(declare (type index ,n-supplied))
,(if (policy *lexenv* (zerop safety))
`(declare (ignore ,n-supplied))
- `(%verify-argument-count ,n-supplied ,nargs))
+ `(%verify-arg-count ,n-supplied ,nargs))
(%funcall ,fun ,@temps))))
(optional-dispatch
(let* ((min (optional-dispatch-min-args fun))
(%more-arg-context ,n-supplied ,max)
(%funcall ,more ,@temps ,n-context ,n-count))))))
(t
- (%argument-count-error ,n-supplied)))))))))
+ (%arg-count-error ,n-supplied)))))))))
;;; Make an external entry point (XEP) for FUN and return it. We
;;; convert the result of MAKE-XEP-LAMBDA in the correct environment,
;;;
;;; We set REANALYZE and REOPTIMIZE in the component, just in case we
;;; discover an XEP after the initial local call analyze pass.
-(defun make-external-entry-point (fun)
+(defun make-xep (fun)
(declare (type functional fun))
- (aver (not (functional-entry-fun fun)))
- (with-ir1-environment (lambda-bind (main-entry 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)
:debug-name (debug-namify
"XEP for ~A"
(component-reanalyze *current-component*) t
(component-reoptimize *current-component*) t)
(etypecase fun
- (clambda (locall-analyze-fun-1 fun))
+ (clambda
+ (locall-analyze-fun-1 fun))
(optional-dispatch
(dolist (ep (optional-dispatch-entry-points fun))
(locall-analyze-fun-1 ep))
(defun reference-entry-point (ref)
(declare (type ref ref))
(let ((fun (ref-leaf ref)))
- (unless (or (external-entry-point-p fun)
+ (unless (or (xep-p fun)
(member (functional-kind fun) '(:escape :cleanup)))
(change-ref-leaf ref (or (functional-entry-fun fun)
- (make-external-entry-point fun))))))
+ (make-xep fun))))))
\f
;;; Attempt to convert all references to FUN to local calls. The
;;; reference must be the function for a call, and the function
(values))
-;;; We examine all NEW-FUNS in COMPONENT, attempting to convert calls
-;;; into local calls when it is legal. We also attempt to convert each
-;;; LAMBDA to a LET. LET conversion is also triggered by deletion of a
-;;; function reference, but functions that start out eligible for
-;;; conversion must be noticed sometime.
+;;; We examine all NEW-FUNCTIONALS in COMPONENT, attempting to convert
+;;; calls into local calls when it is legal. We also attempt to
+;;; convert each LAMBDA to a LET. LET conversion is also triggered by
+;;; deletion of a function reference, but functions that start out
+;;; eligible for conversion must be noticed sometime.
;;;
;;; Note that there is a lot of action going on behind the scenes
;;; here, triggered by reference deletion. In particular, the
-;;; COMPONENT-LAMBDAS are being hacked to remove newly deleted and let
+;;; COMPONENT-LAMBDAS are being hacked to remove newly deleted and LET
;;; converted LAMBDAs, so it is important that the LAMBDA is added to
-;;; the COMPONENT-LAMBDAS when it is. Also, the COMPONENT-NEW-FUNS may
-;;; contain all sorts of drivel, since it is not updated when we
-;;; delete functions, etc. Only COMPONENT-LAMBDAS is updated.
+;;; the COMPONENT-LAMBDAS when it is. Also, the
+;;; COMPONENT-NEW-FUNCTIONALS may contain all sorts of drivel, since
+;;; it is not updated when we delete functions, etc. Only
+;;; COMPONENT-LAMBDAS is updated.
;;;
-;;; COMPONENT-REANALYZE-FUNS is treated similarly to
-;;; NEW-FUNS, but we don't add lambdas to the LAMBDAS.
+;;; COMPONENT-REANALYZE-FUNCTIONALS is treated similarly to
+;;; COMPONENT-NEW-FUNCTIONALS, but we don't add lambdas to the
+;;; LAMBDAS.
(defun locall-analyze-component (component)
(declare (type component component))
+ (aver-live-component component)
(loop
- (let* ((new-fun (pop (component-new-funs component)))
- (fun (or new-fun (pop (component-reanalyze-funs component)))))
- (unless fun (return))
- (let ((kind (functional-kind fun)))
- (cond ((member kind '(:deleted :let :mv-let :assignment)))
- ((and (null (leaf-refs fun)) (eq kind nil)
- (not (functional-entry-fun fun)))
- (delete-functional fun))
+ (let* ((new-functional (pop (component-new-functionals component)))
+ (functional (or new-functional
+ (pop (component-reanalyze-functionals component)))))
+ (unless functional
+ (return))
+ (let ((kind (functional-kind functional)))
+ (cond ((or (functional-somewhat-letlike-p functional)
+ (eql kind :deleted))
+ (values)) ; nothing to do
+ ((and (null (leaf-refs functional)) (eq kind nil)
+ (not (functional-entry-fun functional)))
+ (delete-functional functional))
(t
- ;; Fix/check FUN's relationship to COMPONENT-LAMDBAS.
- (cond ((not (lambda-p fun))
- ;; Since FUN's not a LAMBDA, this doesn't apply: no-op.
+ ;; Fix/check FUNCTIONAL's relationship to COMPONENT-LAMDBAS.
+ (cond ((not (lambda-p functional))
+ ;; Since FUNCTIONAL isn't a LAMBDA, this doesn't
+ ;; apply: no-op.
(values))
- (new-fun ; FUN came from NEW-FUNS, hence is new.
- ;; FUN becomes part of COMPONENT-LAMBDAS now.
- (aver (not (member fun (component-lambdas component))))
- (push fun (component-lambdas component)))
- (t ; FUN's old.
- ;; FUN should be in COMPONENT-LAMBDAS already.
- (aver (member fun (component-lambdas component)))))
- (locall-analyze-fun-1 fun)
- (when (lambda-p fun)
- (maybe-let-convert fun)))))))
+ (new-functional ; FUNCTIONAL came from
+ ; NEW-FUNCTIONALS, hence is new.
+ ;; FUNCTIONAL becomes part of COMPONENT-LAMBDAS now.
+ (aver (not (member functional
+ (component-lambdas component))))
+ (push functional (component-lambdas component)))
+ (t ; FUNCTIONAL is old.
+ ;; FUNCTIONAL should be in COMPONENT-LAMBDAS already.
+ (aver (member functional (component-lambdas
+ component)))))
+ (locall-analyze-fun-1 functional)
+ (when (lambda-p functional)
+ (maybe-let-convert functional)))))))
(values))
(defun locall-analyze-clambdas-until-done (clambdas)
;; COMPONENT is the only one here. Let's make that explicit.
(aver (= 1 (length (functional-components clambda))))
(aver (eql component (first (functional-components clambda))))
- (when (component-new-funs component)
+ (when (component-new-functionals component)
(setf did-something t)
(locall-analyze-component component))))
(unless did-something
;;; to be in an infinite recursive loop, then change the reference to
;;; reference a fresh copy. We return whichever function we decide to
;;; reference.
-(defun maybe-expand-local-inline (fun ref call)
+(defun maybe-expand-local-inline (original-functional ref call)
(if (and (policy call
- (and (>= speed space) (>= speed compilation-speed)))
+ (and (>= speed space)
+ (>= speed compilation-speed)))
(not (eq (functional-kind (node-home-lambda call)) :external))
(inline-expansion-ok call))
- (with-ir1-environment call
- (let* ((*lexenv* (functional-lexenv fun))
- (won nil)
- (res (catch 'local-call-lossage
- (prog1
- (ir1-convert-lambda
- (functional-inline-expansion fun)
- :debug-name (debug-namify "local inline ~A"
- (leaf-debug-name fun)))
- (setq won t)))))
- (cond (won
- (change-ref-leaf ref res)
- res)
- (t
- (let ((*compiler-error-context* call))
- (compiler-note "couldn't inline expand because expansion ~
- calls this LET-converted local function:~
- ~% ~S"
- (leaf-debug-name res)))
- fun))))
- fun))
+ (multiple-value-bind (losing-local-functional converted-lambda)
+ (catch 'locall-already-let-converted
+ (with-ir1-environment-from-node call
+ (let ((*lexenv* (functional-lexenv original-functional)))
+ (values nil
+ (ir1-convert-lambda
+ (functional-inline-expansion original-functional)
+ :debug-name (debug-namify
+ "local inline ~A"
+ (leaf-debug-name
+ original-functional)))))))
+ (cond (losing-local-functional
+ (let ((*compiler-error-context* call))
+ (compiler-note "couldn't inline expand because expansion ~
+ calls this LET-converted local function:~
+ ~% ~S"
+ (leaf-debug-name losing-local-functional)))
+ original-functional)
+ (t
+ (change-ref-leaf ref converted-lambda)
+ converted-lambda)))
+ original-functional))
;;; Dispatch to the appropriate function to attempt to convert a call.
;;; REF must be a reference to a FUNCTIONAL. This is called in IR1
-;;; optimize as well as in local call analysis. If the call is is
+;;; optimization as well as in local call analysis. If the call is is
;;; already :LOCAL, we do nothing. If the call is already scheduled
;;; for deletion, also do nothing (in addition to saving time, this
;;; also avoids some problems with optimizing collections of functions
(node-block
(lambda-bind (main-entry original-fun))))
component))))
- (let ((fun (if (external-entry-point-p original-fun)
+ (let ((fun (if (xep-p original-fun)
(functional-entry-fun original-fun)
original-fun))
(*compiler-error-context* call))
;; wrong. And we're in locall.lisp here, so it's probably
;; (haven't checked this..) a call to something in the same
;; file. So maybe it deserves a full warning anyway.
- (compiler-warning
+ (compiler-warn
"function called with ~R argument~:P, but wants exactly ~R"
call-args nargs)
(setf (basic-combination-kind call) :error)))))
(cond ((< call-args min-args)
;; FIXME: See FIXME note at the previous
;; wrong-number-of-arguments warnings in this file.
- (compiler-warning
+ (compiler-warn
"function called with ~R argument~:P, but wants at least ~R"
call-args min-args)
(setf (basic-combination-kind call) :error))
(t
;; FIXME: See FIXME note at the previous
;; wrong-number-of-arguments warnings in this file.
- (compiler-warning
+ (compiler-warn
"function called with ~R argument~:P, but wants at most ~R"
call-args max-args)
(setf (basic-combination-kind call) :error))))
(declare (list vars ignores args) (type ref ref) (type combination call)
(type clambda entry))
(let ((new-fun
- (with-ir1-environment call
+ (with-ir1-environment-from-node call
(ir1-convert-lambda
`(lambda ,vars
(declare (ignorable . ,ignores))
(%funcall ,entry . ,args))
- :debug-name (debug-namify "hairy fun entry ~S"
+ :debug-name (debug-namify "hairy function entry ~S"
(continuation-fun-name
(basic-combination-fun call)))))))
(convert-call ref call new-fun)
(key-vars var))
((:rest :optional))
((:more-context :more-count)
- (compiler-warning "can't local-call functions with &MORE args")
+ (compiler-warn "can't local-call functions with &MORE args")
(setf (basic-combination-kind call) :error)
(return-from convert-more-call))))))
(when (optional-dispatch-keyp fun)
(when (oddp (length more))
- (compiler-warning "function called with odd number of ~
- arguments in keyword portion")
+ (compiler-warn "function called with odd number of ~
+ arguments in keyword portion")
(setf (basic-combination-kind call) :error)
(return-from convert-more-call))
(return)))))))
(when (and loser (not (optional-dispatch-allowp fun)))
- (compiler-warning "function called with unknown argument keyword ~S"
- loser)
+ (compiler-warn "function called with unknown argument keyword ~S"
+ loser)
(setf (basic-combination-kind call) :error)
(return-from convert-more-call)))
(let* ((call-block (node-block call))
(bind-block (node-block (lambda-bind clambda)))
(component (block-component call-block)))
+ (aver-live-component component)
(let ((clambda-component (block-component bind-block)))
(unless (eq clambda-component component)
(aver (eq (component-kind component) :initial))
(join-components component clambda-component)))
-
(let ((*current-component* component))
(node-ends-block call))
- ;; FIXME: Use PROPER-LIST-OF-LENGTH-P here, and look for other
+ ;; FIXME: Use DESTRUCTURING-BIND here, and grep for other
;; uses of '=.*length' which could also be converted to use
- ;; PROPER-LIST-OF-LENGTH-P.
+ ;; DESTRUCTURING-BIND or PROPER-LIST-OF-LENGTH-P.
(aver (= (length (block-succ call-block)) 1))
(let ((next-block (first (block-succ call-block))))
(unlink-blocks call-block next-block)
(declare (type clambda clambda) (type basic-combination call))
- (let ((component (block-component (node-block call))))
+ (let ((component (node-component call)))
(unlink-blocks (component-head component) (lambda-block clambda))
(setf (component-lambdas component)
(delete clambda (component-lambdas component)))
;;; work. We change the CALL's CONT to be the continuation heading the
;;; BIND block, and also do REOPTIMIZE-CONTINUATION on the args and
;;; CONT so that LET-specific IR1 optimizations get a chance. We blow
-;;; away any entry for the function in *FREE-FUNCTIONS* so that nobody
+;;; away any entry for the function in *FREE-FUNS* so that nobody
;;; will create new references to it.
(defun let-convert (fun call)
(declare (type clambda fun) (type basic-combination call))
(link-blocks block (lambda-block fun))
(values t (maybe-convert-to-assignment fun))))))
-;;; This is called when we believe it might make sense to convert Fun
-;;; to an assignment. All this function really does is determine when
-;;; a function with more than one call can still be combined with the
-;;; calling function's environment. We can convert when:
+;;; This is called when we believe it might make sense to convert
+;;; CLAMBDA to an assignment. All this function really does is
+;;; determine when a function with more than one call can still be
+;;; combined with the calling function's environment. We can convert
+;;; when:
;;; -- The function is a normal, non-entry function, and
;;; -- Except for one call, all calls must be tail recursive calls
;;; in the called function (i.e. are self-recursive tail calls)
;;; calls as long as they all return to the same place (i.e. have the
;;; same conceptual continuation.) A special case of this would be
;;; when all of the outside calls are tail recursive.
-(defun maybe-convert-to-assignment (fun)
- (declare (type clambda fun))
- (when (and (not (functional-kind fun))
- (not (functional-entry-fun fun)))
+(defun maybe-convert-to-assignment (clambda)
+ (declare (type clambda clambda))
+ (when (and (not (functional-kind clambda))
+ (not (functional-entry-fun clambda)))
(let ((non-tail nil)
(call-fun nil))
- (when (and (dolist (ref (leaf-refs fun) t)
+ (when (and (dolist (ref (leaf-refs clambda) t)
(let ((dest (continuation-dest (node-cont ref))))
(when (or (not dest)
(block-delete-p (node-block dest)))
(return nil))
(let ((home (node-home-lambda ref)))
- (unless (eq home fun)
- (when call-fun (return nil))
+ (unless (eq home clambda)
+ (when call-fun
+ (return nil))
(setq call-fun home))
(unless (node-tail-p dest)
- (when (or non-tail (eq home fun)) (return nil))
+ (when (or non-tail (eq home clambda))
+ (return nil))
(setq non-tail dest)))))
- (ok-initial-convert-p fun))
- (setf (functional-kind fun) :assignment)
- (let-convert fun (or non-tail
- (continuation-dest
- (node-cont (first (leaf-refs fun))))))
- (when non-tail (reoptimize-call non-tail))
+ (ok-initial-convert-p clambda))
+ (setf (functional-kind clambda) :assignment)
+ (let-convert clambda
+ (or non-tail
+ (continuation-dest
+ (node-cont (first (leaf-refs clambda))))))
+ (when non-tail
+ (reoptimize-call non-tail))
t))))
projects / sbcl.git / blobdiff