\f
;;;; interface for obtaining results of constant folding
-;;; Return true if the sole use of Cont is a reference to a constant leaf.
-(declaim (ftype (function (continuation) boolean) constant-continuation-p))
-(defun constant-continuation-p (cont)
- (let ((use (continuation-use cont)))
- (and (ref-p use)
- (constant-p (ref-leaf use)))))
+;;; Return true for a CONTINUATION 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.
(eq int *empty-type*)
(not (eq rtype *empty-type*)))
(let ((*compiler-error-context* node))
- (compiler-warning
+ (compiler-warn
"New inferred type ~S conflicts with old type:~
- ~% ~S~%*** Bug?"
+ ~% ~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))))))
(values))
-;;; 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.
+;;; 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)))
(reoptimize-continuation cont)))))
(values))
-;;; Assert that Call is to a function of the specified Type. It is
+;;; 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 function-type type))
- (derive-node-type call (function-type-returns type))
+ (declare (type combination call) (type fun-type type))
+ (derive-node-type call (fun-type-returns type))
(let ((args (combination-args call)))
- (dolist (req (function-type-required type))
+ (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 (function-type-optional type))
+ (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 (function-type-rest type)))
+ (let ((rest (fun-type-rest type)))
(when rest
(dolist (arg args)
(assert-continuation-type arg rest))))
- (dolist (key (function-type-keywords type))
+ (dolist (key (fun-type-keywords type))
(let ((name (key-info-name key)))
(do ((arg args (cddr arg)))
((null arg))
\f
;;;; IR1-OPTIMIZE
-;;; Do one forward pass over Component, deleting unreachable blocks
+;;; Do one forward pass over COMPONENT, deleting unreachable blocks
;;; and doing IR1 optimizations. We can ignore all blocks that don't
-;;; have the Reoptimize flag set. If Component-Reoptimize is true when
+;;; have the REOPTIMIZE flag set. If COMPONENT-REOPTIMIZE is true when
;;; we are done, then another iteration would be beneficial.
;;;
;;; We delete blocks when there is either no predecessor or the block
;;; 1. The successor has more than one predecessor.
;;; 2. The last node's CONT is also used somewhere else.
;;; 3. The successor is the current block (infinite loop).
-;;; 4. The next block has a different cleanup, and thus we may want to
-;;; insert cleanup code between the two blocks at some point.
-;;; 5. The next block has a different home lambda, and thus the control
-;;; transfer is a non-local exit.
+;;; 4. The next block has a different cleanup, and thus we may want
+;;; to insert cleanup code between the two blocks at some point.
+;;; 5. The next block has a different home lambda, and thus the
+;;; control transfer is a non-local exit.
;;;
;;; If we succeed, we return true, otherwise false.
;;;
;; 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
+ ;; 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)
(defun ir1-optimize-return (node)
(declare (type creturn node))
(let* ((tails (lambda-tail-set (return-lambda node)))
- (funs (tail-set-functions tails)))
+ (funs (tail-set-funs tails)))
(collect ((res *empty-type* values-type-union))
(dolist (fun funs)
(let ((return (lambda-return fun)))
(when (type/= (res) (tail-set-type tails))
(setf (tail-set-type tails) (res))
- (dolist (fun (tail-set-functions tails))
+ (dolist (fun (tail-set-funs tails))
(dolist (ref (leaf-refs fun))
(reoptimize-continuation (node-cont ref)))))))
(if (continuation-value test)
(if-alternative node)
(if-consequent node)))
- ((not (types-intersect type (specifier-type 'null)))
+ ((not (types-equal-or-intersect type (specifier-type 'null)))
(if-alternative node))
((type= type (specifier-type 'null))
(if-consequent node)))))
(flush-dest test)
(when (rest (block-succ block))
(unlink-blocks block victim))
- (setf (component-reanalyze (block-component (node-block node))) t)
+ (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
-;;; Use. The test must have >1 use, and must be immediately used by
-;;; Use. Node must be the only node in its block (implying that
+;;; Create a new copy of an IF node that tests the value of the node
+;;; USE. The test must have >1 use, and must be immediately used by
+;;; USE. NODE must be the only node in its block (implying that
;;; block-start = if-test).
;;;
;;; This optimization has an effect semantically similar to the
;;; become unreachable, resulting in a spurious note.
(defun convert-if-if (use node)
(declare (type node use) (type cif node))
- (with-ir1-environment node
+ (with-ir1-environment-from-node node
(let* ((block (node-block node))
(test (if-test node))
(cblock (if-consequent node))
:consequent cblock
:alternative ablock))
(new-block (continuation-starts-block new-cont)))
- (prev-link new-node 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)
(setf (block-last new-block) new-node)
;;; This function attempts to delete an exit node, returning true if
;;; it deletes the block as a consequence:
-;;; -- If the exit is degenerate (has no Entry), then we don't do 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, 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.
-;;; -- If there is no value (as in a GO), then we skip the value semantics.
+;;; -- If the exit is degenerate (has no Entry), then we don't do
+;;; 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,
+;;; 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.
+;;; -- If there is no value (as in a GO), then we skip the value
+;;; semantics.
;;;
;;; This function is also called by environment analysis, since it
;;; wants all exits to be optimized even if normal optimization was
;; cross-compiler doesn't know how to evaluate it.
#+sb-xc-host
(let* ((ref (continuation-use (combination-fun node)))
- (fun (leaf-name (ref-leaf ref))))
- (fboundp fun)))
+ (fun-name (leaf-source-name (ref-leaf ref))))
+ (fboundp fun-name)))
(constant-fold-call node)
(return-from ir1-optimize-combination)))
#!+sb-show
(when *show-transforms-p*
(let* ((cont (basic-combination-fun node))
- (fname (continuation-function-name cont t)))
+ (fname (continuation-fun-name cont 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
+;;; 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.
;;;
-;;; Except when called during IR1, we delete the continuation if it
-;;; has no other uses. (If it does have other uses, we reoptimize.)
+;;; 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.)
;;;
;;; Termination on the basis of a continuation type assertion 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-p)
+(defun maybe-terminate-block (call ir1-converting-not-optimizing-p)
(declare (type basic-combination call))
(let* ((block (node-block call))
(cont (node-cont call))
(tail (component-tail (block-component block)))
(succ (first (block-succ block))))
(unless (or (and (eq call (block-last block)) (eq succ tail))
- (block-delete-p block)
- *converting-for-interpreter*)
+ (block-delete-p block))
(when (or (and (eq (continuation-asserted-type cont) *empty-type*)
- (not (or ir1-p (eq (continuation-kind cont) :deleted))))
+ (not (or ir1-converting-not-optimizing-p
+ (eq (continuation-kind cont) :deleted))))
(eq (node-derived-type call) *empty-type*))
- (cond (ir1-p
+ (cond (ir1-converting-not-optimizing-p
(delete-continuation-use call)
(cond
((block-last block)
;;; This is called both by IR1 conversion and IR1 optimization when
;;; they have verified the type signature for the call, and are
;;; wondering if something should be done to special-case the call. If
-;;; Call is a call to a global function, then see whether it defined
+;;; CALL is a call to a global function, then see whether it defined
;;; or known:
-;;; -- If a DEFINED-FUNCTION should be inline expanded, then convert the
-;;; expansion and change the call to call it. Expansion is enabled if
-;;; :INLINE or if space=0. If the FUNCTIONAL slot is true, we never expand,
-;;; since this function has already been converted. Local call analysis
-;;; will duplicate the definition if necessary. We claim that the parent
-;;; form is LABELS for context declarations, since we don't want it to be
-;;; considered a real global function.
-;;; -- In addition to a direct check for the function name in the table, we
-;;; also must check for slot accessors. If the function is a slot accessor,
-;;; then we set the combination kind to the function info of %Slot-Setter or
-;;; %Slot-Accessor, as appropriate.
-;;; -- If it is a known function, mark it as such by setting the Kind.
+;;; -- If a DEFINED-FUN should be inline expanded, then convert
+;;; the expansion and change the call to call it. Expansion is
+;;; enabled if :INLINE or if SPACE=0. If the FUNCTIONAL slot is
+;;; true, we never expand, since this function has already been
+;;; converted. Local call analysis will duplicate the definition
+;;; if necessary. We claim that the parent form is LABELS for
+;;; context declarations, since we don't want it to be considered
+;;; a real global function.
+;;; -- In addition to a direct check for the function name in the
+;;; table, we also must check for slot accessors. If the function
+;;; is a slot accessor, then we set the combination kind to the
+;;; function info of %SLOT-SETTER or %SLOT-ACCESSOR, as
+;;; appropriate.
+;;; -- If it is a known function, mark it as such by setting the KIND.
;;;
;;; We return the leaf referenced (NIL if not a leaf) and the
-;;; function-info assigned.
-(defun recognize-known-call (call ir1-p)
+;;; FUNCTION-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)))
(leaf (when (ref-p ref) (ref-leaf ref)))
- (inlinep (if (and (defined-function-p leaf)
- (not (byte-compiling)))
- (defined-function-inlinep leaf)
+ (inlinep (if (defined-fun-p leaf)
+ (defined-fun-inlinep leaf)
:no-chance)))
(cond
((eq inlinep :notinline) (values nil nil))
(:inline t)
(:no-chance nil)
((nil :maybe-inline) (policy call (zerop space))))
- (defined-function-inline-expansion leaf)
- (let ((fun (defined-function-functional leaf)))
+ (defined-fun-p leaf)
+ (defined-fun-inline-expansion leaf)
+ (let ((fun (defined-fun-functional leaf)))
(or (not fun)
(and (eq inlinep :inline) (functional-kind fun))))
(inline-expansion-ok call))
- (flet ((frob ()
+ (flet (;; FIXME: Is this what the old CMU CL internal documentation
+ ;; called semi-inlining? A more descriptive name would
+ ;; be nice. -- WHN 2002-01-07
+ (frob ()
(let ((res (ir1-convert-lambda-for-defun
- (defined-function-inline-expansion leaf)
+ (defined-fun-inline-expansion leaf)
leaf t
#'ir1-convert-inline-lambda)))
- (setf (defined-function-functional leaf) res)
+ (setf (defined-fun-functional leaf) res)
(change-ref-leaf ref res))))
- (if ir1-p
+ (if ir1-converting-not-optimizing-p
(frob)
- (with-ir1-environment call
+ (with-ir1-environment-from-node call
(frob)
- (local-call-analyze *current-component*))))
+ (locall-analyze-component *current-component*))))
(values (ref-leaf (continuation-use (basic-combination-fun call)))
nil))
(t
- (let* ((name (leaf-name leaf))
+ (let* ((name (leaf-source-name leaf))
(info (info :function :info
(if (slot-accessor-p leaf)
- (if (consp name)
- '%slot-setter
- '%slot-accessor)
- name))))
+ (if (consp source-name) ; i.e. if SETF function
+ '%slot-setter
+ '%slot-accessor)
+ name))))
(if info
(values leaf (setf (basic-combination-kind call) info))
(values leaf nil)))))))
;;; syntax check, arg/result type processing, but still call
;;; RECOGNIZE-KNOWN-CALL, since the call might be to a known lambda,
;;; and that checking is done by local call analysis.
-(defun validate-call-type (call type ir1-p)
+(defun validate-call-type (call type ir1-converting-not-optimizing-p)
(declare (type combination call) (type ctype type))
- (cond ((not (function-type-p type))
+ (cond ((not (fun-type-p type))
(aver (multiple-value-bind (val win)
(csubtypep type (specifier-type 'function))
(or val (not win))))
- (recognize-known-call call ir1-p))
+ (recognize-known-call call ir1-converting-not-optimizing-p))
((valid-function-use call type
:argument-test #'always-subtypep
:result-test #'always-subtypep
;; FIXME: Actually, I think we could
;; issue a full WARNING if the call
;; violates a DECLAIM FTYPE.
- :error-function #'compiler-style-warning
- :warning-function #'compiler-note)
+ :lossage-fun #'compiler-style-warn
+ :unwinnage-fun #'compiler-note)
(assert-call-type call type)
- (maybe-terminate-block call ir1-p)
- (recognize-known-call call ir1-p))
+ (maybe-terminate-block call ir1-converting-not-optimizing-p)
+ (recognize-known-call call ir1-converting-not-optimizing-p))
(t
(setf (combination-kind call) :error)
(values nil nil))))
;;; This is called by IR1-OPTIMIZE when the function for a call has
-;;; changed. If the call is local, we try to let-convert it, and
+;;; changed. If the call is local, we try to LET-convert it, and
;;; derive the result type. If it is a :FULL call, we validate it
;;; against the type, which recognizes known calls, does inline
;;; expansion, etc. If a call to a predicate in a non-conditional
(continuation-use (basic-combination-fun call))
call))
((not leaf))
- ((or (info :function :source-transform (leaf-name leaf))
+ ((or (info :function :source-transform (leaf-source-name leaf))
(and info
(ir1-attributep (function-info-attributes info)
predicate)
(let ((dest (continuation-dest (node-cont call))))
(and dest (not (if-p dest))))))
- (let ((name (leaf-name leaf)))
- (when (symbolp name)
- (let ((dums (make-gensym-list (length
- (combination-args call)))))
- (transform-call call
- `(lambda ,dums
- (,name ,@dums))))))))))))
+ (when (and (leaf-has-source-name-p leaf)
+ ;; 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.
+ (symbolp (leaf-source-name leaf)))
+ (let ((dummies (make-gensym-list (length
+ (combination-args call)))))
+ (transform-call call
+ `(lambda ,dummies
+ (,(leaf-source-name leaf)
+ ,@dummies)))))))))))
(values))
\f
;;;; known function optimization
-;;; Add a failed optimization note to FAILED-OPTIMZATIONS for Node,
-;;; Fun and Args. If there is already a note for Node and Transform,
+;;; Add a failed optimization note to FAILED-OPTIMZATIONS for NODE,
+;;; FUN and ARGS. If there is already a note for NODE and TRANSFORM,
;;; replace it, otherwise add a new one.
(defun record-optimization-failure (node transform args)
(declare (type combination node) (type transform transform)
- (type (or function-type list) args))
+ (type (or fun-type list) args))
(let* ((table (component-failed-optimizations *component-being-compiled*))
(found (assoc transform (gethash node table))))
(if found
(declare (type combination node) (type transform transform))
(let* ((type (transform-type transform))
(fun (transform-function transform))
- (constrained (function-type-p type))
+ (constrained (fun-type-p type))
(table (component-failed-optimizations *component-being-compiled*))
(flame (if (transform-important transform)
(policy node (>= speed inhibit-warnings))
(policy node (> speed inhibit-warnings))))
(*compiler-error-context* node))
(cond ((not (member (transform-when transform)
- (if *byte-compiling*
- '(:byte :both)
- '(:native :both))))
+ '(:native :both)))
;; FIXME: Make sure that there's a transform for
;; (MEMBER SYMBOL ..) into MEMQ.
;; FIXME: Note that when/if I make SHARE operation to shared
;; '(:BOTH) tail sublists.
(let ((when (transform-when transform)))
(not (or (eq when :both)
- (eq when (if *byte-compiling* :byte :native)))))
+ (eq when :native))))
t)
((or (not constrained)
(valid-function-use node type :strict-result t))
(:aborted
(setf (combination-kind node) :error)
(when args
- (apply #'compiler-warning args))
+ (apply #'compiler-warn args))
(remhash node table)
nil)
(:failure
(record-optimization-failure node transform args))
(setf (gethash node table)
(remove transform (gethash node table) :key #'car)))
- t))))
+ t)
+ (:delayed
+ (remhash node table)
+ nil))))
((and flame
(valid-function-use node
type
- :argument-test #'types-intersect
- :result-test #'values-types-intersect))
+ :argument-test #'types-equal-or-intersect
+ :result-test
+ #'values-types-equal-or-intersect))
(record-optimization-failure node transform type)
t)
(t
t))))
-;;; Just throw the severity and args...
+;;; When we don't like an IR1 transform, we throw the severity/reason
+;;; 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
+;;; possibility that this or some other transform will later succeed.
+;;; If arguments are supplied, they are format arguments for an
+;;; efficiency note.
+;;;
+;;; ABORT-IR1-TRANSFORM is used to throw out of an IR1 transform and
+;;; force a normal call to the function at run time. No further
+;;; optimizations will be attempted.
+;;;
+;;; DELAY-IR1-TRANSFORM is used to throw out of an IR1 transform, and
+;;; delay the transform on the node until later. REASONS specifies
+;;; when the transform will be later retried. The :OPTIMIZE reason
+;;; causes the transform to be delayed until after the current IR1
+;;; optimization pass. The :CONSTRAINT reason causes the transform to
+;;; be delayed until after constraint propagation.
+;;;
+;;; FIXME: Now (0.6.11.44) that there are 4 variants of this (GIVE-UP,
+;;; ABORT, DELAY/:OPTIMIZE, DELAY/:CONSTRAINT) and we're starting to
+;;; do CASE operations on the various REASON values, it might be a
+;;; good idea to go OO, representing the reasons by objects, using
+;;; CLOS methods on the objects instead of CASE, and (possibly) using
+;;; SIGNAL instead of THROW.
(declaim (ftype (function (&rest t) nil) give-up-ir1-transform))
(defun give-up-ir1-transform (&rest args)
- #!+sb-doc
- "This function is used to throw out of an IR1 transform, aborting this
- attempt to transform the call, but admitting the possibility that this or
- some other transform will later succeed. If arguments are supplied, they are
- format arguments for an efficiency note."
(throw 'give-up-ir1-transform (values :failure args)))
(defun abort-ir1-transform (&rest args)
- #!+sb-doc
- "This function is used to throw out of an IR1 transform and force a normal
- call to the function at run time. No further optimizations will be
- attempted."
(throw 'give-up-ir1-transform (values :aborted args)))
-
-;;; Take the lambda-expression Res, IR1 convert it in the proper
+(defun delay-ir1-transform (node &rest reasons)
+ (let ((assoc (assoc node *delayed-ir1-transforms*)))
+ (cond ((not assoc)
+ (setf *delayed-ir1-transforms*
+ (acons node reasons *delayed-ir1-transforms*))
+ (throw 'give-up-ir1-transform :delayed))
+ ((cdr assoc)
+ (dolist (reason reasons)
+ (pushnew reason (cdr assoc)))
+ (throw 'give-up-ir1-transform :delayed)))))
+
+;;; Clear any delayed transform with no reasons - these should have
+;;; been tried in the last pass. Then remove the reason from the
+;;; delayed transform reasons, and if any become empty then set
+;;; reoptimize flags for the node. Return true if any transforms are
+;;; to be retried.
+(defun retry-delayed-ir1-transforms (reason)
+ (setf *delayed-ir1-transforms*
+ (remove-if-not #'cdr *delayed-ir1-transforms*))
+ (let ((reoptimize nil))
+ (dolist (assoc *delayed-ir1-transforms*)
+ (let ((reasons (remove reason (cdr assoc))))
+ (setf (cdr assoc) reasons)
+ (unless reasons
+ (let ((node (car assoc)))
+ (unless (node-deleted node)
+ (setf reoptimize t)
+ (setf (node-reoptimize node) t)
+ (let ((block (node-block node)))
+ (setf (block-reoptimize block) t)
+ (setf (component-reoptimize (block-component block)) t)))))))
+ reoptimize))
+
+
+;;; Take the lambda-expression RES, IR1 convert it in the proper
;;; environment, and then install it as the function for the call
-;;; Node. We do local call analysis so that the new function is
+;;; NODE. We do local call analysis so that the new function is
;;; integrated into the control flow.
(defun transform-call (node res)
(declare (type combination node) (list res))
- (with-ir1-environment node
- (let ((new-fun (ir1-convert-inline-lambda res))
+ (with-ir1-environment-from-node node
+ (let ((new-fun (ir1-convert-inline-lambda
+ res
+ :debug-name "something inlined in TRANSFORM-CALL"))
(ref (continuation-use (combination-fun node))))
(change-ref-leaf ref new-fun)
(setf (combination-kind node) :full)
- (local-call-analyze *current-component*)))
+ (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
+;;; 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
;;; evaluation, we give a warning and leave the call alone, making the
;;; call a :ERROR call.
(declare (type combination call))
(let* ((args (mapcar #'continuation-value (combination-args call)))
(ref (continuation-use (combination-fun call)))
- (fun (leaf-name (ref-leaf ref))))
+ (fun-name (leaf-source-name (ref-leaf ref))))
(multiple-value-bind (values win)
- (careful-call fun args call "constant folding")
+ (careful-call fun-name args call "constant folding")
(if (not win)
(setf (combination-kind call) :error)
(let ((dummies (make-gensym-list (length args))))
call
`(lambda ,dummies
(declare (ignore ,@dummies))
- (values ,@(mapcar #'(lambda (x) `',x) values))))))))
+ (values ,@(mapcar (lambda (x) `',x) values))))))))
(values))
\f
;;;; local call optimization
-;;; Propagate Type to Leaf and its Refs, marking things changed. If
+;;; Propagate TYPE to LEAF and its REFS, marking things changed. If
;;; the leaf type is a function type, then just leave it alone, since
;;; TYPE is never going to be more specific than that (and
;;; TYPE-INTERSECTION would choke.)
(defun propagate-to-refs (leaf type)
(declare (type leaf leaf) (type ctype type))
(let ((var-type (leaf-type leaf)))
- (unless (function-type-p var-type)
+ (unless (fun-type-p var-type)
(let ((int (type-approx-intersection2 var-type type)))
(when (type/= int var-type)
(setf (leaf-type leaf) int)
((or constant functional) t)
(lambda-var
(null (lambda-var-sets leaf)))
- (defined-function
- (not (eq (defined-function-inlinep leaf) :notinline)))
+ (defined-fun
+ (not (eq (defined-fun-inlinep leaf) :notinline)))
(global-var
(case (global-var-kind leaf)
- (:global-function t)
- (:constant t))))))
+ (:global-function t))))))
;;; 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.
;;; would be NIL.
;;; -- the var's DEST has a different policy than the ARG's (think safety).
;;;
-;;; We change the Ref to be a reference to NIL with unused value, and
+;;; 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)
;;; changes. We look at each changed argument. If the corresponding
;;; variable is set, then we call PROPAGATE-FROM-SETS. Otherwise, we
;;; consider substituting for the variable, and also propagate
-;;; derived-type information for the arg to all the Var's refs.
+;;; 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
;;;
;;; Substitution of individual references is inhibited if the
;;; reference is in a different component from the home. This can only
-;;; happen with closures over top-level lambda vars. In such cases,
+;;; happen with closures over top level lambda vars. In such cases,
;;; the references may have already been compiled, and thus can't be
;;; retroactively modified.
;;;
;;; are done, then we delete the LET.
;;;
;;; Note that we are responsible for clearing the
-;;; Continuation-Reoptimize flags.
+;;; CONTINUATION-REOPTIMIZE flags.
(defun propagate-let-args (call fun)
(declare (type combination call) (type clambda fun))
(loop for arg in (combination-args call)
(values-subtypep (leaf-type leaf)
(continuation-asserted-type arg)))
(propagate-to-refs var (continuation-type arg))
- (let ((this-comp (block-component (node-block use))))
+ (let ((use-component (node-component use)))
(substitute-leaf-if
- #'(lambda (ref)
- (cond ((eq (block-component (node-block ref))
- this-comp)
- t)
- (t
- (aver (eq (functional-kind (lambda-home fun))
- :top-level))
- nil)))
+ (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)))
- (not *byte-compiling*)
(substitute-single-use-continuation arg var)))
(t
(propagate-to-refs var (continuation-type arg))))))
(defun propagate-local-call-args (call fun)
(declare (type combination call) (type clambda fun))
- (unless (or (functional-entry-function fun)
+ (unless (or (functional-entry-fun fun)
(lambda-optional-dispatch fun))
(let* ((vars (lambda-vars fun))
- (union (mapcar #'(lambda (arg var)
- (when (and arg
- (continuation-reoptimize arg)
- (null (basic-var-sets var)))
- (continuation-type arg)))
+ (union (mapcar (lambda (arg var)
+ (when (and arg
+ (continuation-reoptimize arg)
+ (null (basic-var-sets var)))
+ (continuation-type arg)))
(basic-combination-args call)
vars))
(this-ref (continuation-use (basic-combination-fun call))))
(let ((dest (continuation-dest (node-cont 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)))
+ (mapcar (lambda (this-arg old)
+ (when old
+ (setf (continuation-reoptimize this-arg) nil)
+ (type-union (continuation-type this-arg) old)))
(basic-combination-args dest)
union)))))
- (mapc #'(lambda (var type)
- (when type
- (propagate-to-refs var type)))
+ (mapc (lambda (var type)
+ (when type
+ (propagate-to-refs var type)))
vars union)))
(values))
(when fun-changed
(setf (continuation-reoptimize fun) nil)
(let ((type (continuation-type fun)))
- (when (function-type-p type)
- (derive-node-type node (function-type-returns type))))
+ (when (fun-type-p type)
+ (derive-node-type node (fun-type-returns type))))
(maybe-terminate-block node nil)
(let ((use (continuation-use fun)))
(when (and (ref-p use) (functional-p (ref-leaf use)))
(when (eq (basic-combination-kind node) :local)
(maybe-let-convert (ref-leaf use))))))
(unless (or (eq (basic-combination-kind node) :local)
- (eq (continuation-function-name fun) '%throw))
+ (eq (continuation-fun-name fun) '%throw))
(ir1-optimize-mv-call node))
(dolist (arg args)
(setf (continuation-reoptimize arg) nil))))
(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
+ (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))))))
(return-from ir1-optimize-mv-call))
(multiple-value-bind (min max)
- (function-type-nargs (continuation-type fun))
+ (fun-type-nargs (continuation-type fun))
(let ((total-nvals
(multiple-value-bind (types nvals)
(values-types (continuation-derived-type (first args)))
(when total-nvals
(when (and min (< total-nvals min))
- (compiler-warning
+ (compiler-warn
"MULTIPLE-VALUE-CALL with ~R values when the function expects ~
at least ~R."
total-nvals min)
(setf (basic-combination-kind node) :error)
(return-from ir1-optimize-mv-call))
(when (and max (> total-nvals max))
- (compiler-warning
+ (compiler-warn
"MULTIPLE-VALUE-CALL with ~R values when the function expects ~
at most ~R."
total-nvals max)
min)
(t nil))))
(when count
- (with-ir1-environment node
+ (with-ir1-environment-from-node node
(let* ((dums (make-gensym-list count))
(ignore (gensym))
(fun (ir1-convert-lambda
(funcall ,(ref-leaf ref) ,@dums)))))
(change-ref-leaf ref fun)
(aver (eq (basic-combination-kind node) :full))
- (local-call-analyze *current-component*)
+ (locall-analyze-component *current-component*)
(aver (eq (basic-combination-kind node) :local)))))))))
(values))
(let* ((arg (first (basic-combination-args call)))
(use (continuation-use arg)))
(when (and (combination-p use)
- (eq (continuation-function-name (combination-fun use))
+ (eq (continuation-fun-name (combination-fun use))
'values))
(let* ((fun (combination-lambda call))
(vars (lambda-vars fun))
(mapc #'flush-dest (subseq vals nvars))
(setq vals (subseq vals 0 nvars)))
((< nvals nvars)
- (with-ir1-environment use
+ (with-ir1-environment-from-node use
(let ((node-prev (node-prev use)))
(setf (node-prev use) nil)
(setf (continuation-next node-prev) nil)
do (reference-constant prev cont nil)
(res cont))
(setq vals (res)))
- (prev-link use (car (last vals)))))))
+ (link-node-to-previous-continuation use
+ (car (last vals)))))))
(setf (combination-args use) vals)
(flush-dest (combination-fun use))
(let ((fun-cont (basic-combination-fun call)))
(defoptimizer (values-list optimizer) ((list) node)
(let ((use (continuation-use list)))
(when (and (combination-p use)
- (eq (continuation-function-name (combination-fun use))
+ (eq (continuation-fun-name (combination-fun use))
'list))
(change-ref-leaf (continuation-use (combination-fun node))
(find-free-function 'values "in a strange place"))
`(lambda (val ,@dummies)
(declare (ignore ,@dummies))
val))
- 'nil))
+ nil))