tuned proofs -- clarified flow of facts wrt. calculation;
(* Author: Tobias Nipkow *)
theory Def_Init_Small
imports Star Def_Init_Exp Def_Init
begin
subsection "Initialization-Sensitive Small Step Semantics"
inductive
small_step :: "(com \<times> state) \<Rightarrow> (com \<times> state) \<Rightarrow> bool" (infix "\<rightarrow>" 55)
where
Assign: "aval a s = Some i \<Longrightarrow> (x ::= a, s) \<rightarrow> (SKIP, s(x := Some i))" |
Seq1: "(SKIP;;c,s) \<rightarrow> (c,s)" |
Seq2: "(c\<^sub>1,s) \<rightarrow> (c\<^sub>1',s') \<Longrightarrow> (c\<^sub>1;;c\<^sub>2,s) \<rightarrow> (c\<^sub>1';;c\<^sub>2,s')" |
IfTrue: "bval b s = Some True \<Longrightarrow> (IF b THEN c\<^sub>1 ELSE c\<^sub>2,s) \<rightarrow> (c\<^sub>1,s)" |
IfFalse: "bval b s = Some False \<Longrightarrow> (IF b THEN c\<^sub>1 ELSE c\<^sub>2,s) \<rightarrow> (c\<^sub>2,s)" |
While: "(WHILE b DO c,s) \<rightarrow> (IF b THEN c;; WHILE b DO c ELSE SKIP,s)"
lemmas small_step_induct = small_step.induct[split_format(complete)]
abbreviation small_steps :: "com * state \<Rightarrow> com * state \<Rightarrow> bool" (infix "\<rightarrow>*" 55)
where "x \<rightarrow>* y == star small_step x y"
subsection "Soundness wrt Small Steps"
theorem progress:
"D (dom s) c A' \<Longrightarrow> c \<noteq> SKIP \<Longrightarrow> EX cs'. (c,s) \<rightarrow> cs'"
proof (induction c arbitrary: s A')
case Assign thus ?case by auto (metis aval_Some small_step.Assign)
next
case (If b c1 c2)
then obtain bv where "bval b s = Some bv" by (auto dest!:bval_Some)
then show ?case
by(cases bv)(auto intro: small_step.IfTrue small_step.IfFalse)
qed (fastforce intro: small_step.intros)+
lemma D_mono: "D A c M \<Longrightarrow> A \<subseteq> A' \<Longrightarrow> EX M'. D A' c M' & M <= M'"
proof (induction c arbitrary: A A' M)
case Seq thus ?case by auto (metis D.intros(3))
next
case (If b c1 c2)
then obtain M1 M2 where "vars b \<subseteq> A" "D A c1 M1" "D A c2 M2" "M = M1 \<inter> M2"
by auto
with If.IH `A \<subseteq> A'` obtain M1' M2'
where "D A' c1 M1'" "D A' c2 M2'" and "M1 \<subseteq> M1'" "M2 \<subseteq> M2'" by metis
hence "D A' (IF b THEN c1 ELSE c2) (M1' \<inter> M2')" and "M \<subseteq> M1' \<inter> M2'"
using `vars b \<subseteq> A` `A \<subseteq> A'` `M = M1 \<inter> M2` by(fastforce intro: D.intros)+
thus ?case by metis
next
case While thus ?case by auto (metis D.intros(5) subset_trans)
qed (auto intro: D.intros)
theorem D_preservation:
"(c,s) \<rightarrow> (c',s') \<Longrightarrow> D (dom s) c A \<Longrightarrow> EX A'. D (dom s') c' A' & A <= A'"
proof (induction arbitrary: A rule: small_step_induct)
case (While b c s)
then obtain A' where "vars b \<subseteq> dom s" "A = dom s" "D (dom s) c A'" by blast
moreover
then obtain A'' where "D A' c A''" by (metis D_incr D_mono)
ultimately have "D (dom s) (IF b THEN c;; WHILE b DO c ELSE SKIP) (dom s)"
by (metis D.If[OF `vars b \<subseteq> dom s` D.Seq[OF `D (dom s) c A'` D.While[OF _ `D A' c A''`]] D.Skip] D_incr Int_absorb1 subset_trans)
thus ?case by (metis D_incr `A = dom s`)
next
case Seq2 thus ?case by auto (metis D_mono D.intros(3))
qed (auto intro: D.intros)
theorem D_sound:
"(c,s) \<rightarrow>* (c',s') \<Longrightarrow> D (dom s) c A'
\<Longrightarrow> (\<exists>cs''. (c',s') \<rightarrow> cs'') \<or> c' = SKIP"
apply(induction arbitrary: A' rule:star_induct)
apply (metis progress)
by (metis D_preservation)
end