(setf (car args) nil)))
(values))
-(defun handle-nested-dynamic-extent-lvars (lvar)
- (let ((uses (lvar-uses lvar)))
- ;; Stack analysis wants DX value generators to end their
- ;; blocks. Uses of mupltiple used LVARs already end their blocks,
- ;; so we just need to process used-once LVARs.
- (when (node-p uses)
- (node-ends-block uses))
- ;; If this LVAR's USE is good for DX, it must be a regular
- ;; combination, and its arguments are potentially DX as well.
- (flet ((recurse (use)
- (loop for arg in (combination-args use)
- when (lvar-good-for-dx-p arg)
- append (handle-nested-dynamic-extent-lvars arg))))
- (cons lvar
- (if (listp uses)
- (loop for use in uses
- when (use-good-for-dx-p use)
- nconc (recurse use))
- (when (use-good-for-dx-p uses)
- (recurse uses)))))))
-
(defun recognize-dynamic-extent-lvars (call fun)
(declare (type combination call) (type clambda fun))
(loop for arg in (basic-combination-args call)
- and var in (lambda-vars fun)
- when (and arg (lambda-var-dynamic-extent var)
- (not (lvar-dynamic-extent arg)))
- append (handle-nested-dynamic-extent-lvars arg) into dx-lvars
+ for var in (lambda-vars fun)
+ for dx = (leaf-dynamic-extent var)
+ when (and dx arg (not (lvar-dynamic-extent arg)))
+ append (handle-nested-dynamic-extent-lvars dx arg) into dx-lvars
finally (when dx-lvars
- (binding* ((before-ctran (node-prev call))
- (nil (ensure-block-start before-ctran))
- (block (ctran-block before-ctran))
- (new-call-ctran (make-ctran :kind :inside-block
- :next call
- :block block))
- (entry (with-ir1-environment-from-node call
- (make-entry :prev before-ctran
- :next new-call-ctran)))
- (cleanup (make-cleanup :kind :dynamic-extent
- :mess-up entry
- :info dx-lvars)))
- (setf (node-prev call) new-call-ctran)
- (setf (ctran-next before-ctran) entry)
- (setf (ctran-use new-call-ctran) entry)
+ ;; Stack analysis requires that the CALL ends the block, so
+ ;; that MAP-BLOCK-NLXES sees the cleanup we insert here.
+ (node-ends-block call)
+ (let* ((entry (with-ir1-environment-from-node call
+ (make-entry)))
+ (cleanup (make-cleanup :kind :dynamic-extent
+ :mess-up entry
+ :info dx-lvars)))
(setf (entry-cleanup entry) cleanup)
+ (insert-node-before call entry)
(setf (node-lexenv call)
(make-lexenv :default (node-lexenv call)
:cleanup cleanup))
(push entry (lambda-entries (node-home-lambda entry)))
- (dolist (lvar dx-lvars)
- (setf (lvar-dynamic-extent lvar) cleanup)))))
+ (dolist (cell dx-lvars)
+ (setf (lvar-dynamic-extent (cdr cell)) cleanup)))))
(values))
;;; This function handles merging the tail sets if CALL is potentially
,(if (policy *lexenv* (zerop verify-arg-count))
`(declare (ignore ,n-supplied))
`(%verify-arg-count ,n-supplied ,nargs))
- (locally
- (declare (optimize (merge-tail-calls 3)))
- (%funcall ,fun ,@temps)))))
+ (%funcall ,fun ,@temps))))
(optional-dispatch
(let* ((min (optional-dispatch-min-args fun))
(max (optional-dispatch-max-args fun))
do (entries `((eql ,n-supplied ,n)
(%funcall ,(force ep) ,@(subseq temps 0 n)))))
`(lambda (,n-supplied ,@temps)
- ;; FIXME: Make sure that INDEX type distinguishes between
- ;; target and host. (Probably just make the SB!XC:DEFTYPE
- ;; different from CL:DEFTYPE.)
(declare (type index ,n-supplied))
(cond
,@(if more (butlast (entries)) (entries))
;; KLUDGE: (NOT (< ...)) instead of >= avoids one round of
;; deftransforms and lambda-conversion.
`((,(if (zerop min) t `(not (< ,n-supplied ,max)))
- ,(let ((n-context (gensym))
- (n-count (gensym)))
+ ,(with-unique-names (n-context n-count)
`(multiple-value-bind (,n-context ,n-count)
(%more-arg-context ,n-supplied ,max)
- (locally
- (declare (optimize (merge-tail-calls 3)))
- (%funcall ,more ,@temps ,n-context ,n-count)))))))
+ (%funcall ,more ,@temps ,n-context ,n-count))))))
(t
(%arg-count-error ,n-supplied)))))))))
(declare (type functional fun))
(aver (null (functional-entry-fun fun)))
(with-ir1-environment-from-node (lambda-bind (main-entry fun))
- (let ((res (ir1-convert-lambda (make-xep-lambda-expression fun)
+ (let ((xep (ir1-convert-lambda (make-xep-lambda-expression fun)
:debug-name (debug-name
- 'xep (leaf-debug-name fun)))))
- (setf (functional-kind res) :external
- (leaf-ever-used res) t
- (functional-entry-fun res) fun
- (functional-entry-fun fun) res
+ 'xep (leaf-debug-name fun))
+ :system-lambda t)))
+ (setf (functional-kind xep) :external
+ (leaf-ever-used xep) t
+ (functional-entry-fun xep) fun
+ (functional-entry-fun fun) xep
(component-reanalyze *current-component*) t)
(reoptimize-component *current-component* :maybe)
- (etypecase fun
- (clambda
- (locall-analyze-fun-1 fun))
- (optional-dispatch
- (dolist (ep (optional-dispatch-entry-points fun))
- (locall-analyze-fun-1 (force ep)))
- (when (optional-dispatch-more-entry fun)
- (locall-analyze-fun-1 (optional-dispatch-more-entry fun)))))
- res)))
+ (locall-analyze-xep-entry-point fun)
+ xep)))
+
+(defun locall-analyze-xep-entry-point (fun)
+ (declare (type functional fun))
+ (etypecase fun
+ (clambda
+ (locall-analyze-fun-1 fun))
+ (optional-dispatch
+ (dolist (ep (optional-dispatch-entry-points fun))
+ (locall-analyze-fun-1 (force ep)))
+ (when (optional-dispatch-more-entry fun)
+ (locall-analyze-fun-1 (optional-dispatch-more-entry fun))))))
;;; Notice a REF that is not in a local-call context. If the REF is
;;; already to an XEP, then do nothing, otherwise change it to the
component)))))
(locall-analyze-fun-1 functional)
(when (lambda-p functional)
- (maybe-let-convert functional)))))))
+ (maybe-let-convert functional component)))))))
(values))
(defun locall-analyze-clambdas-until-done (clambdas)
(declare (type ref ref) (type mv-combination call) (type functional fun))
(when (and (looks-like-an-mv-bind fun)
(singleton-p (leaf-refs fun))
- (singleton-p (basic-combination-args call)))
+ (singleton-p (basic-combination-args call))
+ (not (functional-entry-fun fun)))
(let* ((*current-component* (node-component ref))
(ep (optional-dispatch-entry-point-fun
fun (optional-dispatch-max-args fun))))
(when (null (leaf-refs ep))
(aver (= (optional-dispatch-min-args fun) 0))
- (aver (not (functional-entry-fun fun)))
(setf (basic-combination-kind call) :local)
(sset-adjoin ep (lambda-calls-or-closes (node-home-lambda call)))
(merge-tail-sets call ep)
(lexenv-policy (node-lexenv call))))))
(values))
+;;; Convenience function to mark local calls as known bad.
+(defun transform-call-with-ir1-environment (node lambda default-name)
+ (aver (combination-p node))
+ (with-ir1-environment-from-node node
+ (transform-call node lambda
+ (or (combination-fun-source-name node nil)
+ default-name))))
+
+(defun warn-invalid-local-call (node count &rest warn-arguments)
+ (aver (combination-p node))
+ (aver (typep count 'unsigned-byte))
+ (apply 'warn warn-arguments)
+ (transform-call-with-ir1-environment node
+ `(lambda (&rest args)
+ (declare (ignore args))
+ (%arg-count-error ,count))
+ '%arg-count-error))
+
;;; Attempt to convert a call to a lambda. If the number of args is
;;; wrong, we give a warning and mark the call as :ERROR to remove it
;;; from future consideration. If the argcount is O.K. then we just
(cond ((= n-call-args nargs)
(convert-call ref call fun))
(t
- (warn
+ (warn-invalid-local-call call n-call-args
'local-argument-mismatch
:format-control
"function called with ~R argument~:P, but wants exactly ~R"
- :format-arguments (list n-call-args nargs))
- (setf (basic-combination-kind call) :error)))))
+ :format-arguments (list n-call-args nargs))))))
\f
;;;; &OPTIONAL, &MORE and &KEYWORD calls
(max-args (optional-dispatch-max-args fun))
(call-args (length (combination-args call))))
(cond ((< call-args min-args)
- (warn
+ (warn-invalid-local-call call call-args
'local-argument-mismatch
:format-control
"function called with ~R argument~:P, but wants at least ~R"
- :format-arguments (list call-args min-args))
- (setf (basic-combination-kind call) :error))
+ :format-arguments (list call-args min-args)))
((<= call-args max-args)
(convert-call ref call
(let ((*current-component* (node-component ref)))
((optional-dispatch-more-entry fun)
(convert-more-call ref call fun))
(t
- (warn
+ (warn-invalid-local-call call call-args
'local-argument-mismatch
:format-control
"function called with ~R argument~:P, but wants at most ~R"
:format-arguments
- (list call-args max-args))
- (setf (basic-combination-kind call) :error))))
+ (list call-args max-args)))))
(values))
;;; This function is used to convert a call to an entry point when
;;; function that rearranges the arguments and calls the entry point.
;;; We analyze the new function and the entry point immediately so
;;; that everything gets converted during the single pass.
-(defun convert-hairy-fun-entry (ref call entry vars ignores args)
+(defun convert-hairy-fun-entry (ref call entry vars ignores args indef)
(declare (list vars ignores args) (type ref ref) (type combination call)
(type clambda entry))
(let ((new-fun
(with-ir1-environment-from-node call
(ir1-convert-lambda
`(lambda ,vars
- (declare (ignorable ,@ignores))
+ (declare (ignorable ,@ignores)
+ (indefinite-extent ,@indef))
(%funcall ,entry ,@args))
:debug-name (debug-name 'hairy-function-entry
(lvar-fun-debug-name
- (basic-combination-fun call)))))))
+ (basic-combination-fun call)))
+ :system-lambda t))))
(convert-call ref call new-fun)
(dolist (ref (leaf-refs entry))
(convert-call-if-possible ref (lvar-dest (node-lvar ref))))))
(when (oddp (length more))
(compiler-warn "function called with odd number of ~
arguments in keyword portion")
- (setf (basic-combination-kind call) :error)
+ (transform-call-with-ir1-environment
+ call
+ `(lambda (&rest args)
+ (declare (ignore args))
+ (%odd-key-args-error))
+ '%odd-key-args-error)
(return-from convert-more-call))
(do ((key more (cddr key))
(when (and loser (not (optional-dispatch-allowp fun)) (not allowp))
(compiler-warn "function called with unknown argument keyword ~S"
(car loser))
- (setf (basic-combination-kind call) :error)
+ (transform-call-with-ir1-environment
+ call
+ `(lambda (&rest args)
+ (declare (ignore args))
+ (%unknown-key-arg-error ',(car loser)))
+ '%unknown-key-arg-error)
(return-from convert-more-call)))
(collect ((call-args))
(call-args t)))
(:rest
(call-args `(list ,@more-temps))
+ ;; &REST arguments may be accompanied by extra
+ ;; context and count arguments. We know this by
+ ;; the ARG-INFO-DEFAULT. Supply 0 and 0 or
+ ;; don't convert at all depending.
+ (let ((more (arg-info-default info)))
+ (when more
+ (unless (eq t more)
+ (destructuring-bind (context count &optional used) more
+ (declare (ignore context count))
+ (when used
+ ;; We've already converted to use the more context
+ ;; instead of the rest list.
+ (return-from convert-more-call))))
+ (call-args 0)
+ (call-args 0)
+ (setf (arg-info-default info) t)))
(return))
(:keyword
(return)))
(convert-hairy-fun-entry ref call (optional-dispatch-main-entry fun)
(append temps more-temps)
- (ignores) (call-args)))))
+ (ignores) (call-args)
+ (when (optional-rest-p fun)
+ more-temps)))))
(values))
\f
(setf (lambda-physenv clambda) home-physenv)
(when physenv
+ (unless home-physenv
+ (setf home-physenv (get-lambda-physenv home)))
(setf (physenv-nlx-info home-physenv)
(nconc (physenv-nlx-info physenv)
(physenv-nlx-info home-physenv))))
;; with anonymous things, and suppressing inlining
;; for such things can easily give Python acute indigestion, so
;; we don't.)
- (when (leaf-has-source-name-p clambda)
+ ;;
+ ;; A functional that is already inline-expanded in this componsne definitely
+ ;; deserves let-conversion -- and in case of main entry points for inline
+ ;; expanded optional dispatch, the main-etry isn't explicitly marked :INLINE
+ ;; even if the function really is.
+ (when (and (leaf-has-source-name-p clambda)
+ (not (functional-inline-expanded clambda)))
;; ANSI requires that explicit NOTINLINE be respected.
(or (eq (lambda-inlinep clambda) :notinline)
;; If (= LET-CONVERSION 0) we can guess that inlining
(eq (component-kind (lambda-component fun))
:initial)))))
+;;; ir1opt usually takes care of forwarding let-bound values directly
+;;; to their destination when possible. However, locall analysis
+;;; greatly benefits from that transformation, and is executed in a
+;;; distinct phase from ir1opt. After let-conversion, variables
+;;; bound to functional values are immediately substituted away.
+;;;
+;;; When called from locall, component is non-nil, and the functionals
+;;; are marked for reanalysis when appropriate.
+(defun substitute-let-funargs (call fun component)
+ (declare (type combination call) (type clambda fun)
+ (type (or null component) component))
+ (loop for arg in (combination-args call)
+ and var in (lambda-vars fun)
+ ;; only do that in the absence of assignment
+ when (and arg (null (lambda-var-sets var)))
+ do
+ (binding* ((use (lvar-uses arg))
+ (() (ref-p use) :exit-if-null)
+ (leaf (ref-leaf use))
+ (done-something nil))
+ ;; unlike propagate-let-args, we're only concerned with
+ ;; functionals.
+ (cond ((not (functional-p leaf)))
+ ;; if the types match, we can mutate refs to point to
+ ;; the functional instead of var
+ ((csubtypep (single-value-type (node-derived-type use))
+ (leaf-type var))
+ (let ((use-component (node-component use)))
+ (substitute-leaf-if
+ (lambda (ref)
+ (cond ((eq (node-component ref) use-component)
+ (setf done-something t))
+ (t
+ (aver (lambda-toplevelish-p (lambda-home fun)))
+ nil)))
+ leaf var)))
+ ;; otherwise, we can still play LVAR-level tricks for single
+ ;; destination variables.
+ ((and (singleton-p (leaf-refs var))
+ ;; Don't substitute single-ref variables on high-debug /
+ ;; low speed, to improve the debugging experience.
+ (not (preserve-single-use-debug-var-p call var)))
+ (setf done-something t)
+ (substitute-single-use-lvar arg var)))
+ ;; if we've done something, the functional may now be used in
+ ;; more analysis-friendly manners. Enqueue it if we're in
+ ;; locall.
+ (when (and done-something
+ component
+ (member leaf (component-lambdas component)))
+ (pushnew leaf (component-reanalyze-functionals component)))))
+ (values))
+
;;; This function is called when there is some reason to believe that
;;; CLAMBDA might be converted into a LET. This is done after local
;;; call analysis, and also when a reference is deleted. We return
;;; true if we converted.
-(defun maybe-let-convert (clambda)
- (declare (type clambda clambda))
+;;;
+;;; COMPONENT is non-nil during local call analysis. It is used to
+;;; re-enqueue functionals for reanalysis when they have been forwarded
+;;; directly to destination nodes.
+(defun maybe-let-convert (clambda &optional component)
+ (declare (type clambda clambda)
+ (type (or null component) component))
(unless (or (declarations-suppress-let-conversion-p clambda)
(functional-has-external-references-p clambda))
;; We only convert to a LET when the function is a normal local
(let-convert clambda dest))
(reoptimize-call dest)
(setf (functional-kind clambda)
- (if (mv-combination-p dest) :mv-let :let))))
+ (if (mv-combination-p dest) :mv-let :let))
+ (when (combination-p dest) ; mv-combinations are too hairy
+ ; for me to handle - PK 2012-05-30
+ (substitute-let-funargs dest clambda component))))
t))))
\f
;;;; tail local calls and assignments