1 ;;;; the top level interfaces to the compiler, plus some other
2 ;;;; compiler-related stuff (e.g. CL:CALL-ARGUMENTS-LIMIT) which
3 ;;;; doesn't obviously belong anywhere else
5 ;;;; This software is part of the SBCL system. See the README file for
8 ;;;; This software is derived from the CMU CL system, which was
9 ;;;; written at Carnegie Mellon University and released into the
10 ;;;; public domain. The software is in the public domain and is
11 ;;;; provided with absolutely no warranty. See the COPYING and CREDITS
12 ;;;; files for more information.
16 ;;; FIXME: Doesn't this belong somewhere else, like early-c.lisp?
17 (declaim (special *constants* *free-vars* *component-being-compiled*
18 *code-vector* *next-location* *result-fixups*
19 *free-funs* *source-paths*
20 *seen-blocks* *seen-funs* *list-conflicts-table*
21 *continuation-number* *continuation-numbers*
22 *number-continuations* *tn-id* *tn-ids* *id-tns*
23 *label-ids* *label-id* *id-labels*
24 *undefined-warnings* *compiler-error-count*
25 *compiler-warning-count* *compiler-style-warning-count*
27 *compiler-error-bailout*
28 #!+sb-show *compiler-trace-output*
29 *last-source-context* *last-original-source*
30 *last-source-form* *last-format-string* *last-format-args*
31 *last-message-count* *lexenv*))
33 (defvar *check-consistency* nil)
34 (defvar *all-components*)
36 ;;; Bind this to a stream to capture various internal debugging output.
37 (defvar *compiler-trace-output* nil)
39 ;;; The current block compilation state. These are initialized to the
40 ;;; :BLOCK-COMPILE and :ENTRY-POINTS arguments that COMPILE-FILE was
43 ;;; *BLOCK-COMPILE-ARG* holds the original value of the :BLOCK-COMPILE
44 ;;; argument, which overrides any internal declarations.
45 (defvar *block-compile*)
46 (defvar *block-compile-arg*)
47 (declaim (type (member nil t :specified) *block-compile* *block-compile-arg*))
48 (defvar *entry-points*)
49 (declaim (list *entry-points*))
51 ;;; When block compiling, used by PROCESS-FORM to accumulate top level
52 ;;; lambdas resulting from compiling subforms. (In reverse order.)
53 (defvar *toplevel-lambdas*)
54 (declaim (list *toplevel-lambdas*))
56 (defvar sb!xc:*compile-verbose* t
58 "The default for the :VERBOSE argument to COMPILE-FILE.")
59 (defvar sb!xc:*compile-print* t
61 "The default for the :PRINT argument to COMPILE-FILE.")
62 (defvar *compile-progress* nil
64 "When this is true, the compiler prints to *ERROR-OUTPUT* progress
65 information about the phases of compilation of each function. (This
66 is useful mainly in large block compilations.)")
68 (defvar sb!xc:*compile-file-pathname* nil
70 "The defaulted pathname of the file currently being compiled, or NIL if not
72 (defvar sb!xc:*compile-file-truename* nil
74 "The TRUENAME of the file currently being compiled, or NIL if not
77 (declaim (type (or pathname null)
78 sb!xc:*compile-file-pathname*
79 sb!xc:*compile-file-truename*))
81 ;;; the SOURCE-INFO structure for the current compilation. This is
82 ;;; null globally to indicate that we aren't currently in any
83 ;;; identifiable compilation.
84 (defvar *source-info* nil)
86 ;;; This is true if we are within a WITH-COMPILATION-UNIT form (which
87 ;;; normally causes nested uses to be no-ops).
88 (defvar *in-compilation-unit* nil)
90 ;;; Count of the number of compilation units dynamically enclosed by
91 ;;; the current active WITH-COMPILATION-UNIT that were unwound out of.
92 (defvar *aborted-compilation-unit-count*)
94 ;;; Mumble conditional on *COMPILE-PROGRESS*.
95 (defun maybe-mumble (&rest foo)
96 (when *compile-progress*
97 (compiler-mumble "~&")
98 (pprint-logical-block (*error-output* nil :per-line-prefix "; ")
99 (apply #'compiler-mumble foo))))
101 (deftype object () '(or fasl-output core-object null))
103 (defvar *compile-object* nil)
104 (declaim (type object *compile-object*))
106 ;;;; WITH-COMPILATION-UNIT and WITH-COMPILATION-VALUES
108 (defmacro sb!xc:with-compilation-unit (options &body body)
110 "WITH-COMPILATION-UNIT ({Key Value}*) Form*
111 This form affects compilations that take place within its dynamic extent. It
112 is intended to be wrapped around the compilation of all files in the same
113 system. These keywords are defined:
114 :OVERRIDE Boolean-Form
115 One of the effects of this form is to delay undefined warnings
116 until the end of the form, instead of giving them at the end of each
117 compilation. If OVERRIDE is NIL (the default), then the outermost
118 WITH-COMPILATION-UNIT form grabs the undefined warnings. Specifying
119 OVERRIDE true causes that form to grab any enclosed warnings, even if
120 it is enclosed by another WITH-COMPILATION-UNIT."
121 `(%with-compilation-unit (lambda () ,@body) ,@options))
123 (defun %with-compilation-unit (fn &key override)
124 (let ((succeeded-p nil))
125 (if (and *in-compilation-unit* (not override))
126 ;; Inside another WITH-COMPILATION-UNIT, a WITH-COMPILATION-UNIT is
127 ;; ordinarily (unless OVERRIDE) basically a no-op.
129 (multiple-value-prog1 (funcall fn) (setf succeeded-p t))
131 (incf *aborted-compilation-unit-count*)))
132 ;; FIXME: Now *COMPILER-FOO-COUNT* stuff is bound in more than
133 ;; one place. If we can get rid of the IR1 interpreter, this
134 ;; should be easier to clean up.
135 (let ((*aborted-compilation-unit-count* 0)
136 (*compiler-error-count* 0)
137 (*compiler-warning-count* 0)
138 (*compiler-style-warning-count* 0)
139 (*compiler-note-count* 0)
140 (*undefined-warnings* nil)
141 (*in-compilation-unit* t))
142 (handler-bind ((parse-unknown-type
144 (note-undefined-reference
145 (parse-unknown-type-specifier c)
148 (multiple-value-prog1 (funcall fn) (setf succeeded-p t))
150 (incf *aborted-compilation-unit-count*))
151 (summarize-compilation-unit (not succeeded-p))))))))
153 ;;; This is to be called at the end of a compilation unit. It signals
154 ;;; any residual warnings about unknown stuff, then prints the total
155 ;;; error counts. ABORT-P should be true when the compilation unit was
156 ;;; aborted by throwing out. ABORT-COUNT is the number of dynamically
157 ;;; enclosed nested compilation units that were aborted.
158 (defun summarize-compilation-unit (abort-p)
160 (handler-bind ((style-warning #'compiler-style-warning-handler)
161 (warning #'compiler-warning-handler))
163 (let ((undefs (sort *undefined-warnings* #'string<
165 (let ((x (undefined-warning-name x)))
168 (prin1-to-string x)))))))
169 (dolist (undef undefs)
170 (let ((name (undefined-warning-name undef))
171 (kind (undefined-warning-kind undef))
172 (warnings (undefined-warning-warnings undef))
173 (undefined-warning-count (undefined-warning-count undef)))
174 (dolist (*compiler-error-context* warnings)
175 (compiler-style-warn "undefined ~(~A~): ~S" kind name))
176 (let ((warn-count (length warnings)))
177 (when (and warnings (> undefined-warning-count warn-count))
178 (let ((more (- undefined-warning-count warn-count)))
180 "~W more use~:P of undefined ~(~A~) ~S"
183 (dolist (kind '(:variable :function :type))
184 (let ((summary (mapcar #'undefined-warning-name
185 (remove kind undefs :test-not #'eq
186 :key #'undefined-warning-kind))))
189 "~:[This ~(~A~) is~;These ~(~A~)s are~] undefined:~
190 ~% ~{~<~% ~1:;~S~>~^ ~}"
191 (cdr summary) kind summary)))))))
193 (unless (and (not abort-p)
194 (zerop *aborted-compilation-unit-count*)
195 (zerop *compiler-error-count*)
196 (zerop *compiler-warning-count*)
197 (zerop *compiler-style-warning-count*)
198 (zerop *compiler-note-count*))
199 (format *error-output* "~&")
200 (pprint-logical-block (*error-output* nil :per-line-prefix "; ")
201 (compiler-mumble "compilation unit ~:[finished~;aborted~]~
202 ~[~:;~:*~& caught ~W fatal ERROR condition~:P~]~
203 ~[~:;~:*~& caught ~W ERROR condition~:P~]~
204 ~[~:;~:*~& caught ~W WARNING condition~:P~]~
205 ~[~:;~:*~& caught ~W STYLE-WARNING condition~:P~]~
206 ~[~:;~:*~& printed ~W note~:P~]"
208 *aborted-compilation-unit-count*
209 *compiler-error-count*
210 *compiler-warning-count*
211 *compiler-style-warning-count*
212 *compiler-note-count*)))
213 (format *error-output* "~&"))
215 ;;; Evaluate BODY, then return (VALUES BODY-VALUE WARNINGS-P
216 ;;; FAILURE-P), where BODY-VALUE is the first value of the body, and
217 ;;; WARNINGS-P and FAILURE-P are as in CL:COMPILE or CL:COMPILE-FILE.
218 ;;; This also wraps up WITH-IR1-NAMESPACE functionality.
219 (defmacro with-compilation-values (&body body)
221 (let ((*warnings-p* nil)
223 (values (progn ,@body)
227 ;;;; component compilation
229 (defparameter *max-optimize-iterations* 3 ; ARB
231 "The upper limit on the number of times that we will consecutively do IR1
232 optimization that doesn't introduce any new code. A finite limit is
233 necessary, since type inference may take arbitrarily long to converge.")
235 (defevent ir1-optimize-until-done "IR1-OPTIMIZE-UNTIL-DONE called")
236 (defevent ir1-optimize-maxed-out "hit *MAX-OPTIMIZE-ITERATIONS* limit")
238 ;;; Repeatedly optimize COMPONENT until no further optimizations can
239 ;;; be found or we hit our iteration limit. When we hit the limit, we
240 ;;; clear the component and block REOPTIMIZE flags to discourage the
241 ;;; next optimization attempt from pounding on the same code.
242 (defun ir1-optimize-until-done (component)
243 (declare (type component component))
245 (event ir1-optimize-until-done)
247 (cleared-reanalyze nil))
249 (when (component-reanalyze component)
251 (setq cleared-reanalyze t)
252 (setf (component-reanalyze component) nil))
253 (setf (component-reoptimize component) nil)
254 (ir1-optimize component)
255 (cond ((component-reoptimize component)
257 (when (= count *max-optimize-iterations*)
259 (cond ((retry-delayed-ir1-transforms :optimize)
263 (event ir1-optimize-maxed-out)
264 (setf (component-reoptimize component) nil)
265 (do-blocks (block component)
266 (setf (block-reoptimize block) nil))
268 ((retry-delayed-ir1-transforms :optimize)
275 (when cleared-reanalyze
276 (setf (component-reanalyze component) t)))
279 (defparameter *constraint-propagate* t)
281 ;;; KLUDGE: This was bumped from 5 to 10 in a DTC patch ported by MNA
282 ;;; from CMU CL into sbcl-0.6.11.44, the same one which allowed IR1
283 ;;; transforms to be delayed. Either DTC or MNA or both didn't explain
284 ;;; why, and I don't know what the rationale was. -- WHN 2001-04-28
286 ;;; FIXME: It would be good to document why it's important to have a
287 ;;; large value here, and what the drawbacks of an excessively large
288 ;;; value are; and it might also be good to make it depend on
289 ;;; optimization policy.
290 (defparameter *reoptimize-after-type-check-max* 10)
292 (defevent reoptimize-maxed-out
293 "*REOPTIMIZE-AFTER-TYPE-CHECK-MAX* exceeded.")
295 ;;; Iterate doing FIND-DFO until no new dead code is discovered.
296 (defun dfo-as-needed (component)
297 (declare (type component component))
298 (when (component-reanalyze component)
302 (unless (component-reanalyze component)
308 ;;; Do all the IR1 phases for a non-top-level component.
309 (defun ir1-phases (component)
310 (declare (type component component))
311 (aver-live-component component)
312 (let ((*constraint-number* 0)
314 (*delayed-ir1-transforms* nil))
315 (declare (special *constraint-number* *delayed-ir1-transforms*))
317 (ir1-optimize-until-done component)
318 (when (or (component-new-functionals component)
319 (component-reanalyze-functionals component))
320 (maybe-mumble "locall ")
321 (locall-analyze-component component))
322 (dfo-as-needed component)
323 (when *constraint-propagate*
324 (maybe-mumble "constraint ")
325 (constraint-propagate component))
326 (when (retry-delayed-ir1-transforms :constraint)
327 (maybe-mumble "Rtran "))
328 (flet ((want-reoptimization-p ()
329 (or (component-reoptimize component)
330 (component-reanalyze component)
331 (component-new-functionals component)
332 (component-reanalyze-functionals component))))
333 (unless (and (want-reoptimization-p)
334 ;; We delay the generation of type checks until
335 ;; the type constraints have had time to
336 ;; propagate, else the compiler can confuse itself.
337 (< loop-count (- *reoptimize-after-type-check-max* 4)))
338 (maybe-mumble "type ")
339 (generate-type-checks component)
340 (unless (want-reoptimization-p)
342 (when (>= loop-count *reoptimize-after-type-check-max*)
343 (maybe-mumble "[reoptimize limit]")
344 (event reoptimize-maxed-out)
348 (ir1-finalize component)
351 (defun %compile-component (component)
352 (let ((*code-segment* nil)
354 (maybe-mumble "GTN ")
355 (gtn-analyze component)
356 (maybe-mumble "LTN ")
357 (ltn-analyze component)
358 (dfo-as-needed component)
359 (maybe-mumble "control ")
360 (control-analyze component #'make-ir2-block)
362 (when (ir2-component-values-receivers (component-info component))
363 (maybe-mumble "stack ")
364 (stack-analyze component)
365 ;; Assign BLOCK-NUMBER for any cleanup blocks introduced by
366 ;; stack analysis. There shouldn't be any unreachable code after
367 ;; control, so this won't delete anything.
368 (dfo-as-needed component))
372 (maybe-mumble "IR2tran ")
374 (entry-analyze component)
375 (ir2-convert component)
377 (when (policy *lexenv* (>= speed compilation-speed))
378 (maybe-mumble "copy ")
379 (copy-propagate component))
381 (select-representations component)
383 (when *check-consistency*
384 (maybe-mumble "check2 ")
385 (check-ir2-consistency component))
387 (delete-unreferenced-tns component)
389 (maybe-mumble "life ")
390 (lifetime-analyze component)
392 (when *compile-progress*
393 (compiler-mumble "") ; Sync before doing more output.
394 (pre-pack-tn-stats component *error-output*))
396 (when *check-consistency*
397 (maybe-mumble "check-life ")
398 (check-life-consistency component))
400 (maybe-mumble "pack ")
403 (when *check-consistency*
404 (maybe-mumble "check-pack ")
405 (check-pack-consistency component))
407 (when *compiler-trace-output*
408 (describe-component component *compiler-trace-output*)
409 (describe-ir2-component component *compiler-trace-output*))
411 (maybe-mumble "code ")
412 (multiple-value-bind (code-length trace-table fixups)
413 (generate-code component)
415 (when *compiler-trace-output*
416 (format *compiler-trace-output*
417 "~|~%disassembly of code for ~S~2%" component)
418 (sb!disassem:disassemble-assem-segment *code-segment*
419 *compiler-trace-output*))
421 (etypecase *compile-object*
423 (maybe-mumble "fasl")
424 (fasl-dump-component component
431 (maybe-mumble "core")
432 (make-core-component component
440 ;; We're done, so don't bother keeping anything around.
441 (setf (component-info component) :dead)
445 ;;; Delete components with no external entry points before we try to
446 ;;; generate code. Unreachable closures can cause IR2 conversion to
447 ;;; puke on itself, since it is the reference to the closure which
448 ;;; normally causes the components to be combined.
449 (defun delete-if-no-entries (component)
450 (dolist (fun (component-lambdas component) (delete-component component))
451 (when (functional-has-external-references-p fun)
453 (case (functional-kind fun)
456 (unless (every (lambda (ref)
457 (eq (node-component ref) component))
461 (defun compile-component (component)
463 ;; miscellaneous sanity checks
465 ;; FIXME: These are basically pretty wimpy compared to the checks done
466 ;; by the old CHECK-IR1-CONSISTENCY code. It would be really nice to
467 ;; make those internal consistency checks work again and use them.
468 (aver-live-component component)
469 (do-blocks (block component)
470 (aver (eql (block-component block) component)))
471 (dolist (lambda (component-lambdas component))
472 ;; sanity check to prevent weirdness from propagating insidiously as
473 ;; far from its root cause as it did in bug 138: Make sure that
474 ;; thing-to-COMPONENT links are consistent.
475 (aver (eql (lambda-component lambda) component))
476 (aver (eql (node-component (lambda-bind lambda)) component)))
478 (let* ((*component-being-compiled* component))
479 (when sb!xc:*compile-print*
480 (compiler-mumble "~&; compiling ~A: " (component-name component)))
482 (ir1-phases component)
484 ;; FIXME: What is MAYBE-MUMBLE for? Do we need it any more?
485 (maybe-mumble "env ")
486 (physenv-analyze component)
487 (dfo-as-needed component)
489 (delete-if-no-entries component)
491 (unless (eq (block-next (component-head component))
492 (component-tail component))
493 (%compile-component component)))
495 (clear-constant-info)
497 (when sb!xc:*compile-print*
498 (compiler-mumble "~&"))
502 ;;;; clearing global data structures
504 ;;;; FIXME: Is it possible to get rid of this stuff, getting rid of
505 ;;;; global data structures entirely when possible and consing up the
506 ;;;; others from scratch instead of clearing and reusing them?
508 ;;; Clear the INFO in constants in the *FREE-VARS*, etc. In
509 ;;; addition to allowing stuff to be reclaimed, this is required for
510 ;;; correct assignment of constant offsets, since we need to assign a
511 ;;; new offset for each component. We don't clear the FUNCTIONAL-INFO
512 ;;; slots, since they are used to keep track of functions across
513 ;;; component boundaries.
514 (defun clear-constant-info ()
515 (maphash (lambda (k v)
517 (setf (leaf-info v) nil))
519 (maphash (lambda (k v)
522 (setf (leaf-info v) nil)))
526 ;;; Blow away the REFS for all global variables, and let COMPONENT
528 (defun clear-ir1-info (component)
529 (declare (type component component))
531 (maphash (lambda (k v)
535 (delete-if #'here-p (leaf-refs v)))
536 (when (basic-var-p v)
537 (setf (basic-var-sets v)
538 (delete-if #'here-p (basic-var-sets v))))))
541 (eq (node-component x) component)))
547 ;;; Clear global variables used by the compiler.
549 ;;; FIXME: It seems kinda nasty and unmaintainable to have to do this,
550 ;;; and it adds overhead even when people aren't using the compiler.
551 ;;; Perhaps we could make these global vars unbound except when
552 ;;; actually in use, so that this function could go away.
553 (defun clear-stuff (&optional (debug-too t))
555 ;; Clear global tables.
556 (when (boundp '*free-funs*)
557 (clrhash *free-funs*)
558 (clrhash *free-vars*)
559 (clrhash *constants*))
561 ;; Clear debug counters and tables.
562 (clrhash *seen-blocks*)
563 (clrhash *seen-funs*)
564 (clrhash *list-conflicts-table*)
567 (clrhash *continuation-numbers*)
568 (clrhash *number-continuations*)
569 (setq *continuation-number* 0)
573 (clrhash *label-ids*)
574 (clrhash *id-labels*)
577 ;; Clear some PACK data structures (for GC purposes only).
578 (aver (not *in-pack*))
579 (dolist (sb *backend-sb-list*)
580 (when (finite-sb-p sb)
581 (fill (finite-sb-live-tns sb) nil))))
583 ;; (Note: The CMU CL code used to set CL::*GENSYM-COUNTER* to zero here.
584 ;; Superficially, this seemed harmful -- the user could reasonably be
585 ;; surprised if *GENSYM-COUNTER* turned back to zero when something was
586 ;; compiled. A closer inspection showed that this actually turned out to be
587 ;; harmless in practice, because CLEAR-STUFF was only called from within
588 ;; forms which bound CL::*GENSYM-COUNTER* to zero. However, this means that
589 ;; even though zeroing CL::*GENSYM-COUNTER* here turned out to be harmless in
590 ;; practice, it was also useless in practice. So we don't do it any more.)
596 ;;; Print out some useful info about COMPONENT to STREAM.
597 (defun describe-component (component *standard-output*)
598 (declare (type component component))
599 (format t "~|~%;;;; component: ~S~2%" (component-name component))
600 (print-blocks component)
603 (defun describe-ir2-component (component *standard-output*)
604 (format t "~%~|~%;;;; IR2 component: ~S~2%" (component-name component))
605 (format t "entries:~%")
606 (dolist (entry (ir2-component-entries (component-info component)))
607 (format t "~4TL~D: ~S~:[~; [closure]~]~%"
608 (label-id (entry-info-offset entry))
609 (entry-info-name entry)
610 (entry-info-closure-p entry)))
612 (pre-pack-tn-stats component *standard-output*)
614 (print-ir2-blocks component)
620 ;;;; When reading from a file, we have to keep track of some source
621 ;;;; information. We also exploit our ability to back up for printing
622 ;;;; the error context and for recovering from errors.
624 ;;;; The interface we provide to this stuff is the stream-oid
625 ;;;; SOURCE-INFO structure. The bookkeeping is done as a side effect
626 ;;;; of getting the next source form.
628 ;;; A FILE-INFO structure holds all the source information for a
630 (defstruct (file-info (:copier nil))
631 ;; If a file, the truename of the corresponding source file. If from
632 ;; a Lisp form, :LISP. If from a stream, :STREAM.
633 (name (missing-arg) :type (or pathname (member :lisp :stream)))
634 ;; the defaulted, but not necessarily absolute file name (i.e. prior
635 ;; to TRUENAME call.) Null if not a file. This is used to set
636 ;; *COMPILE-FILE-PATHNAME*, and if absolute, is dumped in the
638 (untruename nil :type (or pathname null))
639 ;; the file's write date (if relevant)
640 (write-date nil :type (or unsigned-byte null))
641 ;; the source path root number of the first form in this file (i.e.
642 ;; the total number of forms converted previously in this
644 (source-root 0 :type unsigned-byte)
645 ;; parallel vectors containing the forms read out of the file and
646 ;; the file positions that reading of each form started at (i.e. the
647 ;; end of the previous form)
648 (forms (make-array 10 :fill-pointer 0 :adjustable t) :type (vector t))
649 (positions (make-array 10 :fill-pointer 0 :adjustable t) :type (vector t)))
651 ;;; The SOURCE-INFO structure provides a handle on all the source
652 ;;; information for an entire compilation.
653 (defstruct (source-info
654 #-no-ansi-print-object
655 (:print-object (lambda (s stream)
656 (print-unreadable-object (s stream :type t))))
658 ;; the UT that compilation started at
659 (start-time (get-universal-time) :type unsigned-byte)
660 ;; the FILE-INFO structure for this compilation
661 (file-info nil :type (or file-info null))
662 ;; the stream that we are using to read the FILE-INFO, or NIL if
663 ;; no stream has been opened yet
664 (stream nil :type (or stream null)))
666 ;;; Given a pathname, return a SOURCE-INFO structure.
667 (defun make-file-source-info (file)
668 (let ((file-info (make-file-info :name (truename file)
670 :write-date (file-write-date file))))
672 (make-source-info :file-info file-info)))
674 ;;; Return a SOURCE-INFO to describe the incremental compilation of FORM.
675 (defun make-lisp-source-info (form)
676 (make-source-info :start-time (get-universal-time)
677 :file-info (make-file-info :name :lisp
681 ;;; Return a SOURCE-INFO which will read from STREAM.
682 (defun make-stream-source-info (stream)
683 (let ((file-info (make-file-info :name :stream)))
684 (make-source-info :file-info file-info
687 ;;; Return a form read from STREAM; or for EOF use the trick,
688 ;;; popularized by Kent Pitman, of returning STREAM itself. If an
689 ;;; error happens, then convert it to standard abort-the-compilation
690 ;;; error condition (possibly recording some extra location
692 (defun read-for-compile-file (stream position)
693 (handler-case (read stream nil stream)
694 (reader-error (condition)
695 (error 'input-error-in-compile-file
697 ;; We don't need to supply :POSITION here because
698 ;; READER-ERRORs already know their position in the file.
700 ;; ANSI, in its wisdom, says that READ should return END-OF-FILE
701 ;; (and that this is not a READER-ERROR) when it encounters end of
702 ;; file in the middle of something it's trying to read.
703 (end-of-file (condition)
704 (error 'input-error-in-compile-file
706 ;; We need to supply :POSITION here because the END-OF-FILE
707 ;; condition doesn't carry the position that the user
708 ;; probably cares about, where the failed READ began.
709 :position position))))
711 ;;; If STREAM is present, return it, otherwise open a stream to the
712 ;;; current file. There must be a current file.
714 ;;; FIXME: This is probably an unnecessarily roundabout way to do
715 ;;; things now that we process a single file in COMPILE-FILE (unlike
716 ;;; the old CMU CL code, which accepted multiple files). Also, the old
718 ;;; When we open a new file, we also reset *PACKAGE* and policy.
719 ;;; This gives the effect of rebinding around each file.
720 ;;; which doesn't seem to be true now. Check to make sure that if
721 ;;; such rebinding is necessary, it's still done somewhere.
722 (defun get-source-stream (info)
723 (declare (type source-info info))
724 (or (source-info-stream info)
725 (let* ((file-info (source-info-file-info info))
726 (name (file-info-name file-info)))
727 (setf sb!xc:*compile-file-truename* name
728 sb!xc:*compile-file-pathname* (file-info-untruename file-info)
729 (source-info-stream info) (open name :direction :input)))))
731 ;;; Close the stream in INFO if it is open.
732 (defun close-source-info (info)
733 (declare (type source-info info))
734 (let ((stream (source-info-stream info)))
735 (when stream (close stream)))
736 (setf (source-info-stream info) nil)
739 ;;; Read and compile the source file.
740 (defun sub-sub-compile-file (info)
741 (let* ((file-info (source-info-file-info info))
742 (stream (get-source-stream info)))
744 (let* ((pos (file-position stream))
745 (form (read-for-compile-file stream pos)))
746 (if (eq form stream) ; i.e., if EOF
748 (let* ((forms (file-info-forms file-info))
749 (current-idx (+ (fill-pointer forms)
750 (file-info-source-root file-info))))
751 (vector-push-extend form forms)
752 (vector-push-extend pos (file-info-positions file-info))
753 (find-source-paths form current-idx)
754 (process-toplevel-form form
755 `(original-source-start 0 ,current-idx)
758 ;;; Return the INDEX'th source form read from INFO and the position
759 ;;; where it was read.
760 (defun find-source-root (index info)
761 (declare (type index index) (type source-info info))
762 (let ((file-info (source-info-file-info info)))
763 (values (aref (file-info-forms file-info) index)
764 (aref (file-info-positions file-info) index))))
766 ;;;; processing of top level forms
768 ;;; This is called by top level form processing when we are ready to
769 ;;; actually compile something. If *BLOCK-COMPILE* is T, then we still
770 ;;; convert the form, but delay compilation, pushing the result on
771 ;;; *TOPLEVEL-LAMBDAS* instead.
772 (defun convert-and-maybe-compile (form path)
773 (declare (list path))
774 (let* ((*lexenv* (make-lexenv :policy *policy*))
775 (tll (ir1-toplevel form path nil)))
776 (cond ((eq *block-compile* t) (push tll *toplevel-lambdas*))
777 (t (compile-toplevel (list tll) nil)))))
779 ;;; Macroexpand FORM in the current environment with an error handler.
780 ;;; We only expand one level, so that we retain all the intervening
781 ;;; forms in the source path.
782 (defun preprocessor-macroexpand-1 (form)
783 (handler-case (sb!xc:macroexpand-1 form *lexenv*)
785 (compiler-error "(during macroexpansion of ~A)~%~A"
786 (let ((*print-level* 1)
788 (format nil "~S" form))
791 ;;; Process a PROGN-like portion of a top level form. FORMS is a list of
792 ;;; the forms, and PATH is the source path of the FORM they came out of.
793 ;;; COMPILE-TIME-TOO is as in ANSI "3.2.3.1 Processing of Top Level Forms".
794 (defun process-toplevel-progn (forms path compile-time-too)
795 (declare (list forms) (list path))
797 (process-toplevel-form form path compile-time-too)))
799 ;;; Process a top level use of LOCALLY, or anything else (e.g.
800 ;;; MACROLET) at top level which has declarations and ordinary forms.
801 ;;; We parse declarations and then recursively process the body.
802 (defun process-toplevel-locally (body path compile-time-too)
803 (declare (list path))
804 (multiple-value-bind (forms decls) (sb!sys:parse-body body nil)
806 (process-decls decls nil nil (make-continuation)))
807 ;; Binding *POLICY* is pretty much of a hack, since it
808 ;; causes LOCALLY to "capture" enclosed proclamations. It
809 ;; is necessary because CONVERT-AND-MAYBE-COMPILE uses the
810 ;; value of *POLICY* as the policy. The need for this hack
811 ;; is due to the quirk that there is no way to represent in
812 ;; a POLICY that an optimize quality came from the default.
814 ;; FIXME: Ideally, something should be done so that DECLAIM
815 ;; inside LOCALLY works OK. Failing that, at least we could
816 ;; issue a warning instead of silently screwing up.
817 (*policy* (lexenv-policy *lexenv*)))
818 (process-toplevel-progn forms path compile-time-too))))
820 ;;; Parse an EVAL-WHEN situations list, returning three flags,
821 ;;; (VALUES COMPILE-TOPLEVEL LOAD-TOPLEVEL EXECUTE), indicating
822 ;;; the types of situations present in the list.
823 (defun parse-eval-when-situations (situations)
824 (when (or (not (listp situations))
825 (set-difference situations
832 (compiler-error "bad EVAL-WHEN situation list: ~S" situations))
833 (let ((deprecated-names (intersection situations '(compile load eval))))
834 (when deprecated-names
835 (style-warn "using deprecated EVAL-WHEN situation names~{ ~S~}"
837 (values (intersection '(:compile-toplevel compile)
839 (intersection '(:load-toplevel load) situations)
840 (intersection '(:execute eval) situations)))
843 ;;; utilities for extracting COMPONENTs of FUNCTIONALs
844 (defun functional-components (f)
845 (declare (type functional f))
847 (clambda (list (lambda-component f)))
848 (optional-dispatch (let ((result nil))
849 (labels ((frob (clambda)
850 (pushnew (lambda-component clambda)
852 (maybe-frob (maybe-clambda)
854 (frob maybe-clambda))))
855 (mapc #'frob (optional-dispatch-entry-points f))
856 (maybe-frob (optional-dispatch-more-entry f))
857 (maybe-frob (optional-dispatch-main-entry f)))))))
859 (defun make-functional-from-toplevel-lambda (definition
863 ;; I'd thought NIL should
864 ;; work, but it doesn't.
867 (let* ((*current-path* path)
868 (component (make-empty-component))
869 (*current-component* component))
870 (setf (component-name component)
871 (debug-namify "~S initial component" name))
872 (setf (component-kind component) :initial)
873 (let* ((locall-fun (ir1-convert-lambda
875 :debug-name (debug-namify "top level local call ~S"
877 (fun (ir1-convert-lambda (make-xep-lambda-expression locall-fun)
878 :source-name (or name '.anonymous.)
879 :debug-name (unless name
881 (setf (functional-entry-fun fun) locall-fun
882 (functional-kind fun) :external
883 (functional-has-external-references-p fun) t)
886 ;;; Compile LAMBDA-EXPRESSION into *COMPILE-OBJECT*, returning a
887 ;;; description of the result.
888 ;;; * If *COMPILE-OBJECT* is a CORE-OBJECT, then write the function
889 ;;; into core and return the compiled FUNCTION value.
890 ;;; * If *COMPILE-OBJECT* is a fasl file, then write the function
891 ;;; into the fasl file and return a dump handle.
893 ;;; If NAME is provided, then we try to use it as the name of the
894 ;;; function for debugging/diagnostic information.
895 (defun %compile (lambda-expression
900 ;; This magical idiom seems to be the appropriate
901 ;; path for compiling standalone LAMBDAs, judging
902 ;; from the CMU CL code and experiment, so it's a
903 ;; nice default for things where we don't have a
904 ;; real source path (as in e.g. inside CL:COMPILE).
905 '(original-source-start 0 0)))
906 (unless (or (null name) (legal-fun-name-p name))
907 (error "not a legal function name: ~S" name))
908 (let* ((*lexenv* (make-lexenv :policy *policy*))
909 (fun (make-functional-from-toplevel-lambda lambda-expression
913 ;; FIXME: The compile-it code from here on is sort of a
914 ;; twisted version of the code in COMPILE-TOPLEVEL. It'd be
915 ;; better to find a way to share the code there; or
916 ;; alternatively, to use this code to replace the code there.
917 ;; (The second alternative might be pretty easy if we used
918 ;; the :LOCALL-ONLY option to IR1-FOR-LAMBDA. Then maybe the
919 ;; whole FUNCTIONAL-KIND=:TOPLEVEL case could go away..)
921 (locall-analyze-clambdas-until-done (list fun))
923 (multiple-value-bind (components-from-dfo top-components hairy-top)
924 (find-initial-dfo (list fun))
926 (let ((*all-components* (append components-from-dfo top-components)))
927 ;; FIXME: This is more monkey see monkey do based on CMU CL
928 ;; code. If anyone figures out why to only prescan HAIRY-TOP
929 ;; and TOP-COMPONENTS here, instead of *ALL-COMPONENTS* or
930 ;; some other combination of results from FIND-INITIAL-VALUES,
931 ;; it'd be good to explain it.
932 (mapc #'preallocate-physenvs-for-toplevelish-lambdas hairy-top)
933 (mapc #'preallocate-physenvs-for-toplevelish-lambdas top-components)
934 (dolist (component-from-dfo components-from-dfo)
935 (compile-component component-from-dfo)
936 (replace-toplevel-xeps component-from-dfo)))
939 (let ((entry-table (etypecase *compile-object*
940 (fasl-output (fasl-output-entry-table
942 (core-object (core-object-entry-table
943 *compile-object*)))))
944 (multiple-value-bind (result found-p)
945 (gethash (leaf-info fun) entry-table)
948 (mapc #'clear-ir1-info components-from-dfo)
951 (defun process-toplevel-cold-fset (name lambda-expression path)
952 (unless (producing-fasl-file)
953 (error "can't COLD-FSET except in a fasl file"))
954 (unless (legal-fun-name-p name)
955 (error "not a legal function name: ~S" name))
956 (fasl-dump-cold-fset name
957 (%compile lambda-expression
964 ;;; Process a top level FORM with the specified source PATH.
965 ;;; * If this is a magic top level form, then do stuff.
966 ;;; * If this is a macro, then expand it.
967 ;;; * Otherwise, just compile it.
969 ;;; COMPILE-TIME-TOO is as defined in ANSI
970 ;;; "3.2.3.1 Processing of Top Level Forms".
971 (defun process-toplevel-form (form path compile-time-too)
973 (declare (list path))
975 (catch 'process-toplevel-form-error-abort
976 (let* ((path (or (gethash form *source-paths*) (cons form path)))
977 (*compiler-error-bailout*
979 (convert-and-maybe-compile
980 `(error "execution of a form compiled with errors:~% ~S"
983 (throw 'process-toplevel-form-error-abort nil))))
986 ;; (There are no EVAL-WHEN issues in the ATOM case until
987 ;; SBCL gets smart enough to handle global
988 ;; DEFINE-SYMBOL-MACRO.)
989 (convert-and-maybe-compile form path)
990 (flet ((need-at-least-one-arg (form)
992 (compiler-error "~S form is too short: ~S"
996 ;; In the cross-compiler, top level COLD-FSET arranges
997 ;; for static linking at cold init time.
1000 (aver (not compile-time-too))
1001 (destructuring-bind (cold-fset fun-name lambda-expression) form
1002 (declare (ignore cold-fset))
1003 (process-toplevel-cold-fset fun-name
1006 ((eval-when macrolet symbol-macrolet);things w/ 1 arg before body
1007 (need-at-least-one-arg form)
1008 (destructuring-bind (special-operator magic &rest body) form
1009 (ecase special-operator
1011 ;; CT, LT, and E here are as in Figure 3-7 of ANSI
1012 ;; "3.2.3.1 Processing of Top Level Forms".
1013 (multiple-value-bind (ct lt e)
1014 (parse-eval-when-situations magic)
1015 (let ((new-compile-time-too (or ct
1016 (and compile-time-too
1018 (cond (lt (process-toplevel-progn
1019 body path new-compile-time-too))
1020 (new-compile-time-too (eval
1021 `(progn ,@body)))))))
1023 (funcall-in-macrolet-lexenv
1026 (process-toplevel-locally body
1028 compile-time-too))))
1030 (funcall-in-symbol-macrolet-lexenv
1033 (process-toplevel-locally body
1035 compile-time-too)))))))
1037 (process-toplevel-locally (rest form) path compile-time-too))
1039 (process-toplevel-progn (rest form) path compile-time-too))
1040 ;; When we're cross-compiling, consider: what should we
1041 ;; do when we hit e.g.
1042 ;; (EVAL-WHEN (:COMPILE-TOPLEVEL)
1043 ;; (DEFUN FOO (X) (+ 7 X)))?
1044 ;; DEFUN has a macro definition in the cross-compiler,
1045 ;; and a different macro definition in the target
1046 ;; compiler. The only sensible thing is to use the
1047 ;; target compiler's macro definition, since the
1048 ;; cross-compiler's macro is in general into target
1049 ;; functions which can't meaningfully be executed at
1050 ;; cross-compilation time. So make sure we do the EVAL
1051 ;; here, before we macroexpand.
1053 ;; Then things get even dicier with something like
1054 ;; (DEFCONSTANT-EQX SB!XC:LAMBDA-LIST-KEYWORDS ..)
1055 ;; where we have to make sure that we don't uncross
1056 ;; the SB!XC: prefix before we do EVAL, because otherwise
1057 ;; we'd be trying to redefine the cross-compilation host's
1060 ;; (Isn't it fun to cross-compile Common Lisp?:-)
1063 (when compile-time-too
1064 (eval form)) ; letting xc host EVAL do its own macroexpansion
1065 (let* (;; (We uncross the operator name because things
1066 ;; like SB!XC:DEFCONSTANT and SB!XC:DEFTYPE
1067 ;; should be equivalent to their CL: counterparts
1068 ;; when being compiled as target code. We leave
1069 ;; the rest of the form uncrossed because macros
1070 ;; might yet expand into EVAL-WHEN stuff, and
1071 ;; things inside EVAL-WHEN can't be uncrossed
1072 ;; until after we've EVALed them in the
1073 ;; cross-compilation host.)
1074 (slightly-uncrossed (cons (uncross (first form))
1076 (expanded (preprocessor-macroexpand-1
1077 slightly-uncrossed)))
1078 (if (eq expanded slightly-uncrossed)
1079 ;; (Now that we're no longer processing toplevel
1080 ;; forms, and hence no longer need to worry about
1081 ;; EVAL-WHEN, we can uncross everything.)
1082 (convert-and-maybe-compile expanded path)
1083 ;; (We have to demote COMPILE-TIME-TOO to NIL
1084 ;; here, no matter what it was before, since
1085 ;; otherwise we'd tend to EVAL subforms more than
1086 ;; once, because of WHEN COMPILE-TIME-TOO form
1088 (process-toplevel-form expanded path nil))))
1089 ;; When we're not cross-compiling, we only need to
1090 ;; macroexpand once, so we can follow the 1-thru-6
1091 ;; sequence of steps in ANSI's "3.2.3.1 Processing of
1092 ;; Top Level Forms".
1095 (let ((expanded (preprocessor-macroexpand-1 form)))
1096 (cond ((eq expanded form)
1097 (when compile-time-too
1099 (convert-and-maybe-compile form path))
1101 (process-toplevel-form expanded
1103 compile-time-too))))))))))
1107 ;;;; load time value support
1109 ;;;; (See EMIT-MAKE-LOAD-FORM.)
1111 ;;; Return T if we are currently producing a fasl file and hence
1112 ;;; constants need to be dumped carefully.
1113 (defun producing-fasl-file ()
1114 (fasl-output-p *compile-object*))
1116 ;;; Compile FORM and arrange for it to be called at load-time. Return
1117 ;;; the dumper handle and our best guess at the type of the object.
1118 (defun compile-load-time-value (form)
1119 (let ((lambda (compile-load-time-stuff form t)))
1121 (fasl-dump-load-time-value-lambda lambda *compile-object*)
1122 (let ((type (leaf-type lambda)))
1123 (if (fun-type-p type)
1124 (single-value-type (fun-type-returns type))
1127 ;;; Compile the FORMS and arrange for them to be called (for effect,
1128 ;;; not value) at load time.
1129 (defun compile-make-load-form-init-forms (forms)
1130 (let ((lambda (compile-load-time-stuff `(progn ,@forms) nil)))
1131 (fasl-dump-toplevel-lambda-call lambda *compile-object*)))
1133 ;;; Do the actual work of COMPILE-LOAD-TIME-VALUE or
1134 ;;; COMPILE-MAKE-LOAD-FORM-INIT-FORMS.
1135 (defun compile-load-time-stuff (form for-value)
1137 (let* ((*lexenv* (make-null-lexenv))
1138 (lambda (ir1-toplevel form *current-path* for-value)))
1139 (compile-toplevel (list lambda) t)
1142 ;;; This is called by COMPILE-TOPLEVEL when it was passed T for
1143 ;;; LOAD-TIME-VALUE-P (which happens in COMPILE-LOAD-TIME-STUFF). We
1144 ;;; don't try to combine this component with anything else and frob
1145 ;;; the name. If not in a :TOPLEVEL component, then don't bother
1146 ;;; compiling, because it was merged with a run-time component.
1147 (defun compile-load-time-value-lambda (lambdas)
1148 (aver (null (cdr lambdas)))
1149 (let* ((lambda (car lambdas))
1150 (component (lambda-component lambda)))
1151 (when (eql (component-kind component) :toplevel)
1152 (setf (component-name component) (leaf-debug-name lambda))
1153 (compile-component component)
1154 (clear-ir1-info component))))
1158 ;;; We build a list of top level lambdas, and then periodically smash
1159 ;;; them together into a single component and compile it.
1160 (defvar *pending-toplevel-lambdas*)
1162 ;;; The maximum number of top level lambdas we put in a single
1163 ;;; top level component.
1165 ;;; CMU CL 18b used this nontrivially by default (setting it to 10)
1166 ;;; but consequently suffered from the inability to execute some
1167 ;;; troublesome constructs correctly, e.g. inability to load a fasl
1168 ;;; file compiled from the source file
1169 ;;; (defpackage "FOO" (:use "CL"))
1170 ;;; (print 'foo::bar)
1171 ;;; because it would dump data-setup fops (including a FOP-PACKAGE for
1172 ;;; "FOO") for the second form before dumping the the code in the
1173 ;;; first form, or the fop to execute the code in the first form. By
1174 ;;; setting this value to 0 by default, we avoid this badness. This
1175 ;;; increases the number of toplevel form functions, and so increases
1176 ;;; the size of object files.
1178 ;;; The variable is still supported because when we are compiling the
1179 ;;; SBCL system itself, which is known not contain any troublesome
1180 ;;; constructs, we can set it to a nonzero value, which reduces the
1181 ;;; number of toplevel form objects, reducing the peak memory usage in
1182 ;;; GENESIS, which is desirable, since at least for SBCL version
1183 ;;; 0.6.7, this is the high water mark for memory usage during system
1185 (defparameter *toplevel-lambda-max* 0)
1187 (defun object-call-toplevel-lambda (tll)
1188 (declare (type functional tll))
1189 (let ((object *compile-object*))
1192 (fasl-dump-toplevel-lambda-call tll object))
1194 (core-call-toplevel-lambda tll object))
1197 ;;; Add LAMBDAS to the pending lambdas. If this leaves more than
1198 ;;; *TOPLEVEL-LAMBDA-MAX* lambdas in the list, or if FORCE-P is true,
1199 ;;; then smash the lambdas into a single component, compile it, and
1200 ;;; call the resulting function.
1201 (defun sub-compile-toplevel-lambdas (lambdas force-p)
1202 (declare (list lambdas))
1203 (setq *pending-toplevel-lambdas*
1204 (append *pending-toplevel-lambdas* lambdas))
1205 (let ((pending *pending-toplevel-lambdas*))
1207 (or (> (length pending) *toplevel-lambda-max*)
1209 (multiple-value-bind (component tll) (merge-toplevel-lambdas pending)
1210 (setq *pending-toplevel-lambdas* ())
1211 (compile-component component)
1212 (clear-ir1-info component)
1213 (object-call-toplevel-lambda tll))))
1216 ;;; Compile top level code and call the top level lambdas. We pick off
1217 ;;; top level lambdas in non-top-level components here, calling
1218 ;;; SUB-c-t-l-l on each subsequence of normal top level lambdas.
1219 (defun compile-toplevel-lambdas (lambdas force-p)
1220 (declare (list lambdas))
1221 (let ((len (length lambdas)))
1222 (flet ((loser (start)
1223 (or (position-if (lambda (x)
1224 (not (eq (component-kind
1225 (node-component (lambda-bind x)))
1230 (do* ((start 0 (1+ loser))
1231 (loser (loser start) (loser start)))
1234 (sub-compile-toplevel-lambdas nil t)))
1235 (sub-compile-toplevel-lambdas (subseq lambdas start loser)
1236 (or force-p (/= loser len)))
1237 (unless (= loser len)
1238 (object-call-toplevel-lambda (elt lambdas loser))))))
1241 ;;; Compile LAMBDAS (a list of CLAMBDAs for top level forms) into the
1244 ;;; LOAD-TIME-VALUE-P seems to control whether it's MAKE-LOAD-FORM and
1245 ;;; COMPILE-LOAD-TIME-VALUE stuff. -- WHN 20000201
1246 (defun compile-toplevel (lambdas load-time-value-p)
1247 (declare (list lambdas))
1249 (maybe-mumble "locall ")
1250 (locall-analyze-clambdas-until-done lambdas)
1252 (maybe-mumble "IDFO ")
1253 (multiple-value-bind (components top-components hairy-top)
1254 (find-initial-dfo lambdas)
1255 (let ((*all-components* (append components top-components))
1256 (toplevel-closure nil))
1257 (when *check-consistency*
1258 (maybe-mumble "[check]~%")
1259 (check-ir1-consistency *all-components*))
1261 (dolist (component (append hairy-top top-components))
1262 (when (pre-physenv-analyze-toplevel component)
1263 (setq toplevel-closure t)))
1265 (dolist (component components)
1266 (compile-component component)
1267 (when (replace-toplevel-xeps component)
1268 (setq toplevel-closure t)))
1270 (when *check-consistency*
1271 (maybe-mumble "[check]~%")
1272 (check-ir1-consistency *all-components*))
1274 (if load-time-value-p
1275 (compile-load-time-value-lambda lambdas)
1276 (compile-toplevel-lambdas lambdas toplevel-closure))
1278 (mapc #'clear-ir1-info components)
1282 ;;; Actually compile any stuff that has been queued up for block
1284 (defun finish-block-compilation ()
1285 (when *block-compile*
1286 (when *toplevel-lambdas*
1287 (compile-toplevel (nreverse *toplevel-lambdas*) nil)
1288 (setq *toplevel-lambdas* ()))
1289 (setq *block-compile* nil)
1290 (setq *entry-points* nil)))
1292 ;;; Read all forms from INFO and compile them, with output to OBJECT.
1293 ;;; Return (VALUES NIL WARNINGS-P FAILURE-P).
1294 (defun sub-compile-file (info)
1295 (declare (type source-info info))
1296 (let* ((*block-compile* *block-compile-arg*)
1297 (*package* (sane-package))
1299 (*lexenv* (make-null-lexenv))
1300 (*source-info* info)
1301 (sb!xc:*compile-file-pathname* nil)
1302 (sb!xc:*compile-file-truename* nil)
1303 (*toplevel-lambdas* ())
1304 (*pending-toplevel-lambdas* ())
1305 (*compiler-error-bailout*
1307 (compiler-mumble "~2&; fatal error, aborting compilation~%")
1308 (return-from sub-compile-file (values nil t t))))
1309 (*current-path* nil)
1310 (*last-source-context* nil)
1311 (*last-original-source* nil)
1312 (*last-source-form* nil)
1313 (*last-format-string* nil)
1314 (*last-format-args* nil)
1315 (*last-message-count* 0)
1316 ;; FIXME: Do we need this rebinding here? It's a literal
1317 ;; translation of the old CMU CL rebinding to
1318 ;; (OR *BACKEND-INFO-ENVIRONMENT* *INFO-ENVIRONMENT*),
1319 ;; and it's not obvious whether the rebinding to itself is
1320 ;; needed that SBCL doesn't need *BACKEND-INFO-ENVIRONMENT*.
1321 (*info-environment* *info-environment*)
1322 (*gensym-counter* 0))
1324 (with-compilation-values
1325 (sb!xc:with-compilation-unit ()
1328 (sub-sub-compile-file info)
1330 (finish-block-compilation)
1331 (compile-toplevel-lambdas () t)
1332 (let ((object *compile-object*))
1334 (fasl-output (fasl-dump-source-info info object))
1335 (core-object (fix-core-source-info info object))
1338 ;; Some errors are sufficiently bewildering that we just fail
1339 ;; immediately, without trying to recover and compile more of
1341 (input-error-in-compile-file (condition)
1342 (format *error-output*
1343 "~@<compilation aborted because of input error: ~2I~_~A~:>"
1345 (values nil t t)))))
1347 ;;; Return a pathname for the named file. The file must exist.
1348 (defun verify-source-file (pathname-designator)
1349 (let* ((pathname (pathname pathname-designator))
1350 (default-host (make-pathname :host (pathname-host pathname))))
1351 (flet ((try-with-type (path type error-p)
1352 (let ((new (merge-pathnames
1353 path (make-pathname :type type
1354 :defaults default-host))))
1355 (if (probe-file new)
1357 (and error-p (truename new))))))
1358 (cond ((typep pathname 'logical-pathname)
1359 (try-with-type pathname "LISP" t))
1360 ((probe-file pathname) pathname)
1361 ((try-with-type pathname "lisp" nil))
1362 ((try-with-type pathname "lisp" t))))))
1364 (defun elapsed-time-to-string (tsec)
1365 (multiple-value-bind (tmin sec) (truncate tsec 60)
1366 (multiple-value-bind (thr min) (truncate tmin 60)
1367 (format nil "~D:~2,'0D:~2,'0D" thr min sec))))
1369 ;;; Print some junk at the beginning and end of compilation.
1370 (defun start-error-output (source-info)
1371 (declare (type source-info source-info))
1372 (let ((file-info (source-info-file-info source-info)))
1373 (compiler-mumble "~&; compiling file ~S (written ~A):~%"
1374 (namestring (file-info-name file-info))
1375 (sb!int:format-universal-time nil
1376 (file-info-write-date
1380 :print-timezone nil)))
1382 (defun finish-error-output (source-info won)
1383 (declare (type source-info source-info))
1384 (compiler-mumble "~&; compilation ~:[aborted after~;finished in~] ~A~&"
1386 (elapsed-time-to-string
1387 (- (get-universal-time)
1388 (source-info-start-time source-info))))
1391 ;;; Open some files and call SUB-COMPILE-FILE. If something unwinds
1392 ;;; out of the compile, then abort the writing of the output file, so
1393 ;;; that we don't overwrite it with known garbage.
1394 (defun sb!xc:compile-file
1399 (output-file (cfp-output-file-default input-file))
1400 ;; FIXME: ANSI doesn't seem to say anything about
1401 ;; *COMPILE-VERBOSE* and *COMPILE-PRINT* being rebound by this
1403 ((:verbose sb!xc:*compile-verbose*) sb!xc:*compile-verbose*)
1404 ((:print sb!xc:*compile-print*) sb!xc:*compile-print*)
1405 (external-format :default)
1409 ((:block-compile *block-compile-arg*) nil))
1412 "Compile INPUT-FILE, producing a corresponding fasl file and returning
1413 its filename. Besides the ANSI &KEY arguments :OUTPUT-FILE, :VERBOSE,
1414 :PRINT, and :EXTERNAL-FORMAT,the following extensions are supported:
1416 If given, internal data structures are dumped to the specified
1417 file, or if a value of T is given, to a file of *.trace type
1418 derived from the input file name.
1419 Also, as a workaround for vaguely-non-ANSI behavior, the :BLOCK-COMPILE
1420 argument is quasi-supported, to determine whether multiple
1421 functions are compiled together as a unit, resolving function
1422 references at compile time. NIL means that global function names
1423 are never resolved at compilation time. Currently NIL is the
1424 default behavior, because although section 3.2.2.3, \"Semantic
1425 Constraints\", of the ANSI spec allows this behavior under all
1426 circumstances, the compiler's runtime scales badly when it
1427 tries to do this for large files. If/when this performance
1428 problem is fixed, the block compilation default behavior will
1429 probably be made dependent on the SPEED and COMPILATION-SPEED
1430 optimization values, and the :BLOCK-COMPILE argument will probably
1433 (unless (eq external-format :default)
1434 (error "Non-:DEFAULT EXTERNAL-FORMAT values are not supported."))
1435 (let* ((fasl-output nil)
1436 (output-file-name nil)
1439 (failure-p t) ; T in case error keeps this from being set later
1440 (input-pathname (verify-source-file input-file))
1441 (source-info (make-file-source-info input-pathname))
1442 (*compiler-trace-output* nil)) ; might be modified below
1447 (setq output-file-name
1448 (sb!xc:compile-file-pathname input-file
1449 :output-file output-file))
1451 (open-fasl-output output-file-name
1452 (namestring input-pathname))))
1454 (let* ((default-trace-file-pathname
1455 (make-pathname :type "trace" :defaults input-pathname))
1456 (trace-file-pathname
1457 (if (eql trace-file t)
1458 default-trace-file-pathname
1459 (merge-pathnames trace-file
1460 default-trace-file-pathname))))
1461 (setf *compiler-trace-output*
1462 (open trace-file-pathname
1463 :if-exists :supersede
1464 :direction :output))))
1466 (when sb!xc:*compile-verbose*
1467 (start-error-output source-info))
1468 (let ((*compile-object* fasl-output)
1470 (multiple-value-setq (dummy warnings-p failure-p)
1471 (sub-compile-file source-info)))
1472 (setq compile-won t))
1474 (close-source-info source-info)
1477 (close-fasl-output fasl-output (not compile-won))
1478 (setq output-file-name
1479 (pathname (fasl-output-stream fasl-output)))
1480 (when (and compile-won sb!xc:*compile-verbose*)
1481 (compiler-mumble "~2&; ~A written~%" (namestring output-file-name))))
1483 (when sb!xc:*compile-verbose*
1484 (finish-error-output source-info compile-won))
1486 (when *compiler-trace-output*
1487 (close *compiler-trace-output*)))
1489 (values (if output-file
1490 ;; Hack around filesystem race condition...
1491 (or (probe-file output-file-name) output-file-name)
1496 ;;; a helper function for COMPILE-FILE-PATHNAME: the default for
1497 ;;; the OUTPUT-FILE argument
1499 ;;; ANSI: The defaults for the OUTPUT-FILE are taken from the pathname
1500 ;;; that results from merging the INPUT-FILE with the value of
1501 ;;; *DEFAULT-PATHNAME-DEFAULTS*, except that the type component should
1502 ;;; default to the appropriate implementation-defined default type for
1504 (defun cfp-output-file-default (input-file)
1505 (let* ((defaults (merge-pathnames input-file *default-pathname-defaults*))
1506 (retyped (make-pathname :type *fasl-file-type* :defaults defaults)))
1509 ;;; KLUDGE: Part of the ANSI spec for this seems contradictory:
1510 ;;; If INPUT-FILE is a logical pathname and OUTPUT-FILE is unsupplied,
1511 ;;; the result is a logical pathname. If INPUT-FILE is a logical
1512 ;;; pathname, it is translated into a physical pathname as if by
1513 ;;; calling TRANSLATE-LOGICAL-PATHNAME.
1514 ;;; So I haven't really tried to make this precisely ANSI-compatible
1515 ;;; at the level of e.g. whether it returns logical pathname or a
1516 ;;; physical pathname. Patches to make it more correct are welcome.
1517 ;;; -- WHN 2000-12-09
1518 (defun sb!xc:compile-file-pathname (input-file
1520 (output-file (cfp-output-file-default
1524 "Return a pathname describing what file COMPILE-FILE would write to given
1526 (pathname output-file))
1528 ;;;; MAKE-LOAD-FORM stuff
1530 ;;; The entry point for MAKE-LOAD-FORM support. When IR1 conversion
1531 ;;; finds a constant structure, it invokes this to arrange for proper
1532 ;;; dumping. If it turns out that the constant has already been
1533 ;;; dumped, then we don't need to do anything.
1535 ;;; If the constant hasn't been dumped, then we check to see whether
1536 ;;; we are in the process of creating it. We detect this by
1537 ;;; maintaining the special *CONSTANTS-BEING-CREATED* as a list of all
1538 ;;; the constants we are in the process of creating. Actually, each
1539 ;;; entry is a list of the constant and any init forms that need to be
1540 ;;; processed on behalf of that constant.
1542 ;;; It's not necessarily an error for this to happen. If we are
1543 ;;; processing the init form for some object that showed up *after*
1544 ;;; the original reference to this constant, then we just need to
1545 ;;; defer the processing of that init form. To detect this, we
1546 ;;; maintain *CONSTANTS-CREATED-SINCE-LAST-INIT* as a list of the
1547 ;;; constants created since the last time we started processing an
1548 ;;; init form. If the constant passed to emit-make-load-form shows up
1549 ;;; in this list, then there is a circular chain through creation
1550 ;;; forms, which is an error.
1552 ;;; If there is some intervening init form, then we blow out of
1553 ;;; processing it by throwing to the tag PENDING-INIT. The value we
1554 ;;; throw is the entry from *CONSTANTS-BEING-CREATED*. This is so the
1555 ;;; offending init form can be tacked onto the init forms for the
1556 ;;; circular object.
1558 ;;; If the constant doesn't show up in *CONSTANTS-BEING-CREATED*, then
1559 ;;; we have to create it. We call MAKE-LOAD-FORM and check to see
1560 ;;; whether the creation form is the magic value
1561 ;;; :JUST-DUMP-IT-NORMALLY. If it is, then we don't do anything. The
1562 ;;; dumper will eventually get its hands on the object and use the
1563 ;;; normal structure dumping noise on it.
1565 ;;; Otherwise, we bind *CONSTANTS-BEING-CREATED* and
1566 ;;; *CONSTANTS-CREATED-SINCE- LAST-INIT* and compile the creation form
1567 ;;; much the way LOAD-TIME-VALUE does. When this finishes, we tell the
1568 ;;; dumper to use that result instead whenever it sees this constant.
1570 ;;; Now we try to compile the init form. We bind
1571 ;;; *CONSTANTS-CREATED-SINCE-LAST-INIT* to NIL and compile the init
1572 ;;; form (and any init forms that were added because of circularity
1573 ;;; detection). If this works, great. If not, we add the init forms to
1574 ;;; the init forms for the object that caused the problems and let it
1576 (defvar *constants-being-created* nil)
1577 (defvar *constants-created-since-last-init* nil)
1578 ;;; FIXME: Shouldn't these^ variables be bound in LET forms?
1579 (defun emit-make-load-form (constant)
1580 (aver (fasl-output-p *compile-object*))
1581 (unless (or (fasl-constant-already-dumped-p constant *compile-object*)
1582 ;; KLUDGE: This special hack is because I was too lazy
1583 ;; to rework DEF!STRUCT so that the MAKE-LOAD-FORM
1584 ;; function of LAYOUT returns nontrivial forms when
1585 ;; building the cross-compiler but :IGNORE-IT when
1586 ;; cross-compiling or running under the target Lisp. --
1588 #+sb-xc-host (typep constant 'layout))
1589 (let ((circular-ref (assoc constant *constants-being-created* :test #'eq)))
1591 (when (find constant *constants-created-since-last-init* :test #'eq)
1593 (throw 'pending-init circular-ref)))
1594 (multiple-value-bind (creation-form init-form)
1596 (sb!xc:make-load-form constant (make-null-lexenv))
1598 (compiler-error "(while making load form for ~S)~%~A"
1602 (:just-dump-it-normally
1603 (fasl-validate-structure constant *compile-object*)
1608 (compile-toplevel-lambdas () t)
1609 (when (fasl-constant-already-dumped-p constant *compile-object*)
1610 (return-from emit-make-load-form nil))
1611 (let* ((name (let ((*print-level* 1) (*print-length* 2))
1612 (with-output-to-string (stream)
1613 (write constant :stream stream))))
1615 (list constant name init-form)
1617 (let ((*constants-being-created*
1618 (cons info *constants-being-created*))
1619 (*constants-created-since-last-init*
1620 (cons constant *constants-created-since-last-init*)))
1623 (fasl-note-handle-for-constant
1625 (compile-load-time-value
1629 (compiler-error "circular references in creation form for ~S"
1632 (let* ((*constants-created-since-last-init* nil)
1634 (catch 'pending-init
1635 (loop for (name form) on (cdr info) by #'cddr
1636 collect name into names
1637 collect form into forms
1639 (compile-make-load-form-init-forms
1641 (format nil "init form~:[~;s~] for ~{~A~^, ~}"
1642 (cdr forms) names)))
1645 (setf (cdr circular-ref)
1646 (append (cdr circular-ref) (cdr info))))))))))))