\f
;;;; interface for obtaining results of constant folding
-;;; Return true for a CONTINUATION whose sole use is a reference to a
+;;; Return true for an LVAR whose sole use is a reference to a
;;; constant leaf.
-(defun constant-continuation-p (thing)
- (and (continuation-p thing)
- (let ((use (continuation-use thing)))
- (and (ref-p use)
- (constant-p (ref-leaf use))))))
-
-;;; Return the constant value for a continuation whose only use is a
-;;; constant node.
-(declaim (ftype (function (continuation) t) continuation-value))
-(defun continuation-value (cont)
- (aver (constant-continuation-p cont))
- (constant-value (ref-leaf (continuation-use cont))))
+(defun constant-lvar-p (thing)
+ (and (lvar-p thing)
+ (let ((use (principal-lvar-use thing)))
+ (and (ref-p use) (constant-p (ref-leaf use))))))
+
+;;; Return the constant value for an LVAR whose only use is a constant
+;;; node.
+(declaim (ftype (function (lvar) t) lvar-value))
+(defun lvar-value (lvar)
+ (let ((use (principal-lvar-use lvar)))
+ (constant-value (ref-leaf use))))
\f
;;;; interface for obtaining results of type inference
-;;; Return a (possibly values) type that describes what we have proven
-;;; about the type of Cont without taking any type assertions into
-;;; consideration. This is just the union of the NODE-DERIVED-TYPE of
-;;; all the uses. Most often people use CONTINUATION-DERIVED-TYPE or
-;;; CONTINUATION-TYPE instead of using this function directly.
-(defun continuation-proven-type (cont)
- (declare (type continuation cont))
- (ecase (continuation-kind cont)
- ((:block-start :deleted-block-start)
- (let ((uses (block-start-uses (continuation-block cont))))
- (if uses
- (do ((res (node-derived-type (first uses))
- (values-type-union (node-derived-type (first current))
- res))
- (current (rest uses) (rest current)))
- ((null current) res))
- *empty-type*)))
- (:inside-block
- (node-derived-type (continuation-use cont)))))
-
-;;; Our best guess for the type of this continuation's value. Note
-;;; that this may be VALUES or FUNCTION type, which cannot be passed
-;;; as an argument to the normal type operations. See
-;;; CONTINUATION-TYPE. This may be called on deleted continuations,
-;;; always returning *.
+;;; Our best guess for the type of this lvar's value. Note that this
+;;; may be VALUES or FUNCTION type, which cannot be passed as an
+;;; argument to the normal type operations. See LVAR-TYPE.
;;;
-;;; What we do is call CONTINUATION-PROVEN-TYPE and check whether the
-;;; result is a subtype of the assertion. If so, return the proven
-;;; type and set TYPE-CHECK to nil. Otherwise, return the intersection
-;;; of the asserted and proven types, and set TYPE-CHECK T. If
-;;; TYPE-CHECK already has a non-null value, then preserve it. Only in
-;;; the somewhat unusual circumstance of a newly discovered assertion
-;;; will we change TYPE-CHECK from NIL to T.
-;;;
-;;; The result value is cached in the CONTINUATION-%DERIVED-TYPE slot.
-;;; If the slot is true, just return that value, otherwise recompute
-;;; and stash the value there.
-#!-sb-fluid (declaim (inline continuation-derived-type))
-(defun continuation-derived-type (cont)
- (declare (type continuation cont))
- (or (continuation-%derived-type cont)
- (%continuation-derived-type cont)))
-(defun %continuation-derived-type (cont)
- (declare (type continuation cont))
- (let ((proven (continuation-proven-type cont))
- (asserted (continuation-asserted-type cont)))
- (cond ((values-subtypep proven asserted)
- (setf (continuation-%type-check cont) nil)
- (setf (continuation-%derived-type cont) proven))
- ((and (values-subtypep proven (specifier-type 'function))
- (values-subtypep asserted (specifier-type 'function)))
- ;; It's physically impossible for a runtime type check to
- ;; distinguish between the various subtypes of FUNCTION, so
- ;; it'd be pointless to do more type checks here.
- (setf (continuation-%type-check cont) nil)
- (setf (continuation-%derived-type cont)
- ;; FIXME: This should depend on optimization
- ;; policy. This is for SPEED > SAFETY:
- #+nil (values-type-intersection asserted proven)
- ;; and this is for SAFETY >= SPEED:
- #-nil proven))
- (t
- (unless (or (continuation-%type-check cont)
- (not (continuation-dest cont))
- (eq asserted *universal-type*))
- (setf (continuation-%type-check cont) t))
-
- (setf (continuation-%derived-type cont)
- (values-type-intersection asserted proven))))))
-
-;;; Call CONTINUATION-DERIVED-TYPE to make sure the slot is up to
-;;; date, then return it.
-#!-sb-fluid (declaim (inline continuation-type-check))
-(defun continuation-type-check (cont)
- (declare (type continuation cont))
- (continuation-derived-type cont)
- (continuation-%type-check cont))
-
-;;; Return the derived type for CONT's first value. This is guaranteed
+;;; The result value is cached in the LVAR-%DERIVED-TYPE slot. If the
+;;; slot is true, just return that value, otherwise recompute and
+;;; stash the value there.
+#!-sb-fluid (declaim (inline lvar-derived-type))
+(defun lvar-derived-type (lvar)
+ (declare (type lvar lvar))
+ (or (lvar-%derived-type lvar)
+ (setf (lvar-%derived-type lvar)
+ (%lvar-derived-type lvar))))
+(defun %lvar-derived-type (lvar)
+ (declare (type lvar lvar))
+ (let ((uses (lvar-uses lvar)))
+ (cond ((null uses) *empty-type*)
+ ((listp uses)
+ (do ((res (node-derived-type (first uses))
+ (values-type-union (node-derived-type (first current))
+ res))
+ (current (rest uses) (rest current)))
+ ((null current) res)))
+ (t
+ (node-derived-type (lvar-uses lvar))))))
+
+;;; Return the derived type for LVAR's first value. This is guaranteed
;;; not to be a VALUES or FUNCTION type.
-(declaim (ftype (function (continuation) ctype) continuation-type))
-(defun continuation-type (cont)
- (single-value-type (continuation-derived-type cont)))
+(declaim (ftype (sfunction (lvar) ctype) lvar-type))
+(defun lvar-type (lvar)
+ (single-value-type (lvar-derived-type lvar)))
+
+;;; If LVAR is an argument of a function, return a type which the
+;;; function checks LVAR for.
+#!-sb-fluid (declaim (inline lvar-externally-checkable-type))
+(defun lvar-externally-checkable-type (lvar)
+ (or (lvar-%externally-checkable-type lvar)
+ (%lvar-%externally-checkable-type lvar)))
+(defun %lvar-%externally-checkable-type (lvar)
+ (declare (type lvar lvar))
+ (let ((dest (lvar-dest lvar)))
+ (if (not (and dest (combination-p dest)))
+ ;; TODO: MV-COMBINATION
+ (setf (lvar-%externally-checkable-type lvar) *wild-type*)
+ (let* ((fun (combination-fun dest))
+ (args (combination-args dest))
+ (fun-type (lvar-type fun)))
+ (setf (lvar-%externally-checkable-type fun) *wild-type*)
+ (if (or (not (call-full-like-p dest))
+ (not (fun-type-p fun-type))
+ ;; FUN-TYPE might be (AND FUNCTION (SATISFIES ...)).
+ (fun-type-wild-args fun-type))
+ (dolist (arg args)
+ (when arg
+ (setf (lvar-%externally-checkable-type arg)
+ *wild-type*)))
+ (map-combination-args-and-types
+ (lambda (arg type)
+ (setf (lvar-%externally-checkable-type arg)
+ (acond ((lvar-%externally-checkable-type arg)
+ (values-type-intersection
+ it (coerce-to-values type)))
+ (t (coerce-to-values type)))))
+ dest)))))
+ (lvar-%externally-checkable-type lvar))
+#!-sb-fluid(declaim (inline flush-lvar-externally-checkable-type))
+(defun flush-lvar-externally-checkable-type (lvar)
+ (declare (type lvar lvar))
+ (setf (lvar-%externally-checkable-type lvar) nil))
\f
;;;; interface routines used by optimizers
;;; This function is called by optimizers to indicate that something
-;;; interesting has happened to the value of Cont. Optimizers must
+;;; interesting has happened to the value of LVAR. Optimizers must
;;; make sure that they don't call for reoptimization when nothing has
;;; happened, since optimization will fail to terminate.
;;;
-;;; We clear any cached type for the continuation and set the
-;;; reoptimize flags on everything in sight, unless the continuation
-;;; is deleted (in which case we do nothing.)
-;;;
-;;; Since this can get called during IR1 conversion, we have to be
-;;; careful not to fly into space when the Dest's Prev is missing.
-(defun reoptimize-continuation (cont)
- (declare (type continuation cont))
- (unless (member (continuation-kind cont) '(:deleted :unused))
- (setf (continuation-%derived-type cont) nil)
- (let ((dest (continuation-dest cont)))
+;;; We clear any cached type for the lvar and set the reoptimize flags
+;;; on everything in sight.
+(defun reoptimize-lvar (lvar)
+ (declare (type (or lvar null) lvar))
+ (when lvar
+ (setf (lvar-%derived-type lvar) nil)
+ (let ((dest (lvar-dest lvar)))
(when dest
- (setf (continuation-reoptimize cont) t)
- (setf (node-reoptimize dest) t)
- (let ((prev (node-prev dest)))
- (when prev
- (let* ((block (continuation-block prev))
- (component (block-component block)))
- (when (typep dest 'cif)
- (setf (block-test-modified block) t))
- (setf (block-reoptimize block) t)
- (setf (component-reoptimize component) t))))))
- (do-uses (node cont)
+ (setf (lvar-reoptimize lvar) t)
+ (setf (node-reoptimize dest) t)
+ (binding* (;; Since this may be called during IR1 conversion,
+ ;; PREV may be missing.
+ (prev (node-prev dest) :exit-if-null)
+ (block (ctran-block prev))
+ (component (block-component block)))
+ (when (typep dest 'cif)
+ (setf (block-test-modified block) t))
+ (setf (block-reoptimize block) t)
+ (setf (component-reoptimize component) t))))
+ (do-uses (node lvar)
(setf (block-type-check (node-block node)) t)))
(values))
-;;; Annotate Node to indicate that its result has been proven to be
-;;; typep to RType. After IR1 conversion has happened, this is the
+(defun reoptimize-lvar-uses (lvar)
+ (declare (type lvar lvar))
+ (do-uses (use lvar)
+ (setf (node-reoptimize use) t)
+ (setf (block-reoptimize (node-block use)) t)
+ (setf (component-reoptimize (node-component use)) t)))
+
+;;; Annotate NODE to indicate that its result has been proven to be
+;;; TYPEP to RTYPE. After IR1 conversion has happened, this is the
;;; only correct way to supply information discovered about a node's
-;;; type. If you screw with the Node-Derived-Type directly, then
+;;; type. If you screw with the NODE-DERIVED-TYPE directly, then
;;; information may be lost and reoptimization may not happen.
;;;
-;;; What we do is intersect Rtype with Node's Derived-Type. If the
+;;; What we do is intersect RTYPE with NODE's DERIVED-TYPE. If the
;;; intersection is different from the old type, then we do a
-;;; Reoptimize-Continuation on the Node-Cont.
+;;; REOPTIMIZE-LVAR on the NODE-LVAR.
(defun derive-node-type (node rtype)
- (declare (type node node) (type ctype rtype))
+ (declare (type valued-node node) (type ctype rtype))
(let ((node-type (node-derived-type node)))
(unless (eq node-type rtype)
- (let ((int (values-type-intersection node-type rtype)))
+ (let ((int (values-type-intersection node-type rtype))
+ (lvar (node-lvar node)))
(when (type/= node-type int)
(when (and *check-consistency*
(eq int *empty-type*)
~% ~S~%*** possible internal error? Please report this."
(type-specifier rtype) (type-specifier node-type))))
(setf (node-derived-type node) int)
- (reoptimize-continuation (node-cont node))))))
+ ;; If the new type consists of only one object, replace the
+ ;; node with a constant reference.
+ (when (and (ref-p node)
+ (lambda-var-p (ref-leaf node)))
+ (let ((type (single-value-type int)))
+ (when (and (member-type-p type)
+ (null (rest (member-type-members type))))
+ (change-ref-leaf node (find-constant
+ (first (member-type-members type)))))))
+ (reoptimize-lvar lvar)))))
(values))
;;; This is similar to DERIVE-NODE-TYPE, but asserts that it is an
-;;; error for CONT's value not to be TYPEP to TYPE. If we improve the
-;;; assertion, we set TYPE-CHECK and TYPE-ASSERTED to guarantee that
-;;; the new assertion will be checked.
-(defun assert-continuation-type (cont type)
- (declare (type continuation cont) (type ctype type))
- (let ((cont-type (continuation-asserted-type cont)))
- (unless (eq cont-type type)
- (let ((int (values-type-intersection cont-type type)))
- (when (type/= cont-type int)
- (setf (continuation-asserted-type cont) int)
- (do-uses (node cont)
- (setf (block-attributep (block-flags (node-block node))
- type-check type-asserted)
- t))
- (reoptimize-continuation cont)))))
- (values))
+;;; error for LVAR's value not to be TYPEP to TYPE. We implement it
+;;; splitting off DEST a new CAST node; old LVAR will deliver values
+;;; to CAST. If we improve the assertion, we set TYPE-CHECK and
+;;; TYPE-ASSERTED to guarantee that the new assertion will be checked.
+(defun assert-lvar-type (lvar type policy)
+ (declare (type lvar lvar) (type ctype type))
+ (unless (values-subtypep (lvar-derived-type lvar) type)
+ (let* ((dest (lvar-dest lvar))
+ (ctran (node-prev dest)))
+ (with-ir1-environment-from-node dest
+ (let* ((cast (make-cast lvar type policy))
+ (internal-lvar (make-lvar))
+ (internal-ctran (make-ctran)))
+ (setf (ctran-next ctran) cast
+ (node-prev cast) ctran)
+ (use-continuation cast internal-ctran internal-lvar)
+ (link-node-to-previous-ctran dest internal-ctran)
+ (substitute-lvar internal-lvar lvar)
+ (setf (lvar-dest lvar) cast)
+ (reoptimize-lvar lvar)
+ (when (return-p dest)
+ (node-ends-block cast))
+ (setf (block-attributep (block-flags (node-block cast))
+ type-check type-asserted)
+ t))))))
-;;; Assert that CALL is to a function of the specified TYPE. It is
-;;; assumed that the call is legal and has only constants in the
-;;; keyword positions.
-(defun assert-call-type (call type)
- (declare (type combination call) (type fun-type type))
- (derive-node-type call (fun-type-returns type))
- (let ((args (combination-args call)))
- (dolist (req (fun-type-required type))
- (when (null args) (return-from assert-call-type))
- (let ((arg (pop args)))
- (assert-continuation-type arg req)))
- (dolist (opt (fun-type-optional type))
- (when (null args) (return-from assert-call-type))
- (let ((arg (pop args)))
- (assert-continuation-type arg opt)))
-
- (let ((rest (fun-type-rest type)))
- (when rest
- (dolist (arg args)
- (assert-continuation-type arg rest))))
-
- (dolist (key (fun-type-keywords type))
- (let ((name (key-info-name key)))
- (do ((arg args (cddr arg)))
- ((null arg))
- (when (eq (continuation-value (first arg)) name)
- (assert-continuation-type
- (second arg) (key-info-type key)))))))
- (values))
\f
;;;; IR1-OPTIMIZE
(setf (component-reoptimize component) nil)
(do-blocks (block component)
(cond
- ((or (block-delete-p block)
- (null (block-pred block)))
- (delete-block block))
- ((eq (functional-kind (block-home-lambda block)) :deleted)
- ;; Preserve the BLOCK-SUCC invariant that almost every block has
- ;; one successor (and a block with DELETE-P set is an acceptable
- ;; exception).
- (labels ((mark-blocks (block)
- (dolist (pred (block-pred block))
- (when (and (not (block-delete-p pred))
- (eq (functional-kind (block-home-lambda pred))
- :deleted))
- (setf (block-delete-p pred) t)
- (mark-blocks pred)))))
- (mark-blocks block)
- (delete-block block)))
- (t
- (loop
- (let ((succ (block-succ block)))
- (unless (and succ (null (rest succ)))
- (return)))
-
- (let ((last (block-last block)))
- (typecase last
- (cif
- (flush-dest (if-test last))
- (when (unlink-node last)
- (return)))
- (exit
- (when (maybe-delete-exit last)
- (return)))))
-
- (unless (join-successor-if-possible block)
- (return)))
-
- (when (and (block-reoptimize block) (block-component block))
- (aver (not (block-delete-p block)))
- (ir1-optimize-block block))
-
;; We delete blocks when there is either no predecessor or the
;; block is in a lambda that has been deleted. These blocks
;; would eventually be deleted by DFO recomputation, but doing
;; it here immediately makes the effect available to IR1
;; optimization.
- (when (and (block-flush-p block) (block-component block))
- (aver (not (block-delete-p block)))
- (flush-dead-code block)))))
+ ((or (block-delete-p block)
+ (null (block-pred block)))
+ (delete-block block))
+ ((eq (functional-kind (block-home-lambda block)) :deleted)
+ ;; Preserve the BLOCK-SUCC invariant that almost every block has
+ ;; one successor (and a block with DELETE-P set is an acceptable
+ ;; exception).
+ (mark-for-deletion block)
+ (delete-block block))
+ (t
+ (loop
+ (let ((succ (block-succ block)))
+ (unless (singleton-p succ)
+ (return)))
+
+ (let ((last (block-last block)))
+ (typecase last
+ (cif
+ (flush-dest (if-test last))
+ (when (unlink-node last)
+ (return)))
+ (exit
+ (when (maybe-delete-exit last)
+ (return)))))
+
+ (unless (join-successor-if-possible block)
+ (return)))
+
+ (when (and (block-reoptimize block) (block-component block))
+ (aver (not (block-delete-p block)))
+ (ir1-optimize-block block))
+
+ (cond ((and (block-delete-p block) (block-component block))
+ (delete-block block))
+ ((and (block-flush-p block) (block-component block))
+ (flush-dead-code block))))))
(values))
;; optimization, not after. This ensures that the node or block will
;; be reoptimized if necessary.
(setf (block-reoptimize block) nil)
- (do-nodes (node cont block :restart-p t)
+ (do-nodes (node nil block :restart-p t)
(when (node-reoptimize node)
;; As above, we clear the node REOPTIMIZE flag before optimizing.
(setf (node-reoptimize node) nil)
(ir1-optimize-mv-combination node))
(exit
;; With an EXIT, we derive the node's type from the VALUE's
- ;; type. We don't propagate CONT's assertion to the VALUE,
- ;; since if we did, this would move the checking of CONT's
- ;; assertion to the exit. This wouldn't work with CATCH and
- ;; UWP, where the EXIT node is just a placeholder for the
- ;; actual unknown exit.
+ ;; type.
(let ((value (exit-value node)))
(when value
- (derive-node-type node (continuation-derived-type value)))))
+ (derive-node-type node (lvar-derived-type value)))))
(cset
- (ir1-optimize-set node)))))
+ (ir1-optimize-set node))
+ (cast
+ (ir1-optimize-cast node)))))
+
(values))
;;; Try to join with a successor block. If we succeed, we return true,
(defun join-successor-if-possible (block)
(declare (type cblock block))
(let ((next (first (block-succ block))))
- (when (block-start next)
- (let* ((last (block-last block))
- (last-cont (node-cont last))
- (next-cont (block-start next)))
- (cond (;; We cannot combine with a successor block if:
- (or
- ;; The successor has more than one predecessor.
- (rest (block-pred next))
- ;; The last node's CONT is also used somewhere else.
- (not (eq (continuation-use last-cont) last))
- ;; The successor is the current block (infinite loop).
- (eq next block)
- ;; The next block has a different cleanup, and thus
- ;; we may want to insert cleanup code between the
- ;; two blocks at some point.
- (not (eq (block-end-cleanup block)
- (block-start-cleanup next)))
- ;; The next block has a different home lambda, and
- ;; thus the control transfer is a non-local exit.
- (not (eq (block-home-lambda block)
- (block-home-lambda next))))
- nil)
- ;; Joining is easy when the successor's START
- ;; continuation is the same from our LAST's CONT.
- ((eq last-cont next-cont)
- (join-blocks block next)
- t)
- ;; If they differ, then we can still join when the last
- ;; continuation has no next and the next continuation
- ;; has no uses.
- ((and (null (block-start-uses next))
- (eq (continuation-kind last-cont) :inside-block))
- ;; In this case, we replace the next
- ;; continuation with the last before joining the blocks.
- (let ((next-node (continuation-next next-cont)))
- ;; If NEXT-CONT does have a dest, it must be
- ;; unreachable, since there are no USES.
- ;; DELETE-CONTINUATION will mark the dest block as
- ;; DELETE-P [and also this block, unless it is no
- ;; longer backward reachable from the dest block.]
- (delete-continuation next-cont)
- (setf (node-prev next-node) last-cont)
- (setf (continuation-next last-cont) next-node)
- (setf (block-start next) last-cont)
- (join-blocks block next))
- t)
- (t
- nil))))))
-
-;;; Join together two blocks which have the same ending/starting
-;;; continuation. The code in BLOCK2 is moved into BLOCK1 and BLOCK2
-;;; is deleted from the DFO. We combine the optimize flags for the two
-;;; blocks so that any indicated optimization gets done.
+ (when (block-start next) ; NEXT is not an END-OF-COMPONENT marker
+ (cond ( ;; We cannot combine with a successor block if:
+ (or
+ ;; The successor has more than one predecessor.
+ (rest (block-pred next))
+ ;; The successor is the current block (infinite loop).
+ (eq next block)
+ ;; The next block has a different cleanup, and thus
+ ;; we may want to insert cleanup code between the
+ ;; two blocks at some point.
+ (not (eq (block-end-cleanup block)
+ (block-start-cleanup next)))
+ ;; The next block has a different home lambda, and
+ ;; thus the control transfer is a non-local exit.
+ (not (eq (block-home-lambda block)
+ (block-home-lambda next))))
+ nil)
+ (t
+ (join-blocks block next)
+ t)))))
+
+;;; Join together two blocks. The code in BLOCK2 is moved into BLOCK1
+;;; and BLOCK2 is deleted from the DFO. We combine the optimize flags
+;;; for the two blocks so that any indicated optimization gets done.
(defun join-blocks (block1 block2)
(declare (type cblock block1 block2))
- (let* ((last (block-last block2))
- (last-cont (node-cont last))
+ (let* ((last1 (block-last block1))
+ (last2 (block-last block2))
(succ (block-succ block2))
(start2 (block-start block2)))
- (do ((cont start2 (node-cont (continuation-next cont))))
- ((eq cont last-cont)
- (when (eq (continuation-kind last-cont) :inside-block)
- (setf (continuation-block last-cont) block1)))
- (setf (continuation-block cont) block1))
+ (do ((ctran start2 (node-next (ctran-next ctran))))
+ ((not ctran))
+ (setf (ctran-block ctran) block1))
(unlink-blocks block1 block2)
(dolist (block succ)
(unlink-blocks block2 block)
(link-blocks block1 block))
- (setf (block-last block1) last)
- (setf (continuation-kind start2) :inside-block))
+ (setf (ctran-kind start2) :inside-block)
+ (setf (node-next last1) start2)
+ (setf (ctran-use start2) last1)
+ (setf (block-last block1) last2))
(setf (block-flags block1)
(attributes-union (block-flags block1)
;;; variable has no references.
(defun flush-dead-code (block)
(declare (type cblock block))
- (do-nodes-backwards (node cont block)
- (unless (continuation-dest cont)
+ (setf (block-flush-p block) nil)
+ (do-nodes-backwards (node lvar block)
+ (unless lvar
(typecase node
(ref
(delete-ref node)
;; functional args to determine if they have
;; any side effects.
(if (policy node (= safety 3))
- (and (ir1-attributep attr flushable)
- (every (lambda (arg)
- (member (continuation-type-check arg)
- '(nil :deleted)))
- (basic-combination-args node))
- (valid-fun-use node
- (info :function :type
- (leaf-source-name (ref-leaf (continuation-use (basic-combination-fun node)))))
- :result-test #'always-subtypep
- :lossage-fun nil
- :unwinnage-fun nil))
+ (ir1-attributep attr flushable)
(ir1-attributep attr unsafely-flushable)))
- (flush-dest (combination-fun node))
- (dolist (arg (combination-args node))
- (flush-dest arg))
- (unlink-node node))))))
+ (flush-combination node))))))
(mv-combination
(when (eq (basic-combination-kind node) :local)
(let ((fun (combination-lambda node)))
(null (leaf-refs var)))
(flush-dest (set-value node))
(setf (basic-var-sets var)
- (delete node (basic-var-sets var)))
- (unlink-node node)))))))
+ (delq node (basic-var-sets var)))
+ (unlink-node node))))
+ (cast
+ (unless (cast-type-check node)
+ (flush-dest (cast-value node))
+ (unlink-node node))))))
- (setf (block-flush-p block) nil)
(values))
\f
;;;; local call return type propagation
(return-from find-result-type (values)))))
(t
(use-union (node-derived-type use)))))
- (let ((int (values-type-intersection
- (continuation-asserted-type result)
- (use-union))))
+ (let ((int
+ ;; (values-type-intersection
+ ;; (continuation-asserted-type result) ; FIXME -- APD, 2002-01-26
+ (use-union)
+ ;; )
+ ))
(setf (return-result-type node) int))))
(values))
;;; all functions in the tail set to be equivalent, this amounts to
;;; bringing the entire tail set up to date. We iterate over the
;;; returns for all the functions in the tail set, reanalyzing them
-;;; all (not treating Node specially.)
+;;; all (not treating NODE specially.)
;;;
;;; When we are done, we check whether the new type is different from
;;; the old TAIL-SET-TYPE. If so, we set the type and also reoptimize
-;;; all the continuations for references to functions in the tail set.
-;;; This will cause IR1-OPTIMIZE-COMBINATION to derive the new type as
-;;; the results of the calls.
+;;; all the lvars for references to functions in the tail set. This
+;;; will cause IR1-OPTIMIZE-COMBINATION to derive the new type as the
+;;; results of the calls.
(defun ir1-optimize-return (node)
(declare (type creturn node))
(let* ((tails (lambda-tail-set (return-lambda node)))
(setf (tail-set-type tails) (res))
(dolist (fun (tail-set-funs tails))
(dolist (ref (leaf-refs fun))
- (reoptimize-continuation (node-cont ref)))))))
+ (reoptimize-lvar (node-lvar ref)))))))
(values))
\f
(let ((test (if-test node))
(block (node-block node)))
- (when (and (eq (block-start block) test)
- (eq (continuation-next test) node)
- (rest (block-start-uses block)))
+ (when (and (eq (block-start-node block) node)
+ (listp (lvar-uses test)))
(do-uses (use test)
(when (immediately-used-p test use)
(convert-if-if use node)
- (when (continuation-use test) (return)))))
-
- (let* ((type (continuation-type test))
- (victim
- (cond ((constant-continuation-p test)
- (if (continuation-value test)
- (if-alternative node)
- (if-consequent node)))
- ((not (types-equal-or-intersect type (specifier-type 'null)))
- (if-alternative node))
- ((type= type (specifier-type 'null))
- (if-consequent node)))))
+ (when (not (listp (lvar-uses test))) (return)))))
+
+ (let* ((type (lvar-type test))
+ (victim
+ (cond ((constant-lvar-p test)
+ (if (lvar-value test)
+ (if-alternative node)
+ (if-consequent node)))
+ ((not (types-equal-or-intersect type (specifier-type 'null)))
+ (if-alternative node))
+ ((type= type (specifier-type 'null))
+ (if-consequent node)))))
(when victim
- (flush-dest test)
- (when (rest (block-succ block))
- (unlink-blocks block victim))
- (setf (component-reanalyze (node-component node)) t)
- (unlink-node node))))
+ (flush-dest test)
+ (when (rest (block-succ block))
+ (unlink-blocks block victim))
+ (setf (component-reanalyze (node-component node)) t)
+ (unlink-node node))))
(values))
;;; Create a new copy of an IF node that tests the value of the node
(cblock (if-consequent node))
(ablock (if-alternative node))
(use-block (node-block use))
- (dummy-cont (make-continuation))
- (new-cont (make-continuation))
- (new-node (make-if :test new-cont
+ (new-ctran (make-ctran))
+ (new-lvar (make-lvar))
+ (new-node (make-if :test new-lvar
:consequent cblock
:alternative ablock))
- (new-block (continuation-starts-block new-cont)))
- (link-node-to-previous-continuation new-node new-cont)
- (setf (continuation-dest new-cont) new-node)
- (add-continuation-use new-node dummy-cont)
+ (new-block (ctran-starts-block new-ctran)))
+ (link-node-to-previous-ctran new-node new-ctran)
+ (setf (lvar-dest new-lvar) new-node)
(setf (block-last new-block) new-node)
(unlink-blocks use-block block)
- (delete-continuation-use use)
- (add-continuation-use use new-cont)
+ (%delete-lvar-use use)
+ (add-lvar-use use new-lvar)
(link-blocks use-block new-block)
(link-blocks new-block cblock)
(push "<IF Duplication>" (node-source-path node))
(push "<IF Duplication>" (node-source-path new-node))
- (reoptimize-continuation test)
- (reoptimize-continuation new-cont)
+ (reoptimize-lvar test)
+ (reoptimize-lvar new-lvar)
(setf (component-reanalyze *current-component*) t)))
(values))
\f
;;; anything, since there is nothing to be done.
;;; -- If the exit node and its ENTRY have the same home lambda then
;;; we know the exit is local, and can delete the exit. We change
-;;; uses of the Exit-Value to be uses of the original continuation,
+;;; uses of the Exit-Value to be uses of the original lvar,
;;; then unlink the node. If the exit is to a TR context, then we
;;; must do MERGE-TAIL-SETS on any local calls which delivered
;;; their value to this exit.
(defun maybe-delete-exit (node)
(declare (type exit node))
(let ((value (exit-value node))
- (entry (exit-entry node))
- (cont (node-cont node)))
+ (entry (exit-entry node)))
(when (and entry
(eq (node-home-lambda node) (node-home-lambda entry)))
- (setf (entry-exits entry) (delete node (entry-exits entry)))
- (prog1
- (unlink-node node)
- (when value
- (collect ((merges))
- (when (return-p (continuation-dest cont))
- (do-uses (use value)
- (when (and (basic-combination-p use)
- (eq (basic-combination-kind use) :local))
- (merges use))))
- (substitute-continuation-uses cont value)
- (dolist (merge (merges))
- (merge-tail-sets merge))))))))
+ (setf (entry-exits entry) (delq node (entry-exits entry)))
+ (if value
+ (delete-filter node (node-lvar node) value)
+ (unlink-node node)))))
+
\f
;;;; combination IR1 optimization
;;; Do IR1 optimizations on a COMBINATION node.
(declaim (ftype (function (combination) (values)) ir1-optimize-combination))
(defun ir1-optimize-combination (node)
- (when (continuation-reoptimize (basic-combination-fun node))
+ (when (lvar-reoptimize (basic-combination-fun node))
(propagate-fun-change node))
(let ((args (basic-combination-args node))
(kind (basic-combination-kind node)))
((:full :error)
(dolist (arg args)
(when arg
- (setf (continuation-reoptimize arg) nil))))
+ (setf (lvar-reoptimize arg) nil))))
(t
(dolist (arg args)
(when arg
- (setf (continuation-reoptimize arg) nil)))
+ (setf (lvar-reoptimize arg) nil)))
(let ((attr (fun-info-attributes kind)))
(when (and (ir1-attributep attr foldable)
;; CALL attributes when they're actually passed
;; function arguments. -- WHN 19990918
(not (ir1-attributep attr call))
- (every #'constant-continuation-p args)
- (continuation-dest (node-cont node))
+ (every #'constant-lvar-p args)
+ (node-lvar node)
;; Even if the function is foldable in principle,
;; it might be one of our low-level
;; implementation-specific functions. Such
;; cross-compiler can't fold it because the
;; cross-compiler doesn't know how to evaluate it.
#+sb-xc-host
- (fboundp (combination-fun-source-name node)))
+ (or (fboundp (combination-fun-source-name node))
+ (progn (format t ";;; !!! Unbound fun: (~S~{ ~S~})~%"
+ (combination-fun-source-name node)
+ (mapcar #'lvar-value args))
+ nil)))
(constant-fold-call node)
(return-from ir1-optimize-combination)))
(when fun
(let ((res (funcall fun node)))
(when res
- (derive-node-type node res)
+ (derive-node-type node (coerce-to-values res))
(maybe-terminate-block node nil)))))
(let ((fun (fun-info-optimizer kind)))
(unless (and fun (funcall fun node))
(dolist (x (fun-info-transforms kind))
- #!+sb-show
+ #!+sb-show
(when *show-transforms-p*
- (let* ((cont (basic-combination-fun node))
- (fname (continuation-fun-name cont t)))
+ (let* ((lvar (basic-combination-fun node))
+ (fname (lvar-fun-name lvar t)))
(/show "trying transform" x (transform-function x) "for" fname)))
(unless (ir1-transform node x)
#!+sb-show
(values))
-;;; If CALL is to a function that doesn't return (i.e. return type is
-;;; NIL), then terminate the block there, and link it to the component
-;;; tail. We also change the call's CONT to be a dummy continuation to
-;;; prevent the use from confusing things.
+;;; If NODE doesn't return (i.e. return type is NIL), then terminate
+;;; the block there, and link it to the component tail.
;;;
-;;; Except when called during IR1 [FIXME: What does this mean? Except
-;;; during IR1 conversion? What about IR1 optimization?], we delete
-;;; the continuation if it has no other uses. (If it does have other
-;;; uses, we reoptimize.)
+;;; Except when called during IR1 convertion, we delete the
+;;; continuation if it has no other uses. (If it does have other uses,
+;;; we reoptimize.)
;;;
-;;; Termination on the basis of a continuation type assertion is
+;;; Termination on the basis of a continuation type is
;;; inhibited when:
;;; -- The continuation is deleted (hence the assertion is spurious), or
;;; -- We are in IR1 conversion (where THE assertions are subject to
-;;; weakening.)
-(defun maybe-terminate-block (call ir1-converting-not-optimizing-p)
- (declare (type basic-combination call))
- (let* ((block (node-block call))
- (cont (node-cont call))
+;;; weakening.) FIXME: Now THE assertions are not weakened, but new
+;;; uses can(?) be added later. -- APD, 2003-07-17
+;;;
+;;; Why do we need to consider LVAR type? -- APD, 2003-07-30
+(defun maybe-terminate-block (node ir1-converting-not-optimizing-p)
+ (declare (type (or basic-combination cast) node))
+ (let* ((block (node-block node))
+ (lvar (node-lvar node))
+ (ctran (node-next node))
(tail (component-tail (block-component block)))
(succ (first (block-succ block))))
- (unless (or (and (eq call (block-last block)) (eq succ tail))
+ (unless (or (and (eq node (block-last block)) (eq succ tail))
(block-delete-p block))
- (when (or (and (eq (continuation-asserted-type cont) *empty-type*)
- (not (or ir1-converting-not-optimizing-p
- (eq (continuation-kind cont) :deleted))))
- (eq (node-derived-type call) *empty-type*))
+ (when (eq (node-derived-type node) *empty-type*)
(cond (ir1-converting-not-optimizing-p
- (delete-continuation-use call)
(cond
- ((block-last block)
- (aver (and (eq (block-last block) call)
- (eq (continuation-kind cont) :block-start))))
- (t
- (setf (block-last block) call)
- (link-blocks block (continuation-starts-block cont)))))
+ ((block-last block)
+ (aver (eq (block-last block) node)))
+ (t
+ (setf (block-last block) node)
+ (setf (ctran-use ctran) nil)
+ (setf (ctran-kind ctran) :unused)
+ (setf (ctran-block ctran) nil)
+ (setf (node-next node) nil)
+ (link-blocks block (ctran-starts-block ctran)))))
(t
- (node-ends-block call)
- (delete-continuation-use call)
- (if (eq (continuation-kind cont) :unused)
- (delete-continuation cont)
- (reoptimize-continuation cont))))
-
+ (node-ends-block node)))
+
(unlink-blocks block (first (block-succ block)))
(setf (component-reanalyze (block-component block)) t)
(aver (not (block-succ block)))
(link-blocks block tail)
- (add-continuation-use call (make-continuation))
+ (if ir1-converting-not-optimizing-p
+ (%delete-lvar-use node)
+ (delete-lvar-use node))
t))))
;;; This is called both by IR1 conversion and IR1 optimization when
;;;
;;; We return the leaf referenced (NIL if not a leaf) and the
;;; FUN-INFO assigned.
-;;;
-;;; FIXME: The IR1-CONVERTING-NOT-OPTIMIZING-P argument is what the
-;;; old CMU CL code called IR1-P, without explanation. My (WHN
-;;; 2002-01-09) tentative understanding of it is that we can call this
-;;; operation either in initial IR1 conversion or in later IR1
-;;; optimization, and it tells which is which. But it would be good
-;;; for someone who really understands it to check whether this is
-;;; really right.
(defun recognize-known-call (call ir1-converting-not-optimizing-p)
(declare (type combination call))
- (let* ((ref (continuation-use (basic-combination-fun call)))
+ (let* ((ref (lvar-uses (basic-combination-fun call)))
(leaf (when (ref-p ref) (ref-leaf ref)))
(inlinep (if (defined-fun-p leaf)
(defined-fun-inlinep leaf)
(frob)
(locall-analyze-component *current-component*))))
- (values (ref-leaf (continuation-use (basic-combination-fun call)))
+ (values (ref-leaf (lvar-uses (basic-combination-fun call)))
nil))
(t
(let ((info (info :function :info (leaf-source-name leaf))))
;; issue a full WARNING if the call
;; violates a DECLAIM FTYPE.
:lossage-fun #'compiler-style-warn
- :unwinnage-fun #'compiler-note)
+ :unwinnage-fun #'compiler-notify)
(assert-call-type call type)
(maybe-terminate-block call ir1-converting-not-optimizing-p)
(recognize-known-call call ir1-converting-not-optimizing-p))
(defun propagate-fun-change (call)
(declare (type combination call))
(let ((*compiler-error-context* call)
- (fun-cont (basic-combination-fun call)))
- (setf (continuation-reoptimize fun-cont) nil)
+ (fun-lvar (basic-combination-fun call)))
+ (setf (lvar-reoptimize fun-lvar) nil)
(case (combination-kind call)
(:local
(let ((fun (combination-lambda call)))
(derive-node-type call (tail-set-type (lambda-tail-set fun))))))
(:full
(multiple-value-bind (leaf info)
- (validate-call-type call (continuation-type fun-cont) nil)
+ (validate-call-type call (lvar-type fun-lvar) nil)
(cond ((functional-p leaf)
(convert-call-if-possible
- (continuation-use (basic-combination-fun call))
+ (lvar-uses (basic-combination-fun call))
call))
((not leaf))
((and (leaf-has-source-name-p leaf)
(and info
(ir1-attributep (fun-info-attributes info)
predicate)
- (let ((dest (continuation-dest (node-cont call))))
- (and dest (not (if-p dest)))))))
- ;; FIXME: This SYMBOLP is part of a literal
- ;; translation of a test in the old CMU CL
- ;; source, and it's not quite clear what
- ;; the old source meant. Did it mean "has a
- ;; valid name"? Or did it mean "is an
- ;; ordinary function name, not a SETF
- ;; function"? Either way, the old CMU CL
- ;; code probably didn't deal with SETF
- ;; functions correctly, and neither does
- ;; this new SBCL code, and that should be fixed.
- (when (symbolp (leaf-source-name leaf))
- (let ((dummies (make-gensym-list
- (length (combination-args call)))))
- (transform-call call
- `(lambda ,dummies
- (,(leaf-source-name leaf)
- ,@dummies))
- (leaf-source-name leaf))))))))))
+ (let ((lvar (node-lvar call)))
+ (and lvar (not (if-p (lvar-dest lvar))))))))
+ (let ((name (leaf-source-name leaf))
+ (dummies (make-gensym-list
+ (length (combination-args call)))))
+ (transform-call call
+ `(lambda ,dummies
+ (,@(if (symbolp name)
+ `(,name)
+ `(funcall #',name))
+ ,@dummies))
+ (leaf-source-name leaf)))))))))
(values))
\f
;;;; known function optimization
(policy node (> speed inhibit-warnings))))
(*compiler-error-context* node))
(cond ((or (not constrained)
- (valid-fun-use node type :strict-result t))
+ (valid-fun-use node type))
(multiple-value-bind (severity args)
(catch 'give-up-ir1-transform
(transform-call node
t))))
;;; When we don't like an IR1 transform, we throw the severity/reason
-;;; and args.
+;;; and args.
;;;
;;; GIVE-UP-IR1-TRANSFORM is used to throw out of an IR1 transform,
;;; aborting this attempt to transform the call, but admitting the
;;; possible to do this starting from debug names as well as source
;;; names, but as of sbcl-0.7.1.5, there was no need for this
;;; generality, since source names are always known to our callers.)
-(defun transform-call (node res source-name)
- (declare (type combination node) (list res))
+(defun transform-call (call res source-name)
+ (declare (type combination call) (list res))
(aver (and (legal-fun-name-p source-name)
(not (eql source-name '.anonymous.))))
- (with-ir1-environment-from-node node
+ (node-ends-block call)
+ (with-ir1-environment-from-node call
+ (with-component-last-block (*current-component*
+ (block-next (node-block call)))
(let ((new-fun (ir1-convert-inline-lambda
res
:debug-name (debug-namify "LAMBDA-inlined ~A"
(as-debug-name
source-name
"<unknown function>"))))
- (ref (continuation-use (combination-fun node))))
+ (ref (lvar-use (combination-fun call))))
(change-ref-leaf ref new-fun)
- (setf (combination-kind node) :full)
- (locall-analyze-component *current-component*)))
+ (setf (combination-kind call) :full)
+ (locall-analyze-component *current-component*))))
(values))
;;; Replace a call to a foldable function of constant arguments with
-;;; the result of evaluating the form. We insert the resulting
-;;; constant node after the call, stealing the call's continuation. We
-;;; give the call a continuation with no DEST, which should cause it
-;;; and its arguments to go away. If there is an error during the
+;;; the result of evaluating the form. If there is an error during the
;;; evaluation, we give a warning and leave the call alone, making the
;;; call a :ERROR call.
;;;
;;; If there is more than one value, then we transform the call into a
;;; VALUES form.
(defun constant-fold-call (call)
- (let ((args (mapcar #'continuation-value (combination-args call)))
+ (let ((args (mapcar #'lvar-value (combination-args call)))
(fun-name (combination-fun-source-name call)))
(multiple-value-bind (values win)
(careful-call fun-name
;; when the compiler tries to constant-fold (<=
;; END SIZE).
;;
- ;; So, with or without bug 173, it'd be
+ ;; So, with or without bug 173, it'd be
;; unnecessarily evil to do a full
;; COMPILER-WARNING (and thus return FAILURE-P=T
;; from COMPILE-FILE) for legal code, so we we
;; use a wimpier COMPILE-STYLE-WARNING instead.
#'compiler-style-warn
"constant folding")
- (if (not win)
- (setf (combination-kind call) :error)
- (let ((dummies (make-gensym-list (length args))))
- (transform-call
- call
- `(lambda ,dummies
- (declare (ignore ,@dummies))
- (values ,@(mapcar (lambda (x) `',x) values)))
- fun-name)))))
+ (cond ((not win)
+ (setf (combination-kind call) :error))
+ ((and (proper-list-of-length-p values 1))
+ (with-ir1-environment-from-node call
+ (let* ((lvar (node-lvar call))
+ (prev (node-prev call))
+ (intermediate-ctran (make-ctran)))
+ (%delete-lvar-use call)
+ (setf (ctran-next prev) nil)
+ (setf (node-prev call) nil)
+ (reference-constant prev intermediate-ctran lvar
+ (first values))
+ (link-node-to-previous-ctran call intermediate-ctran)
+ (reoptimize-lvar lvar)
+ (flush-combination call))))
+ (t (let ((dummies (make-gensym-list (length args))))
+ (transform-call
+ call
+ `(lambda ,dummies
+ (declare (ignore ,@dummies))
+ (values ,@(mapcar (lambda (x) `',x) values)))
+ fun-name))))))
(values))
\f
;;;; local call optimization
(when (type/= int var-type)
(setf (leaf-type leaf) int)
(dolist (ref (leaf-refs leaf))
- (derive-node-type ref int))))
+ (derive-node-type ref (make-single-value-type int))
+ ;; KLUDGE: LET var substitution
+ (let* ((lvar (node-lvar ref)))
+ (when (and lvar (combination-p (lvar-dest lvar)))
+ (reoptimize-lvar lvar))))))
(values))))
+;;; Iteration variable: exactly one SETQ of the form:
+;;;
+;;; (let ((var initial))
+;;; ...
+;;; (setq var (+ var step))
+;;; ...)
+(defun maybe-infer-iteration-var-type (var initial-type)
+ (binding* ((sets (lambda-var-sets var) :exit-if-null)
+ (set (first sets))
+ (() (null (rest sets)) :exit-if-null)
+ (set-use (principal-lvar-use (set-value set)))
+ (() (and (combination-p set-use)
+ (fun-info-p (combination-kind set-use))
+ (eq (combination-fun-source-name set-use) '+))
+ :exit-if-null)
+ (+-args (basic-combination-args set-use))
+ (() (and (proper-list-of-length-p +-args 2 2)
+ (let ((first (principal-lvar-use
+ (first +-args))))
+ (and (ref-p first)
+ (eq (ref-leaf first) var))))
+ :exit-if-null)
+ (step-type (lvar-type (second +-args)))
+ (set-type (lvar-type (set-value set))))
+ (when (and (numeric-type-p initial-type)
+ (numeric-type-p step-type)
+ (numeric-type-equal initial-type step-type))
+ (multiple-value-bind (low high)
+ (cond ((csubtypep step-type (specifier-type '(real 0 *)))
+ (values (numeric-type-low initial-type)
+ (when (and (numeric-type-p set-type)
+ (numeric-type-equal set-type initial-type))
+ (numeric-type-high set-type))))
+ ((csubtypep step-type (specifier-type '(real * 0)))
+ (values (when (and (numeric-type-p set-type)
+ (numeric-type-equal set-type initial-type))
+ (numeric-type-low set-type))
+ (numeric-type-high initial-type)))
+ (t
+ (values nil nil)))
+ (modified-numeric-type initial-type
+ :low low
+ :high high
+ :enumerable nil)))))
+(deftransform + ((x y) * * :result result)
+ "check for iteration variable reoptimization"
+ (let ((dest (principal-lvar-end result))
+ (use (principal-lvar-use x)))
+ (when (and (ref-p use)
+ (set-p dest)
+ (eq (ref-leaf use)
+ (set-var dest)))
+ (reoptimize-lvar (set-value dest))))
+ (give-up-ir1-transform))
+
;;; Figure out the type of a LET variable that has sets. We compute
-;;; the union of the initial value Type and the types of all the set
+;;; the union of the INITIAL-TYPE and the types of all the set
;;; values and to a PROPAGATE-TO-REFS with this type.
-(defun propagate-from-sets (var type)
- (collect ((res type type-union))
+(defun propagate-from-sets (var initial-type)
+ (collect ((res initial-type type-union))
(dolist (set (basic-var-sets var))
- (res (continuation-type (set-value set)))
- (setf (node-reoptimize set) nil))
- (propagate-to-refs var (res)))
+ (let ((type (lvar-type (set-value set))))
+ (res type)
+ (when (node-reoptimize set)
+ (derive-node-type set (make-single-value-type type))
+ (setf (node-reoptimize set) nil))))
+ (let ((res (res)))
+ (awhen (maybe-infer-iteration-var-type var initial-type)
+ (setq res it))
+ (propagate-to-refs var res)))
(values))
;;; If a LET variable, find the initial value's type and do
(when (and (lambda-var-p var) (leaf-refs var))
(let ((home (lambda-var-home var)))
(when (eq (functional-kind home) :let)
- (let ((iv (let-var-initial-value var)))
- (setf (continuation-reoptimize iv) nil)
- (propagate-from-sets var (continuation-type iv)))))))
+ (let* ((initial-value (let-var-initial-value var))
+ (initial-type (lvar-type initial-value)))
+ (setf (lvar-reoptimize initial-value) nil)
+ (propagate-from-sets var initial-type))))))
- (derive-node-type node (continuation-type (set-value node)))
+ (derive-node-type node (make-single-value-type
+ (lvar-type (set-value node))))
(values))
;;; Return true if the value of REF will always be the same (and is
(not (eq (defined-fun-inlinep leaf) :notinline)))
(global-var
(case (global-var-kind leaf)
- (:global-function t))))))
+ (:global-function
+ (let ((name (leaf-source-name leaf)))
+ (or #-sb-xc-host
+ (eq (symbol-package (fun-name-block-name name))
+ *cl-package*)
+ (info :function :info name)))))))))
;;; If we have a non-set LET var with a single use, then (if possible)
-;;; replace the variable reference's CONT with the arg continuation.
-;;; This is inhibited when:
-;;; -- CONT has other uses, or
-;;; -- CONT receives multiple values, or
-;;; -- the reference is in a different environment from the variable, or
-;;; -- either continuation has a funky TYPE-CHECK annotation.
-;;; -- the continuations have incompatible assertions, so the new asserted type
-;;; would be NIL.
-;;; -- the var's DEST has a different policy than the ARG's (think safety).
+;;; replace the variable reference's LVAR with the arg lvar.
;;;
;;; We change the REF to be a reference to NIL with unused value, and
;;; let it be flushed as dead code. A side effect of this substitution
;;; is to delete the variable.
-(defun substitute-single-use-continuation (arg var)
- (declare (type continuation arg) (type lambda-var var))
- (let* ((ref (first (leaf-refs var)))
- (cont (node-cont ref))
- (cont-atype (continuation-asserted-type cont))
- (dest (continuation-dest cont)))
- (when (and (eq (continuation-use cont) ref)
- dest
- (not (typep dest '(or creturn exit mv-combination)))
- (eq (node-home-lambda ref)
- (lambda-home (lambda-var-home var)))
- (member (continuation-type-check arg) '(t nil))
- (member (continuation-type-check cont) '(t nil))
- (not (eq (values-type-intersection
- cont-atype
- (continuation-asserted-type arg))
- *empty-type*))
- (eq (lexenv-policy (node-lexenv dest))
- (lexenv-policy (node-lexenv (continuation-dest arg)))))
- (aver (member (continuation-kind arg)
- '(:block-start :deleted-block-start :inside-block)))
- (assert-continuation-type arg cont-atype)
+(defun substitute-single-use-lvar (arg var)
+ (declare (type lvar arg) (type lambda-var var))
+ (binding* ((ref (first (leaf-refs var)))
+ (lvar (node-lvar ref) :exit-if-null)
+ (dest (lvar-dest lvar)))
+ (when (and
+ ;; Think about (LET ((A ...)) (IF ... A ...)): two
+ ;; LVAR-USEs should not be met on one path.
+ (eq (lvar-uses lvar) ref)
+ (typecase dest
+ ;; we should not change lifetime of unknown values lvars
+ (cast
+ (and (type-single-value-p (lvar-derived-type arg))
+ (multiple-value-bind (pdest pprev)
+ (principal-lvar-end lvar)
+ (declare (ignore pdest))
+ (lvar-single-value-p pprev))))
+ (mv-combination
+ (or (eq (basic-combination-fun dest) lvar)
+ (and (eq (basic-combination-kind dest) :local)
+ (type-single-value-p (lvar-derived-type arg)))))
+ ((or creturn exit)
+ ;; While CRETURN and EXIT nodes may be known-values,
+ ;; they have their own complications, such as
+ ;; substitution into CRETURN may create new tail calls.
+ nil)
+ (t
+ (aver (lvar-single-value-p lvar))
+ t))
+ (eq (node-home-lambda ref)
+ (lambda-home (lambda-var-home var))))
(setf (node-derived-type ref) *wild-type*)
+ (substitute-lvar-uses lvar arg)
+ (delete-lvar-use ref)
(change-ref-leaf ref (find-constant nil))
- (substitute-continuation arg cont)
- (reoptimize-continuation arg)
+ (delete-ref ref)
+ (unlink-node ref)
+ (reoptimize-lvar lvar)
t)))
;;; Delete a LET, removing the call and bind nodes, and warning about
;;; any unreferenced variables. Note that FLUSH-DEAD-CODE will come
;;; along right away and delete the REF and then the lambda, since we
-;;; flush the FUN continuation.
+;;; flush the FUN lvar.
(defun delete-let (clambda)
(declare (type clambda clambda))
(aver (functional-letlike-p clambda))
;;; derived-type information for the arg to all the VAR's refs.
;;;
;;; Substitution is inhibited when the arg leaf's derived type isn't a
-;;; subtype of the argument's asserted type. This prevents type
-;;; checking from being defeated, and also ensures that the best
-;;; representation for the variable can be used.
+;;; subtype of the argument's leaf type. This prevents type checking
+;;; from being defeated, and also ensures that the best representation
+;;; for the variable can be used.
;;;
;;; Substitution of individual references is inhibited if the
;;; reference is in a different component from the home. This can only
;;; If all of the variables are deleted (have no references) when we
;;; are done, then we delete the LET.
;;;
-;;; Note that we are responsible for clearing the
-;;; CONTINUATION-REOPTIMIZE flags.
+;;; Note that we are responsible for clearing the LVAR-REOPTIMIZE
+;;; flags.
(defun propagate-let-args (call fun)
(declare (type combination call) (type clambda fun))
(loop for arg in (combination-args call)
and var in (lambda-vars fun) do
- (when (and arg (continuation-reoptimize arg))
- (setf (continuation-reoptimize arg) nil)
+ (when (and arg (lvar-reoptimize arg))
+ (setf (lvar-reoptimize arg) nil)
(cond
- ((lambda-var-sets var)
- (propagate-from-sets var (continuation-type arg)))
- ((let ((use (continuation-use arg)))
- (when (ref-p use)
- (let ((leaf (ref-leaf use)))
- (when (and (constant-reference-p use)
- (values-subtypep (leaf-type leaf)
- (continuation-asserted-type arg)))
- (propagate-to-refs var (continuation-type arg))
- (let ((use-component (node-component use)))
- (substitute-leaf-if
- (lambda (ref)
- (cond ((eq (node-component ref) use-component)
- t)
- (t
- (aver (lambda-toplevelish-p (lambda-home fun)))
- nil)))
- leaf var))
- t)))))
- ((and (null (rest (leaf-refs var)))
- (substitute-single-use-continuation arg var)))
- (t
- (propagate-to-refs var (continuation-type arg))))))
-
- (when (every #'null (combination-args call))
+ ((lambda-var-sets var)
+ (propagate-from-sets var (lvar-type arg)))
+ ((let ((use (lvar-uses arg)))
+ (when (ref-p use)
+ (let ((leaf (ref-leaf use)))
+ (when (and (constant-reference-p use)
+ (csubtypep (leaf-type leaf)
+ ;; (NODE-DERIVED-TYPE USE) would
+ ;; be better -- APD, 2003-05-15
+ (leaf-type var)))
+ (propagate-to-refs var (lvar-type arg))
+ (let ((use-component (node-component use)))
+ (prog1 (substitute-leaf-if
+ (lambda (ref)
+ (cond ((eq (node-component ref) use-component)
+ t)
+ (t
+ (aver (lambda-toplevelish-p (lambda-home fun)))
+ nil)))
+ leaf var)))
+ t)))))
+ ((and (null (rest (leaf-refs var)))
+ (substitute-single-use-lvar arg var)))
+ (t
+ (propagate-to-refs var (lvar-type arg))))))
+
+ (when (every #'not (combination-args call))
(delete-let fun))
(values))
;;; If the function has an XEP, then we don't do anything, since we
;;; won't discover anything.
;;;
-;;; We can clear the Continuation-Reoptimize flags for arguments in
-;;; all calls corresponding to changed arguments in Call, since the
-;;; only use in IR1 optimization of the Reoptimize flag for local call
-;;; args is right here.
+;;; We can clear the LVAR-REOPTIMIZE flags for arguments in all calls
+;;; corresponding to changed arguments in CALL, since the only use in
+;;; IR1 optimization of the REOPTIMIZE flag for local call args is
+;;; right here.
(defun propagate-local-call-args (call fun)
(declare (type combination call) (type clambda fun))
(let* ((vars (lambda-vars fun))
(union (mapcar (lambda (arg var)
(when (and arg
- (continuation-reoptimize arg)
+ (lvar-reoptimize arg)
(null (basic-var-sets var)))
- (continuation-type arg)))
+ (lvar-type arg)))
(basic-combination-args call)
vars))
- (this-ref (continuation-use (basic-combination-fun call))))
+ (this-ref (lvar-use (basic-combination-fun call))))
(dolist (arg (basic-combination-args call))
(when arg
- (setf (continuation-reoptimize arg) nil)))
+ (setf (lvar-reoptimize arg) nil)))
(dolist (ref (leaf-refs fun))
- (let ((dest (continuation-dest (node-cont ref))))
+ (let ((dest (node-dest ref)))
(unless (or (eq ref this-ref) (not dest))
(setq union
(mapcar (lambda (this-arg old)
(when old
- (setf (continuation-reoptimize this-arg) nil)
- (type-union (continuation-type this-arg) old)))
+ (setf (lvar-reoptimize this-arg) nil)
+ (type-union (lvar-type this-arg) old)))
(basic-combination-args dest)
union)))))
- (mapc (lambda (var type)
- (when type
- (propagate-to-refs var type)))
- vars union)))
+ (loop for var in vars
+ and type in union
+ when type do (propagate-to-refs var type))))
(values))
\f
(defun ir1-optimize-mv-combination (node)
(ecase (basic-combination-kind node)
(:local
- (let ((fun-cont (basic-combination-fun node)))
- (when (continuation-reoptimize fun-cont)
- (setf (continuation-reoptimize fun-cont) nil)
+ (let ((fun-lvar (basic-combination-fun node)))
+ (when (lvar-reoptimize fun-lvar)
+ (setf (lvar-reoptimize fun-lvar) nil)
(maybe-let-convert (combination-lambda node))))
- (setf (continuation-reoptimize (first (basic-combination-args node))) nil)
+ (setf (lvar-reoptimize (first (basic-combination-args node))) nil)
(when (eq (functional-kind (combination-lambda node)) :mv-let)
(unless (convert-mv-bind-to-let node)
(ir1-optimize-mv-bind node))))
(:full
(let* ((fun (basic-combination-fun node))
- (fun-changed (continuation-reoptimize fun))
+ (fun-changed (lvar-reoptimize fun))
(args (basic-combination-args node)))
(when fun-changed
- (setf (continuation-reoptimize fun) nil)
- (let ((type (continuation-type fun)))
+ (setf (lvar-reoptimize fun) nil)
+ (let ((type (lvar-type fun)))
(when (fun-type-p type)
(derive-node-type node (fun-type-returns type))))
- (maybe-terminate-block node nil)
- (let ((use (continuation-use fun)))
+ (maybe-terminate-block node nil)
+ (let ((use (lvar-uses fun)))
(when (and (ref-p use) (functional-p (ref-leaf use)))
(convert-call-if-possible use node)
(when (eq (basic-combination-kind node) :local)
(maybe-let-convert (ref-leaf use))))))
(unless (or (eq (basic-combination-kind node) :local)
- (eq (continuation-fun-name fun) '%throw))
+ (eq (lvar-fun-name fun) '%throw))
(ir1-optimize-mv-call node))
(dolist (arg args)
- (setf (continuation-reoptimize arg) nil))))
+ (setf (lvar-reoptimize arg) nil))))
(:error))
(values))
-;;; Propagate derived type info from the values continuation to the
-;;; vars.
+;;; Propagate derived type info from the values lvar to the vars.
(defun ir1-optimize-mv-bind (node)
(declare (type mv-combination node))
- (let ((arg (first (basic-combination-args node)))
- (vars (lambda-vars (combination-lambda node))))
- (multiple-value-bind (types nvals)
- (values-types (continuation-derived-type arg))
- (unless (eq nvals :unknown)
- (mapc (lambda (var type)
- (if (basic-var-sets var)
- (propagate-from-sets var type)
- (propagate-to-refs var type)))
- vars
- (append types
- (make-list (max (- (length vars) nvals) 0)
- :initial-element (specifier-type 'null))))))
- (setf (continuation-reoptimize arg) nil))
+ (let* ((arg (first (basic-combination-args node)))
+ (vars (lambda-vars (combination-lambda node)))
+ (n-vars (length vars))
+ (types (values-type-in (lvar-derived-type arg)
+ n-vars)))
+ (loop for var in vars
+ and type in types
+ do (if (basic-var-sets var)
+ (propagate-from-sets var type)
+ (propagate-to-refs var type)))
+ (setf (lvar-reoptimize arg) nil))
(values))
;;; If possible, convert a general MV call to an MV-BIND. We can do
(defun ir1-optimize-mv-call (node)
(let ((fun (basic-combination-fun node))
(*compiler-error-context* node)
- (ref (continuation-use (basic-combination-fun node)))
+ (ref (lvar-uses (basic-combination-fun node)))
(args (basic-combination-args node)))
(unless (and (ref-p ref) (constant-reference-p ref)
- args (null (rest args)))
+ (singleton-p args))
(return-from ir1-optimize-mv-call))
(multiple-value-bind (min max)
- (fun-type-nargs (continuation-type fun))
+ (fun-type-nargs (lvar-type fun))
(let ((total-nvals
(multiple-value-bind (types nvals)
- (values-types (continuation-derived-type (first args)))
+ (values-types (lvar-derived-type (first args)))
(declare (ignore types))
(if (eq nvals :unknown) nil nvals))))
(return-from ir1-optimize-mv-call)))
(let ((count (cond (total-nvals)
- ((and (policy node (zerop safety))
+ ((and (policy node (zerop verify-arg-count))
(eql min max))
min)
(t nil))))
;;; What we actually do is convert the VALUES combination into a
;;; normal LET combination calling the original :MV-LET lambda. If
;;; there are extra args to VALUES, discard the corresponding
-;;; continuations. If there are insufficient args, insert references
-;;; to NIL.
+;;; lvars. If there are insufficient args, insert references to NIL.
(defun convert-mv-bind-to-let (call)
(declare (type mv-combination call))
(let* ((arg (first (basic-combination-args call)))
- (use (continuation-use arg)))
+ (use (lvar-uses arg)))
(when (and (combination-p use)
- (eq (continuation-fun-name (combination-fun use))
+ (eq (lvar-fun-name (combination-fun use))
'values))
(let* ((fun (combination-lambda call))
(vars (lambda-vars fun))
(with-ir1-environment-from-node use
(let ((node-prev (node-prev use)))
(setf (node-prev use) nil)
- (setf (continuation-next node-prev) nil)
+ (setf (ctran-next node-prev) nil)
(collect ((res vals))
- (loop as cont = (make-continuation use)
- and prev = node-prev then cont
- repeat (- nvars nvals)
- do (reference-constant prev cont nil)
- (res cont))
- (setq vals (res)))
- (link-node-to-previous-continuation use
- (car (last vals)))))))
+ (loop for count below (- nvars nvals)
+ for prev = node-prev then ctran
+ for ctran = (make-ctran)
+ and lvar = (make-lvar use)
+ do (reference-constant prev ctran lvar nil)
+ (res lvar)
+ finally (link-node-to-previous-ctran
+ use ctran))
+ (setq vals (res)))))))
(setf (combination-args use) vals)
(flush-dest (combination-fun use))
- (let ((fun-cont (basic-combination-fun call)))
- (setf (continuation-dest fun-cont) use)
- (setf (combination-fun use) fun-cont))
+ (let ((fun-lvar (basic-combination-fun call)))
+ (setf (lvar-dest fun-lvar) use)
+ (setf (combination-fun use) fun-lvar)
+ (flush-lvar-externally-checkable-type fun-lvar))
(setf (combination-kind use) :local)
(setf (functional-kind fun) :let)
(flush-dest (first (basic-combination-args call)))
(unlink-node call)
(when vals
- (reoptimize-continuation (first vals)))
- (propagate-to-args use fun))
+ (reoptimize-lvar (first vals)))
+ (propagate-to-args use fun)
+ (reoptimize-call use))
t)))
;;; If we see:
;;;
;;; In implementation, this is somewhat similar to
;;; CONVERT-MV-BIND-TO-LET. We grab the args of LIST and make them
-;;; args of the VALUES-LIST call, flushing the old argument
-;;; continuation (allowing the LIST to be flushed.)
+;;; args of the VALUES-LIST call, flushing the old argument lvar
+;;; (allowing the LIST to be flushed.)
+;;;
+;;; FIXME: Thus we lose possible type assertions on (LIST ...).
(defoptimizer (values-list optimizer) ((list) node)
- (let ((use (continuation-use list)))
+ (let ((use (lvar-uses list)))
(when (and (combination-p use)
- (eq (continuation-fun-name (combination-fun use))
+ (eq (lvar-fun-name (combination-fun use))
'list))
- (change-ref-leaf (continuation-use (combination-fun node))
+
+ ;; FIXME: VALUES might not satisfy an assertion on NODE-LVAR.
+ (change-ref-leaf (lvar-uses (combination-fun node))
(find-free-fun 'values "in a strange place"))
(setf (combination-kind node) :full)
(let ((args (combination-args use)))
(dolist (arg args)
- (setf (continuation-dest arg) node))
+ (setf (lvar-dest arg) node)
+ (flush-lvar-externally-checkable-type arg))
(setf (combination-args use) nil)
(flush-dest list)
(setf (combination-args node) args))
;;; to a PROG1. This allows the computation of the additional values
;;; to become dead code.
(deftransform values ((&rest vals) * * :node node)
- (when (typep (continuation-dest (node-cont node))
- '(or creturn exit mv-combination))
+ (unless (lvar-single-value-p (node-lvar node))
(give-up-ir1-transform))
(setf (node-derived-type node) *wild-type*)
+ (principal-lvar-single-valuify (node-lvar node))
(if vals
(let ((dummies (make-gensym-list (length (cdr vals)))))
`(lambda (val ,@dummies)
(declare (ignore ,@dummies))
val))
nil))
+
+;;; TODO:
+;;; - CAST chains;
+(defun ir1-optimize-cast (cast &optional do-not-optimize)
+ (declare (type cast cast))
+ (let* ((value (cast-value cast))
+ (value-type (lvar-derived-type value))
+ (atype (cast-asserted-type cast))
+ (int (values-type-intersection value-type atype)))
+ (derive-node-type cast int)
+ (when (eq int *empty-type*)
+ (unless (eq value-type *empty-type*)
+
+ ;; FIXME: Do it in one step.
+ (filter-lvar
+ value
+ `(multiple-value-call #'list 'dummy))
+ (filter-lvar
+ (cast-value cast)
+ ;; FIXME: Derived type.
+ `(%compile-time-type-error 'dummy
+ ',(type-specifier atype)
+ ',(type-specifier value-type)))
+ ;; KLUDGE: FILTER-LVAR does not work for non-returning
+ ;; functions, so we declare the return type of
+ ;; %COMPILE-TIME-TYPE-ERROR to be * and derive the real type
+ ;; here.
+ (setq value (cast-value cast))
+ (derive-node-type (lvar-uses value) *empty-type*)
+ (maybe-terminate-block (lvar-uses value) nil)
+ ;; FIXME: Is it necessary?
+ (aver (null (block-pred (node-block cast))))
+ (setf (block-delete-p (node-block cast)) t)
+ (return-from ir1-optimize-cast)))
+ (when (eq (node-derived-type cast) *empty-type*)
+ (maybe-terminate-block cast nil))
+
+ (when (not do-not-optimize)
+ (let ((lvar (node-lvar cast)))
+ (when (values-subtypep value-type (cast-asserted-type cast))
+ (delete-filter cast lvar value)
+ (when lvar
+ (reoptimize-lvar lvar)
+ (when (lvar-single-value-p lvar)
+ (note-single-valuified-lvar lvar)))
+ (return-from ir1-optimize-cast t))
+
+ (when (and (listp (lvar-uses value))
+ lvar)
+ ;; Pathwise removing of CAST
+ (let ((ctran (node-next cast))
+ (dest (lvar-dest lvar))
+ next-block)
+ (collect ((merges))
+ (do-uses (use value)
+ (when (and (values-subtypep (node-derived-type use) atype)
+ (immediately-used-p value use))
+ (unless next-block
+ (when ctran (ensure-block-start ctran))
+ (setq next-block (first (block-succ (node-block cast)))))
+ (%delete-lvar-use use)
+ (add-lvar-use use lvar)
+ (unlink-blocks (node-block use) (node-block cast))
+ (link-blocks (node-block use) next-block)
+ (when (and (return-p dest)
+ (basic-combination-p use)
+ (eq (basic-combination-kind use) :local))
+ (merges use))))
+ (dolist (use (merges))
+ (merge-tail-sets use)))))))
+
+ (when (and (cast-%type-check cast)
+ (values-subtypep value-type
+ (cast-type-to-check cast)))
+ (setf (cast-%type-check cast) nil)))
+
+ (unless do-not-optimize
+ (setf (node-reoptimize cast) nil)))