(in-package "SB!IMPL")
+;;; Limitation: no list might have more than INDEX conses.
+
;;;; KLUDGE: comment from CMU CL, what does it mean?
;;;; NSUBLIS, things at the beginning broken.
;;;; -- WHN 20000127
(cdr list))
(defun nthcdr (n list)
- (declare (type index n))
#!+sb-doc
"Performs the cdr function n times on a list."
- (do ((i n (1- i))
- (result list (cdr result)))
- ((not (plusp i)) result)
- (declare (type index i))))
+ (flet ((fast-nthcdr (n list)
+ (declare (type index n))
+ (do ((i n (1- i))
+ (result list (cdr result)))
+ ((not (plusp i)) result)
+ (declare (type index i)))))
+ (typecase n
+ (index (fast-nthcdr n list))
+ (t (do ((i 0 (1+ i))
+ (r-i list (cdr r-i))
+ (r-2i list (cddr r-2i)))
+ ((and (eq r-i r-2i) (not (zerop i)))
+ (fast-nthcdr (mod n i) r-i))
+ (declare (type index i)))))))
(defun last (list &optional (n 1))
#!+sb-doc
"Return the last N conses (not the last element!) of a list."
- (declare (type index n))
- (do ((checked-list list (cdr checked-list))
- (returned-list list)
- (index 0 (1+ index)))
- ((atom checked-list) returned-list)
- (declare (type index index))
- (if (>= index n)
- (pop returned-list))))
+ (if (typep n 'index)
+ (do ((checked-list list (cdr checked-list))
+ (returned-list list)
+ (index 0 (1+ index)))
+ ((atom checked-list) returned-list)
+ (declare (type index index))
+ (if (>= index n)
+ (pop returned-list)))
+ list))
(defun list (&rest args)
#!+sb-doc
(let ((result (list (car list))))
(do ((x (cdr list) (cdr x))
(splice result
- (cdr (rplacd splice (cons (car x) '() ))) ))
+ (cdr (rplacd splice (cons (car x) '())))))
((atom x)
(unless (null x)
(rplacd splice x))))
(defun copy-alist (alist)
#!+sb-doc
"Return a new association list which is EQUAL to ALIST."
- (if (atom alist)
+ (if (endp alist)
alist
(let ((result
(cons (if (atom (car alist))
(car alist)
- (cons (caar alist) (cdar alist)) )
+ (cons (caar alist) (cdar alist)))
nil)))
(do ((x (cdr alist) (cdr x))
(splice result
(car x)
(cons (caar x) (cdar x)))
nil)))))
- ;; Non-null terminated alist done here.
- ((atom x)
- (unless (null x)
- (rplacd splice x))))
+ ((endp x)))
result)))
(defun copy-tree (object)
(defun nreconc (x y)
#!+sb-doc
"Return (NCONC (NREVERSE X) Y)."
- (do ((1st (cdr x) (if (atom 1st) 1st (cdr 1st)))
+ (do ((1st (cdr x) (if (endp 1st) 1st (cdr 1st)))
(2nd x 1st) ;2nd follows first down the list.
(3rd y 2nd)) ;3rd follows 2nd down the list.
((atom 2nd) 3rd)
(declare (type index result)))))
(declare (ftype (function (t) index) count-conses))
(defun butlast (list &optional (n 1))
- (let ((n-conses-in-list (count-conses list)))
- (cond ((zerop n)
- ;; (We can't use SUBSEQ in this case because LIST isn't
- ;; necessarily a proper list, but SUBSEQ expects a
- ;; proper sequence. COPY-LIST isn't so fussy.)
- (copy-list list))
- ((>= n n-conses-in-list)
- nil)
- (t
- ;; (LIST isn't necessarily a proper list in this case
- ;; either, and technically SUBSEQ wants a proper
- ;; sequence, but no reasonable implementation of SUBSEQ
- ;; will actually walk down to the end of the list to
- ;; check, and since we're calling our own implementation
- ;; we know it's reasonable, so it's OK.)
- (subseq list 0 (- n-conses-in-list n))))))
+ (if (typep n 'index)
+ (let ((n-conses-in-list (count-conses list)))
+ (cond ((zerop n)
+ ;; (We can't use SUBSEQ in this case because LIST isn't
+ ;; necessarily a proper list, but SUBSEQ expects a
+ ;; proper sequence. COPY-LIST isn't so fussy.)
+ (copy-list list))
+ ((>= n n-conses-in-list)
+ nil)
+ (t
+ ;; (LIST isn't necessarily a proper list in this case
+ ;; either, and technically SUBSEQ wants a proper
+ ;; sequence, but no reasonable implementation of SUBSEQ
+ ;; will actually walk down to the end of the list to
+ ;; check, and since we're calling our own implementation
+ ;; we know it's reasonable, so it's OK.)
+ (subseq list 0 (- n-conses-in-list n)))))
+ nil))
(defun nbutlast (list &optional (n 1))
- (if (zerop n)
- list
- (let ((n-conses-in-list (count-conses list)))
- (unless (<= n-conses-in-list n)
- (setf (cdr (nthcdr (- n-conses-in-list n 1) list))
- nil)
- list)))))
+ (cond ((zerop n)
+ list)
+ ((not (typep n 'index))
+ nil)
+ (t (let ((n-conses-in-list (count-conses list)))
+ (unless (<= n-conses-in-list n)
+ (setf (cdr (nthcdr (- n-conses-in-list n 1) list))
+ nil)
+ list))))))
(defun ldiff (list object)
"Return a new list, whose elements are those of LIST that appear before
;;; Set the Nth element of LIST to NEWVAL.
(defun %setnth (n list newval)
- (declare (type index n))
- (do ((count n (1- count))
- (list list (cdr list)))
- ((endp list)
- (error "~S is too large an index for SETF of NTH." n))
- (declare (type fixnum count))
- (when (<= count 0)
- (rplaca list newval)
- (return newval))))
+ (typecase n
+ (index
+ (do ((count n (1- count))
+ (list list (cdr list)))
+ ((endp list)
+ (error "~S is too large an index for SETF of NTH." n))
+ (declare (type fixnum count))
+ (when (<= count 0)
+ (rplaca list newval)
+ (return newval))))
+ (t (let ((cons (nthcdr n list)))
+ (when (endp cons)
+ (error "~S is too large an index for SETF of NTH." n))
+ (rplaca cons newval)
+ newval))))
\f
;;;; :KEY arg optimization to save funcall of IDENTITY
((atom subtree) subtree)
(t (let ((car (s (car subtree)))
(cdr (s (cdr subtree))))
- (if (and (eq car (car subtreE))
+ (if (and (eq car (car subtree))
(eq cdr (cdr subtree)))
subtree
(cons car cdr))))))))
;; reached, what is left of LIST2 is tacked onto what is left of
;; LIST1. The splicing operation ensures that the correct
;; operation is performed depending on whether splice is at the
- ;; top of the list or not
+ ;; top of the list or not.
(do ((list1 list1)
(list2 list2)
(x list1 (cdr x))
- (splicex ()))
+ (splicex ())
+ (deleted-y ())
+ ;; elements of LIST2, which are "equal" to some processed
+ ;; earlier elements of LIST1
+ )
((endp x)
(if (null splicex)
(setq list1 list2)
(rplacd splicex list2))
list1)
- (do ((y list2 (cdr y))
- (splicey ()))
- ((endp y) (setq splicex x))
- (cond ((let ((key-val-x (apply-key key (car x)))
- (key-val-y (apply-key key (Car y))))
- (if notp
- (not (funcall test-not key-val-x key-val-y))
- (funcall test key-val-x key-val-y)))
- (if (null splicex)
- (setq list1 (cdr x))
- (rplacd splicex (cdr x)))
- (if (null splicey)
- (setq list2 (cdr y))
- (rplacd splicey (cdr y)))
- (return ())) ; assume lists are really sets
- (t (setq splicey y)))))))
+ (let ((key-val-x (apply-key key (car x)))
+ (found-duplicate nil))
+
+ ;; Move all elements from LIST2, which are "equal" to (CAR X),
+ ;; to DELETED-Y.
+ (do* ((y list2 next-y)
+ (next-y (cdr y) (cdr y))
+ (splicey ()))
+ ((endp y))
+ (cond ((let ((key-val-y (apply-key key (car y))))
+ (if notp
+ (not (funcall test-not key-val-x key-val-y))
+ (funcall test key-val-x key-val-y)))
+ (if (null splicey)
+ (setq list2 (cdr y))
+ (rplacd splicey (cdr y)))
+ (setq deleted-y (rplacd y deleted-y))
+ (setq found-duplicate t))
+ (t (setq splicey y))))
+
+ (unless found-duplicate
+ (setq found-duplicate (with-set-keys (member key-val-x deleted-y))))
+
+ (if found-duplicate
+ (if (null splicex)
+ (setq list1 (cdr x))
+ (rplacd splicex (cdr x)))
+ (setq splicex x))))))
(defun subsetp (list1 list2 &key key (test #'eql testp) (test-not nil notp))
#!+sb-doc