1 ;;; cl-extra.el --- Common Lisp extensions for GNU Emacs Lisp (part two)
3 ;; Copyright (C) 1993 Free Software Foundation, Inc.
5 ;; Author: Dave Gillespie <daveg@synaptics.com>
7 ;; Keywords: extensions
9 ;; This file is part of GNU Emacs.
11 ;; GNU Emacs is free software; you can redistribute it and/or modify
12 ;; it under the terms of the GNU General Public License as published by
13 ;; the Free Software Foundation; either version 2, or (at your option)
16 ;; GNU Emacs is distributed in the hope that it will be useful,
17 ;; but WITHOUT ANY WARRANTY; without even the implied warranty of
18 ;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 ;; GNU General Public License for more details.
21 ;; You should have received a copy of the GNU General Public License
22 ;; along with GNU Emacs; see the file COPYING. If not, write to the
23 ;; Free Software Foundation, Inc., 59 Temple Place - Suite 330,
24 ;; Boston, MA 02111-1307, USA.
28 ;; These are extensions to Emacs Lisp that provide a degree of
29 ;; Common Lisp compatibility, beyond what is already built-in
32 ;; This package was written by Dave Gillespie; it is a complete
33 ;; rewrite of Cesar Quiroz's original cl.el package of December 1986.
35 ;; This package works with Emacs 18, Emacs 19, and Lucid Emacs 19.
37 ;; Bug reports, comments, and suggestions are welcome!
39 ;; This file contains portions of the Common Lisp extensions
40 ;; package which are autoloaded since they are relatively obscure.
42 ;; See cl.el for Change Log.
47 (or (memq 'cl-19 features
)
48 (error "Tried to load `cl-extra' before `cl'!"))
51 ;;; We define these here so that this file can compile without having
52 ;;; loaded the cl.el file already.
54 (defmacro cl-push
(x place
) (list 'setq place
(list 'cons x place
)))
55 (defmacro cl-pop
(place)
56 (list 'car
(list 'prog1 place
(list 'setq place
(list 'cdr place
)))))
58 (defvar cl-emacs-type
)
63 (defun coerce (x type
)
64 "Coerce OBJECT to type TYPE.
65 TYPE is a Common Lisp type specifier."
66 (cond ((eq type
'list
) (if (listp x
) x
(append x nil
)))
67 ((eq type
'vector
) (if (vectorp x
) x
(vconcat x
)))
68 ((eq type
'string
) (if (stringp x
) x
(concat x
)))
69 ((eq type
'array
) (if (arrayp x
) x
(vconcat x
)))
70 ((and (eq type
'character
) (stringp x
) (= (length x
) 1)) (aref x
0))
71 ((and (eq type
'character
) (symbolp x
)) (coerce (symbol-name x
) type
))
72 ((eq type
'float
) (float x
))
74 (t (error "Can't coerce %s to type %s" x type
))))
80 "T if two Lisp objects have similar structures and contents.
81 This is like `equal', except that it accepts numerically equal
82 numbers of different types (float vs. integer), and also compares
83 strings case-insensitively."
86 (and (stringp y
) (= (length x
) (length y
))
87 (or (string-equal x y
)
88 (string-equal (downcase x
) (downcase y
))))) ; lazy but simple!
90 (and (numberp y
) (= x y
)))
92 (while (and (consp x
) (consp y
) (equalp (car x
) (car y
)))
93 (setq x
(cdr x
) y
(cdr y
)))
94 (and (not (consp x
)) (equalp x y
)))
96 (and (vectorp y
) (= (length x
) (length y
))
98 (while (and (>= (setq i
(1- i
)) 0)
99 (equalp (aref x i
) (aref y i
))))
104 ;;; Control structures.
106 (defun cl-mapcar-many (cl-func cl-seqs
)
107 (if (cdr (cdr cl-seqs
))
109 (cl-n (apply 'min
(mapcar 'length cl-seqs
)))
111 (cl-args (copy-sequence cl-seqs
))
113 (setq cl-seqs
(copy-sequence cl-seqs
))
115 (setq cl-p1 cl-seqs cl-p2 cl-args
)
118 (if (consp (car cl-p1
))
119 (prog1 (car (car cl-p1
))
120 (setcar cl-p1
(cdr (car cl-p1
))))
121 (aref (car cl-p1
) cl-i
)))
122 (setq cl-p1
(cdr cl-p1
) cl-p2
(cdr cl-p2
)))
123 (cl-push (apply cl-func cl-args
) cl-res
)
124 (setq cl-i
(1+ cl-i
)))
128 (cl-y (nth 1 cl-seqs
)))
129 (let ((cl-n (min (length cl-x
) (length cl-y
)))
131 (while (< (setq cl-i
(1+ cl-i
)) cl-n
)
132 (cl-push (funcall cl-func
133 (if (consp cl-x
) (cl-pop cl-x
) (aref cl-x cl-i
))
134 (if (consp cl-y
) (cl-pop cl-y
) (aref cl-y cl-i
)))
138 (defun map (cl-type cl-func cl-seq
&rest cl-rest
)
139 "Map a function across one or more sequences, returning a sequence.
140 TYPE is the sequence type to return, FUNC is the function, and SEQS
141 are the argument sequences."
142 (let ((cl-res (apply 'mapcar
* cl-func cl-seq cl-rest
)))
143 (and cl-type
(coerce cl-res cl-type
))))
145 (defun maplist (cl-func cl-list
&rest cl-rest
)
146 "Map FUNC to each sublist of LIST or LISTS.
147 Like `mapcar', except applies to lists and their cdr's rather than to
148 the elements themselves."
151 (cl-args (cons cl-list
(copy-sequence cl-rest
)))
153 (while (not (memq nil cl-args
))
154 (cl-push (apply cl-func cl-args
) cl-res
)
156 (while cl-p
(setcar cl-p
(cdr (cl-pop cl-p
)) )))
160 (cl-push (funcall cl-func cl-list
) cl-res
)
161 (setq cl-list
(cdr cl-list
)))
164 (defun mapc (cl-func cl-seq
&rest cl-rest
)
165 "Like `mapcar', but does not accumulate values returned by the function."
167 (apply 'map nil cl-func cl-seq cl-rest
)
168 (mapcar cl-func cl-seq
))
171 (defun mapl (cl-func cl-list
&rest cl-rest
)
172 "Like `maplist', but does not accumulate values returned by the function."
174 (apply 'maplist cl-func cl-list cl-rest
)
175 (let ((cl-p cl-list
))
176 (while cl-p
(funcall cl-func cl-p
) (setq cl-p
(cdr cl-p
)))))
179 (defun mapcan (cl-func cl-seq
&rest cl-rest
)
180 "Like `mapcar', but nconc's together the values returned by the function."
181 (apply 'nconc
(apply 'mapcar
* cl-func cl-seq cl-rest
)))
183 (defun mapcon (cl-func cl-list
&rest cl-rest
)
184 "Like `maplist', but nconc's together the values returned by the function."
185 (apply 'nconc
(apply 'maplist cl-func cl-list cl-rest
)))
187 (defun some (cl-pred cl-seq
&rest cl-rest
)
188 "Return true if PREDICATE is true of any element of SEQ or SEQs.
189 If so, return the true (non-nil) value returned by PREDICATE."
190 (if (or cl-rest
(nlistp cl-seq
))
193 (function (lambda (&rest cl-x
)
194 (let ((cl-res (apply cl-pred cl-x
)))
195 (if cl-res
(throw 'cl-some cl-res
)))))
198 (while (and cl-seq
(not (setq cl-x
(funcall cl-pred
(cl-pop cl-seq
))))))
201 (defun every (cl-pred cl-seq
&rest cl-rest
)
202 "Return true if PREDICATE is true of every element of SEQ or SEQs."
203 (if (or cl-rest
(nlistp cl-seq
))
206 (function (lambda (&rest cl-x
)
207 (or (apply cl-pred cl-x
) (throw 'cl-every nil
))))
209 (while (and cl-seq
(funcall cl-pred
(car cl-seq
)))
210 (setq cl-seq
(cdr cl-seq
)))
213 (defun notany (cl-pred cl-seq
&rest cl-rest
)
214 "Return true if PREDICATE is false of every element of SEQ or SEQs."
215 (not (apply 'some cl-pred cl-seq cl-rest
)))
217 (defun notevery (cl-pred cl-seq
&rest cl-rest
)
218 "Return true if PREDICATE is false of some element of SEQ or SEQs."
219 (not (apply 'every cl-pred cl-seq cl-rest
)))
221 ;;; Support for `loop'.
222 (defun cl-map-keymap (cl-func cl-map
)
223 (while (symbolp cl-map
) (setq cl-map
(symbol-function cl-map
)))
224 (if (eq cl-emacs-type
'lucid
) (funcall 'map-keymap cl-func cl-map
)
227 (while (consp (setq cl-p
(cdr cl-p
)))
228 (cond ((consp (car cl-p
))
229 (funcall cl-func
(car (car cl-p
)) (cdr (car cl-p
))))
230 ((vectorp (car cl-p
))
231 (cl-map-keymap cl-func
(car cl-p
)))
232 ((eq (car cl-p
) 'keymap
)
235 (while (< (setq cl-i
(1+ cl-i
)) (length cl-map
))
236 (if (aref cl-map cl-i
)
237 (funcall cl-func cl-i
(aref cl-map cl-i
))))))))
239 (defun cl-map-keymap-recursively (cl-func-rec cl-map
&optional cl-base
)
241 (setq cl-base
(copy-sequence (if (eq cl-emacs-type
18) "0" [0]))))
244 (lambda (cl-key cl-bind)
245 (aset cl-base (1- (length cl-base)) cl-key)
246 (if (keymapp cl-bind)
247 (cl-map-keymap-recursively
249 (funcall (if (eq cl-emacs-type 18) 'concat 'vconcat)
251 (funcall cl-func-rec cl-base cl-bind))))
254 (defun cl-map-intervals (cl-func &optional cl-what cl-prop cl-start cl-end)
255 (or cl-what (setq cl-what (current-buffer)))
256 (if (bufferp cl-what)
257 (let (cl-mark cl-mark2 (cl-next t) cl-next2)
260 (setq cl-mark (copy-marker (or cl-start (point-min))))
261 (setq cl-mark2 (and cl-end (copy-marker cl-end))))
262 (while (and cl-next (or (not cl-mark2) (< cl-mark cl-mark2)))
263 (setq cl-next (and (fboundp 'next-property-change)
264 (if cl-prop (next-single-property-change
265 cl-mark cl-prop cl-what)
266 (next-property-change cl-mark cl-what)))
267 cl-next2 (or cl-next (save-excursion
268 (set-buffer cl-what) (point-max))))
269 (funcall cl-func (prog1 (marker-position cl-mark)
270 (set-marker cl-mark cl-next2))
271 (if cl-mark2 (min cl-next2 cl-mark2) cl-next2)))
272 (set-marker cl-mark nil) (if cl-mark2 (set-marker cl-mark2 nil)))
273 (or cl-start (setq cl-start 0))
274 (or cl-end (setq cl-end (length cl-what)))
275 (while (< cl-start cl-end)
276 (let ((cl-next (or (and (fboundp 'next-property-change)
277 (if cl-prop (next-single-property-change
278 cl-start cl-prop cl-what)
279 (next-property-change cl-start cl-what)))
281 (funcall cl-func cl-start (min cl-next cl-end))
282 (setq cl-start cl-next)))))
284 (defun cl-map-overlays (cl-func &optional cl-buffer cl-start cl-end cl-arg)
285 (or cl-buffer (setq cl-buffer (current-buffer)))
286 (if (fboundp 'overlay-lists)
288 ;; This is the preferred algorithm, though overlay-lists is undocumented.
291 (set-buffer cl-buffer)
292 (setq cl-ovl (overlay-lists))
293 (if cl-start (setq cl-start (copy-marker cl-start)))
294 (if cl-end (setq cl-end (copy-marker cl-end))))
295 (setq cl-ovl (nconc (car cl-ovl) (cdr cl-ovl)))
297 (or (not (overlay-start (car cl-ovl)))
298 (and cl-end (>= (overlay-start (car cl-ovl)) cl-end))
299 (and cl-start (<= (overlay-end (car cl-ovl)) cl-start))
300 (not (funcall cl-func (car cl-ovl) cl-arg))))
301 (setq cl-ovl (cdr cl-ovl)))
302 (if cl-start (set-marker cl-start nil))
303 (if cl-end (set-marker cl-end nil)))
305 ;; This alternate algorithm fails to find zero-length overlays.
306 (let ((cl-mark (save-excursion (set-buffer cl-buffer)
307 (copy-marker (or cl-start (point-min)))))
308 (cl-mark2 (and cl-end (save-excursion (set-buffer cl-buffer)
309 (copy-marker cl-end))))
311 (while (save-excursion
312 (and (setq cl-pos (marker-position cl-mark))
313 (< cl-pos (or cl-mark2 (point-max)))
315 (set-buffer cl-buffer)
316 (setq cl-ovl (overlays-at cl-pos))
317 (set-marker cl-mark (next-overlay-change cl-pos)))))
319 (or (/= (overlay-start (car cl-ovl)) cl-pos)
320 (not (and (funcall cl-func (car cl-ovl) cl-arg)
321 (set-marker cl-mark nil)))))
322 (setq cl-ovl (cdr cl-ovl))))
323 (set-marker cl-mark nil) (if cl-mark2 (set-marker cl-mark2 nil)))))
325 ;;; Support for `setf'.
326 (defun cl-set-frame-visible-p (frame val)
327 (cond ((null val) (make-frame-invisible frame))
328 ((eq val 'icon) (iconify-frame frame))
329 (t (make-frame-visible frame)))
332 ;;; Support for `progv'.
333 (defvar cl-progv-save)
334 (defun cl-progv-before (syms values)
336 (cl-push (if (boundp (car syms))
337 (cons (car syms) (symbol-value (car syms)))
338 (car syms)) cl-progv-save)
340 (set (cl-pop syms) (cl-pop values))
341 (makunbound (cl-pop syms)))))
343 (defun cl-progv-after ()
345 (if (consp (car cl-progv-save))
346 (set (car (car cl-progv-save)) (cdr (car cl-progv-save)))
347 (makunbound (car cl-progv-save)))
348 (cl-pop cl-progv-save)))
353 (defun gcd (&rest args)
354 "Return the greatest common divisor of the arguments."
355 (let ((a (abs (or (cl-pop args) 0))))
357 (let ((b (abs (cl-pop args))))
358 (while (> b 0) (setq b (% a (setq a b))))))
361 (defun lcm (&rest args)
362 "Return the least common multiple of the arguments."
365 (let ((a (abs (or (cl-pop args) 1))))
367 (let ((b (abs (cl-pop args))))
368 (setq a (* (/ a (gcd a b)) b))))
372 "Return the integer square root of the argument."
373 (if (and (integerp a) (> a 0))
374 (let ((g (cond ((<= a 100) 10) ((<= a 10000) 100)
375 ((<= a 1000000) 1000) (t a)))
377 (while (< (setq g2 (/ (+ g (/ a g)) 2)) g)
380 (if (eq a 0) 0 (signal 'arith-error nil))))
383 "Return X raised to the power of Y. Works only for integer arguments."
384 (if (<= y 0) (if (= y 0) 1 (if (memq x '(-1 1)) (cl-expt x (- y)) 0))
385 (* (if (= (% y 2) 0) 1 x) (cl-expt (* x x) (/ y 2)))))
386 (or (and (fboundp 'expt) (subrp (symbol-function 'expt)))
387 (defalias 'expt 'cl-expt))
389 (defun floor* (x &optional y)
390 "Return a list of the floor of X and the fractional part of X.
391 With two arguments, return floor and remainder of their quotient."
392 (let ((q (floor x y)))
393 (list q (- x (if y (* y q) q)))))
395 (defun ceiling* (x &optional y)
396 "Return a list of the ceiling of X and the fractional part of X.
397 With two arguments, return ceiling and remainder of their quotient."
398 (let ((res (floor* x y)))
399 (if (= (car (cdr res)) 0) res
400 (list (1+ (car res)) (- (car (cdr res)) (or y 1))))))
402 (defun truncate* (x &optional y)
403 "Return a list of the integer part of X and the fractional part of X.
404 With two arguments, return truncation and remainder of their quotient."
405 (if (eq (>= x 0) (or (null y) (>= y 0)))
406 (floor* x y) (ceiling* x y)))
408 (defun round* (x &optional y)
409 "Return a list of X rounded to the nearest integer and the remainder.
410 With two arguments, return rounding and remainder of their quotient."
412 (if (and (integerp x) (integerp y))
414 (res (floor* (+ x hy) y)))
415 (if (and (= (car (cdr res)) 0)
417 (/= (% (car res) 2) 0))
418 (list (1- (car res)) hy)
419 (list (car res) (- (car (cdr res)) hy))))
420 (let ((q (round (/ x y))))
421 (list q (- x (* q y)))))
422 (if (integerp x) (list x 0)
427 "The remainder of X divided by Y, with the same sign as Y."
428 (nth 1 (floor* x y)))
431 "The remainder of X divided by Y, with the same sign as X."
432 (nth 1 (truncate* x y)))
435 "Return 1 if A is positive, -1 if negative, 0 if zero."
436 (cond ((> a 0) 1) ((< a 0) -1) (t 0)))
441 (defvar *random-state*)
442 (defun random* (lim &optional state)
443 "Return a random nonnegative number less than LIM, an integer or float.
444 Optional second arg STATE is a random-state object."
445 (or state (setq state *random-state*))
446 ;; Inspired by "ran3" from Numerical Recipes. Additive congruential method.
447 (let ((vec (aref state 3)))
449 (let ((i 0) (j (- 1357335 (% (abs vec) 1357333))) (k 1) ii)
450 (aset state 3 (setq vec (make-vector 55 nil)))
452 (while (> (setq i (% (+ i 21) 55)) 0)
453 (aset vec i (setq j (prog1 k (setq k (- j k))))))
454 (while (< (setq i (1+ i)) 200) (random* 2 state))))
455 (let* ((i (aset state 1 (% (1+ (aref state 1)) 55)))
456 (j (aset state 2 (% (1+ (aref state 2)) 55)))
457 (n (logand 8388607 (aset vec i (- (aref vec i) (aref vec j))))))
459 (if (<= lim 512) (% n lim)
460 (if (> lim 8388607) (setq n (+ (lsh n 9) (random* 512 state))))
462 (while (< mask (1- lim)) (setq mask (1+ (+ mask mask))))
463 (if (< (setq n (logand n mask)) lim) n (random* lim state))))
464 (* (/ n '8388608e0) lim)))))
466 (defun make-random-state (&optional state)
467 "Return a copy of random-state STATE, or of `*random-state*' if omitted.
468 If STATE is t, return a new state object seeded from the time of day."
469 (cond ((null state) (make-random-state *random-state*))
470 ((vectorp state) (cl-copy-tree state t))
471 ((integerp state) (vector 'cl-random-state-tag -1 30 state))
472 (t (make-random-state (cl-random-time)))))
474 (defun random-state-p (object)
475 "Return t if OBJECT is a random-state object."
476 (and (vectorp object) (= (length object) 4)
477 (eq (aref object 0) 'cl-random-state-tag)))
480 ;; Implementation limits.
482 (defun cl-finite-do (func a b)
484 (let ((res (funcall func a b))) ; check for IEEE infinity
485 (and (numberp res) (/= res (/ res 2)) res))
488 (defvar most-positive-float)
489 (defvar most-negative-float)
490 (defvar least-positive-float)
491 (defvar least-negative-float)
492 (defvar least-positive-normalized-float)
493 (defvar least-negative-normalized-float)
494 (defvar float-epsilon)
495 (defvar float-negative-epsilon)
497 (defun cl-float-limits ()
498 (or most-positive-float (not (numberp '2e1))
500 ;; Find maximum exponent (first two loops are optimizations)
501 (while (cl-finite-do '* x x) (setq x (* x x)))
502 (while (cl-finite-do '* x (/ x 2)) (setq x (* x (/ x 2))))
503 (while (cl-finite-do '+ x x) (setq x (+ x x)))
505 ;; Now fill in 1's in the mantissa.
506 (while (and (cl-finite-do '+ x y) (/= (+ x y) x))
507 (setq x (+ x y) y (/ y 2)))
508 (setq most-positive-float x
509 most-negative-float (- x))
510 ;; Divide down until mantissa starts rounding.
511 (setq x (/ x z) y (/ 16 z) x (* x y))
512 (while (condition-case err (and (= x (* (/ x 2) 2)) (> (/ y 2) 0))
514 (setq x (/ x 2) y (/ y 2)))
515 (setq least-positive-normalized-float y
516 least-negative-normalized-float (- y))
517 ;; Divide down until value underflows to zero.
519 (while (condition-case err (> (/ x 2) 0) (arith-error nil))
521 (setq least-positive-float x
522 least-negative-float (- x))
524 (while (/= (+ '1e0 x) '1e0) (setq x (/ x 2)))
525 (setq float-epsilon (* x 2))
527 (while (/= (- '1e0 x) '1e0) (setq x (/ x 2)))
528 (setq float-negative-epsilon (* x 2))))
532 ;;; Sequence functions.
534 (defun subseq (seq start &optional end)
535 "Return the subsequence of SEQ from START to END.
536 If END is omitted, it defaults to the length of the sequence.
537 If START or END is negative, it counts from the end."
538 (if (stringp seq) (substring seq start end)
540 (and end (< end 0) (setq end (+ end (setq len (length seq)))))
541 (if (< start 0) (setq start (+ start (or len (setq len (length seq))))))
543 (if (> start 0) (setq seq (nthcdr start seq)))
546 (while (>= (setq end (1- end)) start)
547 (cl-push (cl-pop seq) res))
549 (copy-sequence seq)))
551 (or end (setq end (or len (length seq))))
552 (let ((res (make-vector (max (- end start) 0) nil))
555 (aset res i (aref seq start))
556 (setq i (1+ i) start (1+ start)))
559 (defun concatenate (type &rest seqs)
560 "Concatenate, into a sequence of type TYPE, the argument SEQUENCES."
561 (cond ((eq type 'vector) (apply 'vconcat seqs))
562 ((eq type 'string) (apply 'concat seqs))
563 ((eq type 'list) (apply 'append (append seqs '(nil))))
564 (t (error "Not a sequence type name: %s" type))))
569 (defun revappend (x y)
570 "Equivalent to (append (reverse X) Y)."
571 (nconc (reverse x) y))
574 "Equivalent to (nconc (nreverse X) Y)."
575 (nconc (nreverse x) y))
577 (defun list-length (x)
578 "Return the length of a list. Return nil if list is circular."
579 (let ((n 0) (fast x) (slow x))
580 (while (and (cdr fast) (not (and (eq fast slow) (> n 0))))
581 (setq n (+ n 2) fast (cdr (cdr fast)) slow (cdr slow)))
582 (if fast (if (cdr fast) nil (1+ n)) n)))
584 (defun tailp (sublist list)
585 "Return true if SUBLIST is a tail of LIST."
586 (while (and (consp list) (not (eq sublist list)))
587 (setq list (cdr list)))
588 (if (numberp sublist) (equal sublist list) (eq sublist list)))
590 (defun cl-copy-tree (tree &optional vecp)
591 "Make a copy of TREE.
592 If TREE is a cons cell, this recursively copies both its car and its cdr.
593 Contrast to copy-sequence, which copies only along the cdrs. With second
594 argument VECP, this copies vectors as well as conses."
596 (let ((p (setq tree (copy-list tree))))
598 (if (or (consp (car p)) (and vecp (vectorp (car p))))
599 (setcar p (cl-copy-tree (car p) vecp)))
600 (or (listp (cdr p)) (setcdr p (cl-copy-tree (cdr p) vecp)))
602 (if (and vecp (vectorp tree))
603 (let ((i (length (setq tree (copy-sequence tree)))))
604 (while (>= (setq i (1- i)) 0)
605 (aset tree i (cl-copy-tree (aref tree i) vecp))))))
607 (or (and (fboundp 'copy-tree) (subrp (symbol-function 'copy-tree)))
608 (defalias 'copy-tree 'cl-copy-tree))
613 (defun get* (sym tag &optional def) ; See compiler macro in cl-macs.el
614 "Return the value of SYMBOL's PROPNAME property, or DEFAULT if none."
617 (let ((plist (symbol-plist sym)))
618 (while (and plist (not (eq (car plist) tag)))
619 (setq plist (cdr (cdr plist))))
620 (if plist (car (cdr plist)) def)))))
622 (defun getf (plist tag &optional def)
623 "Search PROPLIST for property PROPNAME; return its value or DEFAULT.
624 PROPLIST is a list of the sort returned by `symbol-plist'."
625 (setplist '--cl-getf-symbol-- plist)
626 (or (get '--cl-getf-symbol-- tag)
627 (and def (get* '--cl-getf-symbol-- tag def))))
629 (defun cl-set-getf (plist tag val)
631 (while (and p (not (eq (car p) tag))) (setq p (cdr (cdr p))))
632 (if p (progn (setcar (cdr p) val) plist) (list* tag val plist))))
634 (defun cl-do-remf (plist tag)
635 (let ((p (cdr plist)))
636 (while (and (cdr p) (not (eq (car (cdr p)) tag))) (setq p (cdr (cdr p))))
637 (and (cdr p) (progn (setcdr p (cdr (cdr (cdr p)))) t))))
639 (defun cl-remprop (sym tag)
640 "Remove from SYMBOL's plist the property PROP and its value."
641 (let ((plist (symbol-plist sym)))
642 (if (and plist (eq tag (car plist)))
643 (progn (setplist sym (cdr (cdr plist))) t)
644 (cl-do-remf plist tag))))
645 (or (and (fboundp 'remprop) (subrp (symbol-function 'remprop)))
646 (defalias 'remprop 'cl-remprop))
652 (defun make-hash-table (&rest cl-keys)
653 "Make an empty Common Lisp-style hash-table.
654 If :test is `eq', this can use Lucid Emacs built-in hash-tables.
655 In non-Lucid Emacs, or with non-`eq' test, this internally uses a-lists.
656 Keywords supported: :test :size
657 The Common Lisp keywords :rehash-size and :rehash-threshold are ignored."
658 (let ((cl-test (or (car (cdr (memq ':test cl-keys))) 'eql))
659 (cl-size (or (car (cdr (memq ':size cl-keys))) 20)))
660 (if (and (eq cl-test 'eq) (fboundp 'make-hashtable))
661 (funcall 'make-hashtable cl-size)
662 (list 'cl-hash-table-tag cl-test
663 (if (> cl-size 1) (make-vector cl-size 0)
664 (let ((sym (make-symbol "--hashsym--"))) (set sym nil) sym))
667 (defvar cl-lucid-hash-tag
668 (if (and (fboundp 'make-hashtable) (vectorp (make-hashtable 1)))
669 (aref (make-hashtable 1) 0) (make-symbol "--cl-hash-tag--")))
671 (defun hash-table-p (x)
672 "Return t if OBJECT is a hash table."
673 (or (eq (car-safe x) 'cl-hash-table-tag)
674 (and (vectorp x) (= (length x) 4) (eq (aref x 0) cl-lucid-hash-tag))
675 (and (fboundp 'hashtablep) (funcall 'hashtablep x))))
677 (defun cl-not-hash-table (x &optional y &rest z)
678 (signal 'wrong-type-argument (list 'hash-table-p (or y x))))
680 (defun cl-hash-lookup (key table)
681 (or (eq (car-safe table) 'cl-hash-table-tag) (cl-not-hash-table table))
682 (let* ((array (nth 2 table)) (test (car (cdr table))) (str key) sym)
683 (if (symbolp array) (setq str nil sym (symbol-value array))
684 (while (or (consp str) (and (vectorp str) (> (length str) 0)))
685 (setq str (elt str 0)))
686 (cond ((stringp str) (if (eq test 'equalp) (setq str (downcase str))))
687 ((symbolp str) (setq str (symbol-name str)))
688 ((and (numberp str) (> str -8000000) (< str 8000000))
689 (or (integerp str) (setq str (truncate str)))
690 (setq str (aref ["0" "1" "2" "3" "4" "5" "6" "7" "8" "9" "10"
691 "11" "12" "13" "14" "15"] (logand str 15))))
693 (setq sym (symbol-value (intern-soft str array))))
694 (list (and sym (cond ((or (eq test 'eq)
695 (and (eq test 'eql) (not (numberp key))))
697 ((memq test '(eql equal)) (assoc key sym))
698 (t (assoc* key sym ':test test))))
701 (defvar cl-builtin-gethash
702 (if (and (fboundp 'gethash) (subrp (symbol-function 'gethash)))
703 (symbol-function 'gethash) 'cl-not-hash-table))
704 (defvar cl-builtin-remhash
705 (if (and (fboundp 'remhash) (subrp (symbol-function 'remhash)))
706 (symbol-function 'remhash) 'cl-not-hash-table))
707 (defvar cl-builtin-clrhash
708 (if (and (fboundp 'clrhash) (subrp (symbol-function 'clrhash)))
709 (symbol-function 'clrhash) 'cl-not-hash-table))
710 (defvar cl-builtin-maphash
711 (if (and (fboundp 'maphash) (subrp (symbol-function 'maphash)))
712 (symbol-function 'maphash) 'cl-not-hash-table))
714 (defun cl-gethash (key table &optional def)
715 "Look up KEY in HASH-TABLE; return corresponding value, or DEFAULT."
717 (let ((found (cl-hash-lookup key table)))
718 (if (car found) (cdr (car found)) def))
719 (funcall cl-builtin-gethash key table def)))
720 (defalias 'gethash 'cl-gethash)
722 (defun cl-puthash (key val table)
724 (let ((found (cl-hash-lookup key table)))
725 (if (car found) (setcdr (car found) val)
728 (if (> (nth 3 table) (* (length (nth 2 table)) 3))
729 (let ((new-table (make-vector (nth 3 table) 0)))
732 (set (intern (symbol-name sym) new-table)
733 (symbol-value sym))))
735 (setcar (cdr (cdr table)) new-table)))
736 (set (intern (nth 2 found) (nth 2 table))
737 (cons (cons key val) (nth 1 found))))
738 (set (nth 2 table) (cons (cons key val) (nth 1 found))))
739 (setcar (cdr (cdr (cdr table))) (1+ (nth 3 table)))))
740 (funcall 'puthash key val table)) val)
742 (defun cl-remhash (key table)
743 "Remove KEY from HASH-TABLE."
745 (let ((found (cl-hash-lookup key table)))
747 (let ((del (delq (car found) (nth 1 found))))
748 (setcar (cdr (cdr (cdr table))) (1- (nth 3 table)))
749 (if (nth 2 found) (set (intern (nth 2 found) (nth 2 table)) del)
750 (set (nth 2 table) del)) t)))
751 (prog1 (not (eq (funcall cl-builtin-gethash key table '--cl--) '--cl--))
752 (funcall cl-builtin-remhash key table))))
753 (defalias 'remhash 'cl-remhash)
755 (defun cl-clrhash (table)
759 (or (hash-table-p table) (cl-not-hash-table table))
760 (if (symbolp (nth 2 table)) (set (nth 2 table) nil)
761 (setcar (cdr (cdr table)) (make-vector (length (nth 2 table)) 0)))
762 (setcar (cdr (cdr (cdr table))) 0))
763 (funcall cl-builtin-clrhash table))
765 (defalias 'clrhash 'cl-clrhash)
767 (defun cl-maphash (cl-func cl-table)
768 "Call FUNCTION on keys and values from HASH-TABLE."
769 (or (hash-table-p cl-table) (cl-not-hash-table cl-table))
771 (mapatoms (function (lambda (cl-x)
772 (setq cl-x (symbol-value cl-x))
774 (funcall cl-func (car (car cl-x))
776 (setq cl-x (cdr cl-x)))))
777 (if (symbolp (nth 2 cl-table))
778 (vector (nth 2 cl-table)) (nth 2 cl-table)))
779 (funcall cl-builtin-maphash cl-func cl-table)))
780 (defalias 'maphash 'cl-maphash)
782 (defun hash-table-count (table)
783 "Return the number of entries in HASH-TABLE."
784 (or (hash-table-p table) (cl-not-hash-table table))
785 (if (consp table) (nth 3 table) (funcall 'hashtable-fullness table)))
788 ;;; Some debugging aids.
790 (defun cl-prettyprint (form)
791 "Insert a pretty-printed rendition of a Lisp FORM in current buffer."
792 (let ((pt (point)) last)
793 (insert "\n" (prin1-to-string form) "\n")
796 (while (search-forward "(quote " last t)
797 (delete-backward-char 7)
802 (cl-do-prettyprint)))
804 (defun cl-do-prettyprint ()
805 (skip-chars-forward " ")
807 (let ((skip (or (looking-at "((") (looking-at "(prog")
808 (looking-at "(unwind-protect ")
809 (looking-at "(function (")
810 (looking-at "(cl-block-wrapper ")))
811 (two (or (looking-at "(defun ") (looking-at "(defmacro ")))
812 (let (or (looking-at "(let\\*? ") (looking-at "(while ")))
813 (set (looking-at "(p?set[qf] ")))
817 (and (>= (current-column) 78) (progn (backward-sexp) t))))
821 (or skip (looking-at ")") (cl-do-prettyprint))
822 (or (not two) (looking-at ")") (cl-do-prettyprint))
823 (while (not (looking-at ")"))
824 (if set (setq nl (not nl)))
825 (if nl (insert "\n"))
831 (defvar cl-macroexpand-cmacs nil)
832 (defvar cl-closure-vars nil)
834 (defun cl-macroexpand-all (form &optional env)
835 "Expand all macro calls through a Lisp FORM.
836 This also does some trivial optimizations to make the form prettier."
837 (while (or (not (eq form (setq form (macroexpand form env))))
838 (and cl-macroexpand-cmacs
839 (not (eq form (setq form (compiler-macroexpand form)))))))
840 (cond ((not (consp form)) form)
841 ((memq (car form) '(let let*))
842 (if (null (nth 1 form))
843 (cl-macroexpand-all (cons 'progn (cddr form)) env)
844 (let ((letf nil) (res nil) (lets (cadr form)))
846 (cl-push (if (consp (car lets))
847 (let ((exp (cl-macroexpand-all (caar lets) env)))
848 (or (symbolp exp) (setq letf t))
849 (cons exp (cl-macroexpand-body (cdar lets) env)))
850 (let ((exp (cl-macroexpand-all (car lets) env)))
851 (if (symbolp exp) exp
852 (setq letf t) (list exp nil)))) res)
853 (setq lets (cdr lets)))
854 (list* (if letf (if (eq (car form) 'let) 'letf 'letf*) (car form))
855 (nreverse res) (cl-macroexpand-body (cddr form) env)))))
856 ((eq (car form) 'cond)
858 (mapcar (function (lambda (x) (cl-macroexpand-body x env)))
860 ((eq (car form) 'condition-case)
861 (list* (car form) (nth 1 form) (cl-macroexpand-all (nth 2 form) env)
864 (cons (car x) (cl-macroexpand-body (cdr x) env))))
866 ((memq (car form) '(quote function))
867 (if (eq (car-safe (nth 1 form)) 'lambda)
868 (let ((body (cl-macroexpand-body (cddadr form) env)))
869 (if (and cl-closure-vars (eq (car form) 'function)
870 (cl-expr-contains-any body cl-closure-vars))
871 (let* ((new (mapcar 'gensym cl-closure-vars))
872 (sub (pairlis cl-closure-vars new)) (decls nil))
873 (while (or (stringp (car body))
874 (eq (car-safe (car body)) 'interactive))
875 (cl-push (list 'quote (cl-pop body)) decls))
876 (put (car (last cl-closure-vars)) 'used t)
878 (list 'list '(quote lambda) '(quote (&rest --cl-rest--)))
879 (sublis sub (nreverse decls))
881 (list* 'list '(quote apply)
882 (list 'list '(quote quote)
885 (append new (cadadr form))
887 (nconc (mapcar (function
889 (list 'list '(quote quote) x)))
891 '((quote --cl-rest--)))))))
892 (list (car form) (list* 'lambda (cadadr form) body))))
893 (let ((found (assq (cadr form) env)))
894 (if (eq (cadr (caddr found)) 'cl-labels-args)
895 (cl-macroexpand-all (cadr (caddr (cadddr found))) env)
897 ((memq (car form) '(defun defmacro))
898 (list* (car form) (nth 1 form) (cl-macroexpand-body (cddr form) env)))
899 ((and (eq (car form) 'progn) (not (cddr form)))
900 (cl-macroexpand-all (nth 1 form) env))
901 ((eq (car form) 'setq)
902 (let* ((args (cl-macroexpand-body (cdr form) env)) (p args))
903 (while (and p (symbolp (car p))) (setq p (cddr p)))
904 (if p (cl-macroexpand-all (cons 'setf args)) (cons 'setq args))))
905 (t (cons (car form) (cl-macroexpand-body (cdr form) env)))))
907 (defun cl-macroexpand-body (body &optional env)
908 (mapcar (function (lambda (x) (cl-macroexpand-all x env))) body))
910 (defun cl-prettyexpand (form &optional full)
911 (message "Expanding...")
912 (let ((cl-macroexpand-cmacs full) (cl-compiling-file full)
913 (byte-compile-macro-environment nil))
914 (setq form (cl-macroexpand-all form
915 (and (not full) '((block) (eval-when)))))
916 (message "Formatting...")
917 (prog1 (cl-prettyprint form)
922 (run-hooks 'cl-extra-load-hook)
924 ;;; cl-extra.el ends here