Recognizer for svar-size-alist.
(svar-size-alist-p x) → *
Function:
(defun svar-size-alist-p (x) (declare (xargs :guard t)) (let ((__function__ 'svar-size-alist-p)) (declare (ignorable __function__)) (if (atom x) t (and (consp (car x)) (svar-p (caar x)) (natp (cdar x)) (svar-size-alist-p (cdr x))))))
Theorem:
(defthm svar-size-alist-p-of-revappend (equal (svar-size-alist-p (revappend x y)) (and (svar-size-alist-p (list-fix x)) (svar-size-alist-p y))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-remove (implies (svar-size-alist-p x) (svar-size-alist-p (remove acl2::a x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-last (implies (svar-size-alist-p (double-rewrite x)) (svar-size-alist-p (last x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-nthcdr (implies (svar-size-alist-p (double-rewrite x)) (svar-size-alist-p (nthcdr acl2::n x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-butlast (implies (svar-size-alist-p (double-rewrite x)) (svar-size-alist-p (butlast x acl2::n))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-update-nth (implies (svar-size-alist-p (double-rewrite x)) (iff (svar-size-alist-p (update-nth acl2::n y x)) (and (and (consp y) (svar-p (car y)) (natp (cdr y))) (or (<= (nfix acl2::n) (len x)) (and (consp nil) (svar-p (car nil)) (natp (cdr nil))))))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-repeat (iff (svar-size-alist-p (repeat acl2::n x)) (or (and (consp x) (svar-p (car x)) (natp (cdr x))) (zp acl2::n))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-take (implies (svar-size-alist-p (double-rewrite x)) (iff (svar-size-alist-p (take acl2::n x)) (or (and (consp nil) (svar-p (car nil)) (natp (cdr nil))) (<= (nfix acl2::n) (len x))))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-union-equal (equal (svar-size-alist-p (union-equal x y)) (and (svar-size-alist-p (list-fix x)) (svar-size-alist-p (double-rewrite y)))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-intersection-equal-2 (implies (svar-size-alist-p (double-rewrite y)) (svar-size-alist-p (intersection-equal x y))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-intersection-equal-1 (implies (svar-size-alist-p (double-rewrite x)) (svar-size-alist-p (intersection-equal x y))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-set-difference-equal (implies (svar-size-alist-p x) (svar-size-alist-p (set-difference-equal x y))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-set-equiv-congruence (implies (set-equiv x y) (equal (svar-size-alist-p x) (svar-size-alist-p y))) :rule-classes :congruence)
Theorem:
(defthm svar-size-alist-p-when-subsetp-equal (and (implies (and (subsetp-equal x y) (svar-size-alist-p y)) (svar-size-alist-p x)) (implies (and (svar-size-alist-p y) (subsetp-equal x y)) (svar-size-alist-p x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-rcons (iff (svar-size-alist-p (acl2::rcons acl2::a x)) (and (and (consp acl2::a) (svar-p (car acl2::a)) (natp (cdr acl2::a))) (svar-size-alist-p (list-fix x)))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-rev (equal (svar-size-alist-p (rev x)) (svar-size-alist-p (list-fix x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-duplicated-members (implies (svar-size-alist-p x) (svar-size-alist-p (duplicated-members x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-difference (implies (svar-size-alist-p x) (svar-size-alist-p (difference x y))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-intersect-2 (implies (svar-size-alist-p y) (svar-size-alist-p (intersect x y))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-intersect-1 (implies (svar-size-alist-p x) (svar-size-alist-p (intersect x y))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-union (iff (svar-size-alist-p (union x y)) (and (svar-size-alist-p (sfix x)) (svar-size-alist-p (sfix y)))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-mergesort (iff (svar-size-alist-p (mergesort x)) (svar-size-alist-p (list-fix x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-delete (implies (svar-size-alist-p x) (svar-size-alist-p (delete acl2::k x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-insert (iff (svar-size-alist-p (insert acl2::a x)) (and (svar-size-alist-p (sfix x)) (and (consp acl2::a) (svar-p (car acl2::a)) (natp (cdr acl2::a))))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-sfix (iff (svar-size-alist-p (sfix x)) (or (svar-size-alist-p x) (not (setp x)))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-list-fix (equal (svar-size-alist-p (list-fix x)) (svar-size-alist-p x)) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-append (equal (svar-size-alist-p (append acl2::a acl2::b)) (and (svar-size-alist-p acl2::a) (svar-size-alist-p acl2::b))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-when-not-consp (implies (not (consp x)) (svar-size-alist-p x)) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-cdr-when-svar-size-alist-p (implies (svar-size-alist-p (double-rewrite x)) (svar-size-alist-p (cdr x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-cons (equal (svar-size-alist-p (cons acl2::a x)) (and (and (consp acl2::a) (svar-p (car acl2::a)) (natp (cdr acl2::a))) (svar-size-alist-p x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-make-fal (implies (and (svar-size-alist-p x) (svar-size-alist-p y)) (svar-size-alist-p (make-fal x y))) :rule-classes ((:rewrite)))
Theorem:
(defthm natp-of-cdr-when-member-equal-of-svar-size-alist-p (and (implies (and (svar-size-alist-p x) (member-equal acl2::a x)) (natp (cdr acl2::a))) (implies (and (member-equal acl2::a x) (svar-size-alist-p x)) (natp (cdr acl2::a)))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-p-of-car-when-member-equal-of-svar-size-alist-p (and (implies (and (svar-size-alist-p x) (member-equal acl2::a x)) (svar-p (car acl2::a))) (implies (and (member-equal acl2::a x) (svar-size-alist-p x)) (svar-p (car acl2::a)))) :rule-classes ((:rewrite)))
Theorem:
(defthm consp-when-member-equal-of-svar-size-alist-p (implies (and (svar-size-alist-p x) (member-equal acl2::a x)) (consp acl2::a)) :rule-classes ((:rewrite :backchain-limit-lst (0 0)) (:rewrite :backchain-limit-lst (0 0) :corollary (implies (if (member-equal acl2::a x) (svar-size-alist-p x) 'nil) (consp acl2::a)))))
Theorem:
(defthm svar-size-alist-p-of-fast-alist-clean (implies (svar-size-alist-p x) (svar-size-alist-p (fast-alist-clean x))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-hons-shrink-alist (implies (and (svar-size-alist-p x) (svar-size-alist-p y)) (svar-size-alist-p (hons-shrink-alist x y))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-size-alist-p-of-hons-acons (equal (svar-size-alist-p (hons-acons acl2::a acl2::n x)) (and (svar-p acl2::a) (natp acl2::n) (svar-size-alist-p x))) :rule-classes ((:rewrite)))
Theorem:
(defthm natp-of-cdr-of-hons-assoc-equal-when-svar-size-alist-p (implies (svar-size-alist-p x) (iff (natp (cdr (hons-assoc-equal acl2::k x))) (or (hons-assoc-equal acl2::k x) (natp nil)))) :rule-classes ((:rewrite)))
Theorem:
(defthm natp-of-cdar-when-svar-size-alist-p (implies (svar-size-alist-p x) (iff (natp (cdar x)) (or (consp x) (natp nil)))) :rule-classes ((:rewrite)))
Theorem:
(defthm svar-p-of-caar-when-svar-size-alist-p (implies (svar-size-alist-p x) (iff (svar-p (caar x)) (or (consp x) (svar-p nil)))) :rule-classes ((:rewrite)))