1 ;;; cc-defs.el --- compile time definitions for CC Mode
3 ;; Copyright (C) 1985, 1987, 1992-2014 Free Software Foundation, Inc.
5 ;; Authors: 2003- Alan Mackenzie
6 ;; 1998- Martin Stjernholm
7 ;; 1992-1999 Barry A. Warsaw
10 ;; 1985 Richard M. Stallman
11 ;; Maintainer: bug-cc-mode@gnu.org
12 ;; Created: 22-Apr-1997 (split from cc-mode.el)
13 ;; Keywords: c languages
16 ;; This file is part of GNU Emacs.
18 ;; GNU Emacs is free software: you can redistribute it and/or modify
19 ;; it under the terms of the GNU General Public License as published by
20 ;; the Free Software Foundation, either version 3 of the License, or
21 ;; (at your option) any later version.
23 ;; GNU Emacs is distributed in the hope that it will be useful,
24 ;; but WITHOUT ANY WARRANTY; without even the implied warranty of
25 ;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
26 ;; GNU General Public License for more details.
28 ;; You should have received a copy of the GNU General Public License
29 ;; along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>.
33 ;; This file contains macros, defsubsts, and various other things that
34 ;; must be loaded early both during compilation and at runtime.
40 (if (and (boundp 'byte-compile-dest-file
)
41 (stringp byte-compile-dest-file
))
42 (cons (file-name-directory byte-compile-dest-file
) load-path
)
44 (load "cc-bytecomp" nil t
)))
46 (eval-when-compile (require 'cl
)) ; was (cc-external-require 'cl). ACM 2005/11/29.
47 (cc-external-require 'regexp-opt
)
49 ;; Silence the compiler.
50 (cc-bytecomp-defvar c-enable-xemacs-performance-kludge-p
) ; In cc-vars.el
51 (cc-bytecomp-defun region-active-p) ; XEmacs
52 (cc-bytecomp-defvar mark-active
) ; Emacs
53 (cc-bytecomp-defvar deactivate-mark
) ; Emacs
54 (cc-bytecomp-defvar inhibit-point-motion-hooks
) ; Emacs
55 (cc-bytecomp-defvar parse-sexp-lookup-properties
) ; Emacs
56 (cc-bytecomp-defvar text-property-default-nonsticky
) ; Emacs 21
57 (cc-bytecomp-defun string-to-syntax) ; Emacs 21
60 ;; cc-fix.el contains compatibility macros that should be used if
63 (if (or (/= (regexp-opt-depth "\\(\\(\\)\\)") 2)
64 (not (fboundp 'push
)))
67 ; (eval-after-load "font-lock" ; 2006-07-09. font-lock is now preloaded
69 (if (and (featurep 'xemacs
) ; There is now (2005/12) code in GNU Emacs CVS
70 ; to make the call to f-l-c-k throw an error.
71 (not (featurep 'cc-fix
)) ; only load the file once.
72 (let (font-lock-keywords)
73 (font-lock-compile-keywords '("\\<\\>"))
74 font-lock-keywords
)) ; did the previous call foul this up?
77 ;; The above takes care of the delayed loading, but this is necessary
78 ;; to ensure correct byte compilation.
80 (if (and (featurep 'xemacs
)
81 (not (featurep 'cc-fix
))
84 (let (font-lock-keywords)
85 (font-lock-compile-keywords '("\\<\\>"))
90 ;;; Variables also used at compile time.
92 (defconst c-version
"5.32.5"
93 "CC Mode version number.")
95 (defconst c-version-sym
(intern c-version
))
96 ;; A little more compact and faster in comparisons.
98 (defvar c-buffer-is-cc-mode nil
99 "Non-nil for all buffers with a major mode derived from CC Mode.
100 Otherwise, this variable is nil. I.e. this variable is non-nil for
101 `c-mode', `c++-mode', `objc-mode', `java-mode', `idl-mode',
102 `pike-mode', `awk-mode', and any other non-CC Mode mode that calls
103 `c-initialize-cc-mode'. The value is the mode symbol itself
104 \(i.e. `c-mode' etc) of the original CC Mode mode, or just t if it's
106 (make-variable-buffer-local 'c-buffer-is-cc-mode
)
108 ;; Have to make `c-buffer-is-cc-mode' permanently local so that it
109 ;; survives the initialization of the derived mode.
110 (put 'c-buffer-is-cc-mode
'permanent-local t
)
113 ;; The following is used below during compilation.
115 (defvar c-inside-eval-when-compile nil
)
117 (defmacro cc-eval-when-compile
(&rest body
)
118 "Like `progn', but evaluates the body at compile time.
119 The result of the body appears to the compiler as a quoted constant.
121 This variant works around bugs in `eval-when-compile' in various
122 \(X)Emacs versions. See cc-defs.el for details."
124 (if c-inside-eval-when-compile
125 ;; XEmacs 21.4.6 has a bug in `eval-when-compile' in that it
126 ;; evaluates its body at macro expansion time if it's nested
127 ;; inside another `eval-when-compile'. So we use a dynamically
128 ;; bound variable to avoid nesting them.
132 ;; In all (X)Emacsen so far, `eval-when-compile' byte compiles
133 ;; its contents before evaluating it. That can cause forms to
134 ;; be compiled in situations they aren't intended to be
137 ;; Example: It's not possible to defsubst a primitive, e.g. the
138 ;; following will produce an error (in any emacs flavor), since
139 ;; `nthcdr' is a primitive function that's handled specially by
140 ;; the byte compiler and thus can't be redefined:
142 ;; (defsubst nthcdr (val) val)
144 ;; `defsubst', like `defmacro', needs to be evaluated at
145 ;; compile time, so this will produce an error during byte
148 ;; CC Mode occasionally needs to do things like this for
149 ;; cross-emacs compatibility. It therefore uses the following
150 ;; to conditionally do a `defsubst':
152 ;; (eval-when-compile
153 ;; (if (not (fboundp 'foo))
154 ;; (defsubst foo ...)))
156 ;; But `eval-when-compile' byte compiles its contents and
157 ;; _then_ evaluates it (in all current emacs versions, up to
158 ;; and including Emacs 20.6 and XEmacs 21.1 as of this
159 ;; writing). So this will still produce an error, since the
160 ;; byte compiler will get to the defsubst anyway. That's
161 ;; arguably a bug because the point with `eval-when-compile' is
162 ;; that it should evaluate rather than compile its contents.
164 ;; We get around it by expanding the body to a quoted
165 ;; constant that we eval. That otoh introduce a problem in
166 ;; that a returned lambda expression doesn't get byte
167 ;; compiled (even if `function' is used).
168 (eval '(let ((c-inside-eval-when-compile t
)) ,@body
)))))
170 (put 'cc-eval-when-compile
'lisp-indent-hook
0))
175 (defmacro c-point
(position &optional point
)
176 "Return the value of certain commonly referenced POSITIONs relative to POINT.
177 The current point is used if POINT isn't specified. POSITION can be
178 one of the following symbols:
180 `bol' -- beginning of line
182 `bod' -- beginning of defun
183 `eod' -- end of defun
184 `boi' -- beginning of indentation
185 `ionl' -- indentation of next line
186 `iopl' -- indentation of previous line
187 `bonl' -- beginning of next line
188 `eonl' -- end of next line
189 `bopl' -- beginning of previous line
190 `eopl' -- end of previous line
191 `bosws' -- beginning of syntactic whitespace
192 `eosws' -- end of syntactic whitespace
194 If the referenced position doesn't exist, the closest accessible point
195 to it is returned. This function does not modify the point or the mark."
197 (if (eq (car-safe position
) 'quote
)
198 (let ((position (eval position
)))
202 (if (and (cc-bytecomp-fboundp 'line-beginning-position
) (not point
))
203 `(line-beginning-position)
205 ,@(if point
`((goto-char ,point
)))
210 (if (and (cc-bytecomp-fboundp 'line-end-position
) (not point
))
213 ,@(if point
`((goto-char ,point
)))
219 ,@(if point
`((goto-char ,point
)))
220 (back-to-indentation)
225 ,@(if point
`((goto-char ,point
)))
226 (c-beginning-of-defun-1)
231 ,@(if point
`((goto-char ,point
)))
236 (if (and (cc-bytecomp-fboundp 'line-beginning-position
) (not point
))
237 `(line-beginning-position 0)
239 ,@(if point
`((goto-char ,point
)))
244 (if (and (cc-bytecomp-fboundp 'line-beginning-position
) (not point
))
245 `(line-beginning-position 2)
247 ,@(if point
`((goto-char ,point
)))
252 (if (and (cc-bytecomp-fboundp 'line-end-position
) (not point
))
253 `(line-end-position 0)
255 ,@(if point
`((goto-char ,point
)))
257 (or (bobp) (backward-char))
261 (if (and (cc-bytecomp-fboundp 'line-end-position
) (not point
))
262 `(line-end-position 2)
264 ,@(if point
`((goto-char ,point
)))
271 ,@(if point
`((goto-char ,point
)))
273 (back-to-indentation)
278 ,@(if point
`((goto-char ,point
)))
280 (back-to-indentation)
283 ((eq position
'bosws
)
285 ,@(if point
`((goto-char ,point
)))
286 (c-backward-syntactic-ws)
289 ((eq position
'eosws
)
291 ,@(if point
`((goto-char ,point
)))
292 (c-forward-syntactic-ws)
295 (t (error "Unknown buffer position requested: %s" position
))))
297 ;; The bulk of this should perhaps be in a function to avoid large
298 ;; expansions, but this case is not used anywhere in CC Mode (and
299 ;; probably not anywhere else either) so we only have it to be on
301 (message "Warning: c-point long expansion")
303 ,@(if point
`((goto-char ,point
)))
304 (let ((position ,position
))
306 ((eq position
'bol
) (beginning-of-line))
307 ((eq position
'eol
) (end-of-line))
308 ((eq position
'boi
) (back-to-indentation))
309 ((eq position
'bod
) (c-beginning-of-defun-1))
310 ((eq position
'eod
) (c-end-of-defun-1))
311 ((eq position
'bopl
) (forward-line -
1))
312 ((eq position
'bonl
) (forward-line 1))
313 ((eq position
'eopl
) (progn
315 (or (bobp) (backward-char))))
316 ((eq position
'eonl
) (progn
319 ((eq position
'iopl
) (progn
321 (back-to-indentation)))
322 ((eq position
'ionl
) (progn
324 (back-to-indentation)))
325 ((eq position
'bosws
) (c-backward-syntactic-ws))
326 ((eq position
'eosws
) (c-forward-syntactic-ws))
327 (t (error "Unknown buffer position requested: %s" position
))))
330 (defmacro c-region-is-active-p
()
331 ;; Return t when the region is active. The determination of region
332 ;; activeness is different in both Emacs and XEmacs.
333 ;; FIXME? Emacs has region-active-p since 23.1, so maybe this test
334 ;; should be updated.
335 (if (cc-bytecomp-boundp 'mark-active
)
341 (defmacro c-set-region-active
(activate)
342 ;; Activate the region if ACTIVE is non-nil, deactivate it
343 ;; otherwise. Covers the differences between Emacs and XEmacs.
344 (if (fboundp 'zmacs-activate-region
)
347 (zmacs-activate-region)
348 (zmacs-deactivate-region))
350 `(setq mark-active
,activate
)))
352 (defmacro c-delete-and-extract-region
(start end
)
353 "Delete the text between START and END and return it."
354 (if (cc-bytecomp-fboundp 'delete-and-extract-region
)
355 ;; Emacs 21.1 and later
356 `(delete-and-extract-region ,start
,end
)
357 ;; XEmacs and Emacs 20.x
359 (buffer-substring ,start
,end
)
360 (delete-region ,start
,end
))))
362 (defmacro c-safe
(&rest body
)
363 ;; safely execute BODY, return nil if an error occurred
367 (put 'c-safe
'lisp-indent-function
0)
369 (defmacro c-int-to-char
(integer)
370 ;; In Emacs, a character is an integer. In XEmacs, a character is a
371 ;; type distinct from an integer. Sometimes we need to convert integers to
372 ;; characters. `c-int-to-char' makes this conversion, if necessary.
373 (if (fboundp 'int-to-char
)
374 `(int-to-char ,integer
)
377 (defmacro c-last-command-char
()
378 ;; The last character just typed. Note that `last-command-event' exists in
379 ;; both Emacs and XEmacs, but with confusingly different meanings.
380 (if (featurep 'xemacs
)
382 'last-command-event
))
384 (defmacro c-sentence-end
()
385 ;; Get the regular expression `sentence-end'.
386 (if (cc-bytecomp-fboundp 'sentence-end
)
389 ;; Emacs <22 + XEmacs
392 (defmacro c-default-value-sentence-end
()
393 ;; Get the default value of the variable sentence end.
394 (if (cc-bytecomp-fboundp 'sentence-end
)
396 `(let (sentence-end) (sentence-end))
397 ;; Emacs <22 + XEmacs
398 `(default-value 'sentence-end
)))
400 ;; The following is essentially `save-buffer-state' from lazy-lock.el.
401 ;; It ought to be a standard macro.
402 (defmacro c-save-buffer-state
(varlist &rest body
)
403 "Bind variables according to VARLIST (in `let*' style) and eval BODY,
404 then restore the buffer state under the assumption that no significant
405 modification has been made in BODY. A change is considered
406 significant if it affects the buffer text in any way that isn't
407 completely restored again. Changes in text properties like `face' or
408 `syntax-table' are considered insignificant. This macro allows text
409 properties to be changed, even in a read-only buffer.
411 This macro should be placed around all calculations which set
412 \"insignificant\" text properties in a buffer, even when the buffer is
413 known to be writable. That way, these text properties remain set
414 even if the user undoes the command which set them.
416 This macro should ALWAYS be placed around \"temporary\" internal buffer
417 changes \(like adding a newline to calculate a text-property then
418 deleting it again\), so that the user never sees them on his
419 `buffer-undo-list'. See also `c-tentative-buffer-changes'.
421 However, any user-visible changes to the buffer \(like auto-newlines\)
422 must not be within a `c-save-buffer-state', since the user then
423 wouldn't be able to undo them.
425 The return value is the value of the last form in BODY."
426 `(let* ((modified (buffer-modified-p)) (buffer-undo-list t
)
427 (inhibit-read-only t
) (inhibit-point-motion-hooks t
)
428 before-change-functions after-change-functions
430 buffer-file-name buffer-file-truename
; Prevent primitives checking
431 ; for file modification
437 (set-buffer-modified-p nil
)))))
438 (put 'c-save-buffer-state
'lisp-indent-function
1)
440 (defmacro c-tentative-buffer-changes
(&rest body
)
441 "Eval BODY and optionally restore the buffer contents to the state it
442 was in before BODY. Any changes are kept if the last form in BODY
443 returns non-nil. Otherwise it's undone using the undo facility, and
444 various other buffer state that might be affected by the changes is
445 restored. That includes the current buffer, point, mark, mark
446 activation \(similar to `save-excursion'), and the modified state.
447 The state is also restored if BODY exits nonlocally.
449 If BODY makes a change that unconditionally is undone then wrap this
450 macro inside `c-save-buffer-state'. That way the change can be done
451 even when the buffer is read-only, and without interference from
452 various buffer change hooks."
453 `(let (-tnt-chng-keep
456 ;; Insert an undo boundary for use with `undo-more'. We
457 ;; don't use `undo-boundary' since it doesn't insert one
459 (setq buffer-undo-list
(cons nil buffer-undo-list
)
460 -tnt-chng-state
(c-tnt-chng-record-state)
461 -tnt-chng-keep
(progn ,@body
))
462 (c-tnt-chng-cleanup -tnt-chng-keep -tnt-chng-state
))))
463 (put 'c-tentative-buffer-changes
'lisp-indent-function
0)
465 (defun c-tnt-chng-record-state ()
466 ;; Used internally in `c-tentative-buffer-changes'.
467 (vector buffer-undo-list
; 0
469 ;; No need to use markers for the point and mark; if the
470 ;; undo got out of synch we're hosed anyway.
473 (c-region-is-active-p) ; 4
474 (buffer-modified-p))) ; 5
476 (defun c-tnt-chng-cleanup (keep saved-state
)
477 ;; Used internally in `c-tentative-buffer-changes'.
479 (let ((saved-undo-list (elt saved-state
0)))
480 (if (eq buffer-undo-list saved-undo-list
)
481 ;; No change was done after all.
482 (setq buffer-undo-list
(cdr saved-undo-list
))
485 ;; Find and remove the undo boundary.
486 (let ((p buffer-undo-list
))
487 (while (not (eq (cdr p
) saved-undo-list
))
489 (setcdr p
(cdr saved-undo-list
)))
491 ;; `primitive-undo' will remove the boundary.
492 (setq saved-undo-list
(cdr saved-undo-list
))
493 (let ((undo-in-progress t
))
494 (while (not (eq (setq buffer-undo-list
495 (primitive-undo 1 buffer-undo-list
))
498 (when (buffer-live-p (elt saved-state
1))
499 (set-buffer (elt saved-state
1))
500 (goto-char (elt saved-state
2))
501 (set-mark (elt saved-state
3))
502 (c-set-region-active (elt saved-state
4))
503 (and (not (elt saved-state
5))
505 (set-buffer-modified-p nil
)))))))
507 (defmacro c-forward-syntactic-ws
(&optional limit
)
508 "Forward skip over syntactic whitespace.
509 Syntactic whitespace is defined as whitespace characters, comments,
510 and preprocessor directives. However if point starts inside a comment
511 or preprocessor directive, the content of it is not treated as
514 LIMIT sets an upper limit of the forward movement, if specified. If
515 LIMIT or the end of the buffer is reached inside a comment or
516 preprocessor directive, the point will be left there.
518 Note that this function might do hidden buffer changes. See the
519 comment at the start of cc-engine.el for more info."
522 (narrow-to-region (point-min) (or ,limit
(point-max)))
526 (defmacro c-backward-syntactic-ws
(&optional limit
)
527 "Backward skip over syntactic whitespace.
528 Syntactic whitespace is defined as whitespace characters, comments,
529 and preprocessor directives. However if point starts inside a comment
530 or preprocessor directive, the content of it is not treated as
533 LIMIT sets a lower limit of the backward movement, if specified. If
534 LIMIT is reached inside a line comment or preprocessor directive then
535 the point is moved into it past the whitespace at the end.
537 Note that this function might do hidden buffer changes. See the
538 comment at the start of cc-engine.el for more info."
541 (narrow-to-region (or ,limit
(point-min)) (point-max))
545 (defmacro c-forward-sexp
(&optional count
)
546 "Move forward across COUNT balanced expressions.
547 A negative COUNT means move backward. Signal an error if the move
548 fails for any reason.
550 This is like `forward-sexp' except that it isn't interactive and does
551 not do any user friendly adjustments of the point and that it isn't
552 susceptible to user configurations such as disabling of signals in
554 (or count
(setq count
1))
555 `(goto-char (scan-sexps (point) ,count
)))
557 (defmacro c-backward-sexp
(&optional count
)
558 "See `c-forward-sexp' and reverse directions."
559 (or count
(setq count
1))
560 `(c-forward-sexp ,(if (numberp count
) (- count
) `(- ,count
))))
562 (defmacro c-safe-scan-lists
(from count depth
&optional limit
)
563 "Like `scan-lists' but returns nil instead of signaling errors
564 for unbalanced parens.
566 A limit for the search may be given. FROM is assumed to be on the
568 (let ((res (if (featurep 'xemacs
)
569 `(scan-lists ,from
,count
,depth nil t
)
570 `(c-safe (scan-lists ,from
,count
,depth
)))))
575 `(narrow-to-region ,limit
(point-max))
576 `(narrow-to-region (point-min) ,limit
))
578 (narrow-to-region ,limit
(point-max))
579 (narrow-to-region (point-min) ,limit
)))
584 ;; Wrappers for common scan-lists cases, mainly because it's almost
585 ;; impossible to get a feel for how that function works.
587 (defmacro c-go-list-forward
()
588 "Move backward across one balanced group of parentheses.
590 Return POINT when we succeed, NIL when we fail. In the latter case, leave
592 `(c-safe (let ((endpos (scan-lists (point) 1 0)))
596 (defmacro c-go-list-backward
()
597 "Move backward across one balanced group of parentheses.
599 Return POINT when we succeed, NIL when we fail. In the latter case, leave
601 `(c-safe (let ((endpos (scan-lists (point) -
1 0)))
605 (defmacro c-up-list-forward
(&optional pos limit
)
606 "Return the first position after the list sexp containing POS,
607 or nil if no such position exists. The point is used if POS is left out.
609 A limit for the search may be given. The start position is assumed to
611 `(c-safe-scan-lists ,(or pos
`(point)) 1 1 ,limit
))
613 (defmacro c-up-list-backward
(&optional pos limit
)
614 "Return the position of the start of the list sexp containing POS,
615 or nil if no such position exists. The point is used if POS is left out.
617 A limit for the search may be given. The start position is assumed to
619 `(c-safe-scan-lists ,(or pos
`(point)) -
1 1 ,limit
))
621 (defmacro c-down-list-forward
(&optional pos limit
)
622 "Return the first position inside the first list sexp after POS,
623 or nil if no such position exists. The point is used if POS is left out.
625 A limit for the search may be given. The start position is assumed to
627 `(c-safe-scan-lists ,(or pos
`(point)) 1 -
1 ,limit
))
629 (defmacro c-down-list-backward
(&optional pos limit
)
630 "Return the last position inside the last list sexp before POS,
631 or nil if no such position exists. The point is used if POS is left out.
633 A limit for the search may be given. The start position is assumed to
635 `(c-safe-scan-lists ,(or pos
`(point)) -
1 -
1 ,limit
))
637 (defmacro c-go-up-list-forward
(&optional pos limit
)
638 "Move the point to the first position after the list sexp containing POS,
639 or containing the point if POS is left out. Return t if such a
640 position exists, otherwise nil is returned and the point isn't moved.
642 A limit for the search may be given. The start position is assumed to
644 (let ((res `(c-safe (goto-char (scan-lists ,(or pos
`(point)) 1 1)) t
)))
647 (narrow-to-region (point-min) ,limit
)
651 (defmacro c-go-up-list-backward
(&optional pos limit
)
652 "Move the point to the position of the start of the list sexp containing POS,
653 or containing the point if POS is left out. Return t if such a
654 position exists, otherwise nil is returned and the point isn't moved.
656 A limit for the search may be given. The start position is assumed to
658 (let ((res `(c-safe (goto-char (scan-lists ,(or pos
`(point)) -
1 1)) t
)))
661 (narrow-to-region ,limit
(point-max))
665 (defmacro c-go-down-list-forward
(&optional pos limit
)
666 "Move the point to the first position inside the first list sexp after POS,
667 or before the point if POS is left out. Return t if such a position
668 exists, otherwise nil is returned and the point isn't moved.
670 A limit for the search may be given. The start position is assumed to
672 (let ((res `(c-safe (goto-char (scan-lists ,(or pos
`(point)) 1 -
1)) t
)))
675 (narrow-to-region (point-min) ,limit
)
679 (defmacro c-go-down-list-backward
(&optional pos limit
)
680 "Move the point to the last position inside the last list sexp before POS,
681 or before the point if POS is left out. Return t if such a position
682 exists, otherwise nil is returned and the point isn't moved.
684 A limit for the search may be given. The start position is assumed to
686 (let ((res `(c-safe (goto-char (scan-lists ,(or pos
`(point)) -
1 -
1)) t
)))
689 (narrow-to-region ,limit
(point-max))
694 (defmacro c-beginning-of-defun-1
()
695 ;; Wrapper around beginning-of-defun.
697 ;; NOTE: This function should contain the only explicit use of
698 ;; beginning-of-defun in CC Mode. Eventually something better than
699 ;; b-o-d will be available and this should be the only place the
700 ;; code needs to change. Everything else should use
701 ;; (c-beginning-of-defun-1)
703 ;; This is really a bit too large to be a macro but that isn't a
704 ;; problem as long as it only is used in one place in
708 (if (and ,(fboundp 'buffer-syntactic-context-depth
)
709 c-enable-xemacs-performance-kludge-p
)
710 ,(when (fboundp 'buffer-syntactic-context-depth
)
711 ;; XEmacs only. This can improve the performance of
712 ;; c-parse-state to between 3 and 60 times faster when
713 ;; braces are hung. It can also degrade performance by
714 ;; about as much when braces are not hung.
715 '(let (beginning-of-defun-function end-of-defun-function
720 (setq pos
(c-safe-scan-lists
721 (point) -
1 (buffer-syntactic-context-depth))))
723 ((bobp) (setq pos
(point-min)))
725 (let ((distance (skip-chars-backward "^{")))
726 ;; unbalanced parenthesis, while invalid C code,
727 ;; shouldn't cause an infloop! See unbal.c
728 (when (zerop distance
)
731 (setq pos
(point)))))
733 ((not (eq (char-after pos
) ?
{))
738 ;; Emacs, which doesn't have buffer-syntactic-context-depth
739 (let (beginning-of-defun-function end-of-defun-function
)
740 (beginning-of-defun)))
741 ;; if defun-prompt-regexp is non-nil, b-o-d won't leave us at the
743 (and defun-prompt-regexp
744 (looking-at defun-prompt-regexp
)
745 (goto-char (match-end 0)))))
748 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
749 ;; V i r t u a l S e m i c o l o n s
751 ;; In most CC Mode languages, statements are terminated explicitly by
752 ;; semicolons or closing braces. In some of the CC modes (currently AWK Mode
753 ;; and certain user-specified #define macros in C, C++, etc. (November 2008)),
754 ;; statements are (or can be) terminated by EOLs. Such a statement is said to
755 ;; be terminated by a "virtual semicolon" (VS). A statement terminated by an
756 ;; actual semicolon or brace is never considered to have a VS.
758 ;; The indentation engine (or whatever) tests for a VS at a specific position
759 ;; by invoking the macro `c-at-vsemi-p', which in its turn calls the mode
760 ;; specific function (if any) which is the value of the language variable
761 ;; `c-at-vsemi-p-fn'. This function should only use "low-level" features of
762 ;; CC Mode, i.e. features which won't trigger infinite recursion. ;-) The
763 ;; actual details of what constitutes a VS in a language are thus encapsulated
764 ;; in code specific to that language (e.g. cc-awk.el). `c-at-vsemi-p' returns
765 ;; non-nil if point (or the optional parameter POS) is at a VS, nil otherwise.
767 ;; The language specific function might well do extensive analysis of the
768 ;; source text, and may use a caching scheme to speed up repeated calls.
770 ;; The "virtual semicolon" lies just after the last non-ws token on the line.
771 ;; Like POINT, it is considered to lie between two characters. For example,
772 ;; at the place shown in the following AWK source line:
774 ;; kbyte = 1024 # 1000 if you're not picky
779 ;; In addition to `c-at-vsemi-p-fn', a mode may need to supply a function for
780 ;; `c-vsemi-status-unknown-p-fn'. The macro `c-vsemi-status-unknown-p' is a
781 ;; rather recondite kludge. It exists because the function
782 ;; `c-beginning-of-statement-1' sometimes tests for VSs as an optimization,
783 ;; but `c-at-vsemi-p' might well need to call `c-beginning-of-statement-1' in
784 ;; its calculations, thus potentially leading to infinite recursion.
786 ;; The macro `c-vsemi-status-unknown-p' resolves this problem; it may return
787 ;; non-nil at any time; returning nil is a guarantee that an immediate
788 ;; invocation of `c-at-vsemi-p' at point will NOT call
789 ;; `c-beginning-of-statement-1'. `c-vsemi-status-unknown-p' may not itself
790 ;; call `c-beginning-of-statement-1'.
792 ;; The macro `c-vsemi-status-unknown-p' will typically check the caching
793 ;; scheme used by the `c-at-vsemi-p-fn', hence the name - the status is
794 ;; "unknown" if there is no cache entry current for the line.
795 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
797 (defmacro c-at-vsemi-p
(&optional pos
)
798 ;; Is there a virtual semicolon (not a real one or a }) at POS (defaults to
799 ;; point)? Always returns nil for languages which don't have Virtual
801 ;; This macro might do hidden buffer changes.
803 (funcall c-at-vsemi-p-fn
,@(if pos
`(,pos
)))))
805 (defmacro c-vsemi-status-unknown-p
()
806 ;; Return NIL only if it can be guaranteed that an immediate
807 ;; (c-at-vsemi-p) will NOT call c-beginning-of-statement-1. Otherwise,
808 ;; return non-nil. (See comments above). The function invoked by this
809 ;; macro MUST NOT UNDER ANY CIRCUMSTANCES itself call
810 ;; c-beginning-of-statement-1.
811 ;; Languages which don't have EOL terminated statements always return NIL
812 ;; (they _know_ there's no vsemi ;-).
813 `(if c-vsemi-status-unknown-p-fn
(funcall c-vsemi-status-unknown-p-fn
)))
816 (defmacro c-benign-error
(format &rest args
)
817 ;; Formats an error message for the echo area and dings, i.e. like
818 ;; `error' but doesn't abort.
820 (message ,format
,@args
)
823 (defmacro c-with-syntax-table
(table &rest code
)
824 ;; Temporarily switches to the specified syntax table in a failsafe
825 ;; way to execute code.
826 `(let ((c-with-syntax-table-orig-table (syntax-table)))
829 (set-syntax-table ,table
)
831 (set-syntax-table c-with-syntax-table-orig-table
))))
832 (put 'c-with-syntax-table
'lisp-indent-function
1)
834 (defmacro c-skip-ws-forward
(&optional limit
)
835 "Skip over any whitespace following point.
836 This function skips over horizontal and vertical whitespace and line
839 `(let ((limit (or ,limit
(point-max))))
841 ;; skip-syntax-* doesn't count \n as whitespace..
842 (skip-chars-forward " \t\n\r\f\v" limit
)
843 (when (and (eq (char-after) ?
\\)
847 (progn (backward-char) nil
))))))
849 (skip-chars-forward " \t\n\r\f\v")
850 (when (eq (char-after) ?
\\)
853 (progn (backward-char) nil
)))))))
855 (defmacro c-skip-ws-backward
(&optional limit
)
856 "Skip over any whitespace preceding point.
857 This function skips over horizontal and vertical whitespace and line
860 `(let ((limit (or ,limit
(point-min))))
862 ;; skip-syntax-* doesn't count \n as whitespace..
863 (skip-chars-backward " \t\n\r\f\v" limit
)
865 (eq (char-before) ?
\\)
869 (skip-chars-backward " \t\n\r\f\v")
871 (eq (char-before) ?
\\)))
875 (defvar c-langs-are-parametric nil
))
877 (defmacro c-major-mode-is
(mode)
878 "Return non-nil if the current CC Mode major mode is MODE.
879 MODE is either a mode symbol or a list of mode symbols."
881 (if c-langs-are-parametric
882 ;; Inside a `c-lang-defconst'.
883 `(c-lang-major-mode-is ,mode
)
885 (if (eq (car-safe mode
) 'quote
)
886 (let ((mode (eval mode
)))
888 `(memq c-buffer-is-cc-mode
',mode
)
889 `(eq c-buffer-is-cc-mode
',mode
)))
893 (memq c-buffer-is-cc-mode mode
)
894 (eq c-buffer-is-cc-mode mode
))))))
897 ;; Macros/functions to handle so-called "char properties", which are
898 ;; properties set on a single character and that never spread to any
902 ;; Constant used at compile time to decide whether or not to use
903 ;; XEmacs extents. Check all the extent functions we'll use since
904 ;; some packages might add compatibility aliases for some of them in
906 (defconst c-use-extents
(and (cc-bytecomp-fboundp 'extent-at
)
907 (cc-bytecomp-fboundp 'set-extent-property
)
908 (cc-bytecomp-fboundp 'set-extent-properties
)
909 (cc-bytecomp-fboundp 'make-extent
)
910 (cc-bytecomp-fboundp 'extent-property
)
911 (cc-bytecomp-fboundp 'delete-extent
)
912 (cc-bytecomp-fboundp 'map-extents
))))
914 ;; `c-put-char-property' is complex enough in XEmacs and Emacs < 21 to
915 ;; make it a function.
916 (defalias 'c-put-char-property-fun
917 (cc-eval-when-compile
921 (lambda (pos property value
)
922 (let ((ext (extent-at pos nil property
)))
924 (set-extent-property ext property value
)
925 (set-extent-properties (make-extent pos
(1+ pos
))
931 ((not (cc-bytecomp-boundp 'text-property-default-nonsticky
))
932 ;; In Emacs < 21 we have to mess with the `rear-nonsticky' property.
934 (lambda (pos property value
)
935 (put-text-property pos
(1+ pos
) property value
)
936 (let ((prop (get-text-property pos
'rear-nonsticky
)))
937 (or (memq property prop
)
938 (put-text-property pos
(1+ pos
)
940 (cons property prop
)))))))
941 ;; This won't be used for anything.
943 (cc-bytecomp-defun c-put-char-property-fun) ; Make it known below.
945 (defmacro c-put-char-property
(pos property value
)
946 ;; Put the given property with the given value on the character at
947 ;; POS and make it front and rear nonsticky, or start and end open
948 ;; in XEmacs vocabulary. If the character already has the given
949 ;; property then the value is replaced, and the behavior is
950 ;; undefined if that property has been put by some other function.
951 ;; PROPERTY is assumed to be constant.
953 ;; If there's a `text-property-default-nonsticky' variable (Emacs
954 ;; 21) then it's assumed that the property is present on it.
956 ;; This macro does a hidden buffer change.
957 (setq property
(eval property
))
958 (if (or c-use-extents
959 (not (cc-bytecomp-boundp 'text-property-default-nonsticky
)))
960 ;; XEmacs and Emacs < 21.
961 `(c-put-char-property-fun ,pos
',property
,value
)
962 ;; In Emacs 21 we got the `rear-nonsticky' property covered
963 ;; by `text-property-default-nonsticky'.
965 (put-text-property -pos-
(1+ -pos-
) ',property
,value
))))
967 (defmacro c-get-char-property
(pos property
)
968 ;; Get the value of the given property on the character at POS if
969 ;; it's been put there by `c-put-char-property'. PROPERTY is
970 ;; assumed to be constant.
971 (setq property
(eval property
))
974 `(let ((ext (extent-at ,pos nil
',property
)))
975 (if ext
(extent-property ext
',property
)))
977 `(get-text-property ,pos
',property
)))
979 ;; `c-clear-char-property' is complex enough in Emacs < 21 to make it
980 ;; a function, since we have to mess with the `rear-nonsticky' property.
981 (defalias 'c-clear-char-property-fun
982 (cc-eval-when-compile
983 (unless (or c-use-extents
984 (cc-bytecomp-boundp 'text-property-default-nonsticky
))
986 (lambda (pos property
)
987 (when (get-text-property pos property
)
988 (remove-text-properties pos
(1+ pos
) (list property nil
))
989 (put-text-property pos
(1+ pos
)
991 (delq property
(get-text-property
992 pos
'rear-nonsticky
)))))))))
993 (cc-bytecomp-defun c-clear-char-property-fun) ; Make it known below.
995 (defmacro c-clear-char-property
(pos property
)
996 ;; Remove the given property on the character at POS if it's been put
997 ;; there by `c-put-char-property'. PROPERTY is assumed to be
1000 ;; This macro does a hidden buffer change.
1001 (setq property
(eval property
))
1002 (cond (c-use-extents
1004 `(let ((ext (extent-at ,pos nil
',property
)))
1005 (if ext
(delete-extent ext
))))
1006 ((cc-bytecomp-boundp 'text-property-default-nonsticky
)
1007 ;; In Emacs 21 we got the `rear-nonsticky' property covered
1008 ;; by `text-property-default-nonsticky'.
1010 (remove-text-properties pos
(1+ pos
)
1014 `(c-clear-char-property-fun ,pos
',property
))))
1016 (defmacro c-clear-char-properties
(from to property
)
1017 ;; Remove all the occurrences of the given property in the given
1018 ;; region that has been put with `c-put-char-property'. PROPERTY is
1019 ;; assumed to be constant.
1021 ;; Note that this function does not clean up the property from the
1022 ;; lists of the `rear-nonsticky' properties in the region, if such
1023 ;; are used. Thus it should not be used for common properties like
1026 ;; This macro does hidden buffer changes.
1027 (setq property
(eval property
))
1030 `(map-extents (lambda (ext ignored
)
1031 (delete-extent ext
))
1032 nil
,from
,to nil nil
',property
)
1034 `(remove-text-properties ,from
,to
'(,property nil
))))
1036 (defmacro c-search-forward-char-property
(property value
&optional limit
)
1037 "Search forward for a text-property PROPERTY having value VALUE.
1038 LIMIT bounds the search. The comparison is done with `equal'.
1040 Leave point just after the character, and set the match data on
1041 this character, and return point. If VALUE isn't found, Return
1042 nil; point is then left undefined."
1043 `(let ((place (point)))
1046 (< place
,(or limit
'(point-max)))
1047 (not (equal (get-text-property place
,property
) ,value
)))
1048 (setq place
(next-single-property-change
1049 place
,property nil
,(or limit
'(point-max)))))
1050 (when (< place
,(or limit
'(point-max)))
1052 (search-forward-regexp ".") ; to set the match-data.
1055 (defmacro c-search-backward-char-property
(property value
&optional limit
)
1056 "Search backward for a text-property PROPERTY having value VALUE.
1057 LIMIT bounds the search. The comparison is done with `equal'.
1059 Leave point just before the character, set the match data on this
1060 character, and return point. If VALUE isn't found, Return nil;
1061 point is then left undefined."
1062 `(let ((place (point)))
1065 (> place
,(or limit
'(point-min)))
1066 (not (equal (get-text-property (1- place
) ,property
) ,value
)))
1067 (setq place
(previous-single-property-change
1068 place
,property nil
,(or limit
'(point-min)))))
1069 (when (> place
,(or limit
'(point-max)))
1071 (search-backward-regexp ".") ; to set the match-data.
1074 (defun c-clear-char-property-with-value-function (from to property value
)
1075 "Remove all text-properties PROPERTY from the region (FROM, TO)
1076 which have the value VALUE, as tested by `equal'. These
1077 properties are assumed to be over individual characters, having
1078 been put there by c-put-char-property. POINT remains unchanged."
1079 (let ((place from
) end-place
)
1080 (while ; loop round occurrences of (PROPERTY VALUE)
1082 (while ; loop round changes in PROPERTY till we find VALUE
1085 (not (equal (get-text-property place property
) value
)))
1086 (setq place
(next-single-property-change place property nil to
)))
1088 (setq end-place
(next-single-property-change place property nil to
))
1089 (remove-text-properties place end-place
(cons property nil
))
1090 ;; Do we have to do anything with stickiness here?
1091 (setq place end-place
))))
1093 (defmacro c-clear-char-property-with-value
(from to property value
)
1094 "Remove all text-properties PROPERTY from the region [FROM, TO)
1095 which have the value VALUE, as tested by `equal'. These
1096 properties are assumed to be over individual characters, having
1097 been put there by c-put-char-property. POINT remains unchanged."
1100 `(let ((-property- ,property
))
1101 (map-extents (lambda (ext val
)
1102 (if (equal (extent-property ext -property-
) val
)
1103 (delete-extent ext
)))
1104 nil
,from
,to
,value nil -property-
))
1106 `(c-clear-char-property-with-value-function ,from
,to
,property
,value
)))
1108 ;; Macros to put overlays (Emacs) or extents (XEmacs) on buffer text.
1109 ;; For our purposes, these are characterized by being possible to
1110 ;; remove again without affecting the other text properties in the
1111 ;; buffer that got overridden when they were put.
1113 (defmacro c-put-overlay
(from to property value
)
1114 ;; Put an overlay/extent covering the given range in the current
1115 ;; buffer. It's currently undefined whether it's front/end sticky
1116 ;; or not. The overlay/extent object is returned.
1117 (if (cc-bytecomp-fboundp 'make-overlay
)
1119 `(let ((ol (make-overlay ,from
,to
)))
1120 (overlay-put ol
,property
,value
)
1123 `(let ((ext (make-extent ,from
,to
)))
1124 (set-extent-property ext
,property
,value
)
1127 (defmacro c-delete-overlay
(overlay)
1128 ;; Deletes an overlay/extent object previously retrieved using
1130 (if (cc-bytecomp-fboundp 'make-overlay
)
1132 `(delete-overlay ,overlay
)
1134 `(delete-extent ,overlay
)))
1137 ;; Make edebug understand the macros.
1138 ;(eval-after-load "edebug" ; 2006-07-09: def-edebug-spec is now in subr.el.
1140 (def-edebug-spec cc-eval-when-compile
(&rest def-form
))
1141 (def-edebug-spec c-point t
)
1142 (def-edebug-spec c-set-region-active t
)
1143 (def-edebug-spec c-safe t
)
1144 (def-edebug-spec c-save-buffer-state let
*)
1145 (def-edebug-spec c-tentative-buffer-changes t
)
1146 (def-edebug-spec c-forward-syntactic-ws t
)
1147 (def-edebug-spec c-backward-syntactic-ws t
)
1148 (def-edebug-spec c-forward-sexp t
)
1149 (def-edebug-spec c-backward-sexp t
)
1150 (def-edebug-spec c-up-list-forward t
)
1151 (def-edebug-spec c-up-list-backward t
)
1152 (def-edebug-spec c-down-list-forward t
)
1153 (def-edebug-spec c-down-list-backward t
)
1154 (def-edebug-spec c-add-syntax t
)
1155 (def-edebug-spec c-add-class-syntax t
)
1156 (def-edebug-spec c-benign-error t
)
1157 (def-edebug-spec c-with-syntax-table t
)
1158 (def-edebug-spec c-skip-ws-forward t
)
1159 (def-edebug-spec c-skip-ws-backward t
)
1160 (def-edebug-spec c-major-mode-is t
)
1161 (def-edebug-spec c-put-char-property t
)
1162 (def-edebug-spec c-get-char-property t
)
1163 (def-edebug-spec c-clear-char-property t
)
1164 (def-edebug-spec c-clear-char-properties t
)
1165 (def-edebug-spec c-put-overlay t
)
1166 (def-edebug-spec c-delete-overlay t
) ;))
1171 ;; Note: All these after the macros, to be on safe side in avoiding
1172 ;; bugs where macros are defined too late. These bugs often only show
1173 ;; when the files are compiled in a certain order within the same
1176 (defsubst c-end-of-defun-1
()
1177 ;; Replacement for end-of-defun that use c-beginning-of-defun-1.
1178 (let ((start (point)))
1179 ;; Skip forward into the next defun block. Don't bother to avoid
1180 ;; comments, literals etc, since beginning-of-defun doesn't do that
1182 (skip-chars-forward "^}")
1183 (c-beginning-of-defun-1)
1184 (if (eq (char-after) ?
{)
1186 (if (< (point) start
)
1187 (goto-char (point-max)))))
1189 (defconst c-
<-as-paren-syntax
'(4 . ?
>))
1190 (put 'c-
<-as-paren-syntax
'syntax-table c-
<-as-paren-syntax
)
1192 (defsubst c-mark-
<-as-paren
(pos)
1193 ;; Mark the "<" character at POS as a template opener using the
1194 ;; `syntax-table' property via the `category' property.
1196 ;; This function does a hidden buffer change. Note that we use
1197 ;; indirection through the `category' text property. This allows us to
1198 ;; toggle the property in all template brackets simultaneously and
1199 ;; cheaply. We use this, for instance, in `c-parse-state'.
1200 (c-put-char-property pos
'category
'c-
<-as-paren-syntax
))
1202 (defconst c-
>-as-paren-syntax
'(5 . ?
<))
1203 (put 'c-
>-as-paren-syntax
'syntax-table c-
>-as-paren-syntax
)
1205 (defsubst c-mark-
>-as-paren
(pos)
1206 ;; Mark the ">" character at POS as an sexp list closer using the
1207 ;; syntax-table property.
1209 ;; This function does a hidden buffer change. Note that we use
1210 ;; indirection through the `category' text property. This allows us to
1211 ;; toggle the property in all template brackets simultaneously and
1212 ;; cheaply. We use this, for instance, in `c-parse-state'.
1213 (c-put-char-property pos
'category
'c-
>-as-paren-syntax
))
1215 (defsubst c-unmark-
<-
>-as-paren
(pos)
1216 ;; Unmark the "<" or "<" character at POS as an sexp list opener using
1217 ;; the syntax-table property indirectly through the `category' text
1220 ;; This function does a hidden buffer change. Note that we use
1221 ;; indirection through the `category' text property. This allows us to
1222 ;; toggle the property in all template brackets simultaneously and
1223 ;; cheaply. We use this, for instance, in `c-parse-state'.
1224 (c-clear-char-property pos
'category
))
1226 (defsubst c-suppress-
<-
>-as-parens
()
1227 ;; Suppress the syntactic effect of all marked < and > as parens. Note
1228 ;; that this effect is NOT buffer local. You should probably not use
1229 ;; this directly, but only through the macro
1230 ;; `c-with-<->-as-parens-suppressed'
1231 (put 'c-
<-as-paren-syntax
'syntax-table nil
)
1232 (put 'c-
>-as-paren-syntax
'syntax-table nil
))
1234 (defsubst c-restore-
<-
>-as-parens
()
1235 ;; Restore the syntactic effect of all marked <s and >s as parens. This
1236 ;; has no effect on unmarked <s and >s
1237 (put 'c-
<-as-paren-syntax
'syntax-table c-
<-as-paren-syntax
)
1238 (put 'c-
>-as-paren-syntax
'syntax-table c-
>-as-paren-syntax
))
1240 (defmacro c-with-
<-
>-as-parens-suppressed
(&rest forms
)
1241 ;; Like progn, except that the paren property is suppressed on all
1242 ;; template brackets whilst they are running. This macro does a hidden
1246 (c-suppress-<-
>-as-parens
)
1248 (c-restore-<-
>-as-parens
)))
1252 (defconst c-cpp-delimiter
'(14)) ; generic comment syntax
1253 ;; This is the value of the `category' text property placed on every #
1254 ;; which introduces a CPP construct and every EOL (or EOB, or character
1255 ;; preceding //, etc.) which terminates it. We can instantly "comment
1256 ;; out" all CPP constructs by giving `c-cpp-delimiter' a syntax-table
1257 ;; property '(14) (generic comment delimiter).
1258 (defmacro c-set-cpp-delimiters
(beg end
)
1259 ;; This macro does a hidden buffer change.
1261 (c-put-char-property ,beg
'category
'c-cpp-delimiter
)
1262 (if (< ,end
(point-max))
1263 (c-put-char-property ,end
'category
'c-cpp-delimiter
))))
1264 (defmacro c-clear-cpp-delimiters
(beg end
)
1265 ;; This macro does a hidden buffer change.
1267 (c-clear-char-property ,beg
'category
)
1268 (if (< ,end
(point-max))
1269 (c-clear-char-property ,end
'category
))))
1271 (defsubst c-comment-out-cpps
()
1272 ;; Render all preprocessor constructs syntactically commented out.
1273 (put 'c-cpp-delimiter
'syntax-table c-cpp-delimiter
))
1274 (defsubst c-uncomment-out-cpps
()
1275 ;; Restore the syntactic visibility of preprocessor constructs.
1276 (put 'c-cpp-delimiter
'syntax-table nil
))
1278 (defmacro c-with-cpps-commented-out
(&rest forms
)
1279 ;; Execute FORMS... whilst the syntactic effect of all characters in
1280 ;; all CPP regions is suppressed. In particular, this is to suppress
1281 ;; the syntactic significance of parens/braces/brackets to functions
1282 ;; such as `scan-lists' and `parse-partial-sexp'.
1284 (c-save-buffer-state ()
1285 (c-comment-out-cpps)
1287 (c-save-buffer-state ()
1288 (c-uncomment-out-cpps))))
1290 (defmacro c-with-all-but-one-cpps-commented-out
(beg end
&rest forms
)
1291 ;; Execute FORMS... whilst the syntactic effect of all characters in
1292 ;; every CPP region APART FROM THE ONE BETWEEN BEG and END is
1295 (c-save-buffer-state ()
1298 (c-clear-cpp-delimiters ,beg
,end
))
1299 ,`(c-with-cpps-commented-out ,@forms
))
1300 (c-save-buffer-state ()
1303 (c-set-cpp-delimiters ,beg
,end
)))))
1305 (defsubst c-intersect-lists
(list alist
)
1306 ;; return the element of ALIST that matches the first element found
1307 ;; in LIST. Uses assq.
1310 (not (setq match
(assq (car list
) alist
))))
1311 (setq list
(cdr list
)))
1314 (defsubst c-lookup-lists
(list alist1 alist2
)
1315 ;; first, find the first entry from LIST that is present in ALIST1,
1316 ;; then find the entry in ALIST2 for that entry.
1317 (assq (car (c-intersect-lists list alist1
)) alist2
))
1319 (defsubst c-langelem-sym
(langelem)
1320 "Return the syntactic symbol in LANGELEM.
1322 LANGELEM is either a cons cell on the \"old\" form given as the first
1323 argument to lineup functions or a syntactic element on the \"new\"
1324 form as used in `c-syntactic-element'."
1327 (defsubst c-langelem-pos
(langelem)
1328 "Return the anchor position in LANGELEM, or nil if there is none.
1330 LANGELEM is either a cons cell on the \"old\" form given as the first
1331 argument to lineup functions or a syntactic element on the \"new\"
1332 form as used in `c-syntactic-element'."
1333 (if (consp (cdr langelem
))
1334 (car-safe (cdr langelem
))
1337 (defun c-langelem-col (langelem &optional preserve-point
)
1338 "Return the column of the anchor position in LANGELEM.
1339 Also move the point to that position unless PRESERVE-POINT is non-nil.
1341 LANGELEM is either a cons cell on the \"old\" form given as the first
1342 argument to lineup functions or a syntactic element on the \"new\"
1343 form as used in `c-syntactic-element'."
1344 (let ((pos (c-langelem-pos langelem
))
1349 (prog1 (current-column)
1354 (defsubst c-langelem-2nd-pos
(langelem)
1355 "Return the secondary position in LANGELEM, or nil if there is none.
1357 LANGELEM is typically a syntactic element on the \"new\" form as used
1358 in `c-syntactic-element'. It may also be a cons cell as passed in the
1359 first argument to lineup functions, but then the returned value always
1361 (car-safe (cdr-safe (cdr-safe langelem
))))
1363 (defsubst c-keep-region-active
()
1364 ;; Do whatever is necessary to keep the region active in XEmacs.
1365 ;; This is not needed for Emacs.
1366 (and (boundp 'zmacs-region-stays
)
1367 (setq zmacs-region-stays t
)))
1369 (put 'c-mode
'c-mode-prefix
"c-")
1370 (put 'c
++-mode
'c-mode-prefix
"c++-")
1371 (put 'objc-mode
'c-mode-prefix
"objc-")
1372 (put 'java-mode
'c-mode-prefix
"java-")
1373 (put 'idl-mode
'c-mode-prefix
"idl-")
1374 (put 'pike-mode
'c-mode-prefix
"pike-")
1375 (put 'awk-mode
'c-mode-prefix
"awk-")
1377 (defsubst c-mode-symbol
(suffix)
1378 "Prefix the current mode prefix (e.g. \"c-\") to SUFFIX and return
1379 the corresponding symbol."
1380 (or c-buffer-is-cc-mode
1381 (error "Not inside a CC Mode based mode"))
1382 (let ((mode-prefix (get c-buffer-is-cc-mode
'c-mode-prefix
)))
1384 (error "%S has no mode prefix known to `c-mode-symbol'"
1385 c-buffer-is-cc-mode
))
1386 (intern (concat mode-prefix suffix
))))
1388 (defsubst c-mode-var
(suffix)
1389 "Prefix the current mode prefix (e.g. \"c-\") to SUFFIX and return
1390 the value of the variable with that name."
1391 (symbol-value (c-mode-symbol suffix
)))
1393 (defsubst c-got-face-at
(pos faces
)
1394 "Return non-nil if position POS in the current buffer has any of the
1395 faces in the list FACES."
1396 (let ((pos-faces (get-text-property pos
'face
)))
1397 (if (consp pos-faces
)
1399 (while (and pos-faces
1400 (not (memq (car pos-faces
) faces
)))
1401 (setq pos-faces
(cdr pos-faces
)))
1403 (memq pos-faces faces
))))
1405 (defsubst c-face-name-p
(facename)
1406 ;; Return t if FACENAME is the name of a face. This method is
1407 ;; necessary since facep in XEmacs only returns t for the actual
1408 ;; face objects (while it's only their names that are used just
1409 ;; about anywhere else) without providing a predicate that tests
1411 (memq facename
(face-list)))
1413 (defun c-concat-separated (list separator
)
1414 "Like `concat' on LIST, but separate each element with SEPARATOR.
1415 Notably, null elements in LIST are ignored."
1416 (mapconcat 'identity
(delete nil
(append list nil
)) separator
))
1418 (defun c-make-keywords-re (adorn list
&optional mode
)
1419 "Make a regexp that matches all the strings the list.
1420 Duplicates and nil elements in the list are removed. The resulting
1421 regexp may contain zero or more submatch expressions.
1423 If ADORN is t there will be at least one submatch and the first
1424 surrounds the matched alternative, and the regexp will also not match
1425 a prefix of any identifier. Adorned regexps cannot be appended. The
1426 language variable `c-nonsymbol-key' is used to make the adornment.
1428 A value 'appendable for ADORN is like above, but all alternatives in
1429 the list that end with a word constituent char will have \\> appended
1430 instead, so that the regexp remains appendable. Note that this
1431 variant doesn't always guarantee that an identifier prefix isn't
1432 matched since the symbol constituent '_' is normally considered a
1433 nonword token by \\>.
1435 The optional MODE specifies the language to get `c-nonsymbol-key' from
1436 when it's needed. The default is the current language taken from
1437 `c-buffer-is-cc-mode'."
1441 (unless (member elt unique
)
1443 (setq list
(delete nil unique
)))
1447 (if (eq adorn
'appendable
)
1448 ;; This is kludgy but it works: Search for a string that
1449 ;; doesn't occur in any word in LIST. Append it to all
1450 ;; the alternatives where we want to add \>. Run through
1451 ;; `regexp-opt' and then replace it with \>.
1452 (let ((unique "") pos
)
1454 (setq unique
(concat unique
"@")
1457 (if (string-match unique
(car pos
))
1458 (progn (setq found t
)
1461 (setq pos
(cdr pos
)))
1465 (if (string-match "\\w\\'" (car pos
))
1466 (setcar pos
(concat (car pos
) unique
)))
1467 (setq pos
(cdr pos
)))
1468 (setq re
(regexp-opt list
))
1470 (while (string-match unique re pos
)
1471 (setq pos
(+ (match-beginning 0) 2)
1472 re
(replace-match "\\>" t t re
))))
1474 (setq re
(regexp-opt list
)))
1476 ;; Emacs 20 and XEmacs (all versions so far) has a buggy
1477 ;; regexp-opt that doesn't always cope with strings containing
1478 ;; newlines. This kludge doesn't handle shy parens correctly
1479 ;; so we can't advice regexp-opt directly with it.
1482 (and (string-match "\n" (car list
)) ; To speed it up a little.
1483 (not (string-match (concat "\\`\\(" re
"\\)\\'")
1485 (setq fail-list
(cons (car list
) fail-list
)))
1486 (setq list
(cdr list
)))
1491 (if (eq adorn
'appendable
)
1493 (if (string-match "\\w\\'" str
)
1494 (concat (regexp-quote str
)
1496 (regexp-quote str
)))
1500 (> (length a
) (length b
))))
1503 ;; Add our own grouping parenthesis around re instead of
1504 ;; passing adorn to `regexp-opt', since in XEmacs it makes the
1505 ;; top level grouping "shy".
1506 (cond ((eq adorn
'appendable
)
1507 (concat "\\(" re
"\\)"))
1509 (concat "\\(" re
"\\)"
1511 (c-get-lang-constant 'c-nonsymbol-key nil mode
)
1516 ;; Produce a regexp that matches nothing.
1521 (put 'c-make-keywords-re
'lisp-indent-function
1)
1523 (defun c-make-bare-char-alt (chars &optional inverted
)
1524 "Make a character alternative string from the list of characters CHARS.
1525 The returned string is of the type that can be used with
1526 `skip-chars-forward' and `skip-chars-backward'. If INVERTED is
1527 non-nil, a caret is prepended to invert the set."
1528 ;; This function ought to be in the elisp core somewhere.
1529 (let ((str (if inverted
"^" "")) char char2
)
1530 (setq chars
(sort (append chars nil
) `<))
1532 (setq char
(pop chars
))
1533 (if (memq char
'(?
\\ ?^ ?-
))
1534 ;; Quoting necessary (this method only works in the skip
1536 (setq str
(format "%s\\%c" str char
))
1537 (setq str
(format "%s%c" str char
)))
1540 (while (and chars
(>= (1+ char2
) (car chars
)))
1541 (setq char2
(pop chars
)))
1542 (unless (= char char2
)
1543 (if (< (1+ char
) char2
)
1544 (setq str
(format "%s-%c" str char2
))
1545 (push char2 chars
))))
1548 ;; Leftovers from (X)Emacs 19 compatibility.
1549 (defalias 'c-regexp-opt
'regexp-opt
)
1550 (defalias 'c-regexp-opt-depth
'regexp-opt-depth
)
1553 ;; Figure out what features this Emacs has
1555 (cc-bytecomp-defvar open-paren-in-column-0-is-defun-start
)
1557 (defconst c-emacs-features
1560 (if (boundp 'infodock-version
)
1561 ;; I've no idea what this actually is, but it's legacy. /mast
1562 (setq list
(cons 'infodock list
)))
1564 ;; XEmacs uses 8-bit modify-syntax-entry flags.
1565 ;; Emacs uses a 1-bit flag. We will have to set up our
1566 ;; syntax tables differently to handle this.
1567 (let ((table (copy-syntax-table))
1569 (modify-syntax-entry ?a
". 12345678" table
)
1573 (setq entry
(aref table ?a
))
1574 ;; In Emacs, table entries are cons cells
1575 (if (consp entry
) (setq entry
(car entry
))))
1577 ((fboundp 'get-char-table
)
1578 (setq entry
(get-char-table ?a table
)))
1580 (t (error "CC Mode is incompatible with this version of Emacs")))
1581 (setq list
(cons (if (= (logand (lsh entry -
16) 255) 255)
1586 ;; Check whether beginning/end-of-defun call
1587 ;; beginning/end-of-defun-function nicely, passing through the
1588 ;; argument and respecting the return code.
1590 (bod-param 'foo
) (eod-param 'foo
)
1591 (beginning-of-defun-function
1592 (lambda (&optional arg
)
1593 (or (eq bod-param
'foo
) (setq bod-param
'bar
))
1594 (and (eq bod-param
'foo
)
1595 (setq bod-param arg
)
1597 (end-of-defun-function
1598 (lambda (&optional arg
)
1599 (and (eq eod-param
'foo
)
1600 (setq eod-param arg
)
1602 (if (save-excursion (and (beginning-of-defun 3) (eq bod-param
3)
1603 (not (beginning-of-defun))
1604 (end-of-defun 3) (eq eod-param
3)
1605 (not (end-of-defun))))
1606 (setq list
(cons 'argumentative-bod-function list
))))
1608 (let ((buf (generate-new-buffer " test"))
1609 parse-sexp-lookup-properties
1610 parse-sexp-ignore-comments
1611 lookup-syntax-properties
) ; XEmacs
1612 (with-current-buffer buf
1613 (set-syntax-table (make-syntax-table))
1615 ;; For some reason we have to set some of these after the
1616 ;; buffer has been made current. (Specifically,
1617 ;; `parse-sexp-ignore-comments' in Emacs 21.)
1618 (setq parse-sexp-lookup-properties t
1619 parse-sexp-ignore-comments t
1620 lookup-syntax-properties t
)
1622 ;; Find out if the `syntax-table' text property works.
1623 (modify-syntax-entry ?
< ".")
1624 (modify-syntax-entry ?
> ".")
1626 (c-mark-<-as-paren
(point-min))
1627 (c-mark->-as-paren
(+ 3 (point-min)))
1628 (goto-char (point-min))
1630 (if (= (point) (+ 4 (point-min)))
1631 (setq list
(cons 'syntax-properties list
))
1633 "CC Mode is incompatible with this version of Emacs - "
1634 "support for the `syntax-table' text property "
1637 ;; Find out if generic comment delimiters work.
1639 (modify-syntax-entry ?x
"!")
1640 (if (string-match "\\s!" "x")
1641 (setq list
(cons 'gen-comment-delim list
))))
1643 ;; Find out if generic string delimiters work.
1645 (modify-syntax-entry ?x
"|")
1646 (if (string-match "\\s|" "x")
1647 (setq list
(cons 'gen-string-delim list
))))
1649 ;; See if POSIX char classes work.
1650 (when (and (string-match "[[:alpha:]]" "a")
1651 ;; All versions of Emacs 21 so far haven't fixed
1652 ;; char classes in `skip-chars-forward' and
1653 ;; `skip-chars-backward'.
1655 (delete-region (point-min) (point-max))
1657 (skip-chars-backward "[:alnum:]")
1659 (= (skip-chars-forward "[:alpha:]") 3))
1660 (setq list
(cons 'posix-char-classes list
)))
1662 ;; See if `open-paren-in-column-0-is-defun-start' exists and
1663 ;; isn't buggy (Emacs >= 21.4).
1664 (when (boundp 'open-paren-in-column-0-is-defun-start
)
1665 (let ((open-paren-in-column-0-is-defun-start nil
)
1666 (parse-sexp-ignore-comments t
))
1667 (delete-region (point-min) (point-max))
1668 (set-syntax-table (make-syntax-table))
1669 (modify-syntax-entry ?
\' "\"")
1671 ;; XEmacs. Afaik this is currently an Emacs-only
1672 ;; feature, but it's good to be prepared.
1674 (modify-syntax-entry ?
/ ". 1456")
1675 (modify-syntax-entry ?
* ". 23"))
1678 (modify-syntax-entry ?
/ ". 124b")
1679 (modify-syntax-entry ?
* ". 23")))
1680 (modify-syntax-entry ?
\n "> b")
1681 (insert "/* '\n () */")
1684 (setq list
(cons 'col-0-paren list
)))))
1686 (set-buffer-modified-p nil
))
1689 ;; See if `parse-partial-sexp' returns the eighth element.
1690 (if (c-safe (>= (length (save-excursion (parse-partial-sexp (point) (point))))
1692 (setq list
(cons 'pps-extended-state list
))
1694 "CC Mode is incompatible with this version of Emacs - "
1695 "`parse-partial-sexp' has to return at least 10 elements.")))
1697 ;;(message "c-emacs-features: %S" list)
1699 "A list of certain features in the (X)Emacs you are using.
1700 There are many flavors of Emacs out there, each with different
1701 features supporting those needed by CC Mode. The following values
1704 '8-bit 8 bit syntax entry flags (XEmacs style).
1705 '1-bit 1 bit syntax entry flags (Emacs style).
1706 'argumentative-bod-function beginning-of-defun passes ARG through
1707 to a non-null beginning-of-defun-function. It is assumed
1708 the end-of-defun does the same thing.
1709 'syntax-properties It works to override the syntax for specific characters
1710 in the buffer with the 'syntax-table property. It's
1711 always set - CC Mode no longer works in emacsen without
1713 'gen-comment-delim Generic comment delimiters work
1714 (i.e. the syntax class `!').
1715 'gen-string-delim Generic string delimiters work
1716 (i.e. the syntax class `|').
1717 'pps-extended-state `parse-partial-sexp' returns a list with at least 10
1718 elements, i.e. it contains the position of the start of
1719 the last comment or string. It's always set - CC Mode
1720 no longer works in emacsen without this feature.
1721 'posix-char-classes The regexp engine understands POSIX character classes.
1722 'col-0-paren It's possible to turn off the ad-hoc rule that a paren
1723 in column zero is the start of a defun.
1724 'infodock This is Infodock (based on XEmacs).
1726 '8-bit and '1-bit are mutually exclusive.")
1729 ;;; Some helper constants.
1731 ;; If the regexp engine supports POSIX char classes then we can use
1732 ;; them to handle extended charsets correctly.
1733 (if (memq 'posix-char-classes c-emacs-features
)
1735 (defconst c-alpha
"[:alpha:]")
1736 (defconst c-alnum
"[:alnum:]")
1737 (defconst c-digit
"[:digit:]")
1738 (defconst c-upper
"[:upper:]")
1739 (defconst c-lower
"[:lower:]"))
1740 (defconst c-alpha
"a-zA-Z")
1741 (defconst c-alnum
"a-zA-Z0-9")
1742 (defconst c-digit
"0-9")
1743 (defconst c-upper
"A-Z")
1744 (defconst c-lower
"a-z"))
1747 ;;; System for handling language dependent constants.
1749 ;; This is used to set various language dependent data in a flexible
1750 ;; way: Language constants can be built from the values of other
1751 ;; language constants, also those for other languages. They can also
1752 ;; process the values of other language constants uniformly across all
1753 ;; the languages. E.g. one language constant can list all the type
1754 ;; keywords in each language, and another can build a regexp for each
1755 ;; language from those lists without code duplication.
1757 ;; Language constants are defined with `c-lang-defconst', and their
1758 ;; value forms (referred to as source definitions) are evaluated only
1759 ;; on demand when requested for a particular language with
1760 ;; `c-lang-const'. It's therefore possible to refer to the values of
1761 ;; constants defined later in the file, or in another file, just as
1762 ;; long as all the relevant `c-lang-defconst' have been loaded when
1763 ;; `c-lang-const' is actually evaluated from somewhere else.
1765 ;; `c-lang-const' forms are also evaluated at compile time and
1766 ;; replaced with the values they produce. Thus there's no overhead
1767 ;; for this system when compiled code is used - only the values
1768 ;; actually used in the code are present, and the file(s) containing
1769 ;; the `c-lang-defconst' forms don't need to be loaded at all then.
1770 ;; There are however safeguards to make sure that they can be loaded
1771 ;; to get the source definitions for the values if there's a mismatch
1772 ;; in compiled versions, or if `c-lang-const' is used uncompiled.
1774 ;; Note that the source definitions in a `c-lang-defconst' form are
1775 ;; compiled into the .elc file where it stands; there's no need to
1776 ;; load the source file to get it.
1778 ;; See cc-langs.el for more details about how this system is deployed
1779 ;; in CC Mode, and how the associated language variable system
1780 ;; (`c-lang-defvar') works. That file also contains a lot of
1783 (defun c-add-language (mode base-mode
)
1784 "Declare a new language in the language dependent variable system.
1785 This is intended to be used by modes that inherit CC Mode to add new
1786 languages. It should be used at the top level before any calls to
1787 `c-lang-defconst'. MODE is the mode name symbol for the new language,
1788 and BASE-MODE is the mode name symbol for the language in CC Mode that
1789 is to be the template for the new mode.
1791 The exact effect of BASE-MODE is to make all language constants that
1792 haven't got a setting in the new language fall back to their values in
1793 BASE-MODE. It does not have any effect outside the language constant
1795 (unless (string-match "\\`\\(.*-\\)mode\\'" (symbol-name mode
))
1796 (error "The mode name symbol `%s' must end with \"-mode\"" mode
))
1797 (put mode
'c-mode-prefix
(match-string 1 (symbol-name mode
)))
1798 (unless (get base-mode
'c-mode-prefix
)
1799 (error "Unknown base mode `%s'" base-mode
))
1800 (put mode
'c-fallback-mode base-mode
))
1802 (defvar c-lang-constants
(make-vector 151 0))
1803 ;; This obarray is a cache to keep track of the language constants
1804 ;; defined by `c-lang-defconst' and the evaluated values returned by
1805 ;; `c-lang-const'. It's mostly used at compile time but it's not
1806 ;; stored in compiled files.
1808 ;; The obarray contains all the language constants as symbols. The
1809 ;; value cells hold the evaluated values as alists where each car is
1810 ;; the mode name symbol and the corresponding cdr is the evaluated
1811 ;; value in that mode. The property lists hold the source definitions
1812 ;; and other miscellaneous data. The obarray might also contain
1813 ;; various other symbols, but those don't have any variable bindings.
1815 (defvar c-lang-const-expansion nil
)
1817 (defsubst c-get-current-file
()
1818 ;; Return the base name of the current file.
1823 ((and (boundp 'byte-compile-dest-file
)
1824 (stringp byte-compile-dest-file
))
1826 byte-compile-dest-file
)
1828 ;; Being evaluated interactively.
1829 (buffer-file-name)))))
1830 (and file
(file-name-base file
))))
1832 (defmacro c-lang-defconst-eval-immediately
(form)
1833 "Can be used inside a VAL in `c-lang-defconst' to evaluate FORM
1834 immediately, i.e. at the same time as the `c-lang-defconst' form
1835 itself is evaluated."
1836 ;; Evaluate at macro expansion time, i.e. in the
1837 ;; `cl-macroexpand-all' inside `c-lang-defconst'.
1840 ;; Only used at compile time - suppress "might not be defined at runtime".
1841 (declare-function cl-macroexpand-all
"cl" (form &optional env
))
1843 (defmacro c-lang-defconst
(name &rest args
)
1844 "Set the language specific values of the language constant NAME.
1845 The second argument can optionally be a docstring. The rest of the
1846 arguments are one or more repetitions of LANG VAL where LANG specifies
1847 the language(s) that VAL applies to. LANG is the name of the
1848 language, i.e. the mode name without the \"-mode\" suffix, or a list
1849 of such language names, or `t' for all languages. VAL is a form to
1850 evaluate to get the value.
1852 If LANG isn't `t' or one of the core languages in CC Mode, it must
1853 have been declared with `c-add-language'.
1855 Neither NAME, LANG nor VAL are evaluated directly - they should not be
1856 quoted. `c-lang-defconst-eval-immediately' can however be used inside
1857 VAL to evaluate parts of it directly.
1859 When VAL is evaluated for some language, that language is temporarily
1860 made current so that `c-lang-const' without an explicit language can
1861 be used inside VAL to refer to the value of a language constant in the
1862 same language. That is particularly useful if LANG is `t'.
1864 VAL is not evaluated right away but rather when the value is requested
1865 with `c-lang-const'. Thus it's possible to use `c-lang-const' inside
1866 VAL to refer to language constants that haven't been defined yet.
1867 However, if the definition of a language constant is in another file
1868 then that file must be loaded \(at compile time) before it's safe to
1869 reference the constant.
1871 The assignments in ARGS are processed in sequence like `setq', so
1872 \(c-lang-const NAME) may be used inside a VAL to refer to the last
1873 assigned value to this language constant, or a value that it has
1874 gotten in another earlier loaded file.
1876 To work well with repeated loads and interactive reevaluation, only
1877 one `c-lang-defconst' for each NAME is permitted per file. If there
1878 already is one it will be completely replaced; the value in the
1879 earlier definition will not affect `c-lang-const' on the same
1880 constant. A file is identified by its base name."
1882 (let* ((sym (intern (symbol-name name
) c-lang-constants
))
1883 ;; Make `c-lang-const' expand to a straightforward call to
1884 ;; `c-get-lang-constant' in `cl-macroexpand-all' below.
1886 ;; (The default behavior, i.e. to expand to a call inside
1887 ;; `eval-when-compile' should be equivalent, since that macro
1888 ;; should only expand to its content if it's used inside a
1889 ;; form that's already evaluated at compile time. It's
1890 ;; however necessary to use our cover macro
1891 ;; `cc-eval-when-compile' due to bugs in `eval-when-compile',
1892 ;; and it expands to a bulkier form that in this case only is
1893 ;; unnecessary garbage that we don't want to store in the
1894 ;; language constant source definitions.)
1895 (c-lang-const-expansion 'call
)
1896 (c-langs-are-parametric t
)
1901 (error "Not a symbol: %s" name
))
1903 (when (stringp (car-safe args
))
1904 ;; The docstring is hardly used anywhere since there's no normal
1905 ;; symbol to attach it to. It's primarily for getting the right
1906 ;; format in the source.
1907 (put sym
'variable-documentation
(car args
))
1908 (setq args
(cdr args
)))
1911 (error "No assignments in `c-lang-defconst' for %s" name
))
1913 ;; Rework ARGS to an association list to make it easier to handle.
1914 ;; It's reversed at the same time to make it easier to implement
1915 ;; the demand-driven (i.e. reversed) evaluation in `c-lang-const'.
1917 (let ((assigned-mode
1918 (cond ((eq (car args
) t
) t
)
1919 ((symbolp (car args
))
1920 (list (intern (concat (symbol-name (car args
))
1923 (mapcar (lambda (lang)
1925 (error "Not a list of symbols: %s"
1927 (intern (concat (symbol-name lang
)
1930 (t (error "Not a symbol or a list of symbols: %s"
1935 (error "No value for %s" (car args
)))
1936 (setq args
(cdr args
)
1939 ;; Emacs has a weird bug where it seems to fail to read
1940 ;; backquote lists from byte compiled files correctly (,@
1941 ;; forms, to be specific), so make sure the bindings in the
1942 ;; expansion below don't contain any backquote stuff.
1943 ;; (XEmacs handles it correctly and doesn't need this for that
1944 ;; reason, but we also use this expansion handle
1945 ;; `c-lang-defconst-eval-immediately' and to register
1946 ;; dependencies on the `c-lang-const's in VAL.)
1947 (setq val
(cl-macroexpand-all val
))
1949 (setq bindings
(cons (cons assigned-mode val
) bindings
)
1952 ;; Compile in the other files that have provided source
1953 ;; definitions for this symbol, to make sure the order in the
1954 ;; `source' property is correct even when files are loaded out of
1956 (setq pre-files
(nreverse
1957 ;; Reverse to get the right load order.
1958 (mapcar 'car
(get sym
'source
))))
1961 (c-define-lang-constant ',name
',bindings
1962 ,@(and pre-files
`(',pre-files
))))))
1964 (put 'c-lang-defconst
'lisp-indent-function
1)
1965 ;(eval-after-load "edebug" ; 2006-07-09: def-edebug-spec is now in subr.el.
1967 (def-edebug-spec c-lang-defconst
1968 (&define name
[&optional stringp
] [&rest sexp def-form
]))
1970 (defun c-define-lang-constant (name bindings
&optional pre-files
)
1971 ;; Used by `c-lang-defconst'.
1973 (let* ((sym (intern (symbol-name name
) c-lang-constants
))
1974 (source (get sym
'source
))
1976 (or (c-get-current-file)
1977 (error "`c-lang-defconst' must be used in a file"))))
1978 (elem (assq file source
)))
1980 ;;(when (cdr-safe elem)
1981 ;; (message "Language constant %s redefined in %S" name file))
1983 ;; Note that the order in the source alist is relevant. Like how
1984 ;; `c-lang-defconst' reverses the bindings, this reverses the
1985 ;; order between files so that the last to evaluate comes first.
1988 (unless (assq (car pre-files
) source
)
1989 (setq source
(cons (list (car pre-files
)) source
)))
1990 (setq pre-files
(cdr pre-files
)))
1991 (put sym
'source
(cons (setq elem
(list file
)) source
)))
1993 (setcdr elem bindings
)
1995 ;; Bind the symbol as a variable, or clear any earlier evaluated
1999 ;; Clear the evaluated values that depend on this source.
2000 (let ((agenda (get sym
'dependents
))
2001 (visited (make-vector 101 0))
2004 (setq sym
(car agenda
)
2005 agenda
(cdr agenda
))
2006 (intern (symbol-name sym
) visited
)
2008 (setq ptr
(get sym
'dependents
))
2012 (unless (intern-soft (symbol-name sym
) visited
)
2013 (setq agenda
(cons sym agenda
))))))
2017 (defmacro c-lang-const
(name &optional lang
)
2018 "Get the mode specific value of the language constant NAME in language LANG.
2019 LANG is the name of the language, i.e. the mode name without the
2020 \"-mode\" suffix. If used inside `c-lang-defconst' or
2021 `c-lang-defvar', LANG may be left out to refer to the current
2022 language. NAME and LANG are not evaluated so they should not be
2026 (error "Not a symbol: %s" name
))
2028 (error "Not a symbol: %s" lang
))
2030 (let ((sym (intern (symbol-name name
) c-lang-constants
))
2031 mode source-files args
)
2034 (setq mode
(intern (concat (symbol-name lang
) "-mode")))
2035 (unless (get mode
'c-mode-prefix
)
2037 "Unknown language %S since it got no `c-mode-prefix' property"
2038 (symbol-name lang
))))
2040 (if (eq c-lang-const-expansion
'immediate
)
2041 ;; No need to find out the source file(s) when we evaluate
2042 ;; immediately since all the info is already there in the
2043 ;; `source' property.
2044 `',(c-get-lang-constant name nil mode
)
2046 (let ((file (c-get-current-file)))
2047 (if file
(setq file
(intern file
)))
2048 ;; Get the source file(s) that must be loaded to get the value
2049 ;; of the constant. If the symbol isn't defined yet we assume
2050 ;; that its definition will come later in this file, and thus
2051 ;; are no file dependencies needed.
2052 (setq source-files
(nreverse
2053 ;; Reverse to get the right load order.
2055 (mapcar (lambda (elem)
2056 (if (eq file
(car elem
))
2057 nil
; Exclude our own file.
2059 (get sym
'source
))))))
2061 ;; Make some effort to do a compact call to
2062 ;; `c-get-lang-constant' since it will be compiled in.
2063 (setq args
(and mode
`(',mode
)))
2064 (if (or source-files args
)
2065 (setq args
(cons (and source-files
`',source-files
)
2068 (if (or (eq c-lang-const-expansion
'call
)
2069 (and (not c-lang-const-expansion
)
2072 (not (boundp 'byte-compile-dest-file
))
2073 (not (stringp byte-compile-dest-file
)))
2074 ;; Either a straight call is requested in the context, or
2075 ;; we're in an "uncontrolled" context and got no language,
2076 ;; or we're not being byte compiled so the compile time
2077 ;; stuff below is unnecessary.
2078 `(c-get-lang-constant ',name
,@args
)
2080 ;; Being compiled. If the loading and compiling version is
2081 ;; the same we use a value that is evaluated at compile time,
2082 ;; otherwise it's evaluated at runtime.
2083 `(if (eq c-version-sym
',c-version-sym
)
2084 (cc-eval-when-compile
2085 (c-get-lang-constant ',name
,@args
))
2086 (c-get-lang-constant ',name
,@args
))))))
2088 (defvar c-lang-constants-under-evaluation nil
)
2090 (defun c-get-lang-constant (name &optional source-files mode
)
2091 ;; Used by `c-lang-const'.
2094 (setq mode c-buffer-is-cc-mode
)
2095 (error "No current language"))
2097 (let* ((sym (intern (symbol-name name
) c-lang-constants
))
2098 (source (get sym
'source
))
2100 (eval-in-sym (and c-lang-constants-under-evaluation
2101 (caar c-lang-constants-under-evaluation
))))
2103 ;; Record the dependencies between this symbol and the one we're
2104 ;; being evaluated in.
2106 (or (memq eval-in-sym
(get sym
'dependents
))
2107 (put sym
'dependents
(cons eval-in-sym
(get sym
'dependents
)))))
2109 ;; Make sure the source files have entries on the `source'
2110 ;; property so that loading will take place when necessary.
2112 (unless (assq (car source-files
) source
)
2114 (setq source
(cons (list (car source-files
)) source
)))
2115 ;; Might pull in more definitions which affect the value. The
2116 ;; clearing of dependent values etc is done when the
2117 ;; definition is encountered during the load; this is just to
2118 ;; jump past the check for a cached value below.
2120 (setq source-files
(cdr source-files
)))
2122 (if (and (boundp sym
)
2123 (setq elem
(assq mode
(symbol-value sym
))))
2126 ;; Check if an evaluation of this symbol is already underway.
2127 ;; In that case we just continue with the "assignment" before
2128 ;; the one currently being evaluated, thereby creating the
2129 ;; illusion if a `setq'-like sequence of assignments.
2130 (let* ((c-buffer-is-cc-mode mode
)
2132 (or (assq sym c-lang-constants-under-evaluation
)
2133 (cons sym
(vector source nil
))))
2134 ;; Append `c-lang-constants-under-evaluation' even if an
2135 ;; earlier entry is found. It's only necessary to get
2136 ;; the recording of dependencies above correct.
2137 (c-lang-constants-under-evaluation
2138 (cons source-pos c-lang-constants-under-evaluation
))
2139 (fallback (get mode
'c-fallback-mode
))
2141 ;; Make sure the recursion limits aren't very low
2142 ;; since the `c-lang-const' dependencies can go deep.
2143 (max-specpdl-size (max max-specpdl-size
3000))
2144 (max-lisp-eval-depth (max max-lisp-eval-depth
1000)))
2147 (let ((backup-source-pos (copy-sequence (cdr source-pos
))))
2149 ;; First try the original mode but don't accept an
2150 ;; entry matching all languages since the fallback
2151 ;; mode might have an explicit entry before that.
2152 (eq (setq value
(c-find-assignment-for-mode
2153 (cdr source-pos
) mode nil name
))
2155 ;; Try again with the fallback mode from the
2156 ;; original position. Note that
2157 ;; `c-buffer-is-cc-mode' still is the real mode if
2158 ;; language parameterization takes place.
2159 (eq (setq value
(c-find-assignment-for-mode
2160 (setcdr source-pos backup-source-pos
)
2163 ;; A simple lookup with no fallback mode.
2164 (eq (setq value
(c-find-assignment-for-mode
2165 (cdr source-pos
) mode t name
))
2168 "`%s' got no (prior) value in %s (might be a cyclic reference)"
2172 (setq value
(eval value
))
2174 ;; Print a message to aid in locating the error. We don't
2175 ;; print the error itself since that will be done later by
2176 ;; some caller higher up.
2177 (message "Eval error in the `c-lang-defconst' for `%s' in %s:"
2180 (signal (car err
) (cdr err
))))
2182 (set sym
(cons (cons mode value
) (symbol-value sym
)))
2185 (defun c-find-assignment-for-mode (source-pos mode match-any-lang name
)
2186 ;; Find the first assignment entry that applies to MODE at or after
2187 ;; SOURCE-POS. If MATCH-ANY-LANG is non-nil, entries with `t' as
2188 ;; the language list are considered to match, otherwise they don't.
2189 ;; On return SOURCE-POS is updated to point to the next assignment
2190 ;; after the returned one. If no assignment is found,
2191 ;; `c-lang-constants' is returned as a magic value.
2193 ;; SOURCE-POS is a vector that points out a specific assignment in
2194 ;; the double alist that's used in the `source' property. The first
2195 ;; element is the position in the top alist which is indexed with
2196 ;; the source files, and the second element is the position in the
2197 ;; nested bindings alist.
2199 ;; NAME is only used for error messages.
2202 (let ((file-entry (elt source-pos
0))
2203 (assignment-entry (elt source-pos
1))
2206 (while (if assignment-entry
2208 ;; Handled the last assignment from one file, begin on the
2209 ;; next. Due to the check in `c-lang-defconst', we know
2210 ;; there's at least one.
2213 (unless (aset source-pos
1
2214 (setq assignment-entry
(cdar file-entry
)))
2215 ;; The file containing the source definitions has not
2217 (let ((file (symbol-name (caar file-entry
)))
2218 (c-lang-constants-under-evaluation nil
))
2219 ;;(message (concat "Loading %s to get the source "
2220 ;; "value for language constant %s")
2224 (unless (setq assignment-entry
(cdar file-entry
))
2225 ;; The load didn't fill in the source for the
2226 ;; constant as expected. The situation is
2227 ;; probably that a derived mode was written for
2228 ;; and compiled with another version of CC Mode,
2229 ;; and the requested constant isn't in the
2230 ;; currently loaded one. Put in a dummy
2231 ;; assignment that matches no language.
2232 (setcdr (car file-entry
)
2233 (setq assignment-entry
(list (list nil
))))))
2235 (aset source-pos
0 (setq file-entry
(cdr file-entry
)))
2238 (setq assignment
(car assignment-entry
))
2240 (setq assignment-entry
(cdr assignment-entry
)))
2242 (when (if (listp (car assignment
))
2243 (memq mode
(car assignment
))
2245 (throw 'found
(cdr assignment
))))
2249 (defun c-lang-major-mode-is (mode)
2250 ;; `c-major-mode-is' expands to a call to this function inside
2251 ;; `c-lang-defconst'. Here we also match the mode(s) against any
2252 ;; fallback modes for the one in `c-buffer-is-cc-mode', so that
2253 ;; e.g. (c-major-mode-is 'c++-mode) is true in a derived language
2254 ;; that has c++-mode as base mode.
2255 (unless (listp mode
)
2256 (setq mode
(list mode
)))
2257 (let (match (buf-mode c-buffer-is-cc-mode
))
2258 (while (if (memq buf-mode mode
)
2262 (setq buf-mode
(get buf-mode
'c-fallback-mode
))))
2266 (cc-provide 'cc-defs
)
2268 ;;; cc-defs.el ends here