Access the |X86ISA|::|UMIP| field of a cr4bits bit structure.
Function:
(defun cr4bits->umip$inline (x) (declare (xargs :guard (cr4bits-p x))) (mbe :logic (let ((x (cr4bits-fix x))) (part-select x :low 11 :width 1)) :exec (the (unsigned-byte 1) (logand (the (unsigned-byte 1) 1) (the (unsigned-byte 11) (ash (the (unsigned-byte 22) x) -11))))))
Theorem:
(defthm bitp-of-cr4bits->umip (b* ((umip (cr4bits->umip$inline x))) (bitp umip)) :rule-classes :rewrite)
Theorem:
(defthm cr4bits->umip$inline-of-cr4bits-fix-x (equal (cr4bits->umip$inline (cr4bits-fix x)) (cr4bits->umip$inline x)))
Theorem:
(defthm cr4bits->umip$inline-cr4bits-equiv-congruence-on-x (implies (cr4bits-equiv x x-equiv) (equal (cr4bits->umip$inline x) (cr4bits->umip$inline x-equiv))) :rule-classes :congruence)
Theorem:
(defthm cr4bits->umip-of-cr4bits (equal (cr4bits->umip (cr4bits vme pvi tsd de pse pae mce pge pce osfxsr osxmmexcpt umip la57 vmxe smxe res1 fsgsbase pcide osxsave res2 smep smap)) (bfix umip)))
Theorem:
(defthm cr4bits->umip-of-write-with-mask (implies (and (fty::bitstruct-read-over-write-hyps x cr4bits-equiv-under-mask) (cr4bits-equiv-under-mask x y fty::mask) (equal (logand (lognot fty::mask) 2048) 0)) (equal (cr4bits->umip x) (cr4bits->umip y))))