(declare (type cblock block1 block2) (type node node)
(type (or cleanup null) cleanup))
(setf (component-reanalyze (block-component block1)) t)
- (with-ir1-environment node
- (let* ((start (make-continuation))
- (block (continuation-starts-block start))
- (cont (make-continuation))
- (*lexenv* (if cleanup
- (make-lexenv :cleanup cleanup)
- *lexenv*)))
- (change-block-successor block1 block2 block)
- (link-blocks block block2)
- (ir1-convert start cont form)
- (setf (block-last block) (continuation-use cont))
- block)))
+ (with-ir1-environment-from-node node
+ (with-component-last-block (*current-component*
+ (block-next (component-head *current-component*)))
+ (let* ((start (make-ctran))
+ (block (ctran-starts-block start))
+ (next (make-ctran))
+ (*lexenv* (if cleanup
+ (make-lexenv :cleanup cleanup)
+ *lexenv*)))
+ (change-block-successor block1 block2 block)
+ (link-blocks block block2)
+ (ir1-convert start next nil form)
+ (setf (block-last block) (ctran-use next))
+ (setf (node-next (block-last block)) nil)
+ block))))
\f
-;;;; continuation use hacking
-
-;;; Return a list of all the nodes which use Cont.
-(declaim (ftype (function (continuation) list) find-uses))
-(defun find-uses (cont)
- (ecase (continuation-kind cont)
- ((:block-start :deleted-block-start)
- (block-start-uses (continuation-block cont)))
- (:inside-block (list (continuation-use cont)))
- (:unused nil)
- (:deleted nil)))
-
-;;; Update continuation use information so that NODE is no longer a
-;;; use of its CONT. If the old continuation doesn't start its block,
-;;; then we don't update the BLOCK-START-USES, since it will be
-;;; deleted when we are done.
+;;;; lvar use hacking
+
+;;; Return a list of all the nodes which use LVAR.
+(declaim (ftype (sfunction (lvar) list) find-uses))
+(defun find-uses (lvar)
+ (let ((uses (lvar-uses lvar)))
+ (if (listp uses)
+ uses
+ (list uses))))
+
+(defun principal-lvar-use (lvar)
+ (let ((use (lvar-uses lvar)))
+ (if (cast-p use)
+ (principal-lvar-use (cast-value use))
+ use)))
+
+;;; Update lvar use information so that NODE is no longer a use of its
+;;; LVAR.
;;;
;;; Note: if you call this function, you may have to do a
-;;; REOPTIMIZE-CONTINUATION to inform IR1 optimization that something
-;;; has changed.
-(declaim (ftype (function (node) (values)) delete-continuation-use))
-(defun delete-continuation-use (node)
- (let* ((cont (node-cont node))
- (block (continuation-block cont)))
- (ecase (continuation-kind cont)
- (:deleted)
- ((:block-start :deleted-block-start)
- (let ((uses (delete node (block-start-uses block))))
- (setf (block-start-uses block) uses)
- (setf (continuation-use cont)
- (if (cdr uses) nil (car uses)))))
- (:inside-block
- (setf (continuation-kind cont) :unused)
- (setf (continuation-block cont) nil)
- (setf (continuation-use cont) nil)
- (setf (continuation-next cont) nil)))
- (setf (node-cont node) nil))
+;;; REOPTIMIZE-LVAR to inform IR1 optimization that something has
+;;; changed.
+(declaim (ftype (sfunction (node) (values))
+ delete-lvar-use
+ %delete-lvar-use))
+;;; Just delete NODE from its LVAR uses; LVAR is preserved so it may
+;;; be given a new use.
+(defun %delete-lvar-use (node)
+ (let* ((lvar (node-lvar node)))
+ (when lvar
+ (if (listp (lvar-uses lvar))
+ (let ((new-uses (delq node (lvar-uses lvar))))
+ (setf (lvar-uses lvar)
+ (if (singleton-p new-uses)
+ (first new-uses)
+ new-uses)))
+ (setf (lvar-uses lvar) nil))
+ (setf (node-lvar node) nil)))
+ (values))
+;;; Delete NODE from its LVAR uses; if LVAR has no other uses, delete
+;;; its DEST's block, which must be unreachable.
+(defun delete-lvar-use (node)
+ (let ((lvar (node-lvar node)))
+ (when lvar
+ (%delete-lvar-use node)
+ (if (null (lvar-uses lvar))
+ (binding* ((dest (lvar-dest lvar) :exit-if-null)
+ (() (not (node-deleted dest)) :exit-if-null)
+ (block (node-block dest)))
+ (mark-for-deletion block))
+ (reoptimize-lvar lvar))))
(values))
-;;; Update continuation use information so that NODE uses CONT. If
-;;; CONT is :UNUSED, then we set its block to NODE's NODE-BLOCK (which
-;;; must be set.)
+;;; Update lvar use information so that NODE uses LVAR.
;;;
;;; Note: if you call this function, you may have to do a
-;;; REOPTIMIZE-CONTINUATION to inform IR1 optimization that something
-;;; has changed.
-(declaim (ftype (function (node continuation) (values)) add-continuation-use))
-(defun add-continuation-use (node cont)
- (aver (not (node-cont node)))
- (let ((block (continuation-block cont)))
- (ecase (continuation-kind cont)
- (:deleted)
- (:unused
- (aver (not block))
- (let ((block (node-block node)))
- (aver block)
- (setf (continuation-block cont) block))
- (setf (continuation-kind cont) :inside-block)
- (setf (continuation-use cont) node))
- ((:block-start :deleted-block-start)
- (let ((uses (cons node (block-start-uses block))))
- (setf (block-start-uses block) uses)
- (setf (continuation-use cont)
- (if (cdr uses) nil (car uses)))))))
- (setf (node-cont node) cont)
+;;; REOPTIMIZE-LVAR to inform IR1 optimization that something has
+;;; changed.
+(declaim (ftype (sfunction (node (or lvar null)) (values)) add-lvar-use))
+(defun add-lvar-use (node lvar)
+ (aver (not (node-lvar node)))
+ (when lvar
+ (let ((uses (lvar-uses lvar)))
+ (setf (lvar-uses lvar)
+ (cond ((null uses)
+ node)
+ ((listp uses)
+ (cons node uses))
+ (t
+ (list node uses))))
+ (setf (node-lvar node) lvar)))
+
(values))
-;;; Return true if CONT is the NODE-CONT for NODE and CONT is
-;;; transferred to immediately after the evaluation of NODE.
-(defun immediately-used-p (cont node)
- (declare (type continuation cont) (type node node))
- (and (eq (node-cont node) cont)
- (not (eq (continuation-kind cont) :deleted))
- (let ((cblock (continuation-block cont))
- (nblock (node-block node)))
- (or (eq cblock nblock)
- (let ((succ (block-succ nblock)))
- (and (= (length succ) 1)
- (eq (first succ) cblock)))))))
+;;; Return true if LVAR destination is executed immediately after
+;;; NODE. Cleanups are ignored.
+(defun immediately-used-p (lvar node)
+ (declare (type lvar lvar) (type node node))
+ (aver (eq (node-lvar node) lvar))
+ (and (eq (lvar-dest lvar)
+ (acond ((node-next node)
+ (ctran-next it))
+ (t (let* ((block (node-block node))
+ (next-block (first (block-succ block))))
+ (block-start-node next-block)))))))
\f
-;;;; continuation substitution
+;;;; lvar substitution
;;; In OLD's DEST, replace OLD with NEW. NEW's DEST must initially be
-;;; NIL. When we are done, we call FLUSH-DEST on OLD to clear its DEST
-;;; and to note potential optimization opportunities.
-(defun substitute-continuation (new old)
- (declare (type continuation old new))
- (aver (not (continuation-dest new)))
- (let ((dest (continuation-dest old)))
+;;; NIL. We do not flush OLD's DEST.
+(defun substitute-lvar (new old)
+ (declare (type lvar old new))
+ (aver (not (lvar-dest new)))
+ (let ((dest (lvar-dest old)))
(etypecase dest
((or ref bind))
(cif (setf (if-test dest) new))
(if (eq old (basic-combination-fun dest))
(setf (basic-combination-fun dest) new)
(setf (basic-combination-args dest)
- (nsubst new old (basic-combination-args dest))))))
+ (nsubst new old (basic-combination-args dest)))))
+ (cast (setf (cast-value dest) new)))
- (flush-dest old)
- (setf (continuation-dest new) dest))
+ (setf (lvar-dest old) nil)
+ (setf (lvar-dest new) dest)
+ (flush-lvar-externally-checkable-type new))
(values))
;;; Replace all uses of OLD with uses of NEW, where NEW has an
-;;; arbitary number of uses. If NEW will end up with more than one
-;;; use, then we must arrange for it to start a block if it doesn't
-;;; already.
-(defun substitute-continuation-uses (new old)
- (declare (type continuation old new))
- (unless (and (eq (continuation-kind new) :unused)
- (eq (continuation-kind old) :inside-block))
- (ensure-block-start new))
+;;; arbitary number of uses.
+(defun substitute-lvar-uses (new old)
+ (declare (type lvar old)
+ (type (or lvar null) new))
(do-uses (node old)
- (delete-continuation-use node)
- (add-continuation-use node new))
- (dolist (lexenv-use (continuation-lexenv-uses old))
- (setf (cadr lexenv-use) new))
+ (%delete-lvar-use node)
+ (when new
+ (add-lvar-use node new)))
- (reoptimize-continuation new)
+ (when new (reoptimize-lvar new))
(values))
\f
;;;; block starting/creation
-;;; Return the block that CONT is the start of, making a block if
+;;; Return the block that CTRAN is the start of, making a block if
;;; necessary. This function is called by IR1 translators which may
-;;; cause a continuation to be used more than once. Every continuation
-;;; which may be used more than once must start a block by the time
-;;; that anyone does a USE-CONTINUATION on it.
+;;; cause a CTRAN to be used more than once. Every CTRAN which may be
+;;; used more than once must start a block by the time that anyone
+;;; does a USE-CTRAN on it.
;;;
;;; We also throw the block into the next/prev list for the
;;; *CURRENT-COMPONENT* so that we keep track of which blocks we have
;;; made.
-(defun continuation-starts-block (cont)
- (declare (type continuation cont))
- (ecase (continuation-kind cont)
+(defun ctran-starts-block (ctran)
+ (declare (type ctran ctran))
+ (ecase (ctran-kind ctran)
(:unused
- (aver (not (continuation-block cont)))
- (let* ((head (component-head *current-component*))
- (next (block-next head))
- (new-block (make-block cont)))
- (setf (block-next new-block) next)
- (setf (block-prev new-block) head)
- (setf (block-prev next) new-block)
- (setf (block-next head) new-block)
- (setf (continuation-block cont) new-block)
- (setf (continuation-use cont) nil)
- (setf (continuation-kind cont) :block-start)
+ (aver (not (ctran-block ctran)))
+ (let* ((next (component-last-block *current-component*))
+ (prev (block-prev next))
+ (new-block (make-block ctran)))
+ (setf (block-next new-block) next
+ (block-prev new-block) prev
+ (block-prev next) new-block
+ (block-next prev) new-block
+ (ctran-block ctran) new-block
+ (ctran-kind ctran) :block-start)
+ (aver (not (ctran-use ctran)))
new-block))
(:block-start
- (continuation-block cont))))
-
-;;; Ensure that Cont is the start of a block (or deleted) so that the use
-;;; set can be freely manipulated.
-;;; -- If the continuation is :Unused or is :Inside-Block and the Cont of Last
-;;; in its block, then we make it the start of a new deleted block.
-;;; -- If the continuation is :Inside-Block inside a block, then we split the
-;;; block using Node-Ends-Block, which makes the continuation be a
-;;; :Block-Start.
-(defun ensure-block-start (cont)
- (declare (type continuation cont))
- (let ((kind (continuation-kind cont)))
+ (ctran-block ctran))))
+
+;;; Ensure that CTRAN is the start of a block so that the use set can
+;;; be freely manipulated.
+(defun ensure-block-start (ctran)
+ (declare (type ctran ctran))
+ (let ((kind (ctran-kind ctran)))
(ecase kind
- ((:deleted :block-start :deleted-block-start))
- ((:unused :inside-block)
- (let ((block (continuation-block cont)))
- (cond ((or (eq kind :unused)
- (eq (node-cont (block-last block)) cont))
- (setf (continuation-block cont)
- (make-block-key :start cont
- :component nil
- :start-uses (find-uses cont)))
- (setf (continuation-kind cont) :deleted-block-start))
- (t
- (node-ends-block (continuation-use cont))))))))
+ ((:block-start))
+ ((:unused)
+ (setf (ctran-block ctran)
+ (make-block-key :start ctran))
+ (setf (ctran-kind ctran) :block-start))
+ ((:inside-block)
+ (node-ends-block (ctran-use ctran)))))
(values))
\f
+;;;;
+
+;;; Filter values of LVAR through FORM, which must be an ordinary/mv
+;;; call. First argument must be 'DUMMY, which will be replaced with
+;;; LVAR. In case of an ordinary call the function should not have
+;;; return type NIL. We create a new "filtered" lvar.
+;;;
+;;; TODO: remove preconditions.
+(defun filter-lvar (lvar form)
+ (declare (type lvar lvar) (type list form))
+ (let* ((dest (lvar-dest lvar))
+ (ctran (node-prev dest)))
+ (with-ir1-environment-from-node dest
+
+ (ensure-block-start ctran)
+ (let* ((old-block (ctran-block ctran))
+ (new-start (make-ctran))
+ (filtered-lvar (make-lvar))
+ (new-block (ctran-starts-block new-start)))
+
+ ;; Splice in the new block before DEST, giving the new block
+ ;; all of DEST's predecessors.
+ (dolist (block (block-pred old-block))
+ (change-block-successor block old-block new-block))
+
+ (ir1-convert new-start ctran filtered-lvar form)
+
+ ;; KLUDGE: Comments at the head of this function in CMU CL
+ ;; said that somewhere in here we
+ ;; Set the new block's start and end cleanups to the *start*
+ ;; cleanup of PREV's block. This overrides the incorrect
+ ;; default from WITH-IR1-ENVIRONMENT-FROM-NODE.
+ ;; Unfortunately I can't find any code which corresponds to this.
+ ;; Perhaps it was a stale comment? Or perhaps I just don't
+ ;; understand.. -- WHN 19990521
+
+ ;; Replace 'DUMMY with the LVAR. (We can find 'DUMMY because
+ ;; no LET conversion has been done yet.) The [mv-]combination
+ ;; code from the call in the form will be the use of the new
+ ;; check lvar. We substitute for the first argument of
+ ;; this node.
+ (let* ((node (lvar-use filtered-lvar))
+ (args (basic-combination-args node))
+ (victim (first args)))
+ (aver (eq (constant-value (ref-leaf (lvar-use victim)))
+ 'dummy))
+
+ (substitute-lvar filtered-lvar lvar)
+ (substitute-lvar lvar victim)
+ (flush-dest victim))
+
+ ;; Invoking local call analysis converts this call to a LET.
+ (locall-analyze-component *current-component*))))
+ (values))
+
+;;; Delete NODE and VALUE. It may result in some calls becoming tail.
+(defun delete-filter (node lvar value)
+ (aver (eq (lvar-dest value) node))
+ (aver (eq (node-lvar node) lvar))
+ (cond (lvar (collect ((merges))
+ (when (return-p (lvar-dest lvar))
+ (do-uses (use value)
+ (when (and (basic-combination-p use)
+ (eq (basic-combination-kind use) :local))
+ (merges use))))
+ (%delete-lvar-use node)
+ (substitute-lvar-uses lvar value)
+ (prog1
+ (unlink-node node)
+ (dolist (merge (merges))
+ (merge-tail-sets merge)))))
+ (t (flush-dest value)
+ (unlink-node node))))
+\f
;;;; miscellaneous shorthand functions
;;; Return the home (i.e. enclosing non-LET) CLAMBDA for NODE. Since
;;; the LEXENV-LAMBDA may be deleted, we must chain up the
;;; LAMBDA-CALL-LEXENV thread until we find a CLAMBDA that isn't
;;; deleted, and then return its home.
-(declaim (maybe-inline node-home-lambda))
(defun node-home-lambda (node)
(declare (type node node))
(do ((fun (lexenv-lambda (node-lexenv node))
(when (eq (lambda-home fun) fun)
(return fun))))
-#!-sb-fluid (declaim (inline node-block node-tlf-number))
-(declaim (maybe-inline node-physenv))
+#!-sb-fluid (declaim (inline node-block))
(defun node-block (node)
- (declare (type node node))
- (the cblock (continuation-block (node-prev node))))
+ (ctran-block (node-prev node)))
+(declaim (ftype (sfunction (node) component) node-component))
+(defun node-component (node)
+ (block-component (node-block node)))
+(declaim (ftype (sfunction (node) physenv) node-physenv))
(defun node-physenv (node)
- (declare (type node node))
- #!-sb-fluid (declare (inline node-home-lambda))
- (the physenv (lambda-physenv (node-home-lambda node))))
+ (lambda-physenv (node-home-lambda node)))
+#!-sb-fluid (declaim (inline node-dest))
+(defun node-dest (node)
+ (awhen (node-lvar node) (lvar-dest it)))
-#!-sb-fluid (declaim (maybe-inline lambda-block))
+(declaim (ftype (sfunction (clambda) cblock) lambda-block))
(defun lambda-block (clambda)
- (declare (type clambda clambda))
(node-block (lambda-bind clambda)))
+(declaim (ftype (sfunction (clambda) component) lambda-component))
(defun lambda-component (clambda)
- (declare (inline lambda-block))
(block-component (lambda-block clambda)))
+(declaim (ftype (sfunction (cblock) node) block-start-node))
+(defun block-start-node (block)
+ (ctran-next (block-start block)))
+
;;; Return the enclosing cleanup for environment of the first or last
;;; node in BLOCK.
(defun block-start-cleanup (block)
- (declare (type cblock block))
- (node-enclosing-cleanup (continuation-next (block-start block))))
+ (node-enclosing-cleanup (block-start-node block)))
(defun block-end-cleanup (block)
- (declare (type cblock block))
(node-enclosing-cleanup (block-last block)))
+;;; Return the non-LET LAMBDA that holds BLOCK's code, or NIL
+;;; if there is none.
+;;;
+;;; There can legitimately be no home lambda in dead code early in the
+;;; IR1 conversion process, e.g. when IR1-converting the SETQ form in
+;;; (BLOCK B (RETURN-FROM B) (SETQ X 3))
+;;; where the block is just a placeholder during parsing and doesn't
+;;; actually correspond to code which will be written anywhere.
+(declaim (ftype (sfunction (cblock) (or clambda null)) block-home-lambda-or-null))
+(defun block-home-lambda-or-null (block)
+ (if (node-p (block-last block))
+ ;; This is the old CMU CL way of doing it.
+ (node-home-lambda (block-last block))
+ ;; Now that SBCL uses this operation more aggressively than CMU
+ ;; CL did, the old CMU CL way of doing it can fail in two ways.
+ ;; 1. It can fail in a few cases even when a meaningful home
+ ;; lambda exists, e.g. in IR1-CONVERT of one of the legs of
+ ;; an IF.
+ ;; 2. It can fail when converting a form which is born orphaned
+ ;; so that it never had a meaningful home lambda, e.g. a form
+ ;; which follows a RETURN-FROM or GO form.
+ (let ((pred-list (block-pred block)))
+ ;; To deal with case 1, we reason that
+ ;; previous-in-target-execution-order blocks should be in the
+ ;; same lambda, and that they seem in practice to be
+ ;; previous-in-compilation-order blocks too, so we look back
+ ;; to find one which is sufficiently initialized to tell us
+ ;; what the home lambda is.
+ (if pred-list
+ ;; We could get fancy about this, flooding through the
+ ;; graph of all the previous blocks, but in practice it
+ ;; seems to work just to grab the first previous block and
+ ;; use it.
+ (node-home-lambda (block-last (first pred-list)))
+ ;; In case 2, we end up with an empty PRED-LIST and
+ ;; have to punt: There's no home lambda.
+ nil))))
+
;;; Return the non-LET LAMBDA that holds BLOCK's code.
+(declaim (ftype (sfunction (cblock) clambda) block-home-lambda))
(defun block-home-lambda (block)
- (declare (type cblock block))
- #!-sb-fluid (declare (inline node-home-lambda))
- (node-home-lambda (block-last block)))
+ (block-home-lambda-or-null block))
;;; Return the IR1 physical environment for BLOCK.
+(declaim (ftype (sfunction (cblock) physenv) block-physenv))
(defun block-physenv (block)
- (declare (type cblock block))
- #!-sb-fluid (declare (inline node-home-lambda))
- (lambda-physenv (node-home-lambda (block-last block))))
+ (lambda-physenv (block-home-lambda block)))
;;; Return the Top Level Form number of PATH, i.e. the ordinal number
;;; of its original source's top level form in its compilation unit.
(first forms)
(values (find-original-source path)))))
-;;; Return NODE-SOURCE-FORM, T if continuation has a single use,
-;;; otherwise NIL, NIL.
-(defun continuation-source (cont)
- (let ((use (continuation-use cont)))
- (if use
- (values (node-source-form use) t)
- (values nil nil))))
+;;; Return NODE-SOURCE-FORM, T if lvar has a single use, otherwise
+;;; NIL, NIL.
+(defun lvar-source (lvar)
+ (let ((use (lvar-uses lvar)))
+ (if (listp use)
+ (values nil nil)
+ (values (node-source-form use) t))))
+
+;;; Return the unique node, delivering a value to LVAR.
+#!-sb-fluid (declaim (inline lvar-use))
+(defun lvar-use (lvar)
+ (the (not list) (lvar-uses lvar)))
+
+#!-sb-fluid (declaim (inline lvar-has-single-use-p))
+(defun lvar-has-single-use-p (lvar)
+ (typep (lvar-uses lvar) '(not list)))
+
+;;; Return the LAMBDA that is CTRAN's home, or NIL if there is none.
+(declaim (ftype (sfunction (ctran) (or clambda null))
+ ctran-home-lambda-or-null))
+(defun ctran-home-lambda-or-null (ctran)
+ ;; KLUDGE: This function is a post-CMU-CL hack by WHN, and this
+ ;; implementation might not be quite right, or might be uglier than
+ ;; necessary. It appears that the original Python never found a need
+ ;; to do this operation. The obvious things based on
+ ;; NODE-HOME-LAMBDA of CTRAN-USE usually work; then if that fails,
+ ;; BLOCK-HOME-LAMBDA of CTRAN-BLOCK works, given that we
+ ;; generalize it enough to grovel harder when the simple CMU CL
+ ;; approach fails, and furthermore realize that in some exceptional
+ ;; cases it might return NIL. -- WHN 2001-12-04
+ (cond ((ctran-use ctran)
+ (node-home-lambda (ctran-use ctran)))
+ ((ctran-block ctran)
+ (block-home-lambda-or-null (ctran-block ctran)))
+ (t
+ (bug "confused about home lambda for ~S" ctran))))
+
+;;; Return the LAMBDA that is CTRAN's home.
+(declaim (ftype (sfunction (ctran) clambda) ctran-home-lambda))
+(defun ctran-home-lambda (ctran)
+ (ctran-home-lambda-or-null ctran))
+
+#!-sb-fluid (declaim (inline lvar-single-value-p))
+(defun lvar-single-value-p (lvar)
+ (or (not lvar)
+ (let ((dest (lvar-dest lvar)))
+ (typecase dest
+ ((or creturn exit)
+ nil)
+ (mv-combination
+ (eq (basic-combination-fun dest) lvar))
+ (cast
+ (locally
+ (declare (notinline lvar-single-value-p))
+ (and (not (values-type-p (cast-asserted-type dest)))
+ (lvar-single-value-p (node-lvar dest)))))
+ (t
+ t)))))
+
+(defun principal-lvar-end (lvar)
+ (loop for prev = lvar then (node-lvar dest)
+ for dest = (and prev (lvar-dest prev))
+ while (cast-p dest)
+ finally (return (values dest prev))))
+
+(defun principal-lvar-single-valuify (lvar)
+ (loop for prev = lvar then (node-lvar dest)
+ for dest = (and prev (lvar-dest prev))
+ while (cast-p dest)
+ do (setf (node-derived-type dest)
+ (make-short-values-type (list (single-value-type
+ (node-derived-type dest)))))
+ (reoptimize-lvar prev)))
\f
;;; Return a new LEXENV just like DEFAULT except for the specified
;;; slot values. Values for the alist slots are NCONCed to the
;;; beginning of the current value, rather than replacing it entirely.
(defun make-lexenv (&key (default *lexenv*)
- functions variables blocks tags type-restrictions
- options
+ funs vars blocks tags
+ type-restrictions
(lambda (lexenv-lambda default))
(cleanup (lexenv-cleanup default))
(policy (lexenv-policy default)))
(nconc ,var old)
old))))
(internal-make-lexenv
- (frob functions lexenv-functions)
- (frob variables lexenv-variables)
+ (frob funs lexenv-funs)
+ (frob vars lexenv-vars)
(frob blocks lexenv-blocks)
(frob tags lexenv-tags)
(frob type-restrictions lexenv-type-restrictions)
- lambda cleanup policy
- (frob options lexenv-options))))
+ lambda cleanup policy)))
+
+;;; Makes a LEXENV, suitable for using in a MACROLET introduced
+;;; macroexpander
+(defun make-restricted-lexenv (lexenv)
+ (flet ((fun-good-p (fun)
+ (destructuring-bind (name . thing) fun
+ (declare (ignore name))
+ (etypecase thing
+ (functional nil)
+ (global-var t)
+ (cons (aver (eq (car thing) 'macro))
+ t))))
+ (var-good-p (var)
+ (destructuring-bind (name . thing) var
+ (declare (ignore name))
+ (etypecase thing
+ (leaf nil)
+ (cons (aver (eq (car thing) 'macro))
+ t)
+ (heap-alien-info nil)))))
+ (internal-make-lexenv
+ (remove-if-not #'fun-good-p (lexenv-funs lexenv))
+ (remove-if-not #'var-good-p (lexenv-vars lexenv))
+ nil
+ nil
+ (lexenv-type-restrictions lexenv) ; XXX
+ nil
+ nil
+ (lexenv-policy lexenv))))
\f
;;;; flow/DFO/component hackery
;;; Join BLOCK1 and BLOCK2.
-#!-sb-fluid (declaim (inline link-blocks))
(defun link-blocks (block1 block2)
(declare (type cblock block1 block2))
(setf (block-succ block1)
(push block1 (block-pred block2))
(values))
(defun %link-blocks (block1 block2)
- (declare (type cblock block1 block2) (inline member))
+ (declare (type cblock block1 block2))
(let ((succ1 (block-succ block1)))
- (aver (not (member block2 succ1 :test #'eq)))
+ (aver (not (memq block2 succ1)))
(cons block2 succ1)))
;;; This is like LINK-BLOCKS, but we separate BLOCK1 and BLOCK2. If
(let ((new-pred (delq block1 (block-pred block2))))
(setf (block-pred block2) new-pred)
- (when (and new-pred (null (rest new-pred)))
+ (when (singleton-p new-pred)
(let ((pred-block (first new-pred)))
(when (if-p (block-last pred-block))
(setf (block-test-modified pred-block) t)))))
;;; BLOCK-TEST-MODIFIED so that any test constraint will be applied to
;;; the new successor.
(defun change-block-successor (block old new)
- (declare (type cblock new old block) (inline member))
+ (declare (type cblock new old block))
(unlink-blocks block old)
(let ((last (block-last block))
(comp (block-component block)))
succ-left)
(first succ-left)
new)))
- (unless (member new succ-left :test #'eq)
+ (unless (memq new succ-left)
(link-blocks block new))
(macrolet ((frob (slot)
`(when (eq (,slot last) old)
(setf (,slot last) new))))
(frob if-consequent)
- (frob if-alternative))))
+ (frob if-alternative)
+ (when (eq (if-consequent last)
+ (if-alternative last))
+ (setf (component-reoptimize (block-component block)) t)))))
(t
- (unless (member new (block-succ block) :test #'eq)
+ (unless (memq new (block-succ block))
(link-blocks block new)))))
(values))
;;; Unlink a block from the next/prev chain. We also null out the
;;; COMPONENT.
-(declaim (ftype (function (cblock) (values)) remove-from-dfo))
+(declaim (ftype (sfunction (cblock) (values)) remove-from-dfo))
(defun remove-from-dfo (block)
(let ((next (block-next block))
(prev (block-prev block)))
(values))
;;; Add BLOCK to the next/prev chain following AFTER. We also set the
-;;; Component to be the same as for AFTER.
+;;; COMPONENT to be the same as for AFTER.
(defun add-to-dfo (block after)
(declare (type cblock block after))
(let ((next (block-next after))
;;; Set the FLAG for all the blocks in COMPONENT to NIL, except for
;;; the head and tail which are set to T.
-(declaim (ftype (function (component) (values)) clear-flags))
+(declaim (ftype (sfunction (component) (values)) clear-flags))
(defun clear-flags (component)
(let ((head (component-head component))
(tail (component-tail component)))
;;; Make a component with no blocks in it. The BLOCK-FLAG is initially
;;; true in the head and tail blocks.
-(declaim (ftype (function nil component) make-empty-component))
+(declaim (ftype (sfunction () component) make-empty-component))
(defun make-empty-component ()
(let* ((head (make-block-key :start nil :component nil))
(tail (make-block-key :start nil :component nil))
- (res (make-component :head head :tail tail)))
+ (res (make-component head tail)))
(setf (block-flag head) t)
(setf (block-flag tail) t)
(setf (block-component head) res)
(defun node-ends-block (node)
(declare (type node node))
(let* ((block (node-block node))
- (start (node-cont node))
- (last (block-last block))
- (last-cont (node-cont last)))
+ (start (node-next node))
+ (last (block-last block)))
(unless (eq last node)
- (aver (and (eq (continuation-kind start) :inside-block)
- (not (block-delete-p block))))
+ (aver (and (eq (ctran-kind start) :inside-block)
+ (not (block-delete-p block))))
(let* ((succ (block-succ block))
(new-block
(make-block-key :start start
:component (block-component block)
- :start-uses (list (continuation-use start))
:succ succ :last last)))
- (setf (continuation-kind start) :block-start)
+ (setf (ctran-kind start) :block-start)
+ (setf (ctran-use start) nil)
+ (setf (block-last block) node)
+ (setf (node-next node) nil)
(dolist (b succ)
(setf (block-pred b)
(cons new-block (remove block (block-pred b)))))
(setf (block-succ block) ())
- (setf (block-last block) node)
(link-blocks block new-block)
(add-to-dfo new-block block)
(setf (component-reanalyze (block-component block)) t)
-
- (do ((cont start (node-cont (continuation-next cont))))
- ((eq cont last-cont)
- (when (eq (continuation-kind last-cont) :inside-block)
- (setf (continuation-block last-cont) new-block)))
- (setf (continuation-block cont) new-block))
+
+ (do ((ctran start (node-next (ctran-next ctran))))
+ ((not ctran))
+ (setf (ctran-block ctran) new-block))
(setf (block-type-asserted block) t)
(setf (block-test-modified block) t))))
-
(values))
\f
;;;; deleting stuff
-;;; Deal with deleting the last (read) reference to a LAMBDA-VAR. We
-;;; iterate over all local calls flushing the corresponding argument,
-;;; allowing the computation of the argument to be deleted. We also
-;;; mark the let for reoptimization, since it may be that we have
-;;; deleted the last variable.
-;;;
-;;; The LAMBDA-VAR may still have some SETs, but this doesn't cause
-;;; too much difficulty, since we can efficiently implement write-only
-;;; variables. We iterate over the sets, marking their blocks for dead
-;;; code flushing, since we can delete sets whose value is unused.
+;;; Deal with deleting the last (read) reference to a LAMBDA-VAR.
(defun delete-lambda-var (leaf)
(declare (type lambda-var leaf))
+
+ ;; Iterate over all local calls flushing the corresponding argument,
+ ;; allowing the computation of the argument to be deleted. We also
+ ;; mark the LET for reoptimization, since it may be that we have
+ ;; deleted its last variable.
(let* ((fun (lambda-var-home leaf))
(n (position leaf (lambda-vars fun))))
(dolist (ref (leaf-refs fun))
- (let* ((cont (node-cont ref))
- (dest (continuation-dest cont)))
+ (let* ((lvar (node-lvar ref))
+ (dest (and lvar (lvar-dest lvar))))
(when (and (combination-p dest)
- (eq (basic-combination-fun dest) cont)
+ (eq (basic-combination-fun dest) lvar)
(eq (basic-combination-kind dest) :local))
(let* ((args (basic-combination-args dest))
(arg (elt args n)))
- (reoptimize-continuation arg)
+ (reoptimize-lvar arg)
(flush-dest arg)
(setf (elt args n) nil))))))
+ ;; The LAMBDA-VAR may still have some SETs, but this doesn't cause
+ ;; too much difficulty, since we can efficiently implement
+ ;; write-only variables. We iterate over the SETs, marking their
+ ;; blocks for dead code flushing, since we can delete SETs whose
+ ;; value is unused.
(dolist (set (lambda-var-sets leaf))
(setf (block-flush-p (node-block set)) t))
(values))
-;;; Note that something interesting has happened to VAR. We only deal
-;;; with LET variables, marking the corresponding initial value arg as
-;;; needing to be reoptimized.
+;;; Note that something interesting has happened to VAR.
(defun reoptimize-lambda-var (var)
(declare (type lambda-var var))
(let ((fun (lambda-var-home var)))
+ ;; We only deal with LET variables, marking the corresponding
+ ;; initial value arg as needing to be reoptimized.
(when (and (eq (functional-kind fun) :let)
(leaf-refs var))
(do ((args (basic-combination-args
- (continuation-dest
- (node-cont
- (first (leaf-refs fun)))))
+ (lvar-dest (node-lvar (first (leaf-refs fun)))))
(cdr args))
(vars (lambda-vars fun) (cdr vars)))
((eq (car vars) var)
- (reoptimize-continuation (car args))))))
+ (reoptimize-lvar (car args))))))
(values))
;;; Delete a function that has no references. This need only be called
(clambda (delete-lambda fun)))
(values))
-;;; Deal with deleting the last reference to a LAMBDA. Since there is
-;;; only one way into a LAMBDA, deleting the last reference to a
-;;; LAMBDA ensures that there is no way to reach any of the code in
+;;; Deal with deleting the last reference to a CLAMBDA. Since there is
+;;; only one way into a CLAMBDA, deleting the last reference to a
+;;; CLAMBDA ensures that there is no way to reach any of the code in
;;; it. So we just set the FUNCTIONAL-KIND for FUN and its LETs to
;;; :DELETED, causing IR1 optimization to delete blocks in that
-;;; lambda.
-;;;
-;;; If the function isn't a LET, we unlink the function head and tail
-;;; from the component head and tail to indicate that the code is
-;;; unreachable. We also delete the function from COMPONENT-LAMBDAS
-;;; (it won't be there before local call analysis, but no matter.) If
-;;; the lambda was never referenced, we give a note.
-;;;
-;;; If the lambda is an XEP, then we null out the ENTRY-FUN in its
-;;; ENTRY-FUN so that people will know that it is not an entry point
-;;; anymore.
-(defun delete-lambda (leaf)
- (declare (type clambda leaf))
- (let ((kind (functional-kind leaf))
- (bind (lambda-bind leaf)))
- (aver (not (member kind '(:deleted :optional :toplevel))))
- (aver (not (functional-has-external-references-p leaf)))
- (setf (functional-kind leaf) :deleted)
- (setf (lambda-bind leaf) nil)
- (dolist (let (lambda-lets leaf))
+;;; CLAMBDA.
+(defun delete-lambda (clambda)
+ (declare (type clambda clambda))
+ (let ((original-kind (functional-kind clambda))
+ (bind (lambda-bind clambda)))
+ (aver (not (member original-kind '(:deleted :optional :toplevel))))
+ (aver (not (functional-has-external-references-p clambda)))
+ (setf (functional-kind clambda) :deleted)
+ (setf (lambda-bind clambda) nil)
+ (dolist (let (lambda-lets clambda))
(setf (lambda-bind let) nil)
(setf (functional-kind let) :deleted))
- (if (member kind '(:let :mv-let :assignment))
- (let ((home (lambda-home leaf)))
- (setf (lambda-lets home) (delete leaf (lambda-lets home))))
+ ;; LET may be deleted if its BIND is unreachable. Autonomous
+ ;; function may be deleted if it has no reachable references.
+ (unless (member original-kind '(:let :mv-let :assignment))
+ (dolist (ref (lambda-refs clambda))
+ (mark-for-deletion (node-block ref))))
+
+ ;; (The IF test is (FUNCTIONAL-SOMEWHAT-LETLIKE-P CLAMBDA), except
+ ;; that we're using the old value of the KIND slot, not the
+ ;; current slot value, which has now been set to :DELETED.)
+ (if (member original-kind '(:let :mv-let :assignment))
+ (let ((home (lambda-home clambda)))
+ (setf (lambda-lets home) (delete clambda (lambda-lets home))))
+ ;; If the function isn't a LET, we unlink the function head
+ ;; and tail from the component head and tail to indicate that
+ ;; the code is unreachable. We also delete the function from
+ ;; COMPONENT-LAMBDAS (it won't be there before local call
+ ;; analysis, but no matter.) If the lambda was never
+ ;; referenced, we give a note.
(let* ((bind-block (node-block bind))
(component (block-component bind-block))
- (return (lambda-return leaf)))
- (aver (null (leaf-refs leaf)))
- (unless (leaf-ever-used leaf)
+ (return (lambda-return clambda))
+ (return-block (and return (node-block return))))
+ (unless (leaf-ever-used clambda)
(let ((*compiler-error-context* bind))
- (compiler-note "deleting unused function~:[.~;~:*~% ~S~]"
- (leaf-debug-name leaf))))
- (unlink-blocks (component-head component) bind-block)
- (when return
- (unlink-blocks (node-block return) (component-tail component)))
+ (compiler-notify 'code-deletion-note
+ :format-control "deleting unused function~:[.~;~:*~% ~S~]"
+ :format-arguments (list (leaf-debug-name clambda)))))
+ (unless (block-delete-p bind-block)
+ (unlink-blocks (component-head component) bind-block))
+ (when (and return-block (not (block-delete-p return-block)))
+ (mark-for-deletion return-block)
+ (unlink-blocks return-block (component-tail component)))
(setf (component-reanalyze component) t)
- (let ((tails (lambda-tail-set leaf)))
+ (let ((tails (lambda-tail-set clambda)))
(setf (tail-set-funs tails)
- (delete leaf (tail-set-funs tails)))
- (setf (lambda-tail-set leaf) nil))
+ (delete clambda (tail-set-funs tails)))
+ (setf (lambda-tail-set clambda) nil))
(setf (component-lambdas component)
- (delete leaf (component-lambdas component)))))
+ (delete clambda (component-lambdas component)))))
- (when (eq kind :external)
- (let ((fun (functional-entry-fun leaf)))
+ ;; If the lambda is an XEP, then we null out the ENTRY-FUN in its
+ ;; ENTRY-FUN so that people will know that it is not an entry
+ ;; point anymore.
+ (when (eq original-kind :external)
+ (let ((fun (functional-entry-fun clambda)))
(setf (functional-entry-fun fun) nil)
(when (optional-dispatch-p fun)
(delete-optional-dispatch fun)))))
;;; entry-points, making them be normal lambdas, and then deleting the
;;; ones with no references. This deletes any e-p lambdas that were
;;; either never referenced, or couldn't be deleted when the last
-;;; deference was deleted (due to their :OPTIONAL kind.)
+;;; reference was deleted (due to their :OPTIONAL kind.)
;;;
-;;; Note that the last optional ep may alias the main entry, so when
-;;; we process the main entry, its kind may have been changed to NIL
-;;; or even converted to a let.
+;;; Note that the last optional entry point may alias the main entry,
+;;; so when we process the main entry, its KIND may have been changed
+;;; to NIL or even converted to a LETlike value.
(defun delete-optional-dispatch (leaf)
(declare (type optional-dispatch leaf))
(let ((entry (functional-entry-fun leaf)))
(maybe-convert-to-assignment fun)))
(t
(maybe-convert-to-assignment fun)))))))
-
+
(dolist (ep (optional-dispatch-entry-points leaf))
- (frob ep))
+ (when (promise-ready-p ep)
+ (frob (force ep))))
(when (optional-dispatch-more-entry leaf)
(frob (optional-dispatch-more-entry leaf)))
(let ((main (optional-dispatch-main-entry leaf)))
(defun delete-ref (ref)
(declare (type ref ref))
(let* ((leaf (ref-leaf ref))
- (refs (delete ref (leaf-refs leaf))))
+ (refs (delq ref (leaf-refs leaf))))
(setf (leaf-refs leaf) refs)
(cond ((null refs)
(typecase leaf
- (lambda-var (delete-lambda-var leaf))
+ (lambda-var
+ (delete-lambda-var leaf))
(clambda
(ecase (functional-kind leaf)
((nil :let :mv-let :assignment :escape :cleanup)
- (aver (not (functional-entry-fun leaf)))
+ (aver (null (functional-entry-fun leaf)))
(delete-lambda leaf))
(:external
(delete-lambda leaf))
(values))
;;; This function is called by people who delete nodes; it provides a
-;;; way to indicate that the value of a continuation is no longer
-;;; used. We null out the CONTINUATION-DEST, set FLUSH-P in the blocks
-;;; containing uses of CONT and set COMPONENT-REOPTIMIZE. If the PREV
-;;; of the use is deleted, then we blow off reoptimization.
-;;;
-;;; If the continuation is :Deleted, then we don't do anything, since
-;;; all semantics have already been flushed. :DELETED-BLOCK-START
-;;; start continuations are treated just like :BLOCK-START; it is
-;;; possible that the continuation may be given a new dest (e.g. by
-;;; SUBSTITUTE-CONTINUATION), so we don't want to delete it.
-(defun flush-dest (cont)
- (declare (type continuation cont))
-
- (unless (eq (continuation-kind cont) :deleted)
- (aver (continuation-dest cont))
- (setf (continuation-dest cont) nil)
- (do-uses (use cont)
+;;; way to indicate that the value of a lvar is no longer used. We
+;;; null out the LVAR-DEST, set FLUSH-P in the blocks containing uses
+;;; of LVAR and set COMPONENT-REOPTIMIZE.
+(defun flush-dest (lvar)
+ (declare (type (or lvar null) lvar))
+ (unless (null lvar)
+ (setf (lvar-dest lvar) nil)
+ (flush-lvar-externally-checkable-type lvar)
+ (do-uses (use lvar)
(let ((prev (node-prev use)))
- (unless (eq (continuation-kind prev) :deleted)
- (let ((block (continuation-block prev)))
- (setf (component-reoptimize (block-component block)) t)
- (setf (block-attributep (block-flags block) flush-p type-asserted)
- t))))))
-
- (setf (continuation-%type-check cont) nil)
-
+ (let ((block (ctran-block prev)))
+ (setf (component-reoptimize (block-component block)) t)
+ (setf (block-attributep (block-flags block) flush-p type-asserted)
+ t)))
+ (setf (node-lvar use) nil))
+ (setf (lvar-uses lvar) nil))
(values))
+(defun delete-dest (lvar)
+ (when lvar
+ (let* ((dest (lvar-dest lvar))
+ (prev (node-prev dest)))
+ (let ((block (ctran-block prev)))
+ (unless (block-delete-p block)
+ (mark-for-deletion block))))))
+
;;; Do a graph walk backward from BLOCK, marking all predecessor
;;; blocks with the DELETE-P flag.
(defun mark-for-deletion (block)
(declare (type cblock block))
- (unless (block-delete-p block)
- (setf (block-delete-p block) t)
- (setf (component-reanalyze (block-component block)) t)
- (dolist (pred (block-pred block))
- (mark-for-deletion pred)))
- (values))
-
-;;; Delete CONT, eliminating both control and value semantics. We set
-;;; FLUSH-P and COMPONENT-REOPTIMIZE similarly to in FLUSH-DEST. Here
-;;; we must get the component from the use block, since the
-;;; continuation may be a :DELETED-BLOCK-START.
-;;;
-;;; If CONT has DEST, then it must be the case that the DEST is
-;;; unreachable, since we can't compute the value desired. In this
-;;; case, we call MARK-FOR-DELETION to cause the DEST block and its
-;;; predecessors to tell people to ignore them, and to cause them to
-;;; be deleted eventually.
-(defun delete-continuation (cont)
- (declare (type continuation cont))
- (aver (not (eq (continuation-kind cont) :deleted)))
-
- (do-uses (use cont)
- (let ((prev (node-prev use)))
- (unless (eq (continuation-kind prev) :deleted)
- (let ((block (continuation-block prev)))
- (setf (block-attributep (block-flags block) flush-p type-asserted) t)
- (setf (component-reoptimize (block-component block)) t)))))
-
- (let ((dest (continuation-dest cont)))
- (when dest
- (let ((prev (node-prev dest)))
- (when (and prev
- (not (eq (continuation-kind prev) :deleted)))
- (let ((block (continuation-block prev)))
- (unless (block-delete-p block)
- (mark-for-deletion block)))))))
-
- (setf (continuation-kind cont) :deleted)
- (setf (continuation-dest cont) nil)
- (setf (continuation-next cont) nil)
- (setf (continuation-asserted-type cont) *empty-type*)
- (setf (continuation-%derived-type cont) *empty-type*)
- (setf (continuation-use cont) nil)
- (setf (continuation-block cont) nil)
- (setf (continuation-reoptimize cont) nil)
- (setf (continuation-%type-check cont) nil)
- (setf (continuation-info cont) nil)
-
+ (let* ((component (block-component block))
+ (head (component-head component)))
+ (labels ((helper (block)
+ (setf (block-delete-p block) t)
+ (dolist (pred (block-pred block))
+ (unless (or (block-delete-p pred)
+ (eq pred head))
+ (helper pred)))))
+ (unless (block-delete-p block)
+ (helper block)
+ (setf (component-reanalyze component) t))))
(values))
;;; This function does what is necessary to eliminate the code in it
;;; from the IR1 representation. This involves unlinking it from its
;;; predecessors and successors and deleting various node-specific
;;; semantic information.
-;;;
-;;; We mark the START as has having no next and remove the last node
-;;; from its CONT's uses. We also flush the DEST for all continuations
-;;; whose values are received by nodes in the block.
-(defun delete-block (block)
+(defun delete-block (block &optional silent)
(declare (type cblock block))
- (aver (block-component block)) ; else block is already deleted!
- (note-block-deletion block)
+ (aver (block-component block)) ; else block is already deleted!
+ (unless silent
+ (note-block-deletion block))
(setf (block-delete-p block) t)
- (let* ((last (block-last block))
- (cont (node-cont last)))
- (delete-continuation-use last)
- (if (eq (continuation-kind cont) :unused)
- (delete-continuation cont)
- (reoptimize-continuation cont)))
-
(dolist (b (block-pred block))
- (unlink-blocks b block))
+ (unlink-blocks b block)
+ ;; In bug 147 the almost-all-blocks-have-a-successor invariant was
+ ;; broken when successors were deleted without setting the
+ ;; BLOCK-DELETE-P flags of their predececessors. Make sure that
+ ;; doesn't happen again.
+ (aver (not (and (null (block-succ b))
+ (not (block-delete-p b))
+ (not (eq b (component-head (block-component b))))))))
(dolist (b (block-succ block))
(unlink-blocks block b))
- (do-nodes (node cont block)
+ (do-nodes-carefully (node block)
+ (when (valued-node-p node)
+ (delete-lvar-use node))
(typecase node
(ref (delete-ref node))
- (cif
- (flush-dest (if-test node)))
+ (cif (flush-dest (if-test node)))
;; The next two cases serve to maintain the invariant that a LET
;; always has a well-formed COMBINATION, REF and BIND. We delete
;; the lambda whenever we delete any of these, but we must be
;; careful that this LET has not already been partially deleted.
(basic-combination
(when (and (eq (basic-combination-kind node) :local)
- ;; Guards COMBINATION-LAMBDA agains the REF being deleted.
- (continuation-use (basic-combination-fun node)))
- (let ((fun (combination-lambda node)))
- ;; If our REF was the 2'nd to last ref, and has been deleted, then
- ;; Fun may be a LET for some other combination.
- (when (and (member (functional-kind fun) '(:let :mv-let))
- (eq (let-combination fun) node))
- (delete-lambda fun))))
+ ;; Guards COMBINATION-LAMBDA agains the REF being deleted.
+ (lvar-uses (basic-combination-fun node)))
+ (let ((fun (combination-lambda node)))
+ ;; If our REF was the second-to-last ref, and has been
+ ;; deleted, then FUN may be a LET for some other
+ ;; combination.
+ (when (and (functional-letlike-p fun)
+ (eq (let-combination fun) node))
+ (delete-lambda fun))))
(flush-dest (basic-combination-fun node))
(dolist (arg (basic-combination-args node))
- (when arg (flush-dest arg))))
+ (when arg (flush-dest arg))))
(bind
(let ((lambda (bind-lambda node)))
- (unless (eq (functional-kind lambda) :deleted)
- (aver (member (functional-kind lambda) '(:let :mv-let :assignment)))
- (delete-lambda lambda))))
+ (unless (eq (functional-kind lambda) :deleted)
+ (delete-lambda lambda))))
(exit
(let ((value (exit-value node))
- (entry (exit-entry node)))
- (when value
- (flush-dest value))
- (when entry
- (setf (entry-exits entry)
- (delete node (entry-exits entry))))))
+ (entry (exit-entry node)))
+ (when value
+ (flush-dest value))
+ (when entry
+ (setf (entry-exits entry)
+ (delq node (entry-exits entry))))))
(creturn
(flush-dest (return-result node))
(delete-return node))
(cset
(flush-dest (set-value node))
(let ((var (set-var node)))
- (setf (basic-var-sets var)
- (delete node (basic-var-sets var))))))
-
- (delete-continuation (node-prev node)))
+ (setf (basic-var-sets var)
+ (delete node (basic-var-sets var)))))
+ (cast
+ (flush-dest (cast-value node)))))
(remove-from-dfo block)
(values))
-;;; Do stuff to indicate that the return node Node is being deleted.
-;;; We set the RETURN to NIL.
+;;; Do stuff to indicate that the return node NODE is being deleted.
(defun delete-return (node)
(declare (type creturn node))
- (let ((fun (return-lambda node)))
+ (let* ((fun (return-lambda node))
+ (tail-set (lambda-tail-set fun)))
(aver (lambda-return fun))
- (setf (lambda-return fun) nil))
+ (setf (lambda-return fun) nil)
+ (when (and tail-set (not (find-if #'lambda-return
+ (tail-set-funs tail-set))))
+ (setf (tail-set-type tail-set) *empty-type*)))
(values))
;;; If any of the VARS in FUN was never referenced and was not
(unless (policy *compiler-error-context* (= inhibit-warnings 3))
;; ANSI section "3.2.5 Exceptional Situations in the Compiler"
;; requires this to be no more than a STYLE-WARNING.
- (compiler-style-warning "The variable ~S is defined but never used."
- (leaf-debug-name var)))
+ (compiler-style-warn "The variable ~S is defined but never used."
+ (leaf-debug-name var)))
(setf (leaf-ever-used var) t)))) ; to avoid repeated warnings? -- WHN
(values))
(defun note-block-deletion (block)
(let ((home (block-home-lambda block)))
(unless (eq (functional-kind home) :deleted)
- (do-nodes (node cont block)
+ (do-nodes (node nil block)
(let* ((path (node-source-path node))
(first (first path)))
(when (or (eq first 'original-source-start)
(not (eq pkg (symbol-package :end))))))
(not (member first *deletion-ignored-objects*))
(not (typep first '(or fixnum character)))
- (every #'(lambda (x)
- (present-in-form first x 0))
+ (every (lambda (x)
+ (present-in-form first x 0))
(source-path-forms path))
(present-in-form first (find-original-source path)
0)))
(unless (return-p node)
(let ((*compiler-error-context* node))
- (compiler-note "deleting unreachable code")))
+ (compiler-notify 'code-deletion-note
+ :format-control "deleting unreachable code"
+ :format-arguments nil)))
(return))))))
(values))
;;; Delete a node from a block, deleting the block if there are no
-;;; nodes left. We remove the node from the uses of its CONT, but we
-;;; don't deal with cleaning up any type-specific semantic
-;;; attachments. If the CONT is :UNUSED after deleting this use, then
-;;; we delete CONT. (Note :UNUSED is not the same as no uses. A
-;;; continuation will only become :UNUSED if it was :INSIDE-BLOCK
-;;; before.)
+;;; nodes left. We remove the node from the uses of its LVAR.
;;;
;;; If the node is the last node, there must be exactly one successor.
;;; We link all of our precedessors to the successor and unlink the
;;; empty blocks in IR1.
(defun unlink-node (node)
(declare (type node node))
- (let* ((cont (node-cont node))
- (next (continuation-next cont))
+ (when (valued-node-p node)
+ (delete-lvar-use node))
+
+ (let* ((ctran (node-next node))
+ (next (and ctran (ctran-next ctran)))
(prev (node-prev node))
- (block (continuation-block prev))
- (prev-kind (continuation-kind prev))
+ (block (ctran-block prev))
+ (prev-kind (ctran-kind prev))
(last (block-last block)))
- (unless (eq (continuation-kind cont) :deleted)
- (delete-continuation-use node)
- (when (eq (continuation-kind cont) :unused)
- (aver (not (continuation-dest cont)))
- (delete-continuation cont)))
-
(setf (block-type-asserted block) t)
(setf (block-test-modified block) t)
(and (eq prev-kind :block-start)
(not (eq node last))))
(cond ((eq node last)
- (setf (block-last block) (continuation-use prev))
- (setf (continuation-next prev) nil))
+ (setf (block-last block) (ctran-use prev))
+ (setf (node-next (ctran-use prev)) nil))
(t
- (setf (continuation-next prev) next)
- (setf (node-prev next) prev)))
+ (setf (ctran-next prev) next)
+ (setf (node-prev next) prev)
+ (when (if-p next) ; AOP wanted
+ (reoptimize-lvar (if-test next)))))
(setf (node-prev node) nil)
nil)
(t
(aver (eq node last))
(let* ((succ (block-succ block))
(next (first succ)))
- (aver (and succ (null (cdr succ))))
+ (aver (singleton-p succ))
(cond
- ((member block succ)
- (with-ir1-environment node
- (let ((exit (make-exit))
- (dummy (make-continuation)))
- (setf (continuation-next prev) nil)
- (prev-link exit prev)
- (add-continuation-use exit dummy)
+ ((eq block (first succ))
+ (with-ir1-environment-from-node node
+ (let ((exit (make-exit)))
+ (setf (ctran-next prev) nil)
+ (link-node-to-previous-ctran exit prev)
(setf (block-last block) exit)))
(setf (node-prev node) nil)
nil)
(dolist (pred (block-pred block))
(change-block-successor pred block next))
(remove-from-dfo block)
- (cond ((continuation-dest prev)
- (setf (continuation-next prev) nil)
- (setf (continuation-kind prev) :deleted-block-start))
- (t
- (delete-continuation prev)))
+ (setf (block-delete-p block) t)
(setf (node-prev node) nil)
t)))))))
(declare (type node node))
(let ((prev (node-prev node)))
(not (and prev
- (not (eq (continuation-kind prev) :deleted))
- (let ((block (continuation-block prev)))
+ (let ((block (ctran-block prev)))
(and (block-component block)
(not (block-delete-p block))))))))
;;; Delete all the blocks and functions in COMPONENT. We scan first
-;;; marking the blocks as delete-p to prevent weird stuff from being
+;;; marking the blocks as DELETE-P to prevent weird stuff from being
;;; triggered by deletion.
(defun delete-component (component)
(declare (type component component))
- (aver (null (component-new-funs component)))
+ (aver (null (component-new-functionals component)))
(setf (component-kind component) :deleted)
(do-blocks (block component)
(setf (block-delete-p block) t))
;;; of arguments changes, the transform must be prepared to return a
;;; lambda with a new lambda-list with the correct number of
;;; arguments.
-(defun extract-function-args (cont fun num-args)
+(defun extract-fun-args (lvar fun num-args)
#!+sb-doc
- "If CONT is a call to FUN with NUM-ARGS args, change those arguments
- to feed directly to the continuation-dest of CONT, which must be
- a combination."
- (declare (type continuation cont)
+ "If LVAR is a call to FUN with NUM-ARGS args, change those arguments
+ to feed directly to the LVAR-DEST of LVAR, which must be a
+ combination."
+ (declare (type lvar lvar)
(type symbol fun)
(type index num-args))
- (let ((outside (continuation-dest cont))
- (inside (continuation-use cont)))
+ (let ((outside (lvar-dest lvar))
+ (inside (lvar-uses lvar)))
(aver (combination-p outside))
(unless (combination-p inside)
(give-up-ir1-transform))
(let ((inside-fun (combination-fun inside)))
- (unless (eq (continuation-fun-name inside-fun) fun)
+ (unless (eq (lvar-fun-name inside-fun) fun)
(give-up-ir1-transform))
(let ((inside-args (combination-args inside)))
(unless (= (length inside-args) num-args)
(give-up-ir1-transform))
(let* ((outside-args (combination-args outside))
- (arg-position (position cont outside-args))
+ (arg-position (position lvar outside-args))
(before-args (subseq outside-args 0 arg-position))
(after-args (subseq outside-args (1+ arg-position))))
(dolist (arg inside-args)
- (setf (continuation-dest arg) outside))
+ (setf (lvar-dest arg) outside)
+ (flush-lvar-externally-checkable-type arg))
(setf (combination-args inside) nil)
(setf (combination-args outside)
(append before-args inside-args after-args))
- (change-ref-leaf (continuation-use inside-fun)
- (find-free-function 'list "???"))
- (setf (combination-kind inside) :full)
+ (change-ref-leaf (lvar-uses inside-fun)
+ (find-free-fun 'list "???"))
+ (setf (combination-kind inside)
+ (info :function :info 'list))
(setf (node-derived-type inside) *wild-type*)
- (flush-dest cont)
- (setf (continuation-asserted-type cont) *wild-type*)
+ (flush-dest lvar)
(values))))))
+
+(defun flush-combination (combination)
+ (declare (type combination combination))
+ (flush-dest (combination-fun combination))
+ (dolist (arg (combination-args combination))
+ (flush-dest arg))
+ (unlink-node combination)
+ (values))
+
\f
;;;; leaf hackery
(push ref (leaf-refs leaf))
(delete-ref ref)
(setf (ref-leaf ref) leaf)
- (let ((ltype (leaf-type leaf)))
- (if (fun-type-p ltype)
- (setf (node-derived-type ref) ltype)
- (derive-node-type ref ltype)))
- (reoptimize-continuation (node-cont ref)))
+ (setf (leaf-ever-used leaf) t)
+ (let* ((ltype (leaf-type leaf))
+ (vltype (make-single-value-type ltype)))
+ (if (let* ((lvar (node-lvar ref))
+ (dest (and lvar (lvar-dest lvar))))
+ (and (basic-combination-p dest)
+ (eq lvar (basic-combination-fun dest))
+ (csubtypep ltype (specifier-type 'function))))
+ (setf (node-derived-type ref) vltype)
+ (derive-node-type ref vltype)))
+ (reoptimize-lvar (node-lvar ref)))
(values))
;;; Change all REFS for OLD-LEAF to NEW-LEAF.
(change-ref-leaf ref new-leaf))
(values))
-;;; Like SUBSITUTE-LEAF, only there is a predicate on the REF to tell
-;;; whether to substitute.
+;;; like SUBSITUTE-LEAF, only there is a predicate on the REF to tell
+;;; whether to substitute
(defun substitute-leaf-if (test new-leaf old-leaf)
(declare (type leaf new-leaf old-leaf) (type function test))
(dolist (ref (leaf-refs old-leaf))
:type (ctype-of object)
:where-from :defined)))
\f
+;;; Return true if VAR would have to be closed over if environment
+;;; analysis ran now (i.e. if there are any uses that have a different
+;;; home lambda than VAR's home.)
+(defun closure-var-p (var)
+ (declare (type lambda-var var))
+ (let ((home (lambda-var-home var)))
+ (cond ((eq (functional-kind home) :deleted)
+ nil)
+ (t (let ((home (lambda-home home)))
+ (flet ((frob (l)
+ (find home l
+ :key #'node-home-lambda
+ :test-not #'eq)))
+ (or (frob (leaf-refs var))
+ (frob (basic-var-sets var)))))))))
+
;;; If there is a non-local exit noted in ENTRY's environment that
;;; exits to CONT in that entry, then return it, otherwise return NIL.
-(defun find-nlx-info (entry cont)
- (declare (type entry entry) (type continuation cont))
- (let ((entry-cleanup (entry-cleanup entry)))
+(defun find-nlx-info (exit)
+ (declare (type exit exit))
+ (let* ((entry (exit-entry exit))
+ (entry-cleanup (entry-cleanup entry)))
(dolist (nlx (physenv-nlx-info (node-physenv entry)) nil)
- (when (and (eq (nlx-info-continuation nlx) cont)
- (eq (nlx-info-cleanup nlx) entry-cleanup))
+ (when (eq (nlx-info-exit nlx) exit)
(return nlx)))))
\f
;;;; functional hackery
-(declaim (ftype (function (functional) clambda) main-entry))
+(declaim (ftype (sfunction (functional) clambda) main-entry))
(defun main-entry (functional)
(etypecase functional
(clambda functional)
;;; MV-BIND when it appears in an MV-CALL. All fixed arguments must be
;;; optional with null default and no SUPPLIED-P. There must be a
;;; &REST arg with no references.
-(declaim (ftype (function (functional) boolean) looks-like-an-mv-bind))
+(declaim (ftype (sfunction (functional) boolean) looks-like-an-mv-bind))
(defun looks-like-an-mv-bind (functional)
(and (optional-dispatch-p functional)
(do ((arg (optional-dispatch-arglist functional) (cdr arg)))
(t
(return nil)))))))
-;;; Return true if function is an XEP. This is true of normal XEPs
-;;; (:EXTERNAL kind) and top level lambdas (:TOPLEVEL kind.)
-(defun external-entry-point-p (fun)
+;;; Return true if function is an external entry point. This is true
+;;; of normal XEPs (:EXTERNAL kind) and also of top level lambdas
+;;; (:TOPLEVEL kind.)
+(defun xep-p (fun)
(declare (type functional fun))
(not (null (member (functional-kind fun) '(:external :toplevel)))))
-;;; If CONT's only use is a non-notinline global function reference,
+;;; If LVAR's only use is a non-notinline global function reference,
;;; then return the referenced symbol, otherwise NIL. If NOTINLINE-OK
;;; is true, then we don't care if the leaf is NOTINLINE.
-(defun continuation-fun-name (cont &optional notinline-ok)
- (declare (type continuation cont))
- (let ((use (continuation-use cont)))
+(defun lvar-fun-name (lvar &optional notinline-ok)
+ (declare (type lvar lvar))
+ (let ((use (lvar-uses lvar)))
(if (ref-p use)
(let ((leaf (ref-leaf use)))
(if (and (global-var-p leaf)
nil))
nil)))
+;;; Return the source name of a combination. (This is an idiom
+;;; which was used in CMU CL. I gather it always works. -- WHN)
+(defun combination-fun-source-name (combination)
+ (let ((ref (lvar-uses (combination-fun combination))))
+ (leaf-source-name (ref-leaf ref))))
+
;;; Return the COMBINATION node that is the call to the LET FUN.
(defun let-combination (fun)
(declare (type clambda fun))
- (aver (member (functional-kind fun) '(:let :mv-let)))
- (continuation-dest (node-cont (first (leaf-refs fun)))))
+ (aver (functional-letlike-p fun))
+ (lvar-dest (node-lvar (first (leaf-refs fun)))))
-;;; Return the initial value continuation for a LET variable, or NIL
-;;; if there is none.
+;;; Return the initial value lvar for a LET variable, or NIL if there
+;;; is none.
(defun let-var-initial-value (var)
(declare (type lambda-var var))
(let ((fun (lambda-var-home var)))
(elt (combination-args (let-combination fun))
(position-or-lose var (lambda-vars fun)))))
-;;; Return the LAMBDA that is called by the local Call.
-#!-sb-fluid (declaim (inline combination-lambda))
+;;; Return the LAMBDA that is called by the local CALL.
(defun combination-lambda (call)
(declare (type basic-combination call))
(aver (eq (basic-combination-kind call) :local))
- (ref-leaf (continuation-use (basic-combination-fun call))))
+ (ref-leaf (lvar-uses (basic-combination-fun call))))
(defvar *inline-expansion-limit* 200
#!+sb-doc
;; compiler to be able to use WITH-COMPILATION-UNIT on
;; arbitrarily huge blocks of code. -- WHN)
(let ((*compiler-error-context* node))
- (compiler-note "*INLINE-EXPANSION-LIMIT* (~D) was exceeded, ~
- probably trying to~% ~
- inline a recursive function."
- *inline-expansion-limit*))
+ (compiler-notify "*INLINE-EXPANSION-LIMIT* (~W) was exceeded, ~
+ probably trying to~% ~
+ inline a recursive function."
+ *inline-expansion-limit*))
nil)
(t t))))
+
+;;; Make sure that FUNCTIONAL is not let-converted or deleted.
+(defun assure-functional-live-p (functional)
+ (declare (type functional functional))
+ (when (and (or
+ ;; looks LET-converted
+ (functional-somewhat-letlike-p functional)
+ ;; It's possible for a LET-converted function to end up
+ ;; deleted later. In that case, for the purposes of this
+ ;; analysis, it is LET-converted: LET-converted functionals
+ ;; are too badly trashed to expand them inline, and deleted
+ ;; LET-converted functionals are even worse.
+ (eql (functional-kind functional) :deleted)))
+ (throw 'locall-already-let-converted functional)))
\f
;;;; careful call
;;; Apply a function to some arguments, returning a list of the values
;;; resulting of the evaluation. If an error is signalled during the
-;;; application, then we print a warning message and return NIL as our
-;;; second value to indicate this. Node is used as the error context
-;;; for any error message, and Context is a string that is spliced
-;;; into the warning.
-(declaim (ftype (function ((or symbol function) list node string)
+;;; application, then we produce a warning message using WARN-FUN and
+;;; return NIL as our second value to indicate this. NODE is used as
+;;; the error context for any error message, and CONTEXT is a string
+;;; that is spliced into the warning.
+(declaim (ftype (sfunction ((or symbol function) list node function string)
(values list boolean))
careful-call))
-(defun careful-call (function args node context)
+(defun careful-call (function args node warn-fun context)
(values
(multiple-value-list
(handler-case (apply function args)
(error (condition)
(let ((*compiler-error-context* node))
- (compiler-warning "Lisp error during ~A:~%~A" context condition)
+ (funcall warn-fun "Lisp error during ~A:~%~A" context condition)
(return-from careful-call (values nil nil))))))
t))
+
+;;; Variations of SPECIFIER-TYPE for parsing possibly wrong
+;;; specifiers.
+(macrolet
+ ((deffrob (basic careful compiler transform)
+ `(progn
+ (defun ,careful (specifier)
+ (handler-case (,basic specifier)
+ (sb!kernel::arg-count-error (condition)
+ (values nil (list (format nil "~A" condition))))
+ (simple-error (condition)
+ (values nil (list* (simple-condition-format-control condition)
+ (simple-condition-format-arguments condition))))))
+ (defun ,compiler (specifier)
+ (multiple-value-bind (type error-args) (,careful specifier)
+ (or type
+ (apply #'compiler-error error-args))))
+ (defun ,transform (specifier)
+ (multiple-value-bind (type error-args) (,careful specifier)
+ (or type
+ (apply #'give-up-ir1-transform
+ error-args)))))))
+ (deffrob specifier-type careful-specifier-type compiler-specifier-type ir1-transform-specifier-type)
+ (deffrob values-specifier-type careful-values-specifier-type compiler-values-specifier-type ir1-transform-values-specifier-type))
+
\f
;;;; utilities used at run-time for parsing &KEY args in IR1
;;; This function is used by the result of PARSE-DEFTRANSFORM to find
-;;; the continuation for the value of the &KEY argument KEY in the
-;;; list of continuations ARGS. It returns the continuation if the
-;;; keyword is present, or NIL otherwise. The legality and
-;;; constantness of the keywords should already have been checked.
-(declaim (ftype (function (list keyword) (or continuation null))
- find-keyword-continuation))
-(defun find-keyword-continuation (args key)
+;;; the lvar for the value of the &KEY argument KEY in the list of
+;;; lvars ARGS. It returns the lvar if the keyword is present, or NIL
+;;; otherwise. The legality and constantness of the keywords should
+;;; already have been checked.
+(declaim (ftype (sfunction (list keyword) (or lvar null))
+ find-keyword-lvar))
+(defun find-keyword-lvar (args key)
(do ((arg args (cddr arg)))
((null arg) nil)
- (when (eq (continuation-value (first arg)) key)
+ (when (eq (lvar-value (first arg)) key)
(return (second arg)))))
;;; This function is used by the result of PARSE-DEFTRANSFORM to
-;;; verify that alternating continuations in ARGS are constant and
-;;; that there is an even number of args.
-(declaim (ftype (function (list) boolean) check-key-args-constant))
+;;; verify that alternating lvars in ARGS are constant and that there
+;;; is an even number of args.
+(declaim (ftype (sfunction (list) boolean) check-key-args-constant))
(defun check-key-args-constant (args)
(do ((arg args (cddr arg)))
((null arg) t)
(unless (and (rest arg)
- (constant-continuation-p (first arg)))
+ (constant-lvar-p (first arg)))
(return nil))))
;;; This function is used by the result of PARSE-DEFTRANSFORM to
-;;; verify that the list of continuations ARGS is a well-formed &KEY
-;;; arglist and that only keywords present in the list KEYS are
-;;; supplied.
-(declaim (ftype (function (list list) boolean) check-transform-keys))
+;;; verify that the list of lvars ARGS is a well-formed &KEY arglist
+;;; and that only keywords present in the list KEYS are supplied.
+(declaim (ftype (sfunction (list list) boolean) check-transform-keys))
(defun check-transform-keys (args keys)
(and (check-key-args-constant args)
(do ((arg args (cddr arg)))
((null arg) t)
- (unless (member (continuation-value (first arg)) keys)
+ (unless (member (lvar-value (first arg)) keys)
(return nil)))))
\f
;;;; miscellaneous
;;; Called by the expansion of the EVENT macro.
-(declaim (ftype (function (event-info (or node null)) *) %event))
+(declaim (ftype (sfunction (event-info (or node null)) *) %event))
(defun %event (info node)
(incf (event-info-count info))
(when (and (>= (event-info-level info) *event-note-threshold*)
(policy (or node *lexenv*)
(= inhibit-warnings 0)))
(let ((*compiler-error-context* node))
- (compiler-note (event-info-description info))))
+ (compiler-notify (event-info-description info))))
(let ((action (event-info-action info)))
(when action (funcall action node))))
+
+;;;
+(defun make-cast (value type policy)
+ (declare (type lvar value)
+ (type ctype type)
+ (type policy policy))
+ (%make-cast :asserted-type type
+ :type-to-check (maybe-weaken-check type policy)
+ :value value
+ :derived-type (coerce-to-values type)))
+
+(defun cast-type-check (cast)
+ (declare (type cast cast))
+ (when (cast-reoptimize cast)
+ (ir1-optimize-cast cast t))
+ (cast-%type-check cast))
+
+(defun note-single-valuified-lvar (lvar)
+ (declare (type (or lvar null) lvar))
+ (when lvar
+ (let ((use (lvar-uses lvar)))
+ (cond ((ref-p use)
+ (let ((leaf (ref-leaf use)))
+ (when (and (lambda-var-p leaf)
+ (null (rest (leaf-refs leaf))))
+ (reoptimize-lambda-var leaf))))
+ ((or (listp use) (combination-p use))
+ (do-uses (node lvar)
+ (setf (node-reoptimize node) t)
+ (setf (block-reoptimize (node-block node)) t)
+ (setf (component-reoptimize (node-component node)) t)))))))