 1) \<and>
(\<forall>x i. P x \<and> Q i \<and> l x i = 0 \<longrightarrow> x i \<le> f x i) \<and>
(\<forall>x i. P x \<and> Q i \<and> l x i = 1 \<longrightarrow> f x i \<le> x i)"
proof -
have and_forall_thm: "\<And>P Q. (\<forall>x. P x) \<and> (\<forall>x. Q x) \<longleftrightarrow> (\<forall>x. P x \<and> Q x)"
by auto
have *: "\<forall>x y::real. 0 \<le> x \<and> x \<le> 1 \<and> 0 \<le> y \<and> y \<le> 1 \<longrightarrow> x \<noteq> 1 \<and> x \<le> y \<or> x \<noteq> 0 \<and> y \<le> x"
by auto
show ?thesis
unfolding and_forall_thm
apply (subst choice_iff[symmetric])+
apply rule
apply rule
proof -
case goal1
let ?R = "\<lambda>y::nat.
(P x \<and> Q xa \<and> x xa = 0 \<longrightarrow> y = 0) \<and>
(P x \<and> Q xa \<and> x xa = 1 \<longrightarrow> y = 1) \<and>
(P x \<and> Q xa \<and> y = 0 \<longrightarrow> x xa \<le> (f x) xa) \<and>
(P x \<and> Q xa \<and> y = 1 \<longrightarrow> (f x) xa \<le> x xa)"
{
assume "P x" and "Q xa"
then have "0 \<le> f x xa \<and> f x xa \<le> 1"
using assms(2)[rule_format,of "f x" xa]
apply (drule_tac assms(1)[rule_format])
apply auto
done
}
then have "?R 0 \<or> ?R 1"
by auto
then show ?case
by auto
qed
qed
lemma brouwer_cube:
fixes f :: "'a::ordered_euclidean_space \<Rightarrow> 'a::ordered_euclidean_space"
assumes "continuous_on {0..(\<Sum>Basis)} f"
and "f ` {0..(\<Sum>Basis)} \<subseteq> {0..(\<Sum>Basis)}"
shows "\<exists>x\<in>{0..(\<Sum>Basis)}. f x = x"
proof (rule ccontr)
def n \<equiv> "DIM('a)"
have n: "1 \<le> n" "0 < n" "n \<noteq> 0"
unfolding n_def by (auto simp add: Suc_le_eq DIM_positive)
assume "\<not> ?thesis"
then have *: "\<not> (\<exists>x\<in>{0..\<Sum>Basis}. f x - x = 0)"
by auto
guess d
apply (rule brouwer_compactness_lemma[OF compact_interval _ *])
apply (rule continuous_on_intros assms)+
done
note d = this [rule_format]
have *: "\<forall>x. x \<in> {0..\<Sum>Basis} \<longrightarrow> f x \<in> {0..\<Sum>Basis}" "\<forall>x. x \<in> {0..(\<Sum>Basis)::'a} \<longrightarrow>
(\<forall>i\<in>Basis. True \<longrightarrow> 0 \<le> x \<bullet> i \<and> x \<bullet> i \<le> 1)"
using assms(2)[unfolded image_subset_iff Ball_def]
unfolding mem_interval by auto
guess label using kuhn_labelling_lemma[OF *] by (elim exE conjE)
note label = this [rule_format]
have lem1: "\<forall>x\<in>{0..\<Sum>Basis}.\<forall>y\<in>{0..\<Sum>Basis}.\<forall>i\<in>Basis. label x i \<noteq> label y i \<longrightarrow>
abs (f x \<bullet> i - x \<bullet> i) \<le> norm (f y - f x) + norm (y - x)"
proof safe
fix x y :: 'a
assume x: "x \<in> {0..\<Sum>Basis}"
assume y: "y \<in> {0..\<Sum>Basis}"
fix i
assume i: "label x i \<noteq> label y i" "i \<in> Basis"
have *: "\<And>x y fx fy :: real. x \<le> fx \<and> fy \<le> y \<or> fx \<le> x \<and> y \<le> fy \<Longrightarrow>
abs (fx - x) \<le> abs (fy - fx) + abs (y - x)" by auto
have "\<bar>(f x - x) \<bullet> i\<bar> \<le> abs ((f y - f x)\<bullet>i) + abs ((y - x)\<bullet>i)"
unfolding inner_simps
apply (rule *)
apply (cases "label x i = 0")
apply (rule disjI1)
apply rule
prefer 3
apply (rule disjI2)
apply rule
proof -
assume lx: "label x i = 0"
then have ly: "label y i = 1"
using i label(1)[of i y]
by auto
show "x \<bullet> i \<le> f x \<bullet> i"
apply (rule label(4)[rule_format])
using x y lx i(2)
apply auto
done
show "f y \<bullet> i \<le> y \<bullet> i"
apply (rule label(5)[rule_format])
using x y ly i(2)
apply auto
done
next
assume "label x i \<noteq> 0"
then have l: "label x i = 1" "label y i = 0"
using i label(1)[of i x] label(1)[of i y]
by auto
show "f x \<bullet> i \<le> x \<bullet> i"
apply (rule label(5)[rule_format])
using x y l i(2)
apply auto
done
show "y \<bullet> i \<le> f y \<bullet> i"
apply (rule label(4)[rule_format])
using x y l i(2)
apply auto
done
qed
also have "\<dots> \<le> norm (f y - f x) + norm (y - x)"
apply (rule add_mono)
apply (rule Basis_le_norm[OF i(2)])+
done
finally show "\<bar>f x \<bullet> i - x \<bullet> i\<bar> \<le> norm (f y - f x) + norm (y - x)"
unfolding inner_simps .
qed
have "\<exists>e>0. \<forall>x\<in>{0..\<Sum>Basis}. \<forall>y\<in>{0..\<Sum>Basis}. \<forall>z\<in>{0..\<Sum>Basis}. \<forall>i\<in>Basis.
norm (x - z) < e \<and> norm (y - z) < e \<and> label x i \<noteq> label y i \<longrightarrow>
abs ((f(z) - z)\<bullet>i) < d / (real n)"
proof -
have d': "d / real n / 8 > 0"
apply (rule divide_pos_pos)+
using d(1)
unfolding n_def
apply (auto simp: DIM_positive)
done
have *: "uniformly_continuous_on {0..\<Sum>Basis} f"
by (rule compact_uniformly_continuous[OF assms(1) compact_interval])
guess e using *[unfolded uniformly_continuous_on_def,rule_format,OF d'] by (elim exE conjE)
note e=this[rule_format,unfolded dist_norm]
show ?thesis
apply (rule_tac x="min (e/2) (d/real n/8)" in exI)
apply safe
proof -
show "0 < min (e / 2) (d / real n / 8)"
using d' e by auto
fix x y z i
assume as:
"x \<in> {0..\<Sum>Basis}" "y \<in> {0..\<Sum>Basis}" "z \<in> {0..\<Sum>Basis}"
"norm (x - z) < min (e / 2) (d / real n / 8)"
"norm (y - z) < min (e / 2) (d / real n / 8)"
"label x i \<noteq> label y i"
assume i: "i \<in> Basis"
have *: "\<And>z fz x fx n1 n2 n3 n4 d4 d :: real. abs(fx - x) \<le> n1 + n2 \<Longrightarrow>
abs (fx - fz) \<le> n3 \<Longrightarrow> abs (x - z) \<le> n4 \<Longrightarrow>
n1 < d4 \<Longrightarrow> n2 < 2 * d4 \<Longrightarrow> n3 < d4 \<Longrightarrow> n4 < d4 \<Longrightarrow>
(8 * d4 = d) \<Longrightarrow> abs(fz - z) < d"
by auto
show "\<bar>(f z - z) \<bullet> i\<bar> < d / real n"
unfolding inner_simps
proof (rule *)
show "\<bar>f x \<bullet> i - x \<bullet> i\<bar> \<le> norm (f y -f x) + norm (y - x)"
apply (rule lem1[rule_format])
using as i
apply auto
done
show "\<bar>f x \<bullet> i - f z \<bullet> i\<bar> \<le> norm (f x - f z)" "\<bar>x \<bullet> i - z \<bullet> i\<bar> \<le> norm (x - z)"
unfolding inner_diff_left[symmetric]
by (rule Basis_le_norm[OF i])+
have tria: "norm (y - x) \<le> norm (y - z) + norm (x - z)"
using dist_triangle[of y x z, unfolded dist_norm]
unfolding norm_minus_commute
by auto
also have "\<dots> < e / 2 + e / 2"
apply (rule add_strict_mono)
using as(4,5)
apply auto
done
finally show "norm (f y - f x) < d / real n / 8"
apply -
apply (rule e(2))
using as
apply auto
done
have "norm (y - z) + norm (x - z) < d / real n / 8 + d / real n / 8"
apply (rule add_strict_mono)
using as
apply auto
done
then show "norm (y - x) < 2 * (d / real n / 8)"
using tria
by auto
show "norm (f x - f z) < d / real n / 8"
apply (rule e(2))
using as e(1)
apply auto
done
qed (insert as, auto)
qed
qed
then guess e by (elim exE conjE) note e=this[rule_format]
guess p using real_arch_simple[of "1 + real n / e"] .. note p=this
have "1 + real n / e > 0"
apply (rule add_pos_pos)
defer
apply (rule divide_pos_pos)
using e(1) n
apply auto
done
then have "p > 0"
using p by auto
obtain b :: "nat \<Rightarrow> 'a" where b: "bij_betw b {1..n} Basis"
by atomize_elim (auto simp: n_def intro!: finite_same_card_bij)
def b' \<equiv> "inv_into {1..n} b"
then have b': "bij_betw b' Basis {1..n}"
using bij_betw_inv_into[OF b] by auto
then have b'_Basis: "\<And>i. i \<in> Basis \<Longrightarrow> b' i \<in> {Suc 0 .. n}"
unfolding bij_betw_def by (auto simp: set_eq_iff)
have bb'[simp]:"\<And>i. i \<in> Basis \<Longrightarrow> b (b' i) = i"
unfolding b'_def
using b
by (auto simp: f_inv_into_f bij_betw_def)
have b'b[simp]:"\<And>i. i \<in> {1..n} \<Longrightarrow> b' (b i) = i"
unfolding b'_def
using b
by (auto simp: inv_into_f_eq bij_betw_def)
have *: "\<And>x :: nat. x = 0 \<or> x = 1 \<longleftrightarrow> x \<le> 1"
by auto
have b'': "\<And>j. j \<in> {Suc 0..n} \<Longrightarrow> b j \<in> Basis"
using b unfolding bij_betw_def by auto
have q1: "0 < p" "0 < n" "\<forall>x. (\<forall>i\<in>{1..n}. x i \<le> p) \<longrightarrow>
(\<forall>i\<in>{1..n}. (label (\<Sum>i\<in>Basis. (real (x (b' i)) / real p) *\<^sub>R i) \<circ> b) i = 0 \<or>
(label (\<Sum>i\<in>Basis. (real (x (b' i)) / real p) *\<^sub>R i) \<circ> b) i = 1)"
unfolding *
using `p > 0` `n > 0`
using label(1)[OF b'']
by auto
have q2: "\<forall>x. (\<forall>i\<in>{1..n}. x i \<le> p) \<longrightarrow> (\<forall>i\<in>{1..n}. x i = 0 \<longrightarrow>
(label (\<Sum>i\<in>Basis. (real (x (b' i)) / real p) *\<^sub>R i) \<circ> b) i = 0)"
"\<forall>x. (\<forall>i\<in>{1..n}. x i \<le> p) \<longrightarrow> (\<forall>i\<in>{1..n}. x i = p \<longrightarrow>
(label (\<Sum>i\<in>Basis. (real (x (b' i)) / real p) *\<^sub>R i) \<circ> b) i = 1)"
apply rule
apply rule
apply rule
apply rule
defer
apply rule
apply rule
apply rule
apply rule
proof -
fix x i
assume as: "\<forall>i\<in>{1..n}. x i \<le> p" "i \<in> {1..n}"
{
assume "x i = p \<or> x i = 0"
have "(\<Sum>i\<in>Basis. (real (x (b' i)) / real p) *\<^sub>R i) \<in> {0::'a..\<Sum>Basis}"
unfolding mem_interval
using as b'_Basis
by (auto simp add: inner_simps bij_betw_def zero_le_divide_iff divide_le_eq_1)
}
note cube = this
{
assume "x i = p"
then show "(label (\<Sum>i\<in>Basis. (real (x (b' i)) / real p) *\<^sub>R i) \<circ> b) i = 1"
unfolding o_def
using cube as `p > 0`
by (intro label(3)) (auto simp add: b'')
}
{
assume "x i = 0"
then show "(label (\<Sum>i\<in>Basis. (real (x (b' i)) / real p) *\<^sub>R i) \<circ> b) i = 0"
unfolding o_def using cube as `p > 0`
by (intro label(2)) (auto simp add: b'')
}
qed
guess q by (rule kuhn_lemma[OF q1 q2]) note q = this
def z \<equiv> "(\<Sum>i\<in>Basis. (real (q (b' i)) / real p) *\<^sub>R i)::'a"
have "\<exists>i\<in>Basis. d / real n \<le> abs ((f z - z)\<bullet>i)"
proof (rule ccontr)
have "\<forall>i\<in>Basis. q (b' i) \<in> {0..p}"
using q(1) b'
by (auto intro: less_imp_le simp: bij_betw_def)
then have "z \<in> {0..\<Sum>Basis}"
unfolding z_def mem_interval
using b'_Basis
by (auto simp add: inner_simps bij_betw_def zero_le_divide_iff divide_le_eq_1)
then have d_fz_z: "d \<le> norm (f z - z)"
by (rule d)
assume "\<not> ?thesis"
then have as: "\<forall>i\<in>Basis. \<bar>f z \<bullet> i - z \<bullet> i\<bar> < d / real n"
using `n > 0`
by (auto simp add: not_le inner_simps)
have "norm (f z - z) \<le> (\<Sum>i\<in>Basis. \<bar>f z \<bullet> i - z \<bullet> i\<bar>)"
unfolding inner_diff_left[symmetric]
by (rule norm_le_l1)
also have "\<dots> < (\<Sum>(i::'a) \<in> Basis. d / real n)"
apply (rule setsum_strict_mono)
using as
apply auto
done
also have "\<dots> = d"
using DIM_positive[where 'a='a]
by (auto simp: real_eq_of_nat n_def)
finally show False
using d_fz_z by auto
qed
then guess i .. note i = this
have *: "b' i \<in> {1..n}"
using i
using b'[unfolded bij_betw_def]
by auto
guess r using q(2)[rule_format,OF *] ..
then guess s by (elim exE conjE) note rs = this[rule_format]
have b'_im: "\<And>i. i \<in> Basis \<Longrightarrow> b' i \<in> {1..n}"
using b' unfolding bij_betw_def by auto
def r' \<equiv> "(\<Sum>i\<in>Basis. (real (r (b' i)) / real p) *\<^sub>R i)::'a"
have "\<And>i. i \<in> Basis \<Longrightarrow> r (b' i) \<le> p"
apply (rule order_trans)
apply (rule rs(1)[OF b'_im,THEN conjunct2])
using q(1)[rule_format,OF b'_im]
apply (auto simp add: Suc_le_eq)
done
then have "r' \<in> {0..\<Sum>Basis}"
unfolding r'_def mem_interval
using b'_Basis
by (auto simp add: inner_simps bij_betw_def zero_le_divide_iff divide_le_eq_1)
def s' \<equiv> "(\<Sum>i\<in>Basis. (real (s (b' i)) / real p) *\<^sub>R i)::'a"
have "\<And>i. i \<in> Basis \<Longrightarrow> s (b' i) \<le> p"
apply (rule order_trans)
apply (rule rs(2)[OF b'_im, THEN conjunct2])
using q(1)[rule_format,OF b'_im]
apply (auto simp add: Suc_le_eq)
done
then have "s' \<in> {0..\<Sum>Basis}"
unfolding s'_def mem_interval
using b'_Basis
by (auto simp add: inner_simps bij_betw_def zero_le_divide_iff divide_le_eq_1)
have "z \<in> {0..\<Sum>Basis}"
unfolding z_def mem_interval
using b'_Basis q(1)[rule_format,OF b'_im] `p > 0`
by (auto simp add: inner_simps bij_betw_def zero_le_divide_iff divide_le_eq_1 less_imp_le)
have *: "\<And>x. 1 + real x = real (Suc x)"
by auto
{
have "(\<Sum>i\<in>Basis. \<bar>real (r (b' i)) - real (q (b' i))\<bar>) \<le> (\<Sum>(i::'a)\<in>Basis. 1)"
apply (rule setsum_mono)
using rs(1)[OF b'_im]
apply (auto simp add:* field_simps)
done
also have "\<dots> < e * real p"
using p `e > 0` `p > 0`
by (auto simp add: field_simps n_def real_of_nat_def)
finally have "(\<Sum>i\<in>Basis. \<bar>real (r (b' i)) - real (q (b' i))\<bar>) < e * real p" .
}
moreover
{
have "(\<Sum>i\<in>Basis. \<bar>real (s (b' i)) - real (q (b' i))\<bar>) \<le> (\<Sum>(i::'a)\<in>Basis. 1)"
apply (rule setsum_mono)
using rs(2)[OF b'_im]
apply (auto simp add:* field_simps)
done
also have "\<dots> < e * real p"
using p `e > 0` `p > 0`
by (auto simp add: field_simps n_def real_of_nat_def)
finally have "(\<Sum>i\<in>Basis. \<bar>real (s (b' i)) - real (q (b' i))\<bar>) < e * real p" .
}
ultimately
have "norm (r' - z) < e" and "norm (s' - z) < e"
unfolding r'_def s'_def z_def
using `p > 0`
apply (rule_tac[!] le_less_trans[OF norm_le_l1])
apply (auto simp add: field_simps setsum_divide_distrib[symmetric] inner_diff_left)
done
then have "\<bar>(f z - z) \<bullet> i\<bar> < d / real n"
using rs(3) i
unfolding r'_def[symmetric] s'_def[symmetric] o_def bb'
by (intro e(2)[OF `r'\<in>{0..\<Sum>Basis}` `s'\<in>{0..\<Sum>Basis}` `z\<in>{0..\<Sum>Basis}`]) auto
then show False
using i by auto
qed
subsection {* Retractions *}
definition "retraction s t r \<longleftrightarrow> t \<subseteq> s \<and> continuous_on s r \<and> r ` s \<subseteq> t \<and> (\<forall>x\<in>t. r x = x)"
definition retract_of (infixl "retract'_of" 12)
where "(t retract_of s) \<longleftrightarrow> (\<exists>r. retraction s t r)"
lemma retraction_idempotent: "retraction s t r \<Longrightarrow> x \<in> s \<Longrightarrow> r (r x) = r x"
unfolding retraction_def by auto
subsection {* Preservation of fixpoints under (more general notion of) retraction *}
lemma invertible_fixpoint_property:
fixes s :: "'a::euclidean_space set"
and t :: "'b::euclidean_space set"
assumes "continuous_on t i"
and "i ` t \<subseteq> s"
and "continuous_on s r"
and "r ` s \<subseteq> t"
and "\<forall>y\<in>t. r (i y) = y"
and "\<forall>f. continuous_on s f \<and> f ` s \<subseteq> s \<longrightarrow> (\<exists>x\<in>s. f x = x)"
and "continuous_on t g"
and "g ` t \<subseteq> t"
obtains y where "y \<in> t" and "g y = y"
proof -
have "\<exists>x\<in>s. (i \<circ> g \<circ> r) x = x"
apply (rule assms(6)[rule_format])
apply rule
apply (rule continuous_on_compose assms)+
apply ((rule continuous_on_subset)?, rule assms)+
using assms(2,4,8)
unfolding image_compose
apply auto
apply blast
done
then guess x .. note x = this
then have *: "g (r x) \<in> t"
using assms(4,8) by auto
have "r ((i \<circ> g \<circ> r) x) = r x"
using x by auto
then show ?thesis
apply (rule_tac that[of "r x"])
using x
unfolding o_def
unfolding assms(5)[rule_format,OF *]
using assms(4)
apply auto
done
qed
lemma homeomorphic_fixpoint_property:
fixes s :: "'a::euclidean_space set"
and t :: "'b::euclidean_space set"
assumes "s homeomorphic t"
shows "(\<forall>f. continuous_on s f \<and> f ` s \<subseteq> s \<longrightarrow> (\<exists>x\<in>s. f x = x)) \<longleftrightarrow>
(\<forall>g. continuous_on t g \<and> g ` t \<subseteq> t \<longrightarrow> (\<exists>y\<in>t. g y = y))"
proof -
guess r using assms[unfolded homeomorphic_def homeomorphism_def] ..
then guess i ..
then show ?thesis
apply -
apply rule
apply (rule_tac[!] allI impI)+
apply (rule_tac g=g in invertible_fixpoint_property[of t i s r])
prefer 10
apply (rule_tac g=f in invertible_fixpoint_property[of s r t i])
apply auto
done
qed
lemma retract_fixpoint_property:
fixes f :: "'a::euclidean_space \<Rightarrow> 'b::euclidean_space"
and s :: "'a set"
assumes "t retract_of s"
and "\<forall>f. continuous_on s f \<and> f ` s \<subseteq> s \<longrightarrow> (\<exists>x\<in>s. f x = x)"
and "continuous_on t g"
and "g ` t \<subseteq> t"
obtains y where "y \<in> t" and "g y = y"
proof -
guess h using assms(1) unfolding retract_of_def ..
then show ?thesis
unfolding retraction_def
apply -
apply (rule invertible_fixpoint_property[OF continuous_on_id _ _ _ _ assms(2), of t h g])
prefer 7
apply (rule_tac y = y in that)
using assms
apply auto
done
qed
subsection {* The Brouwer theorem for any set with nonempty interior *}
lemma brouwer_weak:
fixes f :: "'a::ordered_euclidean_space \<Rightarrow> 'a::ordered_euclidean_space"
assumes "compact s"
and "convex s"
and "interior s \<noteq> {}"
and "continuous_on s f"
and "f ` s \<subseteq> s"
obtains x where "x \<in> s" and "f x = x"
proof -
have *: "interior {0::'a..\<Sum>Basis} \<noteq> {}"
unfolding interior_closed_interval interval_eq_empty
by auto
have *: "{0::'a..\<Sum>Basis} homeomorphic s"
using homeomorphic_convex_compact[OF convex_interval(1) compact_interval * assms(2,1,3)] .
have "\<forall>f. continuous_on {0::'a..\<Sum>Basis} f \<and> f ` {0::'a..\<Sum>Basis} \<subseteq> {0::'a..\<Sum>Basis} \<longrightarrow>
(\<exists>x\<in>{0::'a..\<Sum>Basis}. f x = x)"
using brouwer_cube by auto
then show ?thesis
unfolding homeomorphic_fixpoint_property[OF *]
apply (erule_tac x=f in allE)
apply (erule impE)
defer
apply (erule bexE)
apply (rule_tac x=y in that)
using assms
apply auto
done
qed
text {* And in particular for a closed ball. *}
lemma brouwer_ball:
fixes f :: "'a::ordered_euclidean_space \<Rightarrow> 'a"
assumes "e > 0"
and "continuous_on (cball a e) f"
and "f ` cball a e \<subseteq> cball a e"
obtains x where "x \<in> cball a e" and "f x = x"
using brouwer_weak[OF compact_cball convex_cball, of a e f]
unfolding interior_cball ball_eq_empty
using assms by auto
text {*Still more general form; could derive this directly without using the
rather involved @{text "HOMEOMORPHIC_CONVEX_COMPACT"} theorem, just using
a scaling and translation to put the set inside the unit cube. *}
lemma brouwer:
fixes f :: "'a::ordered_euclidean_space \<Rightarrow> 'a"
assumes "compact s"
and "convex s"
and "s \<noteq> {}"
and "continuous_on s f"
and "f ` s \<subseteq> s"
obtains x where "x \<in> s" and "f x = x"
proof -
have "\<exists>e>0. s \<subseteq> cball 0 e"
using compact_imp_bounded[OF assms(1)]
unfolding bounded_pos
apply (erule_tac exE)
apply (rule_tac x=b in exI)
apply (auto simp add: dist_norm)
done
then guess e by (elim exE conjE)
note e = this
have "\<exists>x\<in> cball 0 e. (f \<circ> closest_point s) x = x"
apply (rule_tac brouwer_ball[OF e(1), of 0 "f \<circ> closest_point s"])
apply (rule continuous_on_compose )
apply (rule continuous_on_closest_point[OF assms(2) compact_imp_closed[OF assms(1)] assms(3)])
apply (rule continuous_on_subset[OF assms(4)])
apply (insert closest_point_in_set[OF compact_imp_closed[OF assms(1)] assms(3)])
defer
using assms(5)[unfolded subset_eq]
using e(2)[unfolded subset_eq mem_cball]
apply (auto simp add: dist_norm)
done
then guess x .. note x=this
have *: "closest_point s x = x"
apply (rule closest_point_self)
apply (rule assms(5)[unfolded subset_eq,THEN bspec[where x="x"], unfolded image_iff])
apply (rule_tac x="closest_point s x" in bexI)
using x
unfolding o_def
using closest_point_in_set[OF compact_imp_closed[OF assms(1)] assms(3), of x]
apply auto
done
show thesis
apply (rule_tac x="closest_point s x" in that)
unfolding x(2)[unfolded o_def]
apply (rule closest_point_in_set[OF compact_imp_closed[OF assms(1)] assms(3)])
using *
apply auto
done
qed
text {*So we get the no-retraction theorem. *}
lemma no_retraction_cball:
fixes a :: "'a::ordered_euclidean_space"
assumes "e > 0"
shows "\<not> (frontier (cball a e) retract_of (cball a e))"
proof
case goal1
have *: "\<And>xa. a - (2 *\<^sub>R a - xa) = - (a - xa)"
using scaleR_left_distrib[of 1 1 a] by auto
guess x
apply (rule retract_fixpoint_property[OF goal1, of "\<lambda>x. scaleR 2 a - x"])
apply rule
apply rule
apply (erule conjE)
apply (rule brouwer_ball[OF assms])
apply assumption+
apply (rule_tac x=x in bexI)
apply assumption+
apply (rule continuous_on_intros)+
unfolding frontier_cball subset_eq Ball_def image_iff
apply rule
apply rule
apply (erule bexE)
unfolding dist_norm
apply (simp add: * norm_minus_commute)
done
note x = this
then have "scaleR 2 a = scaleR 1 x + scaleR 1 x"
by (auto simp add: algebra_simps)
then have "a = x"
unfolding scaleR_left_distrib[symmetric]
by auto
then show False
using x assms by auto
qed
subsection {*Bijections between intervals. *}
definition interval_bij :: "'a \<times> 'a \<Rightarrow> 'a \<times> 'a \<Rightarrow> 'a \<Rightarrow> 'a::ordered_euclidean_space"
where "interval_bij =
(\<lambda>(a, b) (u, v) x. (\<Sum>i\<in>Basis. (u\<bullet>i + (x\<bullet>i - a\<bullet>i) / (b\<bullet>i - a\<bullet>i) * (v\<bullet>i - u\<bullet>i)) *\<^sub>R i))"
lemma interval_bij_affine:
"interval_bij (a,b) (u,v) = (\<lambda>x. (\<Sum>i\<in>Basis. ((v\<bullet>i - u\<bullet>i) / (b\<bullet>i - a\<bullet>i) * (x\<bullet>i)) *\<^sub>R i) +
(\<Sum>i\<in>Basis. (u\<bullet>i - (v\<bullet>i - u\<bullet>i) / (b\<bullet>i - a\<bullet>i) * (a\<bullet>i)) *\<^sub>R i))"
by (auto simp: setsum_addf[symmetric] scaleR_add_left[symmetric] interval_bij_def fun_eq_iff
field_simps inner_simps add_divide_distrib[symmetric] intro!: setsum_cong)
lemma continuous_interval_bij:
fixes a b :: "'a::ordered_euclidean_space"
shows "continuous (at x) (interval_bij (a, b) (u, v))"
by (auto simp add: divide_inverse interval_bij_def intro!: continuous_setsum continuous_intros)
lemma continuous_on_interval_bij: "continuous_on s (interval_bij (a, b) (u, v))"
apply(rule continuous_at_imp_continuous_on)
apply (rule, rule continuous_interval_bij)
done
lemma in_interval_interval_bij:
fixes a b u v x :: "'a::ordered_euclidean_space"
assumes "x \<in> {a..b}"
and "{u..v} \<noteq> {}"
shows "interval_bij (a, b) (u, v) x \<in> {u..v}"
apply (simp only: interval_bij_def split_conv mem_interval inner_setsum_left_Basis cong: ball_cong)
apply safe
proof -
fix i :: 'a
assume i: "i \<in> Basis"
have "{a..b} \<noteq> {}"
using assms by auto
with i have *: "a\<bullet>i \<le> b\<bullet>i" "u\<bullet>i \<le> v\<bullet>i"
using assms(2) by (auto simp add: interval_eq_empty interval)
have x: "a\<bullet>i\<le>x\<bullet>i" "x\<bullet>i\<le>b\<bullet>i"
using assms(1)[unfolded mem_interval] using i by auto
have "0 \<le> (x \<bullet> i - a \<bullet> i) / (b \<bullet> i - a \<bullet> i) * (v \<bullet> i - u \<bullet> i)"
using * x by (auto intro!: mult_nonneg_nonneg divide_nonneg_nonneg)
then show "u \<bullet> i \<le> u \<bullet> i + (x \<bullet> i - a \<bullet> i) / (b \<bullet> i - a \<bullet> i) * (v \<bullet> i - u \<bullet> i)"
using * by auto
have "((x \<bullet> i - a \<bullet> i) / (b \<bullet> i - a \<bullet> i)) * (v \<bullet> i - u \<bullet> i) \<le> 1 * (v \<bullet> i - u \<bullet> i)"
apply (rule mult_right_mono)
unfolding divide_le_eq_1
using * x
apply auto
done
then show "u \<bullet> i + (x \<bullet> i - a \<bullet> i) / (b \<bullet> i - a \<bullet> i) * (v \<bullet> i - u \<bullet> i) \<le> v \<bullet> i"
using * by auto
qed
lemma interval_bij_bij:
"\<forall>(i::'a::ordered_euclidean_space)\<in>Basis. a\<bullet>i < b\<bullet>i \<and> u\<bullet>i < v\<bullet>i \<Longrightarrow>
interval_bij (a, b) (u, v) (interval_bij (u, v) (a, b) x) = x"
by (auto simp: interval_bij_def euclidean_eq_iff[where 'a='a])
end