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 :equivalence
rule might be built is
as follows. (We assume that r-equal
has been defined.)
Example: (and (booleanp (r-equal x y)) (r-equal x x) (implies (r-equal x y) (r-equal y x)) (implies (and (r-equal x y) (r-equal y z)) (r-equal x z))).Also see defequiv.
General Form: (and (booleanp (equiv x y)) (equiv x x) (implies (equiv x y) (equiv y x)) (implies (and (equiv x y) (equiv y z)) (equiv x z)))except that the order of the conjuncts and terms and the choice of variable symbols is unimportant. The effect of such a rule is to identify
equiv
as an equivalence relation. Note that only Boolean
2-place function symbols can be treated as equivalence relations.
See congruence and see refinement for closely related
concepts.The macro form (defequiv equiv)
is an abbreviation for a defthm
of
rule-class :equivalence
that establishes that equiv
is an
equivalence relation. It generates the formula shown above.
See defequiv.
When equiv
is marked as an equivalence relation, its reflexivity,
symmetry, and transitivity are built into the system in a deeper way
than via :
rewrite
rules. More importantly, after equiv
has been
shown to be an equivalence relation, lemmas about equiv
, e.g.,
(implies hyps (equiv lhs rhs)),when stored as
:
rewrite
rules, cause the system to rewrite certain
occurrences of (instances of) lhs
to (instances of) rhs
. Roughly
speaking, an occurrence of lhs
in the kth
argument of some
fn
-expression, (fn ... lhs' ...)
, can be rewritten to produce
(fn ... rhs' ...)
, provided the system ``knows'' that the value
of fn
is unaffected by equiv
-substitution in the kth
argument. Such knowledge is communicated to the system via
``congruence lemmas.''For example, suppose that r-equal
is known to be an equivalence
relation. The :
congruence
lemma
(implies (r-equal s1 s2) (equal (fn s1 n) (fn s2 n)))informs the rewriter that, while rewriting the first argument of
fn
-expressions, it is permitted to use r-equal
rewrite-rules.
See congruence for details about :
congruence
lemmas.
Interestingly, congruence lemmas are automatically created when an
equivalence relation is stored, saying that either of the
equivalence relation's arguments may be replaced by an equivalent
argument. That is, if the equivalence relation is fn
, we store
congruence rules that state the following fact:
(implies (and (fn x1 y1) (fn x2 y2)) (iff (fn x1 x2) (fn y1 y2)))Another aspect of equivalence relations is that of ``refinement.'' We say
equiv1
``refines'' equiv2
iff (equiv1 x y)
implies
(equiv2 x y)
. :
refinement
rules permit you to establish such
connections between your equivalence relations. The value of
refinements is that if the system is trying to rewrite something
while maintaining equiv2
it is permitted to use as a :
rewrite
rule any refinement of equiv2
. Thus, if equiv1
is a
refinement of equiv2
and there are equiv1
rewrite-rules
available, they can be brought to bear while maintaining equiv2
.
See refinement.The system initially has knowledge of two equivalence relations,
equality, denoted by the symbol equal
, and propositional
equivalence, denoted by iff
. Equal
is known to be a refinement of
all equivalence relations and to preserve equality across all
arguments of all functions.
Typically there are five steps involved in introducing and using a new equivalence relation, equiv.
(1) Define
equiv
,(2) prove the
:equivalence
lemma aboutequiv
,(3) prove the
:
congruence
lemmas that show whereequiv
can be used to maintain known relations,(4) prove the
:
refinement
lemmas that relateequiv
to known relations other than equal, and(5) develop the theory of conditional
:
rewrite
rules that drive equiv rewriting.
More will be written about this as we develop the techniques. For now, here is an example that shows how to make use of equivalence relations in rewriting.
Among the theorems proved below is
(defthm insert-sort-is-id (perm (insert-sort x) x))Here
perm
is defined as usual with delete
and is proved to be an
equivalence relation and to be a congruence relation for cons
and
member
.Then we prove the lemma
(defthm insert-is-cons (perm (insert a x) (cons a x)))which you must think of as you would
(insert a x) = (cons a x)
.Now prove (perm (insert-sort x) x)
. The base case is trivial. The
induction step is
(consp x) & (perm (insert-sort (cdr x)) (cdr x)) -> (perm (insert-sort x) x).Opening
insert-sort
makes the conclusion be
(perm (insert (car x) (insert-sort (cdr x))) x).Then apply the induction hypothesis (rewriting
(insert-sort (cdr x))
to (cdr x)
), to make the conclusion be
(perm (insert (car x) (cdr x)) x)Then apply
insert-is-cons
to get (perm (cons (car x) (cdr x)) x)
.
But we know that (cons (car x) (cdr x))
is x
, so we get (perm x x)
which is trivial, since perm
is an equivalence relation.Here are the events.
(encapsulate (((lt * *) => *)) (local (defun lt (x y) (declare (ignore x y)) nil)) (defthm lt-non-symmetric (implies (lt x y) (not (lt y x))))) (defun insert (x lst) (cond ((atom lst) (list x)) ((lt x (car lst)) (cons x lst)) (t (cons (car lst) (insert x (cdr lst)))))) (defun insert-sort (lst) (cond ((atom lst) nil) (t (insert (car lst) (insert-sort (cdr lst)))))) (defun del (x lst) (cond ((atom lst) nil) ((equal x (car lst)) (cdr lst)) (t (cons (car lst) (del x (cdr lst)))))) (defun mem (x lst) (cond ((atom lst) nil) ((equal x (car lst)) t) (t (mem x (cdr lst))))) (defun perm (lst1 lst2) (cond ((atom lst1) (atom lst2)) ((mem (car lst1) lst2) (perm (cdr lst1) (del (car lst1) lst2))) (t nil))) (defthm perm-reflexive (perm x x)) (defthm perm-cons (implies (mem a x) (equal (perm x (cons a y)) (perm (del a x) y))) :hints (("Goal" :induct (perm x y)))) (defthm perm-symmetric (implies (perm x y) (perm y x))) (defthm mem-del (implies (mem a (del b x)) (mem a x))) (defthm perm-mem (implies (and (perm x y) (mem a x)) (mem a y))) (defthm mem-del2 (implies (and (mem a x) (not (equal a b))) (mem a (del b x)))) (defthm comm-del (equal (del a (del b x)) (del b (del a x)))) (defthm perm-del (implies (perm x y) (perm (del a x) (del a y)))) (defthm perm-transitive (implies (and (perm x y) (perm y z)) (perm x z))) (defequiv perm) (in-theory (disable perm perm-reflexive perm-symmetric perm-transitive)) (defcong perm perm (cons x y) 2) (defcong perm iff (mem x y) 2) (defthm atom-perm (implies (not (consp x)) (perm x nil)) :rule-classes :forward-chaining :hints (("Goal" :in-theory (enable perm)))) (defthm insert-is-cons (perm (insert a x) (cons a x))) (defthm insert-sort-is-id (perm (insert-sort x) x)) (defun app (x y) (if (consp x) (cons (car x) (app (cdr x) y)) y)) (defun rev (x) (if (consp x) (app (rev (cdr x)) (list (car x))) nil)) (defcong perm perm (app x y) 2) (defthm app-cons (perm (app a (cons b c)) (cons b (app a c)))) (defthm app-commutes (perm (app a b) (app b a))) (defcong perm perm (app x y) 1 :hints (("Goal" :induct (app y x)))) (defthm rev-is-id (perm (rev x) x)) (defun == (x y) (if (consp x) (if (consp y) (and (equal (car x) (car y)) (== (cdr x) (cdr y))) nil) (not (consp y)))) (defthm ==-reflexive (== x x)) (defthm ==-symmetric (implies (== x y) (== y x))) (defequiv ==) (in-theory (disable ==-symmetric ==-reflexive)) (defcong == == (cons x y) 2) (defcong == iff (consp x) 1) (defcong == == (app x y) 2) (defcong == == (app x y) 1) (defthm rev-rev (== (rev (rev x)) x))