(setf (component-reanalyze component) nil)
(let ((head (component-head component)))
(do ()
- ((dolist (ep (block-succ head) t)
- (unless (block-flag ep)
- (find-dfo-aux ep head component)
- (return nil))))))
-
+ ((dolist (ep (block-succ head) t)
+ (unless (or (block-flag ep) (block-delete-p ep))
+ (find-dfo-aux ep head component)
+ (return nil))))))
(let ((num 0))
(declare (fixnum num))
(do-blocks-backwards (block component :both)
(if (block-flag block)
- (setf (block-number block) (incf num))
- (setf (block-delete-p block) t)))
- (do-blocks (block component)
- (unless (block-flag block)
- (delete-block block))))
+ (setf (block-number block) (incf num))
+ (delete-block-lazily block)))
+ (clean-component component (component-head component)))
(values))
;;; Move all the code and entry points from OLD to NEW. The code in
(defun join-components (new old)
(aver (eq (component-kind new) (component-kind old)))
(let ((old-head (component-head old))
- (old-tail (component-tail old))
- (head (component-head new))
- (tail (component-tail new)))
+ (old-tail (component-tail old))
+ (head (component-head new))
+ (tail (component-tail new)))
(do-blocks (block old)
(setf (block-flag block) nil)
(setf (block-component block) new))
(let ((old-next (block-next old-head))
- (old-last (block-prev old-tail))
- (next (block-next head)))
+ (old-last (block-prev old-tail))
+ (next (block-next head)))
(unless (eq old-next old-tail)
- (setf (block-next head) old-next)
- (setf (block-prev old-next) head)
-
- (setf (block-prev next) old-last)
- (setf (block-next old-last) next))
+ (setf (block-next head) old-next)
+ (setf (block-prev old-next) head)
+
+ (setf (block-prev next) old-last)
+ (setf (block-next old-last) next))
(setf (block-next old-head) old-tail)
(setf (block-prev old-tail) old-head))
(setf (component-lambdas new)
- (nconc (component-lambdas old) (component-lambdas new)))
- (setf (component-lambdas old) ())
- (setf (component-new-functions new)
- (nconc (component-new-functions old) (component-new-functions new)))
- (setf (component-new-functions old) ())
+ (nconc (component-lambdas old) (component-lambdas new)))
+ (setf (component-lambdas old) nil)
+ (setf (component-new-functionals new)
+ (nconc (component-new-functionals old)
+ (component-new-functionals new)))
+ (setf (component-new-functionals old) nil)
(dolist (xp (block-pred old-tail))
(unlink-blocks xp old-tail)
(defun find-dfo-aux (block head component)
(unless (eq (block-component block) component)
(join-components component (block-component block)))
-
- (unless (block-flag block)
+ (unless (or (block-flag block) (block-delete-p block))
(setf (block-flag block) t)
(dolist (succ (block-succ block))
(find-dfo-aux succ head component))
-
+ (when (component-nlx-info-generated-p component)
+ ;; FIXME: We also need (and do) this walk before physenv
+ ;; analysis, but at that time we are probably not very
+ ;; interested in the actual DF order.
+ ;;
+ ;; TODO: It is probable that one of successors have the same (or
+ ;; similar) set of NLXes; try to shorten the walk (but think
+ ;; about a loop, the only exit from which is non-local).
+ (map-block-nlxes (lambda (nlx-info)
+ (let ((nle (nlx-info-target nlx-info)))
+ (find-dfo-aux nle head component)))
+ block))
(remove-from-dfo block)
(add-to-dfo block head))
(values))
;;; This function is called on each block by FIND-INITIAL-DFO-AUX
-;;; before it walks the successors. It looks at the home lambda's bind
-;;; block to see whether that block is in some other component:
-
+;;; before it walks the successors. It looks at the home CLAMBDA's
+;;; BIND block to see whether that block is in some other component:
;;; -- If the block is in the initial component, then do
-;;; DFO-WALK-CALL-GRAPH on the home function to move it
+;;; DFO-SCAVENGE-DEPENDENCY-GRAPH on the home function to move it
;;; into COMPONENT.
;;; -- If the block is in some other component, join COMPONENT into
;;; it and return that component.
;;; the same component, even when they might not seem reachable from
;;; the environment entry. Consider the case of code that is only
;;; reachable from a non-local exit.
-(defun walk-home-call-graph (block component)
+(defun scavenge-home-dependency-graph (block component)
(declare (type cblock block) (type component component))
- (let ((home (block-home-lambda block)))
- (if (eq (functional-kind home) :deleted)
- component
- (let* ((bind-block (node-block (lambda-bind home)))
- (home-component (block-component bind-block)))
- (cond ((eq (component-kind home-component) :initial)
- (dfo-walk-call-graph home component))
- ((eq home-component component)
- component)
- (t
- (join-components home-component component)
- home-component))))))
+ (let ((home-lambda (block-home-lambda block)))
+ (if (eq (functional-kind home-lambda) :deleted)
+ component
+ (let ((home-component (lambda-component home-lambda)))
+ (cond ((eq (component-kind home-component) :initial)
+ (dfo-scavenge-dependency-graph home-lambda component))
+ ((eq home-component component)
+ component)
+ (t
+ (join-components home-component component)
+ home-component))))))
;;; This is somewhat similar to FIND-DFO-AUX, except that it merges
;;; the current component with any strange component, rather than the
(let ((this (block-component block)))
(cond
((not (or (eq this component)
- (eq (component-kind this) :initial)))
+ (eq (component-kind this) :initial)))
(join-components this component)
this)
((block-flag block) component)
(t
(setf (block-flag block) t)
- (let ((current (walk-home-call-graph block component)))
- (dolist (succ (block-succ block))
- (setq current (find-initial-dfo-aux succ current)))
-
- (remove-from-dfo block)
- (add-to-dfo block (component-head current))
- current)))))
+ (let ((current (scavenge-home-dependency-graph block component)))
+ (dolist (succ (block-succ block))
+ (setq current (find-initial-dfo-aux succ current)))
+ (remove-from-dfo block)
+ (add-to-dfo block (component-head current))
+ current)))))
;;; Return a list of all the home lambdas that reference FUN (may
;;; contain duplications).
;;; References to functions which local call analysis could not (or
;;; were chosen not) to local call convert will appear as references
;;; to XEP lambdas. We can ignore references to XEPs that appear in
-;;; :TOP-LEVEL components, since environment analysis goes to special
-;;; effort to allow closing over of values from a separate top-level
+;;; :TOPLEVEL components, since environment analysis goes to special
+;;; effort to allow closing over of values from a separate top level
;;; component. (And now that HAS-EXTERNAL-REFERENCES-P-ness
-;;; generalizes :TOP-LEVEL-ness, we ignore those too.) All other
+;;; generalizes :TOPLEVEL-ness, we ignore those too.) All other
;;; references must cause components to be joined.
;;;
;;; References in deleted functions are also ignored, since this code
;;; will be deleted eventually.
-(defun find-reference-functions (fun)
+(defun find-reference-funs (fun)
(collect ((res))
(dolist (ref (leaf-refs fun))
(let* ((home (node-home-lambda ref))
- (home-kind (functional-kind home))
- (home-externally-visible-p
- (or (eq home-kind :top-level)
- (functional-has-external-references-p home))))
- (unless (or (and home-externally-visible-p
- (eq (functional-kind fun) :external))
- (eq home-kind :deleted))
- (res home))))
+ (home-kind (functional-kind home))
+ (home-externally-visible-p
+ (or (eq home-kind :toplevel)
+ (functional-has-external-references-p home)
+ (let ((entry (functional-entry-fun home)))
+ (and entry
+ (functional-has-external-references-p entry))))))
+ (unless (or (and home-externally-visible-p
+ (eq (functional-kind fun) :external))
+ (eq home-kind :deleted))
+ (res home))))
(res)))
-;;; Move the code for FUN and all functions called by it into
-;;; COMPONENT. If FUN is already in COMPONENT, then we just return
-;;; that component.
+;;; If CLAMBDA is already in COMPONENT, just return that
+;;; component. Otherwise, move the code for CLAMBDA and all lambdas it
+;;; physically depends on (either because of calls or because of
+;;; closure relationships) into COMPONENT, or possibly into another
+;;; COMPONENT that we find to be related. Return whatever COMPONENT we
+;;; actually merged into.
+;;;
+;;; (Note: The analogous CMU CL code only scavenged call-based
+;;; dependencies, not closure dependencies. That seems to've been by
+;;; oversight, not by design, as per the bug reported by WHN on
+;;; cmucl-imp ca. 2001-11-29 and explained by DTC shortly after.)
;;;
;;; If the function is in an initial component, then we move its head
;;; and tail to COMPONENT and add it to COMPONENT's lambdas. It is
;;; unreachable) because if the return is unreachable it (and its
;;; successor link) will be deleted in the post-deletion pass.
;;;
-;;; We then do a FIND-DFO-AUX starting at the head of FUN. If this
+;;; We then do a FIND-DFO-AUX starting at the head of CLAMBDA. If this
;;; flow-graph walk encounters another component (which can only
;;; happen due to a non-local exit), then we move code into that
;;; component instead. We then recurse on all functions called from
-;;; FUN, moving code into whichever component the preceding call
+;;; CLAMBDA, moving code into whichever component the preceding call
;;; returned.
;;;
-;;; If FUN is in the initial component, but the BLOCK-FLAG is set in
-;;; the bind block, then we just return COMPONENT, since we must have
-;;; already reached this function in the current walk (or the
+;;; If CLAMBDA is in the initial component, but the BLOCK-FLAG is set
+;;; in the bind block, then we just return COMPONENT, since we must
+;;; have already reached this function in the current walk (or the
;;; component would have been changed).
;;;
;;; If the function is an XEP, then we also walk all functions that
;;; ensures that conversion of a full call to a local call won't
;;; result in a need to join components, since the components will
;;; already be one.
-(defun dfo-walk-call-graph (fun component)
- (declare (type clambda fun) (type component component))
- (let* ((bind-block (node-block (lambda-bind fun)))
- (this (block-component bind-block))
- (return (lambda-return fun)))
+(defun dfo-scavenge-dependency-graph (clambda component)
+ (declare (type clambda clambda) (type component component))
+ (assert (not (eql (lambda-kind clambda) :deleted)))
+ (let* ((bind-block (node-block (lambda-bind clambda)))
+ (old-lambda-component (block-component bind-block))
+ (return (lambda-return clambda)))
(cond
- ((eq this component) component)
- ((not (eq (component-kind this) :initial))
- (join-components this component)
- this)
+ ((eq old-lambda-component component)
+ component)
+ ((not (eq (component-kind old-lambda-component) :initial))
+ (join-components old-lambda-component component)
+ old-lambda-component)
((block-flag bind-block)
component)
(t
- (push fun (component-lambdas component))
- (setf (component-lambdas this)
- (delete fun (component-lambdas this)))
+ (push clambda (component-lambdas component))
+ (setf (component-lambdas old-lambda-component)
+ (delete clambda (component-lambdas old-lambda-component)))
(link-blocks (component-head component) bind-block)
- (unlink-blocks (component-head this) bind-block)
+ (unlink-blocks (component-head old-lambda-component) bind-block)
(when return
- (let ((return-block (node-block return)))
- (link-blocks return-block (component-tail component))
- (unlink-blocks return-block (component-tail this))))
- (let ((calls (if (eq (functional-kind fun) :external)
- (append (find-reference-functions fun)
- (lambda-calls fun))
- (lambda-calls fun))))
- (do ((res (find-initial-dfo-aux bind-block component)
- (dfo-walk-call-graph (first funs) res))
- (funs calls (rest funs)))
- ((null funs) res)
- (declare (type component res))))))))
-
-;;; Return true if FUN is either an XEP or has EXITS to some of its
-;;; ENTRIES.
-(defun has-xep-or-nlx (fun)
- (declare (type clambda fun))
- (or (eq (functional-kind fun) :external)
- (let ((entries (lambda-entries fun)))
- (and entries
- (find-if #'entry-exits entries)))))
+ (let ((return-block (node-block return)))
+ (link-blocks return-block (component-tail component))
+ (unlink-blocks return-block (component-tail old-lambda-component))))
+ (let ((res (find-initial-dfo-aux bind-block component)))
+ (declare (type component res))
+ ;; Scavenge related lambdas.
+ (labels ((scavenge-lambda (clambda)
+ (setf res
+ (dfo-scavenge-dependency-graph (lambda-home clambda)
+ res)))
+ (scavenge-possibly-deleted-lambda (clambda)
+ (unless (eql (lambda-kind clambda) :deleted)
+ (scavenge-lambda clambda)))
+ ;; Scavenge call relationship.
+ (scavenge-call (called-lambda)
+ (scavenge-lambda called-lambda))
+ ;; Scavenge closure over a variable: if CLAMBDA
+ ;; refers to a variable whose home lambda is not
+ ;; CLAMBDA, then the home lambda should be in the
+ ;; same component as CLAMBDA. (sbcl-0.6.13, and CMU
+ ;; CL, didn't do this, leading to the occasional
+ ;; failure when physenv analysis, which is local to
+ ;; each component, would bogusly conclude that a
+ ;; closed-over variable was unused and thus delete
+ ;; it. See e.g. cmucl-imp 2001-11-29.)
+ (scavenge-closure-var (var)
+ (unless (null (lambda-var-refs var)) ; unless var deleted
+ (let ((var-home-home (lambda-home (lambda-var-home var))))
+ (scavenge-possibly-deleted-lambda var-home-home))))
+ ;; Scavenge closure over an entry for nonlocal exit.
+ ;; This is basically parallel to closure over a
+ ;; variable above.
+ (scavenge-entry (entry)
+ (declare (type entry entry))
+ (let ((entry-home (node-home-lambda entry)))
+ (scavenge-possibly-deleted-lambda entry-home))))
+ (do-sset-elements (cc (lambda-calls-or-closes clambda))
+ (etypecase cc
+ (clambda (scavenge-call cc))
+ (lambda-var (scavenge-closure-var cc))
+ (entry (scavenge-entry cc))))
+ (when (eq (lambda-kind clambda) :external)
+ (mapc #'scavenge-call (find-reference-funs clambda))))
+ ;; Voila.
+ res)))))
+
+;;; Return true if CLAMBDA either is an XEP or has EXITS to some of
+;;; its ENTRIES.
+(defun has-xep-or-nlx (clambda)
+ (declare (type clambda clambda))
+ (or (eq (functional-kind clambda) :external)
+ (let ((entries (lambda-entries clambda)))
+ (and entries
+ (find-if #'entry-exits entries)))))
;;; Compute the result of FIND-INITIAL-DFO given the list of all
-;;; resulting components. Components with a :TOP-LEVEL lambda, but no
-;;; normal XEPs or potential non-local exits are marked as :TOP-LEVEL.
-;;; If there is a :TOP-LEVEL lambda, and also a normal XEP, then we
+;;; resulting components. Components with a :TOPLEVEL lambda, but no
+;;; normal XEPs or potential non-local exits are marked as :TOPLEVEL.
+;;; If there is a :TOPLEVEL lambda, and also a normal XEP, then we
;;; treat the component as normal, but also return such components in
;;; a list as the third value. Components with no entry of any sort
;;; are deleted.
-(defun find-top-level-components (components)
+(defun separate-toplevelish-components (components)
(declare (list components))
(collect ((real)
- (top)
- (real-top))
- (dolist (com components)
- (unless (eq (block-next (component-head com)) (component-tail com))
- (let* ((funs (component-lambdas com))
- (has-top (find :top-level funs :key #'functional-kind))
- (has-external-references
- (some #'functional-has-external-references-p funs)))
- (cond (;; The FUNCTIONAL-HAS-EXTERNAL-REFERENCES-P concept
- ;; is newer than the rest of this function, and
- ;; doesn't really seem to fit into its mindset. Here
- ;; we mark components which contain such FUNCTIONs
- ;; them as :COMPLEX-TOP-LEVEL, since they do get
- ;; executed at run time, and since it's not valid to
- ;; delete them just because they don't have any
- ;; references from pure :TOP-LEVEL components. -- WHN
- has-external-references
- (setf (component-kind com) :complex-top-level)
- (real com)
- (real-top com))
- ((or (some #'has-xep-or-nlx funs)
- (and has-top (rest funs)))
- (setf (component-name com) (find-component-name com))
- (real com)
- (when has-top
- (setf (component-kind com) :complex-top-level)
- (real-top com)))
- (has-top
- (setf (component-kind com) :top-level)
- (setf (component-name com) "top-level form")
- (top com))
- (t
- (delete-component com))))))
+ (top)
+ (real-top))
+ (dolist (component components)
+ (unless (eq (block-next (component-head component))
+ (component-tail component))
+ (let* ((funs (component-lambdas component))
+ (has-top (find :toplevel funs :key #'functional-kind))
+ (has-external-references
+ (some #'functional-has-external-references-p funs)))
+ (cond (;; The FUNCTIONAL-HAS-EXTERNAL-REFERENCES-P concept
+ ;; is newer than the rest of this function, and
+ ;; doesn't really seem to fit into its mindset. Here
+ ;; we mark components which contain such FUNCTIONs
+ ;; them as :COMPLEX-TOPLEVEL, since they do get
+ ;; executed at run time, and since it's not valid to
+ ;; delete them just because they don't have any
+ ;; references from pure :TOPLEVEL components. -- WHN
+ has-external-references
+ (setf (component-kind component) :complex-toplevel)
+ (real component)
+ (real-top component))
+ ((or (some #'has-xep-or-nlx funs)
+ (and has-top (rest funs)))
+ (setf (component-name component)
+ (find-component-name component))
+ (real component)
+ (when has-top
+ (setf (component-kind component) :complex-toplevel)
+ (real-top component)))
+ (has-top
+ (setf (component-kind component) :toplevel)
+ (setf (component-name component) "top level form")
+ (top component))
+ (t
+ (delete-component component))))))
(values (real) (top) (real-top))))
-;;; Given a list of top-level lambdas, return three lists of
-;;; components representing the actual component division:
-;;; 1. the non-top-level components,
-;;; 2. and the second is the top-level components, and
-;;; 3. Components in [1] that also have a top-level lambda.
+;;; Given a list of top level lambdas, return
+;;; (VALUES NONTOP-COMPONENTS TOP-COMPONENTS HAIRY-TOP-COMPONENTS).
+;;; Each of the three values returned is a list of COMPONENTs:
+;;; NONTOP-COMPONENTS = non-top-level-ish COMPONENTs;
+;;; TOP-COMPONENTS = top-level-ish COMPONENTs;
+;;; HAIRY-TOP-COMPONENTS = a subset of NONTOP-COMPONENTS, those
+;;; elements which include a top-level-ish lambda.
;;;
;;; We assign the DFO for each component, and delete any unreachable
-;;; blocks. We assume that the Flags have already been cleared.
-;;;
-;;; We iterate over the lambdas in each initial component, trying to
-;;; put each function in its own component, but joining it to an
-;;; existing component if we find that there are references between
-;;; them. Any code that is left in an initial component must be
-;;; unreachable, so we can delete it. Stray links to the initial
-;;; component tail (due NIL function terminated blocks) are moved to
-;;; the appropriate newc component tail.
-;;;
-;;; When we are done, we assign DFNs and call
-;;; FIND-TOP-LEVEL-COMPONENTS to pull out top-level code.
-(defun find-initial-dfo (lambdas)
- (declare (list lambdas))
+;;; blocks. We assume that the FLAGS have already been cleared.
+(defun find-initial-dfo (toplevel-lambdas)
+ (declare (list toplevel-lambdas))
(collect ((components))
- (let ((new (make-empty-component)))
- (dolist (tll lambdas)
- (let ((component (block-component (node-block (lambda-bind tll)))))
- (dolist (fun (component-lambdas component))
- (aver (member (functional-kind fun)
- '(:optional :external :top-level nil :escape
- :cleanup)))
- (let ((res (dfo-walk-call-graph fun new)))
- (when (eq res new)
- (components new)
- (setq new (make-empty-component)))))
- (when (eq (component-kind component) :initial)
- (aver (null (component-lambdas component)))
- (let ((tail (component-tail component)))
- (dolist (pred (block-pred tail))
- (let ((pred-component (block-component pred)))
- (unless (eq pred-component component)
- (unlink-blocks pred tail)
- (link-blocks pred (component-tail pred-component))))))
- (delete-component component)))))
-
- (dolist (com (components))
+ ;; We iterate over the lambdas in each initial component, trying
+ ;; to put each function in its own component, but joining it to
+ ;; an existing component if we find that there are references
+ ;; between them. Any code that is left in an initial component
+ ;; must be unreachable, so we can delete it. Stray links to the
+ ;; initial component tail (due to NIL function terminated blocks)
+ ;; are moved to the appropriate new component tail.
+ (dolist (toplevel-lambda toplevel-lambdas)
+ (let* ((old-component (lambda-component toplevel-lambda))
+ (old-component-lambdas (component-lambdas old-component))
+ (new-component nil))
+ (aver (member toplevel-lambda old-component-lambdas))
+ (dolist (component-lambda old-component-lambdas)
+ (aver (member (functional-kind component-lambda)
+ '(:optional :external :toplevel nil :escape
+ :cleanup)))
+ (unless new-component
+ (setf new-component (make-empty-component))
+ (setf (component-name new-component)
+ ;; This isn't necessarily an ideal name for the
+ ;; component, since it might end up with multiple
+ ;; lambdas in it, not just this one, but it does
+ ;; seem a better name than just "<unknown>".
+ (leaf-debug-name component-lambda)))
+ (let ((res (dfo-scavenge-dependency-graph component-lambda
+ new-component)))
+ (when (eq res new-component)
+ (aver (not (position new-component (components))))
+ (components new-component)
+ (setq new-component nil))))
+ (when (eq (component-kind old-component) :initial)
+ (aver (null (component-lambdas old-component)))
+ (let ((tail (component-tail old-component)))
+ (dolist (pred (block-pred tail))
+ (let ((pred-component (block-component pred)))
+ (unless (eq pred-component old-component)
+ (unlink-blocks pred tail)
+ (link-blocks pred (component-tail pred-component))))))
+ (delete-component old-component))))
+
+ ;; When we are done, we assign DFNs.
+ (dolist (component (components))
(let ((num 0))
- (declare (fixnum num))
- (do-blocks-backwards (block com :both)
- (setf (block-number block) (incf num)))))
+ (declare (fixnum num))
+ (do-blocks-backwards (block component :both)
+ (setf (block-number block) (incf num)))))
- (find-top-level-components (components))))
+ ;; Pull out top-level-ish code.
+ (separate-toplevelish-components (components))))
\f
;;; Insert the code in LAMBDA at the end of RESULT-LAMBDA.
-(defun merge-1-tl-lambda (result-lambda lambda)
+(defun merge-1-toplevel-lambda (result-lambda lambda)
(declare (type clambda result-lambda lambda))
;; Delete the lambda, and combine the LETs and entries.
(setf (functional-kind lambda) :deleted)
(dolist (let (lambda-lets lambda))
(setf (lambda-home let) result-lambda)
- (setf (lambda-environment let) (lambda-environment result-lambda))
+ (setf (lambda-physenv let) (lambda-physenv result-lambda))
(push let (lambda-lets result-lambda)))
(setf (lambda-entries result-lambda)
- (nconc (lambda-entries result-lambda)
- (lambda-entries lambda)))
+ (nconc (lambda-entries result-lambda)
+ (lambda-entries lambda)))
(let* ((bind (lambda-bind lambda))
- (bind-block (node-block bind))
- (component (block-component bind-block))
- (result-component
- (block-component (node-block (lambda-bind result-lambda))))
- (result-return-block (node-block (lambda-return result-lambda))))
+ (bind-block (node-block bind))
+ (component (block-component bind-block))
+ (result-component (lambda-component result-lambda))
+ (result-return-block (node-block (lambda-return result-lambda))))
;; Move blocks into the new COMPONENT, and move any nodes directly
;; in the old LAMBDA into the new one (with LETs implicitly moved
;; by changing their home.)
(do-blocks (block component)
- (do-nodes (node cont block)
- (let ((lexenv (node-lexenv node)))
- (when (eq (lexenv-lambda lexenv) lambda)
- (setf (lexenv-lambda lexenv) result-lambda))))
+ (do-nodes (node nil block)
+ (let ((lexenv (node-lexenv node)))
+ (when (eq (lexenv-lambda lexenv) lambda)
+ (setf (lexenv-lambda lexenv) result-lambda))))
(setf (block-component block) result-component))
;; Splice the blocks into the new DFO, and unlink them from the
;; old component head and tail. Non-return blocks that jump to the
;; tail (NIL-returning calls) are switched to go to the new tail.
(let* ((head (component-head component))
- (first (block-next head))
- (tail (component-tail component))
- (last (block-prev tail))
- (prev (block-prev result-return-block)))
+ (first (block-next head))
+ (tail (component-tail component))
+ (last (block-prev tail))
+ (prev (block-prev result-return-block)))
(setf (block-next prev) first)
(setf (block-prev first) prev)
(setf (block-next last) result-return-block)
(setf (block-prev result-return-block) last)
(dolist (succ (block-succ head))
- (unlink-blocks head succ))
+ (unlink-blocks head succ))
(dolist (pred (block-pred tail))
- (unlink-blocks pred tail)
- (let ((last (block-last pred)))
- (unless (return-p last)
- (aver (basic-combination-p last))
- (link-blocks pred (component-tail result-component))))))
+ (unlink-blocks pred tail)
+ (let ((last (block-last pred)))
+ (unless (return-p last)
+ (aver (basic-combination-p last))
+ (link-blocks pred (component-tail result-component))))))
(let ((lambdas (component-lambdas component)))
(aver (and (null (rest lambdas))
- (eq (first lambdas) lambda))))
+ (eq (first lambdas) lambda))))
;; Switch the end of the code from the return block to the start of
;; the next chunk.
;; If there is a return, then delete it (making the preceding node
;; the last node) and link the block to the result return. There
- ;; is always a preceding REF NIL node in top-level lambdas.
+ ;; is always a preceding REF NIL node in top level lambdas.
(let ((return (lambda-return lambda)))
(when return
- (let ((return-block (node-block return))
- (result (return-result return)))
- (setf (block-last return-block) (continuation-use result))
- (flush-dest result)
- (delete-continuation result)
- (link-blocks return-block result-return-block))))))
-
-;;; Given a non-empty list of top-level LAMBDAs, smash them into a
-;;; top-level lambda and component, returning these as values. We use
+ (link-blocks (node-block return) result-return-block)
+ (flush-dest (return-result return))
+ (unlink-node return)))))
+
+;;; Given a non-empty list of top level LAMBDAs, smash them into a
+;;; top level lambda and component, returning these as values. We use
;;; the first lambda and its component, putting the other code in that
;;; component and deleting the other lambdas.
-(defun merge-top-level-lambdas (lambdas)
+(defun merge-toplevel-lambdas (lambdas)
(declare (cons lambdas))
(let* ((result-lambda (first lambdas))
- (result-return (lambda-return result-lambda)))
+ (result-return (lambda-return result-lambda)))
(cond
(result-return
;; Make sure the result's return node starts a block so that we
;; can splice code in before it.
(let ((prev (node-prev
- (continuation-use
- (return-result result-return)))))
- (when (continuation-use prev)
- (node-ends-block (continuation-use prev)))
- (do-uses (use prev)
- (let ((new (make-continuation)))
- (delete-continuation-use use)
- (add-continuation-use use new))))
+ (lvar-uses (return-result result-return)))))
+ (when (ctran-use prev)
+ (node-ends-block (ctran-use prev))))
(dolist (lambda (rest lambdas))
- (merge-1-tl-lambda result-lambda lambda)))
+ (merge-1-toplevel-lambda result-lambda lambda)))
(t
(dolist (lambda (rest lambdas))
- (setf (functional-entry-function lambda) nil)
- (delete-component
- (block-component
- (node-block (lambda-bind lambda)))))))
+ (setf (functional-entry-fun lambda) nil)
+ (delete-component (lambda-component lambda)))))
- (values (block-component (node-block (lambda-bind result-lambda)))
- result-lambda)))
+ (values (lambda-component result-lambda) result-lambda)))