(* Title: ZF/UNITY/WFair.thy Author: Sidi Ehmety, Computer Laboratory Copyright 1998 University of Cambridge *) section\Progress under Weak Fairness\ theory WFair imports UNITY ZFC begin text\This theory defines the operators transient, ensures and leadsTo, assuming weak fairness. From Misra, "A Logic for Concurrent Programming", 1994.\ definition (* This definition specifies weak fairness. The rest of the theory is generic to all forms of fairness.*) transient :: "i=>i" where "transient(A) =={F \ program. (\act\Acts(F). A<=domain(act) & act``A \ state-A) & st_set(A)}" definition ensures :: "[i,i] => i" (infixl "ensures" 60) where "A ensures B == ((A-B) co (A \ B)) \ transient(A-B)" consts (*LEADS-TO constant for the inductive definition*) leads :: "[i, i]=>i" inductive domains "leads(D, F)" \ "Pow(D)*Pow(D)" intros Basis: "[| F \ A ensures B; A \ Pow(D); B \ Pow(D) |] ==> :leads(D, F)" Trans: "[| \ leads(D, F); \ leads(D, F) |] ==> :leads(D, F)" Union: "[| S \ Pow({A \ S. :leads(D, F)}); B \ Pow(D); S \ Pow(Pow(D)) |] ==> <\(S),B>:leads(D, F)" monos Pow_mono type_intros Union_Pow_iff [THEN iffD2] UnionI PowI definition (* The Visible version of the LEADS-TO relation*) leadsTo :: "[i, i] => i" (infixl "\" 60) where "A \ B == {F \ program. :leads(state, F)}" definition (* wlt(F, B) is the largest set that leads to B*) wlt :: "[i, i] => i" where "wlt(F, B) == \({A \ Pow(state). F \ A \ B})" (** Ad-hoc set-theory rules **) lemma Int_Union_Union: "\(B) \ A = (\b \ B. b \ A)" by auto lemma Int_Union_Union2: "A \ \(B) = (\b \ B. A \ b)" by auto (*** transient ***) lemma transient_type: "transient(A)<=program" by (unfold transient_def, auto) lemma transientD2: "F \ transient(A) ==> F \ program & st_set(A)" apply (unfold transient_def, auto) done lemma stable_transient_empty: "[| F \ stable(A); F \ transient(A) |] ==> A = 0" by (simp add: stable_def constrains_def transient_def, fast) lemma transient_strengthen: "[|F \ transient(A); B<=A|] ==> F \ transient(B)" apply (simp add: transient_def st_set_def, clarify) apply (blast intro!: rev_bexI) done lemma transientI: "[|act \ Acts(F); A \ domain(act); act``A \ state-A; F \ program; st_set(A)|] ==> F \ transient(A)" by (simp add: transient_def, blast) lemma transientE: "[| F \ transient(A); !!act. [| act \ Acts(F); A \ domain(act); act``A \ state-A|]==>P|] ==>P" by (simp add: transient_def, blast) lemma transient_state: "transient(state) = 0" apply (simp add: transient_def) apply (rule equalityI, auto) apply (cut_tac F = x in Acts_type) apply (simp add: Diff_cancel) apply (auto intro: st0_in_state) done lemma transient_state2: "state<=B ==> transient(B) = 0" apply (simp add: transient_def st_set_def) apply (rule equalityI, auto) apply (cut_tac F = x in Acts_type) apply (subgoal_tac "B=state") apply (auto intro: st0_in_state) done lemma transient_empty: "transient(0) = program" by (auto simp add: transient_def) declare transient_empty [simp] transient_state [simp] transient_state2 [simp] (*** ensures ***) lemma ensures_type: "A ensures B <=program" by (simp add: ensures_def constrains_def, auto) lemma ensuresI: "[|F:(A-B) co (A \ B); F \ transient(A-B)|]==>F \ A ensures B" apply (unfold ensures_def) apply (auto simp add: transient_type [THEN subsetD]) done (* Added by Sidi, from Misra's notes, Progress chapter, exercise 4 *) lemma ensuresI2: "[| F \ A co A \ B; F \ transient(A) |] ==> F \ A ensures B" apply (drule_tac B = "A-B" in constrains_weaken_L) apply (drule_tac [2] B = "A-B" in transient_strengthen) apply (auto simp add: ensures_def transient_type [THEN subsetD]) done lemma ensuresD: "F \ A ensures B ==> F:(A-B) co (A \ B) & F \ transient (A-B)" by (unfold ensures_def, auto) lemma ensures_weaken_R: "[|F \ A ensures A'; A'<=B' |] ==> F \ A ensures B'" apply (unfold ensures_def) apply (blast intro: transient_strengthen constrains_weaken) done (*The L-version (precondition strengthening) fails, but we have this*) lemma stable_ensures_Int: "[| F \ stable(C); F \ A ensures B |] ==> F:(C \ A) ensures (C \ B)" apply (unfold ensures_def) apply (simp (no_asm) add: Int_Un_distrib [symmetric] Diff_Int_distrib [symmetric]) apply (blast intro: transient_strengthen stable_constrains_Int constrains_weaken) done lemma stable_transient_ensures: "[|F \ stable(A); F \ transient(C); A<=B \ C|] ==> F \ A ensures B" apply (frule stable_type [THEN subsetD]) apply (simp add: ensures_def stable_def) apply (blast intro: transient_strengthen constrains_weaken) done lemma ensures_eq: "(A ensures B) = (A unless B) \ transient (A-B)" by (auto simp add: ensures_def unless_def) lemma subset_imp_ensures: "[| F \ program; A<=B |] ==> F \ A ensures B" by (auto simp add: ensures_def constrains_def transient_def st_set_def) (*** leadsTo ***) lemmas leads_left = leads.dom_subset [THEN subsetD, THEN SigmaD1] lemmas leads_right = leads.dom_subset [THEN subsetD, THEN SigmaD2] lemma leadsTo_type: "A \ B \ program" by (unfold leadsTo_def, auto) lemma leadsToD2: "F \ A \ B ==> F \ program & st_set(A) & st_set(B)" apply (unfold leadsTo_def st_set_def) apply (blast dest: leads_left leads_right) done lemma leadsTo_Basis: "[|F \ A ensures B; st_set(A); st_set(B)|] ==> F \ A \ B" apply (unfold leadsTo_def st_set_def) apply (cut_tac ensures_type) apply (auto intro: leads.Basis) done declare leadsTo_Basis [intro] (* Added by Sidi, from Misra's notes, Progress chapter, exercise number 4 *) (* [| F \ program; A<=B; st_set(A); st_set(B) |] ==> A \ B *) lemmas subset_imp_leadsTo = subset_imp_ensures [THEN leadsTo_Basis] lemma leadsTo_Trans: "[|F \ A \ B; F \ B \ C |]==>F \ A \ C" apply (unfold leadsTo_def) apply (auto intro: leads.Trans) done (* Better when used in association with leadsTo_weaken_R *) lemma transient_imp_leadsTo: "F \ transient(A) ==> F \ A \ (state-A)" apply (unfold transient_def) apply (blast intro: ensuresI [THEN leadsTo_Basis] constrains_weaken transientI) done (*Useful with cancellation, disjunction*) lemma leadsTo_Un_duplicate: "F \ A \ (A' \ A') ==> F \ A \ A'" by simp lemma leadsTo_Un_duplicate2: "F \ A \ (A' \ C \ C) ==> F \ A \ (A' \ C)" by (simp add: Un_ac) (*The Union introduction rule as we should have liked to state it*) lemma leadsTo_Union: "[|!!A. A \ S ==> F \ A \ B; F \ program; st_set(B)|] ==> F \ \(S) \ B" apply (unfold leadsTo_def st_set_def) apply (blast intro: leads.Union dest: leads_left) done lemma leadsTo_Union_Int: "[|!!A. A \ S ==>F \ (A \ C) \ B; F \ program; st_set(B)|] ==> F \ (\(S)Int C)\ B" apply (unfold leadsTo_def st_set_def) apply (simp only: Int_Union_Union) apply (blast dest: leads_left intro: leads.Union) done lemma leadsTo_UN: "[| !!i. i \ I ==> F \ A(i) \ B; F \ program; st_set(B)|] ==> F:(\i \ I. A(i)) \ B" apply (simp add: Int_Union_Union leadsTo_def st_set_def) apply (blast dest: leads_left intro: leads.Union) done (* Binary union introduction rule *) lemma leadsTo_Un: "[| F \ A \ C; F \ B \ C |] ==> F \ (A \ B) \ C" apply (subst Un_eq_Union) apply (blast intro: leadsTo_Union dest: leadsToD2) done lemma single_leadsTo_I: "[|!!x. x \ A==> F:{x} \ B; F \ program; st_set(B) |] ==> F \ A \ B" apply (rule_tac b = A in UN_singleton [THEN subst]) apply (rule leadsTo_UN, auto) done lemma leadsTo_refl: "[| F \ program; st_set(A) |] ==> F \ A \ A" by (blast intro: subset_imp_leadsTo) lemma leadsTo_refl_iff: "F \ A \ A \ F \ program & st_set(A)" by (auto intro: leadsTo_refl dest: leadsToD2) lemma empty_leadsTo: "F \ 0 \ B \ (F \ program & st_set(B))" by (auto intro: subset_imp_leadsTo dest: leadsToD2) declare empty_leadsTo [iff] lemma leadsTo_state: "F \ A \ state \ (F \ program & st_set(A))" by (auto intro: subset_imp_leadsTo dest: leadsToD2 st_setD) declare leadsTo_state [iff] lemma leadsTo_weaken_R: "[| F \ A \ A'; A'<=B'; st_set(B') |] ==> F \ A \ B'" by (blast dest: leadsToD2 intro: subset_imp_leadsTo leadsTo_Trans) lemma leadsTo_weaken_L: "[| F \ A \ A'; B<=A |] ==> F \ B \ A'" apply (frule leadsToD2) apply (blast intro: leadsTo_Trans subset_imp_leadsTo st_set_subset) done lemma leadsTo_weaken: "[| F \ A \ A'; B<=A; A'<=B'; st_set(B')|]==> F \ B \ B'" apply (frule leadsToD2) apply (blast intro: leadsTo_weaken_R leadsTo_weaken_L leadsTo_Trans leadsTo_refl) done (* This rule has a nicer conclusion *) lemma transient_imp_leadsTo2: "[| F \ transient(A); state-A<=B; st_set(B)|] ==> F \ A \ B" apply (frule transientD2) apply (rule leadsTo_weaken_R) apply (auto simp add: transient_imp_leadsTo) done (*Distributes over binary unions*) lemma leadsTo_Un_distrib: "F:(A \ B) \ C \ (F \ A \ C & F \ B \ C)" by (blast intro: leadsTo_Un leadsTo_weaken_L) lemma leadsTo_UN_distrib: "(F:(\i \ I. A(i)) \ B)\ ((\i \ I. F \ A(i) \ B) & F \ program & st_set(B))" apply (blast dest: leadsToD2 intro: leadsTo_UN leadsTo_weaken_L) done lemma leadsTo_Union_distrib: "(F \ \(S) \ B) \ (\A \ S. F \ A \ B) & F \ program & st_set(B)" by (blast dest: leadsToD2 intro: leadsTo_Union leadsTo_weaken_L) text\Set difference: maybe combine with \leadsTo_weaken_L\??\ lemma leadsTo_Diff: "[| F: (A-B) \ C; F \ B \ C; st_set(C) |] ==> F \ A \ C" by (blast intro: leadsTo_Un leadsTo_weaken dest: leadsToD2) lemma leadsTo_UN_UN: "[|!!i. i \ I ==> F \ A(i) \ A'(i); F \ program |] ==> F: (\i \ I. A(i)) \ (\i \ I. A'(i))" apply (rule leadsTo_Union) apply (auto intro: leadsTo_weaken_R dest: leadsToD2) done (*Binary union version*) lemma leadsTo_Un_Un: "[| F \ A \ A'; F \ B \ B' |] ==> F \ (A \ B) \ (A' \ B')" apply (subgoal_tac "st_set (A) & st_set (A') & st_set (B) & st_set (B') ") prefer 2 apply (blast dest: leadsToD2) apply (blast intro: leadsTo_Un leadsTo_weaken_R) done (** The cancellation law **) lemma leadsTo_cancel2: "[|F \ A \ (A' \ B); F \ B \ B'|] ==> F \ A \ (A' \ B')" apply (subgoal_tac "st_set (A) & st_set (A') & st_set (B) & st_set (B') &F \ program") prefer 2 apply (blast dest: leadsToD2) apply (blast intro: leadsTo_Trans leadsTo_Un_Un leadsTo_refl) done lemma leadsTo_cancel_Diff2: "[|F \ A \ (A' \ B); F \ (B-A') \ B'|]==> F \ A \ (A' \ B')" apply (rule leadsTo_cancel2) prefer 2 apply assumption apply (blast dest: leadsToD2 intro: leadsTo_weaken_R) done lemma leadsTo_cancel1: "[| F \ A \ (B \ A'); F \ B \ B' |] ==> F \ A \ (B' \ A')" apply (simp add: Un_commute) apply (blast intro!: leadsTo_cancel2) done lemma leadsTo_cancel_Diff1: "[|F \ A \ (B \ A'); F: (B-A') \ B'|]==> F \ A \ (B' \ A')" apply (rule leadsTo_cancel1) prefer 2 apply assumption apply (blast intro: leadsTo_weaken_R dest: leadsToD2) done (*The INDUCTION rule as we should have liked to state it*) lemma leadsTo_induct: assumes major: "F \ za \ zb" and basis: "!!A B. [|F \ A ensures B; st_set(A); st_set(B)|] ==> P(A,B)" and trans: "!!A B C. [| F \ A \ B; P(A, B); F \ B \ C; P(B, C) |] ==> P(A,C)" and union: "!!B S. [| \A \ S. F \ A \ B; \A \ S. P(A,B); st_set(B); \A \ S. st_set(A)|] ==> P(\(S), B)" shows "P(za, zb)" apply (cut_tac major) apply (unfold leadsTo_def, clarify) apply (erule leads.induct) apply (blast intro: basis [unfolded st_set_def]) apply (blast intro: trans [unfolded leadsTo_def]) apply (force intro: union [unfolded st_set_def leadsTo_def]) done (* Added by Sidi, an induction rule without ensures *) lemma leadsTo_induct2: assumes major: "F \ za \ zb" and basis1: "!!A B. [| A<=B; st_set(B) |] ==> P(A, B)" and basis2: "!!A B. [| F \ A co A \ B; F \ transient(A); st_set(B) |] ==> P(A, B)" and trans: "!!A B C. [| F \ A \ B; P(A, B); F \ B \ C; P(B, C) |] ==> P(A,C)" and union: "!!B S. [| \A \ S. F \ A \ B; \A \ S. P(A,B); st_set(B); \A \ S. st_set(A)|] ==> P(\(S), B)" shows "P(za, zb)" apply (cut_tac major) apply (erule leadsTo_induct) apply (auto intro: trans union) apply (simp add: ensures_def, clarify) apply (frule constrainsD2) apply (drule_tac B' = " (A-B) \ B" in constrains_weaken_R) apply blast apply (frule ensuresI2 [THEN leadsTo_Basis]) apply (drule_tac [4] basis2, simp_all) apply (frule_tac A1 = A and B = B in Int_lower2 [THEN basis1]) apply (subgoal_tac "A=\({A - B, A \ B}) ") prefer 2 apply blast apply (erule ssubst) apply (rule union) apply (auto intro: subset_imp_leadsTo) done (** Variant induction rule: on the preconditions for B **) (*Lemma is the weak version: can't see how to do it in one step*) lemma leadsTo_induct_pre_aux: "[| F \ za \ zb; P(zb); !!A B. [| F \ A ensures B; P(B); st_set(A); st_set(B) |] ==> P(A); !!S. [| \A \ S. P(A); \A \ S. st_set(A) |] ==> P(\(S)) |] ==> P(za)" txt\by induction on this formula\ apply (subgoal_tac "P (zb) \ P (za) ") txt\now solve first subgoal: this formula is sufficient\ apply (blast intro: leadsTo_refl) apply (erule leadsTo_induct) apply (blast+) done lemma leadsTo_induct_pre: "[| F \ za \ zb; P(zb); !!A B. [| F \ A ensures B; F \ B \ zb; P(B); st_set(A) |] ==> P(A); !!S. \A \ S. F \ A \ zb & P(A) & st_set(A) ==> P(\(S)) |] ==> P(za)" apply (subgoal_tac " (F \ za \ zb) & P (za) ") apply (erule conjunct2) apply (frule leadsToD2) apply (erule leadsTo_induct_pre_aux) prefer 3 apply (blast dest: leadsToD2 intro: leadsTo_Union) prefer 2 apply (blast intro: leadsTo_Trans leadsTo_Basis) apply (blast intro: leadsTo_refl) done (** The impossibility law **) lemma leadsTo_empty: "F \ A \ 0 ==> A=0" apply (erule leadsTo_induct_pre) apply (auto simp add: ensures_def constrains_def transient_def st_set_def) apply (drule bspec, assumption)+ apply blast done declare leadsTo_empty [simp] subsection\PSP: Progress-Safety-Progress\ text\Special case of PSP: Misra's "stable conjunction"\ lemma psp_stable: "[| F \ A \ A'; F \ stable(B) |] ==> F:(A \ B) \ (A' \ B)" apply (unfold stable_def) apply (frule leadsToD2) apply (erule leadsTo_induct) prefer 3 apply (blast intro: leadsTo_Union_Int) prefer 2 apply (blast intro: leadsTo_Trans) apply (rule leadsTo_Basis) apply (simp add: ensures_def Diff_Int_distrib2 [symmetric] Int_Un_distrib2 [symmetric]) apply (auto intro: transient_strengthen constrains_Int) done lemma psp_stable2: "[|F \ A \ A'; F \ stable(B) |]==>F: (B \ A) \ (B \ A')" apply (simp (no_asm_simp) add: psp_stable Int_ac) done lemma psp_ensures: "[| F \ A ensures A'; F \ B co B' |]==> F: (A \ B') ensures ((A' \ B) \ (B' - B))" apply (unfold ensures_def constrains_def st_set_def) (*speeds up the proof*) apply clarify apply (blast intro: transient_strengthen) done lemma psp: "[|F \ A \ A'; F \ B co B'; st_set(B')|]==> F:(A \ B') \ ((A' \ B) \ (B' - B))" apply (subgoal_tac "F \ program & st_set (A) & st_set (A') & st_set (B) ") prefer 2 apply (blast dest!: constrainsD2 leadsToD2) apply (erule leadsTo_induct) prefer 3 apply (blast intro: leadsTo_Union_Int) txt\Basis case\ apply (blast intro: psp_ensures leadsTo_Basis) txt\Transitivity case has a delicate argument involving "cancellation"\ apply (rule leadsTo_Un_duplicate2) apply (erule leadsTo_cancel_Diff1) apply (simp add: Int_Diff Diff_triv) apply (blast intro: leadsTo_weaken_L dest: constrains_imp_subset) done lemma psp2: "[| F \ A \ A'; F \ B co B'; st_set(B') |] ==> F \ (B' \ A) \ ((B \ A') \ (B' - B))" by (simp (no_asm_simp) add: psp Int_ac) lemma psp_unless: "[| F \ A \ A'; F \ B unless B'; st_set(B); st_set(B') |] ==> F \ (A \ B) \ ((A' \ B) \ B')" apply (unfold unless_def) apply (subgoal_tac "st_set (A) &st_set (A') ") prefer 2 apply (blast dest: leadsToD2) apply (drule psp, assumption, blast) apply (blast intro: leadsTo_weaken) done subsection\Proving the induction rules\ (** The most general rule \ r is any wf relation; f is any variant function **) lemma leadsTo_wf_induct_aux: "[| wf(r); m \ I; field(r)<=I; F \ program; st_set(B); \m \ I. F \ (A \ f-``{m}) \ ((A \ f-``(converse(r)``{m})) \ B) |] ==> F \ (A \ f-``{m}) \ B" apply (erule_tac a = m in wf_induct2, simp_all) apply (subgoal_tac "F \ (A \ (f-`` (converse (r) ``{x}))) \ B") apply (blast intro: leadsTo_cancel1 leadsTo_Un_duplicate) apply (subst vimage_eq_UN) apply (simp del: UN_simps add: Int_UN_distrib) apply (auto intro: leadsTo_UN simp del: UN_simps simp add: Int_UN_distrib) done (** Meta or object quantifier ? **) lemma leadsTo_wf_induct: "[| wf(r); field(r)<=I; A<=f-``I; F \ program; st_set(A); st_set(B); \m \ I. F \ (A \ f-``{m}) \ ((A \ f-``(converse(r)``{m})) \ B) |] ==> F \ A \