isabelle: doc-src/TutorialI/CTL/CTLind.thy@875bf54b5d74 (annotated)

10218 54411746c549 * empty log message * nipkow parents: diff changeset	1	(<)theory CTLind = CTL:(>)
54411746c549 * empty log message * nipkow parents: diff changeset	2
54411746c549 * empty log message * nipkow parents: diff changeset	3	subsection{CTL revisited}
54411746c549 * empty log message * nipkow parents: diff changeset	4
54411746c549 * empty log message * nipkow parents: diff changeset	5	text{*\label{sec:CTL-revisited}
54411746c549 * empty log message * nipkow parents: diff changeset	6	In \S\ref{sec:CTL} we gave a fairly involved proof of the correctness of a
54411746c549 * empty log message * nipkow parents: diff changeset	7	model checker for CTL. In particular the proof of the
54411746c549 * empty log message * nipkow parents: diff changeset	8	@{thm[source]infinity_lemma} on the way to @{thm[source]AF_lemma2} is not as
54411746c549 * empty log message * nipkow parents: diff changeset	9	simple as one might intuitively expect, due to the @{text SOME} operator
54411746c549 * empty log message * nipkow parents: diff changeset	10	involved. The purpose of this section is to show how an inductive definition
54411746c549 * empty log message * nipkow parents: diff changeset	11	can help to simplify the proof of @{thm[source]AF_lemma2}.
54411746c549 * empty log message * nipkow parents: diff changeset	12
54411746c549 * empty log message * nipkow parents: diff changeset	13	Let us call a (finite or infinite) path \emph{@{term A}-avoiding} if it does
54411746c549 * empty log message * nipkow parents: diff changeset	14	not touch any node in the set @{term A}. Then @{thm[source]AF_lemma2} says
54411746c549 * empty log message * nipkow parents: diff changeset	15	that if no infinite path from some state @{term s} is @{term A}-avoiding,
54411746c549 * empty log message * nipkow parents: diff changeset	16	then @{prop"s \<in> lfp(af A)"}. We prove this by inductively defining the set
54411746c549 * empty log message * nipkow parents: diff changeset	17	@{term"Avoid s A"} of states reachable from @{term s} by a finite @{term
54411746c549 * empty log message * nipkow parents: diff changeset	18	A}-avoiding path:
54411746c549 * empty log message * nipkow parents: diff changeset	19	% Second proof of opposite direction, directly by wellfounded induction
54411746c549 * empty log message * nipkow parents: diff changeset	20	% on the initial segment of M that avoids A.
54411746c549 * empty log message * nipkow parents: diff changeset	21	*}
54411746c549 * empty log message * nipkow parents: diff changeset	22
54411746c549 * empty log message * nipkow parents: diff changeset	23	consts Avoid :: "state \<Rightarrow> state set \<Rightarrow> state set";
54411746c549 * empty log message * nipkow parents: diff changeset	24	inductive "Avoid s A"
54411746c549 * empty log message * nipkow parents: diff changeset	25	intros "s \<in> Avoid s A"
54411746c549 * empty log message * nipkow parents: diff changeset	26	"\<lbrakk> t \<in> Avoid s A; t \<notin> A; (t,u) \<in> M \<rbrakk> \<Longrightarrow> u \<in> Avoid s A";
54411746c549 * empty log message * nipkow parents: diff changeset	27
54411746c549 * empty log message * nipkow parents: diff changeset	28	text{*
54411746c549 * empty log message * nipkow parents: diff changeset	29	It is easy to see that for any infinite @{term A}-avoiding path @{term f}
54411746c549 * empty log message * nipkow parents: diff changeset	30	with @{prop"f 0 \<in> Avoid s A"} there is an infinite @{term A}-avoiding path
54411746c549 * empty log message * nipkow parents: diff changeset	31	starting with @{term s} because (by definition of @{term Avoid}) there is a
54411746c549 * empty log message * nipkow parents: diff changeset	32	finite @{term A}-avoiding path from @{term s} to @{term"f 0"}.
54411746c549 * empty log message * nipkow parents: diff changeset	33	The proof is by induction on @{prop"f 0 \<in> Avoid s A"}. However,
54411746c549 * empty log message * nipkow parents: diff changeset	34	this requires the following
54411746c549 * empty log message * nipkow parents: diff changeset	35	reformulation, as explained in \S\ref{sec:ind-var-in-prems} above;
54411746c549 * empty log message * nipkow parents: diff changeset	36	the @{text rule_format} directive undoes the reformulation after the proof.
54411746c549 * empty log message * nipkow parents: diff changeset	37	*}
54411746c549 * empty log message * nipkow parents: diff changeset	38
54411746c549 * empty log message * nipkow parents: diff changeset	39	lemma ex_infinite_path[rule_format]:
54411746c549 * empty log message * nipkow parents: diff changeset	40	"t \<in> Avoid s A \<Longrightarrow>
54411746c549 * empty log message * nipkow parents: diff changeset	41	\<forall>f\<in>Paths t. (\<forall>i. f i \<notin> A) \<longrightarrow> (\<exists>p\<in>Paths s. \<forall>i. p i \<notin> A)";
54411746c549 * empty log message * nipkow parents: diff changeset	42	apply(erule Avoid.induct);
54411746c549 * empty log message * nipkow parents: diff changeset	43	apply(blast);
54411746c549 * empty log message * nipkow parents: diff changeset	44	apply(clarify);
54411746c549 * empty log message * nipkow parents: diff changeset	45	apply(drule_tac x = "\<lambda>i. case i of 0 \<Rightarrow> t \| Suc i \<Rightarrow> f i" in bspec);
54411746c549 * empty log message * nipkow parents: diff changeset	46	apply(simp_all add:Paths_def split:nat.split);
54411746c549 * empty log message * nipkow parents: diff changeset	47	done
54411746c549 * empty log message * nipkow parents: diff changeset	48
54411746c549 * empty log message * nipkow parents: diff changeset	49	text{*\noindent
54411746c549 * empty log message * nipkow parents: diff changeset	50	The base case (@{prop"t = s"}) is trivial (@{text blast}).
54411746c549 * empty log message * nipkow parents: diff changeset	51	In the induction step, we have an infinite @{term A}-avoiding path @{term f}
54411746c549 * empty log message * nipkow parents: diff changeset	52	starting from @{term u}, a successor of @{term t}. Now we simply instantiate
54411746c549 * empty log message * nipkow parents: diff changeset	53	the @{text"\<forall>f\<in>Paths t"} in the induction hypothesis by the path starting with
54411746c549 * empty log message * nipkow parents: diff changeset	54	@{term t} and continuing with @{term f}. That is what the above $\lambda$-term
54411746c549 * empty log message * nipkow parents: diff changeset	55	expresses. That fact that this is a path starting with @{term t} and that
54411746c549 * empty log message * nipkow parents: diff changeset	56	the instantiated induction hypothesis implies the conclusion is shown by
54411746c549 * empty log message * nipkow parents: diff changeset	57	simplification.
54411746c549 * empty log message * nipkow parents: diff changeset	58
54411746c549 * empty log message * nipkow parents: diff changeset	59	Now we come to the key lemma. It says that if @{term t} can be reached by a
54411746c549 * empty log message * nipkow parents: diff changeset	60	finite @{term A}-avoiding path from @{term s}, then @{prop"t \<in> lfp(af A)"},
54411746c549 * empty log message * nipkow parents: diff changeset	61	provided there is no infinite @{term A}-avoiding path starting from @{term
54411746c549 * empty log message * nipkow parents: diff changeset	62	s}.
54411746c549 * empty log message * nipkow parents: diff changeset	63	*}
54411746c549 * empty log message * nipkow parents: diff changeset	64
54411746c549 * empty log message * nipkow parents: diff changeset	65	lemma Avoid_in_lfp[rule_format(no_asm)]:
54411746c549 * empty log message * nipkow parents: diff changeset	66	"\<forall>p\<in>Paths s. \<exists>i. p i \<in> A \<Longrightarrow> t \<in> Avoid s A \<longrightarrow> t \<in> lfp(af A)";
54411746c549 * empty log message * nipkow parents: diff changeset	67	txt{*\noindent
54411746c549 * empty log message * nipkow parents: diff changeset	68	The trick is not to induct on @{prop"t \<in> Avoid s A"}, as already the base
54411746c549 * empty log message * nipkow parents: diff changeset	69	case would be a problem, but to proceed by wellfounded induction @{term
54411746c549 * empty log message * nipkow parents: diff changeset	70	t}. Hence @{prop"t \<in> Avoid s A"} needs to be brought into the conclusion as
54411746c549 * empty log message * nipkow parents: diff changeset	71	well, which the directive @{text rule_format} undoes at the end (see below).
54411746c549 * empty log message * nipkow parents: diff changeset	72	But induction with respect to which wellfounded relation? The restriction
54411746c549 * empty log message * nipkow parents: diff changeset	73	of @{term M} to @{term"Avoid s A"}:
54411746c549 * empty log message * nipkow parents: diff changeset	74	@{term[display]"{(y,x). (x,y) \<in> M \<and> x \<in> Avoid s A \<and> y \<in> Avoid s A \<and> x \<notin> A}"}
54411746c549 * empty log message * nipkow parents: diff changeset	75	As we shall see in a moment, the absence of infinite @{term A}-avoiding paths
54411746c549 * empty log message * nipkow parents: diff changeset	76	starting from @{term s} implies wellfoundedness of this relation. For the
54411746c549 * empty log message * nipkow parents: diff changeset	77	moment we assume this and proceed with the induction:
54411746c549 * empty log message * nipkow parents: diff changeset	78	*}
54411746c549 * empty log message * nipkow parents: diff changeset	79
54411746c549 * empty log message * nipkow parents: diff changeset	80	apply(subgoal_tac
54411746c549 * empty log message * nipkow parents: diff changeset	81	"wf{(y,x). (x,y)\<in>M \<and> x \<in> Avoid s A \<and> y \<in> Avoid s A \<and> x \<notin> A}");
54411746c549 * empty log message * nipkow parents: diff changeset	82	apply(erule_tac a = t in wf_induct);
54411746c549 * empty log message * nipkow parents: diff changeset	83	apply(clarsimp);
54411746c549 * empty log message * nipkow parents: diff changeset	84
54411746c549 * empty log message * nipkow parents: diff changeset	85	txt{*\noindent
54411746c549 * empty log message * nipkow parents: diff changeset	86	Now can assume additionally (induction hypothesis) that if @{prop"t \<notin> A"}
54411746c549 * empty log message * nipkow parents: diff changeset	87	then all successors of @{term t} that are in @{term"Avoid s A"} are in
54411746c549 * empty log message * nipkow parents: diff changeset	88	@{term"lfp (af A)"}. To prove the actual goal we unfold @{term lfp} once. Now
54411746c549 * empty log message * nipkow parents: diff changeset	89	we have to prove that @{term t} is in @{term A} or all successors of @{term
54411746c549 * empty log message * nipkow parents: diff changeset	90	t} are in @{term"lfp (af A)"}. If @{term t} is not in @{term A}, the second
54411746c549 * empty log message * nipkow parents: diff changeset	91	@{term Avoid}-rule implies that all successors of @{term t} are in
54411746c549 * empty log message * nipkow parents: diff changeset	92	@{term"Avoid s A"} (because we also assume @{prop"t \<in> Avoid s A"}), and
54411746c549 * empty log message * nipkow parents: diff changeset	93	hence, by the induction hypothesis, all successors of @{term t} are indeed in
54411746c549 * empty log message * nipkow parents: diff changeset	94	@{term"lfp(af A)"}. Mechanically:
54411746c549 * empty log message * nipkow parents: diff changeset	95	*}
54411746c549 * empty log message * nipkow parents: diff changeset	96
54411746c549 * empty log message * nipkow parents: diff changeset	97	apply(rule ssubst [OF lfp_unfold[OF mono_af]]);
54411746c549 * empty log message * nipkow parents: diff changeset	98	apply(simp only: af_def);
54411746c549 * empty log message * nipkow parents: diff changeset	99	apply(blast intro:Avoid.intros);
54411746c549 * empty log message * nipkow parents: diff changeset	100
54411746c549 * empty log message * nipkow parents: diff changeset	101	txt{*
54411746c549 * empty log message * nipkow parents: diff changeset	102	Having proved the main goal we return to the proof obligation that the above
54411746c549 * empty log message * nipkow parents: diff changeset	103	relation is indeed wellfounded. This is proved by contraposition: we assume
54411746c549 * empty log message * nipkow parents: diff changeset	104	the relation is not wellfounded. Thus there exists an infinite @{term
54411746c549 * empty log message * nipkow parents: diff changeset	105	A}-avoiding path all in @{term"Avoid s A"}, by theorem
54411746c549 * empty log message * nipkow parents: diff changeset	106	@{thm[source]wf_iff_no_infinite_down_chain}:
54411746c549 * empty log message * nipkow parents: diff changeset	107	@{thm[display]wf_iff_no_infinite_down_chain[no_vars]}
54411746c549 * empty log message * nipkow parents: diff changeset	108	From lemma @{thm[source]ex_infinite_path} the existence of an infinite
54411746c549 * empty log message * nipkow parents: diff changeset	109	@{term A}-avoiding path starting in @{term s} follows, just as required for
54411746c549 * empty log message * nipkow parents: diff changeset	110	the contraposition.
54411746c549 * empty log message * nipkow parents: diff changeset	111	*}
54411746c549 * empty log message * nipkow parents: diff changeset	112
10235 20cf817f3b4a renaming of contrapos rules paulson parents: 10218 diff changeset	113	apply(erule contrapos_pp);
10218 54411746c549 * empty log message * nipkow parents: diff changeset	114	apply(simp add:wf_iff_no_infinite_down_chain);
54411746c549 * empty log message * nipkow parents: diff changeset	115	apply(erule exE);
54411746c549 * empty log message * nipkow parents: diff changeset	116	apply(rule ex_infinite_path);
54411746c549 * empty log message * nipkow parents: diff changeset	117	apply(auto simp add:Paths_def);
54411746c549 * empty log message * nipkow parents: diff changeset	118	done
54411746c549 * empty log message * nipkow parents: diff changeset	119
54411746c549 * empty log message * nipkow parents: diff changeset	120	text{*
54411746c549 * empty log message * nipkow parents: diff changeset	121	The @{text"(no_asm)"} modifier of the @{text"rule_format"} directive means
54411746c549 * empty log message * nipkow parents: diff changeset	122	that the assumption is left unchanged---otherwise the @{text"\<forall>p"} is turned
54411746c549 * empty log message * nipkow parents: diff changeset	123	into a @{text"\<And>p"}, which would complicate matters below. As it is,
54411746c549 * empty log message * nipkow parents: diff changeset	124	@{thm[source]Avoid_in_lfp} is now
54411746c549 * empty log message * nipkow parents: diff changeset	125	@{thm[display]Avoid_in_lfp[no_vars]}
54411746c549 * empty log message * nipkow parents: diff changeset	126	The main theorem is simply the corollary where @{prop"t = s"},
54411746c549 * empty log message * nipkow parents: diff changeset	127	in which case the assumption @{prop"t \<in> Avoid s A"} is trivially true
54411746c549 * empty log message * nipkow parents: diff changeset	128	by the first @{term Avoid}-rule). Isabelle confirms this:
54411746c549 * empty log message * nipkow parents: diff changeset	129	*}
54411746c549 * empty log message * nipkow parents: diff changeset	130
54411746c549 * empty log message * nipkow parents: diff changeset	131	theorem AF_lemma2:
54411746c549 * empty log message * nipkow parents: diff changeset	132	"{s. \<forall>p \<in> Paths s. \<exists> i. p i \<in> A} \<subseteq> lfp(af A)";
54411746c549 * empty log message * nipkow parents: diff changeset	133	by(auto elim:Avoid_in_lfp intro:Avoid.intros);
54411746c549 * empty log message * nipkow parents: diff changeset	134
54411746c549 * empty log message * nipkow parents: diff changeset	135
54411746c549 * empty log message * nipkow parents: diff changeset	136	(<)end(>)

author	nipkow
	Tue, 17 Oct 2000 16:59:02 +0200
changeset 10237	875bf54b5d74
parent 10235	20cf817f3b4a
child 10241	e0428c2778f1
permissions	-rw-r--r--