X-Git-Url: http://repo.macrolet.net/gitweb/?a=blobdiff_plain;f=src%2Fcompiler%2Flocall.lisp;h=8c1843263048c39008176a91601c3e906d0d8386;hb=6c765578c8dc4bcc7798e37c9918715f198b30da;hp=ed6f948b38e49cb73542cb76c51ed1798e0d5663;hpb=1d941f3d8f343f5779526b66b2358b4893a17281;p=sbcl.git diff --git a/src/compiler/locall.lisp b/src/compiler/locall.lisp index ed6f948..8c18432 100644 --- a/src/compiler/locall.lisp +++ b/src/compiler/locall.lisp @@ -154,7 +154,7 @@ (cond ,@(if more (butlast (entries)) (entries)) ,@(when more - `((,(if (zerop min) 't `(>= ,n-supplied ,max)) + `((,(if (zerop min) t `(>= ,n-supplied ,max)) ,(let ((n-context (gensym)) (n-count (gensym))) `(multiple-value-bind (,n-context ,n-count) @@ -168,23 +168,21 @@ ;;; then associate this lambda with FUN as its XEP. After the ;;; conversion, we iterate over the function's associated lambdas, ;;; redoing local call analysis so that the XEP calls will get -;;; converted. We also bind *LEXENV* to change the compilation policy -;;; over to the interface policy. +;;; converted. ;;; ;;; We set REANALYZE and REOPTIMIZE in the component, just in case we ;;; discover an XEP after the initial local call analyze pass. (defun make-external-entry-point (fun) (declare (type functional fun)) - (assert (not (functional-entry-function fun))) + (aver (not (functional-entry-function fun))) (with-ir1-environment (lambda-bind (main-entry fun)) - (let* ((*lexenv* (make-lexenv :policy (make-interface-policy *lexenv*))) - (res (ir1-convert-lambda (make-xep-lambda fun)))) - (setf (functional-kind res) :external) - (setf (leaf-ever-used res) t) - (setf (functional-entry-function res) fun) - (setf (functional-entry-function fun) res) - (setf (component-reanalyze *current-component*) t) - (setf (component-reoptimize *current-component*) t) + (let ((res (ir1-convert-lambda (make-xep-lambda fun)))) + (setf (functional-kind res) :external + (leaf-ever-used res) t + (functional-entry-function res) fun + (functional-entry-function fun) res + (component-reanalyze *current-component*) t + (component-reoptimize *current-component*) t) (etypecase fun (clambda (local-call-analyze-1 fun)) (optional-dispatch @@ -295,7 +293,8 @@ (won nil) (res (catch 'local-call-lossage (prog1 - (ir1-convert-lambda (functional-inline-expansion fun)) + (ir1-convert-lambda (functional-inline-expansion + fun)) (setq won t))))) (cond (won (change-ref-leaf ref res) @@ -332,7 +331,7 @@ (let* ((block (node-block call)) (component (block-component block)) (original-fun (ref-leaf ref))) - (assert (functional-p original-fun)) + (aver (functional-p original-fun)) (unless (or (member (basic-combination-kind call) '(:local :error)) (block-delete-p block) (eq (functional-kind (block-home-lambda block)) :deleted) @@ -352,8 +351,8 @@ (rest (leaf-refs original-fun))) (setq fun (maybe-expand-local-inline fun ref call))) - (assert (member (functional-kind fun) - '(nil :escape :cleanup :optional))) + (aver (member (functional-kind fun) + '(nil :escape :cleanup :optional))) (cond ((mv-combination-p call) (convert-mv-call ref call fun)) ((lambda-p fun) @@ -431,10 +430,11 @@ ;;;; optional, more and keyword calls -;;; Similar to Convert-Lambda-Call, but deals with Optional-Dispatches. If -;;; only fixed args are supplied, then convert a call to the correct entry -;;; point. If keyword args are supplied, then dispatch to a subfunction. We -;;; don't convert calls to functions that have a more (or rest) arg. +;;; This is similar to CONVERT-LAMBDA-CALL, but deals with +;;; OPTIONAL-DISPATCHes. If only fixed args are supplied, then convert +;;; a call to the correct entry point. If &KEY args are supplied, then +;;; dispatch to a subfunction. We don't convert calls to functions +;;; that have a &MORE (or &REST) arg. (defun convert-hairy-call (ref call fun) (declare (type ref ref) (type combination call) (type optional-dispatch fun)) @@ -487,20 +487,21 @@ (dolist (ref (leaf-refs entry)) (convert-call-if-possible ref (continuation-dest (node-cont ref)))))) -;;; Use Convert-Hairy-Fun-Entry to convert a more-arg call to a known -;;; function into a local call to the Main-Entry. +;;; Use CONVERT-HAIRY-FUN-ENTRY to convert a &MORE-arg call to a known +;;; function into a local call to the MAIN-ENTRY. ;;; ;;; First we verify that all keywords are constant and legal. If there ;;; aren't, then we warn the user and don't attempt to convert the call. ;;; -;;; We massage the supplied keyword arguments into the order expected by the -;;; main entry. This is done by binding all the arguments to the keyword call -;;; to variables in the introduced lambda, then passing these values variables -;;; in the correct order when calling the main entry. Unused arguments -;;; (such as the keywords themselves) are discarded simply by not passing them -;;; along. +;;; We massage the supplied &KEY arguments into the order expected +;;; by the main entry. This is done by binding all the arguments to +;;; the keyword call to variables in the introduced lambda, then +;;; passing these values variables in the correct order when calling +;;; the main entry. Unused arguments (such as the keywords themselves) +;;; are discarded simply by not passing them along. ;;; -;;; If there is a rest arg, then we bundle up the args and pass them to LIST. +;;; If there is a &REST arg, then we bundle up the args and pass them +;;; to LIST. (defun convert-more-call (ref call fun) (declare (type ref ref) (type combination call) (type optional-dispatch fun)) (let* ((max (optional-dispatch-max-args fun)) @@ -554,7 +555,7 @@ (ignores dummy val) (setq loser name))) (let ((info (lambda-var-arg-info var))) - (when (eq (arg-info-keyword info) name) + (when (eq (arg-info-key info) name) (ignores dummy) (supplied (cons var val)) (return))))))) @@ -600,33 +601,33 @@ ;;;; LET conversion ;;;; -;;;; Converting to a LET has differing significance to various parts of the -;;;; compiler: -;;;; -- The body of a LET is spliced in immediately after the corresponding -;;;; combination node, making the control transfer explicit and allowing -;;;; LETs to be mashed together into a single block. The value of the LET is -;;;; delivered directly to the original continuation for the call, -;;;; eliminating the need to propagate information from the dummy result -;;;; continuation. -;;;; -- As far as IR1 optimization is concerned, it is interesting in that -;;;; there is only one expression that the variable can be bound to, and -;;;; this is easily substitited for. -;;;; -- LETs are interesting to environment analysis and to the back end -;;;; because in most ways a LET can be considered to be "the same function" -;;;; as its home function. -;;;; -- LET conversion has dynamic scope implications, since control transfers -;;;; within the same environment are local. In a local control transfer, -;;;; cleanup code must be emitted to remove dynamic bindings that are no -;;;; longer in effect. - -;;; Set up the control transfer to the called lambda. We split the call -;;; block immediately after the call, and link the head of FUN to the call -;;; block. The successor block after splitting (where we return to) is -;;; returned. -;;; -;;; If the lambda is is a different component than the call, then we call -;;; JOIN-COMPONENTS. This only happens in block compilation before -;;; FIND-INITIAL-DFO. +;;;; Converting to a LET has differing significance to various parts +;;;; of the compiler: +;;;; -- The body of a LET is spliced in immediately after the +;;;; corresponding combination node, making the control transfer +;;;; explicit and allowing LETs to be mashed together into a single +;;;; block. The value of the LET is delivered directly to the +;;;; original continuation for the call,eliminating the need to +;;;; propagate information from the dummy result continuation. +;;;; -- As far as IR1 optimization is concerned, it is interesting in +;;;; that there is only one expression that the variable can be bound +;;;; to, and this is easily substitited for. +;;;; -- LETs are interesting to environment analysis and to the back +;;;; end because in most ways a LET can be considered to be "the +;;;; same function" as its home function. +;;;; -- LET conversion has dynamic scope implications, since control +;;;; transfers within the same environment are local. In a local +;;;; control transfer, cleanup code must be emitted to remove +;;;; dynamic bindings that are no longer in effect. + +;;; Set up the control transfer to the called lambda. We split the +;;; call block immediately after the call, and link the head of FUN to +;;; the call block. The successor block after splitting (where we +;;; return to) is returned. +;;; +;;; If the lambda is is a different component than the call, then we +;;; call JOIN-COMPONENTS. This only happens in block compilation +;;; before FIND-INITIAL-DFO. (defun insert-let-body (fun call) (declare (type clambda fun) (type basic-combination call)) (let* ((call-block (node-block call)) @@ -634,7 +635,7 @@ (component (block-component call-block))) (let ((fun-component (block-component bind-block))) (unless (eq fun-component component) - (assert (eq (component-kind component) :initial)) + (aver (eq (component-kind component) :initial)) (join-components component fun-component))) (let ((*current-component* component)) @@ -642,7 +643,7 @@ ;; FIXME: Use PROPER-LIST-OF-LENGTH-P here, and look for other ;; uses of '=.*length' which could also be converted to use ;; PROPER-LIST-OF-LENGTH-P. - (assert (= (length (block-succ call-block)) 1)) + (aver (= (length (block-succ call-block)) 1)) (let ((next-block (first (block-succ call-block)))) (unlink-blocks call-block next-block) (link-blocks call-block bind-block) @@ -765,7 +766,7 @@ (add-continuation-use this-call cont))) (:deleted) (:assignment - (assert (eq called fun)))))))) + (aver (eq called fun)))))))) (values)) ;;; Deal with returning from a LET or assignment that we are @@ -804,7 +805,7 @@ (move-return-uses fun call (or next-block (node-block call-return))))) (t - (assert (node-tail-p call)) + (aver (node-tail-p call)) (setf (lambda-return call-fun) return) (setf (return-lambda return) call-fun)))) (move-let-call-cont fun) @@ -920,7 +921,7 @@ (defun maybe-convert-tail-local-call (call) (declare (type combination call)) (let ((return (continuation-dest (node-cont call)))) - (assert (return-p return)) + (aver (return-p return)) (when (and (not (node-tail-p call)) (immediately-used-p (return-result return) call) (not (eq (functional-kind (node-home-lambda call))