VCG is standard name

--- a/src/HOL/IMP/VC.thy	Fri May 31 07:25:55 2013 +0200
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,126 +0,0 @@
-(* Author: Tobias Nipkow *)
-
-theory VC imports Hoare begin
-
-subsection "Verification Conditions"
-
-text{* Annotated commands: commands where loops are annotated with
-invariants. *}
-
-datatype acom =
-  Askip                  ("SKIP") |
-  Aassign vname aexp     ("(_ ::= _)" [1000, 61] 61) |
-  Aseq   acom acom       ("_;;/ _"  [60, 61] 60) |
-  Aif bexp acom acom     ("(IF _/ THEN _/ ELSE _)"  [0, 0, 61] 61) |
-  Awhile assn bexp acom  ("({_}/ WHILE _/ DO _)"  [0, 0, 61] 61)
-
-
-text{* Strip annotations: *}
-
-fun strip :: "acom \<Rightarrow> com" where
-"strip SKIP = com.SKIP" |
-"strip (x ::= a) = (x ::= a)" |
-"strip (c\<^isub>1;; c\<^isub>2) = (strip c\<^isub>1;; strip c\<^isub>2)" |
-"strip (IF b THEN c\<^isub>1 ELSE c\<^isub>2) = (IF b THEN strip c\<^isub>1 ELSE strip c\<^isub>2)" |
-"strip ({_} WHILE b DO c) = (WHILE b DO strip c)"
-
-text{* Weakest precondition from annotated commands: *}
-
-fun pre :: "acom \<Rightarrow> assn \<Rightarrow> assn" where
-"pre SKIP Q = Q" |
-"pre (x ::= a) Q = (\<lambda>s. Q(s(x := aval a s)))" |
-"pre (c\<^isub>1;; c\<^isub>2) Q = pre c\<^isub>1 (pre c\<^isub>2 Q)" |
-"pre (IF b THEN c\<^isub>1 ELSE c\<^isub>2) Q =
-  (\<lambda>s. (bval b s \<longrightarrow> pre c\<^isub>1 Q s) \<and>
-       (\<not> bval b s \<longrightarrow> pre c\<^isub>2 Q s))" |
-"pre ({I} WHILE b DO c) Q = I"
-
-text{* Verification condition: *}
-
-fun vc :: "acom \<Rightarrow> assn \<Rightarrow> assn" where
-"vc SKIP Q = (\<lambda>s. True)" |
-"vc (x ::= a) Q = (\<lambda>s. True)" |
-"vc (c\<^isub>1;; c\<^isub>2) Q = (\<lambda>s. vc c\<^isub>1 (pre c\<^isub>2 Q) s \<and> vc c\<^isub>2 Q s)" |
-"vc (IF b THEN c\<^isub>1 ELSE c\<^isub>2) Q = (\<lambda>s. vc c\<^isub>1 Q s \<and> vc c\<^isub>2 Q s)" |
-"vc ({I} WHILE b DO c) Q =
-  (\<lambda>s. (I s \<and> \<not> bval b s \<longrightarrow> Q s) \<and>
-       (I s \<and> bval b s \<longrightarrow> pre c I s) \<and>
-       vc c I s)"
-
-
-text {* Soundness: *}
-
-lemma vc_sound: "\<forall>s. vc c Q s \<Longrightarrow> \<turnstile> {pre c Q} strip c {Q}"
-proof(induction c arbitrary: Q)
-  case (Awhile I b c)
-  show ?case
-  proof(simp, rule While')
-    from `\<forall>s. vc (Awhile I b c) Q s`
-    have vc: "\<forall>s. vc c I s" and IQ: "\<forall>s. I s \<and> \<not> bval b s \<longrightarrow> Q s" and
-         pre: "\<forall>s. I s \<and> bval b s \<longrightarrow> pre c I s" by simp_all
-    have "\<turnstile> {pre c I} strip c {I}" by(rule Awhile.IH[OF vc])
-    with pre show "\<turnstile> {\<lambda>s. I s \<and> bval b s} strip c {I}"
-      by(rule strengthen_pre)
-    show "\<forall>s. I s \<and> \<not>bval b s \<longrightarrow> Q s" by(rule IQ)
-  qed
-qed (auto intro: hoare.conseq)
-
-corollary vc_sound':
-  "(\<forall>s. vc c Q s) \<and> (\<forall>s. P s \<longrightarrow> pre c Q s) \<Longrightarrow> \<turnstile> {P} strip c {Q}"
-by (metis strengthen_pre vc_sound)
-
-
-text{* Completeness: *}
-
-lemma pre_mono:
-  "\<forall>s. P s \<longrightarrow> P' s \<Longrightarrow> pre c P s \<Longrightarrow> pre c P' s"
-proof (induction c arbitrary: P P' s)
-  case Aseq thus ?case by simp metis
-qed simp_all
-
-lemma vc_mono:
-  "\<forall>s. P s \<longrightarrow> P' s \<Longrightarrow> vc c P s \<Longrightarrow> vc c P' s"
-proof(induction c arbitrary: P P')
-  case Aseq thus ?case by simp (metis pre_mono)
-qed simp_all
-
-lemma vc_complete:
- "\<turnstile> {P}c{Q} \<Longrightarrow> \<exists>c'. strip c' = c \<and> (\<forall>s. vc c' Q s) \<and> (\<forall>s. P s \<longrightarrow> pre c' Q s)"
-  (is "_ \<Longrightarrow> \<exists>c'. ?G P c Q c'")
-proof (induction rule: hoare.induct)
-  case Skip
-  show ?case (is "\<exists>ac. ?C ac")
-  proof show "?C Askip" by simp qed
-next
-  case (Assign P a x)
-  show ?case (is "\<exists>ac. ?C ac")
-  proof show "?C(Aassign x a)" by simp qed
-next
-  case (Seq P c1 Q c2 R)
-  from Seq.IH obtain ac1 where ih1: "?G P c1 Q ac1" by blast
-  from Seq.IH obtain ac2 where ih2: "?G Q c2 R ac2" by blast
-  show ?case (is "\<exists>ac. ?C ac")
-  proof
-    show "?C(Aseq ac1 ac2)"
-      using ih1 ih2 by (fastforce elim!: pre_mono vc_mono)
-  qed
-next
-  case (If P b c1 Q c2)
-  from If.IH obtain ac1 where ih1: "?G (\<lambda>s. P s \<and> bval b s) c1 Q ac1"
-    by blast
-  from If.IH obtain ac2 where ih2: "?G (\<lambda>s. P s \<and> \<not>bval b s) c2 Q ac2"
-    by blast
-  show ?case (is "\<exists>ac. ?C ac")
-  proof
-    show "?C(Aif b ac1 ac2)" using ih1 ih2 by simp
-  qed
-next
-  case (While P b c)
-  from While.IH obtain ac where ih: "?G (\<lambda>s. P s \<and> bval b s) c P ac" by blast
-  show ?case (is "\<exists>ac. ?C ac")
-  proof show "?C(Awhile P b ac)" using ih by simp qed
-next
-  case conseq thus ?case by(fast elim!: pre_mono vc_mono)
-qed
-
-end

--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/src/HOL/IMP/VCG.thy	Fri May 31 07:26:31 2013 +0200
@@ -0,0 +1,126 @@
+(* Author: Tobias Nipkow *)
+
+theory VC imports Hoare begin
+
+subsection "Verification Conditions"
+
+text{* Annotated commands: commands where loops are annotated with
+invariants. *}
+
+datatype acom =
+  Askip                  ("SKIP") |
+  Aassign vname aexp     ("(_ ::= _)" [1000, 61] 61) |
+  Aseq   acom acom       ("_;;/ _"  [60, 61] 60) |
+  Aif bexp acom acom     ("(IF _/ THEN _/ ELSE _)"  [0, 0, 61] 61) |
+  Awhile assn bexp acom  ("({_}/ WHILE _/ DO _)"  [0, 0, 61] 61)
+
+
+text{* Strip annotations: *}
+
+fun strip :: "acom \<Rightarrow> com" where
+"strip SKIP = com.SKIP" |
+"strip (x ::= a) = (x ::= a)" |
+"strip (c\<^isub>1;; c\<^isub>2) = (strip c\<^isub>1;; strip c\<^isub>2)" |
+"strip (IF b THEN c\<^isub>1 ELSE c\<^isub>2) = (IF b THEN strip c\<^isub>1 ELSE strip c\<^isub>2)" |
+"strip ({_} WHILE b DO c) = (WHILE b DO strip c)"
+
+text{* Weakest precondition from annotated commands: *}
+
+fun pre :: "acom \<Rightarrow> assn \<Rightarrow> assn" where
+"pre SKIP Q = Q" |
+"pre (x ::= a) Q = (\<lambda>s. Q(s(x := aval a s)))" |
+"pre (c\<^isub>1;; c\<^isub>2) Q = pre c\<^isub>1 (pre c\<^isub>2 Q)" |
+"pre (IF b THEN c\<^isub>1 ELSE c\<^isub>2) Q =
+  (\<lambda>s. (bval b s \<longrightarrow> pre c\<^isub>1 Q s) \<and>
+       (\<not> bval b s \<longrightarrow> pre c\<^isub>2 Q s))" |
+"pre ({I} WHILE b DO c) Q = I"
+
+text{* Verification condition: *}
+
+fun vc :: "acom \<Rightarrow> assn \<Rightarrow> assn" where
+"vc SKIP Q = (\<lambda>s. True)" |
+"vc (x ::= a) Q = (\<lambda>s. True)" |
+"vc (c\<^isub>1;; c\<^isub>2) Q = (\<lambda>s. vc c\<^isub>1 (pre c\<^isub>2 Q) s \<and> vc c\<^isub>2 Q s)" |
+"vc (IF b THEN c\<^isub>1 ELSE c\<^isub>2) Q = (\<lambda>s. vc c\<^isub>1 Q s \<and> vc c\<^isub>2 Q s)" |
+"vc ({I} WHILE b DO c) Q =
+  (\<lambda>s. (I s \<and> \<not> bval b s \<longrightarrow> Q s) \<and>
+       (I s \<and> bval b s \<longrightarrow> pre c I s) \<and>
+       vc c I s)"
+
+
+text {* Soundness: *}
+
+lemma vc_sound: "\<forall>s. vc c Q s \<Longrightarrow> \<turnstile> {pre c Q} strip c {Q}"
+proof(induction c arbitrary: Q)
+  case (Awhile I b c)
+  show ?case
+  proof(simp, rule While')
+    from `\<forall>s. vc (Awhile I b c) Q s`
+    have vc: "\<forall>s. vc c I s" and IQ: "\<forall>s. I s \<and> \<not> bval b s \<longrightarrow> Q s" and
+         pre: "\<forall>s. I s \<and> bval b s \<longrightarrow> pre c I s" by simp_all
+    have "\<turnstile> {pre c I} strip c {I}" by(rule Awhile.IH[OF vc])
+    with pre show "\<turnstile> {\<lambda>s. I s \<and> bval b s} strip c {I}"
+      by(rule strengthen_pre)
+    show "\<forall>s. I s \<and> \<not>bval b s \<longrightarrow> Q s" by(rule IQ)
+  qed
+qed (auto intro: hoare.conseq)
+
+corollary vc_sound':
+  "(\<forall>s. vc c Q s) \<and> (\<forall>s. P s \<longrightarrow> pre c Q s) \<Longrightarrow> \<turnstile> {P} strip c {Q}"
+by (metis strengthen_pre vc_sound)
+
+
+text{* Completeness: *}
+
+lemma pre_mono:
+  "\<forall>s. P s \<longrightarrow> P' s \<Longrightarrow> pre c P s \<Longrightarrow> pre c P' s"
+proof (induction c arbitrary: P P' s)
+  case Aseq thus ?case by simp metis
+qed simp_all
+
+lemma vc_mono:
+  "\<forall>s. P s \<longrightarrow> P' s \<Longrightarrow> vc c P s \<Longrightarrow> vc c P' s"
+proof(induction c arbitrary: P P')
+  case Aseq thus ?case by simp (metis pre_mono)
+qed simp_all
+
+lemma vc_complete:
+ "\<turnstile> {P}c{Q} \<Longrightarrow> \<exists>c'. strip c' = c \<and> (\<forall>s. vc c' Q s) \<and> (\<forall>s. P s \<longrightarrow> pre c' Q s)"
+  (is "_ \<Longrightarrow> \<exists>c'. ?G P c Q c'")
+proof (induction rule: hoare.induct)
+  case Skip
+  show ?case (is "\<exists>ac. ?C ac")
+  proof show "?C Askip" by simp qed
+next
+  case (Assign P a x)
+  show ?case (is "\<exists>ac. ?C ac")
+  proof show "?C(Aassign x a)" by simp qed
+next
+  case (Seq P c1 Q c2 R)
+  from Seq.IH obtain ac1 where ih1: "?G P c1 Q ac1" by blast
+  from Seq.IH obtain ac2 where ih2: "?G Q c2 R ac2" by blast
+  show ?case (is "\<exists>ac. ?C ac")
+  proof
+    show "?C(Aseq ac1 ac2)"
+      using ih1 ih2 by (fastforce elim!: pre_mono vc_mono)
+  qed
+next
+  case (If P b c1 Q c2)
+  from If.IH obtain ac1 where ih1: "?G (\<lambda>s. P s \<and> bval b s) c1 Q ac1"
+    by blast
+  from If.IH obtain ac2 where ih2: "?G (\<lambda>s. P s \<and> \<not>bval b s) c2 Q ac2"
+    by blast
+  show ?case (is "\<exists>ac. ?C ac")
+  proof
+    show "?C(Aif b ac1 ac2)" using ih1 ih2 by simp
+  qed
+next
+  case (While P b c)
+  from While.IH obtain ac where ih: "?G (\<lambda>s. P s \<and> bval b s) c P ac" by blast
+  show ?case (is "\<exists>ac. ?C ac")
+  proof show "?C(Awhile P b ac)" using ih by simp qed
+next
+  case conseq thus ?case by(fast elim!: pre_mono vc_mono)
+qed
+
+end