(* Title: HOL/TLA/Action.thy
Author: Stephan Merz
Copyright: 1998 University of Munich
*)
section {* The action level of TLA as an Isabelle theory *}
theory Action
imports Stfun
begin
(** abstract syntax **)
type_synonym 'a trfun = "(state * state) \<Rightarrow> 'a"
type_synonym action = "bool trfun"
instance prod :: (world, world) world ..
consts
(** abstract syntax **)
before :: "'a stfun \<Rightarrow> 'a trfun"
after :: "'a stfun \<Rightarrow> 'a trfun"
unch :: "'a stfun \<Rightarrow> action"
SqAct :: "[action, 'a stfun] \<Rightarrow> action"
AnAct :: "[action, 'a stfun] \<Rightarrow> action"
enabled :: "action \<Rightarrow> stpred"
(** concrete syntax **)
syntax
(* Syntax for writing action expressions in arbitrary contexts *)
"_ACT" :: "lift \<Rightarrow> 'a" ("(ACT _)")
"_before" :: "lift \<Rightarrow> lift" ("($_)" [100] 99)
"_after" :: "lift \<Rightarrow> lift" ("(_$)" [100] 99)
"_unchanged" :: "lift \<Rightarrow> lift" ("(unchanged _)" [100] 99)
(*** Priming: same as "after" ***)
"_prime" :: "lift \<Rightarrow> lift" ("(_`)" [100] 99)
"_SqAct" :: "[lift, lift] \<Rightarrow> lift" ("([_]'_(_))" [0,1000] 99)
"_AnAct" :: "[lift, lift] \<Rightarrow> lift" ("(<_>'_(_))" [0,1000] 99)
"_Enabled" :: "lift \<Rightarrow> lift" ("(Enabled _)" [100] 100)
translations
"ACT A" => "(A::state*state \<Rightarrow> _)"
"_before" == "CONST before"
"_after" == "CONST after"
"_prime" => "_after"
"_unchanged" == "CONST unch"
"_SqAct" == "CONST SqAct"
"_AnAct" == "CONST AnAct"
"_Enabled" == "CONST enabled"
"w \<Turnstile> [A]_v" <= "_SqAct A v w"
"w \<Turnstile> <A>_v" <= "_AnAct A v w"
"s \<Turnstile> Enabled A" <= "_Enabled A s"
"w \<Turnstile> unchanged f" <= "_unchanged f w"
axiomatization where
unl_before: "(ACT $v) (s,t) \<equiv> v s" and
unl_after: "(ACT v$) (s,t) \<equiv> v t" and
unchanged_def: "(s,t) \<Turnstile> unchanged v \<equiv> (v t = v s)"
defs
square_def: "ACT [A]_v \<equiv> ACT (A \<or> unchanged v)"
angle_def: "ACT <A>_v \<equiv> ACT (A \<and> \<not> unchanged v)"
enabled_def: "s \<Turnstile> Enabled A \<equiv> \<exists>u. (s,u) \<Turnstile> A"
(* The following assertion specializes "intI" for any world type
which is a pair, not just for "state * state".
*)
lemma actionI [intro!]:
assumes "\<And>s t. (s,t) \<Turnstile> A"
shows "\<turnstile> A"
apply (rule assms intI prod.induct)+
done
lemma actionD [dest]: "\<turnstile> A \<Longrightarrow> (s,t) \<Turnstile> A"
apply (erule intD)
done
lemma pr_rews [int_rewrite]:
"\<turnstile> (#c)` = #c"
"\<And>f. \<turnstile> f<x>` = f<x` >"
"\<And>f. \<turnstile> f<x,y>` = f<x`,y` >"
"\<And>f. \<turnstile> f<x,y,z>` = f<x`,y`,z` >"
"\<turnstile> (\<forall>x. P x)` = (\<forall>x. (P x)`)"
"\<turnstile> (\<exists>x. P x)` = (\<exists>x. (P x)`)"
by (rule actionI, unfold unl_after intensional_rews, rule refl)+
lemmas act_rews [simp] = unl_before unl_after unchanged_def pr_rews
lemmas action_rews = act_rews intensional_rews
(* ================ Functions to "unlift" action theorems into HOL rules ================ *)
ML {*
(* The following functions are specialized versions of the corresponding
functions defined in Intensional.ML in that they introduce a
"world" parameter of the form (s,t) and apply additional rewrites.
*)
fun action_unlift ctxt th =
(rewrite_rule ctxt @{thms action_rews} (th RS @{thm actionD}))
handle THM _ => int_unlift ctxt th;
(* Turn \<turnstile> A = B into meta-level rewrite rule A == B *)
val action_rewrite = int_rewrite
fun action_use ctxt th =
case Thm.concl_of th of
Const _ $ (Const (@{const_name Valid}, _) $ _) =>
(flatten (action_unlift ctxt th) handle THM _ => th)
| _ => th;
*}
attribute_setup action_unlift =
{* Scan.succeed (Thm.rule_attribute (action_unlift o Context.proof_of)) *}
attribute_setup action_rewrite =
{* Scan.succeed (Thm.rule_attribute (action_rewrite o Context.proof_of)) *}
attribute_setup action_use =
{* Scan.succeed (Thm.rule_attribute (action_use o Context.proof_of)) *}
(* =========================== square / angle brackets =========================== *)
lemma idle_squareI: "(s,t) \<Turnstile> unchanged v \<Longrightarrow> (s,t) \<Turnstile> [A]_v"
by (simp add: square_def)
lemma busy_squareI: "(s,t) \<Turnstile> A \<Longrightarrow> (s,t) \<Turnstile> [A]_v"
by (simp add: square_def)
lemma squareE [elim]:
"\<lbrakk> (s,t) \<Turnstile> [A]_v; A (s,t) \<Longrightarrow> B (s,t); v t = v s \<Longrightarrow> B (s,t) \<rbrakk> \<Longrightarrow> B (s,t)"
apply (unfold square_def action_rews)
apply (erule disjE)
apply simp_all
done
lemma squareCI [intro]: "\<lbrakk> v t \<noteq> v s \<Longrightarrow> A (s,t) \<rbrakk> \<Longrightarrow> (s,t) \<Turnstile> [A]_v"
apply (unfold square_def action_rews)
apply (rule disjCI)
apply (erule (1) meta_mp)
done
lemma angleI [intro]: "\<And>s t. \<lbrakk> A (s,t); v t \<noteq> v s \<rbrakk> \<Longrightarrow> (s,t) \<Turnstile> <A>_v"
by (simp add: angle_def)
lemma angleE [elim]: "\<lbrakk> (s,t) \<Turnstile> <A>_v; \<lbrakk> A (s,t); v t \<noteq> v s \<rbrakk> \<Longrightarrow> R \<rbrakk> \<Longrightarrow> R"
apply (unfold angle_def action_rews)
apply (erule conjE)
apply simp
done
lemma square_simulation:
"\<And>f. \<lbrakk> \<turnstile> unchanged f \<and> \<not>B \<longrightarrow> unchanged g;
\<turnstile> A \<and> \<not>unchanged g \<longrightarrow> B
\<rbrakk> \<Longrightarrow> \<turnstile> [A]_f \<longrightarrow> [B]_g"
apply clarsimp
apply (erule squareE)
apply (auto simp add: square_def)
done
lemma not_square: "\<turnstile> (\<not> [A]_v) = <\<not>A>_v"
by (auto simp: square_def angle_def)
lemma not_angle: "\<turnstile> (\<not> <A>_v) = [\<not>A]_v"
by (auto simp: square_def angle_def)
(* ============================== Facts about ENABLED ============================== *)
lemma enabledI: "\<turnstile> A \<longrightarrow> $Enabled A"
by (auto simp add: enabled_def)
lemma enabledE: "\<lbrakk> s \<Turnstile> Enabled A; \<And>u. A (s,u) \<Longrightarrow> Q \<rbrakk> \<Longrightarrow> Q"
apply (unfold enabled_def)
apply (erule exE)
apply simp
done
lemma notEnabledD: "\<turnstile> \<not>$Enabled G \<longrightarrow> \<not> G"
by (auto simp add: enabled_def)
(* Monotonicity *)
lemma enabled_mono:
assumes min: "s \<Turnstile> Enabled F"
and maj: "\<turnstile> F \<longrightarrow> G"
shows "s \<Turnstile> Enabled G"
apply (rule min [THEN enabledE])
apply (rule enabledI [action_use])
apply (erule maj [action_use])
done
(* stronger variant *)
lemma enabled_mono2:
assumes min: "s \<Turnstile> Enabled F"
and maj: "\<And>t. F (s,t) \<Longrightarrow> G (s,t)"
shows "s \<Turnstile> Enabled G"
apply (rule min [THEN enabledE])
apply (rule enabledI [action_use])
apply (erule maj)
done
lemma enabled_disj1: "\<turnstile> Enabled F \<longrightarrow> Enabled (F \<or> G)"
by (auto elim!: enabled_mono)
lemma enabled_disj2: "\<turnstile> Enabled G \<longrightarrow> Enabled (F \<or> G)"
by (auto elim!: enabled_mono)
lemma enabled_conj1: "\<turnstile> Enabled (F \<and> G) \<longrightarrow> Enabled F"
by (auto elim!: enabled_mono)
lemma enabled_conj2: "\<turnstile> Enabled (F \<and> G) \<longrightarrow> Enabled G"
by (auto elim!: enabled_mono)
lemma enabled_conjE:
"\<lbrakk> s \<Turnstile> Enabled (F \<and> G); \<lbrakk> s \<Turnstile> Enabled F; s \<Turnstile> Enabled G \<rbrakk> \<Longrightarrow> Q \<rbrakk> \<Longrightarrow> Q"
apply (frule enabled_conj1 [action_use])
apply (drule enabled_conj2 [action_use])
apply simp
done
lemma enabled_disjD: "\<turnstile> Enabled (F \<or> G) \<longrightarrow> Enabled F \<or> Enabled G"
by (auto simp add: enabled_def)
lemma enabled_disj: "\<turnstile> Enabled (F \<or> G) = (Enabled F \<or> Enabled G)"
apply clarsimp
apply (rule iffI)
apply (erule enabled_disjD [action_use])
apply (erule disjE enabled_disj1 [action_use] enabled_disj2 [action_use])+
done
lemma enabled_ex: "\<turnstile> Enabled (\<exists>x. F x) = (\<exists>x. Enabled (F x))"
by (force simp add: enabled_def)
(* A rule that combines enabledI and baseE, but generates fewer instantiations *)
lemma base_enabled:
"\<lbrakk> basevars vs; \<exists>c. \<forall>u. vs u = c \<longrightarrow> A(s,u) \<rbrakk> \<Longrightarrow> s \<Turnstile> Enabled A"
apply (erule exE)
apply (erule baseE)
apply (rule enabledI [action_use])
apply (erule allE)
apply (erule mp)
apply assumption
done
(* ======================= action_simp_tac ============================== *)
ML {*
(* A dumb simplification-based tactic with just a little first-order logic:
should plug in only "very safe" rules that can be applied blindly.
Note that it applies whatever simplifications are currently active.
*)
fun action_simp_tac ctxt intros elims =
asm_full_simp_tac
(ctxt setloop (fn _ => (resolve_tac ctxt ((map (action_use ctxt) intros)
@ [refl,impI,conjI,@{thm actionI},@{thm intI},allI]))
ORELSE' (eresolve_tac ctxt ((map (action_use ctxt) elims)
@ [conjE,disjE,exE]))));
*}
(* ---------------- enabled_tac: tactic to prove (Enabled A) -------------------- *)
ML {*
(* "Enabled A" can be proven as follows:
- Assume that we know which state variables are "base variables"
this should be expressed by a theorem of the form "basevars (x,y,z,...)".
- Resolve this theorem with baseE to introduce a constant for the value of the
variables in the successor state, and resolve the goal with the result.
- Resolve with enabledI and do some rewriting.
- Solve for the unknowns using standard HOL reasoning.
The following tactic combines these steps except the final one.
*)
fun enabled_tac ctxt base_vars =
clarsimp_tac (ctxt addSIs [base_vars RS @{thm base_enabled}]);
*}
method_setup enabled = {*
Attrib.thm >> (fn th => fn ctxt => SIMPLE_METHOD' (enabled_tac ctxt th))
*}
(* Example *)
lemma
assumes "basevars (x,y,z)"
shows "\<turnstile> x \<longrightarrow> Enabled ($x \<and> (y$ = #False))"
apply (enabled assms)
apply auto
done
end