1 ;;;; the VM definition of arithmetic VOPs for the x86
3 ;;;; This software is part of the SBCL system. See the README file for
6 ;;;; This software is derived from the CMU CL system, which was
7 ;;;; written at Carnegie Mellon University and released into the
8 ;;;; public domain. The software is in the public domain and is
9 ;;;; provided with absolutely no warranty. See the COPYING and CREDITS
10 ;;;; files for more information.
16 (define-vop (fast-safe-arith-op)
21 (define-vop (fixnum-unop fast-safe-arith-op)
22 (:args (x :scs (any-reg) :target res))
23 (:results (res :scs (any-reg)))
24 (:note "inline fixnum arithmetic")
25 (:arg-types tagged-num)
26 (:result-types tagged-num))
28 (define-vop (signed-unop fast-safe-arith-op)
29 (:args (x :scs (signed-reg) :target res))
30 (:results (res :scs (signed-reg)))
31 (:note "inline (signed-byte 32) arithmetic")
32 (:arg-types signed-num)
33 (:result-types signed-num))
35 (define-vop (fast-negate/fixnum fixnum-unop)
41 (define-vop (fast-negate/signed signed-unop)
47 (define-vop (fast-lognot/fixnum fixnum-unop)
51 (inst xor res (fixnumize -1))))
53 (define-vop (fast-lognot/signed signed-unop)
59 ;;;; binary fixnum operations
61 ;;; Assume that any constant operand is the second arg...
63 (define-vop (fast-fixnum-binop fast-safe-arith-op)
64 (:args (x :target r :scs (any-reg)
65 :load-if (not (and (sc-is x control-stack)
67 (sc-is r control-stack)
69 (y :scs (any-reg control-stack)))
70 (:arg-types tagged-num tagged-num)
71 (:results (r :scs (any-reg) :from (:argument 0)
72 :load-if (not (and (sc-is x control-stack)
74 (sc-is r control-stack)
76 (:result-types tagged-num)
77 (:note "inline fixnum arithmetic"))
79 (define-vop (fast-unsigned-binop fast-safe-arith-op)
80 (:args (x :target r :scs (unsigned-reg)
81 :load-if (not (and (sc-is x unsigned-stack)
82 (sc-is y unsigned-reg)
83 (sc-is r unsigned-stack)
85 (y :scs (unsigned-reg unsigned-stack)))
86 (:arg-types unsigned-num unsigned-num)
87 (:results (r :scs (unsigned-reg) :from (:argument 0)
88 :load-if (not (and (sc-is x unsigned-stack)
89 (sc-is y unsigned-reg)
90 (sc-is r unsigned-stack)
92 (:result-types unsigned-num)
93 (:note "inline (unsigned-byte 32) arithmetic"))
95 (define-vop (fast-signed-binop fast-safe-arith-op)
96 (:args (x :target r :scs (signed-reg)
97 :load-if (not (and (sc-is x signed-stack)
99 (sc-is r signed-stack)
101 (y :scs (signed-reg signed-stack)))
102 (:arg-types signed-num signed-num)
103 (:results (r :scs (signed-reg) :from (:argument 0)
104 :load-if (not (and (sc-is x signed-stack)
106 (sc-is r signed-stack)
108 (:result-types signed-num)
109 (:note "inline (signed-byte 32) arithmetic"))
111 (define-vop (fast-fixnum-binop-c fast-safe-arith-op)
112 (:args (x :target r :scs (any-reg control-stack)))
114 (:arg-types tagged-num (:constant (signed-byte 30)))
115 (:results (r :scs (any-reg)
116 :load-if (not (location= x r))))
117 (:result-types tagged-num)
118 (:note "inline fixnum arithmetic"))
120 (define-vop (fast-unsigned-binop-c fast-safe-arith-op)
121 (:args (x :target r :scs (unsigned-reg unsigned-stack)))
123 (:arg-types unsigned-num (:constant (unsigned-byte 32)))
124 (:results (r :scs (unsigned-reg)
125 :load-if (not (location= x r))))
126 (:result-types unsigned-num)
127 (:note "inline (unsigned-byte 32) arithmetic"))
129 (define-vop (fast-signed-binop-c fast-safe-arith-op)
130 (:args (x :target r :scs (signed-reg signed-stack)))
132 (:arg-types signed-num (:constant (signed-byte 32)))
133 (:results (r :scs (signed-reg)
134 :load-if (not (location= x r))))
135 (:result-types signed-num)
136 (:note "inline (signed-byte 32) arithmetic"))
138 (macrolet ((define-binop (translate untagged-penalty op)
140 (define-vop (,(symbolicate "FAST-" translate "/FIXNUM=>FIXNUM")
142 (:translate ,translate)
146 (define-vop (,(symbolicate 'fast- translate '-c/fixnum=>fixnum)
148 (:translate ,translate)
151 (inst ,op r (fixnumize y))))
152 (define-vop (,(symbolicate "FAST-" translate "/SIGNED=>SIGNED")
154 (:translate ,translate)
155 (:generator ,(1+ untagged-penalty)
158 (define-vop (,(symbolicate 'fast- translate '-c/signed=>signed)
160 (:translate ,translate)
161 (:generator ,untagged-penalty
164 (define-vop (,(symbolicate "FAST-"
166 "/UNSIGNED=>UNSIGNED")
168 (:translate ,translate)
169 (:generator ,(1+ untagged-penalty)
172 (define-vop (,(symbolicate 'fast-
174 '-c/unsigned=>unsigned)
175 fast-unsigned-binop-c)
176 (:translate ,translate)
177 (:generator ,untagged-penalty
181 ;;(define-binop + 4 add)
182 (define-binop - 4 sub)
183 (define-binop logand 2 and)
184 (define-binop logior 2 or)
185 (define-binop logxor 2 xor))
187 ;;; Special handling of add on the x86; can use lea to avoid a
188 ;;; register load, otherwise it uses add.
189 (define-vop (fast-+/fixnum=>fixnum fast-safe-arith-op)
191 (:args (x :scs (any-reg) :target r
192 :load-if (not (and (sc-is x control-stack)
194 (sc-is r control-stack)
196 (y :scs (any-reg control-stack)))
197 (:arg-types tagged-num tagged-num)
198 (:results (r :scs (any-reg) :from (:argument 0)
199 :load-if (not (and (sc-is x control-stack)
201 (sc-is r control-stack)
203 (:result-types tagged-num)
204 (:note "inline fixnum arithmetic")
206 (cond ((and (sc-is x any-reg) (sc-is y any-reg) (sc-is r any-reg)
207 (not (location= x r)))
208 (inst lea r (make-ea :dword :base x :index y :scale 1)))
213 (define-vop (fast-+-c/fixnum=>fixnum fast-safe-arith-op)
215 (:args (x :target r :scs (any-reg control-stack)))
217 (:arg-types tagged-num (:constant (signed-byte 30)))
218 (:results (r :scs (any-reg)
219 :load-if (not (location= x r))))
220 (:result-types tagged-num)
221 (:note "inline fixnum arithmetic")
223 (cond ((and (sc-is x any-reg) (sc-is r any-reg) (not (location= x r)))
224 (inst lea r (make-ea :dword :base x :disp (fixnumize y))))
227 (inst add r (fixnumize y))))))
229 (define-vop (fast-+/signed=>signed fast-safe-arith-op)
231 (:args (x :scs (signed-reg) :target r
232 :load-if (not (and (sc-is x signed-stack)
234 (sc-is r signed-stack)
236 (y :scs (signed-reg signed-stack)))
237 (:arg-types signed-num signed-num)
238 (:results (r :scs (signed-reg) :from (:argument 0)
239 :load-if (not (and (sc-is x signed-stack)
242 (:result-types signed-num)
243 (:note "inline (signed-byte 32) arithmetic")
245 (cond ((and (sc-is x signed-reg) (sc-is y signed-reg) (sc-is r signed-reg)
246 (not (location= x r)))
247 (inst lea r (make-ea :dword :base x :index y :scale 1)))
253 ;;;; Special logand cases: (logand signed unsigned) => unsigned
255 (define-vop (fast-logand/signed-unsigned=>unsigned
256 fast-logand/unsigned=>unsigned)
257 (:args (x :target r :scs (signed-reg)
258 :load-if (not (and (sc-is x signed-stack)
259 (sc-is y unsigned-reg)
260 (sc-is r unsigned-stack)
262 (y :scs (unsigned-reg unsigned-stack)))
263 (:arg-types signed-num unsigned-num))
265 (define-vop (fast-logand-c/signed-unsigned=>unsigned
266 fast-logand-c/unsigned=>unsigned)
267 (:args (x :target r :scs (signed-reg signed-stack)))
268 (:arg-types signed-num (:constant (unsigned-byte 32))))
270 (define-vop (fast-logand/unsigned-signed=>unsigned
271 fast-logand/unsigned=>unsigned)
272 (:args (x :target r :scs (unsigned-reg)
273 :load-if (not (and (sc-is x unsigned-stack)
275 (sc-is r unsigned-stack)
277 (y :scs (signed-reg signed-stack)))
278 (:arg-types unsigned-num signed-num))
281 (define-vop (fast-+-c/signed=>signed fast-safe-arith-op)
283 (:args (x :target r :scs (signed-reg signed-stack)))
285 (:arg-types signed-num (:constant (signed-byte 32)))
286 (:results (r :scs (signed-reg)
287 :load-if (not (location= x r))))
288 (:result-types signed-num)
289 (:note "inline (signed-byte 32) arithmetic")
291 (cond ((and (sc-is x signed-reg) (sc-is r signed-reg)
292 (not (location= x r)))
293 (inst lea r (make-ea :dword :base x :disp y)))
300 (define-vop (fast-+/unsigned=>unsigned fast-safe-arith-op)
302 (:args (x :scs (unsigned-reg) :target r
303 :load-if (not (and (sc-is x unsigned-stack)
304 (sc-is y unsigned-reg)
305 (sc-is r unsigned-stack)
307 (y :scs (unsigned-reg unsigned-stack)))
308 (:arg-types unsigned-num unsigned-num)
309 (:results (r :scs (unsigned-reg) :from (:argument 0)
310 :load-if (not (and (sc-is x unsigned-stack)
311 (sc-is y unsigned-reg)
312 (sc-is r unsigned-stack)
314 (:result-types unsigned-num)
315 (:note "inline (unsigned-byte 32) arithmetic")
317 (cond ((and (sc-is x unsigned-reg) (sc-is y unsigned-reg)
318 (sc-is r unsigned-reg) (not (location= x r)))
319 (inst lea r (make-ea :dword :base x :index y :scale 1)))
324 (define-vop (fast-+-c/unsigned=>unsigned fast-safe-arith-op)
326 (:args (x :target r :scs (unsigned-reg unsigned-stack)))
328 (:arg-types unsigned-num (:constant (unsigned-byte 32)))
329 (:results (r :scs (unsigned-reg)
330 :load-if (not (location= x r))))
331 (:result-types unsigned-num)
332 (:note "inline (unsigned-byte 32) arithmetic")
334 (cond ((and (sc-is x unsigned-reg) (sc-is r unsigned-reg)
335 (not (location= x r)))
336 (inst lea r (make-ea :dword :base x :disp y)))
343 ;;;; multiplication and division
345 (define-vop (fast-*/fixnum=>fixnum fast-safe-arith-op)
347 ;; We need different loading characteristics.
348 (:args (x :scs (any-reg) :target r)
349 (y :scs (any-reg control-stack)))
350 (:arg-types tagged-num tagged-num)
351 (:results (r :scs (any-reg) :from (:argument 0)))
352 (:result-types tagged-num)
353 (:note "inline fixnum arithmetic")
359 (define-vop (fast-*-c/fixnum=>fixnum fast-safe-arith-op)
361 ;; We need different loading characteristics.
362 (:args (x :scs (any-reg control-stack)))
364 (:arg-types tagged-num (:constant (signed-byte 30)))
365 (:results (r :scs (any-reg)))
366 (:result-types tagged-num)
367 (:note "inline fixnum arithmetic")
371 (define-vop (fast-*/signed=>signed fast-safe-arith-op)
373 ;; We need different loading characteristics.
374 (:args (x :scs (signed-reg) :target r)
375 (y :scs (signed-reg signed-stack)))
376 (:arg-types signed-num signed-num)
377 (:results (r :scs (signed-reg) :from (:argument 0)))
378 (:result-types signed-num)
379 (:note "inline (signed-byte 32) arithmetic")
384 (define-vop (fast-*-c/signed=>signed fast-safe-arith-op)
386 ;; We need different loading characteristics.
387 (:args (x :scs (signed-reg signed-stack)))
389 (:arg-types signed-num (:constant (signed-byte 32)))
390 (:results (r :scs (signed-reg)))
391 (:result-types signed-num)
392 (:note "inline (signed-byte 32) arithmetic")
396 (define-vop (fast-*/unsigned=>unsigned fast-safe-arith-op)
398 (:args (x :scs (unsigned-reg) :target eax)
399 (y :scs (unsigned-reg unsigned-stack)))
400 (:arg-types unsigned-num unsigned-num)
401 (:temporary (:sc unsigned-reg :offset eax-offset :target result
402 :from (:argument 0) :to :result) eax)
403 (:temporary (:sc unsigned-reg :offset edx-offset
404 :from :eval :to :result) edx)
406 (:results (result :scs (unsigned-reg)))
407 (:result-types unsigned-num)
408 (:note "inline (unsigned-byte 32) arithmetic")
410 (:save-p :compute-only)
417 (define-vop (fast-truncate/fixnum=>fixnum fast-safe-arith-op)
418 (:translate truncate)
419 (:args (x :scs (any-reg) :target eax)
420 (y :scs (any-reg control-stack)))
421 (:arg-types tagged-num tagged-num)
422 (:temporary (:sc signed-reg :offset eax-offset :target quo
423 :from (:argument 0) :to (:result 0)) eax)
424 (:temporary (:sc unsigned-reg :offset edx-offset :target rem
425 :from (:argument 0) :to (:result 1)) edx)
426 (:results (quo :scs (any-reg))
427 (rem :scs (any-reg)))
428 (:result-types tagged-num tagged-num)
429 (:note "inline fixnum arithmetic")
431 (:save-p :compute-only)
433 (let ((zero (generate-error-code vop division-by-zero-error x y)))
434 (if (sc-is y any-reg)
435 (inst test y y) ; smaller instruction
441 (if (location= quo eax)
443 (inst lea quo (make-ea :dword :index eax :scale 4)))
446 (define-vop (fast-truncate-c/fixnum=>fixnum fast-safe-arith-op)
447 (:translate truncate)
448 (:args (x :scs (any-reg) :target eax))
450 (:arg-types tagged-num (:constant (signed-byte 30)))
451 (:temporary (:sc signed-reg :offset eax-offset :target quo
452 :from :argument :to (:result 0)) eax)
453 (:temporary (:sc any-reg :offset edx-offset :target rem
454 :from :eval :to (:result 1)) edx)
455 (:temporary (:sc any-reg :from :eval :to :result) y-arg)
456 (:results (quo :scs (any-reg))
457 (rem :scs (any-reg)))
458 (:result-types tagged-num tagged-num)
459 (:note "inline fixnum arithmetic")
461 (:save-p :compute-only)
465 (inst mov y-arg (fixnumize y))
466 (inst idiv eax y-arg)
467 (if (location= quo eax)
469 (inst lea quo (make-ea :dword :index eax :scale 4)))
472 (define-vop (fast-truncate/unsigned=>unsigned fast-safe-arith-op)
473 (:translate truncate)
474 (:args (x :scs (unsigned-reg) :target eax)
475 (y :scs (unsigned-reg signed-stack)))
476 (:arg-types unsigned-num unsigned-num)
477 (:temporary (:sc unsigned-reg :offset eax-offset :target quo
478 :from (:argument 0) :to (:result 0)) eax)
479 (:temporary (:sc unsigned-reg :offset edx-offset :target rem
480 :from (:argument 0) :to (:result 1)) edx)
481 (:results (quo :scs (unsigned-reg))
482 (rem :scs (unsigned-reg)))
483 (:result-types unsigned-num unsigned-num)
484 (:note "inline (unsigned-byte 32) arithmetic")
486 (:save-p :compute-only)
488 (let ((zero (generate-error-code vop division-by-zero-error x y)))
489 (if (sc-is y unsigned-reg)
490 (inst test y y) ; smaller instruction
499 (define-vop (fast-truncate-c/unsigned=>unsigned fast-safe-arith-op)
500 (:translate truncate)
501 (:args (x :scs (unsigned-reg) :target eax))
503 (:arg-types unsigned-num (:constant (unsigned-byte 32)))
504 (:temporary (:sc unsigned-reg :offset eax-offset :target quo
505 :from :argument :to (:result 0)) eax)
506 (:temporary (:sc unsigned-reg :offset edx-offset :target rem
507 :from :eval :to (:result 1)) edx)
508 (:temporary (:sc unsigned-reg :from :eval :to :result) y-arg)
509 (:results (quo :scs (unsigned-reg))
510 (rem :scs (unsigned-reg)))
511 (:result-types unsigned-num unsigned-num)
512 (:note "inline (unsigned-byte 32) arithmetic")
514 (:save-p :compute-only)
523 (define-vop (fast-truncate/signed=>signed fast-safe-arith-op)
524 (:translate truncate)
525 (:args (x :scs (signed-reg) :target eax)
526 (y :scs (signed-reg signed-stack)))
527 (:arg-types signed-num signed-num)
528 (:temporary (:sc signed-reg :offset eax-offset :target quo
529 :from (:argument 0) :to (:result 0)) eax)
530 (:temporary (:sc signed-reg :offset edx-offset :target rem
531 :from (:argument 0) :to (:result 1)) edx)
532 (:results (quo :scs (signed-reg))
533 (rem :scs (signed-reg)))
534 (:result-types signed-num signed-num)
535 (:note "inline (signed-byte 32) arithmetic")
537 (:save-p :compute-only)
539 (let ((zero (generate-error-code vop division-by-zero-error x y)))
540 (if (sc-is y signed-reg)
541 (inst test y y) ; smaller instruction
550 (define-vop (fast-truncate-c/signed=>signed fast-safe-arith-op)
551 (:translate truncate)
552 (:args (x :scs (signed-reg) :target eax))
554 (:arg-types signed-num (:constant (signed-byte 32)))
555 (:temporary (:sc signed-reg :offset eax-offset :target quo
556 :from :argument :to (:result 0)) eax)
557 (:temporary (:sc signed-reg :offset edx-offset :target rem
558 :from :eval :to (:result 1)) edx)
559 (:temporary (:sc signed-reg :from :eval :to :result) y-arg)
560 (:results (quo :scs (signed-reg))
561 (rem :scs (signed-reg)))
562 (:result-types signed-num signed-num)
563 (:note "inline (signed-byte 32) arithmetic")
565 (:save-p :compute-only)
570 (inst idiv eax y-arg)
577 (define-vop (fast-ash-c/fixnum=>fixnum)
580 (:args (number :scs (any-reg) :target result
581 :load-if (not (and (sc-is number any-reg control-stack)
582 (sc-is result any-reg control-stack)
583 (location= number result)))))
585 (:arg-types tagged-num (:constant integer))
586 (:results (result :scs (any-reg)
587 :load-if (not (and (sc-is number control-stack)
588 (sc-is result control-stack)
589 (location= number result)))))
590 (:result-types tagged-num)
593 (cond ((and (= amount 1) (not (location= number result)))
594 (inst lea result (make-ea :dword :index number :scale 2)))
595 ((and (= amount 2) (not (location= number result)))
596 (inst lea result (make-ea :dword :index number :scale 4)))
597 ((and (= amount 3) (not (location= number result)))
598 (inst lea result (make-ea :dword :index number :scale 8)))
601 (cond ((plusp amount)
602 ;; We don't have to worry about overflow because of the
603 ;; result type restriction.
604 (inst shl result amount))
606 ;; If the amount is greater than 31, only shift by 31. We
607 ;; have to do this because the shift instructions only look
608 ;; at the low five bits of the result.
609 (inst sar result (min 31 (- amount)))
610 ;; Fixnum correction.
611 (inst and result #xfffffffc)))))))
613 (define-vop (fast-ash-left/fixnum=>fixnum)
615 (:args (number :scs (any-reg) :target result
616 :load-if (not (and (sc-is number control-stack)
617 (sc-is result control-stack)
618 (location= number result))))
619 (amount :scs (unsigned-reg) :target ecx))
620 (:arg-types tagged-num positive-fixnum)
621 (:temporary (:sc unsigned-reg :offset ecx-offset :from (:argument 1)) ecx)
622 (:results (result :scs (any-reg) :from (:argument 0)
623 :load-if (not (and (sc-is number control-stack)
624 (sc-is result control-stack)
625 (location= number result)))))
626 (:result-types tagged-num)
632 ;; The result-type ensures us that this shift will not overflow.
633 (inst shl result :cl)))
635 (define-vop (fast-ash-c/signed=>signed)
638 (:args (number :scs (signed-reg) :target result
639 :load-if (not (and (sc-is number signed-stack)
640 (sc-is result signed-stack)
641 (location= number result)))))
643 (:arg-types signed-num (:constant integer))
644 (:results (result :scs (signed-reg)
645 :load-if (not (and (sc-is number signed-stack)
646 (sc-is result signed-stack)
647 (location= number result)))))
648 (:result-types signed-num)
651 (cond ((and (= amount 1) (not (location= number result)))
652 (inst lea result (make-ea :dword :index number :scale 2)))
653 ((and (= amount 2) (not (location= number result)))
654 (inst lea result (make-ea :dword :index number :scale 4)))
655 ((and (= amount 3) (not (location= number result)))
656 (inst lea result (make-ea :dword :index number :scale 8)))
659 (cond ((plusp amount) (inst shl result amount))
660 (t (inst sar result (min 31 (- amount)))))))))
662 (define-vop (fast-ash-c/unsigned=>unsigned)
665 (:args (number :scs (unsigned-reg) :target result
666 :load-if (not (and (sc-is number unsigned-stack)
667 (sc-is result unsigned-stack)
668 (location= number result)))))
670 (:arg-types unsigned-num (:constant integer))
671 (:results (result :scs (unsigned-reg)
672 :load-if (not (and (sc-is number unsigned-stack)
673 (sc-is result unsigned-stack)
674 (location= number result)))))
675 (:result-types unsigned-num)
678 (cond ((and (= amount 1) (not (location= number result)))
679 (inst lea result (make-ea :dword :index number :scale 2)))
680 ((and (= amount 2) (not (location= number result)))
681 (inst lea result (make-ea :dword :index number :scale 4)))
682 ((and (= amount 3) (not (location= number result)))
683 (inst lea result (make-ea :dword :index number :scale 8)))
686 (cond ((< -32 amount 32)
687 ;; this code is used both in ASH and ASH-MOD32, so
690 (inst shl result amount)
691 (inst shr result (- amount))))
692 (t (if (sc-is result unsigned-reg)
693 (inst xor result result)
694 (inst mov result 0))))))))
696 (define-vop (fast-ash-left/signed=>signed)
698 (:args (number :scs (signed-reg) :target result
699 :load-if (not (and (sc-is number signed-stack)
700 (sc-is result signed-stack)
701 (location= number result))))
702 (amount :scs (unsigned-reg) :target ecx))
703 (:arg-types signed-num positive-fixnum)
704 (:temporary (:sc unsigned-reg :offset ecx-offset :from (:argument 1)) ecx)
705 (:results (result :scs (signed-reg) :from (:argument 0)
706 :load-if (not (and (sc-is number signed-stack)
707 (sc-is result signed-stack)
708 (location= number result)))))
709 (:result-types signed-num)
715 (inst shl result :cl)))
717 (define-vop (fast-ash-left/unsigned=>unsigned)
719 (:args (number :scs (unsigned-reg) :target result
720 :load-if (not (and (sc-is number unsigned-stack)
721 (sc-is result unsigned-stack)
722 (location= number result))))
723 (amount :scs (unsigned-reg) :target ecx))
724 (:arg-types unsigned-num positive-fixnum)
725 (:temporary (:sc unsigned-reg :offset ecx-offset :from (:argument 1)) ecx)
726 (:results (result :scs (unsigned-reg) :from (:argument 0)
727 :load-if (not (and (sc-is number unsigned-stack)
728 (sc-is result unsigned-stack)
729 (location= number result)))))
730 (:result-types unsigned-num)
736 (inst shl result :cl)))
738 (define-vop (fast-ash/signed=>signed)
741 (:args (number :scs (signed-reg) :target result)
742 (amount :scs (signed-reg) :target ecx))
743 (:arg-types signed-num signed-num)
744 (:results (result :scs (signed-reg) :from (:argument 0)))
745 (:result-types signed-num)
746 (:temporary (:sc signed-reg :offset ecx-offset :from (:argument 1)) ecx)
752 (inst jmp :ns positive)
758 (inst sar result :cl)
762 ;; The result-type ensures us that this shift will not overflow.
763 (inst shl result :cl)
767 (define-vop (fast-ash/unsigned=>unsigned)
770 (:args (number :scs (unsigned-reg) :target result)
771 (amount :scs (signed-reg) :target ecx))
772 (:arg-types unsigned-num signed-num)
773 (:results (result :scs (unsigned-reg) :from (:argument 0)))
774 (:result-types unsigned-num)
775 (:temporary (:sc signed-reg :offset ecx-offset :from (:argument 1)) ecx)
781 (inst jmp :ns positive)
785 (inst xor result result)
788 (inst shr result :cl)
792 ;; The result-type ensures us that this shift will not overflow.
793 (inst shl result :cl)
799 (defknown %lea (integer integer (member 1 2 4 8) (signed-byte 32))
801 (foldable flushable movable))
803 (defoptimizer (%lea derive-type) ((base index scale disp))
804 (when (and (constant-lvar-p scale)
805 (constant-lvar-p disp))
806 (let ((scale (lvar-value scale))
807 (disp (lvar-value disp))
808 (base-type (lvar-type base))
809 (index-type (lvar-type index)))
810 (when (and (numeric-type-p base-type)
811 (numeric-type-p index-type))
812 (let ((base-lo (numeric-type-low base-type))
813 (base-hi (numeric-type-high base-type))
814 (index-lo (numeric-type-low index-type))
815 (index-hi (numeric-type-high index-type)))
816 (make-numeric-type :class 'integer
818 :low (when (and base-lo index-lo)
819 (+ base-lo (* index-lo scale) disp))
820 :high (when (and base-hi index-hi)
821 (+ base-hi (* index-hi scale) disp))))))))
823 (defun %lea (base index scale disp)
824 (+ base (* index scale) disp))
828 (define-vop (%lea/unsigned=>unsigned)
831 (:args (base :scs (unsigned-reg))
832 (index :scs (unsigned-reg)))
834 (:arg-types unsigned-num unsigned-num
835 (:constant (member 1 2 4 8))
836 (:constant (signed-byte 32)))
837 (:results (r :scs (unsigned-reg)))
838 (:result-types unsigned-num)
840 (inst lea r (make-ea :dword :base base :index index
841 :scale scale :disp disp))))
843 (define-vop (%lea/signed=>signed)
846 (:args (base :scs (signed-reg))
847 (index :scs (signed-reg)))
849 (:arg-types signed-num signed-num
850 (:constant (member 1 2 4 8))
851 (:constant (signed-byte 32)))
852 (:results (r :scs (signed-reg)))
853 (:result-types signed-num)
855 (inst lea r (make-ea :dword :base base :index index
856 :scale scale :disp disp))))
858 (define-vop (%lea/fixnum=>fixnum)
861 (:args (base :scs (any-reg))
862 (index :scs (any-reg)))
864 (:arg-types tagged-num tagged-num
865 (:constant (member 1 2 4 8))
866 (:constant (signed-byte 32)))
867 (:results (r :scs (any-reg)))
868 (:result-types tagged-num)
870 (inst lea r (make-ea :dword :base base :index index
871 :scale scale :disp disp))))
873 ;;; FIXME: before making knowledge of this too public, it needs to be
874 ;;; fixed so that it's actually _faster_ than the non-CMOV version; at
875 ;;; least on my Celeron-XXX laptop, this version is marginally slower
876 ;;; than the above version with branches. -- CSR, 2003-09-04
877 (define-vop (fast-cmov-ash/unsigned=>unsigned)
880 (:args (number :scs (unsigned-reg) :target result)
881 (amount :scs (signed-reg) :target ecx))
882 (:arg-types unsigned-num signed-num)
883 (:results (result :scs (unsigned-reg) :from (:argument 0)))
884 (:result-types unsigned-num)
885 (:temporary (:sc signed-reg :offset ecx-offset :from (:argument 1)) ecx)
886 (:temporary (:sc any-reg :from (:eval 0) :to (:eval 1)) zero)
888 (:guard (member :cmov *backend-subfeatures*))
893 (inst jmp :ns positive)
896 (inst shr result :cl)
898 (inst cmov :nbe result zero)
902 ;; The result-type ensures us that this shift will not overflow.
903 (inst shl result :cl)
907 ;;; Note: documentation for this function is wrong - rtfm
908 (define-vop (signed-byte-32-len)
909 (:translate integer-length)
910 (:note "inline (signed-byte 32) integer-length")
912 (:args (arg :scs (signed-reg) :target res))
913 (:arg-types signed-num)
914 (:results (res :scs (unsigned-reg)))
915 (:result-types unsigned-num)
930 (define-vop (unsigned-byte-32-len)
931 (:translate integer-length)
932 (:note "inline (unsigned-byte 32) integer-length")
934 (:args (arg :scs (unsigned-reg)))
935 (:arg-types unsigned-num)
936 (:results (res :scs (unsigned-reg)))
937 (:result-types unsigned-num)
947 (define-vop (unsigned-byte-32-count)
948 (:translate logcount)
949 (:note "inline (unsigned-byte 32) logcount")
951 (:args (arg :scs (unsigned-reg)))
952 (:arg-types unsigned-num)
953 (:results (result :scs (unsigned-reg)))
954 (:result-types positive-fixnum)
955 (:temporary (:sc unsigned-reg :from (:argument 0)) temp)
959 (inst mov temp result)
961 (inst and result #x55555555)
962 (inst and temp #x55555555)
963 (inst add result temp)
965 (inst mov temp result)
967 (inst and result #x33333333)
968 (inst and temp #x33333333)
969 (inst add result temp)
971 (inst mov temp result)
973 (inst and result #x0f0f0f0f)
974 (inst and temp #x0f0f0f0f)
975 (inst add result temp)
977 (inst mov temp result)
979 (inst and result #x00ff00ff)
980 (inst and temp #x00ff00ff)
981 (inst add result temp)
983 (inst mov temp result)
985 (inst and result #x0000ffff)
986 (inst and temp #x0000ffff)
987 (inst add result temp)))
989 ;;;; binary conditional VOPs
991 (define-vop (fast-conditional)
996 (:policy :fast-safe))
998 (define-vop (fast-conditional/fixnum fast-conditional)
999 (:args (x :scs (any-reg)
1000 :load-if (not (and (sc-is x control-stack)
1001 (sc-is y any-reg))))
1002 (y :scs (any-reg control-stack)))
1003 (:arg-types tagged-num tagged-num)
1004 (:note "inline fixnum comparison"))
1006 (define-vop (fast-conditional-c/fixnum fast-conditional/fixnum)
1007 (:args (x :scs (any-reg control-stack)))
1008 (:arg-types tagged-num (:constant (signed-byte 30)))
1009 (:info target not-p y))
1011 (define-vop (fast-conditional/signed fast-conditional)
1012 (:args (x :scs (signed-reg)
1013 :load-if (not (and (sc-is x signed-stack)
1014 (sc-is y signed-reg))))
1015 (y :scs (signed-reg signed-stack)))
1016 (:arg-types signed-num signed-num)
1017 (:note "inline (signed-byte 32) comparison"))
1019 (define-vop (fast-conditional-c/signed fast-conditional/signed)
1020 (:args (x :scs (signed-reg signed-stack)))
1021 (:arg-types signed-num (:constant (signed-byte 32)))
1022 (:info target not-p y))
1024 (define-vop (fast-conditional/unsigned fast-conditional)
1025 (:args (x :scs (unsigned-reg)
1026 :load-if (not (and (sc-is x unsigned-stack)
1027 (sc-is y unsigned-reg))))
1028 (y :scs (unsigned-reg unsigned-stack)))
1029 (:arg-types unsigned-num unsigned-num)
1030 (:note "inline (unsigned-byte 32) comparison"))
1032 (define-vop (fast-conditional-c/unsigned fast-conditional/unsigned)
1033 (:args (x :scs (unsigned-reg unsigned-stack)))
1034 (:arg-types unsigned-num (:constant (unsigned-byte 32)))
1035 (:info target not-p y))
1038 (macrolet ((define-conditional-vop (tran cond unsigned not-cond not-unsigned)
1041 (lambda (suffix cost signed)
1042 `(define-vop (;; FIXME: These could be done more
1043 ;; cleanly with SYMBOLICATE.
1044 ,(intern (format nil "~:@(FAST-IF-~A~A~)"
1047 (format nil "~:@(FAST-CONDITIONAL~A~)"
1052 ,(if (eq suffix '-c/fixnum)
1063 '(/fixnum -c/fixnum /signed -c/signed /unsigned -c/unsigned)
1065 '(t t t t nil nil)))))
1067 (define-conditional-vop < :l :b :ge :ae)
1068 (define-conditional-vop > :g :a :le :be))
1070 (define-vop (fast-if-eql/signed fast-conditional/signed)
1074 (inst jmp (if not-p :ne :e) target)))
1076 (define-vop (fast-if-eql-c/signed fast-conditional-c/signed)
1079 (cond ((and (sc-is x signed-reg) (zerop y))
1080 (inst test x x)) ; smaller instruction
1083 (inst jmp (if not-p :ne :e) target)))
1085 (define-vop (fast-if-eql/unsigned fast-conditional/unsigned)
1089 (inst jmp (if not-p :ne :e) target)))
1091 (define-vop (fast-if-eql-c/unsigned fast-conditional-c/unsigned)
1094 (cond ((and (sc-is x unsigned-reg) (zerop y))
1095 (inst test x x)) ; smaller instruction
1098 (inst jmp (if not-p :ne :e) target)))
1100 ;;; EQL/FIXNUM is funny because the first arg can be of any type, not just a
1103 ;;; These versions specify a fixnum restriction on their first arg. We have
1104 ;;; also generic-eql/fixnum VOPs which are the same, but have no restriction on
1105 ;;; the first arg and a higher cost. The reason for doing this is to prevent
1106 ;;; fixnum specific operations from being used on word integers, spuriously
1107 ;;; consing the argument.
1109 (define-vop (fast-eql/fixnum fast-conditional)
1110 (:args (x :scs (any-reg)
1111 :load-if (not (and (sc-is x control-stack)
1112 (sc-is y any-reg))))
1113 (y :scs (any-reg control-stack)))
1114 (:arg-types tagged-num tagged-num)
1115 (:note "inline fixnum comparison")
1119 (inst jmp (if not-p :ne :e) target)))
1120 (define-vop (generic-eql/fixnum fast-eql/fixnum)
1121 (:args (x :scs (any-reg descriptor-reg)
1122 :load-if (not (and (sc-is x control-stack)
1123 (sc-is y any-reg))))
1124 (y :scs (any-reg control-stack)))
1125 (:arg-types * tagged-num)
1128 (define-vop (fast-eql-c/fixnum fast-conditional/fixnum)
1129 (:args (x :scs (any-reg control-stack)))
1130 (:arg-types tagged-num (:constant (signed-byte 30)))
1131 (:info target not-p y)
1134 (cond ((and (sc-is x any-reg) (zerop y))
1135 (inst test x x)) ; smaller instruction
1137 (inst cmp x (fixnumize y))))
1138 (inst jmp (if not-p :ne :e) target)))
1139 (define-vop (generic-eql-c/fixnum fast-eql-c/fixnum)
1140 (:args (x :scs (any-reg descriptor-reg control-stack)))
1141 (:arg-types * (:constant (signed-byte 30)))
1144 ;;;; 32-bit logical operations
1146 (define-vop (merge-bits)
1147 (:translate merge-bits)
1148 (:args (shift :scs (signed-reg unsigned-reg) :target ecx)
1149 (prev :scs (unsigned-reg) :target result)
1150 (next :scs (unsigned-reg)))
1151 (:arg-types tagged-num unsigned-num unsigned-num)
1152 (:temporary (:sc signed-reg :offset ecx-offset :from (:argument 0)) ecx)
1153 (:results (result :scs (unsigned-reg) :from (:argument 1)))
1154 (:result-types unsigned-num)
1155 (:policy :fast-safe)
1159 (inst shrd result next :cl)))
1161 (define-source-transform 32bit-logical-not (x)
1162 `(logand (lognot (the (unsigned-byte 32) ,x)) #.(1- (ash 1 32))))
1164 (deftransform 32bit-logical-and ((x y))
1167 (define-source-transform 32bit-logical-nand (x y)
1168 `(32bit-logical-not (32bit-logical-and ,x ,y)))
1170 (deftransform 32bit-logical-or ((x y))
1173 (define-source-transform 32bit-logical-nor (x y)
1174 `(32bit-logical-not (32bit-logical-or ,x ,y)))
1176 (deftransform 32bit-logical-xor ((x y))
1179 (define-source-transform 32bit-logical-eqv (x y)
1180 `(32bit-logical-not (32bit-logical-xor ,x ,y)))
1182 (define-source-transform 32bit-logical-orc1 (x y)
1183 `(32bit-logical-or (32bit-logical-not ,x) ,y))
1185 (define-source-transform 32bit-logical-orc2 (x y)
1186 `(32bit-logical-or ,x (32bit-logical-not ,y)))
1188 (define-source-transform 32bit-logical-andc1 (x y)
1189 `(32bit-logical-and (32bit-logical-not ,x) ,y))
1191 (define-source-transform 32bit-logical-andc2 (x y)
1192 `(32bit-logical-and ,x (32bit-logical-not ,y)))
1194 ;;; Only the lower 5 bits of the shift amount are significant.
1195 (define-vop (shift-towards-someplace)
1196 (:policy :fast-safe)
1197 (:args (num :scs (unsigned-reg) :target r)
1198 (amount :scs (signed-reg) :target ecx))
1199 (:arg-types unsigned-num tagged-num)
1200 (:temporary (:sc signed-reg :offset ecx-offset :from (:argument 1)) ecx)
1201 (:results (r :scs (unsigned-reg) :from (:argument 0)))
1202 (:result-types unsigned-num))
1204 (define-vop (shift-towards-start shift-towards-someplace)
1205 (:translate shift-towards-start)
1206 (:note "SHIFT-TOWARDS-START")
1212 (define-vop (shift-towards-end shift-towards-someplace)
1213 (:translate shift-towards-end)
1214 (:note "SHIFT-TOWARDS-END")
1220 ;;;; Modular functions
1222 (define-modular-fun +-mod32 (x y) + 32)
1223 (define-vop (fast-+-mod32/unsigned=>unsigned fast-+/unsigned=>unsigned)
1224 (:translate +-mod32))
1225 (define-vop (fast-+-mod32-c/unsigned=>unsigned fast-+-c/unsigned=>unsigned)
1226 (:translate +-mod32))
1227 (define-modular-fun --mod32 (x y) - 32)
1228 (define-vop (fast---mod32/unsigned=>unsigned fast--/unsigned=>unsigned)
1229 (:translate --mod32))
1230 (define-vop (fast---mod32-c/unsigned=>unsigned fast---c/unsigned=>unsigned)
1231 (:translate --mod32))
1233 (define-modular-fun *-mod32 (x y) * 32)
1234 (define-vop (fast-*-mod32/unsigned=>unsigned fast-*/unsigned=>unsigned)
1235 (:translate *-mod32))
1236 ;;; (no -C variant as x86 MUL instruction doesn't take an immediate)
1238 (define-vop (fast-ash-left-mod32-c/unsigned=>unsigned
1239 fast-ash-c/unsigned=>unsigned)
1240 (:translate ash-left-mod32))
1244 (defknown sb!vm::%lea-mod32 (integer integer (member 1 2 4 8) (signed-byte 32))
1246 (foldable flushable movable))
1248 (define-modular-fun-optimizer %lea ((base index scale disp) :width width)
1249 (when (and (<= width 32)
1250 (constant-lvar-p scale)
1251 (constant-lvar-p disp))
1252 (cut-to-width base width)
1253 (cut-to-width index width)
1254 'sb!vm::%lea-mod32))
1257 (defun sb!vm::%lea-mod32 (base index scale disp)
1258 (ldb (byte 32 0) (%lea base index scale disp)))
1260 (defun sb!vm::%lea-mod32 (base index scale disp)
1261 (let ((base (logand base #xffffffff))
1262 (index (logand index #xffffffff)))
1263 ;; can't use modular version of %LEA, as we only have VOPs for
1264 ;; constant SCALE and DISP.
1265 (ldb (byte 32 0) (+ base (* index scale) disp))))
1267 (in-package "SB!VM")
1269 (define-vop (%lea-mod32/unsigned=>unsigned
1270 %lea/unsigned=>unsigned)
1271 (:translate %lea-mod32))
1273 ;;; logical operations
1274 (define-modular-fun lognot-mod32 (x) lognot 32)
1275 (define-vop (lognot-mod32/unsigned=>unsigned)
1276 (:translate lognot-mod32)
1277 (:args (x :scs (unsigned-reg unsigned-stack) :target r
1278 :load-if (not (and (sc-is x unsigned-stack)
1279 (sc-is r unsigned-stack)
1281 (:arg-types unsigned-num)
1282 (:results (r :scs (unsigned-reg)
1283 :load-if (not (and (sc-is x unsigned-stack)
1284 (sc-is r unsigned-stack)
1286 (:result-types unsigned-num)
1287 (:policy :fast-safe)
1292 (define-modular-fun logxor-mod32 (x y) logxor 32)
1293 (define-vop (fast-logxor-mod32/unsigned=>unsigned
1294 fast-logxor/unsigned=>unsigned)
1295 (:translate logxor-mod32))
1296 (define-vop (fast-logxor-mod32-c/unsigned=>unsigned
1297 fast-logxor-c/unsigned=>unsigned)
1298 (:translate logxor-mod32))
1300 (define-source-transform logeqv (&rest args)
1301 (if (oddp (length args))
1303 `(lognot (logxor ,@args))))
1304 (define-source-transform logandc1 (x y)
1305 `(logand (lognot ,x) ,y))
1306 (define-source-transform logandc2 (x y)
1307 `(logand ,x (lognot ,y)))
1308 (define-source-transform logorc1 (x y)
1309 `(logior (lognot ,x) ,y))
1310 (define-source-transform logorc2 (x y)
1311 `(logior ,x (lognot ,y)))
1312 (define-source-transform lognor (x y)
1313 `(lognot (logior ,x ,y)))
1314 (define-source-transform lognand (x y)
1315 `(lognot (logand ,x ,y)))
1319 (define-vop (bignum-length get-header-data)
1320 (:translate sb!bignum:%bignum-length)
1321 (:policy :fast-safe))
1323 (define-vop (bignum-set-length set-header-data)
1324 (:translate sb!bignum:%bignum-set-length)
1325 (:policy :fast-safe))
1327 (define-full-reffer bignum-ref * bignum-digits-offset other-pointer-lowtag
1328 (unsigned-reg) unsigned-num sb!bignum:%bignum-ref)
1330 (define-full-setter bignum-set * bignum-digits-offset other-pointer-lowtag
1331 (unsigned-reg) unsigned-num sb!bignum:%bignum-set)
1333 (define-vop (digit-0-or-plus)
1334 (:translate sb!bignum:%digit-0-or-plusp)
1335 (:policy :fast-safe)
1336 (:args (digit :scs (unsigned-reg)))
1337 (:arg-types unsigned-num)
1339 (:info target not-p)
1341 (inst or digit digit)
1342 (inst jmp (if not-p :s :ns) target)))
1345 ;;; For add and sub with carry the sc of carry argument is any-reg so
1346 ;;; the it may be passed as a fixnum or word and thus may be 0, 1, or
1347 ;;; 4. This is easy to deal with and may save a fixnum-word
1349 (define-vop (add-w/carry)
1350 (:translate sb!bignum:%add-with-carry)
1351 (:policy :fast-safe)
1352 (:args (a :scs (unsigned-reg) :target result)
1353 (b :scs (unsigned-reg unsigned-stack) :to :eval)
1354 (c :scs (any-reg) :target temp))
1355 (:arg-types unsigned-num unsigned-num positive-fixnum)
1356 (:temporary (:sc any-reg :from (:argument 2) :to :eval) temp)
1357 (:results (result :scs (unsigned-reg) :from (:argument 0))
1358 (carry :scs (unsigned-reg)))
1359 (:result-types unsigned-num positive-fixnum)
1363 (inst neg temp) ; Set the carry flag to 0 if c=0 else to 1
1366 (inst adc carry carry)))
1368 ;;; Note: the borrow is the oppostite of the x86 convention - 1 for no
1369 ;;; borrow and 0 for a borrow.
1370 (define-vop (sub-w/borrow)
1371 (:translate sb!bignum:%subtract-with-borrow)
1372 (:policy :fast-safe)
1373 (:args (a :scs (unsigned-reg) :to :eval :target result)
1374 (b :scs (unsigned-reg unsigned-stack) :to :result)
1375 (c :scs (any-reg control-stack)))
1376 (:arg-types unsigned-num unsigned-num positive-fixnum)
1377 (:results (result :scs (unsigned-reg) :from :eval)
1378 (borrow :scs (unsigned-reg)))
1379 (:result-types unsigned-num positive-fixnum)
1381 (inst cmp c 1) ; Set the carry flag to 1 if c=0 else to 0
1385 (inst adc borrow borrow)
1386 (inst xor borrow 1)))
1389 (define-vop (bignum-mult-and-add-3-arg)
1390 (:translate sb!bignum:%multiply-and-add)
1391 (:policy :fast-safe)
1392 (:args (x :scs (unsigned-reg) :target eax)
1393 (y :scs (unsigned-reg unsigned-stack))
1394 (carry-in :scs (unsigned-reg unsigned-stack)))
1395 (:arg-types unsigned-num unsigned-num unsigned-num)
1396 (:temporary (:sc unsigned-reg :offset eax-offset :from (:argument 0)
1397 :to (:result 1) :target lo) eax)
1398 (:temporary (:sc unsigned-reg :offset edx-offset :from (:argument 1)
1399 :to (:result 0) :target hi) edx)
1400 (:results (hi :scs (unsigned-reg))
1401 (lo :scs (unsigned-reg)))
1402 (:result-types unsigned-num unsigned-num)
1406 (inst add eax carry-in)
1411 (define-vop (bignum-mult-and-add-4-arg)
1412 (:translate sb!bignum:%multiply-and-add)
1413 (:policy :fast-safe)
1414 (:args (x :scs (unsigned-reg) :target eax)
1415 (y :scs (unsigned-reg unsigned-stack))
1416 (prev :scs (unsigned-reg unsigned-stack))
1417 (carry-in :scs (unsigned-reg unsigned-stack)))
1418 (:arg-types unsigned-num unsigned-num unsigned-num unsigned-num)
1419 (:temporary (:sc unsigned-reg :offset eax-offset :from (:argument 0)
1420 :to (:result 1) :target lo) eax)
1421 (:temporary (:sc unsigned-reg :offset edx-offset :from (:argument 1)
1422 :to (:result 0) :target hi) edx)
1423 (:results (hi :scs (unsigned-reg))
1424 (lo :scs (unsigned-reg)))
1425 (:result-types unsigned-num unsigned-num)
1431 (inst add eax carry-in)
1437 (define-vop (bignum-mult)
1438 (:translate sb!bignum:%multiply)
1439 (:policy :fast-safe)
1440 (:args (x :scs (unsigned-reg) :target eax)
1441 (y :scs (unsigned-reg unsigned-stack)))
1442 (:arg-types unsigned-num unsigned-num)
1443 (:temporary (:sc unsigned-reg :offset eax-offset :from (:argument 0)
1444 :to (:result 1) :target lo) eax)
1445 (:temporary (:sc unsigned-reg :offset edx-offset :from (:argument 1)
1446 :to (:result 0) :target hi) edx)
1447 (:results (hi :scs (unsigned-reg))
1448 (lo :scs (unsigned-reg)))
1449 (:result-types unsigned-num unsigned-num)
1456 (define-vop (bignum-lognot lognot-mod32/unsigned=>unsigned)
1457 (:translate sb!bignum:%lognot))
1459 (define-vop (fixnum-to-digit)
1460 (:translate sb!bignum:%fixnum-to-digit)
1461 (:policy :fast-safe)
1462 (:args (fixnum :scs (any-reg control-stack) :target digit))
1463 (:arg-types tagged-num)
1464 (:results (digit :scs (unsigned-reg)
1465 :load-if (not (and (sc-is fixnum control-stack)
1466 (sc-is digit unsigned-stack)
1467 (location= fixnum digit)))))
1468 (:result-types unsigned-num)
1471 (inst sar digit 2)))
1473 (define-vop (bignum-floor)
1474 (:translate sb!bignum:%floor)
1475 (:policy :fast-safe)
1476 (:args (div-high :scs (unsigned-reg) :target edx)
1477 (div-low :scs (unsigned-reg) :target eax)
1478 (divisor :scs (unsigned-reg unsigned-stack)))
1479 (:arg-types unsigned-num unsigned-num unsigned-num)
1480 (:temporary (:sc unsigned-reg :offset eax-offset :from (:argument 1)
1481 :to (:result 0) :target quo) eax)
1482 (:temporary (:sc unsigned-reg :offset edx-offset :from (:argument 0)
1483 :to (:result 1) :target rem) edx)
1484 (:results (quo :scs (unsigned-reg))
1485 (rem :scs (unsigned-reg)))
1486 (:result-types unsigned-num unsigned-num)
1490 (inst div eax divisor)
1494 (define-vop (signify-digit)
1495 (:translate sb!bignum:%fixnum-digit-with-correct-sign)
1496 (:policy :fast-safe)
1497 (:args (digit :scs (unsigned-reg unsigned-stack) :target res))
1498 (:arg-types unsigned-num)
1499 (:results (res :scs (any-reg signed-reg)
1500 :load-if (not (and (sc-is digit unsigned-stack)
1501 (sc-is res control-stack signed-stack)
1502 (location= digit res)))))
1503 (:result-types signed-num)
1506 (when (sc-is res any-reg control-stack)
1509 (define-vop (digit-ashr)
1510 (:translate sb!bignum:%ashr)
1511 (:policy :fast-safe)
1512 (:args (digit :scs (unsigned-reg unsigned-stack) :target result)
1513 (count :scs (unsigned-reg) :target ecx))
1514 (:arg-types unsigned-num positive-fixnum)
1515 (:temporary (:sc unsigned-reg :offset ecx-offset :from (:argument 1)) ecx)
1516 (:results (result :scs (unsigned-reg) :from (:argument 0)
1517 :load-if (not (and (sc-is result unsigned-stack)
1518 (location= digit result)))))
1519 (:result-types unsigned-num)
1523 (inst sar result :cl)))
1525 (define-vop (digit-lshr digit-ashr)
1526 (:translate sb!bignum:%digit-logical-shift-right)
1530 (inst shr result :cl)))
1532 (define-vop (digit-ashl digit-ashr)
1533 (:translate sb!bignum:%ashl)
1537 (inst shl result :cl)))
1539 ;;;; static functions
1541 (define-static-fun two-arg-/ (x y) :translate /)
1543 (define-static-fun two-arg-gcd (x y) :translate gcd)
1544 (define-static-fun two-arg-lcm (x y) :translate lcm)
1546 (define-static-fun two-arg-and (x y) :translate logand)
1547 (define-static-fun two-arg-ior (x y) :translate logior)
1548 (define-static-fun two-arg-xor (x y) :translate logxor)
1551 ;;; Support for the Mersenne Twister, MT19937, random number generator
1552 ;;; due to Matsumoto and Nishimura.
1554 ;;; Makoto Matsumoto and T. Nishimura, "Mersenne twister: A
1555 ;;; 623-dimensionally equidistributed uniform pseudorandom number
1556 ;;; generator.", ACM Transactions on Modeling and Computer Simulation,
1557 ;;; 1997, to appear.
1560 ;;; 0-1: Constant matrix A. [0, #x9908b0df] (not used here)
1561 ;;; 2: Index; init. to 1.
1563 (defknown random-mt19937 ((simple-array (unsigned-byte 32) (*)))
1564 (unsigned-byte 32) ())
1565 (define-vop (random-mt19937)
1566 (:policy :fast-safe)
1567 (:translate random-mt19937)
1568 (:args (state :scs (descriptor-reg) :to :result))
1569 (:arg-types simple-array-unsigned-byte-32)
1570 (:temporary (:sc unsigned-reg :from (:eval 0) :to :result) k)
1571 (:temporary (:sc unsigned-reg :offset eax-offset
1572 :from (:eval 0) :to :result) tmp)
1573 (:results (y :scs (unsigned-reg) :from (:eval 0)))
1574 (:result-types unsigned-num)
1576 (inst mov k (make-ea :dword :base state
1577 :disp (- (* (+ 2 vector-data-offset)
1579 other-pointer-lowtag)))
1581 (inst jmp :ne no-update)
1582 (inst mov tmp state) ; The state is passed in EAX.
1583 (inst call (make-fixup 'random-mt19937-update :assembly-routine))
1584 ;; Restore k, and set to 0.
1588 (inst mov y (make-ea :dword :base state :index k :scale 4
1589 :disp (- (* (+ 3 vector-data-offset)
1591 other-pointer-lowtag)))
1594 (inst xor y (make-ea :dword :base state :index k :scale 4
1595 :disp (- (* (+ 3 vector-data-offset)
1597 other-pointer-lowtag)))
1598 ;; y ^= (y << 7) & #x9d2c5680
1602 (inst mov (make-ea :dword :base state
1603 :disp (- (* (+ 2 vector-data-offset)
1605 other-pointer-lowtag))
1607 (inst and tmp #x9d2c5680)
1609 ;; y ^= (y << 15) & #xefc60000
1612 (inst and tmp #xefc60000)
1621 ;;; This is essentially a straight implementation of the algorithm in
1622 ;;; "Strength Reduction of Multiplications by Integer Constants",
1623 ;;; Youfeng Wu, ACM SIGPLAN Notices, Vol. 30, No.2, February 1995.
1624 (defun basic-decompose-multiplication (arg num n-bits condensed)
1625 (case (aref condensed 0)
1627 (let ((tmp (min 3 (aref condensed 1))))
1628 (decf (aref condensed 1) tmp)
1631 ,(decompose-multiplication
1632 arg (ash (1- num) (- tmp)) (1- n-bits) (subseq condensed 1))
1635 (let ((r0 (aref condensed 0)))
1636 (incf (aref condensed 1) r0)
1638 (%lea ,(decompose-multiplication
1639 arg (- num (ash 1 r0)) (1- n-bits) (subseq condensed 1))
1642 (t (let ((r0 (aref condensed 0)))
1643 (setf (aref condensed 0) 0)
1645 (ash ,(decompose-multiplication
1646 arg (ash num (- r0)) n-bits condensed)
1649 (defun decompose-multiplication (arg num n-bits condensed)
1654 `(logand #xffffffff (ash ,arg ,(1- (integer-length num)))))
1655 ((let ((max 0) (end 0))
1656 (loop for i from 2 to (length condensed)
1657 for j = (reduce #'+ (subseq condensed 0 i))
1658 when (and (> (- (* 2 i) 3 j) max)
1659 (< (+ (ash 1 (1+ j))
1660 (ash (ldb (byte (- 32 (1+ j)) (1+ j)) num)
1663 do (setq max (- (* 2 i) 3 j)
1666 (let ((j (reduce #'+ (subseq condensed 0 end))))
1667 (let ((n2 (+ (ash 1 (1+ j))
1668 (ash (ldb (byte (- 32 (1+ j)) (1+ j)) num) (1+ j))))
1669 (n1 (1+ (ldb (byte (1+ j) 0) (lognot num)))))
1671 (- ,(optimize-multiply arg n2) ,(optimize-multiply arg n1))))))))
1672 ((dolist (i '(9 5 3))
1673 (when (integerp (/ num i))
1674 (when (< (logcount (/ num i)) (logcount num))
1676 (return `(let ((,x ,(optimize-multiply arg (/ num i))))
1678 (%lea ,x ,x (1- ,i) 0)))))))))
1679 (t (basic-decompose-multiplication arg num n-bits condensed))))
1681 (defun optimize-multiply (arg x)
1682 (let* ((n-bits (logcount x))
1683 (condensed (make-array n-bits)))
1684 (let ((count 0) (bit 0))
1686 (cond ((logbitp i x)
1687 (setf (aref condensed bit) count)
1691 (decompose-multiplication arg x n-bits condensed)))
1693 (defun *-transformer (y)
1695 ((= y (ash 1 (integer-length y)))
1696 ;; there's a generic transform for y = 2^k
1697 (give-up-ir1-transform))
1698 ((member y '(3 5 9))
1699 ;; we can do these multiplications directly using LEA
1700 `(%lea x x ,(1- y) 0))
1701 ((member :pentium4 *backend-subfeatures*)
1702 ;; the pentium4's multiply unit is reportedly very good
1703 (give-up-ir1-transform))
1704 ;; FIXME: should make this more fine-grained. If nothing else,
1705 ;; there should probably be a cutoff of about 9 instructions on
1706 ;; pentium-class machines.
1707 (t (optimize-multiply 'x y))))
1709 (deftransform * ((x y)
1710 ((unsigned-byte 32) (constant-arg (unsigned-byte 32)))
1712 "recode as leas, shifts and adds"
1713 (let ((y (lvar-value y)))
1716 (deftransform sb!vm::*-mod32
1717 ((x y) ((unsigned-byte 32) (constant-arg (unsigned-byte 32)))
1719 "recode as leas, shifts and adds"
1720 (let ((y (lvar-value y)))
1723 ;;; FIXME: we should also be able to write an optimizer or two to
1724 ;;; convert (+ (* x 2) 17), (- (* x 9) 5) to a %LEA.