Major Section: RULE-CLASSES
See rule-classes for a general discussion of rule classes and
how they are used to build rules from formulas. An example
:
corollary
formula from which a :well-founded-relation
rule might be
built is as follows. (Of course, the functions pairp
, lex2p
, and
ordinate
would have to be defined first.)
Example: (and (implies (pairp x) (e0-ordinalp (ordinate x))) (implies (and (pairp x) (pairp y) (lex2p x y)) (e0-ord-< (ordinate x) (ordinate y))))The above example establishes that
lex2p
is a well-founded
relation on pairp
s. We explain and give details below.
Exactly two general forms are recognized:
General Forms (AND (IMPLIES (mp x) (E0-ORDINALP (fn x))) ; Property 1 (IMPLIES (AND (mp x) ; Property 2 (mp y) (rel x y)) (E0-ORD-< (fn x) (fn y)))),or
(AND (E0-ORDINALP (fn x)) ; Property 1 (IMPLIES (rel x y) ; Property 2 (E0-ORD-< (fn x) (fn y))))where
mp
, fn
, and rel
are function symbols, x
and y
are distinct
variable symbols, and no other :well-founded-relation
theorem about
fn
has been proved. When the second general form is used, we act as
though the first form were used with mp
being the function that
ignores its argument and returns t
. The discussion below therefore
considers only the first general form.
Note: We are very rigid when checking that the submitted formula is
of one of these forms. For example, in the first form, we insist
that all the conjuncts appear in the order shown above. Thus,
interchanging the two properties in the top-level conjunct or
rearranging the hyptheses in the second conjunct both produce
unrecognized forms. The requirement that each fn
be proved
well-founded at most once ensures that for each well-founded
relation, fn
, there is a unique mp
that recognizes the domain on
which rel
is well-founded. We impose this requirement simply so
that rel
can be used as a short-hand when specifying the
well-founded relations to be used in definitions; otherwise the
specification would have to indicate which mp
was to be used.
Mp
is a predicate that recognizes the objects that are supposedly
ordered in a well-founded way by rel
. We call such an object an
``mp
-measure'' or simply a ``measure'' when mp
is understood.
Property 1 tells us that every measure can be mapped into an ACL2
ordinal. (See e0-ordinalp.) This mapping is performed by fn
.
Property 2 tells us that if the measure x
is smaller than the
measure y
according to rel
then the image of x
under fn
is a smaller
than that of y
, according to the well-founded relation e0-ord-<
.
(See e0-ord-<.) Thus, the general form of a
:well-founded-relation
formula establishes that there exists a
rel
-order preserving embedding (namely via fn
) of the mp
-measures
into the ordinals. We can thus conclude that rel
is well-founded on
mp
-measures.
Such well-founded relations are used in the admissibility test for recursive functions, in particular, to show that the recursion terminates. To illustrate how such information may be used, consider a generic function definition
(defun g (x) (if (test x) (g (step x)) (base x))).If
rel
has been shown to be well-founded on mp
-measures, then g
's
termination can be ensured by finding a measure, (m x)
, with the
property that m
produces a measure:
(mp (m x)), ; Defun-goal-1and that the argument to
g
gets smaller (when measured by m
and
compared by rel
) in the recursion,
(implies (test x) (rel (m (step x)) (m x))). ; Defun-goal-2If
rel
is selected as the :well-founded-relation
to be used in the
definition of g
, the definitional principal will generate and
attempt to prove defun-goal-1
and defun-goal-2
to justify g
. We
show later why these two goals are sufficient to establish the
termination of g
. Observe that neither the ordinals nor the
embedding, fn
, of the mp
-measures into the ordinals is involved in
the goals generated by the definitional principal.
Suppose now that a :well-founded-relation
theorem has been proved
for mp
and rel
. How can rel
be ``selected as the
:well-founded-relation
'' by defun
? There are two ways.
First, an xargs
keyword to the defun
event allows the
specification of a :well-founded-relation
. Thus, the definition
of g
above might be written
(defun g (x) (declare (xargs :well-founded-relation (mp . rel))) (if (test x) (g (step x)) (base x)))Alternatively,
rel
may be specified as the
:default-well-founded-relation
in acl2-defaults-table
by
executing the event
(set-default-well-founded-relation rel).When a
defun
event does not explicitly specify the relation in its
xargs
the default relation is used. When ACL2 is initialized, the
default relation is e0-ord-<
.
Finally, though it is probably obvious, we now show that
defun-goal-1
and defun-goal-2
are sufficient to ensure the
termination of g
provided property-1
and property-2
of mp
and rel
have been proved. To this end, assume we have proved defun-goal-1
and defun-goal-2
as well as property-1
and property-2
and we show
how to admit g
under the primitive ACL2 definitional principal
(i.e., using only the ordinals). In particular, consider the
definition event
(defun g (x) (declare (xargs :well-founded-relation e0-ord-< :measure (fn (m x)))) (if (test x) (g (step x)) (base x)))Proof that
g
is admissible: To admit the definition of g
above we
must prove
(e0-ordinalp (fn (m x))) ; *1and
(implies (test x) ; *2 (e0-ord-< (fn (m (step x))) (fn (m x)))).But *1 can be proved by instantiating
property-1
to get
(implies (mp (m x)) (e0-ordinalp (fn (m x)))),and then relieving the hypothesis with
defun-goal-1
, (mp (m x))
.
Similarly, *2 can be proved by instantiating property-2
to get
(implies (and (mp (m (step x))) (mp (m x)) (rel (m (step x)) (m x))) (e0-ord-< (fn (m (step x))) (fn (m x))))and relieving the first two hypotheses by appealing to two instances of
defun-goal-1
, thus obtaining
(implies (rel (m (step x)) (m x)) (e0-ord-< (fn (m (step x))) (fn (m x)))).By chaining this together with
defun-goal-2
,
(implies (test x) (rel (m (step x)) (m x)))we obtain *2. Q.E.D.