Major Section: EVENTS
Examples: (encapsulate (((an-element *) => *)); The list of signatures above could also be written ; ((an-element (lst) t))
(local (defun an-element (lst) (if (consp lst) (car lst) nil))) (local (defthm member-equal-car (implies (and lst (true-listp lst)) (member-equal (car lst) lst)))) (defthm thm1 (implies (null lst) (null (an-element lst)))) (defthm thm2 (implies (and (true-listp lst) (not (null lst))) (member-equal (an-element lst) lst))))
(encapsulate ()
(local (defthm hack (implies (and (syntaxp (quotep x)) (syntaxp (quotep y))) (equal (+ x y z) (+ (+ x y) z)))))
(defthm nthcdr-add1-conditional (implies (not (zp (1+ n))) (equal (nthcdr (1+ n) x) (nthcdr n (cdr x))))))
General Form: (encapsulate (signature ... signature) ev1 ... evn)
where each signature
is a well-formed signature (see signature), each
signature
describes a different function symbol, and each evi
is an
embedded event form (See embedded-event-form). There must be at least one
evi
. The evi
inside local
special forms are called ``local''
events below. Events that are not local
are sometimes said
to be ``exported'' by the encapsulation. We make the further restriction
that no defaxiom
event may be introduced in the scope of an
encapsulate
(not even by encapsulate
or include-book
events
that are among the evi
). Furthermore, no non-local
include-book
event is permitted in the scope of any encapsulate
with a non-empty list of signatures.
To be well-formed, an encapsulate
event must have the properties
that each event in the body (including the local
ones) can be
successfully executed in sequence and that in the resulting theory,
each function mentioned among the signatures was introduced via a
local
event and has the signature listed. In addition, the body may
contain no ``local incompatibilities'' which, roughly stated, means
that the events that are not local
must not syntactically require
symbols defined by local
events
, except for the functions listed in
the signatures. See local-incompatibility. Finally, no
non-local
recursive definition in the body may involve in its
suggested induction scheme any function symbol listed among the
signatures. See subversive-recursions.
The result of an encapsulate
event is an extension of the logic
in which, roughly speaking, the functions listed in the
signatures are constrained to have the signatures listed
and to satisfy the non-local
theorems proved about them. In
fact, other functions introduced in the encapsulate
event may be
considered to have ``constraints'' as well. (See constraint
for details, which are only relevant to functional instantiation.)
Since the constraints were all theorems in the ``ephemeral'' or
``local'' theory, we are assured that the extension produced by
encapsulate
is sound. In essence, the local
definitions of
the constrained functions are just ``witness functions'' that
establish the consistency of the constraints. Because those
definitions are local
, they are not present in the theory
produced by encapsulation. Encapsulate
also exports all rules
generated by its non-local
events, but rules generated by
local
events are not exported.
The default-defun-mode for the first event in an encapsulation is
the default defun-mode ``outside'' the encapsulation. But since
events changing the defun-mode are permitted within the body of an
encapsulate
, the default defun-mode may be changed. However,
defun-mode changes occurring within the body of the encapsulate
are not exported. In particular, the acl2-defaults-table
after
an encapsulate
is always the same as it was before the
encapsulate
, even though the encapsulate
body might contain
defun-mode changing events, :
program
and :
logic
.
See defun-mode. More generally, after execution of an
encapsulate
event, the value of acl2-defaults-table
is
restored to what it was immediately before that event was executed.
See acl2-defaults-table.
Theorems about the constrained function symbols may then be proved
-- theorems whose proofs necessarily employ only the constraints.
Thus, those theorems may be later functionally instantiated, as with
the :functional-instance
lemma instance
(see lemma-instance), to derive analogous theorems about
different functions, provided the constraints (see constraint)
can be proved about the new functions.
Observe that if the signatures list is empty, encapsulate
may still
be useful for deriving theorems to be exported whose proofs require
lemmas you prefer to hide (i.e., made local
).
The order of the events in the vicinity of an encapsulate
is
confusing. We discuss it in some detail here because when logical
names are being used with theory functions to compute sets of rules,
it is sometimes important to know the order in which events were
executed. (See logical-name and see theory-functions.)
What, for example, is the set of function names extant in the middle
of an encapsulation?
If the most recent event is previous
and then you execute an
encapsulate
constraining an-element
with two non-local
events in its
body, thm1
and thm2
, then the order of the events after the
encapsulation is (reading chronologically forward): previous
, thm1
,
thm2
, an-element
(the encapsulate
itself). Actually, between
previous
and thm1
certain extensions were made to the world by the
superior encapsulate
, to permit an-element
to be used as a function
symbol in thm1
.
Finally, we note that an encapsulate
event is redundant if and
only if a syntactically identical encapsulate
has already been
executed under the same default-defun-mode
.
See redundant-events.