(in-package :alexandria) (declaim (inline safe-endp)) (defun safe-endp (x) (declare (optimize safety)) (endp x)) (defun alist-plist (alist) "Returns a property list containing the same keys and values as the association list ALIST in the same order." (let (plist) (dolist (pair alist) (push (car pair) plist) (push (cdr pair) plist)) (nreverse plist))) (defun plist-alist (plist) "Returns an association list containing the same keys and values as the property list PLIST in the same order." (let (alist) (do ((tail plist (cddr tail))) ((safe-endp tail) (nreverse alist)) (push (cons (car tail) (cadr tail)) alist)))) (declaim (inline racons)) (defun racons (key value ralist) (acons value key ralist)) (macrolet ((define-alist-get (name get-entry get-value-from-entry add doc) `(progn (declaim (inline ,name)) (defun ,name (alist key &key (test 'eql)) ,doc (let ((entry (,get-entry key alist :test test))) (values (,get-value-from-entry entry) entry))) (define-setf-expander ,name (place key &key (test ''eql) &environment env) (multiple-value-bind (temporary-variables initforms newvals setter getter) (get-setf-expansion place env) (when (cdr newvals) (error "~A cannot store multiple values in one place" ',name)) (with-unique-names (new-value key-val test-val alist entry) (values (append temporary-variables (list alist key-val test-val entry)) (append initforms (list getter key test `(,',get-entry ,key-val ,alist :test ,test-val))) `(,new-value) `(cond (,entry (setf (,',get-value-from-entry ,entry) ,new-value)) (t (let ,newvals (setf ,(first newvals) (,',add ,key ,new-value ,alist)) ,setter ,new-value))) `(,',get-value-from-entry ,entry)))))))) (define-alist-get assoc-value assoc cdr acons "ASSOC-VALUE is an alist accessor very much like ASSOC, but it can be used with SETF.") (define-alist-get rassoc-value rassoc car racons "RASSOC-VALUE is an alist accessor very much like RASSOC, but it can be used with SETF.")) (defun malformed-plist (plist) (error "Malformed plist: ~S" plist)) (defmacro doplist ((key val plist &optional values) &body body) "Iterates over elements of PLIST. BODY can be preceded by declarations, and is like a TAGBODY. RETURN may be used to terminate the iteration early. If RETURN is not used, returns VALUES." (multiple-value-bind (forms declarations) (parse-body body) (with-gensyms (tail loop results) `(block nil (flet ((,results () (let (,key ,val) (declare (ignorable ,key ,val)) (return ,values)))) (let* ((,tail ,plist) (,key (if ,tail (pop ,tail) (,results))) (,val (if ,tail (pop ,tail) (malformed-plist ',plist)))) (declare (ignorable ,key ,val)) ,@declarations (tagbody ,loop ,@forms (setf ,key (if ,tail (pop ,tail) (,results)) ,val (if ,tail (pop ,tail) (malformed-plist ',plist))) (go ,loop)))))))) (define-modify-macro appendf (&rest lists) append "Modify-macro for APPEND. Appends LISTS to the place designated by the first argument.") (define-modify-macro nconcf (&rest lists) nconc "Modify-macro for NCONC. Concatenates LISTS to place designated by the first argument.") (define-modify-macro unionf (list &rest args) union "Modify-macro for UNION. Saves the union of LIST and the contents of the place designated by the first argument to the designated place.") (define-modify-macro nunionf (list &rest args) nunion "Modify-macro for NUNION. Saves the union of LIST and the contents of the place designated by the first argument to the designated place. May modify either argument.") (define-modify-macro reversef () reverse "Modify-macro for REVERSE. Copies and reverses the list stored in the given place and saves back the result into the place.") (define-modify-macro nreversef () nreverse "Modify-macro for NREVERSE. Reverses the list stored in the given place by destructively modifying it and saves back the result into the place.") (defun circular-list (&rest elements) "Creates a circular list of ELEMENTS." (let ((cycle (copy-list elements))) (nconc cycle cycle))) (defun circular-list-p (object) "Returns true if OBJECT is a circular list, NIL otherwise." (and (listp object) (do ((fast object (cddr fast)) (slow (cons (car object) (cdr object)) (cdr slow))) (nil) (unless (and (consp fast) (listp (cdr fast))) (return nil)) (when (eq fast slow) (return t))))) (defun circular-tree-p (object) "Returns true if OBJECT is a circular tree, NIL otherwise." (labels ((circularp (object seen) (and (consp object) (do ((fast (cons (car object) (cdr object)) (cddr fast)) (slow object (cdr slow))) (nil) (when (or (eq fast slow) (member slow seen)) (return-from circular-tree-p t)) (when (or (not (consp fast)) (not (consp (cdr slow)))) (return (do ((tail object (cdr tail))) ((not (consp tail)) nil) (let ((elt (car tail))) (circularp elt (cons object seen)))))))))) (circularp object nil))) (defun proper-list-p (object) "Returns true if OBJECT is a proper list." (cond ((not object) t) ((consp object) (do ((fast object (cddr fast)) (slow (cons (car object) (cdr object)) (cdr slow))) (nil) (unless (and (listp fast) (consp (cdr fast))) (return (and (listp fast) (not (cdr fast))))) (when (eq fast slow) (return nil)))) (t nil))) (deftype proper-list () "Type designator for proper lists. Implemented as a SATISFIES type, hence not recommended for performance intensive use. Main usefullness as a type designator of the expected type in a TYPE-ERROR." `(and list (satisfies proper-list-p))) (defun circular-list-error (list) (error 'type-error :datum list :expected-type '(and list (not circular-list)))) (macrolet ((def (name lambda-list doc step declare ret1 ret2) (assert (member 'list lambda-list)) `(defun ,name ,lambda-list ,doc (do ((last list fast) (fast list (cddr fast)) (slow (cons (car list) (cdr list)) (cdr slow)) ,@(when step (list step))) (nil) (declare (dynamic-extent slow) ,@(when declare (list declare)) (ignorable last)) (when (safe-endp fast) (return ,ret1)) (when (safe-endp (cdr fast)) (return ,ret2)) (when (eq fast slow) (circular-list-error list)))))) (def proper-list-length (list) "Returns length of LIST, signalling an error if it is not a proper list." (n 1 (+ n 2)) ;; KLUDGE: Most implementations don't actually support lists with bignum ;; elements -- and this is WAY faster on most implementations then declaring ;; N to be an UNSIGNED-BYTE. (fixnum n) (1- n) n) (def lastcar (list) "Returns the last element of LIST. Signals a type-error if LIST is not a proper list." nil nil (cadr last) (car fast)) (def (setf lastcar) (object list) "Sets the last element of LIST. Signals a type-error if LIST is not a proper list." nil nil (setf (cadr last) object) (setf (car fast) object))) (defun make-circular-list (length &key initial-element) "Creates a circular list of LENGTH with the given INITIAL-ELEMENT." (let ((cycle (make-list length :initial-element initial-element))) (nconc cycle cycle))) (deftype circular-list () "Type designator for circular lists. Implemented as a SATISFIES type, so not recommended for performance intensive use. Main usefullness as the expected-type designator of a TYPE-ERROR." `(satisfies circular-list-p)) (defun ensure-car (thing) "If THING is a CONS, its CAR is returned. Otherwise THING is returned." (if (consp thing) (car thing) thing)) (defun ensure-cons (cons) "If CONS is a cons, it is returned. Otherwise returns a fresh cons with CONS in the car, and NIL in the cdr." (if (consp cons) cons (cons cons nil))) (defun ensure-list (list) "If LIST is a list, it is returned. Otherwise returns the list designated by LIST." (if (listp list) list (list list))) (defun remove-from-plist (plist &rest keys) "Returns a propery-list with same keys and values as PLIST, except that keys in the list designated by KEYS and values corresponding to them are removed. The returned property-list may share structure with the PLIST, but PLIST is not destructively modified. Keys are compared using EQ." (declare (optimize (speed 3))) ;; FIXME: possible optimization: (remove-from-plist '(:x 0 :a 1 :b 2) :a) ;; could return the tail without consing up a new list. (loop for (key . rest) on plist by #'cddr do (assert rest () "Expected a proper plist, got ~S" plist) unless (member key keys :test #'eq) collect key and collect (first rest))) (defun delete-from-plist (plist &rest keys) "Just like REMOVE-FROM-PLIST, but this version may destructively modify the provided plist." ;; FIXME: should not cons (apply 'remove-from-plist plist keys)) (define-modify-macro remove-from-plistf (&rest keys) remove-from-plist "Modify macro for REMOVE-FROM-PLIST.") (define-modify-macro delete-from-plistf (&rest keys) delete-from-plist "Modify macro for DELETE-FROM-PLIST.") (declaim (inline sans)) (defun sans (plist &rest keys) "Alias of REMOVE-FROM-PLIST for backward compatibility." (apply #'remove-from-plist plist keys)) (defun mappend (function &rest lists) "Applies FUNCTION to respective element(s) of each LIST, appending all the all the result list to a single list. FUNCTION must return a list." (loop for results in (apply #'mapcar function lists) append results)) (defun setp (object &key (test #'eql) (key #'identity)) "Returns true if OBJECT is a list that denotes a set, NIL otherwise. A list denotes a set if each element of the list is unique under KEY and TEST." (and (listp object) (let (seen) (dolist (elt object t) (let ((key (funcall key elt))) (if (member key seen :test test) (return nil) (push key seen))))))) (defun set-equal (list1 list2 &key (test #'eql) (key nil keyp)) "Returns true if every element of LIST1 matches some element of LIST2 and every element of LIST2 matches some element of LIST1. Otherwise returns false." (let ((keylist1 (if keyp (mapcar key list1) list1)) (keylist2 (if keyp (mapcar key list2) list2))) (and (dolist (elt keylist1 t) (or (member elt keylist2 :test test) (return nil))) (dolist (elt keylist2 t) (or (member elt keylist1 :test test) (return nil)))))) (defun map-product (function list &rest more-lists) "Returns a list containing the results of calling FUNCTION with one argument from LIST, and one from each of MORE-LISTS for each combination of arguments. In other words, returns the product of LIST and MORE-LISTS using FUNCTION. Example: (map-product 'list '(1 2) '(3 4) '(5 6)) => ((1 3 5) (1 3 6) (1 4 5) (1 4 6) (2 3 5) (2 3 6) (2 4 5) (2 4 6)) " (labels ((%map-product (f lists) (let ((more (cdr lists)) (one (car lists))) (if (not more) (mapcar f one) (mappend (lambda (x) (%map-product (curry f x) more)) one))))) (%map-product (ensure-function function) (cons list more-lists)))) (defun flatten (tree) "Traverses the tree in order, collecting non-null leaves into a list." (let (list) (labels ((traverse (subtree) (when subtree (if (consp subtree) (progn (traverse (car subtree)) (traverse (cdr subtree))) (push subtree list))))) (traverse tree)) (nreverse list)))