(T (setq splice x)))))
(deftransform fill ((seq item &key (start 0) (end (length seq)))
- (simple-array t &key (:start t) (:end index)))
+ (vector t &key (:start t) (:end index))
+ *
+ :policy (> speed space))
"open code"
- '(do ((i start (1+ i)))
- ((= i end) seq)
- (declare (type index i))
- (setf (aref seq i) item)))
-
-(deftransform position ((item list &key (test #'eql)) (t list))
- "open code"
- '(do ((i 0 (1+ i))
- (l list (cdr l)))
- ((endp l) nil)
- (declare (type index i))
- (when (funcall test item (car l)) (return i))))
-
-(deftransform position ((item vec &key (test #'eql) (start 0)
- (end (length vec)))
- (t simple-array &key (:start t) (:end index)))
- "open code"
- '(do ((i start (1+ i)))
- ((= i end) nil)
- (declare (type index i))
- (when (funcall test item (aref vec i)) (return i))))
-
-;;; names of predicates that compute the same value as CHAR= when
-;;; applied to characters
-(defparameter *char=-functions* '(eql equal char=))
-
-(deftransform search ((string1 string2 &key (start1 0) end1 (start2 0) end2
- test)
- (simple-string simple-string &rest t))
- (unless (or (not test)
- (continuation-function-is test *char=-functions*))
- (give-up-ir1-transform))
- '(sb!impl::%sp-string-search string1 start1 (or end1 (length string1))
- string2 start2 (or end2 (length string2))))
-
-(deftransform position ((item sequence &key from-end test (start 0) end)
- (t simple-string &rest t))
- (unless (or (not test)
- (continuation-function-is test *char=-functions*))
- (give-up-ir1-transform))
- `(and (typep item 'character)
- (,(if (constant-value-or-lose from-end)
- 'sb!impl::%sp-reverse-find-character
- 'sb!impl::%sp-find-character)
- sequence start (or end (length sequence))
- item)))
-
-(deftransform find ((item sequence &key from-end (test #'eql) (start 0) end)
- (t simple-string &rest t))
- `(if (position item sequence
- ,@(when from-end `(:from-end from-end))
- :test test :start start :end end)
- item
- nil))
+ (let ((element-type (upgraded-element-type-specifier-or-give-up seq)))
+ `(with-array-data ((data seq)
+ (start start)
+ (end end))
+ (declare (type (simple-array ,element-type 1) data))
+ (do ((i start (1+ i)))
+ ((= i end) seq)
+ (declare (type index i))
+ ;; WITH-ARRAY-DATA did our range checks once and for all, so
+ ;; it'd be wasteful to check again on every AREF.
+ (declare (optimize (safety 0)))
+ (setf (aref data i) item)))))
\f
;;;; utilities
null-type)
((cons-type-p type)
(cons-type-cdr-type type)))))
+\f
+;;;; FIND, POSITION, and their -IF and -IF-NOT variants
+
+;;; We want to make sure that %FIND-POSITION is inline-expanded into
+;;; %FIND-POSITION-IF only when %FIND-POSITION-IF has an inline
+;;; expansion, so we factor out the condition into this function.
+(defun check-inlineability-of-find-position-if (sequence from-end)
+ (let ((ctype (continuation-type sequence)))
+ (cond ((csubtypep ctype (specifier-type 'vector))
+ ;; It's not worth trying to inline vector code unless we
+ ;; know a fair amount about it at compile time.
+ (upgraded-element-type-specifier-or-give-up sequence)
+ (unless (constant-continuation-p from-end)
+ (give-up-ir1-transform
+ "FROM-END argument value not known at compile time")))
+ ((csubtypep ctype (specifier-type 'list))
+ ;; Inlining on lists is generally worthwhile.
+ )
+ (t
+ (give-up-ir1-transform
+ "sequence type not known at compile time")))))
+
+;;; %FIND-POSITION-IF for LIST data
+(deftransform %find-position-if ((predicate sequence from-end start end key)
+ (function list t t t function)
+ *
+ :policy (> speed space)
+ :important t)
+ "expand inline"
+ '(let ((index 0)
+ (find nil)
+ (position nil))
+ (declare (type index index))
+ (dolist (i sequence (values find position))
+ (let ((key-i (funcall key i)))
+ (when (and end (>= index end))
+ (return (values find position)))
+ (when (>= index start)
+ (when (funcall predicate key-i)
+ ;; This hack of dealing with non-NIL FROM-END for list data
+ ;; by iterating forward through the list and keeping track of
+ ;; the last time we found a match might be more screwy than
+ ;; what the user expects, but it seems to be allowed by the
+ ;; ANSI standard. (And if the user is screwy enough to ask
+ ;; for FROM-END behavior on list data, turnabout is fair play.)
+ ;;
+ ;; It's also not enormously efficient, calling PREDICATE and
+ ;; KEY more often than necessary; but all the alternatives
+ ;; seem to have their own efficiency problems.
+ (if from-end
+ (setf find i
+ position index)
+ (return (values i index))))))
+ (incf index))))
+
+;;; %FIND-POSITION for LIST data can be expanded into %FIND-POSITION-IF
+;;; without loss of efficiency. (I.e., the optimizer should be able
+;;; to straighten everything out.)
+(deftransform %find-position ((item sequence from-end start end key test)
+ (t list t t t t t)
+ *
+ :policy (> speed space)
+ :important t)
+ "expand inline"
+ '(%find-position-if (let ((test-fun (%coerce-callable-to-function test)))
+ (lambda (i)
+ (funcall test-fun i item)))
+ sequence
+ from-end
+ start
+ end
+ (%coerce-callable-to-function key)))
+
+;;; The inline expansions for the VECTOR case are saved as macros so
+;;; that we can share them between the DEFTRANSFORMs and the default
+;;; cases in the DEFUNs. (This isn't needed for the LIST case, because
+;;; the DEFTRANSFORMs for LIST are less choosy about when to expand.)
+(defun %find-position-or-find-position-if-vector-expansion (sequence-arg
+ from-end
+ start
+ end-arg
+ element
+ done-p-expr)
+ (let ((offset (gensym "OFFSET"))
+ (block (gensym "BLOCK"))
+ (index (gensym "INDEX"))
+ (n-sequence (gensym "N-SEQUENCE-"))
+ (sequence (gensym "SEQUENCE"))
+ (n-end (gensym "N-END-"))
+ (end (gensym "END-")))
+ `(let ((,n-sequence ,sequence-arg)
+ (,n-end ,end-arg))
+ (with-array-data ((,sequence ,n-sequence :offset-var ,offset)
+ (,start ,start)
+ (,end (or ,n-end (length ,n-sequence))))
+ (block ,block
+ (macrolet ((maybe-return ()
+ '(let ((,element (aref ,sequence ,index)))
+ (when ,done-p-expr
+ (return-from ,block
+ (values ,element
+ (- ,index ,offset)))))))
+ (if ,from-end
+ (loop for ,index
+ ;; (If we aren't fastidious about declaring that
+ ;; INDEX might be -1, then (FIND 1 #() :FROM-END T)
+ ;; can send us off into never-never land, since
+ ;; INDEX is initialized to -1.)
+ of-type index-or-minus-1
+ from (1- ,end) downto ,start do
+ (maybe-return))
+ (loop for ,index of-type index from ,start below ,end do
+ (maybe-return))))
+ (values nil nil))))))
+
+(def!macro %find-position-vector-macro (item sequence
+ from-end start end key test)
+ (let ((element (gensym "ELEMENT")))
+ (%find-position-or-find-position-if-vector-expansion
+ sequence
+ from-end
+ start
+ end
+ element
+ `(funcall ,test ,item (funcall ,key ,element)))))
+
+(def!macro %find-position-if-vector-macro (predicate sequence
+ from-end start end key)
+ (let ((element (gensym "ELEMENT")))
+ (%find-position-or-find-position-if-vector-expansion
+ sequence
+ from-end
+ start
+ end
+ element
+ `(funcall ,predicate (funcall ,key ,element)))))
+
+;;; %FIND-POSITION and %FIND-POSITION-IF for VECTOR data
+(deftransform %find-position-if ((predicate sequence from-end start end key)
+ (function vector t t t function)
+ *
+ :policy (> speed space)
+ :important t)
+ "expand inline"
+ (check-inlineability-of-find-position-if sequence from-end)
+ '(%find-position-if-vector-macro predicate sequence
+ from-end start end key))
+(deftransform %find-position ((item sequence from-end start end key test)
+ (t vector t t t function function)
+ *
+ :policy (> speed space)
+ :important t)
+ "expand inline"
+ (check-inlineability-of-find-position-if sequence from-end)
+ '(%find-position-vector-macro item sequence
+ from-end start end key test))