Major Section: MISCELLANEOUS
Lemma instances are the objects one provides via :use
and :by
hints
(see hints) to bring to the theorem prover's attention some
previously proved or easily provable fact. A typical use of the
:use
hint is given below. The value specified is a list of five
lemma instances.
:use (reverse-reverse (:type-prescription app) (:instance assoc-of-app (x a) (y b) (z c)) (:functional-instance p-f (p consp) (f flatten)) (:instance (:theorem (equal x x)) (x (flatten a))))Observe that an event name can be a lemma instance. The
:use
hint
allows a single lemma instance to be provided in lieu of a list, as
in:
:use reverse-reverseor
:use (:instance assoc-of-app (x a) (y b) (z c))
A lemma instance denotes a formula which is either known to be a theorem or which must be proved to be a theorem before it can be used. To use a lemma instance in a particular subgoal, the theorem prover adds the formula as a hypothesis to the subgoal before the normal theorem proving heuristics are applied.
A lemma instance, or lmi
, is of one of the following five forms:
(1) name
, where name
names a previously proved theorem, axiom, or
definition and denotes the formula (theorem) of that name.
(2) rune
, where rune
is a rune (see rune) denoting the
:
corollary
justifying the rule named by the rune.
(3) (:theorem term)
, where term
is any term alleged to be a theorem.
Such a lemma instance denotes the formula term
. But before using
such a lemma instance the system will undertake to prove term
.
(4) (:instance lmi (v1 t1) ... (vn tn))
, where lmi
is recursively a
lemma instance, the vi
's are distinct variables and the ti
's are
terms. Such a lemma instance denotes the formula obtained by
instantiating the formula denoted by lmi
, replacing each vi
by ti
.
(5) (:functional-instance lmi (f1 g1) ... (fn gn))
, where lmi
is recursively a lemma instance and each fi
is an
``instantiable'' function symbol of arity ni
and gi
is a
function symbol or a pseudo-lambda expression of arity ni
. An
instantiable function symbol is any defined or constrained function
symbol except the primitives not
, member
, implies
, and
o<
, and a few others, as listed by the constant
*non-instantiable-primitives*
. These are built-in in such a way
that we cannot recover the constraints on them. A pseudo-lambda
expression is an expression of the form (lambda (v1 ... vn) body)
where the vi
are distinct variable symbols and body
is any
term. No a priori relation is imposed between the vi
and the
variables of body
, i.e., body
may ignore some vi
's and may
contain ``free'' variables. However, we do not permit v
to occur
freely in body
if the functional substitution is to be applied to
any formula (lmi
or the constraints to be satisfied) that
contains v
as a variable. This is our draconian restriction to
avoid capture. If you happen to violate this restriction by
choosing a v
that does occur, say in one of the relevant
constraints, an informative error message will be printed. That
message will list for you the illegal choices for v
in the
context in which the functional substitution is offered. A
:functional-instance
lemma instance denotes the formula
obtained by functionally instantiating the formula denoted by
lmi
, replacing fi
by gi
. However, before such a lemma
instance can be used, the system will undertake to prove that the
gi
's satisfy the constraints (see constraint) on the
fi
's. One might expect that if the same instantiated constraint
were generated on behalf of multiple events, then each of those
instances would have to be proved. However, for the sake of
efficiency, ACL2 stores the fact that such an instantiated
constraint has been proved and avoids it in future events.
See functional-instantiation-example for an example of the use
of :functional-instance
(so-called ``functional instantiation).''