## ELIM

make a destructor elimination rule
Major Section:  RULE-CLASSES

See rule-classes for a general discussion of rule classes and how they are used to build rules from formulas. Here we describe the class of :elim rules, which is fundamentally quite different from the more common class of :rewrite rules. Briefly put, a :rewrite rule replaces instances of its left-hand side with corresponding instances of its right-hand side. But an :elim rule, on the other hand, has the effect of generalizing so-called ``destructor'' function applications to variables. In essence, applicability of a :rewrite rule is based on matching its left-hand side, while applicability of an :elim rule is based on the presence of at least one destructor term.

For example, a conjecture about (car x) and (cdr x) can be replaced by a conjecture about new variables x1 and x2, as shown in the following example. (Run the command :mini-proveall and search for CAR-CDR-ELIM to see the full proof containing this excerpt.)

Subgoal *1/1'
(IMPLIES (AND (CONSP X)
(TRUE-LISTP (REV (CDR X))))
(TRUE-LISTP (APP (REV (CDR X)) (LIST (CAR X))))).

The destructor terms (CAR X) and (CDR X) can be eliminated by using CAR-CDR-ELIM to replace X by (CONS X1 X2), (CAR X) by X1 and (CDR X) by X2. This produces the following goal.

Subgoal *1/1'' (IMPLIES (AND (CONSP (CONS X1 X2)) (TRUE-LISTP (REV X2))) (TRUE-LISTP (APP (REV X2) (LIST X1)))).

This simplifies, using primitive type reasoning, to

Subgoal *1/1''' (IMPLIES (TRUE-LISTP (REV X2)) (TRUE-LISTP (APP (REV X2) (LIST X1)))).

The resulting conjecture is often simpler and hence more amenable to proof.

The application of an :elim rule thus replaces a variable by a term that contains applications of so-called ``destructor'' functions to that variable. The example above is typical: the variable x is replaced by the term (cons (car x) (cdr x)), which applies a so-called ``constructor'' function, cons, to applications (car x) and (cdr x) of destructor functions car and cdr to that same variable, x. But that is only part of the story. ACL2 then generalizes the destructor applications (car x) and (cdr x) to new variables x1 and x2, respectively, and ultimately the result is a simpler conjecture.

More generally, the application of an :elim rule replaces a variable by a term containing applications of destructors; there need not be a clear-cut notion of ``constructor.'' But the situation described above is typical, and we will focus on it, giving full details when we introduce the ``General Form'' below.

The example above employs the following built-in :elim rule named car-cdr-elim.

Example:
(implies (consp x)                      when (car v) or (cdr v) appears
(equal (cons (car x) (cdr x))  in a conjecture, and v is a
x))                     variable, consider replacing v by
(cons a b), for two new variables
a and b.

Notice that the situation is complicated a bit by the fact that this replacement is only valid if the variable being replaced a cons structure. Thus, when ACL2 applies car-cdr-elim to replace a variable v, it will split into two cases: one case in which (consp v) is true, in which v is replaced by (cons (car v) (cdr v)) and then (car v) and (cdr v) are generalized to new variables; and one case in which (consp v) is false. In practice, (consp v) is often provable, perhaps even literally present as a hypotheses; then of course there is no need to introduce the second case. That is why there is no such second case in the example above.

You might find :elim rules to be useful whenever you have in mind a data type that can be built up from its fields with a ``constructor'' function and whose fields can be accessed by corresponding ``destructor'' functions. So for example, if you have a ``house'' data structure that represents a house in terms of its address, price, and color, you might have a rule like the following.

Example:
(implies (house-p x)
(price x)
(color x))
x))
The application of such a rule is entirely analogous to the application of the rule car-cdr-elim discussed above. We discuss such rules and their application more carefully below.

General Form: (implies hyp (equiv lhs x))

where equiv is a known equivalence relation (see defequiv); x is a variable symbol; and lhs contains one or more terms (called ``destructor terms'') of the form (fn v1 ... vn), where fn is a function symbol and the vi are distinct variable symbols, v1, ..., vn include all the variable symbols in the formula, no fn occurs in lhs in more than one destructor term, and all occurrences of x in lhs are inside destructor terms.

To use an :elim rule, the theorem prover waits until a conjecture has been maximally simplified. It then searches for an instance of some destructor term (fn v1 ... vn) in the conjecture, where the instance for x is some variable symbol, vi, and every occurrence of vi outside the destructor terms is in an equiv-hittable position. If such an instance is found, then the theorem prover instantiates the :elim formula as indicated by the destructor term matched; splits the conjecture into two goals, according to whether the instantiated hypothesis, hyp, holds; and in the case that it does hold, generalizes all the instantiated destructor terms in the conjecture to new variables and then replaces vi in the conjecture by the generalized instantiated lhs. An occurrence of vi is ``equiv-hittable'' if sufficient congruence rules (see defcong) have been proved to establish that the propositional value of the clause is not altered by replacing that occurrence of vi by some equiv-equivalent term.

If an :elim rule is not applied when you think it should have been, and the rule uses an equivalence relation, equiv, other than equal, it is most likely that there is an occurrence of the variable that is not equiv-hittable. Easy occurrences to overlook are those in the governing hypotheses. If you see an unjustified occurrence of the variable, you must prove the appropriate congruence rule to allow the :elim to fire.

Further examples of how ACL2 :elim rules are used may be found in the corresponding discussion of ``Elimation of Destructors'' for Nqthm, in Section 10.4 of A Computational Logic Handbook.