(* Title: ZF/UNITY/UNITY.thy
Author: Sidi O Ehmety, Computer Laboratory
Copyright 2001 University of Cambridge
*)
header {*The Basic UNITY Theory*}
theory UNITY imports State begin
text{*The basic UNITY theory (revised version, based upon the "co" operator)
From Misra, "A Logic for Concurrent Programming", 1994.
This ZF theory was ported from its HOL equivalent.*}
consts
"constrains" :: "[i, i] => i" (infixl "co" 60)
op_unless :: "[i, i] => i" (infixl "unless" 60)
definition
program :: i where
"program == {<init, acts, allowed>:
Pow(state) * Pow(Pow(state*state)) * Pow(Pow(state*state)).
id(state) \<in> acts & id(state) \<in> allowed}"
definition
mk_program :: "[i,i,i]=>i" where
--{* The definition yields a program thanks to the coercions
init \<inter> state, acts \<inter> Pow(state*state), etc. *}
"mk_program(init, acts, allowed) ==
<init \<inter> state, cons(id(state), acts \<inter> Pow(state*state)),
cons(id(state), allowed \<inter> Pow(state*state))>"
definition
SKIP :: i where
"SKIP == mk_program(state, 0, Pow(state*state))"
(* Coercion from anything to program *)
definition
programify :: "i=>i" where
"programify(F) == if F \<in> program then F else SKIP"
definition
RawInit :: "i=>i" where
"RawInit(F) == fst(F)"
definition
Init :: "i=>i" where
"Init(F) == RawInit(programify(F))"
definition
RawActs :: "i=>i" where
"RawActs(F) == cons(id(state), fst(snd(F)))"
definition
Acts :: "i=>i" where
"Acts(F) == RawActs(programify(F))"
definition
RawAllowedActs :: "i=>i" where
"RawAllowedActs(F) == cons(id(state), snd(snd(F)))"
definition
AllowedActs :: "i=>i" where
"AllowedActs(F) == RawAllowedActs(programify(F))"
definition
Allowed :: "i =>i" where
"Allowed(F) == {G \<in> program. Acts(G) \<subseteq> AllowedActs(F)}"
definition
initially :: "i=>i" where
"initially(A) == {F \<in> program. Init(F)\<subseteq>A}"
definition
stable :: "i=>i" where
"stable(A) == A co A"
definition
strongest_rhs :: "[i, i] => i" where
"strongest_rhs(F, A) == Inter({B \<in> Pow(state). F \<in> A co B})"
definition
invariant :: "i => i" where
"invariant(A) == initially(A) \<inter> stable(A)"
(* meta-function composition *)
definition
metacomp :: "[i=>i, i=>i] => (i=>i)" (infixl "comp" 65) where
"f comp g == %x. f(g(x))"
definition
pg_compl :: "i=>i" where
"pg_compl(X)== program - X"
defs
constrains_def:
"A co B == {F \<in> program. (\<forall>act \<in> Acts(F). act``A\<subseteq>B) & st_set(A)}"
--{* the condition @{term "st_set(A)"} makes the definition slightly
stronger than the HOL one *}
unless_def: "A unless B == (A - B) co (A Un B)"
text{*SKIP*}
lemma SKIP_in_program [iff,TC]: "SKIP \<in> program"
by (force simp add: SKIP_def program_def mk_program_def)
subsection{*The function @{term programify}, the coercion from anything to
program*}
lemma programify_program [simp]: "F \<in> program ==> programify(F)=F"
by (force simp add: programify_def)
lemma programify_in_program [iff,TC]: "programify(F) \<in> program"
by (force simp add: programify_def)
text{*Collapsing rules: to remove programify from expressions*}
lemma programify_idem [simp]: "programify(programify(F))=programify(F)"
by (force simp add: programify_def)
lemma Init_programify [simp]: "Init(programify(F)) = Init(F)"
by (simp add: Init_def)
lemma Acts_programify [simp]: "Acts(programify(F)) = Acts(F)"
by (simp add: Acts_def)
lemma AllowedActs_programify [simp]:
"AllowedActs(programify(F)) = AllowedActs(F)"
by (simp add: AllowedActs_def)
subsection{*The Inspectors for Programs*}
lemma id_in_RawActs: "F \<in> program ==>id(state) \<in> RawActs(F)"
by (auto simp add: program_def RawActs_def)
lemma id_in_Acts [iff,TC]: "id(state) \<in> Acts(F)"
by (simp add: id_in_RawActs Acts_def)
lemma id_in_RawAllowedActs: "F \<in> program ==>id(state) \<in> RawAllowedActs(F)"
by (auto simp add: program_def RawAllowedActs_def)
lemma id_in_AllowedActs [iff,TC]: "id(state) \<in> AllowedActs(F)"
by (simp add: id_in_RawAllowedActs AllowedActs_def)
lemma cons_id_Acts [simp]: "cons(id(state), Acts(F)) = Acts(F)"
by (simp add: cons_absorb)
lemma cons_id_AllowedActs [simp]:
"cons(id(state), AllowedActs(F)) = AllowedActs(F)"
by (simp add: cons_absorb)
subsection{*Types of the Inspectors*}
lemma RawInit_type: "F \<in> program ==> RawInit(F)\<subseteq>state"
by (auto simp add: program_def RawInit_def)
lemma RawActs_type: "F \<in> program ==> RawActs(F)\<subseteq>Pow(state*state)"
by (auto simp add: program_def RawActs_def)
lemma RawAllowedActs_type:
"F \<in> program ==> RawAllowedActs(F)\<subseteq>Pow(state*state)"
by (auto simp add: program_def RawAllowedActs_def)
lemma Init_type: "Init(F)\<subseteq>state"
by (simp add: RawInit_type Init_def)
lemmas InitD = Init_type [THEN subsetD]
lemma st_set_Init [iff]: "st_set(Init(F))"
apply (unfold st_set_def)
apply (rule Init_type)
done
lemma Acts_type: "Acts(F)\<subseteq>Pow(state*state)"
by (simp add: RawActs_type Acts_def)
lemma AllowedActs_type: "AllowedActs(F) \<subseteq> Pow(state*state)"
by (simp add: RawAllowedActs_type AllowedActs_def)
text{*Needed in Behaviors*}
lemma ActsD: "[| act \<in> Acts(F); <s,s'> \<in> act |] ==> s \<in> state & s' \<in> state"
by (blast dest: Acts_type [THEN subsetD])
lemma AllowedActsD:
"[| act \<in> AllowedActs(F); <s,s'> \<in> act |] ==> s \<in> state & s' \<in> state"
by (blast dest: AllowedActs_type [THEN subsetD])
subsection{*Simplification rules involving @{term state}, @{term Init},
@{term Acts}, and @{term AllowedActs}*}
text{*But are they really needed?*}
lemma state_subset_is_Init_iff [iff]: "state \<subseteq> Init(F) <-> Init(F)=state"
by (cut_tac F = F in Init_type, auto)
lemma Pow_state_times_state_is_subset_Acts_iff [iff]:
"Pow(state*state) \<subseteq> Acts(F) <-> Acts(F)=Pow(state*state)"
by (cut_tac F = F in Acts_type, auto)
lemma Pow_state_times_state_is_subset_AllowedActs_iff [iff]:
"Pow(state*state) \<subseteq> AllowedActs(F) <-> AllowedActs(F)=Pow(state*state)"
by (cut_tac F = F in AllowedActs_type, auto)
subsubsection{*Eliminating @{text "\<inter> state"} from expressions*}
lemma Init_Int_state [simp]: "Init(F) \<inter> state = Init(F)"
by (cut_tac F = F in Init_type, blast)
lemma state_Int_Init [simp]: "state \<inter> Init(F) = Init(F)"
by (cut_tac F = F in Init_type, blast)
lemma Acts_Int_Pow_state_times_state [simp]:
"Acts(F) \<inter> Pow(state*state) = Acts(F)"
by (cut_tac F = F in Acts_type, blast)
lemma state_times_state_Int_Acts [simp]:
"Pow(state*state) \<inter> Acts(F) = Acts(F)"
by (cut_tac F = F in Acts_type, blast)
lemma AllowedActs_Int_Pow_state_times_state [simp]:
"AllowedActs(F) \<inter> Pow(state*state) = AllowedActs(F)"
by (cut_tac F = F in AllowedActs_type, blast)
lemma state_times_state_Int_AllowedActs [simp]:
"Pow(state*state) \<inter> AllowedActs(F) = AllowedActs(F)"
by (cut_tac F = F in AllowedActs_type, blast)
subsubsection{*The Operator @{term mk_program}*}
lemma mk_program_in_program [iff,TC]:
"mk_program(init, acts, allowed) \<in> program"
by (auto simp add: mk_program_def program_def)
lemma RawInit_eq [simp]:
"RawInit(mk_program(init, acts, allowed)) = init \<inter> state"
by (auto simp add: mk_program_def RawInit_def)
lemma RawActs_eq [simp]:
"RawActs(mk_program(init, acts, allowed)) =
cons(id(state), acts \<inter> Pow(state*state))"
by (auto simp add: mk_program_def RawActs_def)
lemma RawAllowedActs_eq [simp]:
"RawAllowedActs(mk_program(init, acts, allowed)) =
cons(id(state), allowed \<inter> Pow(state*state))"
by (auto simp add: mk_program_def RawAllowedActs_def)
lemma Init_eq [simp]: "Init(mk_program(init, acts, allowed)) = init \<inter> state"
by (simp add: Init_def)
lemma Acts_eq [simp]:
"Acts(mk_program(init, acts, allowed)) =
cons(id(state), acts \<inter> Pow(state*state))"
by (simp add: Acts_def)
lemma AllowedActs_eq [simp]:
"AllowedActs(mk_program(init, acts, allowed))=
cons(id(state), allowed \<inter> Pow(state*state))"
by (simp add: AllowedActs_def)
text{*Init, Acts, and AlowedActs of SKIP *}
lemma RawInit_SKIP [simp]: "RawInit(SKIP) = state"
by (simp add: SKIP_def)
lemma RawAllowedActs_SKIP [simp]: "RawAllowedActs(SKIP) = Pow(state*state)"
by (force simp add: SKIP_def)
lemma RawActs_SKIP [simp]: "RawActs(SKIP) = {id(state)}"
by (force simp add: SKIP_def)
lemma Init_SKIP [simp]: "Init(SKIP) = state"
by (force simp add: SKIP_def)
lemma Acts_SKIP [simp]: "Acts(SKIP) = {id(state)}"
by (force simp add: SKIP_def)
lemma AllowedActs_SKIP [simp]: "AllowedActs(SKIP) = Pow(state*state)"
by (force simp add: SKIP_def)
text{*Equality of UNITY programs*}
lemma raw_surjective_mk_program:
"F \<in> program ==> mk_program(RawInit(F), RawActs(F), RawAllowedActs(F))=F"
apply (auto simp add: program_def mk_program_def RawInit_def RawActs_def
RawAllowedActs_def, blast+)
done
lemma surjective_mk_program [simp]:
"mk_program(Init(F), Acts(F), AllowedActs(F)) = programify(F)"
by (auto simp add: raw_surjective_mk_program Init_def Acts_def AllowedActs_def)
lemma program_equalityI:
"[|Init(F) = Init(G); Acts(F) = Acts(G);
AllowedActs(F) = AllowedActs(G); F \<in> program; G \<in> program |] ==> F = G"
apply (subgoal_tac "programify(F) = programify(G)")
apply simp
apply (simp only: surjective_mk_program [symmetric])
done
lemma program_equalityE:
"[|F = G;
[|Init(F) = Init(G); Acts(F) = Acts(G); AllowedActs(F) = AllowedActs(G) |]
==> P |]
==> P"
by force
lemma program_equality_iff:
"[| F \<in> program; G \<in> program |] ==>(F=G) <->
(Init(F) = Init(G) & Acts(F) = Acts(G) & AllowedActs(F) = AllowedActs(G))"
by (blast intro: program_equalityI program_equalityE)
subsection{*These rules allow "lazy" definition expansion*}
lemma def_prg_Init:
"F == mk_program (init,acts,allowed) ==> Init(F) = init \<inter> state"
by auto
lemma def_prg_Acts:
"F == mk_program (init,acts,allowed)
==> Acts(F) = cons(id(state), acts \<inter> Pow(state*state))"
by auto
lemma def_prg_AllowedActs:
"F == mk_program (init,acts,allowed)
==> AllowedActs(F) = cons(id(state), allowed \<inter> Pow(state*state))"
by auto
lemma def_prg_simps:
"[| F == mk_program (init,acts,allowed) |]
==> Init(F) = init \<inter> state &
Acts(F) = cons(id(state), acts \<inter> Pow(state*state)) &
AllowedActs(F) = cons(id(state), allowed \<inter> Pow(state*state))"
by auto
text{*An action is expanded only if a pair of states is being tested against it*}
lemma def_act_simp:
"[| act == {<s,s'> \<in> A*B. P(s, s')} |]
==> (<s,s'> \<in> act) <-> (<s,s'> \<in> A*B & P(s, s'))"
by auto
text{*A set is expanded only if an element is being tested against it*}
lemma def_set_simp: "A == B ==> (x \<in> A) <-> (x \<in> B)"
by auto
subsection{*The Constrains Operator*}
lemma constrains_type: "A co B \<subseteq> program"
by (force simp add: constrains_def)
lemma constrainsI:
"[|(!!act s s'. [| act: Acts(F); <s,s'> \<in> act; s \<in> A|] ==> s' \<in> A');
F \<in> program; st_set(A) |] ==> F \<in> A co A'"
by (force simp add: constrains_def)
lemma constrainsD:
"F \<in> A co B ==> \<forall>act \<in> Acts(F). act``A\<subseteq>B"
by (force simp add: constrains_def)
lemma constrainsD2: "F \<in> A co B ==> F \<in> program & st_set(A)"
by (force simp add: constrains_def)
lemma constrains_empty [iff]: "F \<in> 0 co B <-> F \<in> program"
by (force simp add: constrains_def st_set_def)
lemma constrains_empty2 [iff]: "(F \<in> A co 0) <-> (A=0 & F \<in> program)"
by (force simp add: constrains_def st_set_def)
lemma constrains_state [iff]: "(F \<in> state co B) <-> (state\<subseteq>B & F \<in> program)"
apply (cut_tac F = F in Acts_type)
apply (force simp add: constrains_def st_set_def)
done
lemma constrains_state2 [iff]: "F \<in> A co state <-> (F \<in> program & st_set(A))"
apply (cut_tac F = F in Acts_type)
apply (force simp add: constrains_def st_set_def)
done
text{*monotonic in 2nd argument*}
lemma constrains_weaken_R:
"[| F \<in> A co A'; A'\<subseteq>B' |] ==> F \<in> A co B'"
apply (unfold constrains_def, blast)
done
text{*anti-monotonic in 1st argument*}
lemma constrains_weaken_L:
"[| F \<in> A co A'; B\<subseteq>A |] ==> F \<in> B co A'"
apply (unfold constrains_def st_set_def, blast)
done
lemma constrains_weaken:
"[| F \<in> A co A'; B\<subseteq>A; A'\<subseteq>B' |] ==> F \<in> B co B'"
apply (drule constrains_weaken_R)
apply (drule_tac [2] constrains_weaken_L, blast+)
done
subsection{*Constrains and Union*}
lemma constrains_Un:
"[| F \<in> A co A'; F \<in> B co B' |] ==> F \<in> (A Un B) co (A' Un B')"
by (auto simp add: constrains_def st_set_def, force)
lemma constrains_UN:
"[|!!i. i \<in> I ==> F \<in> A(i) co A'(i); F \<in> program |]
==> F \<in> (\<Union>i \<in> I. A(i)) co (\<Union>i \<in> I. A'(i))"
by (force simp add: constrains_def st_set_def)
lemma constrains_Un_distrib:
"(A Un B) co C = (A co C) \<inter> (B co C)"
by (force simp add: constrains_def st_set_def)
lemma constrains_UN_distrib:
"i \<in> I ==> (\<Union>i \<in> I. A(i)) co B = (\<Inter>i \<in> I. A(i) co B)"
by (force simp add: constrains_def st_set_def)
subsection{*Constrains and Intersection*}
lemma constrains_Int_distrib: "C co (A \<inter> B) = (C co A) \<inter> (C co B)"
by (force simp add: constrains_def st_set_def)
lemma constrains_INT_distrib:
"x \<in> I ==> A co (\<Inter>i \<in> I. B(i)) = (\<Inter>i \<in> I. A co B(i))"
by (force simp add: constrains_def st_set_def)
lemma constrains_Int:
"[| F \<in> A co A'; F \<in> B co B' |] ==> F \<in> (A \<inter> B) co (A' \<inter> B')"
by (force simp add: constrains_def st_set_def)
lemma constrains_INT [rule_format]:
"[| \<forall>i \<in> I. F \<in> A(i) co A'(i); F \<in> program|]
==> F \<in> (\<Inter>i \<in> I. A(i)) co (\<Inter>i \<in> I. A'(i))"
apply (case_tac "I=0")
apply (simp add: Inter_def)
apply (erule not_emptyE)
apply (auto simp add: constrains_def st_set_def, blast)
apply (drule bspec, assumption, force)
done
(* The rule below simulates the HOL's one for (\<Inter>z. A i) co (\<Inter>z. B i) *)
lemma constrains_All:
"[| \<forall>z. F:{s \<in> state. P(s, z)} co {s \<in> state. Q(s, z)}; F \<in> program |]==>
F:{s \<in> state. \<forall>z. P(s, z)} co {s \<in> state. \<forall>z. Q(s, z)}"
by (unfold constrains_def, blast)
lemma constrains_imp_subset:
"[| F \<in> A co A' |] ==> A \<subseteq> A'"
by (unfold constrains_def st_set_def, force)
text{*The reasoning is by subsets since "co" refers to single actions
only. So this rule isn't that useful.*}
lemma constrains_trans: "[| F \<in> A co B; F \<in> B co C |] ==> F \<in> A co C"
by (unfold constrains_def st_set_def, auto, blast)
lemma constrains_cancel:
"[| F \<in> A co (A' Un B); F \<in> B co B' |] ==> F \<in> A co (A' Un B')"
apply (drule_tac A = B in constrains_imp_subset)
apply (blast intro: constrains_weaken_R)
done
subsection{*The Unless Operator*}
lemma unless_type: "A unless B \<subseteq> program"
by (force simp add: unless_def constrains_def)
lemma unlessI: "[| F \<in> (A-B) co (A Un B) |] ==> F \<in> A unless B"
apply (unfold unless_def)
apply (blast dest: constrainsD2)
done
lemma unlessD: "F :A unless B ==> F \<in> (A-B) co (A Un B)"
by (unfold unless_def, auto)
subsection{*The Operator @{term initially}*}
lemma initially_type: "initially(A) \<subseteq> program"
by (unfold initially_def, blast)
lemma initiallyI: "[| F \<in> program; Init(F)\<subseteq>A |] ==> F \<in> initially(A)"
by (unfold initially_def, blast)
lemma initiallyD: "F \<in> initially(A) ==> Init(F)\<subseteq>A"
by (unfold initially_def, blast)
subsection{*The Operator @{term stable}*}
lemma stable_type: "stable(A)\<subseteq>program"
by (unfold stable_def constrains_def, blast)
lemma stableI: "F \<in> A co A ==> F \<in> stable(A)"
by (unfold stable_def, assumption)
lemma stableD: "F \<in> stable(A) ==> F \<in> A co A"
by (unfold stable_def, assumption)
lemma stableD2: "F \<in> stable(A) ==> F \<in> program & st_set(A)"
by (unfold stable_def constrains_def, auto)
lemma stable_state [simp]: "stable(state) = program"
by (auto simp add: stable_def constrains_def dest: Acts_type [THEN subsetD])
lemma stable_unless: "stable(A)= A unless 0"
by (auto simp add: unless_def stable_def)
subsection{*Union and Intersection with @{term stable}*}
lemma stable_Un:
"[| F \<in> stable(A); F \<in> stable(A') |] ==> F \<in> stable(A Un A')"
apply (unfold stable_def)
apply (blast intro: constrains_Un)
done
lemma stable_UN:
"[|!!i. i\<in>I ==> F \<in> stable(A(i)); F \<in> program |]
==> F \<in> stable (\<Union>i \<in> I. A(i))"
apply (unfold stable_def)
apply (blast intro: constrains_UN)
done
lemma stable_Int:
"[| F \<in> stable(A); F \<in> stable(A') |] ==> F \<in> stable (A \<inter> A')"
apply (unfold stable_def)
apply (blast intro: constrains_Int)
done
lemma stable_INT:
"[| !!i. i \<in> I ==> F \<in> stable(A(i)); F \<in> program |]
==> F \<in> stable (\<Inter>i \<in> I. A(i))"
apply (unfold stable_def)
apply (blast intro: constrains_INT)
done
lemma stable_All:
"[|\<forall>z. F \<in> stable({s \<in> state. P(s, z)}); F \<in> program|]
==> F \<in> stable({s \<in> state. \<forall>z. P(s, z)})"
apply (unfold stable_def)
apply (rule constrains_All, auto)
done
lemma stable_constrains_Un:
"[| F \<in> stable(C); F \<in> A co (C Un A') |] ==> F \<in> (C Un A) co (C Un A')"
apply (unfold stable_def constrains_def st_set_def, auto)
apply (blast dest!: bspec)
done
lemma stable_constrains_Int:
"[| F \<in> stable(C); F \<in> (C \<inter> A) co A' |] ==> F \<in> (C \<inter> A) co (C \<inter> A')"
by (unfold stable_def constrains_def st_set_def, blast)
(* [| F \<in> stable(C); F \<in> (C \<inter> A) co A |] ==> F \<in> stable(C \<inter> A) *)
lemmas stable_constrains_stable = stable_constrains_Int [THEN stableI]
subsection{*The Operator @{term invariant}*}
lemma invariant_type: "invariant(A) \<subseteq> program"
apply (unfold invariant_def)
apply (blast dest: stable_type [THEN subsetD])
done
lemma invariantI: "[| Init(F)\<subseteq>A; F \<in> stable(A) |] ==> F \<in> invariant(A)"
apply (unfold invariant_def initially_def)
apply (frule stable_type [THEN subsetD], auto)
done
lemma invariantD: "F \<in> invariant(A) ==> Init(F)\<subseteq>A & F \<in> stable(A)"
by (unfold invariant_def initially_def, auto)
lemma invariantD2: "F \<in> invariant(A) ==> F \<in> program & st_set(A)"
apply (unfold invariant_def)
apply (blast dest: stableD2)
done
text{*Could also say
@{term "invariant(A) \<inter> invariant(B) \<subseteq> invariant (A \<inter> B)"}*}
lemma invariant_Int:
"[| F \<in> invariant(A); F \<in> invariant(B) |] ==> F \<in> invariant(A \<inter> B)"
apply (unfold invariant_def initially_def)
apply (simp add: stable_Int, blast)
done
subsection{*The Elimination Theorem*}
(** The "free" m has become universally quantified!
Should the premise be !!m instead of \<forall>m ? Would make it harder
to use in forward proof. **)
text{*The general case is easier to prove than the special case!*}
lemma "elimination":
"[| \<forall>m \<in> M. F \<in> {s \<in> A. x(s) = m} co B(m); F \<in> program |]
==> F \<in> {s \<in> A. x(s) \<in> M} co (\<Union>m \<in> M. B(m))"
by (auto simp add: constrains_def st_set_def, blast)
text{*As above, but for the special case of A=state*}
lemma elimination2:
"[| \<forall>m \<in> M. F \<in> {s \<in> state. x(s) = m} co B(m); F \<in> program |]
==> F:{s \<in> state. x(s) \<in> M} co (\<Union>m \<in> M. B(m))"
by (rule UNITY.elimination, auto)
subsection{*The Operator @{term strongest_rhs}*}
lemma constrains_strongest_rhs:
"[| F \<in> program; st_set(A) |] ==> F \<in> A co (strongest_rhs(F,A))"
by (auto simp add: constrains_def strongest_rhs_def st_set_def
dest: Acts_type [THEN subsetD])
lemma strongest_rhs_is_strongest:
"[| F \<in> A co B; st_set(B) |] ==> strongest_rhs(F,A) \<subseteq> B"
by (auto simp add: constrains_def strongest_rhs_def st_set_def)
ML {*
fun simp_of_act def = def RS @{thm def_act_simp};
fun simp_of_set def = def RS @{thm def_set_simp};
*}
end