wneuper/isa: src/HOLCF/Completion.thy@a2106c0d8c45 (annotated)

huffman@27404	1	(* Title: HOLCF/Completion.thy
huffman@27404	2	ID: $Id$
huffman@27404	3	Author: Brian Huffman
huffman@27404	4	*)
huffman@27404	5
huffman@27404	6	header {* Defining bifinite domains by ideal completion *}
huffman@27404	7
huffman@27404	8	theory Completion
huffman@27404	9	imports Bifinite
huffman@27404	10	begin
huffman@27404	11
huffman@27404	12	subsection {* Ideals over a preorder *}
huffman@27404	13
huffman@27404	14	locale preorder =
huffman@27404	15	fixes r :: "'a::type \<Rightarrow> 'a \<Rightarrow> bool" (infix "\<preceq>" 50)
huffman@27404	16	assumes r_refl: "x \<preceq> x"
huffman@27404	17	assumes r_trans: "\<lbrakk>x \<preceq> y; y \<preceq> z\<rbrakk> \<Longrightarrow> x \<preceq> z"
huffman@27404	18	begin
huffman@27404	19
huffman@27404	20	definition
huffman@27404	21	ideal :: "'a set \<Rightarrow> bool" where
huffman@27404	22	"ideal A = ((\<exists>x. x \<in> A) \<and> (\<forall>x\<in>A. \<forall>y\<in>A. \<exists>z\<in>A. x \<preceq> z \<and> y \<preceq> z) \<and>
huffman@27404	23	(\<forall>x y. x \<preceq> y \<longrightarrow> y \<in> A \<longrightarrow> x \<in> A))"
huffman@27404	24
huffman@27404	25	lemma idealI:
huffman@27404	26	assumes "\<exists>x. x \<in> A"
huffman@27404	27	assumes "\<And>x y. \<lbrakk>x \<in> A; y \<in> A\<rbrakk> \<Longrightarrow> \<exists>z\<in>A. x \<preceq> z \<and> y \<preceq> z"
huffman@27404	28	assumes "\<And>x y. \<lbrakk>x \<preceq> y; y \<in> A\<rbrakk> \<Longrightarrow> x \<in> A"
huffman@27404	29	shows "ideal A"
huffman@27404	30	unfolding ideal_def using prems by fast
huffman@27404	31
huffman@27404	32	lemma idealD1:
huffman@27404	33	"ideal A \<Longrightarrow> \<exists>x. x \<in> A"
huffman@27404	34	unfolding ideal_def by fast
huffman@27404	35
huffman@27404	36	lemma idealD2:
huffman@27404	37	"\<lbrakk>ideal A; x \<in> A; y \<in> A\<rbrakk> \<Longrightarrow> \<exists>z\<in>A. x \<preceq> z \<and> y \<preceq> z"
huffman@27404	38	unfolding ideal_def by fast
huffman@27404	39
huffman@27404	40	lemma idealD3:
huffman@27404	41	"\<lbrakk>ideal A; x \<preceq> y; y \<in> A\<rbrakk> \<Longrightarrow> x \<in> A"
huffman@27404	42	unfolding ideal_def by fast
huffman@27404	43
huffman@27404	44	lemma ideal_directed_finite:
huffman@27404	45	assumes A: "ideal A"
huffman@27404	46	shows "\<lbrakk>finite U; U \<subseteq> A\<rbrakk> \<Longrightarrow> \<exists>z\<in>A. \<forall>x\<in>U. x \<preceq> z"
huffman@27404	47	apply (induct U set: finite)
huffman@27404	48	apply (simp add: idealD1 [OF A])
huffman@27404	49	apply (simp, clarify, rename_tac y)
huffman@27404	50	apply (drule (1) idealD2 [OF A])
huffman@27404	51	apply (clarify, erule_tac x=z in rev_bexI)
huffman@27404	52	apply (fast intro: r_trans)
huffman@27404	53	done
huffman@27404	54
huffman@27404	55	lemma ideal_principal: "ideal {x. x \<preceq> z}"
huffman@27404	56	apply (rule idealI)
huffman@27404	57	apply (rule_tac x=z in exI)
huffman@27404	58	apply (fast intro: r_refl)
huffman@27404	59	apply (rule_tac x=z in bexI, fast)
huffman@27404	60	apply (fast intro: r_refl)
huffman@27404	61	apply (fast intro: r_trans)
huffman@27404	62	done
huffman@27404	63
huffman@27404	64	lemma ex_ideal: "\<exists>A. ideal A"
huffman@27404	65	by (rule exI, rule ideal_principal)
huffman@27404	66
huffman@27404	67	lemma directed_image_ideal:
huffman@27404	68	assumes A: "ideal A"
huffman@27404	69	assumes f: "\<And>x y. x \<preceq> y \<Longrightarrow> f x \<sqsubseteq> f y"
huffman@27404	70	shows "directed (f ` A)"
huffman@27404	71	apply (rule directedI)
huffman@27404	72	apply (cut_tac idealD1 [OF A], fast)
huffman@27404	73	apply (clarify, rename_tac a b)
huffman@27404	74	apply (drule (1) idealD2 [OF A])
huffman@27404	75	apply (clarify, rename_tac c)
huffman@27404	76	apply (rule_tac x="f c" in rev_bexI)
huffman@27404	77	apply (erule imageI)
huffman@27404	78	apply (simp add: f)
huffman@27404	79	done
huffman@27404	80
huffman@27404	81	lemma lub_image_principal:
huffman@27404	82	assumes f: "\<And>x y. x \<preceq> y \<Longrightarrow> f x \<sqsubseteq> f y"
huffman@27404	83	shows "(\<Squnion>x\<in>{x. x \<preceq> y}. f x) = f y"
huffman@27404	84	apply (rule thelubI)
huffman@27404	85	apply (rule is_lub_maximal)
huffman@27404	86	apply (rule ub_imageI)
huffman@27404	87	apply (simp add: f)
huffman@27404	88	apply (rule imageI)
huffman@27404	89	apply (simp add: r_refl)
huffman@27404	90	done
huffman@27404	91
huffman@27404	92	text {* The set of ideals is a cpo *}
huffman@27404	93
huffman@27404	94	lemma ideal_UN:
huffman@27404	95	fixes A :: "nat \<Rightarrow> 'a set"
huffman@27404	96	assumes ideal_A: "\<And>i. ideal (A i)"
huffman@27404	97	assumes chain_A: "\<And>i j. i \<le> j \<Longrightarrow> A i \<subseteq> A j"
huffman@27404	98	shows "ideal (\<Union>i. A i)"
huffman@27404	99	apply (rule idealI)
huffman@27404	100	apply (cut_tac idealD1 [OF ideal_A], fast)
huffman@27404	101	apply (clarify, rename_tac i j)
huffman@27404	102	apply (drule subsetD [OF chain_A [OF le_maxI1]])
huffman@27404	103	apply (drule subsetD [OF chain_A [OF le_maxI2]])
huffman@27404	104	apply (drule (1) idealD2 [OF ideal_A])
huffman@27404	105	apply blast
huffman@27404	106	apply clarify
huffman@27404	107	apply (drule (1) idealD3 [OF ideal_A])
huffman@27404	108	apply fast
huffman@27404	109	done
huffman@27404	110
huffman@27404	111	lemma typedef_ideal_po:
huffman@27404	112	fixes Abs :: "'a set \<Rightarrow> 'b::sq_ord"
huffman@27404	113	assumes type: "type_definition Rep Abs {S. ideal S}"
huffman@27404	114	assumes less: "\<And>x y. x \<sqsubseteq> y \<longleftrightarrow> Rep x \<subseteq> Rep y"
huffman@27404	115	shows "OFCLASS('b, po_class)"
huffman@27404	116	apply (intro_classes, unfold less)
huffman@27404	117	apply (rule subset_refl)
huffman@27404	118	apply (erule (1) subset_trans)
huffman@27404	119	apply (rule type_definition.Rep_inject [OF type, THEN iffD1])
huffman@27404	120	apply (erule (1) subset_antisym)
huffman@27404	121	done
huffman@27404	122
huffman@27404	123	lemma
huffman@27404	124	fixes Abs :: "'a set \<Rightarrow> 'b::po"
huffman@27404	125	assumes type: "type_definition Rep Abs {S. ideal S}"
huffman@27404	126	assumes less: "\<And>x y. x \<sqsubseteq> y \<longleftrightarrow> Rep x \<subseteq> Rep y"
huffman@27404	127	assumes S: "chain S"
huffman@27404	128	shows typedef_ideal_lub: "range S <<\| Abs (\<Union>i. Rep (S i))"
huffman@27404	129	and typedef_ideal_rep_contlub: "Rep (\<Squnion>i. S i) = (\<Union>i. Rep (S i))"
huffman@27404	130	proof -
huffman@27404	131	have 1: "ideal (\<Union>i. Rep (S i))"
huffman@27404	132	apply (rule ideal_UN)
huffman@27404	133	apply (rule type_definition.Rep [OF type, unfolded mem_Collect_eq])
huffman@27404	134	apply (subst less [symmetric])
huffman@27404	135	apply (erule chain_mono [OF S])
huffman@27404	136	done
huffman@27404	137	hence 2: "Rep (Abs (\<Union>i. Rep (S i))) = (\<Union>i. Rep (S i))"
huffman@27404	138	by (simp add: type_definition.Abs_inverse [OF type])
huffman@27404	139	show 3: "range S <<\| Abs (\<Union>i. Rep (S i))"
huffman@27404	140	apply (rule is_lubI)
huffman@27404	141	apply (rule is_ubI)
huffman@27404	142	apply (simp add: less 2, fast)
huffman@27404	143	apply (simp add: less 2 is_ub_def, fast)
huffman@27404	144	done
huffman@27404	145	hence 4: "(\<Squnion>i. S i) = Abs (\<Union>i. Rep (S i))"
huffman@27404	146	by (rule thelubI)
huffman@27404	147	show 5: "Rep (\<Squnion>i. S i) = (\<Union>i. Rep (S i))"
huffman@27404	148	by (simp add: 4 2)
huffman@27404	149	qed
huffman@27404	150
huffman@27404	151	lemma typedef_ideal_cpo:
huffman@27404	152	fixes Abs :: "'a set \<Rightarrow> 'b::po"
huffman@27404	153	assumes type: "type_definition Rep Abs {S. ideal S}"
huffman@27404	154	assumes less: "\<And>x y. x \<sqsubseteq> y \<longleftrightarrow> Rep x \<subseteq> Rep y"
huffman@27404	155	shows "OFCLASS('b, cpo_class)"
huffman@27404	156	by (default, rule exI, erule typedef_ideal_lub [OF type less])
huffman@27404	157
huffman@27404	158	end
huffman@27404	159
huffman@27404	160	interpretation sq_le: preorder ["sq_le :: 'a::po \<Rightarrow> 'a \<Rightarrow> bool"]
huffman@27404	161	apply unfold_locales
huffman@27404	162	apply (rule refl_less)
huffman@27404	163	apply (erule (1) trans_less)
huffman@27404	164	done
huffman@27404	165
huffman@27404	166	subsection {* Defining functions in terms of basis elements *}
huffman@27404	167
huffman@27404	168	lemma finite_directed_contains_lub:
huffman@27404	169	"\<lbrakk>finite S; directed S\<rbrakk> \<Longrightarrow> \<exists>u\<in>S. S <<\| u"
huffman@27404	170	apply (drule (1) directed_finiteD, rule subset_refl)
huffman@27404	171	apply (erule bexE)
huffman@27404	172	apply (rule rev_bexI, assumption)
huffman@27404	173	apply (erule (1) is_lub_maximal)
huffman@27404	174	done
huffman@27404	175
huffman@27404	176	lemma lub_finite_directed_in_self:
huffman@27404	177	"\<lbrakk>finite S; directed S\<rbrakk> \<Longrightarrow> lub S \<in> S"
huffman@27404	178	apply (drule (1) finite_directed_contains_lub, clarify)
huffman@27404	179	apply (drule thelubI, simp)
huffman@27404	180	done
huffman@27404	181
huffman@27404	182	lemma finite_directed_has_lub: "\<lbrakk>finite S; directed S\<rbrakk> \<Longrightarrow> \<exists>u. S <<\| u"
huffman@27404	183	by (drule (1) finite_directed_contains_lub, fast)
huffman@27404	184
huffman@27404	185	lemma is_ub_thelub0: "\<lbrakk>\<exists>u. S <<\| u; x \<in> S\<rbrakk> \<Longrightarrow> x \<sqsubseteq> lub S"
huffman@27404	186	apply (erule exE, drule lubI)
huffman@27404	187	apply (drule is_lubD1)
huffman@27404	188	apply (erule (1) is_ubD)
huffman@27404	189	done
huffman@27404	190
huffman@27404	191	lemma is_lub_thelub0: "\<lbrakk>\<exists>u. S <<\| u; S <\| x\<rbrakk> \<Longrightarrow> lub S \<sqsubseteq> x"
huffman@27404	192	by (erule exE, drule lubI, erule is_lub_lub)
huffman@27404	193
huffman@27404	194	locale basis_take = preorder +
huffman@27404	195	fixes take :: "nat \<Rightarrow> 'a::type \<Rightarrow> 'a"
huffman@27404	196	assumes take_less: "take n a \<preceq> a"
huffman@27404	197	assumes take_take: "take n (take n a) = take n a"
huffman@27404	198	assumes take_mono: "a \<preceq> b \<Longrightarrow> take n a \<preceq> take n b"
huffman@27404	199	assumes take_chain: "take n a \<preceq> take (Suc n) a"
huffman@27404	200	assumes finite_range_take: "finite (range (take n))"
huffman@27404	201	assumes take_covers: "\<exists>n. take n a = a"
huffman@27404	202	begin
huffman@27404	203
huffman@27404	204	lemma take_chain_less: "m < n \<Longrightarrow> take m a \<preceq> take n a"
huffman@27404	205	by (erule less_Suc_induct, rule take_chain, erule (1) r_trans)
huffman@27404	206
huffman@27404	207	lemma take_chain_le: "m \<le> n \<Longrightarrow> take m a \<preceq> take n a"
huffman@27404	208	by (cases "m = n", simp add: r_refl, simp add: take_chain_less)
huffman@27404	209
huffman@27404	210	end
huffman@27404	211
huffman@27404	212	locale ideal_completion = basis_take +
huffman@27404	213	fixes principal :: "'a::type \<Rightarrow> 'b::cpo"
huffman@27404	214	fixes rep :: "'b::cpo \<Rightarrow> 'a::type set"
huffman@27404	215	assumes ideal_rep: "\<And>x. preorder.ideal r (rep x)"
huffman@27404	216	assumes rep_contlub: "\<And>Y. chain Y \<Longrightarrow> rep (\<Squnion>i. Y i) = (\<Union>i. rep (Y i))"
huffman@27404	217	assumes rep_principal: "\<And>a. rep (principal a) = {b. b \<preceq> a}"
huffman@27404	218	assumes subset_repD: "\<And>x y. rep x \<subseteq> rep y \<Longrightarrow> x \<sqsubseteq> y"
huffman@27404	219	begin
huffman@27404	220
huffman@27404	221	lemma finite_take_rep: "finite (take n ` rep x)"
huffman@27404	222	by (rule finite_subset [OF image_mono [OF subset_UNIV] finite_range_take])
huffman@27404	223
huffman@27404	224	lemma basis_fun_lemma0:
huffman@27404	225	fixes f :: "'a::type \<Rightarrow> 'c::cpo"
huffman@27404	226	assumes f_mono: "\<And>a b. a \<preceq> b \<Longrightarrow> f a \<sqsubseteq> f b"
huffman@27404	227	shows "\<exists>u. f ` take i ` rep x <<\| u"
huffman@27404	228	apply (rule finite_directed_has_lub)
huffman@27404	229	apply (rule finite_imageI)
huffman@27404	230	apply (rule finite_take_rep)
huffman@27404	231	apply (subst image_image)
huffman@27404	232	apply (rule directed_image_ideal)
huffman@27404	233	apply (rule ideal_rep)
huffman@27404	234	apply (rule f_mono)
huffman@27404	235	apply (erule take_mono)
huffman@27404	236	done
huffman@27404	237
huffman@27404	238	lemma basis_fun_lemma1:
huffman@27404	239	fixes f :: "'a::type \<Rightarrow> 'c::cpo"
huffman@27404	240	assumes f_mono: "\<And>a b. a \<preceq> b \<Longrightarrow> f a \<sqsubseteq> f b"
huffman@27404	241	shows "chain (\<lambda>i. lub (f ` take i ` rep x))"
huffman@27404	242	apply (rule chainI)
huffman@27404	243	apply (rule is_lub_thelub0)
huffman@27404	244	apply (rule basis_fun_lemma0, erule f_mono)
huffman@27404	245	apply (rule is_ubI, clarsimp, rename_tac a)
haftmann@28053	246	apply (rule trans_less [OF f_mono [OF take_chain]])
huffman@27404	247	apply (rule is_ub_thelub0)
huffman@27404	248	apply (rule basis_fun_lemma0, erule f_mono)
huffman@27404	249	apply simp
huffman@27404	250	done
huffman@27404	251
huffman@27404	252	lemma basis_fun_lemma2:
huffman@27404	253	fixes f :: "'a::type \<Rightarrow> 'c::cpo"
huffman@27404	254	assumes f_mono: "\<And>a b. a \<preceq> b \<Longrightarrow> f a \<sqsubseteq> f b"
huffman@27404	255	shows "f ` rep x <<\| (\<Squnion>i. lub (f ` take i ` rep x))"
huffman@27404	256	apply (rule is_lubI)
huffman@27404	257	apply (rule ub_imageI, rename_tac a)
huffman@27404	258	apply (cut_tac a=a in take_covers, erule exE, rename_tac i)
huffman@27404	259	apply (erule subst)
huffman@27404	260	apply (rule rev_trans_less)
huffman@27404	261	apply (rule_tac x=i in is_ub_thelub)
huffman@27404	262	apply (rule basis_fun_lemma1, erule f_mono)
huffman@27404	263	apply (rule is_ub_thelub0)
huffman@27404	264	apply (rule basis_fun_lemma0, erule f_mono)
huffman@27404	265	apply simp
huffman@27404	266	apply (rule is_lub_thelub [OF _ ub_rangeI])
huffman@27404	267	apply (rule basis_fun_lemma1, erule f_mono)
huffman@27404	268	apply (rule is_lub_thelub0)
huffman@27404	269	apply (rule basis_fun_lemma0, erule f_mono)
huffman@27404	270	apply (rule is_ubI, clarsimp, rename_tac a)
haftmann@28053	271	apply (rule trans_less [OF f_mono [OF take_less]])
huffman@27404	272	apply (erule (1) ub_imageD)
huffman@27404	273	done
huffman@27404	274
huffman@27404	275	lemma basis_fun_lemma:
huffman@27404	276	fixes f :: "'a::type \<Rightarrow> 'c::cpo"
huffman@27404	277	assumes f_mono: "\<And>a b. a \<preceq> b \<Longrightarrow> f a \<sqsubseteq> f b"
huffman@27404	278	shows "\<exists>u. f ` rep x <<\| u"
huffman@27404	279	by (rule exI, rule basis_fun_lemma2, erule f_mono)
huffman@27404	280
huffman@27404	281	lemma rep_mono: "x \<sqsubseteq> y \<Longrightarrow> rep x \<subseteq> rep y"
huffman@27404	282	apply (frule bin_chain)
huffman@27404	283	apply (drule rep_contlub)
huffman@27404	284	apply (simp only: thelubI [OF lub_bin_chain])
huffman@27404	285	apply (rule subsetI, rule UN_I [where a=0], simp_all)
huffman@27404	286	done
huffman@27404	287
huffman@27404	288	lemma less_def: "x \<sqsubseteq> y \<longleftrightarrow> rep x \<subseteq> rep y"
huffman@27404	289	by (rule iffI [OF rep_mono subset_repD])
huffman@27404	290
huffman@27404	291	lemma rep_eq: "rep x = {a. principal a \<sqsubseteq> x}"
huffman@27404	292	unfolding less_def rep_principal
huffman@27404	293	apply safe
huffman@27404	294	apply (erule (1) idealD3 [OF ideal_rep])
huffman@27404	295	apply (erule subsetD, simp add: r_refl)
huffman@27404	296	done
huffman@27404	297
huffman@27404	298	lemma mem_rep_iff_principal_less: "a \<in> rep x \<longleftrightarrow> principal a \<sqsubseteq> x"
huffman@27404	299	by (simp add: rep_eq)
huffman@27404	300
huffman@27404	301	lemma principal_less_iff_mem_rep: "principal a \<sqsubseteq> x \<longleftrightarrow> a \<in> rep x"
huffman@27404	302	by (simp add: rep_eq)
huffman@27404	303
huffman@27404	304	lemma principal_less_iff [simp]: "principal a \<sqsubseteq> principal b \<longleftrightarrow> a \<preceq> b"
huffman@27404	305	by (simp add: principal_less_iff_mem_rep rep_principal)
huffman@27404	306
huffman@27404	307	lemma principal_eq_iff: "principal a = principal b \<longleftrightarrow> a \<preceq> b \<and> b \<preceq> a"
huffman@27404	308	unfolding po_eq_conv [where 'a='b] principal_less_iff ..
huffman@27404	309
huffman@27404	310	lemma repD: "a \<in> rep x \<Longrightarrow> principal a \<sqsubseteq> x"
huffman@27404	311	by (simp add: rep_eq)
huffman@27404	312
huffman@27404	313	lemma principal_mono: "a \<preceq> b \<Longrightarrow> principal a \<sqsubseteq> principal b"
huffman@27404	314	by (simp only: principal_less_iff)
huffman@27404	315
huffman@27404	316	lemma lessI: "(\<And>a. principal a \<sqsubseteq> x \<Longrightarrow> principal a \<sqsubseteq> u) \<Longrightarrow> x \<sqsubseteq> u"
huffman@27404	317	unfolding principal_less_iff_mem_rep
huffman@27404	318	by (simp add: less_def subset_eq)
huffman@27404	319
huffman@27404	320	lemma lub_principal_rep: "principal ` rep x <<\| x"
huffman@27404	321	apply (rule is_lubI)
huffman@27404	322	apply (rule ub_imageI)
huffman@27404	323	apply (erule repD)
huffman@27404	324	apply (subst less_def)
huffman@27404	325	apply (rule subsetI)
huffman@27404	326	apply (drule (1) ub_imageD)
huffman@27404	327	apply (simp add: rep_eq)
huffman@27404	328	done
huffman@27404	329
huffman@27404	330	definition
huffman@27404	331	basis_fun :: "('a::type \<Rightarrow> 'c::cpo) \<Rightarrow> 'b \<rightarrow> 'c" where
huffman@27404	332	"basis_fun = (\<lambda>f. (\<Lambda> x. lub (f ` rep x)))"
huffman@27404	333
huffman@27404	334	lemma basis_fun_beta:
huffman@27404	335	fixes f :: "'a::type \<Rightarrow> 'c::cpo"
huffman@27404	336	assumes f_mono: "\<And>a b. a \<preceq> b \<Longrightarrow> f a \<sqsubseteq> f b"
huffman@27404	337	shows "basis_fun f\<cdot>x = lub (f ` rep x)"
huffman@27404	338	unfolding basis_fun_def
huffman@27404	339	proof (rule beta_cfun)
huffman@27404	340	have lub: "\<And>x. \<exists>u. f ` rep x <<\| u"
huffman@27404	341	using f_mono by (rule basis_fun_lemma)
huffman@27404	342	show cont: "cont (\<lambda>x. lub (f ` rep x))"
huffman@27404	343	apply (rule contI2)
huffman@27404	344	apply (rule monofunI)
huffman@27404	345	apply (rule is_lub_thelub0 [OF lub ub_imageI])
huffman@27404	346	apply (rule is_ub_thelub0 [OF lub imageI])
huffman@27404	347	apply (erule (1) subsetD [OF rep_mono])
huffman@27404	348	apply (rule is_lub_thelub0 [OF lub ub_imageI])
huffman@27404	349	apply (simp add: rep_contlub, clarify)
huffman@27404	350	apply (erule rev_trans_less [OF is_ub_thelub])
huffman@27404	351	apply (erule is_ub_thelub0 [OF lub imageI])
huffman@27404	352	done
huffman@27404	353	qed
huffman@27404	354
huffman@27404	355	lemma basis_fun_principal:
huffman@27404	356	fixes f :: "'a::type \<Rightarrow> 'c::cpo"
huffman@27404	357	assumes f_mono: "\<And>a b. a \<preceq> b \<Longrightarrow> f a \<sqsubseteq> f b"
huffman@27404	358	shows "basis_fun f\<cdot>(principal a) = f a"
huffman@27404	359	apply (subst basis_fun_beta, erule f_mono)
huffman@27404	360	apply (subst rep_principal)
huffman@27404	361	apply (rule lub_image_principal, erule f_mono)
huffman@27404	362	done
huffman@27404	363
huffman@27404	364	lemma basis_fun_mono:
huffman@27404	365	assumes f_mono: "\<And>a b. a \<preceq> b \<Longrightarrow> f a \<sqsubseteq> f b"
huffman@27404	366	assumes g_mono: "\<And>a b. a \<preceq> b \<Longrightarrow> g a \<sqsubseteq> g b"
huffman@27404	367	assumes less: "\<And>a. f a \<sqsubseteq> g a"
huffman@27404	368	shows "basis_fun f \<sqsubseteq> basis_fun g"
huffman@27404	369	apply (rule less_cfun_ext)
huffman@27404	370	apply (simp only: basis_fun_beta f_mono g_mono)
huffman@27404	371	apply (rule is_lub_thelub0)
huffman@27404	372	apply (rule basis_fun_lemma, erule f_mono)
huffman@27404	373	apply (rule ub_imageI, rename_tac a)
haftmann@28053	374	apply (rule trans_less [OF less])
huffman@27404	375	apply (rule is_ub_thelub0)
huffman@27404	376	apply (rule basis_fun_lemma, erule g_mono)
huffman@27404	377	apply (erule imageI)
huffman@27404	378	done
huffman@27404	379
huffman@27404	380	lemma compact_principal [simp]: "compact (principal a)"
huffman@27404	381	by (rule compactI2, simp add: principal_less_iff_mem_rep rep_contlub)
huffman@27404	382
huffman@27404	383	definition
huffman@27404	384	completion_approx :: "nat \<Rightarrow> 'b \<rightarrow> 'b" where
huffman@27404	385	"completion_approx = (\<lambda>i. basis_fun (\<lambda>a. principal (take i a)))"
huffman@27404	386
huffman@27404	387	lemma completion_approx_beta:
huffman@27404	388	"completion_approx i\<cdot>x = (\<Squnion>a\<in>rep x. principal (take i a))"
huffman@27404	389	unfolding completion_approx_def
huffman@27404	390	by (simp add: basis_fun_beta principal_mono take_mono)
huffman@27404	391
huffman@27404	392	lemma completion_approx_principal:
huffman@27404	393	"completion_approx i\<cdot>(principal a) = principal (take i a)"
huffman@27404	394	unfolding completion_approx_def
huffman@27404	395	by (simp add: basis_fun_principal principal_mono take_mono)
huffman@27404	396
huffman@27404	397	lemma chain_completion_approx: "chain completion_approx"
huffman@27404	398	unfolding completion_approx_def
huffman@27404	399	apply (rule chainI)
huffman@27404	400	apply (rule basis_fun_mono)
huffman@27404	401	apply (erule principal_mono [OF take_mono])
huffman@27404	402	apply (erule principal_mono [OF take_mono])
huffman@27404	403	apply (rule principal_mono [OF take_chain])
huffman@27404	404	done
huffman@27404	405
huffman@27404	406	lemma lub_completion_approx: "(\<Squnion>i. completion_approx i\<cdot>x) = x"
huffman@27404	407	unfolding completion_approx_beta
huffman@27404	408	apply (subst image_image [where f=principal, symmetric])
huffman@27404	409	apply (rule unique_lub [OF _ lub_principal_rep])
huffman@27404	410	apply (rule basis_fun_lemma2, erule principal_mono)
huffman@27404	411	done
huffman@27404	412
huffman@27404	413	lemma completion_approx_eq_principal:
huffman@27404	414	"\<exists>a\<in>rep x. completion_approx i\<cdot>x = principal (take i a)"
huffman@27404	415	unfolding completion_approx_beta
huffman@27404	416	apply (subst image_image [where f=principal, symmetric])
huffman@27404	417	apply (subgoal_tac "finite (principal ` take i ` rep x)")
huffman@27404	418	apply (subgoal_tac "directed (principal ` take i ` rep x)")
huffman@27404	419	apply (drule (1) lub_finite_directed_in_self, fast)
huffman@27404	420	apply (subst image_image)
huffman@27404	421	apply (rule directed_image_ideal)
huffman@27404	422	apply (rule ideal_rep)
huffman@27404	423	apply (erule principal_mono [OF take_mono])
huffman@27404	424	apply (rule finite_imageI)
huffman@27404	425	apply (rule finite_take_rep)
huffman@27404	426	done
huffman@27404	427
huffman@27404	428	lemma completion_approx_idem:
huffman@27404	429	"completion_approx i\<cdot>(completion_approx i\<cdot>x) = completion_approx i\<cdot>x"
huffman@27404	430	using completion_approx_eq_principal [where i=i and x=x]
huffman@27404	431	by (auto simp add: completion_approx_principal take_take)
huffman@27404	432
huffman@27404	433	lemma finite_fixes_completion_approx:
huffman@27404	434	"finite {x. completion_approx i\<cdot>x = x}" (is "finite ?S")
huffman@27404	435	apply (subgoal_tac "?S \<subseteq> principal ` range (take i)")
huffman@27404	436	apply (erule finite_subset)
huffman@27404	437	apply (rule finite_imageI)
huffman@27404	438	apply (rule finite_range_take)
huffman@27404	439	apply (clarify, erule subst)
huffman@27404	440	apply (cut_tac x=x and i=i in completion_approx_eq_principal)
huffman@27404	441	apply fast
huffman@27404	442	done
huffman@27404	443
huffman@27404	444	lemma principal_induct:
huffman@27404	445	assumes adm: "adm P"
huffman@27404	446	assumes P: "\<And>a. P (principal a)"
huffman@27404	447	shows "P x"
huffman@27404	448	apply (subgoal_tac "P (\<Squnion>i. completion_approx i\<cdot>x)")
huffman@27404	449	apply (simp add: lub_completion_approx)
huffman@27404	450	apply (rule admD [OF adm])
huffman@27404	451	apply (simp add: chain_completion_approx)
huffman@27404	452	apply (cut_tac x=x and i=i in completion_approx_eq_principal)
huffman@27404	453	apply (clarify, simp add: P)
huffman@27404	454	done
huffman@27404	455
huffman@27404	456	lemma principal_induct2:
huffman@27404	457	"\<lbrakk>\<And>y. adm (\<lambda>x. P x y); \<And>x. adm (\<lambda>y. P x y);
huffman@27404	458	\<And>a b. P (principal a) (principal b)\<rbrakk> \<Longrightarrow> P x y"
huffman@27404	459	apply (rule_tac x=y in spec)
huffman@27404	460	apply (rule_tac x=x in principal_induct, simp)
huffman@27404	461	apply (rule allI, rename_tac y)
huffman@27404	462	apply (rule_tac x=y in principal_induct, simp)
huffman@27404	463	apply simp
huffman@27404	464	done
huffman@27404	465
huffman@27404	466	lemma compact_imp_principal: "compact x \<Longrightarrow> \<exists>a. x = principal a"
huffman@27404	467	apply (drule adm_compact_neq [OF _ cont_id])
huffman@27404	468	apply (drule admD2 [where Y="\<lambda>n. completion_approx n\<cdot>x"])
huffman@27404	469	apply (simp add: chain_completion_approx)
huffman@27404	470	apply (simp add: lub_completion_approx)
huffman@27404	471	apply (erule exE, erule ssubst)
huffman@27404	472	apply (cut_tac i=i and x=x in completion_approx_eq_principal)
huffman@27404	473	apply (clarify, erule exI)
huffman@27404	474	done
huffman@27404	475
huffman@27404	476	end
huffman@27404	477
huffman@27404	478	end

author	haftmann
	Thu, 28 Aug 2008 22:08:11 +0200
changeset 28053	a2106c0d8c45
parent 27404	62171da527d6
child 28133	218252dfd81e
permissions	-rw-r--r--