(* Title: CCL/Lfp.thy Author: Lawrence C Paulson, Cambridge University Computer Laboratory Copyright 1992 University of Cambridge *) section ‹ The Knaster-Tarski Theorem› theory Lfpimports Setbegin definition "['a set==> ==> where 🍋 ‹ least fixed point› "lfp(f) == Inter({u. f(u) <= u})" (* lfp(f) is the greatest lower bound of {u. f(u) <= u} *) lemma lfp_lowerbound: "f(A) <= A ==> lfp(f) <= A" unfolding lfp_def by blastlemma lfp_greatest: "(∧ ==> A<=u) ==> A <= lfp(f)" unfolding lfp_def by blastlemma lfp_lemma2: "mono(f) ==> f(lfp(f)) <= lfp(f)" by (rule lfp_greatest, rule subset_trans, drule monoD, rule lfp_lowerbound, assumption+)lemma lfp_lemma3: "mono(f) ==> lfp(f) <= f(lfp(f))" by (rule lfp_lowerbound, frule monoD, drule lfp_lemma2, assumption+)lemma lfp_Tarski: "mono(f) ==> lfp(f) = f(lfp(f))" by (rule equalityI lfp_lemma2 lfp_lemma3 | assumption)+(*** General induction rule for least fixed points ***) lemma induct:assumes lfp: "a: lfp(f)" and mono: "mono(f)" and indhyp: "∧ [ x: f(lfp(f) Int {x. P(x)})] ==> P(x)" shows "P(a)" apply (rule_tac a = a in Int_lower2 [THEN subsetD, THEN CollectD])apply (rule lfp [THEN [2] lfp_lowerbound [THEN subsetD]])apply (rule Int_greatest, rule subset_trans, rule Int_lower1 [THEN mono [THEN monoD]],THEN lfp_lemma2], rule CollectI [THEN subsetI], rule indhyp, assumption)done (** Definition forms of lfp_Tarski and induct, to control unfolding **) lemma def_lfp_Tarski: "[ h == lfp(f); mono(f)] ==> h = f(h)" apply unfoldapply (drule lfp_Tarski)apply assumptiondone lemma def_induct: "[ A == lfp(f); a:A; mono(f); ∧ ==> P(x)] ==> P(a)" apply (rule induct [of concl: P a])apply simpapply assumptionapply blastdone (*Monotonicity of lfp!*) lemma lfp_mono: "[ mono(g); ∧ ] ==> lfp(f) <= lfp(g)" apply (rule lfp_lowerbound)apply (rule subset_trans)apply (erule meta_spec)apply (erule lfp_lemma2)done end
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