(* Title: HOL/Isar_examples/Hoare.thy
ID: $Id$
Author: Markus Wenzel, TU Muenchen
A formulation of Hoare logic suitable for Isar.
*)
header {* Hoare Logic *}
theory Hoare imports Main
uses ("~~/src/HOL/Hoare/hoare.ML") begin
subsection {* Abstract syntax and semantics *}
text {*
The following abstract syntax and semantics of Hoare Logic over
\texttt{WHILE} programs closely follows the existing tradition in
Isabelle/HOL of formalizing the presentation given in
\cite[\S6]{Winskel:1993}. See also
\url{http://isabelle.in.tum.de/library/Hoare/} and
\cite{Nipkow:1998:Winskel}.
*}
types
'a bexp = "'a set"
'a assn = "'a set"
datatype 'a com =
Basic "'a => 'a"
| Seq "'a com" "'a com" ("(_;/ _)" [60, 61] 60)
| Cond "'a bexp" "'a com" "'a com"
| While "'a bexp" "'a assn" "'a com"
syntax
"_skip" :: "'a com" ("SKIP")
translations
"SKIP" == "Basic id"
types
'a sem = "'a => 'a => bool"
consts
iter :: "nat => 'a bexp => 'a sem => 'a sem"
primrec
"iter 0 b S s s' = (s ~: b & s = s')"
"iter (Suc n) b S s s' =
(s : b & (EX s''. S s s'' & iter n b S s'' s'))"
consts
Sem :: "'a com => 'a sem"
primrec
"Sem (Basic f) s s' = (s' = f s)"
"Sem (c1; c2) s s' = (EX s''. Sem c1 s s'' & Sem c2 s'' s')"
"Sem (Cond b c1 c2) s s' =
(if s : b then Sem c1 s s' else Sem c2 s s')"
"Sem (While b x c) s s' = (EX n. iter n b (Sem c) s s')"
constdefs
Valid :: "'a bexp => 'a com => 'a bexp => bool"
("(3|- _/ (2_)/ _)" [100, 55, 100] 50)
"|- P c Q == ALL s s'. Sem c s s' --> s : P --> s' : Q"
syntax (xsymbols)
Valid :: "'a bexp => 'a com => 'a bexp => bool"
("(3\<turnstile> _/ (2_)/ _)" [100, 55, 100] 50)
lemma ValidI [intro?]:
"(!!s s'. Sem c s s' ==> s : P ==> s' : Q) ==> |- P c Q"
by (simp add: Valid_def)
lemma ValidD [dest?]:
"|- P c Q ==> Sem c s s' ==> s : P ==> s' : Q"
by (simp add: Valid_def)
subsection {* Primitive Hoare rules *}
text {*
From the semantics defined above, we derive the standard set of
primitive Hoare rules; e.g.\ see \cite[\S6]{Winskel:1993}. Usually,
variant forms of these rules are applied in actual proof, see also
\S\ref{sec:hoare-isar} and \S\ref{sec:hoare-vcg}.
\medskip The \name{basic} rule represents any kind of atomic access
to the state space. This subsumes the common rules of \name{skip}
and \name{assign}, as formulated in \S\ref{sec:hoare-isar}.
*}
theorem basic: "|- {s. f s : P} (Basic f) P"
proof
fix s s' assume s: "s : {s. f s : P}"
assume "Sem (Basic f) s s'"
hence "s' = f s" by simp
with s show "s' : P" by simp
qed
text {*
The rules for sequential commands and semantic consequences are
established in a straight forward manner as follows.
*}
theorem seq: "|- P c1 Q ==> |- Q c2 R ==> |- P (c1; c2) R"
proof
assume cmd1: "|- P c1 Q" and cmd2: "|- Q c2 R"
fix s s' assume s: "s : P"
assume "Sem (c1; c2) s s'"
then obtain s'' where sem1: "Sem c1 s s''" and sem2: "Sem c2 s'' s'"
by auto
from cmd1 sem1 s have "s'' : Q" ..
with cmd2 sem2 show "s' : R" ..
qed
theorem conseq: "P' <= P ==> |- P c Q ==> Q <= Q' ==> |- P' c Q'"
proof
assume P'P: "P' <= P" and QQ': "Q <= Q'"
assume cmd: "|- P c Q"
fix s s' :: 'a
assume sem: "Sem c s s'"
assume "s : P'" with P'P have "s : P" ..
with cmd sem have "s' : Q" ..
with QQ' show "s' : Q'" ..
qed
text {*
The rule for conditional commands is directly reflected by the
corresponding semantics; in the proof we just have to look closely
which cases apply.
*}
theorem cond:
"|- (P Int b) c1 Q ==> |- (P Int -b) c2 Q ==> |- P (Cond b c1 c2) Q"
proof
assume case_b: "|- (P Int b) c1 Q" and case_nb: "|- (P Int -b) c2 Q"
fix s s' assume s: "s : P"
assume sem: "Sem (Cond b c1 c2) s s'"
show "s' : Q"
proof cases
assume b: "s : b"
from case_b show ?thesis
proof
from sem b show "Sem c1 s s'" by simp
from s b show "s : P Int b" by simp
qed
next
assume nb: "s ~: b"
from case_nb show ?thesis
proof
from sem nb show "Sem c2 s s'" by simp
from s nb show "s : P Int -b" by simp
qed
qed
qed
text {*
The \name{while} rule is slightly less trivial --- it is the only one
based on recursion, which is expressed in the semantics by a
Kleene-style least fixed-point construction. The auxiliary statement
below, which is by induction on the number of iterations is the main
point to be proven; the rest is by routine application of the
semantics of \texttt{WHILE}.
*}
theorem while: "|- (P Int b) c P ==> |- P (While b X c) (P Int -b)"
proof
assume body: "|- (P Int b) c P"
fix s s' assume s: "s : P"
assume "Sem (While b X c) s s'"
then obtain n where iter: "iter n b (Sem c) s s'" by auto
have "!!s. iter n b (Sem c) s s' ==> s : P ==> s' : P Int -b"
proof (induct n)
case (0 s)
thus ?case by auto
next
case (Suc n s)
then obtain s'' where b: "s : b" and sem: "Sem c s s''"
and iter: "iter n b (Sem c) s'' s'"
by auto
from Suc and b have "s : P Int b" by simp
with body sem have "s'' : P" ..
with iter show ?case by (rule Suc)
qed
from this iter s show "s' : P Int -b" .
qed
subsection {* Concrete syntax for assertions *}
text {*
We now introduce concrete syntax for describing commands (with
embedded expressions) and assertions. The basic technique is that of
semantic ``quote-antiquote''. A \emph{quotation} is a syntactic
entity delimited by an implicit abstraction, say over the state
space. An \emph{antiquotation} is a marked expression within a
quotation that refers the implicit argument; a typical antiquotation
would select (or even update) components from the state.
We will see some examples later in the concrete rules and
applications.
*}
text {*
The following specification of syntax and translations is for
Isabelle experts only; feel free to ignore it.
While the first part is still a somewhat intelligible specification
of the concrete syntactic representation of our Hoare language, the
actual ``ML drivers'' is quite involved. Just note that the we
re-use the basic quote/antiquote translations as already defined in
Isabelle/Pure (see \verb,Syntax.quote_tr, and
\verb,Syntax.quote_tr',).
*}
syntax
"_quote" :: "'b => ('a => 'b)" ("(.'(_').)" [0] 1000)
"_antiquote" :: "('a => 'b) => 'b" ("\<acute>_" [1000] 1000)
"_Subst" :: "'a bexp \<Rightarrow> 'b \<Rightarrow> idt \<Rightarrow> 'a bexp"
("_[_'/\<acute>_]" [1000] 999)
"_Assert" :: "'a => 'a set" ("(.{_}.)" [0] 1000)
"_Assign" :: "idt => 'b => 'a com" ("(\<acute>_ :=/ _)" [70, 65] 61)
"_Cond" :: "'a bexp => 'a com => 'a com => 'a com"
("(0IF _/ THEN _/ ELSE _/ FI)" [0, 0, 0] 61)
"_While_inv" :: "'a bexp => 'a assn => 'a com => 'a com"
("(0WHILE _/ INV _ //DO _ /OD)" [0, 0, 0] 61)
"_While" :: "'a bexp => 'a com => 'a com"
("(0WHILE _ //DO _ /OD)" [0, 0] 61)
syntax (xsymbols)
"_Assert" :: "'a => 'a set" ("(\<lbrace>_\<rbrace>)" [0] 1000)
translations
".{b}." => "Collect .(b)."
"B [a/\<acute>x]" => ".{\<acute>(_update_name x a) \<in> B}."
"\<acute>x := a" => "Basic .(\<acute>(_update_name x a))."
"IF b THEN c1 ELSE c2 FI" => "Cond .{b}. c1 c2"
"WHILE b INV i DO c OD" => "While .{b}. i c"
"WHILE b DO c OD" == "WHILE b INV arbitrary DO c OD"
parse_translation {*
let
fun quote_tr [t] = Syntax.quote_tr "_antiquote" t
| quote_tr ts = raise TERM ("quote_tr", ts);
in [("_quote", quote_tr)] end
*}
text {*
As usual in Isabelle syntax translations, the part for printing is
more complicated --- we cannot express parts as macro rules as above.
Don't look here, unless you have to do similar things for yourself.
*}
print_translation {*
let
fun quote_tr' f (t :: ts) =
Term.list_comb (f $ Syntax.quote_tr' "_antiquote" t, ts)
| quote_tr' _ _ = raise Match;
val assert_tr' = quote_tr' (Syntax.const "_Assert");
fun bexp_tr' name ((Const ("Collect", _) $ t) :: ts) =
quote_tr' (Syntax.const name) (t :: ts)
| bexp_tr' _ _ = raise Match;
fun upd_tr' (x_upd, T) =
(case try (unsuffix RecordPackage.updateN) x_upd of
SOME x => (x, if T = dummyT then T else Term.domain_type T)
| NONE => raise Match);
fun update_name_tr' (Free x) = Free (upd_tr' x)
| update_name_tr' ((c as Const ("_free", _)) $ Free x) =
c $ Free (upd_tr' x)
| update_name_tr' (Const x) = Const (upd_tr' x)
| update_name_tr' _ = raise Match;
fun assign_tr' (Abs (x, _, f $ t $ Bound 0) :: ts) =
quote_tr' (Syntax.const "_Assign" $ update_name_tr' f)
(Abs (x, dummyT, t) :: ts)
| assign_tr' _ = raise Match;
in
[("Collect", assert_tr'), ("Basic", assign_tr'),
("Cond", bexp_tr' "_Cond"), ("While", bexp_tr' "_While_inv")]
end
*}
subsection {* Rules for single-step proof \label{sec:hoare-isar} *}
text {*
We are now ready to introduce a set of Hoare rules to be used in
single-step structured proofs in Isabelle/Isar. We refer to the
concrete syntax introduce above.
\medskip Assertions of Hoare Logic may be manipulated in
calculational proofs, with the inclusion expressed in terms of sets
or predicates. Reversed order is supported as well.
*}
lemma [trans]: "|- P c Q ==> P' <= P ==> |- P' c Q"
by (unfold Valid_def) blast
lemma [trans] : "P' <= P ==> |- P c Q ==> |- P' c Q"
by (unfold Valid_def) blast
lemma [trans]: "Q <= Q' ==> |- P c Q ==> |- P c Q'"
by (unfold Valid_def) blast
lemma [trans]: "|- P c Q ==> Q <= Q' ==> |- P c Q'"
by (unfold Valid_def) blast
lemma [trans]:
"|- .{\<acute>P}. c Q ==> (!!s. P' s --> P s) ==> |- .{\<acute>P'}. c Q"
by (simp add: Valid_def)
lemma [trans]:
"(!!s. P' s --> P s) ==> |- .{\<acute>P}. c Q ==> |- .{\<acute>P'}. c Q"
by (simp add: Valid_def)
lemma [trans]:
"|- P c .{\<acute>Q}. ==> (!!s. Q s --> Q' s) ==> |- P c .{\<acute>Q'}."
by (simp add: Valid_def)
lemma [trans]:
"(!!s. Q s --> Q' s) ==> |- P c .{\<acute>Q}. ==> |- P c .{\<acute>Q'}."
by (simp add: Valid_def)
text {*
Identity and basic assignments.\footnote{The $\idt{hoare}$ method
introduced in \S\ref{sec:hoare-vcg} is able to provide proper
instances for any number of basic assignments, without producing
additional verification conditions.}
*}
lemma skip [intro?]: "|- P SKIP P"
proof -
have "|- {s. id s : P} SKIP P" by (rule basic)
thus ?thesis by simp
qed
lemma assign: "|- P [\<acute>a/\<acute>x] \<acute>x := \<acute>a P"
by (rule basic)
text {*
Note that above formulation of assignment corresponds to our
preferred way to model state spaces, using (extensible) record types
in HOL \cite{Naraschewski-Wenzel:1998:HOOL}. For any record field
$x$, Isabelle/HOL provides a functions $x$ (selector) and
$\idt{x{\dsh}update}$ (update). Above, there is only a place-holder
appearing for the latter kind of function: due to concrete syntax
\isa{\'x := \'a} also contains \isa{x\_update}.\footnote{Note that due
to the external nature of HOL record fields, we could not even state
a general theorem relating selector and update functions (if this
were required here); this would only work for any particular instance
of record fields introduced so far.}
*}
text {*
Sequential composition --- normalizing with associativity achieves
proper of chunks of code verified separately.
*}
lemmas [trans, intro?] = seq
lemma seq_assoc [simp]: "( |- P c1;(c2;c3) Q) = ( |- P (c1;c2);c3 Q)"
by (auto simp add: Valid_def)
text {*
Conditional statements.
*}
lemmas [trans, intro?] = cond
lemma [trans, intro?]:
"|- .{\<acute>P & \<acute>b}. c1 Q
==> |- .{\<acute>P & ~ \<acute>b}. c2 Q
==> |- .{\<acute>P}. IF \<acute>b THEN c1 ELSE c2 FI Q"
by (rule cond) (simp_all add: Valid_def)
text {*
While statements --- with optional invariant.
*}
lemma [intro?]:
"|- (P Int b) c P ==> |- P (While b P c) (P Int -b)"
by (rule while)
lemma [intro?]:
"|- (P Int b) c P ==> |- P (While b arbitrary c) (P Int -b)"
by (rule while)
lemma [intro?]:
"|- .{\<acute>P & \<acute>b}. c .{\<acute>P}.
==> |- .{\<acute>P}. WHILE \<acute>b INV .{\<acute>P}. DO c OD .{\<acute>P & ~ \<acute>b}."
by (simp add: while Collect_conj_eq Collect_neg_eq)
lemma [intro?]:
"|- .{\<acute>P & \<acute>b}. c .{\<acute>P}.
==> |- .{\<acute>P}. WHILE \<acute>b DO c OD .{\<acute>P & ~ \<acute>b}."
by (simp add: while Collect_conj_eq Collect_neg_eq)
subsection {* Verification conditions \label{sec:hoare-vcg} *}
text {*
We now load the \emph{original} ML file for proof scripts and tactic
definition for the Hoare Verification Condition Generator (see
\url{http://isabelle.in.tum.de/library/Hoare/}). As far as we are
concerned here, the result is a proof method \name{hoare}, which may
be applied to a Hoare Logic assertion to extract purely logical
verification conditions. It is important to note that the method
requires \texttt{WHILE} loops to be fully annotated with invariants
beforehand. Furthermore, only \emph{concrete} pieces of code are
handled --- the underlying tactic fails ungracefully if supplied with
meta-variables or parameters, for example.
*}
lemma SkipRule: "p \<subseteq> q \<Longrightarrow> Valid p (Basic id) q"
by (auto simp:Valid_def)
lemma BasicRule: "p \<subseteq> {s. f s \<in> q} \<Longrightarrow> Valid p (Basic f) q"
by (auto simp:Valid_def)
lemma SeqRule: "Valid P c1 Q \<Longrightarrow> Valid Q c2 R \<Longrightarrow> Valid P (c1;c2) R"
by (auto simp:Valid_def)
lemma CondRule:
"p \<subseteq> {s. (s \<in> b \<longrightarrow> s \<in> w) \<and> (s \<notin> b \<longrightarrow> s \<in> w')}
\<Longrightarrow> Valid w c1 q \<Longrightarrow> Valid w' c2 q \<Longrightarrow> Valid p (Cond b c1 c2) q"
by (auto simp:Valid_def)
lemma iter_aux: "! s s'. Sem c s s' --> s : I & s : b --> s' : I ==>
(\<And>s s'. s : I \<Longrightarrow> iter n b (Sem c) s s' \<Longrightarrow> s' : I & s' ~: b)";
apply(induct n)
apply clarsimp
apply(simp (no_asm_use))
apply blast
done
lemma WhileRule:
"p \<subseteq> i \<Longrightarrow> Valid (i \<inter> b) c i \<Longrightarrow> i \<inter> (-b) \<subseteq> q \<Longrightarrow> Valid p (While b i c) q"
apply (clarsimp simp:Valid_def)
apply(drule iter_aux)
prefer 2 apply assumption
apply blast
apply blast
done
ML {* val Valid_def = thm "Valid_def" *}
use "~~/src/HOL/Hoare/hoare.ML"
method_setup hoare = {*
Method.no_args
(Method.SIMPLE_METHOD' HEADGOAL (hoare_tac (K all_tac))) *}
"verification condition generator for Hoare logic"
end