Get the scope field from a vl-elabinstruction-push-anon.
(vl-elabinstruction-push-anon->scope x) → scope
This is an ordinary field accessor created by defprod.
Function:
(defun vl-elabinstruction-push-anon->scope$inline (x) (declare (xargs :guard (vl-elabinstruction-p x))) (declare (xargs :guard (equal (vl-elabinstruction-kind x) :push-anon))) (let ((__function__ 'vl-elabinstruction-push-anon->scope)) (declare (ignorable __function__)) (mbe :logic (b* ((x (and (equal (vl-elabinstruction-kind x) :push-anon) x))) (vl-elabscope-fix (std::da-nth 0 (cdr x)))) :exec (std::da-nth 0 (cdr x)))))
Theorem:
(defthm vl-elabscope-p-of-vl-elabinstruction-push-anon->scope (b* ((scope (vl-elabinstruction-push-anon->scope$inline x))) (vl-elabscope-p scope)) :rule-classes :rewrite)
Theorem:
(defthm vl-elabinstruction-push-anon->scope$inline-of-vl-elabinstruction-fix-x (equal (vl-elabinstruction-push-anon->scope$inline (vl-elabinstruction-fix x)) (vl-elabinstruction-push-anon->scope$inline x)))
Theorem:
(defthm vl-elabinstruction-push-anon->scope$inline-vl-elabinstruction-equiv-congruence-on-x (implies (vl-elabinstruction-equiv x x-equiv) (equal (vl-elabinstruction-push-anon->scope$inline x) (vl-elabinstruction-push-anon->scope$inline x-equiv))) :rule-classes :congruence)
Theorem:
(defthm vl-elabinstruction-push-anon->scope-when-wrong-kind (implies (not (equal (vl-elabinstruction-kind x) :push-anon)) (equal (vl-elabinstruction-push-anon->scope x) (vl-elabscope-fix nil))))