1 ;;;; code to implement bignum support
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.
12 (in-package "SB!BIGNUM")
16 ;;; comments from CMU CL:
17 ;;; These symbols define the interface to the number code:
18 ;;; add-bignums multiply-bignums negate-bignum subtract-bignum
19 ;;; multiply-bignum-and-fixnum multiply-fixnums
20 ;;; bignum-ashift-right bignum-ashift-left bignum-gcd
21 ;;; bignum-to-float bignum-integer-length
22 ;;; bignum-logical-and bignum-logical-ior bignum-logical-xor
23 ;;; bignum-logical-not bignum-load-byte bignum-deposit-byte
24 ;;; bignum-truncate bignum-plus-p bignum-compare make-small-bignum
25 ;;; bignum-logbitp bignum-logcount
26 ;;; These symbols define the interface to the compiler:
27 ;;; bignum-type bignum-element-type bignum-index %allocate-bignum
28 ;;; %bignum-length %bignum-set-length %bignum-ref %bignum-set
29 ;;; %digit-0-or-plusp %add-with-carry %subtract-with-borrow
30 ;;; %multiply-and-add %multiply %lognot %logand %logior %logxor
31 ;;; %fixnum-to-digit %floor %fixnum-digit-with-correct-sign %ashl
32 ;;; %ashr %digit-logical-shift-right))
34 ;;; The following interfaces will either be assembler routines or code
35 ;;; sequences expanded into the code as basic bignum operations:
41 ;;; %BIGNUM-SET-LENGTH
42 ;;; %FIXNUM-DIGIT-WITH-CORRECT-SIGN
46 ;;; %BIGNUM-0-OR-PLUSP
47 ;;; %DIGIT-LOGICAL-SHIFT-RIGHT
48 ;;; General (May not exist when done due to sole use in %-routines.)
53 ;;; %SUBTRACT-WITH-BORROW
58 ;;; Shifting (in place)
59 ;;; %NORMALIZE-BIGNUM-BUFFER
60 ;;; GCD/Relational operators:
63 ;;; Relational operators:
72 ;;; Note: The floating routines know about the float representation.
75 ;;; There might be a problem with various LET's and parameters that take a
76 ;;; digit value. We need to write these so those things stay in machine
77 ;;; registers and number stack slots. I bind locals to these values, and I
78 ;;; use function on them -- ZEROP, ASH, etc.
81 ;;; In shifting and byte operations, I use masks and logical operations that
82 ;;; could result in intermediate bignums. This is hidden by the current system,
83 ;;; but I may need to write these in a way that keeps these masks and logical
84 ;;; operations from diving into the Lisp level bignum code.
88 ;;; logior, logxor, logand
89 ;;; depending on relationals, < (twice) and <= (twice)
90 ;;; or write compare thing (twice).
91 ;;; LDB on fixnum with bignum result.
92 ;;; DPB on fixnum with bignum result.
93 ;;; TRUNCATE returns zero or one as one value and fixnum or minus fixnum
94 ;;; for the other value when given (truncate fixnum bignum).
95 ;;; Returns (truncate bignum fixnum) otherwise.
97 ;;; subtraction (twice)
100 ;;; Write MASK-FIELD and DEPOSIT-FIELD in terms of logical operations.
102 ;;; IF (/ x y) with bignums:
103 ;;; do the truncate, and if rem is 0, return quotient.
106 ;;; "truncate" each by gcd, ignoring remainder 0.
107 ;;; form ratio of each result, bottom is positive.
109 ;;;; What's a bignum?
111 (defconstant digit-size sb
!vm
:n-word-bits
)
113 (defconstant maximum-bignum-length
(1- (ash 1 (- sb
!vm
:n-word-bits
114 sb
!vm
:n-widetag-bits
))))
116 (defconstant all-ones-digit
(1- (ash 1 sb
!vm
:n-word-bits
)))
118 ;;;; internal inline routines
120 ;;; %ALLOCATE-BIGNUM must zero all elements.
121 (defun %allocate-bignum
(length)
122 (declare (type bignum-index length
))
123 (%allocate-bignum length
))
125 ;;; Extract the length of the bignum.
126 (defun %bignum-length
(bignum)
127 (declare (type bignum-type bignum
))
128 (%bignum-length bignum
))
130 ;;; %BIGNUM-REF needs to access bignums as obviously as possible, and it needs
131 ;;; to be able to return the digit somewhere no one looks for real objects.
132 (defun %bignum-ref
(bignum i
)
133 (declare (type bignum-type bignum
)
134 (type bignum-index i
))
135 (%bignum-ref bignum i
))
136 (defun %bignum-set
(bignum i value
)
137 (declare (type bignum-type bignum
)
138 (type bignum-index i
)
139 (type bignum-element-type value
))
140 (%bignum-set bignum i value
))
142 ;;; Return T if digit is positive, or NIL if negative.
143 (defun %digit-0-or-plusp
(digit)
144 (declare (type bignum-element-type digit
))
145 (not (logbitp (1- digit-size
) digit
)))
147 #!-sb-fluid
(declaim (inline %bignum-0-or-plusp
))
148 (defun %bignum-0-or-plusp
(bignum len
)
149 (declare (type bignum-type bignum
)
150 (type bignum-index len
))
151 (%digit-0-or-plusp
(%bignum-ref bignum
(1- len
))))
153 ;;; This should be in assembler, and should not cons intermediate
154 ;;; results. It returns a bignum digit and a carry resulting from adding
155 ;;; together a, b, and an incoming carry.
156 (defun %add-with-carry
(a b carry
)
157 (declare (type bignum-element-type a b
)
158 (type (mod 2) carry
))
159 (%add-with-carry a b carry
))
161 ;;; This should be in assembler, and should not cons intermediate
162 ;;; results. It returns a bignum digit and a borrow resulting from
163 ;;; subtracting b from a, and subtracting a possible incoming borrow.
165 ;;; We really do: a - b - 1 + borrow, where borrow is either 0 or 1.
166 (defun %subtract-with-borrow
(a b borrow
)
167 (declare (type bignum-element-type a b
)
168 (type (mod 2) borrow
))
169 (%subtract-with-borrow a b borrow
))
171 ;;; Multiply two digit-size numbers, returning a 2*digit-size result
172 ;;; split into two digit-size quantities.
173 (defun %multiply
(x y
)
174 (declare (type bignum-element-type x y
))
177 ;;; This multiplies x-digit and y-digit, producing high and low digits
178 ;;; manifesting the result. Then it adds the low digit, res-digit, and
179 ;;; carry-in-digit. Any carries (note, you still have to add two digits
180 ;;; at a time possibly producing two carries) from adding these three
181 ;;; digits get added to the high digit from the multiply, producing the
182 ;;; next carry digit. Res-digit is optional since two uses of this
183 ;;; primitive multiplies a single digit bignum by a multiple digit
184 ;;; bignum, and in this situation there is no need for a result buffer
185 ;;; accumulating partial results which is where the res-digit comes
187 (defun %multiply-and-add
(x-digit y-digit carry-in-digit
188 &optional
(res-digit 0))
189 (declare (type bignum-element-type x-digit y-digit res-digit carry-in-digit
))
190 (%multiply-and-add x-digit y-digit carry-in-digit res-digit
))
192 (defun %lognot
(digit)
193 (declare (type bignum-element-type digit
))
196 ;;; Each of these does the digit-size unsigned op.
197 #!-sb-fluid
(declaim (inline %logand %logior %logxor
))
199 (declare (type bignum-element-type a b
))
202 (declare (type bignum-element-type a b
))
205 (declare (type bignum-element-type a b
))
208 ;;; This takes a fixnum and sets it up as an unsigned digit-size
210 (defun %fixnum-to-digit
(x)
212 (logand x
(1- (ash 1 digit-size
))))
215 ;;; This takes three digits and returns the FLOOR'ed result of
216 ;;; dividing the first two as a 2*digit-size integer by the third.
218 ;;; Do weird LET and SETQ stuff to bamboozle the compiler into allowing
219 ;;; the %FLOOR transform to expand into pseudo-assembler for which the
220 ;;; compiler can later correctly allocate registers.
221 (defun %floor
(a b c
)
222 (let ((a a
) (b b
) (c c
))
223 (declare (type bignum-element-type a b c
))
227 ;;; Convert the digit to a regular integer assuming that the digit is signed.
228 (defun %fixnum-digit-with-correct-sign
(digit)
229 (declare (type bignum-element-type digit
))
230 (if (logbitp (1- digit-size
) digit
)
231 (logior digit
(ash -
1 digit-size
))
234 ;;; Do an arithmetic shift right of data even though bignum-element-type is
236 (defun %ashr
(data count
)
237 (declare (type bignum-element-type data
)
238 (type (mod #.sb
!vm
:n-word-bits
) count
))
241 ;;; This takes a digit-size quantity and shifts it to the left,
242 ;;; returning a digit-size quantity.
243 (defun %ashl
(data count
)
244 (declare (type bignum-element-type data
)
245 (type (mod #.sb
!vm
:n-word-bits
) count
))
248 ;;; Do an unsigned (logical) right shift of a digit by Count.
249 (defun %digit-logical-shift-right
(data count
)
250 (declare (type bignum-element-type data
)
251 (type (mod #.sb
!vm
:n-word-bits
) count
))
252 (%digit-logical-shift-right data count
))
254 ;;; Change the length of bignum to be newlen. Newlen must be the same or
255 ;;; smaller than the old length, and any elements beyond newlen must be zeroed.
256 (defun %bignum-set-length
(bignum newlen
)
257 (declare (type bignum-type bignum
)
258 (type bignum-index newlen
))
259 (%bignum-set-length bignum newlen
))
261 ;;; This returns 0 or "-1" depending on whether the bignum is positive. This
262 ;;; is suitable for infinite sign extension to complete additions,
263 ;;; subtractions, negations, etc. This cannot return a -1 represented as
264 ;;; a negative fixnum since it would then have to low zeros.
265 #!-sb-fluid
(declaim (inline %sign-digit
))
266 (defun %sign-digit
(bignum len
)
267 (declare (type bignum-type bignum
)
268 (type bignum-index len
))
269 (%ashr
(%bignum-ref bignum
(1- len
)) (1- digit-size
)))
271 ;;; These take two digit-size quantities and compare or contrast them
272 ;;; without wasting time with incorrect type checking.
273 #!-sb-fluid
(declaim (inline %digit-compare %digit-greater
))
274 (defun %digit-compare
(x y
)
276 (defun %digit-greater
(x y
)
279 (declaim (optimize (speed 3) (safety 0)))
283 (defun add-bignums (a b
)
284 (declare (type bignum-type a b
))
285 (let ((len-a (%bignum-length a
))
286 (len-b (%bignum-length b
)))
287 (declare (type bignum-index len-a len-b
))
288 (multiple-value-bind (a len-a b len-b
)
290 (values a len-a b len-b
)
291 (values b len-b a len-a
))
292 (declare (type bignum-type a b
)
293 (type bignum-index len-a len-b
))
294 (let* ((len-res (1+ len-a
))
295 (res (%allocate-bignum len-res
))
297 (declare (type bignum-index len-res
)
298 (type bignum-type res
)
299 (type (mod 2) carry
))
301 (declare (type bignum-index i
))
302 (multiple-value-bind (v k
)
303 (%add-with-carry
(%bignum-ref a i
) (%bignum-ref b i
) carry
)
304 (declare (type bignum-element-type v
)
306 (setf (%bignum-ref res i
) v
)
309 (finish-add a res carry
(%sign-digit b len-b
) len-b len-a
)
310 (setf (%bignum-ref res len-a
)
311 (%add-with-carry
(%sign-digit a len-a
)
312 (%sign-digit b len-b
)
314 (%normalize-bignum res len-res
)))))
316 ;;; This takes the longer of two bignums and propagates the carry through its
317 ;;; remaining high order digits.
318 (defun finish-add (a res carry sign-digit-b start end
)
319 (declare (type bignum-type a res
)
321 (type bignum-element-type sign-digit-b
)
322 (type bignum-index start end
))
323 (do ((i start
(1+ i
)))
325 (setf (%bignum-ref res end
)
326 (%add-with-carry
(%sign-digit a end
) sign-digit-b carry
)))
327 (declare (type bignum-index i
))
328 (multiple-value-bind (v k
)
329 (%add-with-carry
(%bignum-ref a i
) sign-digit-b carry
)
330 (setf (%bignum-ref res i
) v
)
336 (eval-when (:compile-toplevel
:execute
)
338 ;;; This subtracts b from a plugging result into res. Return-fun is the
339 ;;; function to call that fixes up the result returning any useful values, such
340 ;;; as the result. This macro may evaluate its arguments more than once.
341 (sb!xc
:defmacro subtract-bignum-loop
(a len-a b len-b res len-res return-fun
)
342 (let ((borrow (gensym))
351 (,a-sign
(%sign-digit
,a
,len-a
))
352 (,b-sign
(%sign-digit
,b
,len-b
)))
353 (declare (type bignum-element-type
,a-sign
,b-sign
))
354 (dotimes (,i
,len-res
)
355 (declare (type bignum-index
,i
))
356 (let ((,a-digit
(if (< ,i
,len-a
) (%bignum-ref
,a
,i
) ,a-sign
))
357 (,b-digit
(if (< ,i
,len-b
) (%bignum-ref
,b
,i
) ,b-sign
)))
358 (declare (type bignum-element-type
,a-digit
,b-digit
))
359 (multiple-value-bind (,v
,k
)
360 (%subtract-with-borrow
,a-digit
,b-digit
,borrow
)
361 (setf (%bignum-ref
,res
,i
) ,v
)
363 (,return-fun
,res
,len-res
))))
367 (defun subtract-bignum (a b
)
368 (declare (type bignum-type a b
))
369 (let* ((len-a (%bignum-length a
))
370 (len-b (%bignum-length b
))
371 (len-res (1+ (max len-a len-b
)))
372 (res (%allocate-bignum len-res
)))
373 (declare (type bignum-index len-a len-b len-res
)) ;Test len-res for bounds?
374 (subtract-bignum-loop a len-a b len-b res len-res %normalize-bignum
)))
376 ;;; Operations requiring a subtraction without the overhead of intermediate
377 ;;; results, such as GCD, use this. It assumes Result is big enough for the
379 (defun subtract-bignum-buffers-with-len (a len-a b len-b result len-res
)
380 (declare (type bignum-type a b result
)
381 (type bignum-index len-a len-b len-res
))
382 (subtract-bignum-loop a len-a b len-b result len-res
383 %normalize-bignum-buffer
))
385 (defun subtract-bignum-buffers (a len-a b len-b result
)
386 (declare (type bignum-type a b result
)
387 (type bignum-index len-a len-b
))
388 (subtract-bignum-loop a len-a b len-b result
(max len-a len-b
)
389 %normalize-bignum-buffer
))
393 (defun multiply-bignums (a b
)
394 (declare (type bignum-type a b
))
395 (let* ((a-plusp (%bignum-0-or-plusp a
(%bignum-length a
)))
396 (b-plusp (%bignum-0-or-plusp b
(%bignum-length b
)))
397 (a (if a-plusp a
(negate-bignum a
)))
398 (b (if b-plusp b
(negate-bignum b
)))
399 (len-a (%bignum-length a
))
400 (len-b (%bignum-length b
))
401 (len-res (+ len-a len-b
))
402 (res (%allocate-bignum len-res
))
403 (negate-res (not (eq a-plusp b-plusp
))))
404 (declare (type bignum-index len-a len-b len-res
))
406 (declare (type bignum-index i
))
407 (let ((carry-digit 0)
408 (x (%bignum-ref a i
))
410 (declare (type bignum-index k
)
411 (type bignum-element-type carry-digit x
))
413 (multiple-value-bind (big-carry res-digit
)
418 (declare (type bignum-element-type big-carry res-digit
))
419 (setf (%bignum-ref res k
) res-digit
)
420 (setf carry-digit big-carry
)
422 (setf (%bignum-ref res k
) carry-digit
)))
423 (when negate-res
(negate-bignum-in-place res
))
424 (%normalize-bignum res len-res
)))
426 (defun multiply-bignum-and-fixnum (bignum fixnum
)
427 (declare (type bignum-type bignum
) (type fixnum fixnum
))
428 (let* ((bignum-plus-p (%bignum-0-or-plusp bignum
(%bignum-length bignum
)))
429 (fixnum-plus-p (not (minusp fixnum
)))
430 (bignum (if bignum-plus-p bignum
(negate-bignum bignum
)))
431 (bignum-len (%bignum-length bignum
))
432 (fixnum (if fixnum-plus-p fixnum
(- fixnum
)))
433 (result (%allocate-bignum
(1+ bignum-len
)))
435 (declare (type bignum-type bignum result
)
436 (type bignum-index bignum-len
)
437 (type bignum-element-type fixnum carry-digit
))
438 (dotimes (index bignum-len
)
439 (declare (type bignum-index index
))
440 (multiple-value-bind (next-digit low
)
441 (%multiply-and-add
(%bignum-ref bignum index
) fixnum carry-digit
)
442 (declare (type bignum-element-type next-digit low
))
443 (setf carry-digit next-digit
)
444 (setf (%bignum-ref result index
) low
)))
445 (setf (%bignum-ref result bignum-len
) carry-digit
)
446 (unless (eq bignum-plus-p fixnum-plus-p
)
447 (negate-bignum-in-place result
))
448 (%normalize-bignum result
(1+ bignum-len
))))
450 (defun multiply-fixnums (a b
)
451 (declare (fixnum a b
))
452 (let* ((a-minusp (minusp a
))
453 (b-minusp (minusp b
)))
454 (multiple-value-bind (high low
)
455 (%multiply
(if a-minusp
(- a
) a
)
456 (if b-minusp
(- b
) b
))
457 (declare (type bignum-element-type high low
))
458 (if (and (zerop high
)
459 (%digit-0-or-plusp low
))
460 (let ((low (sb!ext
:truly-the
(unsigned-byte #.
(1- sb
!vm
:n-word-bits
))
461 (%fixnum-digit-with-correct-sign low
))))
462 (if (eq a-minusp b-minusp
)
465 (let ((res (%allocate-bignum
2)))
466 (%bignum-set res
0 low
)
467 (%bignum-set res
1 high
)
468 (unless (eq a-minusp b-minusp
) (negate-bignum-in-place res
))
469 (%normalize-bignum res
2))))))
471 ;;;; BIGNUM-REPLACE and WITH-BIGNUM-BUFFERS
473 (eval-when (:compile-toplevel
:execute
)
475 (sb!xc
:defmacro bignum-replace
(dest
483 (sb!int
:once-only
((n-dest dest
)
485 (let ((n-start1 (gensym))
491 (end1 (or end1
`(%bignum-length
,n-dest
)))
492 (end2 (or end2
`(%bignum-length
,n-src
))))
494 `(let ((,n-start1
,start1
)
496 (do ((,i1
(1- ,end1
) (1- ,i1
))
497 (,i2
(1- ,end2
) (1- ,i2
)))
498 ((or (< ,i1
,n-start1
) (< ,i2
,n-start2
)))
499 (declare (fixnum ,i1
,i2
))
500 (%bignum-set
,n-dest
,i1
501 (%bignum-ref
,n-src
,i2
))))
502 (if (eql start1 start2
)
503 `(let ((,n-end1
(min ,end1
,end2
)))
504 (do ((,i1
,start1
(1+ ,i1
)))
506 (declare (type bignum-index
,i1
))
507 (%bignum-set
,n-dest
,i1
508 (%bignum-ref
,n-src
,i1
))))
509 `(let ((,n-end1
,end1
)
511 (do ((,i1
,start1
(1+ ,i1
))
512 (,i2
,start2
(1+ ,i2
)))
513 ((or (>= ,i1
,n-end1
) (>= ,i2
,n-end2
)))
514 (declare (type bignum-index
,i1
,i2
))
515 (%bignum-set
,n-dest
,i1
516 (%bignum-ref
,n-src
,i2
)))))))))
518 (sb!xc
:defmacro with-bignum-buffers
(specs &body body
)
520 "WITH-BIGNUM-BUFFERS ({(var size [init])}*) Form*"
521 (sb!int
:collect
((binds)
524 (let ((name (first spec
))
525 (size (second spec
)))
526 (binds `(,name
(%allocate-bignum
,size
)))
527 (let ((init (third spec
)))
529 (inits `(bignum-replace ,name
,init
))))))
538 (eval-when (:compile-toplevel
:load-toplevel
:execute
)
539 ;; The asserts in the GCD implementation are way too expensive to
540 ;; check in normal use, and are disabled here.
541 (sb!xc
:defmacro gcd-assert
(&rest args
)
544 ;; We'll be doing a lot of modular arithmetic.
545 (sb!xc
:defmacro modularly
(form)
546 `(logand all-ones-digit
,form
)))
548 ;;; I'm not sure why I need this FTYPE declaration. Compiled by the
549 ;;; target compiler, it can deduce the return type fine, but without
550 ;;; it, we pay a heavy price in BIGNUM-GCD when compiled by the
551 ;;; cross-compiler. -- CSR, 2004-07-19
552 (declaim (ftype (sfunction (bignum-type bignum-index bignum-type bignum-index
)
553 sb
!vm
::positive-fixnum
)
554 bignum-factors-of-two
))
555 (defun bignum-factors-of-two (a len-a b len-b
)
556 (declare (type bignum-index len-a len-b
) (type bignum-type a b
))
558 (end (min len-a len-b
)))
559 ((= i end
) (error "Unexpected zero bignums?"))
560 (declare (type bignum-index i end
))
561 (let ((or-digits (%logior
(%bignum-ref a i
) (%bignum-ref b i
))))
562 (unless (zerop or-digits
)
563 (return (do ((j 0 (1+ j
))
564 (or-digits or-digits
(%ashr or-digits
1)))
565 ((oddp or-digits
) (+ (* i digit-size
) j
))
566 (declare (type (mod #.sb
!vm
:n-word-bits
) j
))))))))
568 ;;; Multiply a bignum buffer with a fixnum or a digit, storing the
569 ;;; result in another bignum buffer, and without using any
570 ;;; temporaries. Inlined to avoid boxing smallnum if it's actually a
571 ;;; digit. Needed by GCD, should possibly OAOO with
572 ;;; MULTIPLY-BIGNUM-AND-FIXNUM.
573 (declaim (inline multiply-bignum-buffer-and-smallnum-to-buffer
))
574 (defun multiply-bignum-buffer-and-smallnum-to-buffer (bignum bignum-len
576 (declare (type bignum-type bignum
))
577 (let* ((bignum-plus-p (%bignum-0-or-plusp bignum bignum-len
))
578 (smallnum-plus-p (not (minusp smallnum
)))
579 (smallnum (if smallnum-plus-p smallnum
(- smallnum
)))
581 (declare (type bignum-type bignum res
)
582 (type bignum-index bignum-len
)
583 (type bignum-element-type smallnum carry-digit
))
584 (unless bignum-plus-p
585 (negate-bignum-buffer-in-place bignum bignum-len
))
586 (dotimes (index bignum-len
)
587 (declare (type bignum-index index
))
588 (multiple-value-bind (next-digit low
)
589 (%multiply-and-add
(%bignum-ref bignum index
)
592 (declare (type bignum-element-type next-digit low
))
593 (setf carry-digit next-digit
)
594 (setf (%bignum-ref res index
) low
)))
595 (setf (%bignum-ref res bignum-len
) carry-digit
)
596 (unless bignum-plus-p
597 (negate-bignum-buffer-in-place bignum bignum-len
))
598 (let ((res-len (%normalize-bignum-buffer res
(1+ bignum-len
))))
599 (unless (eq bignum-plus-p smallnum-plus-p
)
600 (negate-bignum-buffer-in-place res res-len
))
603 ;;; Given U and V, return U / V mod 2^32. Implements the algorithm in the
604 ;;; paper, but uses some clever bit-twiddling nicked from Nickle to do it.
605 (declaim (inline bmod
))
607 (let ((ud (%bignum-ref u
0))
608 (vd (%bignum-ref v
0))
612 (declare (type (unsigned-byte #.sb
!vm
:n-word-bits
) ud vd umask imask m
))
613 (dotimes (i digit-size
)
614 (setf umask
(logior umask imask
))
615 (when (logtest ud umask
)
616 (setf ud
(modularly (- ud vd
)))
617 (setf m
(modularly (logior m imask
))))
618 (setf imask
(modularly (ash imask
1)))
619 (setf vd
(modularly (ash vd
1))))
622 (defun dmod (u u-len v v-len tmp1
)
623 (loop while
(> (bignum-buffer-integer-length u u-len
)
624 (+ (bignum-buffer-integer-length v v-len
)
627 (unless (zerop (%bignum-ref u
0))
628 (let* ((bmod (bmod u v
))
629 (tmp1-len (multiply-bignum-buffer-and-smallnum-to-buffer v v-len
632 (setf u-len
(subtract-bignum-buffers u u-len
635 (bignum-abs-buffer u u-len
)))
636 (gcd-assert (zerop (%bignum-ref u
0)))
637 (setf u-len
(bignum-buffer-ashift-right u u-len digit-size
)))
638 (let* ((d (+ 1 (- (bignum-buffer-integer-length u u-len
)
639 (bignum-buffer-integer-length v v-len
))))
641 (declare (type (unsigned-byte #.
(integer-length #.sb
!vm
:n-word-bits
)) d
)
642 (type (unsigned-byte #.sb
!vm
:n-word-bits
) n
))
643 (gcd-assert (>= d
0))
644 (when (logtest (%bignum-ref u
0) n
)
646 (multiply-bignum-buffer-and-smallnum-to-buffer v v-len
650 (setf u-len
(subtract-bignum-buffers u u-len
653 (bignum-abs-buffer u u-len
)))
656 (defconstant lower-ones-digit
(1- (ash 1 (truncate sb
!vm
:n-word-bits
2))))
658 ;;; Find D and N such that (LOGAND ALL-ONES-DIGIT (- (* D X) (* N Y))) is 0,
659 ;;; (< 0 N LOWER-ONES-DIGIT) and (< 0 (ABS D) LOWER-ONES-DIGIT).
660 (defun reduced-ratio-mod (x y
)
661 (let* ((c (bmod x y
))
664 (n2 (modularly (1+ (modularly (lognot n1
)))))
666 (declare (type (unsigned-byte #.sb
!vm
:n-word-bits
) n1 d1 n2 d2
))
667 (loop while
(> n2
(expt 2 (truncate digit-size
2))) do
668 (loop for i of-type
(mod #.sb
!vm
:n-word-bits
)
669 downfrom
(- (integer-length n1
) (integer-length n2
))
671 (when (>= n1
(modularly (ash n2 i
)))
672 (psetf n1
(modularly (- n1
(modularly (ash n2 i
))))
673 d1
(modularly (- d1
(modularly (ash d2 i
)))))))
678 (values n2
(if (>= d2
(expt 2 (1- digit-size
)))
679 (lognot (logand most-positive-fixnum
(lognot d2
)))
680 (logand lower-ones-digit d2
)))))
683 (defun copy-bignum (a &optional
(len (%bignum-length a
)))
684 (let ((b (%allocate-bignum len
)))
686 (%bignum-set-length b len
)
689 ;;; Allocate a single word bignum that holds fixnum. This is useful when
690 ;;; we are trying to mix fixnum and bignum operands.
691 #!-sb-fluid
(declaim (inline make-small-bignum
))
692 (defun make-small-bignum (fixnum)
693 (let ((res (%allocate-bignum
1)))
694 (setf (%bignum-ref res
0) (%fixnum-to-digit fixnum
))
697 ;; When the larger number is less than this many bignum digits long, revert
699 (defparameter *accelerated-gcd-cutoff
* 3)
701 ;;; Alternate between k-ary reduction with the help of
702 ;;; REDUCED-RATIO-MOD and digit modulus reduction via DMOD. Once the
703 ;;; arguments get small enough, drop through to BIGNUM-MOD-GCD (since
704 ;;; k-ary reduction can introduce spurious factors, which need to be
705 ;;; filtered out). Reference: Kenneth Weber, "The accelerated integer
706 ;;; GCD algorithm", ACM Transactions on Mathematical Software, volume
707 ;;; 21, number 1, March 1995, epp. 111-122.
708 (defun bignum-gcd (u0 v0
)
709 (declare (type bignum-type u0 v0
))
710 (let* ((u1 (if (%bignum-0-or-plusp u0
(%bignum-length u0
))
712 (negate-bignum u0 nil
)))
713 (v1 (if (%bignum-0-or-plusp v0
(%bignum-length v0
))
715 (negate-bignum v0 nil
))))
717 (return-from bignum-gcd u1
))
720 (let ((n (mod v1 u1
)))
721 (setf v1
(if (fixnump n
)
722 (make-small-bignum n
)
724 (if (and (= 1 (%bignum-length v1
))
725 (zerop (%bignum-ref v1
0)))
726 (return-from bignum-gcd
(%normalize-bignum u1
727 (%bignum-length u1
))))
728 (let* ((buffer-len (+ 2 (%bignum-length u1
)))
729 (u (%allocate-bignum buffer-len
))
730 (u-len (%bignum-length u1
))
731 (v (%allocate-bignum buffer-len
))
732 (v-len (%bignum-length v1
))
733 (tmp1 (%allocate-bignum buffer-len
))
735 (tmp2 (%allocate-bignum buffer-len
))
738 (bignum-factors-of-two u1
(%bignum-length u1
)
739 v1
(%bignum-length v1
))))
740 (declare (type (or null bignum-index
)
741 buffer-len u-len v-len tmp1-len tmp2-len
))
742 (bignum-replace u u1
)
743 (bignum-replace v v1
)
745 (make-gcd-bignum-odd u
746 (bignum-buffer-ashift-right u u-len
749 (make-gcd-bignum-odd v
750 (bignum-buffer-ashift-right v v-len
752 (loop until
(or (< u-len
*accelerated-gcd-cutoff
*)
756 (zerop (%bignum-ref v
0))))
758 (gcd-assert (= buffer-len
(%bignum-length u
)
760 (%bignum-length tmp1
)
761 (%bignum-length tmp2
)))
762 (if (> (bignum-buffer-integer-length u u-len
)
763 (+ #.
(truncate sb
!vm
:n-word-bits
4)
764 (bignum-buffer-integer-length v v-len
)))
765 (setf u-len
(dmod u u-len
768 (multiple-value-bind (n d
) (reduced-ratio-mod u v
)
770 (multiply-bignum-buffer-and-smallnum-to-buffer v v-len
773 (multiply-bignum-buffer-and-smallnum-to-buffer u u-len
775 (gcd-assert (= (copy-bignum tmp2 tmp2-len
)
776 (* (copy-bignum u u-len
) d
)))
777 (gcd-assert (= (copy-bignum tmp1 tmp1-len
)
778 (* (copy-bignum v v-len
) n
)))
780 (subtract-bignum-buffers-with-len tmp1 tmp1-len
785 (gcd-assert (or (zerop (- (copy-bignum tmp1 tmp1-len
)
786 (copy-bignum tmp2 tmp2-len
)))
787 (= (copy-bignum u u-len
)
788 (- (copy-bignum tmp1 tmp1-len
)
789 (copy-bignum tmp2 tmp2-len
)))))
790 (bignum-abs-buffer u u-len
)
791 (gcd-assert (zerop (modularly u
)))))
792 (setf u-len
(make-gcd-bignum-odd u u-len
))
794 (rotatef u-len v-len
))
795 (setf u
(copy-bignum u u-len
))
796 (let ((n (bignum-mod-gcd v1 u
)))
797 (ash (bignum-mod-gcd u1
(if (fixnump n
)
798 (make-small-bignum n
)
802 (defun bignum-mod-gcd (a b
)
803 (declare (type bignum-type a b
))
806 ;; While the length difference of A and B is sufficiently large,
807 ;; reduce using MOD (slowish, but it should equalize the sizes of
808 ;; A and B pretty quickly). After that, use the binary GCD
809 ;; algorithm to handle the rest.
810 (loop until
(and (= (%bignum-length b
) 1) (zerop (%bignum-ref b
0))) do
811 (when (<= (%bignum-length a
) (1+ (%bignum-length b
)))
812 (return-from bignum-mod-gcd
(bignum-binary-gcd a b
)))
813 (let ((rem (mod a b
)))
815 (setf a
(make-small-bignum rem
))
818 (if (= (%bignum-length a
) 1)
819 (%normalize-bignum a
1)
822 (defun bignum-binary-gcd (a b
)
823 (declare (type bignum-type a b
))
824 (let* ((len-a (%bignum-length a
))
825 (len-b (%bignum-length b
)))
826 (declare (type bignum-index len-a len-b
))
827 (with-bignum-buffers ((a-buffer len-a a
)
829 (res-buffer (max len-a len-b
)))
830 (let* ((factors-of-two
831 (bignum-factors-of-two a-buffer len-a
833 (len-a (make-gcd-bignum-odd
835 (bignum-buffer-ashift-right a-buffer len-a
837 (len-b (make-gcd-bignum-odd
839 (bignum-buffer-ashift-right b-buffer len-b
841 (declare (type bignum-index len-a len-b
))
848 (multiple-value-bind (u v len-v r len-r
)
849 (bignum-gcd-order-and-subtract x len-x y len-y z
)
850 (declare (type bignum-index len-v len-r
))
851 (when (and (= len-r
1) (zerop (%bignum-ref r
0)))
852 (if (zerop factors-of-two
)
853 (let ((ret (%allocate-bignum len-v
)))
855 (setf (%bignum-ref ret i
) (%bignum-ref v i
)))
856 (return (%normalize-bignum ret len-v
)))
857 (return (bignum-ashift-left v factors-of-two len-v
))))
858 (setf x v len-x len-v
)
859 (setf y r len-y
(make-gcd-bignum-odd r len-r
))
862 (defun bignum-gcd-order-and-subtract (a len-a b len-b res
)
863 (declare (type bignum-index len-a len-b
) (type bignum-type a b
))
864 (cond ((= len-a len-b
)
865 (do ((i (1- len-a
) (1- i
)))
867 (setf (%bignum-ref res
0) 0)
868 (values a b len-b res
1))
869 (let ((a-digit (%bignum-ref a i
))
870 (b-digit (%bignum-ref b i
)))
871 (cond ((%digit-compare a-digit b-digit
))
872 ((%digit-greater a-digit b-digit
)
874 (values a b len-b res
875 (subtract-bignum-buffers a len-a b len-b
879 (values b a len-a res
880 (subtract-bignum-buffers b len-b
884 (values a b len-b res
885 (subtract-bignum-buffers a len-a b len-b res
)))
887 (values b a len-a res
888 (subtract-bignum-buffers b len-b a len-a res
)))))
890 (defun make-gcd-bignum-odd (a len-a
)
891 (declare (type bignum-type a
) (type bignum-index len-a
))
892 (dotimes (index len-a
)
893 (declare (type bignum-index index
))
894 (do ((digit (%bignum-ref a index
) (%ashr digit
1))
895 (increment 0 (1+ increment
)))
897 (declare (type (mod #.sb
!vm
:n-word-bits
) increment
))
899 (return-from make-gcd-bignum-odd
900 (bignum-buffer-ashift-right a len-a
901 (+ (* index digit-size
)
907 (eval-when (:compile-toplevel
:execute
)
909 ;;; This negates bignum-len digits of bignum, storing the resulting digits into
910 ;;; result (possibly EQ to bignum) and returning whatever end-carry there is.
911 (sb!xc
:defmacro bignum-negate-loop
(bignum
913 &optional
(result nil resultp
))
914 (let ((carry (gensym))
918 `(let* (,@(if (not resultp
) `(,last
))
920 (multiple-value-bind (,value
,carry
)
921 (%add-with-carry
(%lognot
(%bignum-ref
,bignum
0)) 1 0)
923 `(setf (%bignum-ref
,result
0) ,value
)
924 `(setf ,last
,value
))
928 (declare (type bit
,carry
)
929 (type bignum-index i
,end
))
931 (when (= i
,end
) (return))
932 (multiple-value-bind (,value temp
)
933 (%add-with-carry
(%lognot
(%bignum-ref
,bignum i
)) 0 ,carry
)
935 `(setf (%bignum-ref
,result i
) ,value
)
936 `(setf ,last
,value
))
939 ,(if resultp carry
`(values ,carry
,last
)))))
943 ;;; Fully-normalize is an internal optional. It cause this to always return
944 ;;; a bignum, without any extraneous digits, and it never returns a fixnum.
945 (defun negate-bignum (x &optional
(fully-normalize t
))
946 (declare (type bignum-type x
))
947 (let* ((len-x (%bignum-length x
))
949 (res (%allocate-bignum len-res
)))
950 (declare (type bignum-index len-x len-res
)) ;Test len-res for range?
951 (let ((carry (bignum-negate-loop x len-x res
)))
952 (setf (%bignum-ref res len-x
)
953 (%add-with-carry
(%lognot
(%sign-digit x len-x
)) 0 carry
)))
955 (%normalize-bignum res len-res
)
956 (%mostly-normalize-bignum res len-res
))))
958 ;;; This assumes bignum is positive; that is, the result of negating it will
959 ;;; stay in the provided allocated bignum.
960 (defun negate-bignum-buffer-in-place (bignum bignum-len
)
961 (bignum-negate-loop bignum bignum-len bignum
)
964 (defun negate-bignum-in-place (bignum)
965 (declare (inline negate-bignum-buffer-in-place
))
966 (negate-bignum-buffer-in-place bignum
(%bignum-length bignum
)))
968 (defun bignum-abs-buffer (bignum len
)
969 (unless (%bignum-0-or-plusp bignum len
)
970 (negate-bignum-buffer-in-place bignum len
)))
974 (eval-when (:compile-toplevel
:execute
)
976 ;;; This macro is used by BIGNUM-ASHIFT-RIGHT, BIGNUM-BUFFER-ASHIFT-RIGHT, and
977 ;;; BIGNUM-LDB-BIGNUM-RES. They supply a termination form that references
978 ;;; locals established by this form. Source is the source bignum. Start-digit
979 ;;; is the first digit in source from which we pull bits. Start-pos is the
980 ;;; first bit we want. Res-len-form is the form that computes the length of
981 ;;; the resulting bignum. Termination is a DO termination form with a test and
982 ;;; body. When result is supplied, it is the variable to which this binds a
983 ;;; newly allocated bignum.
985 ;;; Given start-pos, 1-31 inclusively, of shift, we form the j'th resulting
986 ;;; digit from high bits of the i'th source digit and the start-pos number of
987 ;;; bits from the i+1'th source digit.
988 (sb!xc
:defmacro shift-right-unaligned
(source
994 `(let* ((high-bits-in-first-digit (- digit-size
,start-pos
))
995 (res-len ,res-len-form
)
996 (res-len-1 (1- res-len
))
997 ,@(if result
`((,result
(%allocate-bignum res-len
)))))
998 (declare (type bignum-index res-len res-len-1
))
999 (do ((i ,start-digit
(1+ i
))
1002 (declare (type bignum-index i j
))
1003 (setf (%bignum-ref
,(if result result source
) j
)
1004 (%logior
(%digit-logical-shift-right
(%bignum-ref
,source i
)
1006 (%ashl
(%bignum-ref
,source
(1+ i
))
1007 high-bits-in-first-digit
))))))
1011 ;;; First compute the number of whole digits to shift, shifting them by
1012 ;;; skipping them when we start to pick up bits, and the number of bits to
1013 ;;; shift the remaining digits into place. If the number of digits is greater
1014 ;;; than the length of the bignum, then the result is either 0 or -1. If we
1015 ;;; shift on a digit boundary (that is, n-bits is zero), then we just copy
1016 ;;; digits. The last branch handles the general case which uses a macro that a
1017 ;;; couple other routines use. The fifth argument to the macro references
1018 ;;; locals established by the macro.
1019 (defun bignum-ashift-right (bignum count
)
1020 (declare (type bignum-type bignum
)
1021 (type unsigned-byte count
))
1022 (let ((bignum-len (%bignum-length bignum
)))
1023 (declare (type bignum-index bignum-len
))
1024 (cond ((fixnump count
)
1025 (multiple-value-bind (digits n-bits
) (truncate count digit-size
)
1026 (declare (type bignum-index digits
))
1028 ((>= digits bignum-len
)
1029 (if (%bignum-0-or-plusp bignum bignum-len
) 0 -
1))
1031 (bignum-ashift-right-digits bignum digits
))
1033 (shift-right-unaligned bignum digits n-bits
(- bignum-len digits
)
1035 (setf (%bignum-ref res j
)
1036 (%ashr
(%bignum-ref bignum i
) n-bits
))
1037 (%normalize-bignum res res-len
))
1039 ((> count bignum-len
)
1040 (if (%bignum-0-or-plusp bignum bignum-len
) 0 -
1))
1041 ;; Since a FIXNUM should be big enough to address anything in
1042 ;; memory, including arrays of bits, and since arrays of bits
1043 ;; take up about the same space as corresponding fixnums, there
1044 ;; should be no way that we fall through to this case: any shift
1045 ;; right by a bignum should give zero. But let's check anyway:
1046 (t (error "bignum overflow: can't shift right by ~S" count
)))))
1048 (defun bignum-ashift-right-digits (bignum digits
)
1049 (declare (type bignum-type bignum
)
1050 (type bignum-index digits
))
1051 (let* ((res-len (- (%bignum-length bignum
) digits
))
1052 (res (%allocate-bignum res-len
)))
1053 (declare (type bignum-index res-len
)
1054 (type bignum-type res
))
1055 (bignum-replace res bignum
:start2 digits
)
1056 (%normalize-bignum res res-len
)))
1058 ;;; GCD uses this for an in-place shifting operation. This is different enough
1059 ;;; from BIGNUM-ASHIFT-RIGHT that it isn't worth folding the bodies into a
1060 ;;; macro, but they share the basic algorithm. This routine foregoes a first
1061 ;;; test for digits being greater than or equal to bignum-len since that will
1062 ;;; never happen for its uses in GCD. We did fold the last branch into a macro
1063 ;;; since it was duplicated a few times, and the fifth argument to it
1064 ;;; references locals established by the macro.
1065 (defun bignum-buffer-ashift-right (bignum bignum-len x
)
1066 (declare (type bignum-index bignum-len
) (fixnum x
))
1067 (multiple-value-bind (digits n-bits
) (truncate x digit-size
)
1068 (declare (type bignum-index digits
))
1071 (let ((new-end (- bignum-len digits
)))
1072 (bignum-replace bignum bignum
:end1 new-end
:start2 digits
1074 (%normalize-bignum-buffer bignum new-end
)))
1076 (shift-right-unaligned bignum digits n-bits
(- bignum-len digits
)
1078 (setf (%bignum-ref bignum j
)
1079 (%ashr
(%bignum-ref bignum i
) n-bits
))
1080 (%normalize-bignum-buffer bignum res-len
)))))))
1082 ;;; This handles shifting a bignum buffer to provide fresh bignum data for some
1083 ;;; internal routines. We know bignum is safe when called with bignum-len.
1084 ;;; First we compute the number of whole digits to shift, shifting them
1085 ;;; starting to store farther along the result bignum. If we shift on a digit
1086 ;;; boundary (that is, n-bits is zero), then we just copy digits. The last
1087 ;;; branch handles the general case.
1088 (defun bignum-ashift-left (bignum x
&optional bignum-len
)
1089 (declare (type bignum-type bignum
)
1090 (type unsigned-byte x
)
1091 (type (or null bignum-index
) bignum-len
))
1093 (multiple-value-bind (digits n-bits
) (truncate x digit-size
)
1094 (let* ((bignum-len (or bignum-len
(%bignum-length bignum
)))
1095 (res-len (+ digits bignum-len
1)))
1096 (when (> res-len maximum-bignum-length
)
1097 (error "can't represent result of left shift"))
1099 (bignum-ashift-left-digits bignum bignum-len digits
)
1100 (bignum-ashift-left-unaligned bignum digits n-bits res-len
))))
1101 ;; Left shift by a number too big to be represented as a fixnum
1102 ;; would exceed our memory capacity, since a fixnum is big enough
1103 ;; to index any array, including a bit array.
1104 (error "can't represent result of left shift")))
1106 (defun bignum-ashift-left-digits (bignum bignum-len digits
)
1107 (declare (type bignum-index bignum-len digits
))
1108 (let* ((res-len (+ bignum-len digits
))
1109 (res (%allocate-bignum res-len
)))
1110 (declare (type bignum-index res-len
))
1111 (bignum-replace res bignum
:start1 digits
:end1 res-len
:end2 bignum-len
1115 ;;; BIGNUM-TRUNCATE uses this to store into a bignum buffer by supplying res.
1116 ;;; When res comes in non-nil, then this foregoes allocating a result, and it
1117 ;;; normalizes the buffer instead of the would-be allocated result.
1119 ;;; We start storing into one digit higher than digits, storing a whole result
1120 ;;; digit from parts of two contiguous digits from bignum. When the loop
1121 ;;; finishes, we store the remaining bits from bignum's first digit in the
1122 ;;; first non-zero result digit, digits. We also grab some left over high
1123 ;;; bits from the last digit of bignum.
1124 (defun bignum-ashift-left-unaligned (bignum digits n-bits res-len
1125 &optional
(res nil resp
))
1126 (declare (type bignum-index digits res-len
)
1127 (type (mod #.digit-size
) n-bits
))
1128 (let* ((remaining-bits (- digit-size n-bits
))
1129 (res-len-1 (1- res-len
))
1130 (res (or res
(%allocate-bignum res-len
))))
1131 (declare (type bignum-index res-len res-len-1
))
1133 (j (1+ digits
) (1+ j
)))
1135 (setf (%bignum-ref res digits
)
1136 (%ashl
(%bignum-ref bignum
0) n-bits
))
1137 (setf (%bignum-ref res j
)
1138 (%ashr
(%bignum-ref bignum i
) remaining-bits
))
1140 (%normalize-bignum-buffer res res-len
)
1141 (%normalize-bignum res res-len
)))
1142 (declare (type bignum-index i j
))
1143 (setf (%bignum-ref res j
)
1144 (%logior
(%digit-logical-shift-right
(%bignum-ref bignum i
)
1146 (%ashl
(%bignum-ref bignum
(1+ i
)) n-bits
))))))
1148 ;;;; relational operators
1150 ;;; Return T iff bignum is positive.
1151 (defun bignum-plus-p (bignum)
1152 (declare (type bignum-type bignum
))
1153 (%bignum-0-or-plusp bignum
(%bignum-length bignum
)))
1155 ;;; This compares two bignums returning -1, 0, or 1, depending on
1156 ;;; whether a is less than, equal to, or greater than b.
1157 (declaim (ftype (function (bignum bignum
) (integer -
1 1)) bignum-compare
))
1158 (defun bignum-compare (a b
)
1159 (declare (type bignum-type a b
))
1160 (let* ((len-a (%bignum-length a
))
1161 (len-b (%bignum-length b
))
1162 (a-plusp (%bignum-0-or-plusp a len-a
))
1163 (b-plusp (%bignum-0-or-plusp b len-b
)))
1164 (declare (type bignum-index len-a len-b
))
1165 (cond ((not (eq a-plusp b-plusp
))
1168 (do ((i (1- len-a
) (1- i
)))
1170 (declare (type bignum-index i
))
1171 (let ((a-digit (%bignum-ref a i
))
1172 (b-digit (%bignum-ref b i
)))
1173 (declare (type bignum-element-type a-digit b-digit
))
1174 (when (%digit-greater a-digit b-digit
)
1176 (when (%digit-greater b-digit a-digit
)
1178 (when (zerop i
) (return 0))))
1181 (t (if a-plusp -
1 1)))))
1183 ;;;; float conversion
1185 ;;; Make a single or double float with the specified significand,
1186 ;;; exponent and sign.
1187 (defun single-float-from-bits (bits exp plusp
)
1188 (declare (fixnum exp
))
1189 (declare (optimize #-sb-xc-host
(sb!ext
:inhibit-warnings
3)))
1191 sb
!vm
:single-float-exponent-byte
1192 (logandc2 (logand #xffffffff
1193 (%bignum-ref bits
1))
1194 sb
!vm
:single-float-hidden-bit
))))
1198 (logior res
(ash -
1 sb
!vm
:float-sign-shift
))))))
1199 (defun double-float-from-bits (bits exp plusp
)
1200 (declare (fixnum exp
))
1201 (declare (optimize #-sb-xc-host
(sb!ext
:inhibit-warnings
3)))
1203 sb
!vm
:double-float-exponent-byte
1204 (logandc2 (ecase sb
!vm
::n-word-bits
1205 (32 (%bignum-ref bits
2))
1206 (64 (ash (%bignum-ref bits
1) -
32)))
1207 sb
!vm
:double-float-hidden-bit
)))
1208 (lo (logand #xffffffff
(%bignum-ref bits
1))))
1209 (make-double-float (if plusp
1211 (logior hi
(ash -
1 sb
!vm
:float-sign-shift
)))
1213 #!+(and long-float x86
)
1214 (defun long-float-from-bits (bits exp plusp
)
1215 (declare (fixnum exp
))
1216 (declare (optimize #-sb-xc-host
(sb!ext
:inhibit-warnings
3)))
1220 (logior exp
(ash 1 15)))
1221 (%bignum-ref bits
2)
1222 (%bignum-ref bits
1)))
1224 ;;; Convert Bignum to a float in the specified Format, rounding to the best
1226 (defun bignum-to-float (bignum format
)
1227 (let* ((plusp (bignum-plus-p bignum
))
1228 (x (if plusp bignum
(negate-bignum bignum
)))
1229 (len (bignum-integer-length x
))
1230 (digits (float-format-digits format
))
1231 (keep (+ digits digit-size
))
1232 (shift (- keep len
))
1233 (shifted (if (minusp shift
)
1234 (bignum-ashift-right x
(- shift
))
1235 (bignum-ashift-left x shift
)))
1236 (low (%bignum-ref shifted
0))
1237 (round-bit (ash 1 (1- digit-size
))))
1238 (declare (type bignum-index len digits keep
) (fixnum shift
))
1239 (labels ((round-up ()
1240 (let ((rounded (add-bignums shifted round-bit
)))
1241 (if (> (integer-length rounded
) keep
)
1242 (float-from-bits (bignum-ashift-right rounded
1)
1244 (float-from-bits rounded len
))))
1245 (float-from-bits (bits len
)
1246 (declare (type bignum-index len
))
1249 (single-float-from-bits
1251 (check-exponent len sb
!vm
:single-float-bias
1252 sb
!vm
:single-float-normal-exponent-max
)
1255 (double-float-from-bits
1257 (check-exponent len sb
!vm
:double-float-bias
1258 sb
!vm
:double-float-normal-exponent-max
)
1262 (long-float-from-bits
1264 (check-exponent len sb
!vm
:long-float-bias
1265 sb
!vm
:long-float-normal-exponent-max
)
1267 (check-exponent (exp bias max
)
1268 (declare (type bignum-index len
))
1269 (let ((exp (+ exp bias
)))
1271 ;; Why a SIMPLE-TYPE-ERROR? Well, this is mainly
1272 ;; called by COERCE, which requires an error of
1273 ;; TYPE-ERROR if the conversion can't happen
1274 ;; (except in certain circumstances when we are
1275 ;; coercing to a FUNCTION) -- CSR, 2002-09-18
1276 (error 'simple-type-error
1277 :format-control
"Too large to be represented as a ~S:~% ~S"
1278 :format-arguments
(list format x
)
1279 :expected-type format
1284 ;; Round down if round bit is 0.
1285 ((not (logtest round-bit low
))
1286 (float-from-bits shifted len
))
1287 ;; If only round bit is set, then round to even.
1288 ((and (= low round-bit
)
1289 (dotimes (i (- (%bignum-length x
) (ceiling keep digit-size
))
1291 (unless (zerop (%bignum-ref x i
)) (return nil
))))
1292 (let ((next (%bignum-ref shifted
1)))
1295 (float-from-bits shifted len
))))
1296 ;; Otherwise, round up.
1300 ;;;; integer length and logbitp/logcount
1302 (defun bignum-buffer-integer-length (bignum len
)
1303 (declare (type bignum-type bignum
))
1304 (let* ((len-1 (1- len
))
1305 (digit (%bignum-ref bignum len-1
)))
1306 (declare (type bignum-index len len-1
)
1307 (type bignum-element-type digit
))
1308 (+ (integer-length (%fixnum-digit-with-correct-sign digit
))
1309 (* len-1 digit-size
))))
1311 (defun bignum-integer-length (bignum)
1312 (declare (type bignum-type bignum
))
1313 (bignum-buffer-integer-length bignum
(%bignum-length bignum
)))
1315 (defun bignum-logbitp (index bignum
)
1316 (declare (type bignum-type bignum
))
1317 (let ((len (%bignum-length bignum
)))
1318 (declare (type bignum-index len
))
1319 (multiple-value-bind (word-index bit-index
)
1320 (floor index digit-size
)
1321 (if (>= word-index len
)
1322 (not (bignum-plus-p bignum
))
1323 (logbitp bit-index
(%bignum-ref bignum word-index
))))))
1325 (defun bignum-logcount (bignum)
1326 (declare (type bignum-type bignum
))
1327 (let ((length (%bignum-length bignum
))
1329 (declare (type bignum-index length
)
1331 (do ((index 0 (1+ index
)))
1333 (if (%bignum-0-or-plusp bignum length
)
1335 (- (* length digit-size
) result
)))
1336 (let ((digit (%bignum-ref bignum index
)))
1337 (declare (type bignum-element-type digit
))
1338 (incf result
(logcount digit
))))))
1340 ;;;; logical operations
1344 (defun bignum-logical-not (a)
1345 (declare (type bignum-type a
))
1346 (let* ((len (%bignum-length a
))
1347 (res (%allocate-bignum len
)))
1348 (declare (type bignum-index len
))
1349 (dotimes (i len res
)
1350 (declare (type bignum-index i
))
1351 (setf (%bignum-ref res i
) (%lognot
(%bignum-ref a i
))))))
1355 (defun bignum-logical-and (a b
)
1356 (declare (type bignum-type a b
))
1357 (let* ((len-a (%bignum-length a
))
1358 (len-b (%bignum-length b
))
1359 (a-plusp (%bignum-0-or-plusp a len-a
))
1360 (b-plusp (%bignum-0-or-plusp b len-b
)))
1361 (declare (type bignum-index len-a len-b
))
1365 (logand-shorter-positive a len-a b
(%allocate-bignum len-a
))
1366 (logand-shorter-negative a len-a b len-b
(%allocate-bignum len-b
))))
1369 (logand-shorter-positive b len-b a
(%allocate-bignum len-b
))
1370 (logand-shorter-negative b len-b a len-a
(%allocate-bignum len-a
))))
1371 (t (logand-shorter-positive a len-a b
(%allocate-bignum len-a
))))))
1373 ;;; This takes a shorter bignum, a and len-a, that is positive. Because this
1374 ;;; is AND, we don't care about any bits longer than a's since its infinite 0
1375 ;;; sign bits will mask the other bits out of b. The result is len-a big.
1376 (defun logand-shorter-positive (a len-a b res
)
1377 (declare (type bignum-type a b res
)
1378 (type bignum-index len-a
))
1380 (declare (type bignum-index i
))
1381 (setf (%bignum-ref res i
)
1382 (%logand
(%bignum-ref a i
) (%bignum-ref b i
))))
1383 (%normalize-bignum res len-a
))
1385 ;;; This takes a shorter bignum, a and len-a, that is negative. Because this
1386 ;;; is AND, we just copy any bits longer than a's since its infinite 1 sign
1387 ;;; bits will include any bits from b. The result is len-b big.
1388 (defun logand-shorter-negative (a len-a b len-b res
)
1389 (declare (type bignum-type a b res
)
1390 (type bignum-index len-a len-b
))
1392 (declare (type bignum-index i
))
1393 (setf (%bignum-ref res i
)
1394 (%logand
(%bignum-ref a i
) (%bignum-ref b i
))))
1395 (do ((i len-a
(1+ i
)))
1397 (declare (type bignum-index i
))
1398 (setf (%bignum-ref res i
) (%bignum-ref b i
)))
1399 (%normalize-bignum res len-b
))
1403 (defun bignum-logical-ior (a b
)
1404 (declare (type bignum-type a b
))
1405 (let* ((len-a (%bignum-length a
))
1406 (len-b (%bignum-length b
))
1407 (a-plusp (%bignum-0-or-plusp a len-a
))
1408 (b-plusp (%bignum-0-or-plusp b len-b
)))
1409 (declare (type bignum-index len-a len-b
))
1413 (logior-shorter-positive a len-a b len-b
(%allocate-bignum len-b
))
1414 (logior-shorter-negative a len-a b len-b
(%allocate-bignum len-b
))))
1417 (logior-shorter-positive b len-b a len-a
(%allocate-bignum len-a
))
1418 (logior-shorter-negative b len-b a len-a
(%allocate-bignum len-a
))))
1419 (t (logior-shorter-positive a len-a b len-b
(%allocate-bignum len-a
))))))
1421 ;;; This takes a shorter bignum, a and len-a, that is positive. Because this
1422 ;;; is IOR, we don't care about any bits longer than a's since its infinite
1423 ;;; 0 sign bits will mask the other bits out of b out to len-b. The result
1425 (defun logior-shorter-positive (a len-a b len-b res
)
1426 (declare (type bignum-type a b res
)
1427 (type bignum-index len-a len-b
))
1429 (declare (type bignum-index i
))
1430 (setf (%bignum-ref res i
)
1431 (%logior
(%bignum-ref a i
) (%bignum-ref b i
))))
1432 (do ((i len-a
(1+ i
)))
1434 (declare (type bignum-index i
))
1435 (setf (%bignum-ref res i
) (%bignum-ref b i
)))
1436 (%normalize-bignum res len-b
))
1438 ;;; This takes a shorter bignum, a and len-a, that is negative. Because this
1439 ;;; is IOR, we just copy any bits longer than a's since its infinite 1 sign
1440 ;;; bits will include any bits from b. The result is len-b long.
1441 (defun logior-shorter-negative (a len-a b len-b res
)
1442 (declare (type bignum-type a b res
)
1443 (type bignum-index len-a len-b
))
1445 (declare (type bignum-index i
))
1446 (setf (%bignum-ref res i
)
1447 (%logior
(%bignum-ref a i
) (%bignum-ref b i
))))
1448 (do ((i len-a
(1+ i
))
1449 (sign (%sign-digit a len-a
)))
1451 (declare (type bignum-index i
))
1452 (setf (%bignum-ref res i
) sign
))
1453 (%normalize-bignum res len-b
))
1457 (defun bignum-logical-xor (a b
)
1458 (declare (type bignum-type a b
))
1459 (let ((len-a (%bignum-length a
))
1460 (len-b (%bignum-length b
)))
1461 (declare (type bignum-index len-a len-b
))
1463 (bignum-logical-xor-aux a len-a b len-b
(%allocate-bignum len-b
))
1464 (bignum-logical-xor-aux b len-b a len-a
(%allocate-bignum len-a
)))))
1466 ;;; This takes the shorter of two bignums in a and len-a. Res is len-b
1467 ;;; long. Do the XOR.
1468 (defun bignum-logical-xor-aux (a len-a b len-b res
)
1469 (declare (type bignum-type a b res
)
1470 (type bignum-index len-a len-b
))
1472 (declare (type bignum-index i
))
1473 (setf (%bignum-ref res i
)
1474 (%logxor
(%bignum-ref a i
) (%bignum-ref b i
))))
1475 (do ((i len-a
(1+ i
))
1476 (sign (%sign-digit a len-a
)))
1478 (declare (type bignum-index i
))
1479 (setf (%bignum-ref res i
) (%logxor sign
(%bignum-ref b i
))))
1480 (%normalize-bignum res len-b
))
1482 ;;;; There used to be a bunch of code to implement "efficient" versions of LDB
1483 ;;;; and DPB here. But it apparently was never used, so it's been deleted.
1484 ;;;; --njf, 2007-02-04
1488 ;;; This is the original sketch of the algorithm from which I implemented this
1489 ;;; TRUNCATE, assuming both operands are bignums. I should modify this to work
1490 ;;; with the documentation on my functions, as a general introduction. I've
1491 ;;; left this here just in case someone needs it in the future. Don't look at
1492 ;;; this unless reading the functions' comments leaves you at a loss. Remember
1493 ;;; this comes from Knuth, so the book might give you the right general
1498 ;;; If X's magnitude is less than Y's, then result is 0 with remainder X.
1500 ;;; Make x and y positive, copying x if it is already positive.
1502 ;;; Shift y left until there's a 1 in the 30'th bit (most significant, non-sign
1504 ;;; Just do most sig digit to determine how much to shift whole number.
1505 ;;; Shift x this much too.
1506 ;;; Remember this initial shift count.
1508 ;;; Allocate q to be len-x minus len-y quantity plus 1.
1510 ;;; i = last digit of x.
1511 ;;; k = last digit of q.
1515 ;;; j = last digit of y.
1518 ;;; if x[i] = y[j] then g = (1- (ash 1 digit-size))
1519 ;;; else g = x[i]x[i-1]/y[j].
1522 ;;; %UNSIGNED-MULTIPLY returns b and c defined below.
1523 ;;; a = x[i-1] - (logand (* g y[j]) #xFFFFFFFF).
1524 ;;; Use %UNSIGNED-MULTIPLY taking low-order result.
1525 ;;; b = (logand (ash (* g y[j-1]) (- digit-size)) (1- (ash 1 digit-size))).
1526 ;;; c = (logand (* g y[j-1]) (1- (ash 1 digit-size))).
1528 ;;; if a > b, guess is too high
1529 ;;; g = g - 1; go back to "check guess".
1530 ;;; if a = b and c > x[i-2], guess is too high
1531 ;;; g = g - 1; go back to "check guess".
1532 ;;; GUESS IS 32-BIT NUMBER, SO USE THING TO KEEP IN SPECIAL REGISTER
1533 ;;; SAME FOR A, B, AND C.
1535 ;;; Subtract g * y from x[i - len-y+1]..x[i]. See paper for doing this in step.
1536 ;;; If x[i] < 0, guess is screwed up.
1537 ;;; negative g, then add 1
1538 ;;; zero or positive g, then subtract 1
1539 ;;; AND add y back into x[len-y+1..i].
1545 ;;; If k>=0, goto LOOP.
1547 ;;; Now quotient is good, but remainder is not.
1548 ;;; Shift x right by saved initial left shifting count.
1550 ;;; Check quotient and remainder signs.
1551 ;;; x pos y pos --> q pos r pos
1552 ;;; x pos y neg --> q neg r pos
1553 ;;; x neg y pos --> q neg r neg
1554 ;;; x neg y neg --> q pos r neg
1556 ;;; Normalize quotient and remainder. Cons result if necessary.
1559 ;;; This used to be split into multiple functions, which shared state
1560 ;;; in special variables *TRUNCATE-X* and *TRUNCATE-Y*. Having so many
1561 ;;; special variable accesses in tight inner loops was having a large
1562 ;;; effect on performance, so the helper functions have now been
1563 ;;; refactored into local functions and the special variables into
1564 ;;; lexicals. There was also a lot of boxing and unboxing of
1565 ;;; (UNSIGNED-BYTE 32)'s going on, which this refactoring
1566 ;;; eliminated. This improves the performance on some CL-BENCH tests
1567 ;;; by up to 50%, which is probably signigicant enough to justify the
1568 ;;; reduction in readability that was introduced. --JES, 2004-08-07
1569 (defun bignum-truncate (x y
)
1570 (declare (type bignum-type x y
))
1571 (let (truncate-x truncate-y
)
1573 ;;; Divide X by Y when Y is a single bignum digit. BIGNUM-TRUNCATE
1574 ;;; fixes up the quotient and remainder with respect to sign and
1577 ;;; We don't have to worry about shifting Y to make its most
1578 ;;; significant digit sufficiently large for %FLOOR to return
1579 ;;; digit-size quantities for the q-digit and r-digit. If Y is
1580 ;;; a single digit bignum, it is already large enough for
1581 ;;; %FLOOR. That is, it has some bits on pretty high in the
1583 ((bignum-truncate-single-digit (x len-x y
)
1584 (declare (type bignum-index len-x
))
1585 (let ((y (%bignum-ref y
0)))
1586 (declare (type bignum-element-type y
))
1587 (if (not (logtest y
(1- y
)))
1588 ;; Y is a power of two.
1590 ;; SHIFT-RIGHT-UNALIGNED won't do the right thing
1591 ;; with a shift count of 0, so special case this.
1592 ;; We could probably get away with (VALUES X 0)
1593 ;; here, but it's not clear that some of the
1594 ;; normalization logic further down would avoid
1595 ;; mutilating X. Just go ahead and cons, consing's
1597 (values (copy-bignum x len-x
) 0)
1598 (let ((n-bits (1- (integer-length y
))))
1600 (shift-right-unaligned x
0 n-bits len-x
1602 (setf (%bignum-ref res j
)
1603 (%ashr
(%bignum-ref x i
) n-bits
))
1606 (logand (%bignum-ref x
0) (1- y
)))))
1607 (do ((i (1- len-x
) (1- i
))
1608 (q (%allocate-bignum len-x
))
1611 (let ((rem (%allocate-bignum
1)))
1612 (setf (%bignum-ref rem
0) r
)
1614 (declare (type bignum-element-type r
))
1615 (multiple-value-bind (q-digit r-digit
)
1616 (%floor r
(%bignum-ref x i
) y
)
1617 (declare (type bignum-element-type q-digit r-digit
))
1618 (setf (%bignum-ref q i
) q-digit
)
1619 (setf r r-digit
))))))
1620 ;;; This returns a guess for the next division step. Y1 is the
1621 ;;; highest y digit, and y2 is the second to highest y
1622 ;;; digit. The x... variables are the three highest x digits
1623 ;;; for the next division step.
1625 ;;; From Knuth, our guess is either all ones or x-i and x-i-1
1626 ;;; divided by y1, depending on whether x-i and y1 are the
1627 ;;; same. We test this guess by determining whether guess*y2
1628 ;;; is greater than the three high digits of x minus guess*y1
1629 ;;; shifted left one digit:
1630 ;;; ------------------------------
1631 ;;; | x-i | x-i-1 | x-i-2 |
1632 ;;; ------------------------------
1633 ;;; ------------------------------
1634 ;;; - | g*y1 high | g*y1 low | 0 |
1635 ;;; ------------------------------
1636 ;;; ... < guess*y2 ???
1637 ;;; If guess*y2 is greater, then we decrement our guess by one
1638 ;;; and try again. This returns a guess that is either
1639 ;;; correct or one too large.
1640 (bignum-truncate-guess (y1 y2 x-i x-i-1 x-i-2
)
1641 (declare (type bignum-element-type y1 y2 x-i x-i-1 x-i-2
))
1642 (let ((guess (if (%digit-compare x-i y1
)
1644 (%floor x-i x-i-1 y1
))))
1645 (declare (type bignum-element-type guess
))
1647 (multiple-value-bind (high-guess*y1 low-guess
*y1
)
1648 (%multiply guess y1
)
1649 (declare (type bignum-element-type low-guess
*y1
1651 (multiple-value-bind (high-guess*y2 low-guess
*y2
)
1652 (%multiply guess y2
)
1653 (declare (type bignum-element-type high-guess
*y2
1655 (multiple-value-bind (middle-digit borrow
)
1656 (%subtract-with-borrow x-i-1 low-guess
*y1
1)
1657 (declare (type bignum-element-type middle-digit
)
1659 ;; Supplying borrow of 1 means there was no
1660 ;; borrow, and we know x-i-2 minus 0 requires
1662 (let ((high-digit (%subtract-with-borrow x-i
1665 (declare (type bignum-element-type high-digit
))
1666 (if (and (%digit-compare high-digit
0)
1667 (or (%digit-greater high-guess
*y2
1669 (and (%digit-compare middle-digit
1671 (%digit-greater low-guess
*y2
1673 (setf guess
(%subtract-with-borrow guess
1 1))
1674 (return guess
)))))))))
1675 ;;; Divide TRUNCATE-X by TRUNCATE-Y, returning the quotient
1676 ;;; and destructively modifying TRUNCATE-X so that it holds
1679 ;;; LEN-X and LEN-Y tell us how much of the buffers we care about.
1681 ;;; TRUNCATE-X definitely has at least three digits, and it has one
1682 ;;; more than TRUNCATE-Y. This keeps i, i-1, i-2, and low-x-digit
1683 ;;; happy. Thanks to SHIFT-AND-STORE-TRUNCATE-BUFFERS.
1684 (return-quotient-leaving-remainder (len-x len-y
)
1685 (declare (type bignum-index len-x len-y
))
1686 (let* ((len-q (- len-x len-y
))
1687 ;; Add one for extra sign digit in case high bit is on.
1688 (q (%allocate-bignum
(1+ len-q
)))
1690 (y1 (%bignum-ref truncate-y
(1- len-y
)))
1691 (y2 (%bignum-ref truncate-y
(- len-y
2)))
1695 (low-x-digit (- i len-y
)))
1696 (declare (type bignum-index len-q k i i-1 i-2 low-x-digit
)
1697 (type bignum-element-type y1 y2
))
1699 (setf (%bignum-ref q k
)
1700 (try-bignum-truncate-guess
1701 ;; This modifies TRUNCATE-X. Must access
1702 ;; elements each pass.
1703 (bignum-truncate-guess y1 y2
1704 (%bignum-ref truncate-x i
)
1705 (%bignum-ref truncate-x i-1
)
1706 (%bignum-ref truncate-x i-2
))
1708 (cond ((zerop k
) (return))
1711 (shiftf i i-1 i-2
(1- i-2
)))))
1713 ;;; This takes a digit guess, multiplies it by TRUNCATE-Y for a
1714 ;;; result one greater in length than LEN-Y, and subtracts this result
1715 ;;; from TRUNCATE-X. LOW-X-DIGIT is the first digit of X to start
1716 ;;; the subtraction, and we know X is long enough to subtract a LEN-Y
1717 ;;; plus one length bignum from it. Next we check the result of the
1718 ;;; subtraction, and if the high digit in X became negative, then our
1719 ;;; guess was one too big. In this case, return one less than GUESS
1720 ;;; passed in, and add one value of Y back into X to account for
1721 ;;; subtracting one too many. Knuth shows that the guess is wrong on
1722 ;;; the order of 3/b, where b is the base (2 to the digit-size power)
1723 ;;; -- pretty rarely.
1724 (try-bignum-truncate-guess (guess len-y low-x-digit
)
1725 (declare (type bignum-index low-x-digit len-y
)
1726 (type bignum-element-type guess
))
1727 (let ((carry-digit 0)
1730 (declare (type bignum-element-type carry-digit
)
1731 (type bignum-index i
)
1733 ;; Multiply guess and divisor, subtracting from dividend
1736 (multiple-value-bind (high-digit low-digit
)
1737 (%multiply-and-add guess
1738 (%bignum-ref truncate-y j
)
1740 (declare (type bignum-element-type high-digit low-digit
))
1741 (setf carry-digit high-digit
)
1742 (multiple-value-bind (x temp-borrow
)
1743 (%subtract-with-borrow
(%bignum-ref truncate-x i
)
1746 (declare (type bignum-element-type x
)
1747 (fixnum temp-borrow
))
1748 (setf (%bignum-ref truncate-x i
) x
)
1749 (setf borrow temp-borrow
)))
1751 (setf (%bignum-ref truncate-x i
)
1752 (%subtract-with-borrow
(%bignum-ref truncate-x i
)
1753 carry-digit borrow
))
1754 ;; See whether guess is off by one, adding one
1755 ;; Y back in if necessary.
1756 (cond ((%digit-0-or-plusp
(%bignum-ref truncate-x i
))
1759 ;; If subtraction has negative result, add one
1760 ;; divisor value back in. The guess was one too
1761 ;; large in magnitude.
1762 (let ((i low-x-digit
)
1765 (multiple-value-bind (v k
)
1766 (%add-with-carry
(%bignum-ref truncate-y j
)
1767 (%bignum-ref truncate-x i
)
1769 (declare (type bignum-element-type v
))
1770 (setf (%bignum-ref truncate-x i
) v
)
1773 (setf (%bignum-ref truncate-x i
)
1774 (%add-with-carry
(%bignum-ref truncate-x i
)
1776 (%subtract-with-borrow guess
1 1)))))
1777 ;;; This returns the amount to shift y to place a one in the
1778 ;;; second highest bit. Y must be positive. If the last digit
1779 ;;; of y is zero, then y has a one in the previous digit's
1780 ;;; sign bit, so we know it will take one less than digit-size
1781 ;;; to get a one where we want. Otherwise, we count how many
1782 ;;; right shifts it takes to get zero; subtracting this value
1783 ;;; from digit-size tells us how many high zeros there are
1784 ;;; which is one more than the shift amount sought.
1786 ;;; Note: This is exactly the same as one less than the
1787 ;;; integer-length of the last digit subtracted from the
1790 ;;; We shift y to make it sufficiently large that doing the
1791 ;;; 2*digit-size by digit-size %FLOOR calls ensures the quotient and
1792 ;;; remainder fit in digit-size.
1793 (shift-y-for-truncate (y)
1794 (let* ((len (%bignum-length y
))
1795 (last (%bignum-ref y
(1- len
))))
1796 (declare (type bignum-index len
)
1797 (type bignum-element-type last
))
1798 (- digit-size
(integer-length last
) 1)))
1799 ;;; Stores two bignums into the truncation bignum buffers,
1800 ;;; shifting them on the way in. This assumes x and y are
1801 ;;; positive and at least two in length, and it assumes
1802 ;;; truncate-x and truncate-y are one digit longer than x and
1804 (shift-and-store-truncate-buffers (x len-x y len-y shift
)
1805 (declare (type bignum-index len-x len-y
)
1806 (type (integer 0 (#.digit-size
)) shift
))
1807 (cond ((zerop shift
)
1808 (bignum-replace truncate-x x
:end1 len-x
)
1809 (bignum-replace truncate-y y
:end1 len-y
))
1811 (bignum-ashift-left-unaligned x
0 shift
(1+ len-x
)
1813 (bignum-ashift-left-unaligned y
0 shift
(1+ len-y
)
1814 truncate-y
))))) ;; LABELS
1815 ;;; Divide X by Y returning the quotient and remainder. In the
1816 ;;; general case, we shift Y to set up for the algorithm, and we
1817 ;;; use two buffers to save consing intermediate values. X gets
1818 ;;; destructively modified to become the remainder, and we have
1819 ;;; to shift it to account for the initial Y shift. After we
1820 ;;; multiple bind q and r, we first fix up the signs and then
1821 ;;; return the normalized results.
1822 (let* ((x-plusp (%bignum-0-or-plusp x
(%bignum-length x
)))
1823 (y-plusp (%bignum-0-or-plusp y
(%bignum-length y
)))
1824 (x (if x-plusp x
(negate-bignum x nil
)))
1825 (y (if y-plusp y
(negate-bignum y nil
)))
1826 (len-x (%bignum-length x
))
1827 (len-y (%bignum-length y
)))
1828 (multiple-value-bind (q r
)
1830 (bignum-truncate-single-digit x len-x y
))
1831 ((plusp (bignum-compare y x
))
1832 (let ((res (%allocate-bignum len-x
)))
1834 (setf (%bignum-ref res i
) (%bignum-ref x i
)))
1837 (let ((len-x+1 (1+ len-x
)))
1838 (setf truncate-x
(%allocate-bignum len-x
+1))
1839 (setf truncate-y
(%allocate-bignum
(1+ len-y
)))
1840 (let ((y-shift (shift-y-for-truncate y
)))
1841 (shift-and-store-truncate-buffers x len-x y
1843 (values (return-quotient-leaving-remainder len-x
+1
1845 ;; Now that RETURN-QUOTIENT-LEAVING-REMAINDER
1846 ;; has executed, we just tidy up the remainder
1847 ;; (in TRUNCATE-X) and return it.
1850 (let ((res (%allocate-bignum len-y
)))
1851 (declare (type bignum-type res
))
1852 (bignum-replace res truncate-x
:end2 len-y
)
1853 (%normalize-bignum res len-y
)))
1855 (shift-right-unaligned
1856 truncate-x
0 y-shift len-y
1858 (setf (%bignum-ref res j
)
1859 (%ashr
(%bignum-ref truncate-x i
)
1861 (%normalize-bignum res res-len
))
1863 (let ((quotient (cond ((eq x-plusp y-plusp
) q
)
1864 ((typep q
'fixnum
) (the fixnum
(- q
)))
1865 (t (negate-bignum-in-place q
))))
1866 (rem (cond (x-plusp r
)
1867 ((typep r
'fixnum
) (the fixnum
(- r
)))
1868 (t (negate-bignum-in-place r
)))))
1869 (values (if (typep quotient
'fixnum
)
1871 (%normalize-bignum quotient
(%bignum-length quotient
)))
1872 (if (typep rem
'fixnum
)
1874 (%normalize-bignum rem
(%bignum-length rem
))))))))))
1877 ;;;; There used to be a pile of code for implementing division for bignum digits
1878 ;;;; for machines that don't have a 2*digit-size by digit-size divide instruction.
1879 ;;;; This happens to be most machines, but all the SBCL ports seem to be content
1880 ;;;; to implement SB-BIGNUM:%FLOOR as a VOP rather than using the code here.
1881 ;;;; So it's been deleted. --njf, 2007-02-04
1883 ;;;; general utilities
1885 ;;; Internal in-place operations use this to fixup remaining digits in the
1886 ;;; incoming data, such as in-place shifting. This is basically the same as
1887 ;;; the first form in %NORMALIZE-BIGNUM, but we return the length of the buffer
1888 ;;; instead of shrinking the bignum.
1889 #!-sb-fluid
(declaim (sb!ext
:maybe-inline %normalize-bignum-buffer
))
1890 (defun %normalize-bignum-buffer
(result len
)
1891 (declare (type bignum-type result
)
1892 (type bignum-index len
))
1894 (do ((next-digit (%bignum-ref result
(- len
2))
1895 (%bignum-ref result
(- len
2)))
1896 (sign-digit (%bignum-ref result
(1- len
)) next-digit
))
1897 ((not (zerop (logxor sign-digit
(%ashr next-digit
(1- digit-size
))))))
1899 (setf (%bignum-ref result len
) 0)
1904 ;;; This drops the last digit if it is unnecessary sign information. It repeats
1905 ;;; this as needed, possibly ending with a fixnum. If the resulting length from
1906 ;;; shrinking is one, see whether our one word is a fixnum. Shift the possible
1907 ;;; fixnum bits completely out of the word, and compare this with shifting the
1908 ;;; sign bit all the way through. If the bits are all 1's or 0's in both words,
1909 ;;; then there are just sign bits between the fixnum bits and the sign bit. If
1910 ;;; we do have a fixnum, shift it over for the two low-tag bits.
1911 (defun %normalize-bignum
(result len
)
1912 (declare (type bignum-type result
)
1913 (type bignum-index len
)
1914 (inline %normalize-bignum-buffer
))
1915 (let ((newlen (%normalize-bignum-buffer result len
)))
1916 (declare (type bignum-index newlen
))
1917 (unless (= newlen len
)
1918 (%bignum-set-length result newlen
))
1920 (let ((digit (%bignum-ref result
0)))
1921 (if (= (%ashr digit sb
!vm
:n-positive-fixnum-bits
)
1922 (%ashr digit
(1- digit-size
)))
1923 (%fixnum-digit-with-correct-sign digit
)
1927 ;;; This drops the last digit if it is unnecessary sign information. It
1928 ;;; repeats this as needed, possibly ending with a fixnum magnitude but never
1929 ;;; returning a fixnum.
1930 (defun %mostly-normalize-bignum
(result len
)
1931 (declare (type bignum-type result
)
1932 (type bignum-index len
)
1933 (inline %normalize-bignum-buffer
))
1934 (let ((newlen (%normalize-bignum-buffer result len
)))
1935 (declare (type bignum-index newlen
))
1936 (unless (= newlen len
)
1937 (%bignum-set-length result newlen
))
1942 ;;; the bignum case of the SXHASH function
1943 (defun sxhash-bignum (x)
1944 (let ((result 316495330))
1945 (declare (type fixnum result
))
1946 (dotimes (i (%bignum-length x
))
1947 (declare (type index i
))
1948 (let ((xi (%bignum-ref x i
)))
1950 (logand most-positive-fixnum