+
+(defun last-directory-piece (pathname)
+ (car (last (pathname-directory pathname))))
+
+;;; Part of DIRECTORY: implements iterating over a :WILD or pattern component
+;;; in the directory spec.
+(defun map-wild (function more directory)
+ (let ((this (pop more))
+ (next (car more)))
+ (flet ((cont (subdirectory)
+ (cond ((not more)
+ ;; end of the line
+ (funcall function subdirectory))
+ ((or (eq :wild next) (typep next 'pattern))
+ (map-wild function more subdirectory))
+ ((eq :wild-inferiors next)
+ (map-wild-inferiors function more subdirectory))
+ (t
+ (let ((this (pathname-directory subdirectory)))
+ (map-matching-directories
+ function
+ (make-pathname :directory (append this more)
+ :defaults subdirectory)))))))
+ (map-directory
+ (if (eq :wild this)
+ #'cont
+ (lambda (sub)
+ (when (pattern-matches this (last-directory-piece sub))
+ (funcall #'cont sub))))
+ directory
+ :files nil
+ :directories t
+ :errorp nil))))
+
+;;; Part of DIRECTORY: implements iterating over a :WILD-INFERIORS component
+;;; in the directory spec.
+(defun map-wild-inferiors (function more directory)
+ (loop while (member (car more) '(:wild :wild-inferiors))
+ do (pop more))
+ (let ((next (car more))
+ (rest (cdr more)))
+ (unless more
+ (funcall function directory))
+ (map-directory
+ (cond ((not more)
+ (lambda (pathname)
+ (funcall function pathname)
+ (map-wild-inferiors function more pathname)))
+ (t
+ (lambda (pathname)
+ (let ((this (pathname-directory pathname)))
+ (when (equal next (car (last this)))
+ (map-matching-directories
+ function
+ (make-pathname :directory (append this rest)
+ :defaults pathname)))
+ (map-wild-inferiors function more pathname)))))
+ directory
+ :files nil
+ :directories t
+ :errorp nil)))
+
+;;; Part of DIRECTORY: implements iterating over entries in a directory, and
+;;; matching them.
+(defun map-matching-entries (function directory match-name match-type)
+ (map-directory
+ (lambda (file)
+ (when (and (funcall match-name (pathname-name file))
+ (funcall match-type (pathname-type file)))
+ (funcall function file)))
+ directory
+ :files t
+ :directories :as-files
+ :errorp nil))
+
+;;; NOTE: There is a fair amount of hair below that is probably not
+;;; strictly necessary.
+;;;
+;;; The issue is the following: what does (DIRECTORY "SYS:*;") mean?
+;;; Until 2004-01, SBCL's behaviour was unquestionably wrong, as it
+;;; did not translate the logical pathname at all, but instead treated
+;;; it as a physical one. Other Lisps seem to to treat this call as
+;;; equivalent to (DIRECTORY (TRANSLATE-LOGICAL-PATHNAME "SYS:*;")),
+;;; which is fine as far as it goes, but not very interesting, and
+;;; arguably counterintuitive. (PATHNAME-MATCH-P "SYS:SRC;" "SYS:*;")
+;;; is true, so why should "SYS:SRC;" not show up in the call to
+;;; DIRECTORY? (assuming the physical pathname corresponding to it
+;;; exists, of course).
+;;;
+;;; So, the interpretation that I am pushing is for all pathnames
+;;; matching the input pathname to be queried. This means that we
+;;; need to compute the intersection of the input pathname and the
+;;; logical host FROM translations, and then translate the resulting
+;;; pathname using the host to the TO translation; this treatment is
+;;; recursively invoked until we get a physical pathname, whereupon
+;;; our physical DIRECTORY implementation takes over.
+
+;;; FIXME: this is an incomplete implementation. It only works when
+;;; both are logical pathnames (which is OK, because that's the only
+;;; case when we call it), but there are other pitfalls as well: see
+;;; the DIRECTORY-HELPER below for some, but others include a lack of
+;;; pattern handling.
+
+;;; The above was written by CSR, I (RMK) believe. The argument that
+;;; motivates the interpretation is faulty, however: PATHNAME-MATCH-P
+;;; returns true for (PATHNAME-MATCH-P #P"/tmp/*/" #P"/tmp/../"), but
+;;; the latter pathname is not in the result of DIRECTORY on the
+;;; former. Indeed, if DIRECTORY were constrained to return the
+;;; truename for every pathname for which PATHNAME-MATCH-P returned
+;;; true and which denoted a filename that named an existing file,
+;;; (DIRECTORY #P"/tmp/**/") would be required to list every file on a
+;;; Unix system, since any file can be named as though it were "below"
+;;; /tmp, given the dotdot entries. So I think the strongest
+;;; "consistency" we can define between PATHNAME-MATCH-P and DIRECTORY
+;;; is that PATHNAME-MATCH-P returns true of everything DIRECTORY
+;;; returns, but not vice versa.
+
+;;; In any case, even if the motivation were sound, DIRECTORY on a
+;;; wild logical pathname has no portable semantics. I see nothing in
+;;; ANSI that requires implementations to support wild physical
+;;; pathnames, and so there need not be any translation of a wild
+;;; logical pathname to a phyiscal pathname. So a program that calls
+;;; DIRECTORY on a wild logical pathname is doing something
+;;; non-portable at best. And if the only sensible semantics for
+;;; DIRECTORY on a wild logical pathname is something like the
+;;; following, it would be just as well if it signaled an error, since
+;;; a program can't possibly rely on the result of an intersection of
+;;; user-defined translations with a file system probe. (Potentially
+;;; useful kinds of "pathname" that might not support wildcards could
+;;; include pathname hosts that model unqueryable namespaces like HTTP
+;;; URIs, or that model namespaces that it's not convenient to
+;;; investigate, such as the namespace of TCP ports that some network
+;;; host listens on. I happen to think it a bad idea to try to
+;;; shoehorn such namespaces into a pathnames system, but people
+;;; sometimes claim to want pathnames for these things.) -- RMK
+;;; 2007-12-31.
+
+(defun pathname-intersections (one two)
+ (aver (logical-pathname-p one))
+ (aver (logical-pathname-p two))
+ (labels
+ ((intersect-version (one two)
+ (aver (typep one '(or null (member :newest :wild :unspecific)
+ integer)))
+ (aver (typep two '(or null (member :newest :wild :unspecific)
+ integer)))
+ (cond
+ ((eq one :wild) two)
+ ((eq two :wild) one)
+ ((or (null one) (eq one :unspecific)) two)
+ ((or (null two) (eq two :unspecific)) one)
+ ((eql one two) one)
+ (t nil)))
+ (intersect-name/type (one two)
+ (aver (typep one '(or null (member :wild :unspecific) string)))
+ (aver (typep two '(or null (member :wild :unspecific) string)))
+ (cond
+ ((eq one :wild) two)
+ ((eq two :wild) one)
+ ((or (null one) (eq one :unspecific)) two)
+ ((or (null two) (eq two :unspecific)) one)
+ ((string= one two) one)
+ (t nil)))
+ (intersect-directory (one two)
+ (aver (typep one '(or null (member :wild :unspecific) list)))
+ (aver (typep two '(or null (member :wild :unspecific) list)))
+ (cond
+ ((eq one :wild) two)
+ ((eq two :wild) one)
+ ((or (null one) (eq one :unspecific)) two)
+ ((or (null two) (eq two :unspecific)) one)
+ (t (aver (eq (car one) (car two)))
+ (mapcar
+ (lambda (x) (cons (car one) x))
+ (intersect-directory-helper (cdr one) (cdr two)))))))
+ (let ((version (intersect-version
+ (pathname-version one) (pathname-version two)))
+ (name (intersect-name/type
+ (pathname-name one) (pathname-name two)))
+ (type (intersect-name/type
+ (pathname-type one) (pathname-type two)))
+ (host (pathname-host one)))
+ (mapcar (lambda (d)
+ (make-pathname :host host :name name :type type
+ :version version :directory d))
+ (intersect-directory
+ (pathname-directory one) (pathname-directory two))))))
+
+;;; FIXME: written as its own function because I (CSR) don't
+;;; understand it, so helping both debuggability and modularity. In
+;;; case anyone is motivated to rewrite it, it returns a list of
+;;; sublists representing the intersection of the two input directory
+;;; paths (excluding the initial :ABSOLUTE or :RELATIVE).
+;;;
+;;; FIXME: Does not work with :UP or :BACK
+;;; FIXME: Does not work with patterns
+;;;
+;;; FIXME: PFD suggests replacing this implementation with a DFA
+;;; conversion of a NDFA. Find out (a) what this means and (b) if it
+;;; turns out to be worth it.
+(defun intersect-directory-helper (one two)
+ (flet ((simple-intersection (cone ctwo)
+ (cond
+ ((eq cone :wild) ctwo)
+ ((eq ctwo :wild) cone)
+ (t (aver (typep cone 'string))
+ (aver (typep ctwo 'string))
+ (if (string= cone ctwo) cone nil)))))
+ (macrolet
+ ((loop-possible-wild-inferiors-matches
+ (lower-bound bounding-sequence order)
+ (let ((index (gensym)) (g2 (gensym)) (g3 (gensym)) (l (gensym)))
+ `(let ((,l (length ,bounding-sequence)))
+ (loop for ,index from ,lower-bound to ,l
+ append (mapcar (lambda (,g2)
+ (append
+ (butlast ,bounding-sequence (- ,l ,index))
+ ,g2))
+ (mapcar
+ (lambda (,g3)
+ (append
+ (if (eq (car (nthcdr ,index ,bounding-sequence))
+ :wild-inferiors)
+ '(:wild-inferiors)
+ nil) ,g3))
+ (intersect-directory-helper
+ ,@(if order
+ `((nthcdr ,index one) (cdr two))
+ `((cdr one) (nthcdr ,index two)))))))))))
+ (cond
+ ((and (eq (car one) :wild-inferiors)
+ (eq (car two) :wild-inferiors))
+ (delete-duplicates
+ (append (mapcar (lambda (x) (cons :wild-inferiors x))
+ (intersect-directory-helper (cdr one) (cdr two)))
+ (loop-possible-wild-inferiors-matches 2 one t)
+ (loop-possible-wild-inferiors-matches 2 two nil))
+ :test 'equal))
+ ((eq (car one) :wild-inferiors)
+ (delete-duplicates (loop-possible-wild-inferiors-matches 0 two nil)
+ :test 'equal))
+ ((eq (car two) :wild-inferiors)
+ (delete-duplicates (loop-possible-wild-inferiors-matches 0 one t)
+ :test 'equal))
+ ((and (null one) (null two)) (list nil))
+ ((null one) nil)
+ ((null two) nil)
+ (t (and (simple-intersection (car one) (car two))
+ (mapcar (lambda (x) (cons (simple-intersection
+ (car one) (car two)) x))
+ (intersect-directory-helper (cdr one) (cdr two)))))))))