;;; cc-engine.el --- core syntax guessing engine for CC mode ;; Copyright (C) 1985, 1987, 1992, 1993, 1994, 1995, 1996, 1997, 1998, ;; 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007 ;; Free Software Foundation, Inc. ;; Authors: 2001- Alan Mackenzie ;; 1998- Martin Stjernholm ;; 1992-1999 Barry A. Warsaw ;; 1987 Dave Detlefs and Stewart Clamen ;; 1985 Richard M. Stallman ;; Maintainer: bug-cc-mode@gnu.org ;; Created: 22-Apr-1997 (split from cc-mode.el) ;; Version: See cc-mode.el ;; Keywords: c languages oop ;; This file is part of GNU Emacs. ;; GNU Emacs is free software; you can redistribute it and/or modify ;; it under the terms of the GNU General Public License as published by ;; the Free Software Foundation; either version 2, or (at your option) ;; any later version. ;; GNU Emacs is distributed in the hope that it will be useful, ;; but WITHOUT ANY WARRANTY; without even the implied warranty of ;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ;; GNU General Public License for more details. ;; You should have received a copy of the GNU General Public License ;; along with this program; see the file COPYING. If not, write to ;; the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, ;; Boston, MA 02110-1301, USA. ;;; Commentary: ;; The functions which have docstring documentation can be considered ;; part of an API which other packages can use in CC Mode buffers. ;; Otoh, undocumented functions and functions with the documentation ;; in comments are considered purely internal and can change semantics ;; or even disappear in the future. ;; ;; (This policy applies to CC Mode as a whole, not just this file. It ;; probably also applies to many other Emacs packages, but here it's ;; clearly spelled out.) ;; Hidden buffer changes ;; ;; Various functions in CC Mode use text properties for caching and ;; syntactic markup purposes, and those of them that might modify such ;; properties but still don't modify the buffer in a visible way are ;; said to do "hidden buffer changes". They should be used within ;; `c-save-buffer-state' or a similar function that saves and restores ;; buffer modifiedness, disables buffer change hooks, etc. ;; ;; Interactive functions are assumed to not do hidden buffer changes, ;; except in the specific parts of them that do real changes. ;; ;; Lineup functions are assumed to do hidden buffer changes. They ;; must not do real changes, though. ;; ;; All other functions that do hidden buffer changes have that noted ;; in their doc string or comment. ;; ;; The intention with this system is to avoid wrapping every leaf ;; function that do hidden buffer changes inside ;; `c-save-buffer-state'. It should be used as near the top of the ;; interactive functions as possible. ;; ;; Functions called during font locking are allowed to do hidden ;; buffer changes since the font-lock package run them in a context ;; similar to `c-save-buffer-state' (in fact, that function is heavily ;; inspired by `save-buffer-state' in the font-lock package). ;; Use of text properties ;; ;; CC Mode uses several text properties internally to mark up various ;; positions, e.g. to improve speed and to eliminate glitches in ;; interactive refontification. ;; ;; Note: This doc is for internal use only. Other packages should not ;; assume that these text properties are used as described here. ;; ;; 'syntax-table ;; Used to modify the syntax of some characters. Currently used to ;; mark the "<" and ">" of angle bracket parens with paren syntax. ;; ;; This property is used on single characters and is therefore ;; always treated as front and rear nonsticky (or start and end open ;; in XEmacs vocabulary). It's therefore installed on ;; `text-property-default-nonsticky' if that variable exists (Emacs ;; >= 21). ;; ;; 'c-is-sws and 'c-in-sws ;; Used by `c-forward-syntactic-ws' and `c-backward-syntactic-ws' to ;; speed them up. See the comment blurb before `c-put-is-sws' ;; below for further details. ;; ;; 'c-type ;; This property is used on single characters to mark positions with ;; special syntactic relevance of various sorts. Its primary use is ;; to avoid glitches when multiline constructs are refontified ;; interactively (on font lock decoration level 3). It's cleared in ;; a region before it's fontified and is then put on relevant chars ;; in that region as they are encountered during the fontification. ;; The value specifies the kind of position: ;; ;; 'c-decl-arg-start ;; Put on the last char of the token preceding each declaration ;; inside a declaration style arglist (typically in a function ;; prototype). ;; ;; 'c-decl-end ;; Put on the last char of the token preceding a declaration. ;; This is used in cases where declaration boundaries can't be ;; recognized simply by looking for a token like ";" or "}". ;; `c-type-decl-end-used' must be set if this is used (see also ;; `c-find-decl-spots'). ;; ;; 'c-<>-arg-sep ;; Put on the commas that separate arguments in angle bracket ;; arglists like C++ template arglists. ;; ;; 'c-decl-id-start and 'c-decl-type-start ;; Put on the last char of the token preceding each declarator ;; in the declarator list of a declaration. They are also used ;; between the identifiers cases like enum declarations. ;; 'c-decl-type-start is used when the declarators are types, ;; 'c-decl-id-start otherwise. ;; ;; 'c-awk-NL-prop ;; Used in AWK mode to mark the various kinds of newlines. See ;; cc-awk.el. ;;; Code: (eval-when-compile (let ((load-path (if (and (boundp 'byte-compile-dest-file) (stringp byte-compile-dest-file)) (cons (file-name-directory byte-compile-dest-file) load-path) load-path))) (load "cc-bytecomp" nil t))) (cc-require 'cc-defs) (cc-require-when-compile 'cc-langs) (cc-require 'cc-vars) ;; Silence the compiler. (cc-bytecomp-defun buffer-syntactic-context) ; XEmacs ;; Make declarations for all the `c-lang-defvar' variables in cc-langs. (defmacro c-declare-lang-variables () `(progn ,@(apply 'nconc (mapcar (lambda (init) `(,(if (elt init 2) `(defvar ,(car init) nil ,(elt init 2)) `(defvar ,(car init) nil)) (make-variable-buffer-local ',(car init)))) (cdr c-lang-variable-inits))))) (c-declare-lang-variables) ;;; Internal state variables. ;; Internal state of hungry delete key feature (defvar c-hungry-delete-key nil) (make-variable-buffer-local 'c-hungry-delete-key) ;; The electric flag (toggled by `c-toggle-electric-state'). ;; If t, electric actions (like automatic reindentation, and (if ;; c-auto-newline is also set) auto newlining) will happen when an electric ;; key like `{' is pressed (or an electric keyword like `else'). (defvar c-electric-flag t) (make-variable-buffer-local 'c-electric-flag) ;; Internal state of auto newline feature. (defvar c-auto-newline nil) (make-variable-buffer-local 'c-auto-newline) ;; Included in the mode line to indicate the active submodes. ;; (defvar c-submode-indicators nil) ;; (make-variable-buffer-local 'c-submode-indicators) (defun c-calculate-state (arg prevstate) ;; Calculate the new state of PREVSTATE, t or nil, based on arg. If ;; arg is nil or zero, toggle the state. If arg is negative, turn ;; the state off, and if arg is positive, turn the state on (if (or (not arg) (zerop (setq arg (prefix-numeric-value arg)))) (not prevstate) (> arg 0))) ;; Dynamically bound cache for `c-in-literal'. (defvar c-in-literal-cache t) ;; Basic handling of preprocessor directives. ;; This is a dynamically bound cache used together with ;; `c-query-macro-start' and `c-query-and-set-macro-start'. It only ;; works as long as point doesn't cross a macro boundary. (defvar c-macro-start 'unknown) (defsubst c-query-and-set-macro-start () (if (symbolp c-macro-start) (setq c-macro-start (save-excursion (c-save-buffer-state () (and (c-beginning-of-macro) (point))))) c-macro-start)) (defsubst c-query-macro-start () (if (symbolp c-macro-start) (save-excursion (c-save-buffer-state () (and (c-beginning-of-macro) (point)))) c-macro-start)) (defun c-beginning-of-macro (&optional lim) "Go to the beginning of a preprocessor directive. Leave point at the beginning of the directive and return t if in one, otherwise return nil and leave point unchanged. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (when c-opt-cpp-prefix (let ((here (point))) (save-restriction (if lim (narrow-to-region lim (point-max))) (beginning-of-line) (while (eq (char-before (1- (point))) ?\\) (forward-line -1)) (back-to-indentation) (if (and (<= (point) here) (looking-at c-opt-cpp-start)) t (goto-char here) nil))))) (defun c-end-of-macro () "Go to the end of a preprocessor directive. More accurately, move the point to the end of the closest following line that doesn't end with a line continuation backslash - no check is done that the point is inside a cpp directive to begin with. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (while (progn (end-of-line) (when (and (eq (char-before) ?\\) (not (eobp))) (forward-char) t)))) (defun c-forward-over-cpp-define-id () ;; Assuming point is at the "#" that introduces a preprocessor ;; directive, it's moved forward to the end of the identifier which is ;; "#define"d (or whatever c-opt-cpp-macro-define specifies). Non-nil ;; is returned in this case, in all other cases nil is returned and ;; point isn't moved. ;; ;; This function might do hidden buffer changes. (when (and c-opt-cpp-macro-define-id (looking-at c-opt-cpp-macro-define-id)) (goto-char (match-end 0)))) (defun c-forward-to-cpp-define-body () ;; Assuming point is at the "#" that introduces a preprocessor ;; directive, it's moved forward to the start of the definition body ;; if it's a "#define" (or whatever c-opt-cpp-macro-define ;; specifies). Non-nil is returned in this case, in all other cases ;; nil is returned and point isn't moved. ;; ;; This function might do hidden buffer changes. (when (and c-opt-cpp-macro-define-start (looking-at c-opt-cpp-macro-define-start) (not (= (match-end 0) (c-point 'eol)))) (goto-char (match-end 0)))) ;;; Basic utility functions. (defun c-syntactic-content (from to paren-level) ;; Return the given region as a string where all syntactic ;; whitespace is removed or, where necessary, replaced with a single ;; space. If PAREN-LEVEL is given then all parens in the region are ;; collapsed to "()", "[]" etc. ;; ;; This function might do hidden buffer changes. (save-excursion (save-restriction (narrow-to-region from to) (goto-char from) (let* ((parts (list nil)) (tail parts) pos in-paren) (while (re-search-forward c-syntactic-ws-start to t) (goto-char (setq pos (match-beginning 0))) (c-forward-syntactic-ws) (if (= (point) pos) (forward-char) (when paren-level (save-excursion (setq in-paren (= (car (parse-partial-sexp from pos 1)) 1) pos (point)))) (if (and (> pos from) (< (point) to) (looking-at "\\w\\|\\s_") (save-excursion (goto-char (1- pos)) (looking-at "\\w\\|\\s_"))) (progn (setcdr tail (list (buffer-substring-no-properties from pos) " ")) (setq tail (cddr tail))) (setcdr tail (list (buffer-substring-no-properties from pos))) (setq tail (cdr tail))) (when in-paren (when (= (car (parse-partial-sexp pos to -1)) -1) (setcdr tail (list (buffer-substring-no-properties (1- (point)) (point)))) (setq tail (cdr tail)))) (setq from (point)))) (setcdr tail (list (buffer-substring-no-properties from to))) (apply 'concat (cdr parts)))))) (defun c-shift-line-indentation (shift-amt) ;; Shift the indentation of the current line with the specified ;; amount (positive inwards). The buffer is modified only if ;; SHIFT-AMT isn't equal to zero. (let ((pos (- (point-max) (point))) (c-macro-start c-macro-start) tmp-char-inserted) (if (zerop shift-amt) nil ;; If we're on an empty line inside a macro, we take the point ;; to be at the current indentation and shift it to the ;; appropriate column. This way we don't treat the extra ;; whitespace out to the line continuation as indentation. (when (and (c-query-and-set-macro-start) (looking-at "[ \t]*\\\\$") (save-excursion (skip-chars-backward " \t") (bolp))) (insert ?x) (backward-char) (setq tmp-char-inserted t)) (unwind-protect (let ((col (current-indentation))) (delete-region (c-point 'bol) (c-point 'boi)) (beginning-of-line) (indent-to (+ col shift-amt))) (when tmp-char-inserted (delete-char 1)))) ;; If initial point was within line's indentation and we're not on ;; a line with a line continuation in a macro, position after the ;; indentation. Else stay at same point in text. (if (and (< (point) (c-point 'boi)) (not tmp-char-inserted)) (back-to-indentation) (if (> (- (point-max) pos) (point)) (goto-char (- (point-max) pos)))))) (defsubst c-keyword-sym (keyword) ;; Return non-nil if the string KEYWORD is a known keyword. More ;; precisely, the value is the symbol for the keyword in ;; `c-keywords-obarray'. (intern-soft keyword c-keywords-obarray)) (defsubst c-keyword-member (keyword-sym lang-constant) ;; Return non-nil if the symbol KEYWORD-SYM, as returned by ;; `c-keyword-sym', is a member of LANG-CONSTANT, which is the name ;; of a language constant that ends with "-kwds". If KEYWORD-SYM is ;; nil then the result is nil. (get keyword-sym lang-constant)) ;; String syntax chars, suitable for skip-syntax-(forward|backward). (defconst c-string-syntax (if (memq 'gen-string-delim c-emacs-features) "\"|" "\"")) ;; Regexp matching string limit syntax. (defconst c-string-limit-regexp (if (memq 'gen-string-delim c-emacs-features) "\\s\"\\|\\s|" "\\s\"")) ;; Regexp matching WS followed by string limit syntax. (defconst c-ws*-string-limit-regexp (concat "[ \t]*\\(" c-string-limit-regexp "\\)")) ;; Holds formatted error strings for the few cases where parse errors ;; are reported. (defvar c-parsing-error nil) (make-variable-buffer-local 'c-parsing-error) (defun c-echo-parsing-error (&optional quiet) (when (and c-report-syntactic-errors c-parsing-error (not quiet)) (c-benign-error "%s" c-parsing-error)) c-parsing-error) ;; Faces given to comments and string literals. This is used in some ;; situations to speed up recognition; it isn't mandatory that font ;; locking is in use. This variable is extended with the face in ;; `c-doc-face-name' when fontification is activated in cc-fonts.el. (defvar c-literal-faces (append '(font-lock-comment-face font-lock-string-face) (when (facep 'font-lock-comment-delimiter-face) ;; New in Emacs 22. '(font-lock-comment-delimiter-face)))) (defsubst c-put-c-type-property (pos value) ;; Put a c-type property with the given value at POS. (c-put-char-property pos 'c-type value)) (defun c-clear-c-type-property (from to value) ;; Remove all occurences of the c-type property that has the given ;; value in the region between FROM and TO. VALUE is assumed to not ;; be nil. ;; ;; Note: This assumes that c-type is put on single chars only; it's ;; very inefficient if matching properties cover large regions. (save-excursion (goto-char from) (while (progn (when (eq (get-text-property (point) 'c-type) value) (c-clear-char-property (point) 'c-type)) (goto-char (next-single-property-change (point) 'c-type nil to)) (< (point) to))))) ;; Some debug tools to visualize various special positions. This ;; debug code isn't as portable as the rest of CC Mode. (cc-bytecomp-defun overlays-in) (cc-bytecomp-defun overlay-get) (cc-bytecomp-defun overlay-start) (cc-bytecomp-defun overlay-end) (cc-bytecomp-defun delete-overlay) (cc-bytecomp-defun overlay-put) (cc-bytecomp-defun make-overlay) (defun c-debug-add-face (beg end face) (c-save-buffer-state ((overlays (overlays-in beg end)) overlay) (while overlays (setq overlay (car overlays) overlays (cdr overlays)) (when (eq (overlay-get overlay 'face) face) (setq beg (min beg (overlay-start overlay)) end (max end (overlay-end overlay))) (delete-overlay overlay))) (overlay-put (make-overlay beg end) 'face face))) (defun c-debug-remove-face (beg end face) (c-save-buffer-state ((overlays (overlays-in beg end)) overlay (ol-beg beg) (ol-end end)) (while overlays (setq overlay (car overlays) overlays (cdr overlays)) (when (eq (overlay-get overlay 'face) face) (setq ol-beg (min ol-beg (overlay-start overlay)) ol-end (max ol-end (overlay-end overlay))) (delete-overlay overlay))) (when (< ol-beg beg) (overlay-put (make-overlay ol-beg beg) 'face face)) (when (> ol-end end) (overlay-put (make-overlay end ol-end) 'face face)))) ;; `c-beginning-of-statement-1' and accompanying stuff. ;; KLUDGE ALERT: c-maybe-labelp is used to pass information between ;; c-crosses-statement-barrier-p and c-beginning-of-statement-1. A ;; better way should be implemented, but this will at least shut up ;; the byte compiler. (defvar c-maybe-labelp) ;; New awk-compatible version of c-beginning-of-statement-1, ACM 2002/6/22 ;; Macros used internally in c-beginning-of-statement-1 for the ;; automaton actions. (defmacro c-bos-push-state () '(setq stack (cons (cons state saved-pos) stack))) (defmacro c-bos-pop-state (&optional do-if-done) `(if (setq state (car (car stack)) saved-pos (cdr (car stack)) stack (cdr stack)) t ,do-if-done (throw 'loop nil))) (defmacro c-bos-pop-state-and-retry () '(throw 'loop (setq state (car (car stack)) saved-pos (cdr (car stack)) ;; Throw nil if stack is empty, else throw non-nil. stack (cdr stack)))) (defmacro c-bos-save-pos () '(setq saved-pos (vector pos tok ptok pptok))) (defmacro c-bos-restore-pos () '(unless (eq (elt saved-pos 0) start) (setq pos (elt saved-pos 0) tok (elt saved-pos 1) ptok (elt saved-pos 2) pptok (elt saved-pos 3)) (goto-char pos) (setq sym nil))) (defmacro c-bos-save-error-info (missing got) `(setq saved-pos (vector pos ,missing ,got))) (defmacro c-bos-report-error () '(unless noerror (setq c-parsing-error (format "No matching `%s' found for `%s' on line %d" (elt saved-pos 1) (elt saved-pos 2) (1+ (count-lines (point-min) (c-point 'bol (elt saved-pos 0)))))))) (defun c-beginning-of-statement-1 (&optional lim ignore-labels noerror comma-delim) "Move to the start of the current statement or declaration, or to the previous one if already at the beginning of one. Only statements/declarations on the same level are considered, i.e. don't move into or out of sexps (not even normal expression parentheses). Stop at statement continuation tokens like \"else\", \"catch\", \"finally\" and the \"while\" in \"do ... while\" if the start point is within the continuation. If starting at such a token, move to the corresponding statement start. If at the beginning of a statement, move to the closest containing statement if there is any. This might also stop at a continuation clause. Labels are treated as part of the following statements if IGNORE-LABELS is non-nil. (FIXME: Doesn't work if we stop at a known statement start keyword.) Otherwise, each label is treated as a separate statement. Macros are ignored \(i.e. skipped over) unless point is within one, in which case the content of the macro is treated as normal code. Aside from any normal statement starts found in it, stop at the first token of the content in the macro, i.e. the expression of an \"#if\" or the start of the definition in a \"#define\". Also stop at start of macros before leaving them. Return 'label if stopped at a label, 'same if stopped at the beginning of the current statement, 'up if stepped to a containing statement, 'previous if stepped to a preceding statement, 'beginning if stepped from a statement continuation clause to its start clause, or 'macro if stepped to a macro start. Note that 'same and not 'label is returned if stopped at the same label without crossing the colon character. LIM may be given to limit the search. If the search hits the limit, point will be left at the closest following token, or at the start position if that is less ('same is returned in this case). NOERROR turns off error logging to `c-parsing-error'. Normally only ';' and virtual semicolons are considered to delimit statements, but if COMMA-DELIM is non-nil then ',' is treated as a delimiter too. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." ;; The bulk of this function is a pushdown automaton that looks at statement ;; boundaries and the tokens (such as "while") in c-opt-block-stmt-key. Its ;; purpose is to keep track of nested statements, ensuring that such ;; statments are skipped over in their entirety (somewhat akin to what C-M-p ;; does with nested braces/brackets/parentheses). ;; ;; Note: The position of a boundary is the following token. ;; ;; Beginning with the current token (the one following point), move back one ;; sexp at a time (where a sexp is, more or less, either a token or the ;; entire contents of a brace/bracket/paren pair). Each time a statement ;; boundary is crossed or a "while"-like token is found, update the state of ;; the PDA. Stop at the beginning of a statement when the stack (holding ;; nested statement info) is empty and the position has been moved. ;; ;; The following variables constitute the PDA: ;; ;; sym: This is either the "while"-like token (e.g. 'for) we've just ;; scanned back over, 'boundary if we've just gone back over a ;; statement boundary, or nil otherwise. ;; state: takes one of the values (nil else else-boundary while ;; while-boundary catch catch-boundary). ;; nil means "no "while"-like token yet scanned". ;; 'else, for example, means "just gone back over an else". ;; 'else-boundary means "just gone back over a statement boundary ;; immediately after having gone back over an else". ;; saved-pos: A vector of either saved positions (tok ptok pptok, etc.) or ;; of error reporting information. ;; stack: The stack onto which the PDA pushes its state. Each entry ;; consists of a saved value of state and saved-pos. An entry is ;; pushed when we move back over a "continuation" token (e.g. else) ;; and popped when we encounter the corresponding opening token ;; (e.g. if). ;; ;; ;; The following diagram briefly outlines the PDA. ;; ;; Common state: ;; "else": Push state, goto state `else'. ;; "while": Push state, goto state `while'. ;; "catch" or "finally": Push state, goto state `catch'. ;; boundary: Pop state. ;; other: Do nothing special. ;; ;; State `else': ;; boundary: Goto state `else-boundary'. ;; other: Error, pop state, retry token. ;; ;; State `else-boundary': ;; "if": Pop state. ;; boundary: Error, pop state. ;; other: See common state. ;; ;; State `while': ;; boundary: Save position, goto state `while-boundary'. ;; other: Pop state, retry token. ;; ;; State `while-boundary': ;; "do": Pop state. ;; boundary: Restore position if it's not at start, pop state. [*see below] ;; other: See common state. ;; ;; State `catch': ;; boundary: Goto state `catch-boundary'. ;; other: Error, pop state, retry token. ;; ;; State `catch-boundary': ;; "try": Pop state. ;; "catch": Goto state `catch'. ;; boundary: Error, pop state. ;; other: See common state. ;; ;; [*] In the `while-boundary' state, we had pushed a 'while state, and were ;; searching for a "do" which would have opened a do-while. If we didn't ;; find it, we discard the analysis done since the "while", go back to this ;; token in the buffer and restart the scanning there, this time WITHOUT ;; pushing the 'while state onto the stack. ;; ;; In addition to the above there is some special handling of labels ;; and macros. (let ((case-fold-search nil) (start (point)) macro-start (delims (if comma-delim '(?\; ?,) '(?\;))) (c-stmt-delim-chars (if comma-delim c-stmt-delim-chars-with-comma c-stmt-delim-chars)) c-in-literal-cache c-maybe-labelp saved ;; Current position. pos ;; Position of last stmt boundary character (e.g. ;). boundary-pos ;; The position of the last sexp or bound that follows the ;; first found colon, i.e. the start of the nonlabel part of ;; the statement. It's `start' if a colon is found just after ;; the start. after-labels-pos ;; Like `after-labels-pos', but the first such position inside ;; a label, i.e. the start of the last label before the start ;; of the nonlabel part of the statement. last-label-pos ;; The last position where a label is possible provided the ;; statement started there. It's nil as long as no invalid ;; label content has been found (according to ;; `c-nonlabel-token-key'. It's `start' if no valid label ;; content was found in the label. Note that we might still ;; regard it a label if it starts with `c-label-kwds'. label-good-pos ;; Symbol just scanned back over (e.g. 'while or 'boundary). ;; See above. sym ;; Current state in the automaton. See above. state ;; Current saved positions. See above. saved-pos ;; Stack of conses (state . saved-pos). stack ;; Regexp which matches "for", "if", etc. (cond-key (or c-opt-block-stmt-key "\\<\\>")) ; Matches nothing. ;; Return value. (ret 'same) ;; Positions of the last three sexps or bounds we've stopped at. tok ptok pptok) (save-restriction (if lim (narrow-to-region lim (point-max))) (if (save-excursion (and (c-beginning-of-macro) (/= (point) start))) (setq macro-start (point))) ;; Try to skip back over unary operator characters, to register ;; that we've moved. (while (progn (setq pos (point)) (c-backward-syntactic-ws) ;; Protect post-++/-- operators just before a virtual semicolon. (and (not (c-at-vsemi-p)) (/= (skip-chars-backward "-+!*&~@`#") 0)))) ;; Skip back over any semicolon here. If it was a bare semicolon, we're ;; done. Later on we ignore the boundaries for statements that don't ;; contain any sexp. The only thing that is affected is that the error ;; checking is a little less strict, and we really don't bother. (if (and (memq (char-before) delims) (progn (forward-char -1) (setq saved (point)) (c-backward-syntactic-ws) (or (memq (char-before) delims) (memq (char-before) '(?: nil)) (eq (char-syntax (char-before)) ?\() (c-at-vsemi-p)))) (setq ret 'previous pos saved) ;; Begin at start and not pos to detect macros if we stand ;; directly after the #. (goto-char start) (if (looking-at "\\<\\|\\W") ;; Record this as the first token if not starting inside it. (setq tok start)) ;; The following while loop goes back one sexp (balanced parens, ;; etc. with contents, or symbol or suchlike) each iteration. This ;; movement is accomplished with a call to scan-sexps approx 130 lines ;; below. (while (catch 'loop ;; Throw nil to break, non-nil to continue. (cond ((save-excursion (and macro-start ; Always NIL for AWK. (progn (skip-chars-backward " \t") (eq (char-before) ?#)) (progn (setq saved (1- (point))) (beginning-of-line) (not (eq (char-before (1- (point))) ?\\))) (looking-at c-opt-cpp-start) (progn (skip-chars-forward " \t") (eq (point) saved)))) (goto-char saved) (if (and (c-forward-to-cpp-define-body) (progn (c-forward-syntactic-ws start) (< (point) start))) ;; Stop at the first token in the content of the macro. (setq pos (point) ignore-labels t) ; Avoid the label check on exit. (setq pos saved ret 'macro ignore-labels t)) (throw 'loop nil)) ;; Do a round through the automaton if we've just passed a ;; statement boundary or passed a "while"-like token. ((or sym (and (looking-at cond-key) (setq sym (intern (match-string 1))))) (when (and (< pos start) (null stack)) (throw 'loop nil)) ;; The PDA state handling. ;; ;; Refer to the description of the PDA in the opening ;; comments. In the following OR form, the first leaf ;; attempts to handles one of the specific actions detailed ;; (e.g., finding token "if" whilst in state `else-boundary'). ;; We drop through to the second leaf (which handles common ;; state) if no specific handler is found in the first cond. ;; If a parsing error is detected (e.g. an "else" with no ;; preceding "if"), we throw to the enclosing catch. ;; ;; Note that the (eq state 'else) means ;; "we've just passed an else", NOT "we're looking for an ;; else". (or (cond ((eq state 'else) (if (eq sym 'boundary) (setq state 'else-boundary) (c-bos-report-error) (c-bos-pop-state-and-retry))) ((eq state 'else-boundary) (cond ((eq sym 'if) (c-bos-pop-state (setq ret 'beginning))) ((eq sym 'boundary) (c-bos-report-error) (c-bos-pop-state)))) ((eq state 'while) (if (and (eq sym 'boundary) ;; Since this can cause backtracking we do a ;; little more careful analysis to avoid it: ;; If there's a label in front of the while ;; it can't be part of a do-while. (not after-labels-pos)) (progn (c-bos-save-pos) (setq state 'while-boundary)) (c-bos-pop-state-and-retry))) ; Can't be a do-while ((eq state 'while-boundary) (cond ((eq sym 'do) (c-bos-pop-state (setq ret 'beginning))) ((eq sym 'boundary) ; isn't a do-while (c-bos-restore-pos) ; the position of the while (c-bos-pop-state)))) ; no longer searching for do. ((eq state 'catch) (if (eq sym 'boundary) (setq state 'catch-boundary) (c-bos-report-error) (c-bos-pop-state-and-retry))) ((eq state 'catch-boundary) (cond ((eq sym 'try) (c-bos-pop-state (setq ret 'beginning))) ((eq sym 'catch) (setq state 'catch)) ((eq sym 'boundary) (c-bos-report-error) (c-bos-pop-state))))) ;; This is state common. We get here when the previous ;; cond statement found no particular state handler. (cond ((eq sym 'boundary) ;; If we have a boundary at the start ;; position we push a frame to go to the ;; previous statement. (if (>= pos start) (c-bos-push-state) (c-bos-pop-state))) ((eq sym 'else) (c-bos-push-state) (c-bos-save-error-info 'if 'else) (setq state 'else)) ((eq sym 'while) ;; Is this a real while, or a do-while? ;; The next `when' triggers unless we are SURE that ;; the `while' is not the tailend of a `do-while'. (when (or (not pptok) (memq (char-after pptok) delims) ;; The following kludge is to prevent ;; infinite recursion when called from ;; c-awk-after-if-for-while-condition-p, ;; or the like. (and (eq (point) start) (c-vsemi-status-unknown-p)) (c-at-vsemi-p pptok)) ;; Since this can cause backtracking we do a ;; little more careful analysis to avoid it: If ;; the while isn't followed by a (possibly ;; virtual) semicolon it can't be a do-while. (c-bos-push-state) (setq state 'while))) ((memq sym '(catch finally)) (c-bos-push-state) (c-bos-save-error-info 'try sym) (setq state 'catch)))) (when c-maybe-labelp ;; We're either past a statement boundary or at the ;; start of a statement, so throw away any label data ;; for the previous one. (setq after-labels-pos nil last-label-pos nil c-maybe-labelp nil)))) ;; Step to the previous sexp, but not if we crossed a ;; boundary, since that doesn't consume an sexp. (if (eq sym 'boundary) (setq ret 'previous) ;; HERE IS THE SINGLE PLACE INSIDE THE PDA LOOP WHERE WE MOVE ;; BACKWARDS THROUGH THE SOURCE. ;; This is typically fast with the caching done by ;; c-(backward|forward)-sws. (c-backward-syntactic-ws) (let ((before-sws-pos (point)) ;; Set as long as we have to continue jumping by sexps. ;; It's the position to use as end in the next round. sexp-loop-continue-pos ;; The end position of the area to search for statement ;; barriers in this round. (sexp-loop-end-pos pos)) ;; The following while goes back one sexp per iteration. (while (progn (unless (c-safe (c-backward-sexp) t) ;; Give up if we hit an unbalanced block. Since the ;; stack won't be empty the code below will report a ;; suitable error. (throw 'loop nil)) ;; Check if the sexp movement crossed a statement or ;; declaration boundary. But first modify the point ;; so that `c-crosses-statement-barrier-p' only looks ;; at the non-sexp chars following the sexp. (save-excursion (when (setq boundary-pos (cond ((if macro-start nil (save-excursion (when (c-beginning-of-macro) ;; Set continuation position in case ;; `c-crosses-statement-barrier-p' ;; doesn't detect anything below. (setq sexp-loop-continue-pos (point))))) ;; If the sexp movement took us into a ;; macro then there were only some non-sexp ;; chars after it. Skip out of the macro ;; to analyze them but not the non-sexp ;; chars that might be inside the macro. (c-end-of-macro) (c-crosses-statement-barrier-p (point) sexp-loop-end-pos)) ((and (eq (char-after) ?{) (not (c-looking-at-inexpr-block lim nil t))) ;; Passed a block sexp. That's a boundary ;; alright. (point)) ((looking-at "\\s\(") ;; Passed some other paren. Only analyze ;; the non-sexp chars after it. (goto-char (1+ (c-down-list-backward before-sws-pos))) ;; We're at a valid token start position ;; (outside the `save-excursion') if ;; `c-crosses-statement-barrier-p' failed. (c-crosses-statement-barrier-p (point) sexp-loop-end-pos)) (t ;; Passed a symbol sexp or line ;; continuation. It doesn't matter that ;; it's included in the analyzed region. (if (c-crosses-statement-barrier-p (point) sexp-loop-end-pos) t ;; If it was a line continuation then we ;; have to continue looping. (if (looking-at "\\\\$") (setq sexp-loop-continue-pos (point))) nil)))) (setq pptok ptok ptok tok tok boundary-pos sym 'boundary) ;; Like a C "continue". Analyze the next sexp. (throw 'loop t))) sexp-loop-continue-pos) ; End of "go back a sexp" loop. (goto-char sexp-loop-continue-pos) (setq sexp-loop-end-pos sexp-loop-continue-pos sexp-loop-continue-pos nil)))) ;; ObjC method def? (when (and c-opt-method-key (setq saved (c-in-method-def-p))) (setq pos saved ignore-labels t) ; Avoid the label check on exit. (throw 'loop nil)) ;; Handle labels. (unless (eq ignore-labels t) (when (numberp c-maybe-labelp) ;; `c-crosses-statement-barrier-p' has found a colon, so we ;; might be in a label now. Have we got a real label ;; (including a case label) or something like C++'s "public:"? (if (or (not (looking-at c-nonlabel-token-key)) ; proper label (save-excursion ; e.g. "case 'a':" ? (and (c-safe (c-backward-sexp) t) (looking-at "\\")))) ; FIXME!!! this is ; wrong for AWK. 2006/1/14. (progn (if after-labels-pos ; Have we already encountered a label? (if (not last-label-pos) (setq last-label-pos (or tok start))) (setq after-labels-pos (or tok start))) (setq c-maybe-labelp t label-good-pos nil)) (setq c-maybe-labelp nil))) ; bogus "label" (when (and (not label-good-pos) ; i.e. no invalid "label"'s yet ; been found. (looking-at c-nonlabel-token-key)) ; e.g. "while :" ;; We're in a potential label and it's the first ;; time we've found something that isn't allowed in ;; one. (setq label-good-pos (or tok start)))) ;; We've moved back by a sexp, so update the token positions. (setq sym nil pptok ptok ptok tok tok (point) pos tok))) ; Not nil (for the while loop). ;; If the stack isn't empty there might be errors to report. (while stack (if (and (vectorp saved-pos) (eq (length saved-pos) 3)) (c-bos-report-error)) (setq saved-pos (cdr (car stack)) stack (cdr stack))) (when (and (eq ret 'same) (not (memq sym '(boundary ignore nil)))) ;; Need to investigate closer whether we've crossed ;; between a substatement and its containing statement. (if (setq saved (if (looking-at c-block-stmt-1-key) ptok pptok)) (cond ((> start saved) (setq pos saved)) ((= start saved) (setq ret 'up))))) (when (and (not ignore-labels) (eq c-maybe-labelp t) (not (eq ret 'beginning)) after-labels-pos (or (not label-good-pos) (<= label-good-pos pos) (progn (goto-char (if (and last-label-pos (< last-label-pos start)) last-label-pos pos)) (looking-at c-label-kwds-regexp)))) ;; We're in a label. Maybe we should step to the statement ;; after it. (if (< after-labels-pos start) (setq pos after-labels-pos) (setq ret 'label) (if (and last-label-pos (< last-label-pos start)) ;; Might have jumped over several labels. Go to the last one. (setq pos last-label-pos))))) ;; Skip over the unary operators that can start the statement. (goto-char pos) (while (progn (c-backward-syntactic-ws) ;; protect AWK post-inc/decrement operators, etc. (and (not (c-at-vsemi-p (point))) (/= (skip-chars-backward "-+!*&~@`#") 0))) (setq pos (point))) (goto-char pos) ret))) (defun c-crosses-statement-barrier-p (from to) "Return non-nil if buffer positions FROM to TO cross one or more statement or declaration boundaries. The returned value is actually the position of the earliest boundary char. FROM must not be within a string or comment. The variable `c-maybe-labelp' is set to the position of the first `:' that might start a label (i.e. not part of `::' and not preceded by `?'). If a single `?' is found, then `c-maybe-labelp' is cleared. For AWK, a statement which is terminated by an EOL (not a \; or a }) is regarded as having a \"virtual semicolon\" immediately after the last token on the line. If this virtual semicolon is _at_ from, the function recognises it. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (let ((skip-chars c-stmt-delim-chars) lit-range) (save-excursion (catch 'done (goto-char from) (while (progn (skip-chars-forward skip-chars to) (< (point) to)) (cond ((setq lit-range (c-literal-limits from)) ; Have we landed in a string/comment? (goto-char (cdr lit-range))) ((eq (char-after) ?:) (forward-char) (if (and (eq (char-after) ?:) (< (point) to)) ;; Ignore scope operators. (forward-char) (setq c-maybe-labelp (1- (point))))) ((eq (char-after) ??) ;; A question mark. Can't be a label, so stop ;; looking for more : and ?. (setq c-maybe-labelp nil skip-chars (substring c-stmt-delim-chars 0 -2))) ((memq (char-after) '(?# ?\n ?\r)) ; A virtual semicolon? (if (and (eq (char-before) ?\\) (memq (char-after) '(?\n ?\r))) (backward-char)) (skip-chars-backward " \t" from) (if (c-at-vsemi-p) (throw 'done (point)) (forward-line))) (t (throw 'done (point))))) ;; In trailing space after an as yet undetected virtual semicolon? (c-backward-syntactic-ws from) (if (and (< (point) to) (c-at-vsemi-p)) (point) nil))))) (defun c-at-statement-start-p () "Return non-nil if the point is at the first token in a statement or somewhere in the syntactic whitespace before it. A \"statement\" here is not restricted to those inside code blocks. Any kind of declaration-like construct that occur outside function bodies is also considered a \"statement\". Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (save-excursion (let ((end (point)) c-maybe-labelp) (c-syntactic-skip-backward (substring c-stmt-delim-chars 1) nil t) (or (bobp) (eq (char-before) ?}) (and (eq (char-before) ?{) (not (and c-special-brace-lists (progn (backward-char) (c-looking-at-special-brace-list))))) (c-crosses-statement-barrier-p (point) end))))) (defun c-at-expression-start-p () "Return non-nil if the point is at the first token in an expression or statement, or somewhere in the syntactic whitespace before it. An \"expression\" here is a bit different from the normal language grammar sense: It's any sequence of expression tokens except commas, unless they are enclosed inside parentheses of some kind. Also, an expression never continues past an enclosing parenthesis, but it might contain parenthesis pairs of any sort except braces. Since expressions never cross statement boundaries, this function also recognizes statement beginnings, just like `c-at-statement-start-p'. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (save-excursion (let ((end (point)) (c-stmt-delim-chars c-stmt-delim-chars-with-comma) c-maybe-labelp) (c-syntactic-skip-backward (substring c-stmt-delim-chars 1) nil t) (or (bobp) (memq (char-before) '(?{ ?})) (save-excursion (backward-char) (looking-at "\\s(")) (c-crosses-statement-barrier-p (point) end))))) ;; A set of functions that covers various idiosyncrasies in ;; implementations of `forward-comment'. ;; Note: Some emacsen considers incorrectly that any line comment ;; ending with a backslash continues to the next line. I can't think ;; of any way to work around that in a reliable way without changing ;; the buffer, though. Suggestions welcome. ;) (No, temporarily ;; changing the syntax for backslash doesn't work since we must treat ;; escapes in string literals correctly.) (defun c-forward-single-comment () "Move forward past whitespace and the closest following comment, if any. Return t if a comment was found, nil otherwise. In either case, the point is moved past the following whitespace. Line continuations, i.e. a backslashes followed by line breaks, are treated as whitespace. The line breaks that end line comments are considered to be the comment enders, so the point will be put on the beginning of the next line if it moved past a line comment. This function does not do any hidden buffer changes." (let ((start (point))) (when (looking-at "\\([ \t\n\r\f\v]\\|\\\\[\n\r]\\)+") (goto-char (match-end 0))) (when (forward-comment 1) (if (eobp) ;; Some emacsen (e.g. XEmacs 21) return t when moving ;; forwards at eob. nil ;; Emacs includes the ending newline in a b-style (c++) ;; comment, but XEmacs doesn't. We depend on the Emacs ;; behavior (which also is symmetric). (if (and (eolp) (elt (parse-partial-sexp start (point)) 7)) (condition-case nil (forward-char 1))) t)))) (defsubst c-forward-comments () "Move forward past all following whitespace and comments. Line continuations, i.e. a backslashes followed by line breaks, are treated as whitespace. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (while (or ;; If forward-comment in at least XEmacs 21 is given a large ;; positive value, it'll loop all the way through if it hits ;; eob. (and (forward-comment 5) ;; Some emacsen (e.g. XEmacs 21) return t when moving ;; forwards at eob. (not (eobp))) (when (looking-at "\\\\[\n\r]") (forward-char 2) t)))) (defun c-backward-single-comment () "Move backward past whitespace and the closest preceding comment, if any. Return t if a comment was found, nil otherwise. In either case, the point is moved past the preceding whitespace. Line continuations, i.e. a backslashes followed by line breaks, are treated as whitespace. The line breaks that end line comments are considered to be the comment enders, so the point cannot be at the end of the same line to move over a line comment. This function does not do any hidden buffer changes." (let ((start (point))) ;; When we got newline terminated comments, forward-comment in all ;; supported emacsen so far will stop at eol of each line not ;; ending with a comment when moving backwards. This corrects for ;; that, and at the same time handles line continuations. (while (progn (skip-chars-backward " \t\n\r\f\v") (and (looking-at "[\n\r]") (eq (char-before) ?\\))) (backward-char)) (if (bobp) ;; Some emacsen (e.g. Emacs 19.34) return t when moving ;; backwards at bob. nil ;; Leave point after the closest following newline if we've ;; backed up over any above, since forward-comment won't move ;; backward over a line comment if point is at the end of the ;; same line. (re-search-forward "\\=\\s *[\n\r]" start t) (if (if (forward-comment -1) (if (eolp) ;; If forward-comment above succeeded and we're at eol ;; then the newline we moved over above didn't end a ;; line comment, so we give it another go. (forward-comment -1) t)) ;; Emacs <= 20 and XEmacs move back over the closer of a ;; block comment that lacks an opener. (if (looking-at "\\*/") (progn (forward-char 2) nil) t))))) (defsubst c-backward-comments () "Move backward past all preceding whitespace and comments. Line continuations, i.e. a backslashes followed by line breaks, are treated as whitespace. The line breaks that end line comments are considered to be the comment enders, so the point cannot be at the end of the same line to move over a line comment. Unlike c-backward-syntactic-ws, this function doesn't move back over preprocessor directives. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (let ((start (point))) (while (and ;; `forward-comment' in some emacsen (e.g. XEmacs 21.4) ;; return t when moving backwards at bob. (not (bobp)) (if (forward-comment -1) (if (looking-at "\\*/") ;; Emacs <= 20 and XEmacs move back over the ;; closer of a block comment that lacks an opener. (progn (forward-char 2) nil) t) ;; XEmacs treats line continuations as whitespace but ;; only in the backward direction, which seems a bit ;; odd. Anyway, this is necessary for Emacs. (when (and (looking-at "[\n\r]") (eq (char-before) ?\\) (< (point) start)) (backward-char) t)))))) ;; Tools for skipping over syntactic whitespace. ;; The following functions use text properties to cache searches over ;; large regions of syntactic whitespace. It works as follows: ;; ;; o If a syntactic whitespace region contains anything but simple ;; whitespace (i.e. space, tab and line breaks), the text property ;; `c-in-sws' is put over it. At places where we have stopped ;; within that region there's also a `c-is-sws' text property. ;; That since there typically are nested whitespace inside that ;; must be handled separately, e.g. whitespace inside a comment or ;; cpp directive. Thus, from one point with `c-is-sws' it's safe ;; to jump to another point with that property within the same ;; `c-in-sws' region. It can be likened to a ladder where ;; `c-in-sws' marks the bars and `c-is-sws' the rungs. ;; ;; o The `c-is-sws' property is put on the simple whitespace chars at ;; a "rung position" and also maybe on the first following char. ;; As many characters as can be conveniently found in this range ;; are marked, but no assumption can be made that the whole range ;; is marked (it could be clobbered by later changes, for ;; instance). ;; ;; Note that some part of the beginning of a sequence of simple ;; whitespace might be part of the end of a preceding line comment ;; or cpp directive and must not be considered part of the "rung". ;; Such whitespace is some amount of horizontal whitespace followed ;; by a newline. In the case of cpp directives it could also be ;; two newlines with horizontal whitespace between them. ;; ;; The reason to include the first following char is to cope with ;; "rung positions" that doesn't have any ordinary whitespace. If ;; `c-is-sws' is put on a token character it does not have ;; `c-in-sws' set simultaneously. That's the only case when that ;; can occur, and the reason for not extending the `c-in-sws' ;; region to cover it is that the `c-in-sws' region could then be ;; accidentally merged with a following one if the token is only ;; one character long. ;; ;; o On buffer changes the `c-in-sws' and `c-is-sws' properties are ;; removed in the changed region. If the change was inside ;; syntactic whitespace that means that the "ladder" is broken, but ;; a later call to `c-forward-sws' or `c-backward-sws' will use the ;; parts on either side and use an ordinary search only to "repair" ;; the gap. ;; ;; Special care needs to be taken if a region is removed: If there ;; are `c-in-sws' on both sides of it which do not connect inside ;; the region then they can't be joined. If e.g. a marked macro is ;; broken, syntactic whitespace inside the new text might be ;; marked. If those marks would become connected with the old ;; `c-in-sws' range around the macro then we could get a ladder ;; with one end outside the macro and the other at some whitespace ;; within it. ;; ;; The main motivation for this system is to increase the speed in ;; skipping over the large whitespace regions that can occur at the ;; top level in e.g. header files that contain a lot of comments and ;; cpp directives. For small comments inside code it's probably ;; slower than using `forward-comment' straightforwardly, but speed is ;; not a significant factor there anyway. ; (defface c-debug-is-sws-face ; '((t (:background "GreenYellow"))) ; "Debug face to mark the `c-is-sws' property.") ; (defface c-debug-in-sws-face ; '((t (:underline t))) ; "Debug face to mark the `c-in-sws' property.") ; (defun c-debug-put-sws-faces () ; ;; Put the sws debug faces on all the `c-is-sws' and `c-in-sws' ; ;; properties in the buffer. ; (interactive) ; (save-excursion ; (c-save-buffer-state (in-face) ; (goto-char (point-min)) ; (setq in-face (if (get-text-property (point) 'c-is-sws) ; (point))) ; (while (progn ; (goto-char (next-single-property-change ; (point) 'c-is-sws nil (point-max))) ; (if in-face ; (progn ; (c-debug-add-face in-face (point) 'c-debug-is-sws-face) ; (setq in-face nil)) ; (setq in-face (point))) ; (not (eobp)))) ; (goto-char (point-min)) ; (setq in-face (if (get-text-property (point) 'c-in-sws) ; (point))) ; (while (progn ; (goto-char (next-single-property-change ; (point) 'c-in-sws nil (point-max))) ; (if in-face ; (progn ; (c-debug-add-face in-face (point) 'c-debug-in-sws-face) ; (setq in-face nil)) ; (setq in-face (point))) ; (not (eobp))))))) (defmacro c-debug-sws-msg (&rest args) ;;`(message ,@args) ) (defmacro c-put-is-sws (beg end) ;; This macro does a hidden buffer change. `(let ((beg ,beg) (end ,end)) (put-text-property beg end 'c-is-sws t) ,@(when (facep 'c-debug-is-sws-face) `((c-debug-add-face beg end 'c-debug-is-sws-face))))) (defmacro c-put-in-sws (beg end) ;; This macro does a hidden buffer change. `(let ((beg ,beg) (end ,end)) (put-text-property beg end 'c-in-sws t) ,@(when (facep 'c-debug-is-sws-face) `((c-debug-add-face beg end 'c-debug-in-sws-face))))) (defmacro c-remove-is-sws (beg end) ;; This macro does a hidden buffer change. `(let ((beg ,beg) (end ,end)) (remove-text-properties beg end '(c-is-sws nil)) ,@(when (facep 'c-debug-is-sws-face) `((c-debug-remove-face beg end 'c-debug-is-sws-face))))) (defmacro c-remove-in-sws (beg end) ;; This macro does a hidden buffer change. `(let ((beg ,beg) (end ,end)) (remove-text-properties beg end '(c-in-sws nil)) ,@(when (facep 'c-debug-is-sws-face) `((c-debug-remove-face beg end 'c-debug-in-sws-face))))) (defmacro c-remove-is-and-in-sws (beg end) ;; This macro does a hidden buffer change. `(let ((beg ,beg) (end ,end)) (remove-text-properties beg end '(c-is-sws nil c-in-sws nil)) ,@(when (facep 'c-debug-is-sws-face) `((c-debug-remove-face beg end 'c-debug-is-sws-face) (c-debug-remove-face beg end 'c-debug-in-sws-face))))) (defsubst c-invalidate-sws-region-after (beg end) ;; Called from `after-change-functions'. Note that if ;; `c-forward-sws' or `c-backward-sws' are used outside ;; `c-save-buffer-state' or similar then this will remove the cache ;; properties right after they're added. ;; ;; This function does hidden buffer changes. (save-excursion ;; Adjust the end to remove the properties in any following simple ;; ws up to and including the next line break, if there is any ;; after the changed region. This is necessary e.g. when a rung ;; marked empty line is converted to a line comment by inserting ;; "//" before the line break. In that case the line break would ;; keep the rung mark which could make a later `c-backward-sws' ;; move into the line comment instead of over it. (goto-char end) (skip-chars-forward " \t\f\v") (when (and (eolp) (not (eobp))) (setq end (1+ (point))))) (when (and (= beg end) (get-text-property beg 'c-in-sws) (> beg (point-min)) (get-text-property (1- beg) 'c-in-sws)) ;; Ensure that an `c-in-sws' range gets broken. Note that it isn't ;; safe to keep a range that was continuous before the change. E.g: ;; ;; #define foo ;; \ ;; bar ;; ;; There can be a "ladder" between "#" and "b". Now, if the newline ;; after "foo" is removed then "bar" will become part of the cpp ;; directive instead of a syntactically relevant token. In that ;; case there's no longer syntactic ws from "#" to "b". (setq beg (1- beg))) (c-debug-sws-msg "c-invalidate-sws-region-after [%s..%s]" beg end) (c-remove-is-and-in-sws beg end)) (defun c-forward-sws () ;; Used by `c-forward-syntactic-ws' to implement the unbounded search. ;; ;; This function might do hidden buffer changes. (let (;; `rung-pos' is set to a position as early as possible in the ;; unmarked part of the simple ws region. (rung-pos (point)) next-rung-pos rung-end-pos last-put-in-sws-pos rung-is-marked next-rung-is-marked simple-ws-end ;; `safe-start' is set when it's safe to cache the start position. ;; It's not set if we've initially skipped over comments and line ;; continuations since we might have gone out through the end of a ;; macro then. This provision makes `c-forward-sws' not populate the ;; cache in the majority of cases, but otoh is `c-backward-sws' by far ;; more common. safe-start) ;; Skip simple ws and do a quick check on the following character to see ;; if it's anything that can't start syntactic ws, so we can bail out ;; early in the majority of cases when there just are a few ws chars. (skip-chars-forward " \t\n\r\f\v") (when (looking-at c-syntactic-ws-start) (setq rung-end-pos (min (1+ (point)) (point-max))) (if (setq rung-is-marked (text-property-any rung-pos rung-end-pos 'c-is-sws t)) ;; Find the last rung position to avoid setting properties in all ;; the cases when the marked rung is complete. ;; (`next-single-property-change' is certain to move at least one ;; step forward.) (setq rung-pos (1- (next-single-property-change rung-is-marked 'c-is-sws nil rung-end-pos))) ;; Got no marked rung here. Since the simple ws might have started ;; inside a line comment or cpp directive we must set `rung-pos' as ;; high as possible. (setq rung-pos (point))) (while (progn (while (when (and rung-is-marked (get-text-property (point) 'c-in-sws)) ;; The following search is the main reason that `c-in-sws' ;; and `c-is-sws' aren't combined to one property. (goto-char (next-single-property-change (point) 'c-in-sws nil (point-max))) (unless (get-text-property (point) 'c-is-sws) ;; If the `c-in-sws' region extended past the last ;; `c-is-sws' char we have to go back a bit. (or (get-text-property (1- (point)) 'c-is-sws) (goto-char (previous-single-property-change (point) 'c-is-sws))) (backward-char)) (c-debug-sws-msg "c-forward-sws cached move %s -> %s (max %s)" rung-pos (point) (point-max)) (setq rung-pos (point)) (and (> (skip-chars-forward " \t\n\r\f\v") 0) (not (eobp)))) ;; We'll loop here if there is simple ws after the last rung. ;; That means that there's been some change in it and it's ;; possible that we've stepped into another ladder, so extend ;; the previous one to join with it if there is one, and try to ;; use the cache again. (c-debug-sws-msg "c-forward-sws extending rung with [%s..%s] (max %s)" (1+ rung-pos) (1+ (point)) (point-max)) (unless (get-text-property (point) 'c-is-sws) ;; Remove any `c-in-sws' property from the last char of ;; the rung before we mark it with `c-is-sws', so that we ;; won't connect with the remains of a broken "ladder". (c-remove-in-sws (point) (1+ (point)))) (c-put-is-sws (1+ rung-pos) (1+ (point))) (c-put-in-sws rung-pos (setq rung-pos (point) last-put-in-sws-pos rung-pos))) (setq simple-ws-end (point)) (c-forward-comments) (cond ((/= (point) simple-ws-end) ;; Skipped over comments. Don't cache at eob in case the buffer ;; is narrowed. (not (eobp))) ((save-excursion (and c-opt-cpp-prefix (looking-at c-opt-cpp-start) (progn (skip-chars-backward " \t") (bolp)) (or (bobp) (progn (backward-char) (not (eq (char-before) ?\\)))))) ;; Skip a preprocessor directive. (end-of-line) (while (and (eq (char-before) ?\\) (= (forward-line 1) 0)) (end-of-line)) (forward-line 1) (setq safe-start t) ;; Don't cache at eob in case the buffer is narrowed. (not (eobp))))) ;; We've searched over a piece of non-white syntactic ws. See if this ;; can be cached. (setq next-rung-pos (point)) (skip-chars-forward " \t\n\r\f\v") (setq rung-end-pos (min (1+ (point)) (point-max))) (if (or ;; Cache if we haven't skipped comments only, and if we started ;; either from a marked rung or from a completely uncached ;; position. (and safe-start (or rung-is-marked (not (get-text-property simple-ws-end 'c-in-sws)))) ;; See if there's a marked rung in the encountered simple ws. If ;; so then we can cache, unless `safe-start' is nil. Even then ;; we need to do this to check if the cache can be used for the ;; next step. (and (setq next-rung-is-marked (text-property-any next-rung-pos rung-end-pos 'c-is-sws t)) safe-start)) (progn (c-debug-sws-msg "c-forward-sws caching [%s..%s] - [%s..%s] (max %s)" rung-pos (1+ simple-ws-end) next-rung-pos rung-end-pos (point-max)) ;; Remove the properties for any nested ws that might be cached. ;; Only necessary for `c-is-sws' since `c-in-sws' will be set ;; anyway. (c-remove-is-sws (1+ simple-ws-end) next-rung-pos) (unless (and rung-is-marked (= rung-pos simple-ws-end)) (c-put-is-sws rung-pos (1+ simple-ws-end)) (setq rung-is-marked t)) (c-put-in-sws rung-pos (setq rung-pos (point) last-put-in-sws-pos rung-pos)) (unless (get-text-property (1- rung-end-pos) 'c-is-sws) ;; Remove any `c-in-sws' property from the last char of ;; the rung before we mark it with `c-is-sws', so that we ;; won't connect with the remains of a broken "ladder". (c-remove-in-sws (1- rung-end-pos) rung-end-pos)) (c-put-is-sws next-rung-pos rung-end-pos)) (c-debug-sws-msg "c-forward-sws not caching [%s..%s] - [%s..%s] (max %s)" rung-pos (1+ simple-ws-end) next-rung-pos rung-end-pos (point-max)) ;; Set `rung-pos' for the next rung. It's the same thing here as ;; initially, except that the rung position is set as early as ;; possible since we can't be in the ending ws of a line comment or ;; cpp directive now. (if (setq rung-is-marked next-rung-is-marked) (setq rung-pos (1- (next-single-property-change rung-is-marked 'c-is-sws nil rung-end-pos))) (setq rung-pos next-rung-pos)) (setq safe-start t))) ;; Make sure that the newly marked `c-in-sws' region doesn't connect to ;; another one after the point (which might occur when editing inside a ;; comment or macro). (when (eq last-put-in-sws-pos (point)) (cond ((< last-put-in-sws-pos (point-max)) (c-debug-sws-msg "c-forward-sws clearing at %s for cache separation" last-put-in-sws-pos) (c-remove-in-sws last-put-in-sws-pos (1+ last-put-in-sws-pos))) (t ;; If at eob we have to clear the last character before the end ;; instead since the buffer might be narrowed and there might ;; be a `c-in-sws' after (point-max). In this case it's ;; necessary to clear both properties. (c-debug-sws-msg "c-forward-sws clearing thoroughly at %s for cache separation" (1- last-put-in-sws-pos)) (c-remove-is-and-in-sws (1- last-put-in-sws-pos) last-put-in-sws-pos)))) ))) (defun c-backward-sws () ;; Used by `c-backward-syntactic-ws' to implement the unbounded search. ;; ;; This function might do hidden buffer changes. (let (;; `rung-pos' is set to a position as late as possible in the unmarked ;; part of the simple ws region. (rung-pos (point)) next-rung-pos last-put-in-sws-pos rung-is-marked simple-ws-beg cmt-skip-pos) ;; Skip simple horizontal ws and do a quick check on the preceding ;; character to see if it's anying that can't end syntactic ws, so we can ;; bail out early in the majority of cases when there just are a few ws ;; chars. Newlines are complicated in the backward direction, so we can't ;; skip over them. (skip-chars-backward " \t\f") (when (and (not (bobp)) (save-excursion (backward-char) (looking-at c-syntactic-ws-end))) ;; Try to find a rung position in the simple ws preceding point, so that ;; we can get a cache hit even if the last bit of the simple ws has ;; changed recently. (setq simple-ws-beg (point)) (skip-chars-backward " \t\n\r\f\v") (if (setq rung-is-marked (text-property-any (point) (min (1+ rung-pos) (point-max)) 'c-is-sws t)) ;; `rung-pos' will be the earliest marked position, which means that ;; there might be later unmarked parts in the simple ws region. ;; It's not worth the effort to fix that; the last part of the ;; simple ws is also typically edited often, so it could be wasted. (goto-char (setq rung-pos rung-is-marked)) (goto-char simple-ws-beg)) (while (progn (while (when (and rung-is-marked (not (bobp)) (get-text-property (1- (point)) 'c-in-sws)) ;; The following search is the main reason that `c-in-sws' ;; and `c-is-sws' aren't combined to one property. (goto-char (previous-single-property-change (point) 'c-in-sws nil (point-min))) (unless (get-text-property (point) 'c-is-sws) ;; If the `c-in-sws' region extended past the first ;; `c-is-sws' char we have to go forward a bit. (goto-char (next-single-property-change (point) 'c-is-sws))) (c-debug-sws-msg "c-backward-sws cached move %s <- %s (min %s)" (point) rung-pos (point-min)) (setq rung-pos (point)) (if (and (< (min (skip-chars-backward " \t\f\v") (progn (setq simple-ws-beg (point)) (skip-chars-backward " \t\n\r\f\v"))) 0) (setq rung-is-marked (text-property-any (point) rung-pos 'c-is-sws t))) t (goto-char simple-ws-beg) nil)) ;; We'll loop here if there is simple ws before the first rung. ;; That means that there's been some change in it and it's ;; possible that we've stepped into another ladder, so extend ;; the previous one to join with it if there is one, and try to ;; use the cache again. (c-debug-sws-msg "c-backward-sws extending rung with [%s..%s] (min %s)" rung-is-marked rung-pos (point-min)) (unless (get-text-property (1- rung-pos) 'c-is-sws) ;; Remove any `c-in-sws' property from the last char of ;; the rung before we mark it with `c-is-sws', so that we ;; won't connect with the remains of a broken "ladder". (c-remove-in-sws (1- rung-pos) rung-pos)) (c-put-is-sws rung-is-marked rung-pos) (c-put-in-sws rung-is-marked (1- rung-pos)) (setq rung-pos rung-is-marked last-put-in-sws-pos rung-pos)) (c-backward-comments) (setq cmt-skip-pos (point)) (cond ((and c-opt-cpp-prefix (/= cmt-skip-pos simple-ws-beg) (c-beginning-of-macro)) ;; Inside a cpp directive. See if it should be skipped over. (let ((cpp-beg (point))) ;; Move back over all line continuations in the region skipped ;; over by `c-backward-comments'. If we go past it then we ;; started inside the cpp directive. (goto-char simple-ws-beg) (beginning-of-line) (while (and (> (point) cmt-skip-pos) (progn (backward-char) (eq (char-before) ?\\))) (beginning-of-line)) (if (< (point) cmt-skip-pos) ;; Don't move past the cpp directive if we began inside ;; it. Note that the position at the end of the last line ;; of the macro is also considered to be within it. (progn (goto-char cmt-skip-pos) nil) ;; It's worthwhile to spend a little bit of effort on finding ;; the end of the macro, to get a good `simple-ws-beg' ;; position for the cache. Note that `c-backward-comments' ;; could have stepped over some comments before going into ;; the macro, and then `simple-ws-beg' must be kept on the ;; same side of those comments. (goto-char simple-ws-beg) (skip-chars-backward " \t\n\r\f\v") (if (eq (char-before) ?\\) (forward-char)) (forward-line 1) (if (< (point) simple-ws-beg) ;; Might happen if comments after the macro were skipped ;; over. (setq simple-ws-beg (point))) (goto-char cpp-beg) t))) ((/= (save-excursion (skip-chars-forward " \t\n\r\f\v" simple-ws-beg) (setq next-rung-pos (point))) simple-ws-beg) ;; Skipped over comments. Must put point at the end of ;; the simple ws at point since we might be after a line ;; comment or cpp directive that's been partially ;; narrowed out, and we can't risk marking the simple ws ;; at the end of it. (goto-char next-rung-pos) t))) ;; We've searched over a piece of non-white syntactic ws. See if this ;; can be cached. (setq next-rung-pos (point)) (skip-chars-backward " \t\f\v") (if (or ;; Cache if we started either from a marked rung or from a ;; completely uncached position. rung-is-marked (not (get-text-property (1- simple-ws-beg) 'c-in-sws)) ;; Cache if there's a marked rung in the encountered simple ws. (save-excursion (skip-chars-backward " \t\n\r\f\v") (text-property-any (point) (min (1+ next-rung-pos) (point-max)) 'c-is-sws t))) (progn (c-debug-sws-msg "c-backward-sws caching [%s..%s] - [%s..%s] (min %s)" (point) (1+ next-rung-pos) simple-ws-beg (min (1+ rung-pos) (point-max)) (point-min)) ;; Remove the properties for any nested ws that might be cached. ;; Only necessary for `c-is-sws' since `c-in-sws' will be set ;; anyway. (c-remove-is-sws (1+ next-rung-pos) simple-ws-beg) (unless (and rung-is-marked (= simple-ws-beg rung-pos)) (let ((rung-end-pos (min (1+ rung-pos) (point-max)))) (unless (get-text-property (1- rung-end-pos) 'c-is-sws) ;; Remove any `c-in-sws' property from the last char of ;; the rung before we mark it with `c-is-sws', so that we ;; won't connect with the remains of a broken "ladder". (c-remove-in-sws (1- rung-end-pos) rung-end-pos)) (c-put-is-sws simple-ws-beg rung-end-pos) (setq rung-is-marked t))) (c-put-in-sws (setq simple-ws-beg (point) last-put-in-sws-pos simple-ws-beg) rung-pos) (c-put-is-sws (setq rung-pos simple-ws-beg) (1+ next-rung-pos))) (c-debug-sws-msg "c-backward-sws not caching [%s..%s] - [%s..%s] (min %s)" (point) (1+ next-rung-pos) simple-ws-beg (min (1+ rung-pos) (point-max)) (point-min)) (setq rung-pos next-rung-pos simple-ws-beg (point)) )) ;; Make sure that the newly marked `c-in-sws' region doesn't connect to ;; another one before the point (which might occur when editing inside a ;; comment or macro). (when (eq last-put-in-sws-pos (point)) (cond ((< (point-min) last-put-in-sws-pos) (c-debug-sws-msg "c-backward-sws clearing at %s for cache separation" (1- last-put-in-sws-pos)) (c-remove-in-sws (1- last-put-in-sws-pos) last-put-in-sws-pos)) ((> (point-min) 1) ;; If at bob and the buffer is narrowed, we have to clear the ;; character we're standing on instead since there might be a ;; `c-in-sws' before (point-min). In this case it's necessary ;; to clear both properties. (c-debug-sws-msg "c-backward-sws clearing thoroughly at %s for cache separation" last-put-in-sws-pos) (c-remove-is-and-in-sws last-put-in-sws-pos (1+ last-put-in-sws-pos))))) ))) ;; Other whitespace tools (defun c-partial-ws-p (beg end) ;; Is the region (beg end) WS, and is there WS (or BOB/EOB) next to the ;; region? This is a "heuristic" function. ..... ;; ;; The motivation for the second bit is to check whether removing this ;; region would coalesce two symbols. ;; ;; FIXME!!! This function doesn't check virtual semicolons in any way. Be ;; careful about using this function for, e.g. AWK. (2007/3/7) (save-excursion (let ((end+1 (min (1+ end) (point-max)))) (or (progn (goto-char (max (point-min) (1- beg))) (c-skip-ws-forward end) (eq (point) end)) (progn (goto-char beg) (c-skip-ws-forward end+1) (eq (point) end+1)))))) ;; A system for finding noteworthy parens before the point. (defvar c-state-cache nil) (make-variable-buffer-local 'c-state-cache) ;; The state cache used by `c-parse-state' to cut down the amount of ;; searching. It's the result from some earlier `c-parse-state' call. ;; ;; The use of the cached info is more effective if the next ;; `c-parse-state' call is on a line close by the one the cached state ;; was made at; the cache can actually slow down a little if the ;; cached state was made very far back in the buffer. The cache is ;; most effective if `c-parse-state' is used on each line while moving ;; forward. (defvar c-state-cache-start 1) (make-variable-buffer-local 'c-state-cache-start) ;; This is (point-min) when `c-state-cache' was calculated, since a ;; change of narrowing is likely to affect the parens that are visible ;; before the point. (defvar c-state-cache-good-pos 1) (make-variable-buffer-local 'c-state-cache-good-pos) ;; This is a position where `c-state-cache' is known to be correct. ;; It's a position inside one of the recorded unclosed parens or the ;; top level, but not further nested inside any literal or subparen ;; that is closed before the last recorded position. ;; ;; The exact position is chosen to try to be close to yet earlier than ;; the position where `c-state-cache' will be called next. Right now ;; the heuristic is to set it to the position after the last found ;; closing paren (of any type) before the line on which ;; `c-parse-state' was called. That is chosen primarily to work well ;; with refontification of the current line. (defsubst c-invalidate-state-cache (pos) ;; Invalidate all info on `c-state-cache' that applies to the buffer ;; at POS or higher. This is much like `c-whack-state-after', but ;; it never changes a paren pair element into an open paren element. ;; Doing that would mean that the new open paren wouldn't have the ;; required preceding paren pair element. (while (and (or c-state-cache (when (< pos c-state-cache-good-pos) (setq c-state-cache-good-pos 1) nil)) (let ((elem (car c-state-cache))) (if (consp elem) (or (< pos (cdr elem)) (when (< pos c-state-cache-good-pos) (setq c-state-cache-good-pos (cdr elem)) nil)) (or (<= pos elem) (when (< pos c-state-cache-good-pos) (setq c-state-cache-good-pos (1+ elem)) nil))))) (setq c-state-cache (cdr c-state-cache)))) (defun c-get-fallback-start-pos (here) ;; Return the start position for building `c-state-cache' from ;; scratch. (save-excursion ;; Go back 2 bods, but ignore any bogus positions returned by ;; beginning-of-defun (i.e. open paren in column zero). (goto-char here) (let ((cnt 2)) (while (not (or (bobp) (zerop cnt))) (c-beginning-of-defun-1) (if (eq (char-after) ?\{) (setq cnt (1- cnt))))) (point))) (defun c-parse-state () ;; Find and record all noteworthy parens between some good point ;; earlier in the file and point. That good point is at least the ;; beginning of the top-level construct we are in, or the beginning ;; of the preceding top-level construct if we aren't in one. ;; ;; The returned value is a list of the noteworthy parens with the ;; last one first. If an element in the list is an integer, it's ;; the position of an open paren which has not been closed before ;; the point. If an element is a cons, it gives the position of a ;; closed brace paren pair; the car is the start paren position and ;; the cdr is the position following the closing paren. Only the ;; last closed brace paren pair before each open paren and before ;; the point is recorded, and thus the state never contains two cons ;; elements in succession. ;; ;; Currently no characters which are given paren syntax with the ;; syntax-table property are recorded, i.e. angle bracket arglist ;; parens are never present here. Note that this might change. ;; ;; BUG: This function doesn't cope entirely well with unbalanced ;; parens in macros. E.g. in the following case the brace before ;; the macro isn't balanced with the one after it: ;; ;; { ;; #define X { ;; } ;; ;; This function might do hidden buffer changes. (save-restriction (let* ((here (point)) (here-bol (c-point 'bol)) (c-macro-start (c-query-macro-start)) (in-macro-start (or c-macro-start (point))) old-state last-pos brace-pair-open brace-pair-close pos save-pos) (c-invalidate-state-cache here) ;; If the minimum position has changed due to narrowing then we ;; have to fix the tail of `c-state-cache' accordingly. (unless (= c-state-cache-start (point-min)) (if (> (point-min) c-state-cache-start) ;; If point-min has moved forward then we just need to cut ;; off a bit of the tail. (let ((ptr (cons nil c-state-cache)) elem) (while (and (setq elem (car-safe (cdr ptr))) (>= (if (consp elem) (car elem) elem) (point-min))) (setq ptr (cdr ptr))) (when (consp ptr) (if (eq (cdr ptr) c-state-cache) (setq c-state-cache nil c-state-cache-good-pos 1) (setcdr ptr nil)))) ;; If point-min has moved backward then we drop the state ;; completely. It's possible to do a better job here and ;; recalculate the top only. (setq c-state-cache nil c-state-cache-good-pos 1)) (setq c-state-cache-start (point-min))) ;; Get the latest position we know are directly inside the ;; closest containing paren of the cached state. (setq last-pos (and c-state-cache (if (consp (car c-state-cache)) (cdr (car c-state-cache)) (1+ (car c-state-cache))))) (if (or (not last-pos) (< last-pos c-state-cache-good-pos)) (setq last-pos c-state-cache-good-pos) ;; Take the opportunity to move the cached good position ;; further down. (if (< last-pos here-bol) (setq c-state-cache-good-pos last-pos))) ;; Check if `last-pos' is in a macro. If it is, and we're not ;; in the same macro, we must discard everything on ;; `c-state-cache' that is inside the macro before using it. (save-excursion (goto-char last-pos) (when (and (c-beginning-of-macro) (/= (point) in-macro-start)) (c-invalidate-state-cache (point)) ;; Set `last-pos' again just like above except that there's ;; no use looking at `c-state-cache-good-pos' here. (setq last-pos (if c-state-cache (if (consp (car c-state-cache)) (cdr (car c-state-cache)) (1+ (car c-state-cache))) 1)))) ;; If we've moved very far from the last cached position then ;; it's probably better to redo it from scratch, otherwise we ;; might spend a lot of time searching from `last-pos' down to ;; here. (when (< last-pos (- here 20000)) ;; First get the fallback start position. If it turns out ;; that it's so far back that the cached state is closer then ;; we'll keep it afterall. (setq pos (c-get-fallback-start-pos here)) (if (<= pos last-pos) (setq pos nil) (setq last-pos nil c-state-cache nil c-state-cache-good-pos 1))) ;; Find the start position for the forward search. (Can't ;; search in the backward direction since the point might be in ;; some kind of literal.) (unless pos (setq old-state c-state-cache) ;; There's a cached state with a containing paren. Pop off ;; the stale containing sexps from it by going forward out of ;; parens as far as possible. (narrow-to-region (point-min) here) (let (placeholder pair-beg) (while (and c-state-cache (setq placeholder (c-up-list-forward last-pos))) (setq last-pos placeholder) (if (consp (car c-state-cache)) (setq pair-beg (car-safe (cdr c-state-cache)) c-state-cache (cdr-safe (cdr c-state-cache))) (setq pair-beg (car c-state-cache) c-state-cache (cdr c-state-cache)))) (when (and pair-beg (eq (char-after pair-beg) ?{)) ;; The last paren pair we moved out from was a brace ;; pair. Modify the state to record this as a closed ;; pair now. (if (consp (car-safe c-state-cache)) (setq c-state-cache (cdr c-state-cache))) (setq c-state-cache (cons (cons pair-beg last-pos) c-state-cache)))) ;; Check if the preceding balanced paren is within a ;; macro; it should be ignored if we're outside the ;; macro. There's no need to check any further upwards; ;; if the macro contains an unbalanced opening paren then ;; we're smoked anyway. (when (and (<= (point) in-macro-start) (consp (car c-state-cache))) (save-excursion (goto-char (car (car c-state-cache))) (when (c-beginning-of-macro) (setq here (point) c-state-cache (cdr c-state-cache))))) (unless (eq c-state-cache old-state) ;; Have to adjust the cached good position if state has been ;; popped off. (setq c-state-cache-good-pos (if c-state-cache (if (consp (car c-state-cache)) (cdr (car c-state-cache)) (1+ (car c-state-cache))) 1) old-state c-state-cache)) (when c-state-cache (setq pos last-pos))) ;; Get the fallback start position. (unless pos (setq pos (c-get-fallback-start-pos here) c-state-cache nil c-state-cache-good-pos 1)) (narrow-to-region (point-min) here) (while pos (setq save-pos pos brace-pair-open nil) ;; Find the balanced brace pairs. This loop is hot, so it ;; does ugly tricks to go faster. (c-safe (let (set-good-pos set-brace-pair) (while t (setq last-pos nil last-pos (scan-lists pos 1 -1)) ; Might signal. (setq pos (scan-lists last-pos 1 1) ; Might signal. set-good-pos (< pos here-bol) set-brace-pair (eq (char-before last-pos) ?{)) ;; Update the cached good position and record the brace ;; pair, whichever is applicable for the paren we've ;; just jumped over. But first check that it isn't ;; inside a macro and the point isn't inside the same ;; one. (when (and (or set-good-pos set-brace-pair) (or (>= pos in-macro-start) (save-excursion (goto-char pos) (not (c-beginning-of-macro))))) (if set-good-pos (setq c-state-cache-good-pos pos)) (if set-brace-pair (setq brace-pair-open last-pos brace-pair-close pos)))))) ;; Record the last brace pair. (when brace-pair-open (let ((head (car-safe c-state-cache))) (if (consp head) (progn (setcar head (1- brace-pair-open)) (setcdr head brace-pair-close)) (setq c-state-cache (cons (cons (1- brace-pair-open) brace-pair-close) c-state-cache))))) (if last-pos ;; Prepare to loop, but record the open paren only if it's ;; outside a macro or within the same macro as point, and ;; if it is a legitimate open paren and not some character ;; that got an open paren syntax-table property. (progn (setq pos last-pos) (when (and (or (>= last-pos in-macro-start) (save-excursion (goto-char last-pos) (not (c-beginning-of-macro)))) ;; Check for known types of parens that we ;; want to record. The syntax table is not to ;; be trusted here since the caller might be ;; using e.g. `c++-template-syntax-table'. (memq (char-before last-pos) '(?{ ?\( ?\[))) (if (< last-pos here-bol) (setq c-state-cache-good-pos last-pos)) (setq c-state-cache (cons (1- last-pos) c-state-cache)))) (if (setq last-pos (c-up-list-forward pos)) ;; Found a close paren without a corresponding opening ;; one. Maybe we didn't go back far enough, so try to ;; scan backward for the start paren and then start over. (progn (setq pos (c-up-list-backward pos) c-state-cache nil c-state-cache-good-pos c-state-cache-start) (when (or (not pos) ;; Emacs (up to at least 21.2) can get confused by ;; open parens in column zero inside comments: The ;; sexp functions can then misbehave and bring us ;; back to the same point again. Check this so that ;; we don't get an infinite loop. (>= pos save-pos)) (setq pos last-pos c-parsing-error (format "Unbalanced close paren at line %d" (1+ (count-lines (point-min) (c-point 'bol last-pos))))))) (setq pos nil)))) ;;(message "c-parse-state: %S end: %S" c-state-cache c-state-cache-good-pos) c-state-cache))) ;; Debug tool to catch cache inconsistencies. (defvar c-debug-parse-state nil) (unless (fboundp 'c-real-parse-state) (fset 'c-real-parse-state (symbol-function 'c-parse-state))) (cc-bytecomp-defun c-real-parse-state) (defun c-debug-parse-state () (let ((res1 (c-real-parse-state)) res2) (let ((c-state-cache nil) (c-state-cache-start 1) (c-state-cache-good-pos 1)) (setq res2 (c-real-parse-state))) (unless (equal res1 res2) ;; The cache can actually go further back due to the ad-hoc way ;; the first paren is found, so try to whack off a bit of its ;; start before complaining. (save-excursion (goto-char (or (c-least-enclosing-brace res2) (point))) (c-beginning-of-defun-1) (while (not (or (bobp) (eq (char-after) ?{))) (c-beginning-of-defun-1)) (unless (equal (c-whack-state-before (point) res1) res2) (message (concat "c-parse-state inconsistency: " "using cache: %s, from scratch: %s") res1 res2)))) res1)) (defun c-toggle-parse-state-debug (&optional arg) (interactive "P") (setq c-debug-parse-state (c-calculate-state arg c-debug-parse-state)) (fset 'c-parse-state (symbol-function (if c-debug-parse-state 'c-debug-parse-state 'c-real-parse-state))) (c-keep-region-active)) (when c-debug-parse-state (c-toggle-parse-state-debug 1)) (defun c-whack-state-before (bufpos paren-state) ;; Whack off any state information from PAREN-STATE which lies ;; before BUFPOS. Not destructive on PAREN-STATE. (let* ((newstate (list nil)) (ptr newstate) car) (while paren-state (setq car (car paren-state) paren-state (cdr paren-state)) (if (< (if (consp car) (car car) car) bufpos) (setq paren-state nil) (setcdr ptr (list car)) (setq ptr (cdr ptr)))) (cdr newstate))) (defun c-whack-state-after (bufpos paren-state) ;; Whack off any state information from PAREN-STATE which lies at or ;; after BUFPOS. Not destructive on PAREN-STATE. (catch 'done (while paren-state (let ((car (car paren-state))) (if (consp car) ;; just check the car, because in a balanced brace ;; expression, it must be impossible for the corresponding ;; close brace to be before point, but the open brace to ;; be after. (if (<= bufpos (car car)) nil ; whack it off (if (< bufpos (cdr car)) ;; its possible that the open brace is before ;; bufpos, but the close brace is after. In that ;; case, convert this to a non-cons element. The ;; rest of the state is before bufpos, so we're ;; done. (throw 'done (cons (car car) (cdr paren-state))) ;; we know that both the open and close braces are ;; before bufpos, so we also know that everything else ;; on state is before bufpos. (throw 'done paren-state))) (if (<= bufpos car) nil ; whack it off ;; it's before bufpos, so everything else should too. (throw 'done paren-state))) (setq paren-state (cdr paren-state))) nil))) (defun c-most-enclosing-brace (paren-state &optional bufpos) ;; Return the bufpos of the innermost enclosing open paren before ;; bufpos, or nil if none was found. (let (enclosingp) (or bufpos (setq bufpos 134217727)) (while paren-state (setq enclosingp (car paren-state) paren-state (cdr paren-state)) (if (or (consp enclosingp) (>= enclosingp bufpos)) (setq enclosingp nil) (setq paren-state nil))) enclosingp)) (defun c-least-enclosing-brace (paren-state) ;; Return the bufpos of the outermost enclosing open paren, or nil ;; if none was found. (let (pos elem) (while paren-state (setq elem (car paren-state) paren-state (cdr paren-state)) (if (integerp elem) (setq pos elem))) pos)) (defun c-safe-position (bufpos paren-state) ;; Return the closest "safe" position recorded on PAREN-STATE that ;; is higher up than BUFPOS. Return nil if PAREN-STATE doesn't ;; contain any. Return nil if BUFPOS is nil, which is useful to ;; find the closest limit before a given limit that might be nil. ;; ;; A "safe" position is a position at or after a recorded open ;; paren, or after a recorded close paren. The returned position is ;; thus either the first position after a close brace, or the first ;; position after an enclosing paren, or at the enclosing paren in ;; case BUFPOS is immediately after it. (when bufpos (let (elem) (catch 'done (while paren-state (setq elem (car paren-state)) (if (consp elem) (cond ((< (cdr elem) bufpos) (throw 'done (cdr elem))) ((< (car elem) bufpos) ;; See below. (throw 'done (min (1+ (car elem)) bufpos)))) (if (< elem bufpos) ;; elem is the position at and not after the opening paren, so ;; we can go forward one more step unless it's equal to ;; bufpos. This is useful in some cases avoid an extra paren ;; level between the safe position and bufpos. (throw 'done (min (1+ elem) bufpos)))) (setq paren-state (cdr paren-state))))))) (defun c-beginning-of-syntax () ;; This is used for `font-lock-beginning-of-syntax-function'. It ;; goes to the closest previous point that is known to be outside ;; any string literal or comment. `c-state-cache' is used if it has ;; a position in the vicinity. (let* ((paren-state c-state-cache) elem (pos (catch 'done ;; Note: Similar code in `c-safe-position'. The ;; difference is that we accept a safe position at ;; the point and don't bother to go forward past open ;; parens. (while paren-state (setq elem (car paren-state)) (if (consp elem) (cond ((<= (cdr elem) (point)) (throw 'done (cdr elem))) ((<= (car elem) (point)) (throw 'done (car elem)))) (if (<= elem (point)) (throw 'done elem))) (setq paren-state (cdr paren-state))) (point-min)))) (if (> pos (- (point) 4000)) (goto-char pos) ;; The position is far back. Try `c-beginning-of-defun-1' ;; (although we can't be entirely sure it will go to a position ;; outside a comment or string in current emacsen). FIXME: ;; Consult `syntax-ppss' here. (c-beginning-of-defun-1) (if (< (point) pos) (goto-char pos))))) ;; Tools for scanning identifiers and other tokens. (defun c-on-identifier () "Return non-nil if the point is on or directly after an identifier. Keywords are recognized and not considered identifiers. If an identifier is detected, the returned value is its starting position. If an identifier ends at the point and another begins at it \(can only happen in Pike) then the point for the preceding one is returned. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." ;; FIXME: Shouldn't this function handle "operator" in C++? (save-excursion (skip-syntax-backward "w_") (or ;; Check for a normal (non-keyword) identifier. (and (looking-at c-symbol-start) (not (looking-at c-keywords-regexp)) (point)) (when (c-major-mode-is 'pike-mode) ;; Handle the ` syntax in Pike. (let ((pos (point))) (skip-chars-backward "-!%&*+/<=>^|~[]()") (and (if (< (skip-chars-backward "`") 0) t (goto-char pos) (eq (char-after) ?\`)) (looking-at c-symbol-key) (>= (match-end 0) pos) (point)))) ;; Handle the "operator +" syntax in C++. (when (and c-overloadable-operators-regexp (= (c-backward-token-2 0) 0)) (cond ((and (looking-at c-overloadable-operators-regexp) (or (not c-opt-op-identifier-prefix) (and (= (c-backward-token-2 1) 0) (looking-at c-opt-op-identifier-prefix)))) (point)) ((save-excursion (and c-opt-op-identifier-prefix (looking-at c-opt-op-identifier-prefix) (= (c-forward-token-2 1) 0) (looking-at c-overloadable-operators-regexp))) (point)))) ))) (defsubst c-simple-skip-symbol-backward () ;; If the point is at the end of a symbol then skip backward to the ;; beginning of it. Don't move otherwise. Return non-nil if point ;; moved. ;; ;; This function might do hidden buffer changes. (or (< (skip-syntax-backward "w_") 0) (and (c-major-mode-is 'pike-mode) ;; Handle the ` syntax in Pike. (let ((pos (point))) (if (and (< (skip-chars-backward "-!%&*+/<=>^|~[]()") 0) (< (skip-chars-backward "`") 0) (looking-at c-symbol-key) (>= (match-end 0) pos)) t (goto-char pos) nil))))) (defun c-beginning-of-current-token (&optional back-limit) ;; Move to the beginning of the current token. Do not move if not ;; in the middle of one. BACK-LIMIT may be used to bound the ;; backward search; if given it's assumed to be at the boundary ;; between two tokens. Return non-nil if the point is move, nil ;; otherwise. ;; ;; This function might do hidden buffer changes. (let ((start (point))) (if (looking-at "\\w\\|\\s_") (skip-syntax-backward "w_" back-limit) (when (< (skip-syntax-backward ".()" back-limit) 0) (while (let ((pos (or (and (looking-at c-nonsymbol-token-regexp) (match-end 0)) ;; `c-nonsymbol-token-regexp' should always match ;; since we've skipped backward over punctuator ;; or paren syntax, but consume one char in case ;; it doesn't so that we don't leave point before ;; some earlier incorrect token. (1+ (point))))) (if (<= pos start) (goto-char pos)))))) (< (point) start))) (defun c-end-of-current-token (&optional back-limit) ;; Move to the end of the current token. Do not move if not in the ;; middle of one. BACK-LIMIT may be used to bound the backward ;; search; if given it's assumed to be at the boundary between two ;; tokens. Return non-nil if the point is moved, nil otherwise. ;; ;; This function might do hidden buffer changes. (let ((start (point))) (cond ((< (skip-syntax-backward "w_" (1- start)) 0) (skip-syntax-forward "w_")) ((< (skip-syntax-backward ".()" back-limit) 0) (while (progn (if (looking-at c-nonsymbol-token-regexp) (goto-char (match-end 0)) ;; `c-nonsymbol-token-regexp' should always match since ;; we've skipped backward over punctuator or paren ;; syntax, but move forward in case it doesn't so that ;; we don't leave point earlier than we started with. (forward-char)) (< (point) start))))) (> (point) start))) (defconst c-jump-syntax-balanced (if (memq 'gen-string-delim c-emacs-features) "\\w\\|\\s_\\|\\s\(\\|\\s\)\\|\\s\"\\|\\s|" "\\w\\|\\s_\\|\\s\(\\|\\s\)\\|\\s\"")) (defconst c-jump-syntax-unbalanced (if (memq 'gen-string-delim c-emacs-features) "\\w\\|\\s_\\|\\s\"\\|\\s|" "\\w\\|\\s_\\|\\s\"")) (defun c-forward-token-2 (&optional count balanced limit) "Move forward by tokens. A token is defined as all symbols and identifiers which aren't syntactic whitespace \(note that multicharacter tokens like \"==\" are treated properly). Point is always either left at the beginning of a token or not moved at all. COUNT specifies the number of tokens to move; a negative COUNT moves in the opposite direction. A COUNT of 0 moves to the next token beginning only if not already at one. If BALANCED is true, move over balanced parens, otherwise move into them. Also, if BALANCED is true, never move out of an enclosing paren. LIMIT sets the limit for the movement and defaults to the point limit. The case when LIMIT is set in the middle of a token, comment or macro is handled correctly, i.e. the point won't be left there. Return the number of tokens left to move \(positive or negative). If BALANCED is true, a move over a balanced paren counts as one. Note that if COUNT is 0 and no appropriate token beginning is found, 1 will be returned. Thus, a return value of 0 guarantees that point is at the requested position and a return value less \(without signs) than COUNT guarantees that point is at the beginning of some token. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (or count (setq count 1)) (if (< count 0) (- (c-backward-token-2 (- count) balanced limit)) (let ((jump-syntax (if balanced c-jump-syntax-balanced c-jump-syntax-unbalanced)) (last (point)) (prev (point))) (if (zerop count) ;; If count is zero we should jump if in the middle of a token. (c-end-of-current-token)) (save-restriction (if limit (narrow-to-region (point-min) limit)) (if (/= (point) (progn (c-forward-syntactic-ws) (point))) ;; Skip whitespace. Count this as a move if we did in ;; fact move. (setq count (max (1- count) 0))) (if (eobp) ;; Moved out of bounds. Make sure the returned count isn't zero. (progn (if (zerop count) (setq count 1)) (goto-char last)) ;; Use `condition-case' to avoid having the limit tests ;; inside the loop. (condition-case nil (while (and (> count 0) (progn (setq last (point)) (cond ((looking-at jump-syntax) (goto-char (scan-sexps (point) 1)) t) ((looking-at c-nonsymbol-token-regexp) (goto-char (match-end 0)) t) ;; `c-nonsymbol-token-regexp' above should always ;; match if there are correct tokens. Try to ;; widen to see if the limit was set in the ;; middle of one, else fall back to treating ;; the offending thing as a one character token. ((and limit (save-restriction (widen) (looking-at c-nonsymbol-token-regexp))) nil) (t (forward-char) t)))) (c-forward-syntactic-ws) (setq prev last count (1- count))) (error (goto-char last))) (when (eobp) (goto-char prev) (setq count (1+ count))))) count))) (defun c-backward-token-2 (&optional count balanced limit) "Move backward by tokens. See `c-forward-token-2' for details." (or count (setq count 1)) (if (< count 0) (- (c-forward-token-2 (- count) balanced limit)) (or limit (setq limit (point-min))) (let ((jump-syntax (if balanced c-jump-syntax-balanced c-jump-syntax-unbalanced)) (last (point))) (if (zerop count) ;; The count is zero so try to skip to the beginning of the ;; current token. (if (> (point) (progn (c-beginning-of-current-token) (point))) (if (< (point) limit) ;; The limit is inside the same token, so return 1. (setq count 1)) ;; We're not in the middle of a token. If there's ;; whitespace after the point then we must move backward, ;; so set count to 1 in that case. (and (looking-at c-syntactic-ws-start) ;; If we're looking at a '#' that might start a cpp ;; directive then we have to do a more elaborate check. (or (/= (char-after) ?#) (not c-opt-cpp-prefix) (save-excursion (and (= (point) (progn (beginning-of-line) (looking-at "[ \t]*") (match-end 0))) (or (bobp) (progn (backward-char) (not (eq (char-before) ?\\))))))) (setq count 1)))) ;; Use `condition-case' to avoid having to check for buffer ;; limits in `backward-char', `scan-sexps' and `goto-char' below. (condition-case nil (while (and (> count 0) (progn (c-backward-syntactic-ws) (backward-char) (if (looking-at jump-syntax) (goto-char (scan-sexps (1+ (point)) -1)) ;; This can be very inefficient if there's a long ;; sequence of operator tokens without any separation. ;; That doesn't happen in practice, anyway. (c-beginning-of-current-token)) (>= (point) limit))) (setq last (point) count (1- count))) (error (goto-char last))) (if (< (point) limit) (goto-char last)) count))) (defun c-forward-token-1 (&optional count balanced limit) "Like `c-forward-token-2' but doesn't treat multicharacter operator tokens like \"==\" as single tokens, i.e. all sequences of symbol characters are jumped over character by character. This function is for compatibility only; it's only a wrapper over `c-forward-token-2'." (let ((c-nonsymbol-token-regexp "\\s.\\|\\s\(\\|\\s\)")) (c-forward-token-2 count balanced limit))) (defun c-backward-token-1 (&optional count balanced limit) "Like `c-backward-token-2' but doesn't treat multicharacter operator tokens like \"==\" as single tokens, i.e. all sequences of symbol characters are jumped over character by character. This function is for compatibility only; it's only a wrapper over `c-backward-token-2'." (let ((c-nonsymbol-token-regexp "\\s.\\|\\s\(\\|\\s\)")) (c-backward-token-2 count balanced limit))) ;; Tools for doing searches restricted to syntactically relevant text. (defun c-syntactic-re-search-forward (regexp &optional bound noerror paren-level not-inside-token lookbehind-submatch) "Like `re-search-forward', but only report matches that are found in syntactically significant text. I.e. matches in comments, macros or string literals are ignored. The start point is assumed to be outside any comment, macro or string literal, or else the content of that region is taken as syntactically significant text. If PAREN-LEVEL is non-nil, an additional restriction is added to ignore matches in nested paren sexps. The search will also not go outside the current list sexp, which has the effect that if the point should be moved to BOUND when no match is found \(i.e. NOERROR is neither nil nor t), then it will be at the closing paren if the end of the current list sexp is encountered first. If NOT-INSIDE-TOKEN is non-nil, matches in the middle of tokens are ignored. Things like multicharacter operators and special symbols \(e.g. \"`()\" in Pike) are handled but currently not floating point constants. If LOOKBEHIND-SUBMATCH is non-nil, it's taken as a number of a subexpression in REGEXP. The end of that submatch is used as the position to check for syntactic significance. If LOOKBEHIND-SUBMATCH isn't used or if that subexpression didn't match then the start position of the whole match is used instead. The \"look behind\" subexpression is never tested before the starting position, so it might be a good idea to include \\=\\= as a match alternative in it. Optimization note: Matches might be missed if the \"look behind\" subexpression can match the end of nonwhite syntactic whitespace, i.e. the end of comments or cpp directives. This since the function skips over such things before resuming the search. It's on the other hand not safe to assume that the \"look behind\" subexpression never matches syntactic whitespace. Bug: Unbalanced parens inside cpp directives are currently not handled correctly \(i.e. they don't get ignored as they should) when PAREN-LEVEL is set. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (or bound (setq bound (point-max))) (if paren-level (setq paren-level -1)) ;;(message "c-syntactic-re-search-forward %s %s %S" (point) bound regexp) (let ((start (point)) tmp ;; Start position for the last search. search-pos ;; The `parse-partial-sexp' state between the start position ;; and the point. state ;; The current position after the last state update. The next ;; `parse-partial-sexp' continues from here. (state-pos (point)) ;; The position at which to check the state and the state ;; there. This is separate from `state-pos' since we might ;; need to back up before doing the next search round. check-pos check-state ;; Last position known to end a token. (last-token-end-pos (point-min)) ;; Set when a valid match is found. found) (condition-case err (while (and (progn (setq search-pos (point)) (re-search-forward regexp bound noerror)) (progn (setq state (parse-partial-sexp state-pos (match-beginning 0) paren-level nil state) state-pos (point)) (if (setq check-pos (and lookbehind-submatch (or (not paren-level) (>= (car state) 0)) (match-end lookbehind-submatch))) (setq check-state (parse-partial-sexp state-pos check-pos paren-level nil state)) (setq check-pos state-pos check-state state)) ;; NOTE: If we got a look behind subexpression and get ;; an insignificant match in something that isn't ;; syntactic whitespace (i.e. strings or in nested ;; parentheses), then we can never skip more than a ;; single character from the match start position ;; (i.e. `state-pos' here) before continuing the ;; search. That since the look behind subexpression ;; might match the end of the insignificant region in ;; the next search. (cond ((elt check-state 7) ;; Match inside a line comment. Skip to eol. Use ;; `re-search-forward' instead of `skip-chars-forward' to get ;; the right bound behavior. (re-search-forward "[\n\r]" bound noerror)) ((elt check-state 4) ;; Match inside a block comment. Skip to the '*/'. (search-forward "*/" bound noerror)) ((and (not (elt check-state 5)) (eq (char-before check-pos) ?/) (not (c-get-char-property (1- check-pos) 'syntax-table)) (memq (char-after check-pos) '(?/ ?*))) ;; Match in the middle of the opener of a block or line ;; comment. (if (= (char-after check-pos) ?/) (re-search-forward "[\n\r]" bound noerror) (search-forward "*/" bound noerror))) ;; The last `parse-partial-sexp' above might have ;; stopped short of the real check position if the end ;; of the current sexp was encountered in paren-level ;; mode. The checks above are always false in that ;; case, and since they can do better skipping in ;; lookbehind-submatch mode, we do them before ;; checking the paren level. ((and paren-level (/= (setq tmp (car check-state)) 0)) ;; Check the paren level first since we're short of the ;; syntactic checking position if the end of the ;; current sexp was encountered by `parse-partial-sexp'. (if (> tmp 0) ;; Inside a nested paren sexp. (if lookbehind-submatch ;; See the NOTE above. (progn (goto-char state-pos) t) ;; Skip out of the paren quickly. (setq state (parse-partial-sexp state-pos bound 0 nil state) state-pos (point))) ;; Have exited the current paren sexp. (if noerror (progn ;; The last `parse-partial-sexp' call above ;; has left us just after the closing paren ;; in this case, so we can modify the bound ;; to leave the point at the right position ;; upon return. (setq bound (1- (point))) nil) (signal 'search-failed (list regexp))))) ((setq tmp (elt check-state 3)) ;; Match inside a string. (if (or lookbehind-submatch (not (integerp tmp))) ;; See the NOTE above. (progn (goto-char state-pos) t) ;; Skip to the end of the string before continuing. (let ((ender (make-string 1 tmp)) (continue t)) (while (if (search-forward ender bound noerror) (progn (setq state (parse-partial-sexp state-pos (point) nil nil state) state-pos (point)) (elt state 3)) (setq continue nil))) continue))) ((save-excursion (save-match-data (c-beginning-of-macro start))) ;; Match inside a macro. Skip to the end of it. (c-end-of-macro) (cond ((<= (point) bound) t) (noerror nil) (t (signal 'search-failed (list regexp))))) ((and not-inside-token (or (< check-pos last-token-end-pos) (< check-pos (save-excursion (goto-char check-pos) (save-match-data (c-end-of-current-token last-token-end-pos)) (setq last-token-end-pos (point)))))) ;; Inside a token. (if lookbehind-submatch ;; See the NOTE above. (goto-char state-pos) (goto-char (min last-token-end-pos bound)))) (t ;; A real match. (setq found t) nil))) ;; Should loop to search again, but take care to avoid ;; looping on the same spot. (or (/= search-pos (point)) (if (= (point) bound) (if noerror nil (signal 'search-failed (list regexp))) (forward-char) t)))) (error (goto-char start) (signal (car err) (cdr err)))) ;;(message "c-syntactic-re-search-forward done %s" (or (match-end 0) (point))) (if found (progn (goto-char (match-end 0)) (match-end 0)) ;; Search failed. Set point as appropriate. (if (eq noerror t) (goto-char start) (goto-char bound)) nil))) (defun c-syntactic-skip-backward (skip-chars &optional limit paren-level) "Like `skip-chars-backward' but only look at syntactically relevant chars, i.e. don't stop at positions inside syntactic whitespace or string literals. Preprocessor directives are also ignored, with the exception of the one that the point starts within, if any. If LIMIT is given, it's assumed to be at a syntactically relevant position. If PAREN-LEVEL is non-nil, the function won't stop in nested paren sexps, and the search will also not go outside the current paren sexp. However, if LIMIT or the buffer limit is reached inside a nested paren then the point will be left at the limit. Non-nil is returned if the point moved, nil otherwise. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (let ((start (point)) state ;; A list of syntactically relevant positions in descending ;; order. It's used to avoid scanning repeatedly over ;; potentially large regions with `parse-partial-sexp' to verify ;; each position. safe-pos-list ;; The position at the beginning of `safe-pos-list'. safe-pos ;; The result from `c-beginning-of-macro' at the start position or the ;; start position itself if it isn't within a macro. Evaluated on ;; demand. start-macro-beg ;; The earliest position after the current one with the same paren ;; level. Used only when `paren-level' is set. (paren-level-pos (point))) (while (progn (while (and (< (skip-chars-backward skip-chars limit) 0) ;; Use `parse-partial-sexp' from a safe position down to ;; the point to check if it's outside comments and ;; strings. (let ((pos (point)) state-2 pps-end-pos) ;; Pick a safe position as close to the point as ;; possible. ;; ;; FIXME: Consult `syntax-ppss' here if our ;; cache doesn't give a good position. (while (and safe-pos-list (> (car safe-pos-list) (point))) (setq safe-pos-list (cdr safe-pos-list))) (unless (setq safe-pos (car-safe safe-pos-list)) (setq safe-pos (max (or (c-safe-position (point) (or c-state-cache (c-parse-state))) 0) (point-min)) safe-pos-list (list safe-pos))) ;; Cache positions along the way to use if we have to ;; back up more. We cache every closing paren on the ;; same level. If the paren cache is relevant in this ;; region then we're typically already on the same ;; level as the target position. Note that we might ;; cache positions after opening parens in case ;; safe-pos is in a nested list. That's both uncommon ;; and harmless. (while (progn (setq state (parse-partial-sexp safe-pos pos 0)) (< (point) pos)) (setq safe-pos (point) safe-pos-list (cons safe-pos safe-pos-list))) (cond ((or (elt state 3) (elt state 4)) ;; Inside string or comment. Continue search at the ;; beginning of it. (goto-char (elt state 8)) t) ((and paren-level (save-excursion (setq state-2 (parse-partial-sexp pos paren-level-pos -1) pps-end-pos (point)) (/= (car state-2) 0))) ;; Not at the right level. (if (and (< (car state-2) 0) ;; We stop above if we go out of a paren. ;; Now check whether it precedes or is ;; nested in the starting sexp. (save-excursion (setq state-2 (parse-partial-sexp pps-end-pos paren-level-pos nil nil state-2)) (< (car state-2) 0))) ;; We've stopped short of the starting position ;; so the hit was inside a nested list. Go up ;; until we are at the right level. (condition-case nil (progn (goto-char (scan-lists pos -1 (- (car state-2)))) (setq paren-level-pos (point)) (if (and limit (>= limit paren-level-pos)) (progn (goto-char limit) nil) t)) (error (goto-char (or limit (point-min))) nil)) ;; The hit was outside the list at the start ;; position. Go to the start of the list and exit. (goto-char (1+ (elt state-2 1))) nil)) ((c-beginning-of-macro limit) ;; Inside a macro. (if (< (point) (or start-macro-beg (setq start-macro-beg (save-excursion (goto-char start) (c-beginning-of-macro limit) (point))))) t ;; It's inside the same macro we started in so it's ;; a relevant match. (goto-char pos) nil))))) ;; If the state contains the start of the containing sexp we ;; cache that position too, so that parse-partial-sexp in the ;; next run has a bigger chance of starting at the same level ;; as the target position and thus will get more good safe ;; positions into the list. (if (elt state 1) (setq safe-pos (1+ (elt state 1)) safe-pos-list (cons safe-pos safe-pos-list)))) (> (point) (progn ;; Skip syntactic ws afterwards so that we don't stop at the ;; end of a comment if `skip-chars' is something like "^/". (c-backward-syntactic-ws) (point))))) ;; We might want to extend this with more useful return values in ;; the future. (/= (point) start))) ;; The following is an alternative implementation of ;; `c-syntactic-skip-backward' that uses backward movement to keep ;; track of the syntactic context. It turned out to be generally ;; slower than the one above which uses forward checks from earlier ;; safe positions. ;; ;;(defconst c-ssb-stop-re ;; ;; The regexp matching chars `c-syntactic-skip-backward' needs to ;; ;; stop at to avoid going into comments and literals. ;; (concat ;; ;; Match comment end syntax and string literal syntax. Also match ;; ;; '/' for block comment endings (not covered by comment end ;; ;; syntax). ;; "\\s>\\|/\\|\\s\"" ;; (if (memq 'gen-string-delim c-emacs-features) ;; "\\|\\s|" ;; "") ;; (if (memq 'gen-comment-delim c-emacs-features) ;; "\\|\\s!" ;; ""))) ;; ;;(defconst c-ssb-stop-paren-re ;; ;; Like `c-ssb-stop-re' but also stops at paren chars. ;; (concat c-ssb-stop-re "\\|\\s(\\|\\s)")) ;; ;;(defconst c-ssb-sexp-end-re ;; ;; Regexp matching the ending syntax of a complex sexp. ;; (concat c-string-limit-regexp "\\|\\s)")) ;; ;;(defun c-syntactic-skip-backward (skip-chars &optional limit paren-level) ;; "Like `skip-chars-backward' but only look at syntactically relevant chars, ;;i.e. don't stop at positions inside syntactic whitespace or string ;;literals. Preprocessor directives are also ignored. However, if the ;;point is within a comment, string literal or preprocessor directory to ;;begin with, its contents is treated as syntactically relevant chars. ;;If LIMIT is given, it limits the backward search and the point will be ;;left there if no earlier position is found. ;; ;;If PAREN-LEVEL is non-nil, the function won't stop in nested paren ;;sexps, and the search will also not go outside the current paren sexp. ;;However, if LIMIT or the buffer limit is reached inside a nested paren ;;then the point will be left at the limit. ;; ;;Non-nil is returned if the point moved, nil otherwise. ;; ;;Note that this function might do hidden buffer changes. See the ;;comment at the start of cc-engine.el for more info." ;; ;; (save-restriction ;; (when limit ;; (narrow-to-region limit (point-max))) ;; ;; (let ((start (point))) ;; (catch 'done ;; (while (let ((last-pos (point)) ;; (stop-pos (progn ;; (skip-chars-backward skip-chars) ;; (point)))) ;; ;; ;; Skip back over the same region as ;; ;; `skip-chars-backward' above, but keep to ;; ;; syntactically relevant positions. ;; (goto-char last-pos) ;; (while (and ;; ;; `re-search-backward' with a single char regexp ;; ;; should be fast. ;; (re-search-backward ;; (if paren-level c-ssb-stop-paren-re c-ssb-stop-re) ;; stop-pos 'move) ;; ;; (progn ;; (cond ;; ((looking-at "\\s(") ;; ;; `paren-level' is set and we've found the ;; ;; start of the containing paren. ;; (forward-char) ;; (throw 'done t)) ;; ;; ((looking-at c-ssb-sexp-end-re) ;; ;; We're at the end of a string literal or paren ;; ;; sexp (if `paren-level' is set). ;; (forward-char) ;; (condition-case nil ;; (c-backward-sexp) ;; (error ;; (goto-char limit) ;; (throw 'done t)))) ;; ;; (t ;; (forward-char) ;; ;; At the end of some syntactic ws or possibly ;; ;; after a plain '/' operator. ;; (let ((pos (point))) ;; (c-backward-syntactic-ws) ;; (if (= pos (point)) ;; ;; Was a plain '/' operator. Go past it. ;; (backward-char))))) ;; ;; (> (point) stop-pos)))) ;; ;; ;; Now the point is either at `stop-pos' or at some ;; ;; position further back if `stop-pos' was at a ;; ;; syntactically irrelevant place. ;; ;; ;; Skip additional syntactic ws so that we don't stop ;; ;; at the end of a comment if `skip-chars' is ;; ;; something like "^/". ;; (c-backward-syntactic-ws) ;; ;; (< (point) stop-pos)))) ;; ;; ;; We might want to extend this with more useful return values ;; ;; in the future. ;; (/= (point) start)))) ;; Tools for handling comments and string literals. (defun c-slow-in-literal (&optional lim detect-cpp) "Return the type of literal point is in, if any. The return value is `c' if in a C-style comment, `c++' if in a C++ style comment, `string' if in a string literal, `pound' if DETECT-CPP is non-nil and in a preprocessor line, or nil if somewhere else. Optional LIM is used as the backward limit of the search. If omitted, or nil, `c-beginning-of-defun' is used. The last point calculated is cached if the cache is enabled, i.e. if `c-in-literal-cache' is bound to a two element vector. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (if (and (vectorp c-in-literal-cache) (= (point) (aref c-in-literal-cache 0))) (aref c-in-literal-cache 1) (let ((rtn (save-excursion (let* ((pos (point)) (lim (or lim (progn (c-beginning-of-syntax) (point)))) (state (parse-partial-sexp lim pos))) (cond ((elt state 3) 'string) ((elt state 4) (if (elt state 7) 'c++ 'c)) ((and detect-cpp (c-beginning-of-macro lim)) 'pound) (t nil)))))) ;; cache this result if the cache is enabled (if (not c-in-literal-cache) (setq c-in-literal-cache (vector (point) rtn))) rtn))) ;; XEmacs has a built-in function that should make this much quicker. ;; I don't think we even need the cache, which makes our lives more ;; complicated anyway. In this case, lim is only used to detect ;; cpp directives. ;; ;; Note that there is a bug in Xemacs's buffer-syntactic-context when used in ;; conjunction with syntax-table-properties. The bug is present in, e.g., ;; Xemacs 21.4.4. It manifested itself thus: ;; ;; Starting with an empty AWK Mode buffer, type ;; /regexp/ { ;; Point gets wrongly left at column 0, rather than being indented to tab-width. ;; ;; AWK Mode is designed such that when the first / is typed, it gets the ;; syntax-table property "string fence". When the second / is typed, BOTH /s ;; are given the s-t property "string". However, buffer-syntactic-context ;; fails to take account of the change of the s-t property on the opening / to ;; "string", and reports that the { is within a string started by the second /. ;; ;; The workaround for this is for the AWK Mode initialisation to switch the ;; defalias for c-in-literal to c-slow-in-literal. This will slow down other ;; cc-modes in Xemacs whenever an awk-buffer has been initialised. ;; ;; (Alan Mackenzie, 2003/4/30). (defun c-fast-in-literal (&optional lim detect-cpp) ;; This function might do hidden buffer changes. (let ((context (buffer-syntactic-context))) (cond ((eq context 'string) 'string) ((eq context 'comment) 'c++) ((eq context 'block-comment) 'c) ((and detect-cpp (save-excursion (c-beginning-of-macro lim))) 'pound)))) (defalias 'c-in-literal (if (fboundp 'buffer-syntactic-context) 'c-fast-in-literal ; XEmacs 'c-slow-in-literal)) ; GNU Emacs ;; The defalias above isn't enough to shut up the byte compiler. (cc-bytecomp-defun c-in-literal) (defun c-literal-limits (&optional lim near not-in-delimiter) "Return a cons of the beginning and end positions of the comment or string surrounding point (including both delimiters), or nil if point isn't in one. If LIM is non-nil, it's used as the \"safe\" position to start parsing from. If NEAR is non-nil, then the limits of any literal next to point is returned. \"Next to\" means there's only spaces and tabs between point and the literal. The search for such a literal is done first in forward direction. If NOT-IN-DELIMITER is non-nil, the case when point is inside a starting delimiter won't be recognized. This only has effect for comments, which have starting delimiters with more than one character. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (save-excursion (let* ((pos (point)) (lim (or lim (progn (c-beginning-of-syntax) (point)))) (state (parse-partial-sexp lim pos))) (cond ((elt state 3) ; String. (goto-char (elt state 8)) (cons (point) (or (c-safe (c-forward-sexp 1) (point)) (point-max)))) ((elt state 4) ; Comment. (goto-char (elt state 8)) (cons (point) (progn (c-forward-single-comment) (point)))) ((and (not not-in-delimiter) (not (elt state 5)) (eq (char-before) ?/) (looking-at "[/*]")) ;; We're standing in a comment starter. (backward-char 1) (cons (point) (progn (c-forward-single-comment) (point)))) (near (goto-char pos) ;; Search forward for a literal. (skip-chars-forward " \t") (cond ((looking-at c-string-limit-regexp) ; String. (cons (point) (or (c-safe (c-forward-sexp 1) (point)) (point-max)))) ((looking-at c-comment-start-regexp) ; Line or block comment. (cons (point) (progn (c-forward-single-comment) (point)))) (t ;; Search backward. (skip-chars-backward " \t") (let ((end (point)) beg) (cond ((save-excursion (< (skip-syntax-backward c-string-syntax) 0)) ; String. (setq beg (c-safe (c-backward-sexp 1) (point)))) ((and (c-safe (forward-char -2) t) (looking-at "*/")) ;; Block comment. Due to the nature of line ;; comments, they will always be covered by the ;; normal case above. (goto-char end) (c-backward-single-comment) ;; If LIM is bogus, beg will be bogus. (setq beg (point)))) (if beg (cons beg end)))))) )))) ;; In case external callers use this; it did have a docstring. (defalias 'c-literal-limits-fast 'c-literal-limits) (defun c-collect-line-comments (range) "If the argument is a cons of two buffer positions (such as returned by `c-literal-limits'), and that range contains a C++ style line comment, then an extended range is returned that contains all adjacent line comments (i.e. all comments that starts in the same column with no empty lines or non-whitespace characters between them). Otherwise the argument is returned. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (save-excursion (condition-case nil (if (and (consp range) (progn (goto-char (car range)) (looking-at c-line-comment-starter))) (let ((col (current-column)) (beg (point)) (bopl (c-point 'bopl)) (end (cdr range))) ;; Got to take care in the backward direction to handle ;; comments which are preceded by code. (while (and (c-backward-single-comment) (>= (point) bopl) (looking-at c-line-comment-starter) (= col (current-column))) (setq beg (point) bopl (c-point 'bopl))) (goto-char end) (while (and (progn (skip-chars-forward " \t") (looking-at c-line-comment-starter)) (= col (current-column)) (prog1 (zerop (forward-line 1)) (setq end (point))))) (cons beg end)) range) (error range)))) (defun c-literal-type (range) "Convenience function that given the result of `c-literal-limits', returns nil or the type of literal that the range surrounds. It's much faster than using `c-in-literal' and is intended to be used when you need both the type of a literal and its limits. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (if (consp range) (save-excursion (goto-char (car range)) (cond ((looking-at c-string-limit-regexp) 'string) ((or (looking-at "//") ; c++ line comment (and (looking-at "\\s<") ; comment starter (looking-at "#"))) ; awk comment. 'c++) (t 'c))) ; Assuming the range is valid. range)) ;; `c-find-decl-spots' and accompanying stuff. ;; Variables used in `c-find-decl-spots' to cache the search done for ;; the first declaration in the last call. When that function starts, ;; it needs to back up over syntactic whitespace to look at the last ;; token before the region being searched. That can sometimes cause ;; moves back and forth over a quite large region of comments and ;; macros, which would be repeated for each changed character when ;; we're called during fontification, since font-lock refontifies the ;; current line for each change. Thus it's worthwhile to cache the ;; first match. ;; ;; `c-find-decl-syntactic-pos' is a syntactically relevant position in ;; the syntactic whitespace less or equal to some start position. ;; There's no cached value if it's nil. ;; ;; `c-find-decl-match-pos' is the match position if ;; `c-find-decl-prefix-search' matched before the syntactic whitespace ;; at `c-find-decl-syntactic-pos', or nil if there's no such match. (defvar c-find-decl-syntactic-pos nil) (make-variable-buffer-local 'c-find-decl-syntactic-pos) (defvar c-find-decl-match-pos nil) (make-variable-buffer-local 'c-find-decl-match-pos) (defsubst c-invalidate-find-decl-cache (change-min-pos) (and c-find-decl-syntactic-pos (< change-min-pos c-find-decl-syntactic-pos) (setq c-find-decl-syntactic-pos nil))) ; (defface c-debug-decl-spot-face ; '((t (:background "Turquoise"))) ; "Debug face to mark the spots where `c-find-decl-spots' stopped.") ; (defface c-debug-decl-sws-face ; '((t (:background "Khaki"))) ; "Debug face to mark the syntactic whitespace between the declaration ; spots and the preceding token end.") (defmacro c-debug-put-decl-spot-faces (match-pos decl-pos) (when (facep 'c-debug-decl-spot-face) `(c-save-buffer-state ((match-pos ,match-pos) (decl-pos ,decl-pos)) (c-debug-add-face (max match-pos (point-min)) decl-pos 'c-debug-decl-sws-face) (c-debug-add-face decl-pos (min (1+ decl-pos) (point-max)) 'c-debug-decl-spot-face)))) (defmacro c-debug-remove-decl-spot-faces (beg end) (when (facep 'c-debug-decl-spot-face) `(c-save-buffer-state () (c-debug-remove-face ,beg ,end 'c-debug-decl-spot-face) (c-debug-remove-face ,beg ,end 'c-debug-decl-sws-face)))) (defmacro c-find-decl-prefix-search () ;; Macro used inside `c-find-decl-spots'. It ought to be a defun, ;; but it contains lots of free variables that refer to things ;; inside `c-find-decl-spots'. The point is left at `cfd-match-pos' ;; if there is a match, otherwise at `cfd-limit'. ;; ;; This macro might do hidden buffer changes. '(progn ;; Find the next property match position if we haven't got one already. (unless cfd-prop-match (save-excursion (while (progn (goto-char (next-single-property-change (point) 'c-type nil cfd-limit)) (and (< (point) cfd-limit) (not (eq (c-get-char-property (1- (point)) 'c-type) 'c-decl-end))))) (setq cfd-prop-match (point)))) ;; Find the next `c-decl-prefix-or-start-re' match if we haven't ;; got one already. (unless cfd-re-match (if (> cfd-re-match-end (point)) (goto-char cfd-re-match-end)) (while (if (setq cfd-re-match-end (re-search-forward c-decl-prefix-or-start-re cfd-limit 'move)) ;; Match. Check if it's inside a comment or string literal. (c-got-face-at (if (setq cfd-re-match (match-end 1)) ;; Matched the end of a token preceding a decl spot. (progn (goto-char cfd-re-match) (1- cfd-re-match)) ;; Matched a token that start a decl spot. (goto-char (match-beginning 0)) (point)) c-literal-faces) ;; No match. Finish up and exit the loop. (setq cfd-re-match cfd-limit) nil) ;; Skip out of comments and string literals. (while (progn (goto-char (next-single-property-change (point) 'face nil cfd-limit)) (and (< (point) cfd-limit) (c-got-face-at (point) c-literal-faces))))) ;; If we matched at the decl start, we have to back up over the ;; preceding syntactic ws to set `cfd-match-pos' and to catch ;; any decl spots in the syntactic ws. (unless cfd-re-match (c-backward-syntactic-ws) (setq cfd-re-match (point)))) ;; Choose whichever match is closer to the start. (if (< cfd-re-match cfd-prop-match) (setq cfd-match-pos cfd-re-match cfd-re-match nil) (setq cfd-match-pos cfd-prop-match cfd-prop-match nil)) (goto-char cfd-match-pos) (when (< cfd-match-pos cfd-limit) ;; Skip forward past comments only so we don't skip macros. (c-forward-comments) ;; Set the position to continue at. We can avoid going over ;; the comments skipped above a second time, but it's possible ;; that the comment skipping has taken us past `cfd-prop-match' ;; since the property might be used inside comments. (setq cfd-continue-pos (if cfd-prop-match (min cfd-prop-match (point)) (point)))))) (defun c-find-decl-spots (cfd-limit cfd-decl-re cfd-face-checklist cfd-fun) ;; Call CFD-FUN for each possible spot for a declaration, cast or ;; label from the point to CFD-LIMIT. Such a spot is: ;; ;; o The first token after bob. ;; o The first token after the end of submatch 1 in ;; `c-decl-prefix-or-start-re' when that submatch matches. ;; o The start of each `c-decl-prefix-or-start-re' match when ;; submatch 1 doesn't match. ;; o The first token after the end of each occurence of the ;; `c-type' text property with the value `c-decl-end', provided ;; `c-type-decl-end-used' is set. ;; ;; Only a spot that match CFD-DECL-RE and whose face is in the ;; CFD-FACE-CHECKLIST list causes CFD-FUN to be called. The face ;; check is disabled if CFD-FACE-CHECKLIST is nil. ;; ;; If the match is inside a macro then the buffer is narrowed to the ;; end of it, so that CFD-FUN can investigate the following tokens ;; without matching something that begins inside a macro and ends ;; outside it. It's to avoid this work that the CFD-DECL-RE and ;; CFD-FACE-CHECKLIST checks exist. ;; ;; CFD-FUN is called with point at the start of the spot. It's ;; passed two arguments: The first is the end position of the token ;; preceding the spot, or 0 for the implicit match at bob. The ;; second is a flag that is t when the match is inside a macro. If ;; CFD-FUN adds `c-decl-end' properties somewhere below the current ;; spot, it should return non-nil to ensure that the next search ;; will find them. ;; ;; The spots are visited approximately in order from top to bottom. ;; It's however the positions where `c-decl-prefix-or-start-re' ;; matches and where `c-decl-end' properties are found that are in ;; order. Since the spots often are at the following token, they ;; might be visited out of order insofar as more spots are reported ;; later on within the syntactic whitespace between the match ;; positions and their spots. ;; ;; It's assumed that comments and strings are fontified in the ;; searched range. ;; ;; This is mainly used in fontification, and so has an elaborate ;; cache to handle repeated calls from the same start position; see ;; the variables above. ;; ;; All variables in this function begin with `cfd-' to avoid name ;; collision with the (dynamically bound) variables used in CFD-FUN. ;; ;; This function might do hidden buffer changes. (let ((cfd-start-pos (point)) (cfd-buffer-end (point-max)) ;; The end of the token preceding the decl spot last found ;; with `c-decl-prefix-or-start-re'. `cfd-limit' if there's ;; no match. cfd-re-match ;; The end position of the last `c-decl-prefix-or-start-re' ;; match. If this is greater than `cfd-continue-pos', the ;; next regexp search is started here instead. (cfd-re-match-end (point-min)) ;; The end of the last `c-decl-end' found by ;; `c-find-decl-prefix-search'. `cfd-limit' if there's no ;; match. If searching for the property isn't needed then we ;; disable it by setting it to `cfd-limit' directly. (cfd-prop-match (unless c-type-decl-end-used cfd-limit)) ;; The end of the token preceding the decl spot last found by ;; `c-find-decl-prefix-search'. 0 for the implicit match at ;; bob. `cfd-limit' if there's no match. In other words, ;; this is the minimum of `cfd-re-match' and `cfd-prop-match'. (cfd-match-pos cfd-limit) ;; The position to continue searching at. cfd-continue-pos ;; The position of the last "real" token we've stopped at. ;; This can be greater than `cfd-continue-pos' when we get ;; hits inside macros or at `c-decl-end' positions inside ;; comments. (cfd-token-pos 0) ;; The end position of the last entered macro. (cfd-macro-end 0)) ;; Initialize by finding a syntactically relevant start position ;; before the point, and do the first `c-decl-prefix-or-start-re' ;; search unless we're at bob. (let (start-in-literal start-in-macro syntactic-pos) ;; Must back up a bit since we look for the end of the previous ;; statement or declaration, which is earlier than the first ;; returned match. (cond ;; First we need to move to a syntactically relevant position. ;; Begin by backing out of comment or string literals. ((and (when (c-got-face-at (point) c-literal-faces) ;; Try to use the faces to back up to the start of the ;; literal. FIXME: What if the point is on a declaration ;; inside a comment? (while (and (not (bobp)) (c-got-face-at (1- (point)) c-literal-faces)) (goto-char (previous-single-property-change (point) 'face nil (point-min)))) ;; XEmacs doesn't fontify the quotes surrounding string ;; literals. (and (featurep 'xemacs) (eq (get-text-property (point) 'face) 'font-lock-string-face) (not (bobp)) (progn (backward-char) (not (looking-at c-string-limit-regexp))) (forward-char)) ;; Don't trust the literal to contain only literal faces ;; (the font lock package might not have fontified the ;; start of it at all, for instance) so check that we have ;; arrived at something that looks like a start or else ;; resort to `c-literal-limits'. (unless (looking-at c-literal-start-regexp) (let ((range (c-literal-limits))) (if range (goto-char (car range))))) (setq start-in-literal (point))) ;; The start is in a literal. If the limit is in the same ;; one we don't have to find a syntactic position etc. We ;; only check that if the limit is at or before bonl to save ;; time; it covers the by far most common case when font-lock ;; refontifies the current line only. (<= cfd-limit (c-point 'bonl cfd-start-pos)) (save-excursion (goto-char cfd-start-pos) (while (progn (goto-char (next-single-property-change (point) 'face nil cfd-limit)) (and (< (point) cfd-limit) (c-got-face-at (point) c-literal-faces)))) (= (point) cfd-limit))) ;; Completely inside a literal. Set up variables to trig the ;; (< cfd-continue-pos cfd-start-pos) case below and it'll ;; find a suitable start position. (setq cfd-continue-pos start-in-literal)) ;; Check if the region might be completely inside a macro, to ;; optimize that like the completely-inside-literal above. ((save-excursion (and (= (forward-line 1) 0) (bolp) ; forward-line has funny behavior at eob. (>= (point) cfd-limit) (progn (backward-char) (eq (char-before) ?\\)))) ;; (Maybe) completely inside a macro. Only need to trig the ;; (< cfd-continue-pos cfd-start-pos) case below to make it ;; set things up. (setq cfd-continue-pos (1- cfd-start-pos) start-in-macro t)) (t ;; Back out of any macro so we don't miss any declaration ;; that could follow after it. (when (c-beginning-of-macro) (setq start-in-macro t)) ;; Now we're at a proper syntactically relevant position so we ;; can use the cache. But first clear it if it applied ;; further down. (c-invalidate-find-decl-cache cfd-start-pos) (setq syntactic-pos (point)) (unless (eq syntactic-pos c-find-decl-syntactic-pos) ;; Don't have to do this if the cache is relevant here, ;; typically if the same line is refontified again. If ;; we're just some syntactic whitespace further down we can ;; still use the cache to limit the skipping. (c-backward-syntactic-ws c-find-decl-syntactic-pos)) ;; If we hit `c-find-decl-syntactic-pos' and ;; `c-find-decl-match-pos' is set then we install the cached ;; values. If we hit `c-find-decl-syntactic-pos' and ;; `c-find-decl-match-pos' is nil then we know there's no decl ;; prefix in the whitespace before `c-find-decl-syntactic-pos' ;; and so we can continue the search from this point. If we ;; didn't hit `c-find-decl-syntactic-pos' then we're now in ;; the right spot to begin searching anyway. (if (and (eq (point) c-find-decl-syntactic-pos) c-find-decl-match-pos) (setq cfd-match-pos c-find-decl-match-pos cfd-continue-pos syntactic-pos) (setq c-find-decl-syntactic-pos syntactic-pos) (when (if (bobp) ;; Always consider bob a match to get the first ;; declaration in the file. Do this separately instead of ;; letting `c-decl-prefix-or-start-re' match bob, so that ;; regexp always can consume at least one character to ;; ensure that we won't get stuck in an infinite loop. (setq cfd-re-match 0) (backward-char) (c-beginning-of-current-token) (< (point) cfd-limit)) ;; Do an initial search now. In the bob case above it's ;; only done to search for a `c-decl-end' spot. (c-find-decl-prefix-search)) (setq c-find-decl-match-pos (and (< cfd-match-pos cfd-start-pos) cfd-match-pos))))) ;; Advance `cfd-continue-pos' if it's before the start position. ;; The closest continue position that might have effect at or ;; after the start depends on what we started in. This also ;; finds a suitable start position in the special cases when the ;; region is completely within a literal or macro. (when (and cfd-continue-pos (< cfd-continue-pos cfd-start-pos)) (cond (start-in-macro ;; If we're in a macro then it's the closest preceding token ;; in the macro. Check this before `start-in-literal', ;; since if we're inside a literal in a macro, the preceding ;; token is earlier than any `c-decl-end' spot inside the ;; literal (comment). (goto-char (or start-in-literal cfd-start-pos)) ;; The only syntactic ws in macros are comments. (c-backward-comments) (backward-char) (c-beginning-of-current-token)) (start-in-literal ;; If we're in a comment it can only be the closest ;; preceding `c-decl-end' position within that comment, if ;; any. Go back to the beginning of such a property so that ;; `c-find-decl-prefix-search' will find the end of it. ;; (Can't stop at the end and install it directly on ;; `cfd-prop-match' since that variable might be cleared ;; after `cfd-fun' below.) ;; ;; Note that if the literal is a string then the property ;; search will simply skip to the beginning of it right ;; away. (if (not c-type-decl-end-used) (goto-char start-in-literal) (goto-char cfd-start-pos) (while (progn (goto-char (previous-single-property-change (point) 'c-type nil start-in-literal)) (and (> (point) start-in-literal) (not (eq (c-get-char-property (point) 'c-type) 'c-decl-end)))))) (when (= (point) start-in-literal) ;; Didn't find any property inside the comment, so we can ;; skip it entirely. (This won't skip past a string, but ;; that'll be handled quickly by the next ;; `c-find-decl-prefix-search' anyway.) (c-forward-single-comment) (if (> (point) cfd-limit) (goto-char cfd-limit)))) (t ;; If we started in normal code, the only match that might ;; apply before the start is what we already got in ;; `cfd-match-pos' so we can continue at the start position. ;; (Note that we don't get here if the first match is below ;; it.) (goto-char cfd-start-pos))) ;; Delete found matches if they are before our new continue ;; position, so that `c-find-decl-prefix-search' won't back up ;; to them later on. (setq cfd-continue-pos (point)) (when (and cfd-re-match (< cfd-re-match cfd-continue-pos)) (setq cfd-re-match nil)) (when (and cfd-prop-match (< cfd-prop-match cfd-continue-pos)) (setq cfd-prop-match nil))) (if syntactic-pos ;; This is the normal case and we got a proper syntactic ;; position. If there's a match then it's always outside ;; macros and comments, so advance to the next token and set ;; `cfd-token-pos'. The loop below will later go back using ;; `cfd-continue-pos' to fix declarations inside the ;; syntactic ws. (when (and cfd-match-pos (< cfd-match-pos syntactic-pos)) (goto-char syntactic-pos) (c-forward-syntactic-ws) (and cfd-continue-pos (< cfd-continue-pos (point)) (setq cfd-token-pos (point)))) ;; Have one of the special cases when the region is completely ;; within a literal or macro. `cfd-continue-pos' is set to a ;; good start position for the search, so do it. (c-find-decl-prefix-search))) ;; Now loop. Round what? (ACM, 2006/7/5). We already got the first match. (while (progn (while (and (< cfd-match-pos cfd-limit) (or ;; Kludge to filter out matches on the "<" that ;; aren't open parens, for the sake of languages ;; that got `c-recognize-<>-arglists' set. (and (eq (char-before cfd-match-pos) ?<) (not (c-get-char-property (1- cfd-match-pos) 'syntax-table))) ;; If `cfd-continue-pos' is less or equal to ;; `cfd-token-pos', we've got a hit inside a macro ;; that's in the syntactic whitespace before the last ;; "real" declaration we've checked. If they're equal ;; we've arrived at the declaration a second time, so ;; there's nothing to do. (= cfd-continue-pos cfd-token-pos) (progn ;; If `cfd-continue-pos' is less than `cfd-token-pos' ;; we're still searching for declarations embedded in ;; the syntactic whitespace. In that case we need ;; only to skip comments and not macros, since they ;; can't be nested, and that's already been done in ;; `c-find-decl-prefix-search'. (when (> cfd-continue-pos cfd-token-pos) (c-forward-syntactic-ws) (setq cfd-token-pos (point))) ;; Continue if the following token fails the ;; CFD-DECL-RE and CFD-FACE-CHECKLIST checks. (when (or (>= (point) cfd-limit) (not (looking-at cfd-decl-re)) (and cfd-face-checklist (not (c-got-face-at (point) cfd-face-checklist)))) (goto-char cfd-continue-pos) t))) (< (point) cfd-limit)) (c-find-decl-prefix-search)) (< (point) cfd-limit)) (when (and (>= (point) cfd-start-pos) (progn ;; Narrow to the end of the macro if we got a hit inside ;; one, to avoid recognizing things that start inside the ;; macro and end outside it. (when (> cfd-match-pos cfd-macro-end) ;; Not in the same macro as in the previous round. (save-excursion (goto-char cfd-match-pos) (setq cfd-macro-end (if (save-excursion (and (c-beginning-of-macro) (< (point) cfd-match-pos))) (progn (c-end-of-macro) (point)) 0)))) (if (zerop cfd-macro-end) t (if (> cfd-macro-end (point)) (progn (narrow-to-region (point-min) cfd-macro-end) t) ;; The matched token was the last thing in the macro, ;; so the whole match is bogus. (setq cfd-macro-end 0) nil)))) (c-debug-put-decl-spot-faces cfd-match-pos (point)) (if (funcall cfd-fun cfd-match-pos (/= cfd-macro-end 0)) (setq cfd-prop-match nil)) (when (/= cfd-macro-end 0) ;; Restore limits if we did macro narrowment above. (narrow-to-region (point-min) cfd-buffer-end))) (goto-char cfd-continue-pos) (if (= cfd-continue-pos cfd-limit) (setq cfd-match-pos cfd-limit) (c-find-decl-prefix-search))))) ;; A cache for found types. ;; Buffer local variable that contains an obarray with the types we've ;; found. If a declaration is recognized somewhere we record the ;; fully qualified identifier in it to recognize it as a type ;; elsewhere in the file too. This is not accurate since we do not ;; bother with the scoping rules of the languages, but in practice the ;; same name is seldom used as both a type and something else in a ;; file, and we only use this as a last resort in ambiguous cases (see ;; `c-forward-decl-or-cast-1'). ;; ;; Not every type need be in this cache. However, things which have ;; ceased to be types must be removed from it. ;; ;; Template types in C++ are added here too but with the template ;; arglist replaced with "<>" in references or "<" for the one in the ;; primary type. E.g. the type "Foo::Bar" is stored as ;; "Foo<>::Bar<". This avoids storing very long strings (since C++ ;; template specs can be fairly sized programs in themselves) and ;; improves the hit ratio (it's a type regardless of the template ;; args; it's just not the same type, but we're only interested in ;; recognizing types, not telling distinct types apart). Note that ;; template types in references are added here too; from the example ;; above there will also be an entry "Foo<". (defvar c-found-types nil) (make-variable-buffer-local 'c-found-types) (defsubst c-clear-found-types () ;; Clears `c-found-types'. (setq c-found-types (make-vector 53 0))) (defun c-add-type (from to) ;; Add the given region as a type in `c-found-types'. If the region ;; doesn't match an existing type but there is a type which is equal ;; to the given one except that the last character is missing, then ;; the shorter type is removed. That's done to avoid adding all ;; prefixes of a type as it's being entered and font locked. This ;; doesn't cover cases like when characters are removed from a type ;; or added in the middle. We'd need the position of point when the ;; font locking is invoked to solve this well. ;; ;; This function might do hidden buffer changes. (let ((type (c-syntactic-content from to c-recognize-<>-arglists))) (unless (intern-soft type c-found-types) (unintern (substring type 0 -1) c-found-types) (intern type c-found-types)))) (defun c-unfind-type (name) ;; Remove the "NAME" from c-found-types, if present. (unintern name c-found-types)) (defsubst c-check-type (from to) ;; Return non-nil if the given region contains a type in ;; `c-found-types'. ;; ;; This function might do hidden buffer changes. (intern-soft (c-syntactic-content from to c-recognize-<>-arglists) c-found-types)) (defun c-list-found-types () ;; Return all the types in `c-found-types' as a sorted list of ;; strings. (let (type-list) (mapatoms (lambda (type) (setq type-list (cons (symbol-name type) type-list))) c-found-types) (sort type-list 'string-lessp))) (defun c-trim-found-types (beg end old-len) ;; An after change function which, in conjunction with the info in ;; c-maybe-stale-found-type (set in c-before-change), removes a type ;; from `c-found-types', should this type have become stale. For ;; example, this happens to "foo" when "foo \n bar();" becomes ;; "foo(); \n bar();". Such stale types, if not removed, foul up ;; the fontification. ;; ;; Have we, perhaps, added non-ws characters to the front/back of a found ;; type? (when (> end beg) (save-excursion (when (< end (point-max)) (goto-char end) (if (and (c-beginning-of-current-token) ; only moves when we started in the middle (progn (goto-char end) (c-end-of-current-token))) (c-unfind-type (buffer-substring-no-properties end (point))))) (when (> beg (point-min)) (goto-char beg) (if (and (c-end-of-current-token) ; only moves when we started in the middle (progn (goto-char beg) (c-beginning-of-current-token))) (c-unfind-type (buffer-substring-no-properties (point) beg)))))) (if c-maybe-stale-found-type ; e.g. (c-decl-id-start "foo" 97 107 " (* ooka) " "o") (cond ;; Changing the amount of (already existing) whitespace - don't do anything. ((and (c-partial-ws-p beg end) (or (= beg end) ; removal of WS ; (string-match "\\s *\\'" (nth 5 c-maybe-stale-found-type)) (string-match "^[ \t\n\r\f\v]*$" (nth 5 c-maybe-stale-found-type))))) ;; The syntactic relationship which defined a "found type" has been ;; destroyed. ((eq (car c-maybe-stale-found-type) 'c-decl-id-start) (c-unfind-type (cadr c-maybe-stale-found-type))) ;; ((eq (car c-maybe-stale-found-type) 'c-decl-type-start) FIXME!!! ))) ;; Handling of small scale constructs like types and names. (defun c-after-change-check-<>-operators (beg end) ;; This is called from `after-change-functions' when ;; c-recognize-<>-arglists' is set. It ensures that no "<" or ">" ;; chars with paren syntax become part of another operator like "<<" ;; or ">=". ;; ;; This function might do hidden buffer changes. (save-excursion (goto-char beg) (when (or (looking-at "[<>]") (< (skip-chars-backward "<>") 0)) (goto-char beg) (c-beginning-of-current-token) (when (and (< (point) beg) (looking-at c-<>-multichar-token-regexp) (< beg (setq beg (match-end 0)))) (while (progn (skip-chars-forward "^<>" beg) (< (point) beg)) (c-clear-char-property (point) 'syntax-table) (forward-char)))) (when (< beg end) (goto-char end) (when (or (looking-at "[<>]") (< (skip-chars-backward "<>") 0)) (goto-char end) (c-beginning-of-current-token) (when (and (< (point) end) (looking-at c-<>-multichar-token-regexp) (< end (setq end (match-end 0)))) (while (progn (skip-chars-forward "^<>" end) (< (point) end)) (c-clear-char-property (point) 'syntax-table) (forward-char))))))) ;; Dynamically bound variable that instructs `c-forward-type' to also ;; treat possible types (i.e. those that it normally returns 'maybe or ;; 'found for) as actual types (and always return 'found for them). ;; This means that it records them in `c-record-type-identifiers' if ;; that is set, and that it adds them to `c-found-types'. (defvar c-promote-possible-types nil) ;; Dynamically bound variable that instructs `c-forward-<>-arglist' to ;; mark up successfully parsed arglists with paren syntax properties on ;; the surrounding angle brackets and with `c-<>-arg-sep' in the ;; `c-type' property of each argument separating comma. ;; ;; Setting this variable also makes `c-forward-<>-arglist' recurse into ;; all arglists for side effects (i.e. recording types), otherwise it ;; exploits any existing paren syntax properties to quickly jump to the ;; end of already parsed arglists. ;; ;; Marking up the arglists is not the default since doing that correctly ;; depends on a proper value for `c-restricted-<>-arglists'. (defvar c-parse-and-markup-<>-arglists nil) ;; Dynamically bound variable that instructs `c-forward-<>-arglist' to ;; not accept arglists that contain binary operators. ;; ;; This is primarily used to handle C++ template arglists. C++ ;; disambiguates them by checking whether the preceding name is a ;; template or not. We can't do that, so we assume it is a template ;; if it can be parsed as one. That usually works well since ;; comparison expressions on the forms "a < b > c" or "a < b, c > d" ;; in almost all cases would be pointless. ;; ;; However, in function arglists, e.g. in "foo (a < b, c > d)", we ;; should let the comma separate the function arguments instead. And ;; in a context where the value of the expression is taken, e.g. in ;; "if (a < b || c > d)", it's probably not a template. (defvar c-restricted-<>-arglists nil) ;; Dynamically bound variables that instructs ;; `c-forward-keyword-clause', `c-forward-<>-arglist', ;; `c-forward-name', `c-forward-type', `c-forward-decl-or-cast-1', and ;; `c-forward-label' to record the ranges of all the type and ;; reference identifiers they encounter. They will build lists on ;; these variables where each element is a cons of the buffer ;; positions surrounding each identifier. This recording is only ;; activated when `c-record-type-identifiers' is non-nil. ;; ;; All known types that can't be identifiers are recorded, and also ;; other possible types if `c-promote-possible-types' is set. ;; Recording is however disabled inside angle bracket arglists that ;; are encountered inside names and other angle bracket arglists. ;; Such occurrences are taken care of by `c-font-lock-<>-arglists' ;; instead. ;; ;; Only the names in C++ template style references (e.g. "tmpl" in ;; "tmpl::foo") are recorded as references, other references ;; aren't handled here. ;; ;; `c-forward-label' records the label identifier(s) on ;; `c-record-ref-identifiers'. (defvar c-record-type-identifiers nil) (defvar c-record-ref-identifiers nil) ;; This variable will receive a cons cell of the range of the last ;; single identifier symbol stepped over by `c-forward-name' if it's ;; successful. This is the range that should be put on one of the ;; record lists above by the caller. It's assigned nil if there's no ;; such symbol in the name. (defvar c-last-identifier-range nil) (defmacro c-record-type-id (range) (if (eq (car-safe range) 'cons) ;; Always true. `(setq c-record-type-identifiers (cons ,range c-record-type-identifiers)) `(let ((range ,range)) (if range (setq c-record-type-identifiers (cons range c-record-type-identifiers)))))) (defmacro c-record-ref-id (range) (if (eq (car-safe range) 'cons) ;; Always true. `(setq c-record-ref-identifiers (cons ,range c-record-ref-identifiers)) `(let ((range ,range)) (if range (setq c-record-ref-identifiers (cons range c-record-ref-identifiers)))))) ;; Dynamically bound variable that instructs `c-forward-type' to ;; record the ranges of types that only are found. Behaves otherwise ;; like `c-record-type-identifiers'. (defvar c-record-found-types nil) (defmacro c-forward-keyword-prefixed-id (type) ;; Used internally in `c-forward-keyword-clause' to move forward ;; over a type (if TYPE is 'type) or a name (otherwise) which ;; possibly is prefixed by keywords and their associated clauses. ;; Try with a type/name first to not trip up on those that begin ;; with a keyword. Return t if a known or found type is moved ;; over. The point is clobbered if nil is returned. If range ;; recording is enabled, the identifier is recorded on as a type ;; if TYPE is 'type or as a reference if TYPE is 'ref. ;; ;; This macro might do hidden buffer changes. `(let (res) (while (if (setq res ,(if (eq type 'type) `(c-forward-type) `(c-forward-name))) nil (and (looking-at c-keywords-regexp) (c-forward-keyword-clause 1)))) (when (memq res '(t known found prefix)) ,(when (eq type 'ref) `(when c-record-type-identifiers (c-record-ref-id c-last-identifier-range))) t))) (defmacro c-forward-id-comma-list (type update-safe-pos) ;; Used internally in `c-forward-keyword-clause' to move forward ;; over a comma separated list of types or names using ;; `c-forward-keyword-prefixed-id'. ;; ;; This macro might do hidden buffer changes. `(while (and (progn ,(when update-safe-pos `(setq safe-pos (point))) (eq (char-after) ?,)) (progn (forward-char) (c-forward-syntactic-ws) (c-forward-keyword-prefixed-id ,type))))) (defun c-forward-keyword-clause (match) ;; Submatch MATCH in the current match data is assumed to surround a ;; token. If it's a keyword, move over it and any immediately ;; following clauses associated with it, stopping at the start of ;; the next token. t is returned in that case, otherwise the point ;; stays and nil is returned. The kind of clauses that are ;; recognized are those specified by `c-type-list-kwds', ;; `c-ref-list-kwds', `c-colon-type-list-kwds', ;; `c-paren-nontype-kwds', `c-paren-type-kwds', `c-<>-type-kwds', ;; and `c-<>-arglist-kwds'. ;; ;; This function records identifier ranges on ;; `c-record-type-identifiers' and `c-record-ref-identifiers' if ;; `c-record-type-identifiers' is non-nil. ;; ;; Note that for `c-colon-type-list-kwds', which doesn't necessary ;; apply directly after the keyword, the type list is moved over ;; only when there is no unaccounted token before it (i.e. a token ;; that isn't moved over due to some other keyword list). The ;; identifier ranges in the list are still recorded if that should ;; be done, though. ;; ;; This function might do hidden buffer changes. (let ((kwd-sym (c-keyword-sym (match-string match))) safe-pos pos ;; The call to `c-forward-<>-arglist' below is made after ;; `c-<>-sexp-kwds' keywords, so we're certain they actually ;; are angle bracket arglists and `c-restricted-<>-arglists' ;; should therefore be nil. (c-parse-and-markup-<>-arglists t) c-restricted-<>-arglists) (when kwd-sym (goto-char (match-end match)) (c-forward-syntactic-ws) (setq safe-pos (point)) (cond ((and (c-keyword-member kwd-sym 'c-type-list-kwds) (c-forward-keyword-prefixed-id type)) ;; There's a type directly after a keyword in `c-type-list-kwds'. (c-forward-id-comma-list type t)) ((and (c-keyword-member kwd-sym 'c-ref-list-kwds) (c-forward-keyword-prefixed-id ref)) ;; There's a name directly after a keyword in `c-ref-list-kwds'. (c-forward-id-comma-list ref t)) ((and (c-keyword-member kwd-sym 'c-paren-any-kwds) (eq (char-after) ?\()) ;; There's an open paren after a keyword in `c-paren-any-kwds'. (forward-char) (when (and (setq pos (c-up-list-forward)) (eq (char-before pos) ?\))) (when (and c-record-type-identifiers (c-keyword-member kwd-sym 'c-paren-type-kwds)) ;; Use `c-forward-type' on every identifier we can find ;; inside the paren, to record the types. (while (c-syntactic-re-search-forward c-symbol-start pos t) (goto-char (match-beginning 0)) (unless (c-forward-type) (looking-at c-symbol-key) ; Always matches. (goto-char (match-end 0))))) (goto-char pos) (c-forward-syntactic-ws) (setq safe-pos (point)))) ((and (c-keyword-member kwd-sym 'c-<>-sexp-kwds) (eq (char-after) ?<) (c-forward-<>-arglist (c-keyword-member kwd-sym 'c-<>-type-kwds))) (c-forward-syntactic-ws) (setq safe-pos (point))) ((and (c-keyword-member kwd-sym 'c-nonsymbol-sexp-kwds) (not (looking-at c-symbol-start)) (c-safe (c-forward-sexp) t)) (c-forward-syntactic-ws) (setq safe-pos (point)))) (when (c-keyword-member kwd-sym 'c-colon-type-list-kwds) (if (eq (char-after) ?:) ;; If we are at the colon already, we move over the type ;; list after it. (progn (forward-char) (c-forward-syntactic-ws) (when (c-forward-keyword-prefixed-id type) (c-forward-id-comma-list type t))) ;; Not at the colon, so stop here. But the identifier ;; ranges in the type list later on should still be ;; recorded. (and c-record-type-identifiers (progn ;; If a keyword matched both one of the types above and ;; this one, we match `c-colon-type-list-re' after the ;; clause matched above. (goto-char safe-pos) (looking-at c-colon-type-list-re)) (progn (goto-char (match-end 0)) (c-forward-syntactic-ws) (c-forward-keyword-prefixed-id type)) ;; There's a type after the `c-colon-type-list-re' match ;; after a keyword in `c-colon-type-list-kwds'. (c-forward-id-comma-list type nil)))) (goto-char safe-pos) t))) (defun c-forward-<>-arglist (all-types) ;; The point is assumed to be at a "<". Try to treat it as the open ;; paren of an angle bracket arglist and move forward to the the ;; corresponding ">". If successful, the point is left after the ;; ">" and t is returned, otherwise the point isn't moved and nil is ;; returned. If ALL-TYPES is t then all encountered arguments in ;; the arglist that might be types are treated as found types. ;; ;; The variable `c-parse-and-markup-<>-arglists' controls how this ;; function handles text properties on the angle brackets and argument ;; separating commas. ;; ;; `c-restricted-<>-arglists' controls how lenient the template ;; arglist recognition should be. ;; ;; This function records identifier ranges on ;; `c-record-type-identifiers' and `c-record-ref-identifiers' if ;; `c-record-type-identifiers' is non-nil. ;; ;; This function might do hidden buffer changes. (let ((start (point)) ;; If `c-record-type-identifiers' is set then activate ;; recording of any found types that constitute an argument in ;; the arglist. (c-record-found-types (if c-record-type-identifiers t))) (if (catch 'angle-bracket-arglist-escape (setq c-record-found-types (c-forward-<>-arglist-recur all-types))) (progn (when (consp c-record-found-types) (setq c-record-type-identifiers ;; `nconc' doesn't mind that the tail of ;; `c-record-found-types' is t. (nconc c-record-found-types c-record-type-identifiers))) t) (goto-char start) nil))) (defun c-forward-<>-arglist-recur (all-types) ;; Recursive part of `c-forward-<>-arglist'. ;; ;; This function might do hidden buffer changes. (let ((start (point)) res pos tmp ;; Cover this so that any recorded found type ranges are ;; automatically lost if it turns out to not be an angle ;; bracket arglist. It's propagated through the return value ;; on successful completion. (c-record-found-types c-record-found-types) ;; List that collects the positions after the argument ;; separating ',' in the arglist. arg-start-pos) ;; If the '<' has paren open syntax then we've marked it as an angle ;; bracket arglist before, so skip to the end. (if (and (not c-parse-and-markup-<>-arglists) (c-get-char-property (point) 'syntax-table)) (progn (forward-char) (if (and (c-go-up-list-forward) (eq (char-before) ?>)) t ;; Got unmatched paren angle brackets. We don't clear the paren ;; syntax properties and retry, on the basis that it's very ;; unlikely that paren angle brackets become operators by code ;; manipulation. It's far more likely that it doesn't match due ;; to narrowing or some temporary change. (goto-char start) nil)) (forward-char) (unless (looking-at c-<-op-cont-regexp) (while (and (progn (when c-record-type-identifiers (if all-types ;; All encountered identifiers are types, so set the ;; promote flag and parse the type. (progn (c-forward-syntactic-ws) (when (looking-at c-identifier-start) (let ((c-promote-possible-types t)) (c-forward-type)))) ;; Check if this arglist argument is a sole type. If ;; it's known then it's recorded in ;; `c-record-type-identifiers'. If it only is found ;; then it's recorded in `c-record-found-types' which we ;; might roll back if it turns out that this isn't an ;; angle bracket arglist afterall. (when (memq (char-before) '(?, ?<)) (let ((orig-record-found-types c-record-found-types)) (c-forward-syntactic-ws) (and (memq (c-forward-type) '(known found)) (not (looking-at "[,>]")) ;; A found type was recorded but it's not the ;; only thing in the arglist argument, so reset ;; `c-record-found-types'. (setq c-record-found-types orig-record-found-types)))))) (setq pos (point)) (or (when (eq (char-after) ?>) ;; Must check for '>' at the very start separately, ;; since the regexp below has to avoid ">>" without ;; using \\=. (forward-char) t) ;; Note: These regexps exploit the match order in \| so ;; that "<>" is matched by "<" rather than "[^>:-]>". (c-syntactic-re-search-forward (if c-restricted-<>-arglists ;; Stop on ',', '|', '&', '+' and '-' to catch ;; common binary operators that could be between ;; two comparison expressions "ad". "[<;{},|&+-]\\|\\([^>:-]>\\)" ;; Otherwise we still stop on ',' to find the ;; argument start positions. "[<;{},]\\|\\([^>:-]>\\)") nil 'move t t 1) ;; If the arglist starter has lost its open paren ;; syntax but not the closer, we won't find the ;; closer above since we only search in the ;; balanced sexp. In that case we stop just short ;; of it so check if the following char is the closer. (when (eq (char-after) ?>) (forward-char) t))) (cond ((eq (char-before) ?>) ;; Either an operator starting with '>' or the end of ;; the angle bracket arglist. (if (looking-at c->-op-cont-regexp) (progn (goto-char (match-end 0)) t) ; Continue the loop. ;; The angle bracket arglist is finished. (when c-parse-and-markup-<>-arglists (while arg-start-pos (c-put-c-type-property (1- (car arg-start-pos)) 'c-<>-arg-sep) (setq arg-start-pos (cdr arg-start-pos))) (c-mark-<-as-paren start) (c-mark->-as-paren (1- (point)))) (setq res t) nil)) ; Exit the loop. ((eq (char-before) ?<) ;; Either an operator starting with '<' or a nested arglist. (setq pos (point)) (let (id-start id-end subres keyword-match) (if (if (looking-at c-<-op-cont-regexp) (setq tmp (match-end 0)) (setq tmp pos) (backward-char) (not (and (save-excursion ;; There's always an identifier before an angle ;; bracket arglist, or a keyword in ;; `c-<>-type-kwds' or `c-<>-arglist-kwds'. (c-backward-syntactic-ws) (setq id-end (point)) (c-simple-skip-symbol-backward) (when (or (setq keyword-match (looking-at c-opt-<>-sexp-key)) (not (looking-at c-keywords-regexp))) (setq id-start (point)))) (setq subres (let ((c-record-type-identifiers nil) (c-record-found-types nil)) (c-forward-<>-arglist-recur (and keyword-match (c-keyword-member (c-keyword-sym (match-string 1)) 'c-<>-type-kwds))))) ))) ;; It was not an angle bracket arglist. (goto-char tmp) ;; It was an angle bracket arglist. (setq c-record-found-types subres) ;; Record the identifier before the template as a type ;; or reference depending on whether the arglist is last ;; in a qualified identifier. (when (and c-record-type-identifiers (not keyword-match)) (if (and c-opt-identifier-concat-key (progn (c-forward-syntactic-ws) (looking-at c-opt-identifier-concat-key))) (c-record-ref-id (cons id-start id-end)) (c-record-type-id (cons id-start id-end)))))) t) ((and (eq (char-before) ?,) (not c-restricted-<>-arglists)) ;; Just another argument. Record the position. The ;; type check stuff that made us stop at it is at ;; the top of the loop. (setq arg-start-pos (cons (point) arg-start-pos))) (t ;; Got a character that can't be in an angle bracket ;; arglist argument. Abort using `throw', since ;; it's useless to try to find a surrounding arglist ;; if we're nested. (throw 'angle-bracket-arglist-escape nil)))))) (if res (or c-record-found-types t))))) (defun c-backward-<>-arglist (all-types &optional limit) ;; The point is assumed to be directly after a ">". Try to treat it ;; as the close paren of an angle bracket arglist and move back to ;; the corresponding "<". If successful, the point is left at ;; the "<" and t is returned, otherwise the point isn't moved and ;; nil is returned. ALL-TYPES is passed on to ;; `c-forward-<>-arglist'. ;; ;; If the optional LIMIT is given, it bounds the backward search. ;; It's then assumed to be at a syntactically relevant position. ;; ;; This is a wrapper around `c-forward-<>-arglist'. See that ;; function for more details. (let ((start (point))) (backward-char) (if (and (not c-parse-and-markup-<>-arglists) (c-get-char-property (point) 'syntax-table)) (if (and (c-go-up-list-backward) (eq (char-after) ?<)) t ;; See corresponding note in `c-forward-<>-arglist'. (goto-char start) nil) (while (progn (c-syntactic-skip-backward "^<;{}" limit t) (and (if (eq (char-before) ?<) t ;; Stopped at bob or a char that isn't allowed in an ;; arglist, so we've failed. (goto-char start) nil) (if (> (point) (progn (c-beginning-of-current-token) (point))) ;; If we moved then the "<" was part of some ;; multicharacter token. t (backward-char) (let ((beg-pos (point))) (if (c-forward-<>-arglist all-types) (cond ((= (point) start) ;; Matched the arglist. Break the while. (goto-char beg-pos) nil) ((> (point) start) ;; We started from a non-paren ">" inside an ;; arglist. (goto-char start) nil) (t ;; Matched a shorter arglist. Can be a nested ;; one so continue looking. (goto-char beg-pos) t)) t)))))) (/= (point) start)))) (defun c-forward-name () ;; Move forward over a complete name if at the beginning of one, ;; stopping at the next following token. If the point is not at ;; something that are recognized as name then it stays put. A name ;; could be something as simple as "foo" in C or something as ;; complex as "X::B, BIT_MAX >> b>, ::operator<> :: ;; Z<(a>b)> :: operator const X<&foo>::T Q::G::*volatile const" in C++ (this function is actually little ;; more than a `looking-at' call in all modes except those that, ;; like C++, have `c-recognize-<>-arglists' set). Return nil if no ;; name is found, 'template if it's an identifier ending with an ;; angle bracket arglist, 'operator of it's an operator identifier, ;; or t if it's some other kind of name. ;; ;; This function records identifier ranges on ;; `c-record-type-identifiers' and `c-record-ref-identifiers' if ;; `c-record-type-identifiers' is non-nil. ;; ;; This function might do hidden buffer changes. (let ((pos (point)) (start (point)) res id-start id-end ;; Turn off `c-promote-possible-types' here since we might ;; call `c-forward-<>-arglist' and we don't want it to promote ;; every suspect thing in the arglist to a type. We're ;; typically called from `c-forward-type' in this case, and ;; the caller only wants the top level type that it finds to ;; be promoted. c-promote-possible-types) (while (and (looking-at c-identifier-key) (progn ;; Check for keyword. We go to the last symbol in ;; `c-identifier-key' first. (goto-char (setq id-end (match-end 0))) (c-simple-skip-symbol-backward) (setq id-start (point)) (if (looking-at c-keywords-regexp) (when (and (c-major-mode-is 'c++-mode) (looking-at (cc-eval-when-compile (concat "\\(operator\\|\\(template\\)\\)" "\\(" (c-lang-const c-nonsymbol-key c++) "\\|$\\)"))) (if (match-beginning 2) ;; "template" is only valid inside an ;; identifier if preceded by "::". (save-excursion (c-backward-syntactic-ws) (and (c-safe (backward-char 2) t) (looking-at "::"))) t)) ;; Handle a C++ operator or template identifier. (goto-char id-end) (c-forward-syntactic-ws) (cond ((eq (char-before id-end) ?e) ;; Got "... ::template". (let ((subres (c-forward-name))) (when subres (setq pos (point) res subres)))) ((looking-at c-identifier-start) ;; Got a cast operator. (when (c-forward-type) (setq pos (point) res 'operator) ;; Now we should match a sequence of either ;; '*', '&' or a name followed by ":: *", ;; where each can be followed by a sequence ;; of `c-opt-type-modifier-key'. (while (cond ((looking-at "[*&]") (goto-char (match-end 0)) t) ((looking-at c-identifier-start) (and (c-forward-name) (looking-at "::") (progn (goto-char (match-end 0)) (c-forward-syntactic-ws) (eq (char-after) ?*)) (progn (forward-char) t)))) (while (progn (c-forward-syntactic-ws) (setq pos (point)) (looking-at c-opt-type-modifier-key)) (goto-char (match-end 1)))))) ((looking-at c-overloadable-operators-regexp) ;; Got some other operator. (setq c-last-identifier-range (cons (point) (match-end 0))) (goto-char (match-end 0)) (c-forward-syntactic-ws) (setq pos (point) res 'operator))) nil) ;; `id-start' is equal to `id-end' if we've jumped over ;; an identifier that doesn't end with a symbol token. ;; That can occur e.g. for Java import directives on the ;; form "foo.bar.*". (when (and id-start (/= id-start id-end)) (setq c-last-identifier-range (cons id-start id-end))) (goto-char id-end) (c-forward-syntactic-ws) (setq pos (point) res t))) (progn (goto-char pos) (when (or c-opt-identifier-concat-key c-recognize-<>-arglists) (cond ((and c-opt-identifier-concat-key (looking-at c-opt-identifier-concat-key)) ;; Got a concatenated identifier. This handles the ;; cases with tricky syntactic whitespace that aren't ;; covered in `c-identifier-key'. (goto-char (match-end 0)) (c-forward-syntactic-ws) t) ((and c-recognize-<>-arglists (eq (char-after) ?<)) ;; Maybe an angle bracket arglist. (when (let (c-record-type-identifiers c-record-found-types) (c-forward-<>-arglist nil)) (c-add-type start (1+ pos)) (c-forward-syntactic-ws) (setq pos (point) c-last-identifier-range nil) (if (and c-opt-identifier-concat-key (looking-at c-opt-identifier-concat-key)) ;; Continue if there's an identifier concatenation ;; operator after the template argument. (progn (when (and c-record-type-identifiers id-start) (c-record-ref-id (cons id-start id-end))) (forward-char 2) (c-forward-syntactic-ws) t) (when (and c-record-type-identifiers id-start) (c-record-type-id (cons id-start id-end))) (setq res 'template) nil))) ))))) (goto-char pos) res)) (defun c-forward-type () ;; Move forward over a type spec if at the beginning of one, ;; stopping at the next following token. Return t if it's a known ;; type that can't be a name or other expression, 'known if it's an ;; otherwise known type (according to `*-font-lock-extra-types'), ;; 'prefix if it's a known prefix of a type, 'found if it's a type ;; that matches one in `c-found-types', 'maybe if it's an identfier ;; that might be a type, or nil if it can't be a type (the point ;; isn't moved then). The point is assumed to be at the beginning ;; of a token. ;; ;; Note that this function doesn't skip past the brace definition ;; that might be considered part of the type, e.g. ;; "enum {a, b, c} foo". ;; ;; This function records identifier ranges on ;; `c-record-type-identifiers' and `c-record-ref-identifiers' if ;; `c-record-type-identifiers' is non-nil. ;; ;; This function might do hidden buffer changes. (let ((start (point)) pos res name-res id-start id-end id-range) ;; Skip leading type modifiers. If any are found we know it's a ;; prefix of a type. (when c-opt-type-modifier-key (while (looking-at c-opt-type-modifier-key) (goto-char (match-end 1)) (c-forward-syntactic-ws) (setq res 'prefix))) (cond ((looking-at c-type-prefix-key) ;; Looking at a keyword that prefixes a type identifier, ;; e.g. "class". (goto-char (match-end 1)) (c-forward-syntactic-ws) (setq pos (point)) (if (memq (setq name-res (c-forward-name)) '(t template)) (progn (when (eq name-res t) ;; In many languages the name can be used without the ;; prefix, so we add it to `c-found-types'. (c-add-type pos (point)) (when (and c-record-type-identifiers c-last-identifier-range) (c-record-type-id c-last-identifier-range))) (setq res t)) ;; Invalid syntax. (goto-char start) (setq res nil))) ((progn (setq pos nil) (if (looking-at c-identifier-start) (save-excursion (setq id-start (point) name-res (c-forward-name)) (when name-res (setq id-end (point) id-range c-last-identifier-range)))) (and (cond ((looking-at c-primitive-type-key) (setq res t)) ((c-with-syntax-table c-identifier-syntax-table (looking-at c-known-type-key)) (setq res 'known))) (or (not id-end) (>= (save-excursion (save-match-data (goto-char (match-end 1)) (c-forward-syntactic-ws) (setq pos (point)))) id-end) (setq res nil)))) ;; Looking at a primitive or known type identifier. We've ;; checked for a name first so that we don't go here if the ;; known type match only is a prefix of another name. (setq id-end (match-end 1)) (when (and c-record-type-identifiers (or c-promote-possible-types (eq res t))) (c-record-type-id (cons (match-beginning 1) (match-end 1)))) (if (and c-opt-type-component-key (save-match-data (looking-at c-opt-type-component-key))) ;; There might be more keywords for the type. (let (safe-pos) (c-forward-keyword-clause 1) (while (progn (setq safe-pos (point)) (looking-at c-opt-type-component-key)) (when (and c-record-type-identifiers (looking-at c-primitive-type-key)) (c-record-type-id (cons (match-beginning 1) (match-end 1)))) (c-forward-keyword-clause 1)) (if (looking-at c-primitive-type-key) (progn (when c-record-type-identifiers (c-record-type-id (cons (match-beginning 1) (match-end 1)))) (c-forward-keyword-clause 1) (setq res t)) (goto-char safe-pos) (setq res 'prefix))) (unless (save-match-data (c-forward-keyword-clause 1)) (if pos (goto-char pos) (goto-char (match-end 1)) (c-forward-syntactic-ws))))) (name-res (cond ((eq name-res t) ;; A normal identifier. (goto-char id-end) (if (or res c-promote-possible-types) (progn (c-add-type id-start id-end) (when (and c-record-type-identifiers id-range) (c-record-type-id id-range)) (unless res (setq res 'found))) (setq res (if (c-check-type id-start id-end) ;; It's an identifier that has been used as ;; a type somewhere else. 'found ;; It's an identifier that might be a type. 'maybe)))) ((eq name-res 'template) ;; A template is a type. (goto-char id-end) (setq res t)) (t ;; Otherwise it's an operator identifier, which is not a type. (goto-char start) (setq res nil))))) (when res ;; Skip trailing type modifiers. If any are found we know it's ;; a type. (when c-opt-type-modifier-key (while (looking-at c-opt-type-modifier-key) (goto-char (match-end 1)) (c-forward-syntactic-ws) (setq res t))) ;; Step over any type suffix operator. Do not let the existence ;; of these alter the classification of the found type, since ;; these operators typically are allowed in normal expressions ;; too. (when c-opt-type-suffix-key (while (looking-at c-opt-type-suffix-key) (goto-char (match-end 1)) (c-forward-syntactic-ws))) (when c-opt-type-concat-key ;; Look for a trailing operator that concatenates the type ;; with a following one, and if so step past that one through ;; a recursive call. Note that we don't record concatenated ;; types in `c-found-types' - it's the component types that ;; are recorded when appropriate. (setq pos (point)) (let* ((c-promote-possible-types (or (memq res '(t known)) c-promote-possible-types)) ;; If we can't promote then set `c-record-found-types' so that ;; we can merge in the types from the second part afterwards if ;; it turns out to be a known type there. (c-record-found-types (and c-record-type-identifiers (not c-promote-possible-types))) subres) (if (and (looking-at c-opt-type-concat-key) (progn (goto-char (match-end 1)) (c-forward-syntactic-ws) (setq subres (c-forward-type)))) (progn ;; If either operand certainly is a type then both are, but we ;; don't let the existence of the operator itself promote two ;; uncertain types to a certain one. (cond ((eq res t)) ((eq subres t) (unless (eq name-res 'template) (c-add-type id-start id-end)) (when (and c-record-type-identifiers id-range) (c-record-type-id id-range)) (setq res t)) ((eq res 'known)) ((eq subres 'known) (setq res 'known)) ((eq res 'found)) ((eq subres 'found) (setq res 'found)) (t (setq res 'maybe))) (when (and (eq res t) (consp c-record-found-types)) ;; Merge in the ranges of any types found by the second ;; `c-forward-type'. (setq c-record-type-identifiers ;; `nconc' doesn't mind that the tail of ;; `c-record-found-types' is t. (nconc c-record-found-types c-record-type-identifiers)))) (goto-char pos)))) (when (and c-record-found-types (memq res '(known found)) id-range) (setq c-record-found-types (cons id-range c-record-found-types)))) ;;(message "c-forward-type %s -> %s: %s" start (point) res) res)) ;; Handling of large scale constructs like statements and declarations. ;; Macro used inside `c-forward-decl-or-cast-1'. It ought to be a ;; defsubst or perhaps even a defun, but it contains lots of free ;; variables that refer to things inside `c-forward-decl-or-cast-1'. (defmacro c-fdoc-shift-type-backward (&optional short) ;; `c-forward-decl-or-cast-1' can consume an arbitrary length list ;; of types when parsing a declaration, which means that it ;; sometimes consumes the identifier in the declaration as a type. ;; This is used to "backtrack" and make the last type be treated as ;; an identifier instead. `(progn ,(unless short ;; These identifiers are bound only in the inner let. '(setq identifier-type at-type identifier-start type-start got-parens nil got-identifier t got-suffix t got-suffix-after-parens id-start paren-depth 0)) (if (setq at-type (if (eq backup-at-type 'prefix) t backup-at-type)) (setq type-start backup-type-start id-start backup-id-start) (setq type-start start-pos id-start start-pos)) ;; When these flags already are set we've found specifiers that ;; unconditionally signal these attributes - backtracking doesn't ;; change that. So keep them set in that case. (or at-type-decl (setq at-type-decl backup-at-type-decl)) (or maybe-typeless (setq maybe-typeless backup-maybe-typeless)) ,(unless short ;; This identifier is bound only in the inner let. '(setq start id-start)))) (defun c-forward-decl-or-cast-1 (preceding-token-end context last-cast-end) ;; Move forward over a declaration or a cast if at the start of one. ;; The point is assumed to be at the start of some token. Nil is ;; returned if no declaration or cast is recognized, and the point ;; is clobbered in that case. ;; ;; If a declaration is parsed: ;; ;; The point is left at the first token after the first complete ;; declarator, if there is one. The return value is a cons where ;; the car is the position of the first token in the declarator. ;; Some examples: ;; ;; void foo (int a, char *b) stuff ... ;; car ^ ^ point ;; float (*a)[], b; ;; car ^ ^ point ;; unsigned int a = c_style_initializer, b; ;; car ^ ^ point ;; unsigned int a (cplusplus_style_initializer), b; ;; car ^ ^ point (might change) ;; class Foo : public Bar {} ;; car ^ ^ point ;; class PikeClass (int a, string b) stuff ... ;; car ^ ^ point ;; enum bool; ;; car ^ ^ point ;; enum bool flag; ;; car ^ ^ point ;; void cplusplus_function (int x) throw (Bad); ;; car ^ ^ point ;; Foo::Foo (int b) : Base (b) {} ;; car ^ ^ point ;; ;; The cdr of the return value is non-nil iff a ;; `c-typedef-decl-kwds' specifier is found in the declaration, ;; i.e. the declared identifier(s) are types. ;; ;; If a cast is parsed: ;; ;; The point is left at the first token after the closing paren of ;; the cast. The return value is `cast'. Note that the start ;; position must be at the first token inside the cast parenthesis ;; to recognize it. ;; ;; PRECEDING-TOKEN-END is the first position after the preceding ;; token, i.e. on the other side of the syntactic ws from the point. ;; Use a value less than or equal to (point-min) if the point is at ;; the first token in (the visible part of) the buffer. ;; ;; CONTEXT is a symbol that describes the context at the point: ;; 'decl In a comma-separatded declaration context (typically ;; inside a function declaration arglist). ;; '<> In an angle bracket arglist. ;; 'arglist Some other type of arglist. ;; nil Some other context or unknown context. ;; ;; LAST-CAST-END is the first token after the closing paren of a ;; preceding cast, or nil if none is known. If ;; `c-forward-decl-or-cast-1' is used in succession, it should be ;; the position after the closest preceding call where a cast was ;; matched. In that case it's used to discover chains of casts like ;; "(a) (b) c". ;; ;; This function records identifier ranges on ;; `c-record-type-identifiers' and `c-record-ref-identifiers' if ;; `c-record-type-identifiers' is non-nil. ;; ;; This function might do hidden buffer changes. (let (;; `start-pos' is used below to point to the start of the ;; first type, i.e. after any leading specifiers. It might ;; also point at the beginning of the preceding syntactic ;; whitespace. (start-pos (point)) ;; Set to the result of `c-forward-type'. at-type ;; The position of the first token in what we currently ;; believe is the type in the declaration or cast, after any ;; specifiers and their associated clauses. type-start ;; The position of the first token in what we currently ;; believe is the declarator for the first identifier. Set ;; when the type is found, and moved forward over any ;; `c-decl-hangon-kwds' and their associated clauses that ;; occurs after the type. id-start ;; These store `at-type', `type-start' and `id-start' of the ;; identifier before the one in those variables. The previous ;; identifier might turn out to be the real type in a ;; declaration if the last one has to be the declarator in it. ;; If `backup-at-type' is nil then the other variables have ;; undefined values. backup-at-type backup-type-start backup-id-start ;; Set if we've found a specifier that makes the defined ;; identifier(s) types. at-type-decl ;; Set if we've found a specifier that can start a declaration ;; where there's no type. maybe-typeless ;; If a specifier is found that also can be a type prefix, ;; these flags are set instead of those above. If we need to ;; back up an identifier, they are copied to the real flag ;; variables. Thus they only take effect if we fail to ;; interpret it as a type. backup-at-type-decl backup-maybe-typeless ;; Whether we've found a declaration or a cast. We might know ;; this before we've found the type in it. It's 'ids if we've ;; found two consecutive identifiers (usually a sure sign, but ;; we should allow that in labels too), and t if we've found a ;; specifier keyword (a 100% sure sign). at-decl-or-cast ;; Set when we need to back up to parse this as a declaration ;; but not as a cast. backup-if-not-cast ;; For casts, the return position. cast-end ;; Save `c-record-type-identifiers' and ;; `c-record-ref-identifiers' since ranges are recorded ;; speculatively and should be thrown away if it turns out ;; that it isn't a declaration or cast. (save-rec-type-ids c-record-type-identifiers) (save-rec-ref-ids c-record-ref-identifiers)) ;; Check for a type. Unknown symbols are treated as possible ;; types, but they could also be specifiers disguised through ;; macros like __INLINE__, so we recognize both types and known ;; specifiers after them too. (while (let* ((start (point)) kwd-sym kwd-clause-end found-type) ;; Look for a specifier keyword clause. (when (looking-at c-prefix-spec-kwds-re) (setq kwd-sym (c-keyword-sym (match-string 1))) (save-excursion (c-forward-keyword-clause 1) (setq kwd-clause-end (point)))) (when (setq found-type (c-forward-type)) ;; Found a known or possible type or a prefix of a known type. (when at-type ;; Got two identifiers with nothing but whitespace ;; between them. That can only happen in declarations. (setq at-decl-or-cast 'ids) (when (eq at-type 'found) ;; If the previous identifier is a found type we ;; record it as a real one; it might be some sort of ;; alias for a prefix like "unsigned". (save-excursion (goto-char type-start) (let ((c-promote-possible-types t)) (c-forward-type))))) (setq backup-at-type at-type backup-type-start type-start backup-id-start id-start at-type found-type type-start start id-start (point) ;; The previous ambiguous specifier/type turned out ;; to be a type since we've parsed another one after ;; it, so clear these backup flags. backup-at-type-decl nil backup-maybe-typeless nil)) (if kwd-sym (progn ;; Handle known specifier keywords and ;; `c-decl-hangon-kwds' which can occur after known ;; types. (if (c-keyword-member kwd-sym 'c-decl-hangon-kwds) ;; It's a hang-on keyword that can occur anywhere. (progn (setq at-decl-or-cast t) (if at-type ;; Move the identifier start position if ;; we've passed a type. (setq id-start kwd-clause-end) ;; Otherwise treat this as a specifier and ;; move the fallback position. (setq start-pos kwd-clause-end)) (goto-char kwd-clause-end)) ;; It's an ordinary specifier so we know that ;; anything before this can't be the type. (setq backup-at-type nil start-pos kwd-clause-end) (if found-type ;; It's ambiguous whether this keyword is a ;; specifier or a type prefix, so set the backup ;; flags. (It's assumed that `c-forward-type' ;; moved further than `c-forward-keyword-clause'.) (progn (when (c-keyword-member kwd-sym 'c-typedef-decl-kwds) (setq backup-at-type-decl t)) (when (c-keyword-member kwd-sym 'c-typeless-decl-kwds) (setq backup-maybe-typeless t))) (when (c-keyword-member kwd-sym 'c-typedef-decl-kwds) (setq at-type-decl t)) (when (c-keyword-member kwd-sym 'c-typeless-decl-kwds) (setq maybe-typeless t)) ;; Haven't matched a type so it's an umambiguous ;; specifier keyword and we know we're in a ;; declaration. (setq at-decl-or-cast t) (goto-char kwd-clause-end)))) ;; If the type isn't known we continue so that we'll jump ;; over all specifiers and type identifiers. The reason ;; to do this for a known type prefix is to make things ;; like "unsigned INT16" work. (and found-type (not (eq found-type t)))))) (cond ((eq at-type t) ;; If a known type was found, we still need to skip over any ;; hangon keyword clauses after it. Otherwise it has already ;; been done in the loop above. (while (looking-at c-decl-hangon-key) (c-forward-keyword-clause 1)) (setq id-start (point))) ((eq at-type 'prefix) ;; A prefix type is itself a primitive type when it's not ;; followed by another type. (setq at-type t)) ((not at-type) ;; Got no type but set things up to continue anyway to handle ;; the various cases when a declaration doesn't start with a ;; type. (setq id-start start-pos)) ((and (eq at-type 'maybe) (c-major-mode-is 'c++-mode)) ;; If it's C++ then check if the last "type" ends on the form ;; "foo::foo" or "foo::~foo", i.e. if it's the name of a ;; (con|de)structor. (save-excursion (let (name end-2 end-1) (goto-char id-start) (c-backward-syntactic-ws) (setq end-2 (point)) (when (and (c-simple-skip-symbol-backward) (progn (setq name (buffer-substring-no-properties (point) end-2)) ;; Cheating in the handling of syntactic ws below. (< (skip-chars-backward ":~ \t\n\r\v\f") 0)) (progn (setq end-1 (point)) (c-simple-skip-symbol-backward)) (>= (point) type-start) (equal (buffer-substring-no-properties (point) end-1) name)) ;; It is a (con|de)structor name. In that case the ;; declaration is typeless so zap out any preceding ;; identifier(s) that we might have taken as types. (goto-char type-start) (setq at-type nil backup-at-type nil id-start type-start)))))) ;; Check for and step over a type decl expression after the thing ;; that is or might be a type. This can't be skipped since we ;; need the correct end position of the declarator for ;; `max-type-decl-end-*'. (let ((start (point)) (paren-depth 0) pos ;; True if there's a non-open-paren match of ;; `c-type-decl-prefix-key'. got-prefix ;; True if the declarator is surrounded by a parenthesis pair. got-parens ;; True if there is an identifier in the declarator. got-identifier ;; True if there's a non-close-paren match of ;; `c-type-decl-suffix-key'. got-suffix ;; True if there's a prefix match outside the outermost ;; paren pair that surrounds the declarator. got-prefix-before-parens ;; True if there's a suffix match outside the outermost ;; paren pair that surrounds the declarator. The value is ;; the position of the first suffix match. got-suffix-after-parens ;; True if we've parsed the type decl to a token that is ;; known to end declarations in this context. at-decl-end ;; The earlier values of `at-type' and `type-start' if we've ;; shifted the type backwards. identifier-type identifier-start ;; If `c-parse-and-markup-<>-arglists' is set we need to ;; turn it off during the name skipping below to avoid ;; getting `c-type' properties that might be bogus. That ;; can happen since we don't know if ;; `c-restricted-<>-arglists' will be correct inside the ;; arglist paren that gets entered. c-parse-and-markup-<>-arglists) (goto-char id-start) ;; Skip over type decl prefix operators. (Note similar code in ;; `c-font-lock-declarators'.) (while (and (looking-at c-type-decl-prefix-key) (if (and (c-major-mode-is 'c++-mode) (match-beginning 2)) ;; If the second submatch matches in C++ then ;; we're looking at an identifier that's a ;; prefix only if it specifies a member pointer. (when (setq got-identifier (c-forward-name)) (if (looking-at "\\(::\\)") ;; We only check for a trailing "::" and ;; let the "*" that should follow be ;; matched in the next round. (progn (setq got-identifier nil) t) ;; It turned out to be the real identifier, ;; so stop. nil)) t)) (if (eq (char-after) ?\() (progn (setq paren-depth (1+ paren-depth)) (forward-char)) (unless got-prefix-before-parens (setq got-prefix-before-parens (= paren-depth 0))) (setq got-prefix t) (goto-char (match-end 1))) (c-forward-syntactic-ws)) (setq got-parens (> paren-depth 0)) ;; Skip over an identifier. (or got-identifier (and (looking-at c-identifier-start) (setq got-identifier (c-forward-name)))) ;; Skip over type decl suffix operators. (while (if (looking-at c-type-decl-suffix-key) (if (eq (char-after) ?\)) (when (> paren-depth 0) (setq paren-depth (1- paren-depth)) (forward-char) t) (when (if (save-match-data (looking-at "\\s\(")) (c-safe (c-forward-sexp 1) t) (goto-char (match-end 1)) t) (when (and (not got-suffix-after-parens) (= paren-depth 0)) (setq got-suffix-after-parens (match-beginning 0))) (setq got-suffix t))) ;; No suffix matched. We might have matched the ;; identifier as a type and the open paren of a ;; function arglist as a type decl prefix. In that ;; case we should "backtrack": Reinterpret the last ;; type as the identifier, move out of the arglist and ;; continue searching for suffix operators. ;; ;; Do this even if there's no preceding type, to cope ;; with old style function declarations in K&R C, ;; (con|de)structors in C++ and `c-typeless-decl-kwds' ;; style declarations. That isn't applicable in an ;; arglist context, though. (when (and (= paren-depth 1) (not got-prefix-before-parens) (not (eq at-type t)) (or backup-at-type maybe-typeless backup-maybe-typeless (when c-recognize-typeless-decls (not context))) (setq pos (c-up-list-forward (point))) (eq (char-before pos) ?\))) (c-fdoc-shift-type-backward) (goto-char pos) t)) (c-forward-syntactic-ws)) (when (and (or maybe-typeless backup-maybe-typeless) (not got-identifier) (not got-prefix) at-type) ;; Have found no identifier but `c-typeless-decl-kwds' has ;; matched so we know we're inside a declaration. The ;; preceding type must be the identifier instead. (c-fdoc-shift-type-backward)) (setq at-decl-or-cast (catch 'at-decl-or-cast (when (> paren-depth 0) ;; Encountered something inside parens that isn't matched by ;; the `c-type-decl-*' regexps, so it's not a type decl ;; expression. Try to skip out to the same paren depth to ;; not confuse the cast check below. (c-safe (goto-char (scan-lists (point) 1 paren-depth))) ;; If we've found a specifier keyword then it's a ;; declaration regardless. (throw 'at-decl-or-cast (eq at-decl-or-cast t))) (setq at-decl-end (looking-at (cond ((eq context '<>) "[,>]") (context "[,\)]") (t "[,;]")))) ;; Now we've collected info about various characteristics of ;; the construct we're looking at. Below follows a decision ;; tree based on that. It's ordered to check more certain ;; signs before less certain ones. (if got-identifier (progn (when (and (or at-type maybe-typeless) (not (or got-prefix got-parens))) ;; Got another identifier directly after the type, so it's a ;; declaration. (throw 'at-decl-or-cast t)) (when (and got-parens (not got-prefix) (not got-suffix-after-parens) (or backup-at-type maybe-typeless backup-maybe-typeless)) ;; Got a declaration of the form "foo bar (gnu);" where we've ;; recognized "bar" as the type and "gnu" as the declarator. ;; In this case it's however more likely that "bar" is the ;; declarator and "gnu" a function argument or initializer (if ;; `c-recognize-paren-inits' is set), since the parens around ;; "gnu" would be superfluous if it's a declarator. Shift the ;; type one step backward. (c-fdoc-shift-type-backward))) ;; Found no identifier. (if backup-at-type (progn (when (= (point) start) ;; Got a plain list of identifiers. If a colon follows it's ;; a valid label. Otherwise the last one probably is the ;; declared identifier and we should back up to the previous ;; type, providing it isn't a cast. (if (eq (char-after) ?:) ;; If we've found a specifier keyword then it's a ;; declaration regardless. (throw 'at-decl-or-cast (eq at-decl-or-cast t)) (setq backup-if-not-cast t) (throw 'at-decl-or-cast t))) (when (and got-suffix (not got-prefix) (not got-parens)) ;; Got a plain list of identifiers followed by some suffix. ;; If this isn't a cast then the last identifier probably is ;; the declared one and we should back up to the previous ;; type. (setq backup-if-not-cast t) (throw 'at-decl-or-cast t))) (when (eq at-type t) ;; If the type is known we know that there can't be any ;; identifier somewhere else, and it's only in declarations in ;; e.g. function prototypes and in casts that the identifier may ;; be left out. (throw 'at-decl-or-cast t)) (when (= (point) start) ;; Only got a single identifier (parsed as a type so far). (if (and ;; Check that the identifier isn't at the start of an ;; expression. at-decl-end (cond ((eq context 'decl) ;; Inside an arglist that contains declarations. If K&R ;; style declarations and parenthesis style initializers ;; aren't allowed then the single identifier must be a ;; type, else we require that it's known or found ;; (primitive types are handled above). (or (and (not c-recognize-knr-p) (not c-recognize-paren-inits)) (memq at-type '(known found)))) ((eq context '<>) ;; Inside a template arglist. Accept known and found ;; types; other identifiers could just as well be ;; constants in C++. (memq at-type '(known found))))) (throw 'at-decl-or-cast t) ;; Can't be a valid declaration or cast, but if we've found a ;; specifier it can't be anything else either, so treat it as ;; an invalid/unfinished declaration or cast. (throw 'at-decl-or-cast at-decl-or-cast)))) (if (and got-parens (not got-prefix) (not context) (not (eq at-type t)) (or backup-at-type maybe-typeless backup-maybe-typeless (when c-recognize-typeless-decls (or (not got-suffix) (not (looking-at c-after-suffixed-type-maybe-decl-key)))))) ;; Got an empty paren pair and a preceding type that probably ;; really is the identifier. Shift the type backwards to make ;; the last one the identifier. This is analogous to the ;; "backtracking" done inside the `c-type-decl-suffix-key' loop ;; above. ;; ;; Exception: In addition to the conditions in that ;; "backtracking" code, do not shift backward if we're not ;; looking at either `c-after-suffixed-type-decl-key' or "[;,]". ;; Since there's no preceding type, the shift would mean that ;; the declaration is typeless. But if the regexp doesn't match ;; then we will simply fall through in the tests below and not ;; recognize it at all, so it's better to try it as an abstract ;; declarator instead. (c-fdoc-shift-type-backward) ;; Still no identifier. (when (and got-prefix (or got-parens got-suffix)) ;; Require `got-prefix' together with either `got-parens' or ;; `got-suffix' to recognize it as an abstract declarator: ;; `got-parens' only is probably an empty function call. ;; `got-suffix' only can build an ordinary expression together ;; with the preceding identifier which we've taken as a type. ;; We could actually accept on `got-prefix' only, but that can ;; easily occur temporarily while writing an expression so we ;; avoid that case anyway. We could do a better job if we knew ;; the point when the fontification was invoked. (throw 'at-decl-or-cast t)) (when (and at-type (not got-prefix) (not got-parens) got-suffix-after-parens (eq (char-after got-suffix-after-parens) ?\()) ;; Got a type, no declarator but a paren suffix. I.e. it's a ;; normal function call afterall (or perhaps a C++ style object ;; instantiation expression). (throw 'at-decl-or-cast nil)))) (when at-decl-or-cast ;; By now we've located the type in the declaration that we know ;; we're in. (throw 'at-decl-or-cast t)) (when (and got-identifier (not context) (looking-at c-after-suffixed-type-decl-key) (if (and got-parens (not got-prefix) (not got-suffix) (not (eq at-type t))) ;; Shift the type backward in the case that there's a ;; single identifier inside parens. That can only ;; occur in K&R style function declarations so it's ;; more likely that it really is a function call. ;; Therefore we only do this after ;; `c-after-suffixed-type-decl-key' has matched. (progn (c-fdoc-shift-type-backward) t) got-suffix-after-parens)) ;; A declaration according to `c-after-suffixed-type-decl-key'. (throw 'at-decl-or-cast t)) (when (and (or got-prefix (not got-parens)) (memq at-type '(t known))) ;; It's a declaration if a known type precedes it and it can't be a ;; function call. (throw 'at-decl-or-cast t)) ;; If we get here we can't tell if this is a type decl or a normal ;; expression by looking at it alone. (That's under the assumption ;; that normal expressions always can look like type decl expressions, ;; which isn't really true but the cases where it doesn't hold are so ;; uncommon (e.g. some placements of "const" in C++) it's not worth ;; the effort to look for them.) (unless (or at-decl-end (looking-at "=[^=]")) ;; If this is a declaration it should end here or its initializer(*) ;; should start here, so check for allowed separation tokens. Note ;; that this rule doesn't work e.g. with a K&R arglist after a ;; function header. ;; ;; *) Don't check for C++ style initializers using parens ;; since those already have been matched as suffixes. ;; ;; If `at-decl-or-cast' is then we've found some other sign that ;; it's a declaration or cast, so then it's probably an ;; invalid/unfinished one. (throw 'at-decl-or-cast at-decl-or-cast)) ;; Below are tests that only should be applied when we're certain to ;; not have parsed halfway through an expression. (when (memq at-type '(t known)) ;; The expression starts with a known type so treat it as a ;; declaration. (throw 'at-decl-or-cast t)) (when (and (c-major-mode-is 'c++-mode) ;; In C++ we check if the identifier is a known type, since ;; (con|de)structors use the class name as identifier. ;; We've always shifted over the identifier as a type and ;; then backed up again in this case. identifier-type (or (memq identifier-type '(found known)) (and (eq (char-after identifier-start) ?~) ;; `at-type' probably won't be 'found for ;; destructors since the "~" is then part of the ;; type name being checked against the list of ;; known types, so do a check without that ;; operator. (or (save-excursion (goto-char (1+ identifier-start)) (c-forward-syntactic-ws) (c-with-syntax-table c-identifier-syntax-table (looking-at c-known-type-key))) (save-excursion (goto-char (1+ identifier-start)) ;; We have already parsed the type earlier, ;; so it'd be possible to cache the end ;; position instead of redoing it here, but ;; then we'd need to keep track of another ;; position everywhere. (c-check-type (point) (progn (c-forward-type) (point)))))))) (throw 'at-decl-or-cast t)) (if got-identifier (progn (when (and got-prefix-before-parens at-type (or at-decl-end (looking-at "=[^=]")) (not context) (not got-suffix)) ;; Got something like "foo * bar;". Since we're not inside an ;; arglist it would be a meaningless expression because the ;; result isn't used. We therefore choose to recognize it as ;; a declaration. Do not allow a suffix since it could then ;; be a function call. (throw 'at-decl-or-cast t)) (when (and (or got-suffix-after-parens (looking-at "=[^=]")) (eq at-type 'found) (not (eq context 'arglist))) ;; Got something like "a (*b) (c);" or "a (b) = c;". It could ;; be an odd expression or it could be a declaration. Treat ;; it as a declaration if "a" has been used as a type ;; somewhere else (if it's a known type we won't get here). (throw 'at-decl-or-cast t))) (when (and context (or got-prefix (and (eq context 'decl) (not c-recognize-paren-inits) (or got-parens got-suffix)))) ;; Got a type followed by an abstract declarator. If `got-prefix' ;; is set it's something like "a *" without anything after it. If ;; `got-parens' or `got-suffix' is set it's "a()", "a[]", "a()[]", ;; or similar, which we accept only if the context rules out ;; expressions. (throw 'at-decl-or-cast t))) ;; If we had a complete symbol table here (which rules out ;; `c-found-types') we should return t due to the disambiguation rule ;; (in at least C++) that anything that can be parsed as a declaration ;; is a declaration. Now we're being more defensive and prefer to ;; highlight things like "foo (bar);" as a declaration only if we're ;; inside an arglist that contains declarations. (eq context 'decl)))) ;; The point is now after the type decl expression. (cond ;; Check for a cast. ((save-excursion (and c-cast-parens ;; Should be the first type/identifier in a cast paren. (> preceding-token-end (point-min)) (memq (char-before preceding-token-end) c-cast-parens) ;; The closing paren should follow. (progn (c-forward-syntactic-ws) (looking-at "\\s\)")) ;; There should be a primary expression after it. (let (pos) (forward-char) (c-forward-syntactic-ws) (setq cast-end (point)) (and (looking-at c-primary-expr-regexp) (progn (setq pos (match-end 0)) (or ;; Check if the expression begins with a prefix keyword. (match-beginning 2) (if (match-beginning 1) ;; Expression begins with an ambiguous operator. Treat ;; it as a cast if it's a type decl or if we've ;; recognized the type somewhere else. (or at-decl-or-cast (memq at-type '(t known found))) ;; Unless it's a keyword, it's the beginning of a primary ;; expression. (not (looking-at c-keywords-regexp))))) ;; If `c-primary-expr-regexp' matched a nonsymbol token, check ;; that it matched a whole one so that we don't e.g. confuse ;; the operator '-' with '->'. It's ok if it matches further, ;; though, since it e.g. can match the float '.5' while the ;; operator regexp only matches '.'. (or (not (looking-at c-nonsymbol-token-regexp)) (<= (match-end 0) pos)))) ;; There should either be a cast before it or something that isn't an ;; identifier or close paren. (> preceding-token-end (point-min)) (progn (goto-char (1- preceding-token-end)) (or (eq (point) last-cast-end) (progn (c-backward-syntactic-ws) (if (< (skip-syntax-backward "w_") 0) ;; It's a symbol. Accept it only if it's one of the ;; keywords that can precede an expression (without ;; surrounding parens). (looking-at c-simple-stmt-key) (and ;; Check that it isn't a close paren (block close is ok, ;; though). (not (memq (char-before) '(?\) ?\]))) ;; Check that it isn't a nonsymbol identifier. (not (c-on-identifier))))))))) ;; Handle the cast. (when (and c-record-type-identifiers at-type (not (eq at-type t))) (let ((c-promote-possible-types t)) (goto-char type-start) (c-forward-type))) (goto-char cast-end) 'cast) (at-decl-or-cast ;; We're at a declaration. Highlight the type and the following ;; declarators. (when backup-if-not-cast (c-fdoc-shift-type-backward t)) (when (and (eq context 'decl) (looking-at ",")) ;; Make sure to propagate the `c-decl-arg-start' property to ;; the next argument if it's set in this one, to cope with ;; interactive refontification. (c-put-c-type-property (point) 'c-decl-arg-start)) (when (and c-record-type-identifiers at-type (not (eq at-type t))) (let ((c-promote-possible-types t)) (save-excursion (goto-char type-start) (c-forward-type)))) (cons id-start at-type-decl)) (t ;; False alarm. Restore the recorded ranges. (setq c-record-type-identifiers save-rec-type-ids c-record-ref-identifiers save-rec-ref-ids) nil)))) (defun c-forward-label (&optional assume-markup preceding-token-end limit) ;; Assuming that point is at the beginning of a token, check if it starts a ;; label and if so move over it and return non-nil (t in default situations, ;; specific symbols (see below) for interesting situations), otherwise don't ;; move and return nil. "Label" here means "most things with a colon". ;; ;; More precisely, a "label" is regarded as one of: ;; (i) a goto target like "foo:" - returns the symbol `goto-target'; ;; (ii) A case label - either the entire construct "case FOO:", or just the ;; bare "case", should the colon be missing. We return t; ;; (iii) a keyword which needs a colon, like "default:" or "private:"; We ;; return t; ;; (iv) One of QT's "extended" C++ variants of ;; "private:"/"protected:"/"public:"/"more:" looking like "public slots:". ;; Returns the symbol `qt-2kwds-colon'. ;; (v) QT's construct "signals:". Returns the symbol `qt-1kwd-colon'. ;; (v) One of the keywords matched by `c-opt-extra-label-key' (without any ;; colon). Currently (2006-03), this applies only to Objective C's ;; keywords "@private", "@protected", and "@public". Returns t. ;; ;; One of the things which will NOT be recognised as a label is a bit-field ;; element of a struct, something like "int foo:5". ;; ;; The end of the label is taken to be just after the colon, or the end of ;; the first submatch in `c-opt-extra-label-key'. The point is directly ;; after the end on return. The terminating char gets marked with ;; `c-decl-end' to improve recognition of the following declaration or ;; statement. ;; ;; If ASSUME-MARKUP is non-nil, it's assumed that the preceding ;; label, if any, has already been marked up like that. ;; ;; If PRECEDING-TOKEN-END is given, it should be the first position ;; after the preceding token, i.e. on the other side of the ;; syntactic ws from the point. Use a value less than or equal to ;; (point-min) if the point is at the first token in (the visible ;; part of) the buffer. ;; ;; The optional LIMIT limits the forward scan for the colon. ;; ;; This function records the ranges of the label symbols on ;; `c-record-ref-identifiers' if `c-record-type-identifiers' (!) is ;; non-nil. ;; ;; This function might do hidden buffer changes. (let ((start (point)) label-end qt-symbol-idx macro-start ; if we're in one. label-type) (cond ;; "case" or "default" (Doesn't apply to AWK). ((looking-at c-label-kwds-regexp) (let ((kwd-end (match-end 1))) ;; Record only the keyword itself for fontification, since in ;; case labels the following is a constant expression and not ;; a label. (when c-record-type-identifiers (c-record-ref-id (cons (match-beginning 1) kwd-end))) ;; Find the label end. (goto-char kwd-end) (setq label-type (if (and (c-syntactic-re-search-forward ;; Stop on chars that aren't allowed in expressions, ;; and on operator chars that would be meaningless ;; there. FIXME: This doesn't cope with ?: operators. "[;{=,@]\\|\\(\\=\\|[^:]\\):\\([^:]\\|\\'\\)" limit t t nil 1) (match-beginning 2)) (progn ; there's a proper : (goto-char (match-beginning 2)) ; just after the : (c-put-c-type-property (1- (point)) 'c-decl-end) t) ;; It's an unfinished label. We consider the keyword enough ;; to recognize it as a label, so that it gets fontified. ;; Leave the point at the end of it, but don't put any ;; `c-decl-end' marker. (goto-char kwd-end) t)))) ;; @private, @protected, @public, in Objective C, or similar. ((and c-opt-extra-label-key (looking-at c-opt-extra-label-key)) ;; For a `c-opt-extra-label-key' match, we record the whole ;; thing for fontification. That's to get the leading '@' in ;; Objective-C protection labels fontified. (goto-char (match-end 1)) (when c-record-type-identifiers (c-record-ref-id (cons (match-beginning 1) (point)))) (c-put-c-type-property (1- (point)) 'c-decl-end) (setq label-type t)) ;; All other cases of labels. ((and c-recognize-colon-labels ; nil for AWK and IDL, otherwise t. ;; A colon label must have something before the colon. (not (eq (char-after) ?:)) ;; Check that we're not after a token that can't precede a label. (or ;; Trivially succeeds when there's no preceding token. (if preceding-token-end (<= preceding-token-end (point-min)) (save-excursion (c-backward-syntactic-ws) (setq preceding-token-end (point)) (bobp))) ;; Check if we're after a label, if we're after a closing ;; paren that belong to statement, and with ;; `c-label-prefix-re'. It's done in different order ;; depending on `assume-markup' since the checks have ;; different expensiveness. (if assume-markup (or (eq (c-get-char-property (1- preceding-token-end) 'c-type) 'c-decl-end) (save-excursion (goto-char (1- preceding-token-end)) (c-beginning-of-current-token) (or (looking-at c-label-prefix-re) (looking-at c-block-stmt-1-key))) (and (eq (char-before preceding-token-end) ?\)) (c-after-conditional))) (or (save-excursion (goto-char (1- preceding-token-end)) (c-beginning-of-current-token) (or (looking-at c-label-prefix-re) (looking-at c-block-stmt-1-key))) (cond ((eq (char-before preceding-token-end) ?\)) (c-after-conditional)) ((eq (char-before preceding-token-end) ?:) ;; Might be after another label, so check it recursively. (save-restriction (save-excursion (goto-char (1- preceding-token-end)) ;; Essentially the same as the ;; `c-syntactic-re-search-forward' regexp below. (setq macro-start (save-excursion (and (c-beginning-of-macro) (point)))) (if macro-start (narrow-to-region macro-start (point-max))) (c-syntactic-skip-backward "^-]:?;}=*/%&|,<>!@+" nil t) ;; Note: the following should work instead of the ;; narrow-to-region above. Investigate why not, ;; sometime. ACM, 2006-03-31. ;; (c-syntactic-skip-backward "^-]:?;}=*/%&|,<>!@+" ;; macro-start t) (let ((pte (point)) ;; If the caller turned on recording for us, ;; it shouldn't apply when we check the ;; preceding label. c-record-type-identifiers) ;; A label can't start at a cpp directive. Check for ;; this, since c-forward-syntactic-ws would foul up on it. (unless (and c-opt-cpp-prefix (looking-at c-opt-cpp-prefix)) (c-forward-syntactic-ws) (c-forward-label nil pte start)))))))))) ;; Point is still at the beginning of the possible label construct. ;; ;; Check that the next nonsymbol token is ":", or that we're in one ;; of QT's "slots" declarations. Allow '(' for the sake of macro ;; arguments. FIXME: Should build this regexp from the language ;; constants. (cond ;; public: protected: private: ((and (c-major-mode-is 'c++-mode) (search-forward-regexp "\\=p\\(r\\(ivate\\|otected\\)\\|ublic\\)\\>[^_]" nil t) (progn (backward-char) (c-forward-syntactic-ws limit) (looking-at ":\\([^:]\\|\\'\\)"))) ; A single colon. (forward-char) (setq label-type t)) ;; QT double keyword like "protected slots:" or goto target. ((progn (goto-char start) nil)) ((when (c-syntactic-re-search-forward "[ \t\n[:?;{=*/%&|,<>!@+-]" limit t t) ; not at EOB (backward-char) (setq label-end (point)) (setq qt-symbol-idx (and (c-major-mode-is 'c++-mode) (string-match "\\(p\\(r\\(ivate\\|otected\\)\\|ublic\\)\\|more\\)\\>" (buffer-substring start (point))))) (c-forward-syntactic-ws limit) (cond ((looking-at ":\\([^:]\\|\\'\\)") ; A single colon. (forward-char) (setq label-type (if (string= "signals" ; Special QT macro (buffer-substring-no-properties start label-end)) 'qt-1kwd-colon 'goto-target))) ((and qt-symbol-idx (search-forward-regexp "\\=slots\\>" limit t) (progn (c-forward-syntactic-ws limit) (looking-at ":\\([^:]\\|\\'\\)"))) ; A single colon (forward-char) (setq label-type 'qt-2kwds-colon))))))) (save-restriction (narrow-to-region start (point)) ;; Check that `c-nonlabel-token-key' doesn't match anywhere. (catch 'check-label (goto-char start) (while (progn (when (looking-at c-nonlabel-token-key) (goto-char start) (setq label-type nil) (throw 'check-label nil)) (and (c-safe (c-forward-sexp) (c-forward-syntactic-ws) t) (not (eobp))))) ;; Record the identifiers in the label for fontification, unless ;; it begins with `c-label-kwds' in which case the following ;; identifiers are part of a (constant) expression that ;; shouldn't be fontified. (when (and c-record-type-identifiers (progn (goto-char start) (not (looking-at c-label-kwds-regexp)))) (while (c-syntactic-re-search-forward c-symbol-key nil t) (c-record-ref-id (cons (match-beginning 0) (match-end 0))))) (c-put-c-type-property (1- (point-max)) 'c-decl-end) (goto-char (point-max)) ))) (t ;; Not a label. (goto-char start))) label-type)) (defun c-forward-objc-directive () ;; Assuming the point is at the beginning of a token, try to move ;; forward to the end of the Objective-C directive that starts ;; there. Return t if a directive was fully recognized, otherwise ;; the point is moved as far as one could be successfully parsed and ;; nil is returned. ;; ;; This function records identifier ranges on ;; `c-record-type-identifiers' and `c-record-ref-identifiers' if ;; `c-record-type-identifiers' is non-nil. ;; ;; This function might do hidden buffer changes. (let ((start (point)) start-char (c-promote-possible-types t) ;; Turn off recognition of angle bracket arglists while parsing ;; types here since the protocol reference list might then be ;; considered part of the preceding name or superclass-name. c-recognize-<>-arglists) (if (or (when (looking-at (eval-when-compile (c-make-keywords-re t (append (c-lang-const c-protection-kwds objc) '("@end")) 'objc-mode))) (goto-char (match-end 1)) t) (and (looking-at (eval-when-compile (c-make-keywords-re t '("@interface" "@implementation" "@protocol") 'objc-mode))) ;; Handle the name of the class itself. (progn ; (c-forward-token-2) ; 2006/1/13 This doesn't move if the token's ; at EOB. (goto-char (match-end 0)) (c-skip-ws-forward) (c-forward-type)) (catch 'break ;; Look for ": superclass-name" or "( category-name )". (when (looking-at "[:\(]") (setq start-char (char-after)) (forward-char) (c-forward-syntactic-ws) (unless (c-forward-type) (throw 'break nil)) (when (eq start-char ?\() (unless (eq (char-after) ?\)) (throw 'break nil)) (forward-char) (c-forward-syntactic-ws))) ;; Look for a protocol reference list. (if (eq (char-after) ?<) (let ((c-recognize-<>-arglists t) (c-parse-and-markup-<>-arglists t) c-restricted-<>-arglists) (c-forward-<>-arglist t)) t)))) (progn (c-backward-syntactic-ws) (c-clear-c-type-property start (1- (point)) 'c-decl-end) (c-put-c-type-property (1- (point)) 'c-decl-end) t) (c-clear-c-type-property start (point) 'c-decl-end) nil))) (defun c-beginning-of-inheritance-list (&optional lim) ;; Go to the first non-whitespace after the colon that starts a ;; multiple inheritance introduction. Optional LIM is the farthest ;; back we should search. ;; ;; This function might do hidden buffer changes. (c-with-syntax-table c++-template-syntax-table (c-backward-token-2 0 t lim) (while (and (or (looking-at c-symbol-start) (looking-at "[<,]\\|::")) (zerop (c-backward-token-2 1 t lim)))))) (defun c-in-method-def-p () ;; Return nil if we aren't in a method definition, otherwise the ;; position of the initial [+-]. ;; ;; This function might do hidden buffer changes. (save-excursion (beginning-of-line) (and c-opt-method-key (looking-at c-opt-method-key) (point)) )) ;; Contributed by Kevin Ryde . (defun c-in-gcc-asm-p () ;; Return non-nil if point is within a gcc \"asm\" block. ;; ;; This should be called with point inside an argument list. ;; ;; Only one level of enclosing parentheses is considered, so for ;; instance `nil' is returned when in a function call within an asm ;; operand. ;; ;; This function might do hidden buffer changes. (and c-opt-asm-stmt-key (save-excursion (beginning-of-line) (backward-up-list 1) (c-beginning-of-statement-1 (point-min) nil t) (looking-at c-opt-asm-stmt-key)))) (defun c-at-toplevel-p () "Return a determination as to whether point is at the `top-level'. Being at the top-level means that point is either outside any enclosing block (such function definition), or only inside a class, namespace or other block that contains another declaration level. If point is not at the top-level (e.g. it is inside a method definition), then nil is returned. Otherwise, if point is at a top-level not enclosed within a class definition, t is returned. Otherwise, a 2-vector is returned where the zeroth element is the buffer position of the start of the class declaration, and the first element is the buffer position of the enclosing class's opening brace. Note that this function might do hidden buffer changes. See the comment at the start of cc-engine.el for more info." (let ((paren-state (c-parse-state))) (or (not (c-most-enclosing-brace paren-state)) (c-search-uplist-for-classkey paren-state)))) (defun c-just-after-func-arglist-p (&optional lim) ;; Return non-nil if the point is in the region after the argument ;; list of a function and its opening brace (or semicolon in case it ;; got no body). If there are K&R style argument declarations in ;; that region, the point has to be inside the first one for this ;; function to recognize it. ;; ;; If successful, the point is moved to the first token after the ;; function header (see `c-forward-decl-or-cast-1' for details) and ;; the position of the opening paren of the function arglist is ;; returned. ;; ;; The point is clobbered if not successful. ;; ;; LIM is used as bound for backward buffer searches. ;; ;; This function might do hidden buffer changes. (let ((beg (point)) end id-start) (and (eq (c-beginning-of-statement-1 lim) 'same) (not (or (c-major-mode-is 'objc-mode) (c-forward-objc-directive))) (setq id-start (car-safe (c-forward-decl-or-cast-1 (c-point 'bosws) nil nil))) (< id-start beg) ;; There should not be a '=' or ',' between beg and the ;; start of the declaration since that means we were in the ;; "expression part" of the declaration. (or (> (point) beg) (not (looking-at "[=,]"))) (save-excursion ;; Check that there's an arglist paren in the ;; declaration. (goto-char id-start) (cond ((eq (char-after) ?\() ;; The declarator is a paren expression, so skip past it ;; so that we don't get stuck on that instead of the ;; function arglist. (c-forward-sexp)) ((and c-opt-op-identifier-prefix (looking-at c-opt-op-identifier-prefix)) ;; Don't trip up on "operator ()". (c-forward-token-2 2 t))) (and (< (point) beg) (c-syntactic-re-search-forward "(" beg t t) (1- (point))))))) (defun c-in-knr-argdecl (&optional lim) ;; Return the position of the first argument declaration if point is ;; inside a K&R style argument declaration list, nil otherwise. ;; `c-recognize-knr-p' is not checked. If LIM is non-nil, it's a ;; position that bounds the backward search for the argument list. ;; ;; Point must be within a possible K&R region, e.g. just before a top-level ;; "{". It must be outside of parens and brackets. The test can return ;; false positives otherwise. ;; ;; This function might do hidden buffer changes. (save-excursion (save-restriction ;; If we're in a macro, our search range is restricted to it. Narrow to ;; the searchable range. (let* ((macro-start (c-query-macro-start)) (lim (max (or lim (point-min)) (or macro-start (point-min)))) before-lparen after-rparen) (narrow-to-region lim (c-point 'eol)) ;; Search backwards for the defun's argument list. We give up if we ;; encounter a "}" (end of a previous defun) or BOB. ;; ;; The criterion for a paren structure being the arg list is: ;; o - there is non-WS stuff after it but before any "{"; AND ;; o - the token after it isn't a ";" AND ;; o - it is preceded by either an identifier (the function name) or ;; a macro expansion like "DEFUN (...)"; AND ;; o - its content is a non-empty comma-separated list of identifiers ;; (an empty arg list won't have a knr region). ;; ;; The following snippet illustrates these rules: ;; int foo (bar, baz, yuk) ;; int bar [] ; ;; int (*baz) (my_type) ; ;; int (*) (void) (*yuk) (void) ; ;; { (catch 'knr (while t ; go round one paren/bracket construct each time round. (c-syntactic-skip-backward "^)]}") (cond ((eq (char-before) ?\)) (setq after-rparen (point))) ((eq (char-before) ?\]) (setq after-rparen nil)) (t ; either } (hit previous defun) or no more parens/brackets (throw 'knr nil))) (if after-rparen ;; We're inside a paren. Could it be our argument list....? (if (and (progn (goto-char after-rparen) (unless (c-go-list-backward) (throw 'knr nil)) ; ;; FIXME!!! What about macros between the parens? 2007/01/20 (setq before-lparen (point))) ;; It can't be the arg list if next token is ; or { (progn (goto-char after-rparen) (c-forward-syntactic-ws) (not (memq (char-after) '(?\; ?\{)))) ;; Is the thing preceding the list an identifier (the ;; function name), or a macro expansion? (progn (goto-char before-lparen) (eq (c-backward-token-2) 0) (or (c-on-identifier) (and (eq (char-after) ?\)) (c-go-up-list-backward) (eq (c-backward-token-2) 0) (c-on-identifier)))) ;; Have we got a non-empty list of comma-separated ;; identifiers? (progn (goto-char before-lparen) (c-forward-token-2) ; to first token inside parens (and (c-on-identifier) (c-forward-token-2) (catch 'id-list (while (eq (char-after) ?\,) (c-forward-token-2) (unless (c-on-identifier) (throw 'id-list nil)) (c-forward-token-2)) (eq (char-after) ?\)))))) ;; ...Yes. We've identified the function's argument list. (throw 'knr (progn (goto-char after-rparen) (c-forward-syntactic-ws) (point))) ;; ...No. The current parens aren't the function's arg list. (goto-char before-lparen)) (or (c-go-list-backward) ; backwards over [ .... ] (throw 'knr nil))))))))) (defun c-skip-conditional () ;; skip forward over conditional at point, including any predicate ;; statements in parentheses. No error checking is performed. ;; ;; This function might do hidden buffer changes. (c-forward-sexp (cond ;; else if() ((looking-at (concat "\\\\([^_]\\|$\\)")) 3) ;; do, else, try, finally ((looking-at (concat "\\<\\(" "do\\|else\\|try\\|finally" "\\)\\>\\([^_]\\|$\\)")) 1) ;; for, if, while, switch, catch, synchronized, foreach (t 2)))) (defun c-after-conditional (&optional lim) ;; If looking at the token after a conditional then return the ;; position of its start, otherwise return nil. ;; ;; This function might do hidden buffer changes. (save-excursion (and (zerop (c-backward-token-2 1 t lim)) (or (looking-at c-block-stmt-1-key) (and (eq (char-after) ?\() (zerop (c-backward-token-2 1 t lim)) (looking-at c-block-stmt-2-key))) (point)))) (defun c-after-special-operator-id (&optional lim) ;; If the point is after an operator identifier that isn't handled ;; like an ordinary symbol (i.e. like "operator =" in C++) then the ;; position of the start of that identifier is returned. nil is ;; returned otherwise. The point may be anywhere in the syntactic ;; whitespace after the last token of the operator identifier. ;; ;; This function might do hidden buffer changes. (save-excursion (and c-overloadable-operators-regexp (zerop (c-backward-token-2 1 nil lim)) (looking-at c-overloadable-operators-regexp) (or (not c-opt-op-identifier-prefix) (and (zerop (c-backward-token-2 1 nil lim)) (looking-at c-opt-op-identifier-prefix))) (point)))) (defsubst c-backward-to-block-anchor (&optional lim) ;; Assuming point is at a brace that opens a statement block of some ;; kind, move to the proper anchor point for that block. It might ;; need to be adjusted further by c-add-stmt-syntax, but the ;; position at return is suitable as start position for that ;; function. ;; ;; This function might do hidden buffer changes. (unless (= (point) (c-point 'boi)) (let ((start (c-after-conditional lim))) (if start (goto-char start))))) (defsubst c-backward-to-decl-anchor (&optional lim) ;; Assuming point is at a brace that opens the block of a top level ;; declaration of some kind, move to the proper anchor point for ;; that block. ;; ;; This function might do hidden buffer changes. (unless (= (point) (c-point 'boi)) (c-beginning-of-statement-1 lim))) (defun c-search-decl-header-end () ;; Search forward for the end of the "header" of the current ;; declaration. That's the position where the definition body ;; starts, or the first variable initializer, or the ending ;; semicolon. I.e. search forward for the closest following ;; (syntactically relevant) '{', '=' or ';' token. Point is left ;; _after_ the first found token, or at point-max if none is found. ;; ;; This function might do hidden buffer changes. (let ((base (point))) (if (c-major-mode-is 'c++-mode) ;; In C++ we need to take special care to handle operator ;; tokens and those pesky template brackets. (while (and (c-syntactic-re-search-forward "[;{<=]" nil 'move t t) (or (c-end-of-current-token base) ;; Handle operator identifiers, i.e. ignore any ;; operator token preceded by "operator". (save-excursion (and (c-safe (c-backward-sexp) t) (looking-at c-opt-op-identifier-prefix))) (and (eq (char-before) ?<) (c-with-syntax-table c++-template-syntax-table (if (c-safe (goto-char (c-up-list-forward (point)))) t (goto-char (point-max)) nil))))) (setq base (point))) (while (and (c-syntactic-re-search-forward "[;{=]" nil 'move t t) (c-end-of-current-token base)) (setq base (point)))))) (defun c-beginning-of-decl-1 (&optional lim) ;; Go to the beginning of the current declaration, or the beginning ;; of the previous one if already at the start of it. Point won't ;; be moved out of any surrounding paren. Return a cons cell of the ;; form (MOVE . KNR-POS). MOVE is like the return value from ;; `c-beginning-of-statement-1'. If point skipped over some K&R ;; style argument declarations (and they are to be recognized) then ;; KNR-POS is set to the start of the first such argument ;; declaration, otherwise KNR-POS is nil. If LIM is non-nil, it's a ;; position that bounds the backward search. ;; ;; NB: Cases where the declaration continues after the block, as in ;; "struct foo { ... } bar;", are currently recognized as two ;; declarations, e.g. "struct foo { ... }" and "bar;" in this case. ;; ;; This function might do hidden buffer changes. (catch 'return (let* ((start (point)) (last-stmt-start (point)) (move (c-beginning-of-statement-1 lim nil t))) ;; `c-beginning-of-statement-1' stops at a block start, but we ;; want to continue if the block doesn't begin a top level ;; construct, i.e. if it isn't preceded by ';', '}', ':', bob, ;; or an open paren. (let ((beg (point)) tentative-move) ;; Go back one "statement" each time round the loop until we're just ;; after a ;, }, or :, or at BOB or the start of a macro or start of ;; an ObjC method. This will move over a multiple declaration whose ;; components are comma separated. (while (and ;; Must check with c-opt-method-key in ObjC mode. (not (and c-opt-method-key (looking-at c-opt-method-key))) (/= last-stmt-start (point)) (progn (c-backward-syntactic-ws lim) (not (memq (char-before) '(?\; ?} ?: nil)))) (save-excursion (backward-char) (not (looking-at "\\s("))) ;; Check that we don't move from the first thing in a ;; macro to its header. (not (eq (setq tentative-move (c-beginning-of-statement-1 lim nil t)) 'macro))) (setq last-stmt-start beg beg (point) move tentative-move)) (goto-char beg)) (when c-recognize-knr-p (let ((fallback-pos (point)) knr-argdecl-start) ;; Handle K&R argdecls. Back up after the "statement" jumped ;; over by `c-beginning-of-statement-1', unless it was the ;; function body, in which case we're sitting on the opening ;; brace now. Then test if we're in a K&R argdecl region and ;; that we started at the other side of the first argdecl in ;; it. (unless (eq (char-after) ?{) (goto-char last-stmt-start)) (if (and (setq knr-argdecl-start (c-in-knr-argdecl lim)) (< knr-argdecl-start start) (progn (goto-char knr-argdecl-start) (not (eq (c-beginning-of-statement-1 lim nil t) 'macro)))) (throw 'return (cons (if (eq (char-after fallback-pos) ?{) 'previous 'same) knr-argdecl-start)) (goto-char fallback-pos)))) ;; `c-beginning-of-statement-1' counts each brace block as a separate ;; statement, so the result will be 'previous if we've moved over any. ;; So change our result back to 'same if necessary. ;; ;; If they were brace list initializers we might not have moved over a ;; declaration boundary though, so change it to 'same if we've moved ;; past a '=' before '{', but not ';'. (This ought to be integrated ;; into `c-beginning-of-statement-1', so we avoid this extra pass which ;; potentially can search over a large amount of text.). Take special ;; pains not to get mislead by C++'s "operator=", and the like. (if (and (eq move 'previous) (c-with-syntax-table (if (c-major-mode-is 'c++-mode) c++-template-syntax-table (syntax-table)) (save-excursion (and (progn (while ; keep going back to "[;={"s until we either find ; no more, or get to one which isn't an "operator =" (and (c-syntactic-re-search-forward "[;={]" start t t t) (eq (char-before) ?=) c-overloadable-operators-regexp c-opt-op-identifier-prefix (save-excursion (eq (c-backward-token-2) 0) (looking-at c-overloadable-operators-regexp) (eq (c-backward-token-2) 0) (looking-at c-opt-op-identifier-prefix)))) (eq (char-before) ?=)) (c-syntactic-re-search-forward "[;{]" start t t) (eq (char-before) ?{) (c-safe (goto-char (c-up-list-forward (point))) t) (not (c-syntactic-re-search-forward ";" start t t)))))) (cons 'same nil) (cons move nil))))) (defun c-end-of-decl-1 () ;; Assuming point is at the start of a declaration (as detected by ;; e.g. `c-beginning-of-decl-1'), go to the end of it. Unlike ;; `c-beginning-of-decl-1', this function handles the case when a ;; block is followed by identifiers in e.g. struct declarations in C ;; or C++. If a proper end was found then t is returned, otherwise ;; point is moved as far as possible within the current sexp and nil ;; is returned. This function doesn't handle macros; use ;; `c-end-of-macro' instead in those cases. ;; ;; This function might do hidden buffer changes. (let ((start (point)) (decl-syntax-table (if (c-major-mode-is 'c++-mode) c++-template-syntax-table (syntax-table)))) (catch 'return (c-search-decl-header-end) (when (and c-recognize-knr-p (eq (char-before) ?\;) (c-in-knr-argdecl start)) ;; Stopped at the ';' in a K&R argdecl section which is ;; detected using the same criteria as in ;; `c-beginning-of-decl-1'. Move to the following block ;; start. (c-syntactic-re-search-forward "{" nil 'move t)) (when (eq (char-before) ?{) ;; Encountered a block in the declaration. Jump over it. (condition-case nil (goto-char (c-up-list-forward (point))) (error (goto-char (point-max)) (throw 'return nil))) (if (or (not c-opt-block-decls-with-vars-key) (save-excursion (c-with-syntax-table decl-syntax-table (let ((lim (point))) (goto-char start) (not (and ;; Check for `c-opt-block-decls-with-vars-key' ;; before the first paren. (c-syntactic-re-search-forward (concat "[;=\(\[{]\\|\\(" c-opt-block-decls-with-vars-key "\\)") lim t t t) (match-beginning 1) (not (eq (char-before) ?_)) ;; Check that the first following paren is ;; the block. (c-syntactic-re-search-forward "[;=\(\[{]" lim t t t) (eq (char-before) ?{))))))) ;; The declaration doesn't have any of the ;; `c-opt-block-decls-with-vars' keywords in the ;; beginning, so it ends here at the end of the block. (throw 'return t))) (c-with-syntax-table decl-syntax-table (while (progn (if (eq (char-before) ?\;) (throw 'return t)) (c-syntactic-re-search-forward ";" nil 'move t)))) nil))) (defun c-looking-at-decl-block (containing-sexp goto-start &optional limit) ;; Assuming the point is at an open brace, check if it starts a ;; block that contains another declaration level, i.e. that isn't a ;; statement block or a brace list, and if so return non-nil. ;; ;; If the check is successful, the return value is the start of the ;; keyword that tells what kind of construct it is, i.e. typically ;; what `c-decl-block-key' matched. Also, if GOTO-START is set then ;; the point will be at the start of the construct, before any ;; leading specifiers, otherwise it's at the returned position. ;; ;; The point is clobbered if the check is unsuccessful. ;; ;; CONTAINING-SEXP is the position of the open of the surrounding ;; paren, or nil if none. ;; ;; The optional LIMIT limits the backward search for the start of ;; the construct. It's assumed to be at a syntactically relevant ;; position. ;; ;; If any template arglists are found in the searched region before ;; the open brace, they get marked with paren syntax. ;; ;; This function might do hidden buffer changes. (let ((open-brace (point)) kwd-start first-specifier-pos) (c-syntactic-skip-backward c-block-prefix-charset limit t) (when (and c-recognize-<>-arglists (eq (char-before) ?>)) ;; Could be at the end of a template arglist. (let ((c-parse-and-markup-<>-arglists t) (c-disallow-comma-in-<>-arglists (and containing-sexp (not (eq (char-after containing-sexp) ?{))))) (while (and (c-backward-<>-arglist nil limit) (progn (c-syntactic-skip-backward c-block-prefix-charset limit t) (eq (char-before) ?>)))))) ;; Note: Can't get bogus hits inside template arglists below since they ;; have gotten paren syntax above. (when (and ;; If `goto-start' is set we begin by searching for the ;; first possible position of a leading specifier list. ;; The `c-decl-block-key' search continues from there since ;; we know it can't match earlier. (if goto-start (when (c-syntactic-re-search-forward c-symbol-start open-brace t t) (goto-char (setq first-specifier-pos (match-beginning 0))) t) t) (cond ((c-syntactic-re-search-forward c-decl-block-key open-brace t t t) (goto-char (setq kwd-start (match-beginning 0))) (or ;; Found a keyword that can't be a type? (match-beginning 1) ;; Can be a type too, in which case it's the return type of a ;; function (under the assumption that no declaration level ;; block construct starts with a type). (not (c-forward-type)) ;; Jumped over a type, but it could be a declaration keyword ;; followed by the declared identifier that we've jumped over ;; instead (e.g. in "class Foo {"). If it indeed is a type ;; then we should be at the declarator now, so check for a ;; valid declarator start. ;; ;; Note: This doesn't cope with the case when a declared ;; identifier is followed by e.g. '(' in a language where '(' ;; also might be part of a declarator expression. Currently ;; there's no such language. (not (or (looking-at c-symbol-start) (looking-at c-type-decl-prefix-key))))) ;; In Pike a list of modifiers may be followed by a brace ;; to make them apply to many identifiers. Note that the ;; match data will be empty on return in this case. ((and (c-major-mode-is 'pike-mode) (progn (goto-char open-brace) (= (c-backward-token-2) 0)) (looking-at c-specifier-key) ;; Use this variant to avoid yet another special regexp. (c-keyword-member (c-keyword-sym (match-string 1)) 'c-modifier-kwds)) (setq kwd-start (point)) t))) ;; Got a match. (if goto-start ;; Back up over any preceding specifiers and their clauses ;; by going forward from `first-specifier-pos', which is the ;; earliest possible position where the specifier list can ;; start. (progn (goto-char first-specifier-pos) (while (< (point) kwd-start) (if (looking-at c-symbol-key) ;; Accept any plain symbol token on the ground that ;; it's a specifier masked through a macro (just ;; like `c-forward-decl-or-cast-1' skip forward over ;; such tokens). ;; ;; Could be more restrictive wrt invalid keywords, ;; but that'd only occur in invalid code so there's ;; no use spending effort on it. (let ((end (match-end 0))) (unless (c-forward-keyword-clause 0) (goto-char end) (c-forward-syntactic-ws))) ;; Can't parse a declaration preamble and is still ;; before `kwd-start'. That means `first-specifier-pos' ;; was in some earlier construct. Search again. (if (c-syntactic-re-search-forward c-symbol-start kwd-start 'move t) (goto-char (setq first-specifier-pos (match-beginning 0))) ;; Got no preamble before the block declaration keyword. (setq first-specifier-pos kwd-start)))) (goto-char first-specifier-pos)) (goto-char kwd-start)) kwd-start))) (defun c-search-uplist-for-classkey (paren-state) ;; Check if the closest containing paren sexp is a declaration ;; block, returning a 2 element vector in that case. Aref 0 ;; contains the bufpos at boi of the class key line, and aref 1 ;; contains the bufpos of the open brace. This function is an ;; obsolete wrapper for `c-looking-at-decl-block'. ;; ;; This function might do hidden buffer changes. (let ((open-paren-pos (c-most-enclosing-brace paren-state))) (when open-paren-pos (save-excursion (goto-char open-paren-pos) (when (and (eq (char-after) ?{) (c-looking-at-decl-block (c-safe-position open-paren-pos paren-state) nil)) (back-to-indentation) (vector (point) open-paren-pos)))))) (defun c-inside-bracelist-p (containing-sexp paren-state) ;; return the buffer position of the beginning of the brace list ;; statement if we're inside a brace list, otherwise return nil. ;; CONTAINING-SEXP is the buffer pos of the innermost containing ;; paren. PAREN-STATE is the remainder of the state of enclosing ;; braces ;; ;; N.B.: This algorithm can potentially get confused by cpp macros ;; placed in inconvenient locations. It's a trade-off we make for ;; speed. ;; ;; This function might do hidden buffer changes. (or ;; This will pick up brace list declarations. (c-safe (save-excursion (goto-char containing-sexp) (c-forward-sexp -1) (let (bracepos) (if (and (or (looking-at c-brace-list-key) (progn (c-forward-sexp -1) (looking-at c-brace-list-key))) (setq bracepos (c-down-list-forward (point))) (not (c-crosses-statement-barrier-p (point) (- bracepos 2)))) (point))))) ;; this will pick up array/aggregate init lists, even if they are nested. (save-excursion (let ((class-key ;; Pike can have class definitions anywhere, so we must ;; check for the class key here. (and (c-major-mode-is 'pike-mode) c-decl-block-key)) bufpos braceassignp lim next-containing) (while (and (not bufpos) containing-sexp) (when paren-state (if (consp (car paren-state)) (setq lim (cdr (car paren-state)) paren-state (cdr paren-state)) (setq lim (car paren-state))) (when paren-state (setq next-containing (car paren-state) paren-state (cdr paren-state)))) (goto-char containing-sexp) (if (c-looking-at-inexpr-block next-containing next-containing) ;; We're in an in-expression block of some kind. Do not ;; check nesting. We deliberately set the limit to the ;; containing sexp, so that c-looking-at-inexpr-block ;; doesn't check for an identifier before it. (setq containing-sexp nil) ;; see if the open brace is preceded by = or [...] in ;; this statement, but watch out for operator= (setq braceassignp 'dontknow) (c-backward-token-2 1 t lim) ;; Checks to do only on the first sexp before the brace. (when (and c-opt-inexpr-brace-list-key (eq (char-after) ?\[)) ;; In Java, an initialization brace list may follow ;; directly after "new Foo[]", so check for a "new" ;; earlier. (while (eq braceassignp 'dontknow) (setq braceassignp (cond ((/= (c-backward-token-2 1 t lim) 0) nil) ((looking-at c-opt-inexpr-brace-list-key) t) ((looking-at "\\sw\\|\\s_\\|[.[]") ;; Carry on looking if this is an ;; identifier (may contain "." in Java) ;; or another "[]" sexp. 'dontknow) (t nil))))) ;; Checks to do on all sexps before the brace, up to the ;; beginning of the statement. (while (eq braceassignp 'dontknow) (cond ((eq (char-after) ?\;) (setq braceassignp nil)) ((and class-key (looking-at class-key)) (setq braceassignp nil)) ((eq (char-after) ?=) ;; We've seen a =, but must check earlier tokens so ;; that it isn't something that should be ignored. (setq braceassignp 'maybe) (while (and (eq braceassignp 'maybe) (zerop (c-backward-token-2 1 t lim))) (setq braceassignp (cond ;; Check for operator = ((and c-opt-op-identifier-prefix (looking-at c-opt-op-identifier-prefix)) nil) ;; Check for `= in Pike. ((and (c-major-mode-is 'pike-mode) (or (eq (char-after) ?`) ;; Special case for Pikes ;; `[]=, since '[' is not in ;; the punctuation class. (and (eq (char-after) ?\[) (eq (char-before) ?`)))) nil) ((looking-at "\\s.") 'maybe) ;; make sure we're not in a C++ template ;; argument assignment ((and (c-major-mode-is 'c++-mode) (save-excursion (let ((here (point)) (pos< (progn (skip-chars-backward "^<>") (point)))) (and (eq (char-before) ?<) (not (c-crosses-statement-barrier-p pos< here)) (not (c-in-literal)) )))) nil) (t t)))))) (if (and (eq braceassignp 'dontknow) (/= (c-backward-token-2 1 t lim) 0)) (setq braceassignp nil))) (if (not braceassignp) (if (eq (char-after) ?\;) ;; Brace lists can't contain a semicolon, so we're done. (setq containing-sexp nil) ;; Go up one level. (setq containing-sexp next-containing lim nil next-containing nil)) ;; we've hit the beginning of the aggregate list (c-beginning-of-statement-1 (c-most-enclosing-brace paren-state)) (setq bufpos (point)))) ) bufpos)) )) (defun c-looking-at-special-brace-list (&optional lim) ;; If we're looking at the start of a pike-style list, ie `({ })', ;; `([ ])', `(< >)' etc, a cons of a cons of its starting and ending ;; positions and its entry in c-special-brace-lists is returned, nil ;; otherwise. The ending position is nil if the list is still open. ;; LIM is the limit for forward search. The point may either be at ;; the `(' or at the following paren character. Tries to check the ;; matching closer, but assumes it's correct if no balanced paren is ;; found (i.e. the case `({ ... } ... )' is detected as _not_ being ;; a special brace list). ;; ;; This function might do hidden buffer changes. (if c-special-brace-lists (condition-case () (save-excursion (let ((beg (point)) inner-beg end type) (c-forward-syntactic-ws) (if (eq (char-after) ?\() (progn (forward-char 1) (c-forward-syntactic-ws) (setq inner-beg (point)) (setq type (assq (char-after) c-special-brace-lists))) (if (setq type (assq (char-after) c-special-brace-lists)) (progn (setq inner-beg (point)) (c-backward-syntactic-ws) (forward-char -1) (setq beg (if (eq (char-after) ?\() (point) nil))))) (if (and beg type) (if (and (c-safe (goto-char beg) (c-forward-sexp 1) (setq end (point)) (= (char-before) ?\))) (c-safe (goto-char inner-beg) (if (looking-at "\\s(") ;; Check balancing of the inner paren ;; below. (progn (c-forward-sexp 1) t) ;; If the inner char isn't a paren then ;; we can't check balancing, so just ;; check the char before the outer ;; closing paren. (goto-char end) (backward-char) (c-backward-syntactic-ws) (= (char-before) (cdr type))))) (if (or (/= (char-syntax (char-before)) ?\)) (= (progn (c-forward-syntactic-ws) (point)) (1- end))) (cons (cons beg end) type)) (cons (list beg) type))))) (error nil)))) (defun c-looking-at-bos (&optional lim) ;; Return non-nil if between two statements or declarations, assuming ;; point is not inside a literal or comment. ;; ;; Obsolete - `c-at-statement-start-p' or `c-at-expression-start-p' ;; are recommended instead. ;; ;; This function might do hidden buffer changes. (c-at-statement-start-p)) (make-obsolete 'c-looking-at-bos 'c-at-statement-start-p) (defun c-looking-at-inexpr-block (lim containing-sexp &optional check-at-end) ;; Return non-nil if we're looking at the beginning of a block ;; inside an expression. The value returned is actually a cons of ;; either 'inlambda, 'inexpr-statement or 'inexpr-class and the ;; position of the beginning of the construct. ;; ;; LIM limits the backward search. CONTAINING-SEXP is the start ;; position of the closest containing list. If it's nil, the ;; containing paren isn't used to decide whether we're inside an ;; expression or not. If both LIM and CONTAINING-SEXP are used, LIM ;; needs to be farther back. ;; ;; If CHECK-AT-END is non-nil then extra checks at the end of the ;; brace block might be done. It should only be used when the ;; construct can be assumed to be complete, i.e. when the original ;; starting position was further down than that. ;; ;; This function might do hidden buffer changes. (save-excursion (let ((res 'maybe) passed-paren (closest-lim (or containing-sexp lim (point-min))) ;; Look at the character after point only as a last resort ;; when we can't disambiguate. (block-follows (and (eq (char-after) ?{) (point)))) (while (and (eq res 'maybe) (progn (c-backward-syntactic-ws) (> (point) closest-lim)) (not (bobp)) (progn (backward-char) (looking-at "[\]\).]\\|\\w\\|\\s_")) (c-safe (forward-char) (goto-char (scan-sexps (point) -1)))) (setq res (if (looking-at c-keywords-regexp) (let ((kw-sym (c-keyword-sym (match-string 1)))) (cond ((and block-follows (c-keyword-member kw-sym 'c-inexpr-class-kwds)) (and (not (eq passed-paren ?\[)) (or (not (looking-at c-class-key)) ;; If the class definition is at the start of ;; a statement, we don't consider it an ;; in-expression class. (let ((prev (point))) (while (and (= (c-backward-token-2 1 nil closest-lim) 0) (eq (char-syntax (char-after)) ?w)) (setq prev (point))) (goto-char prev) (not (c-at-statement-start-p))) ;; Also, in Pike we treat it as an ;; in-expression class if it's used in an ;; object clone expression. (save-excursion (and check-at-end (c-major-mode-is 'pike-mode) (progn (goto-char block-follows) (zerop (c-forward-token-2 1 t))) (eq (char-after) ?\()))) (cons 'inexpr-class (point)))) ((c-keyword-member kw-sym 'c-inexpr-block-kwds) (when (not passed-paren) (cons 'inexpr-statement (point)))) ((c-keyword-member kw-sym 'c-lambda-kwds) (when (or (not passed-paren) (eq passed-paren ?\()) (cons 'inlambda (point)))) ((c-keyword-member kw-sym 'c-block-stmt-kwds) nil) (t 'maybe))) (if (looking-at "\\s(") (if passed-paren (if (and (eq passed-paren ?\[) (eq (char-after) ?\[)) ;; Accept several square bracket sexps for ;; Java array initializations. 'maybe) (setq passed-paren (char-after)) 'maybe) 'maybe)))) (if (eq res 'maybe) (when (and c-recognize-paren-inexpr-blocks block-follows containing-sexp (eq (char-after containing-sexp) ?\()) (goto-char containing-sexp) (if (or (save-excursion (c-backward-syntactic-ws lim) (and (> (point) (or lim (point-min))) (c-on-identifier))) (and c-special-brace-lists (c-looking-at-special-brace-list))) nil (cons 'inexpr-statement (point)))) res)))) (defun c-looking-at-inexpr-block-backward (paren-state) ;; Returns non-nil if we're looking at the end of an in-expression ;; block, otherwise the same as `c-looking-at-inexpr-block'. ;; PAREN-STATE is the paren state relevant at the current position. ;; ;; This function might do hidden buffer changes. (save-excursion ;; We currently only recognize a block. (let ((here (point)) (elem (car-safe paren-state)) containing-sexp) (when (and (consp elem) (progn (goto-char (cdr elem)) (c-forward-syntactic-ws here) (= (point) here))) (goto-char (car elem)) (if (setq paren-state (cdr paren-state)) (setq containing-sexp (car-safe paren-state))) (c-looking-at-inexpr-block (c-safe-position containing-sexp paren-state) containing-sexp))))) ;; `c-guess-basic-syntax' and the functions that precedes it below ;; implements the main decision tree for determining the syntactic ;; analysis of the current line of code. ;; Dynamically bound to t when `c-guess-basic-syntax' is called during ;; auto newline analysis. (defvar c-auto-newline-analysis nil) (defsubst c-add-syntax (symbol &rest args) ;; A simple function to prepend a new syntax element to ;; `c-syntactic-context'. Using `setq' on it is unsafe since it ;; should always be dynamically bound but since we read it first ;; we'll fail properly anyway if this function is misused. (setq c-syntactic-context (cons (cons symbol args) c-syntactic-context))) (defsubst c-append-syntax (symbol &rest args) ;; Like `c-add-syntax' but appends to the end of the syntax list. ;; (Normally not necessary.) (setq c-syntactic-context (nconc c-syntactic-context (list (cons symbol args))))) (defun c-add-stmt-syntax (syntax-symbol syntax-extra-args stop-at-boi-only containing-sexp paren-state) ;; Add the indicated SYNTAX-SYMBOL to `c-syntactic-context', extending it as ;; needed with further syntax elements of the types `substatement', ;; `inexpr-statement', `arglist-cont-nonempty', `statement-block-intro', and ;; `defun-block-intro'. ;; ;; Do the generic processing to anchor the given syntax symbol on ;; the preceding statement: Skip over any labels and containing ;; statements on the same line, and then search backward until we ;; find a statement or block start that begins at boi without a ;; label or comment. ;; ;; Point is assumed to be at the prospective anchor point for the ;; given SYNTAX-SYMBOL. More syntax entries are added if we need to ;; skip past open parens and containing statements. All the added ;; syntax elements will get the same anchor point. ;; ;; SYNTAX-EXTRA-ARGS are a list of the extra arguments for the ;; syntax symbol. They are appended after the anchor point. ;; ;; If STOP-AT-BOI-ONLY is nil, we can stop in the middle of the line ;; if the current statement starts there. ;; ;; Note: It's not a problem if PAREN-STATE "overshoots" ;; CONTAINING-SEXP, i.e. contains info about parens further down. ;; ;; This function might do hidden buffer changes. (if (= (point) (c-point 'boi)) ;; This is by far the most common case, so let's give it special ;; treatment. (apply 'c-add-syntax syntax-symbol (point) syntax-extra-args) (let ((syntax-last c-syntactic-context) (boi (c-point 'boi)) ;; Set when we're on a label, so that we don't stop there. ;; FIXME: To be complete we should check if we're on a label ;; now at the start. on-label) (apply 'c-add-syntax syntax-symbol nil syntax-extra-args) ;; Loop while we have to back out of containing blocks. (while (and (catch 'back-up-block ;; Loop while we have to back up statements. (while (or (/= (point) boi) on-label (looking-at c-comment-start-regexp)) ;; Skip past any comments that stands between the ;; statement start and boi. (let ((savepos (point))) (while (and (/= savepos boi) (c-backward-single-comment)) (setq savepos (point) boi (c-point 'boi))) (goto-char savepos)) ;; Skip to the beginning of this statement or backward ;; another one. (let ((old-pos (point)) (old-boi boi) (step-type (c-beginning-of-statement-1 containing-sexp))) (setq boi (c-point 'boi) on-label (eq step-type 'label)) (cond ((= (point) old-pos) ;; If we didn't move we're at the start of a block and ;; have to continue outside it. (throw 'back-up-block t)) ((and (eq step-type 'up) (>= (point) old-boi) (looking-at "else\\>[^_]") (save-excursion (goto-char old-pos) (looking-at "if\\>[^_]"))) ;; Special case to avoid deeper and deeper indentation ;; of "else if" clauses. ) ((and (not stop-at-boi-only) (/= old-pos old-boi) (memq step-type '(up previous))) ;; If stop-at-boi-only is nil, we shouldn't back up ;; over previous or containing statements to try to ;; reach boi, so go back to the last position and ;; exit. (goto-char old-pos) (throw 'back-up-block nil)) (t (if (and (not stop-at-boi-only) (memq step-type '(up previous beginning))) ;; If we've moved into another statement then we ;; should no longer try to stop in the middle of a ;; line. (setq stop-at-boi-only t)) ;; Record this as a substatement if we skipped up one ;; level. (when (eq step-type 'up) (c-add-syntax 'substatement nil)))) ))) containing-sexp) ;; Now we have to go out of this block. (goto-char containing-sexp) ;; Don't stop in the middle of a special brace list opener ;; like "({". (when c-special-brace-lists (let ((special-list (c-looking-at-special-brace-list))) (when (and special-list (< (car (car special-list)) (point))) (setq containing-sexp (car (car special-list))) (goto-char containing-sexp)))) (setq paren-state (c-whack-state-after containing-sexp paren-state) containing-sexp (c-most-enclosing-brace paren-state) boi (c-point 'boi)) ;; Analyze the construct in front of the block we've stepped out ;; from and add the right syntactic element for it. (let ((paren-pos (point)) (paren-char (char-after)) step-type) (if (eq paren-char ?\() ;; Stepped out of a parenthesis block, so we're in an ;; expression now. (progn (when (/= paren-pos boi) (if (and c-recognize-paren-inexpr-blocks (progn (c-backward-syntactic-ws containing-sexp) (or (not (looking-at "\\>")) (not (c-on-identifier)))) (save-excursion (goto-char (1+ paren-pos)) (c-forward-syntactic-ws) (eq (char-after) ?{))) ;; Stepped out of an in-expression statement. This ;; syntactic element won't get an anchor pos. (c-add-syntax 'inexpr-statement) ;; A parenthesis normally belongs to an arglist. (c-add-syntax 'arglist-cont-nonempty nil paren-pos))) (goto-char (max boi (if containing-sexp (1+ containing-sexp) (point-min)))) (setq step-type 'same on-label nil)) (setq step-type (c-beginning-of-statement-1 containing-sexp) on-label (eq step-type 'label)) (if (and (eq step-type 'same) (/= paren-pos (point))) (save-excursion (goto-char paren-pos) (let ((inexpr (c-looking-at-inexpr-block (c-safe-position containing-sexp paren-state) containing-sexp))) (if (and inexpr (not (eq (car inexpr) 'inlambda))) (c-add-syntax 'statement-block-intro nil) (c-add-syntax 'defun-block-intro nil)))) (c-add-syntax 'statement-block-intro nil))) (if (= paren-pos boi) ;; Always done if the open brace was at boi. The ;; c-beginning-of-statement-1 call above is necessary ;; anyway, to decide the type of block-intro to add. (goto-char paren-pos) (setq boi (c-point 'boi))) )) ;; Fill in the current point as the anchor for all the symbols ;; added above. (let ((p c-syntactic-context)) (while (not (eq p syntax-last)) (if (cdr (car p)) (setcar (cdr (car p)) (point))) (setq p (cdr p)))) ))) (defun c-add-class-syntax (symbol containing-decl-open containing-decl-start containing-decl-kwd paren-state) ;; The inclass and class-close syntactic symbols are added in ;; several places and some work is needed to fix everything. ;; Therefore it's collected here. ;; ;; This function might do hidden buffer changes. (goto-char containing-decl-open) (if (and (eq symbol 'inclass) (= (point) (c-point 'boi))) (progn (c-add-syntax symbol containing-decl-open) containing-decl-open) (goto-char containing-decl-start) ;; Ought to use `c-add-stmt-syntax' instead of backing up to boi ;; here, but we have to do like this for compatibility. (back-to-indentation) (c-add-syntax symbol (point)) (if (and (c-keyword-member containing-decl-kwd 'c-inexpr-class-kwds) (/= containing-decl-start (c-point 'boi containing-decl-start))) (c-add-syntax 'inexpr-class)) (point))) (defun c-guess-continued-construct (indent-point char-after-ip beg-of-same-or-containing-stmt containing-sexp paren-state) ;; This function contains the decision tree reached through both ;; cases 18 and 10. It's a continued statement or top level ;; construct of some kind. ;; ;; This function might do hidden buffer changes. (let (special-brace-list) (goto-char indent-point) (skip-chars-forward " \t") (cond ;; (CASE A removed.) ;; CASE B: open braces for class or brace-lists ((setq special-brace-list (or (and c-special-brace-lists (c-looking-at-special-brace-list)) (eq char-after-ip ?{))) (cond ;; CASE B.1: class-open ((save-excursion (and (eq (char-after) ?{) (c-looking-at-decl-block containing-sexp t) (setq beg-of-same-or-containing-stmt (point)))) (c-add-syntax 'class-open beg-of-same-or-containing-stmt)) ;; CASE B.2: brace-list-open ((or (consp special-brace-list) (save-excursion (goto-char beg-of-same-or-containing-stmt) (c-syntactic-re-search-forward "=\\([^=]\\|$\\)" indent-point t t t))) ;; The most semantically accurate symbol here is ;; brace-list-open, but we normally report it simply as a ;; statement-cont. The reason is that one normally adjusts ;; brace-list-open for brace lists as top-level constructs, ;; and brace lists inside statements is a completely different ;; context. C.f. case 5A.3. (c-beginning-of-statement-1 containing-sexp) (c-add-stmt-syntax (if c-auto-newline-analysis ;; Turn off the dwim above when we're ;; analyzing the nature of the brace ;; for the auto newline feature. 'brace-list-open 'statement-cont) nil nil containing-sexp paren-state)) ;; CASE B.3: The body of a function declared inside a normal ;; block. Can occur e.g. in Pike and when using gcc ;; extensions, but watch out for macros followed by blocks. ;; C.f. cases E, 16F and 17G. ((and (not (c-at-statement-start-p)) (eq (c-beginning-of-statement-1 containing-sexp nil nil t) 'same) (save-excursion (let ((c-recognize-typeless-decls nil)) ;; Turn off recognition of constructs that lacks a ;; type in this case, since that's more likely to be ;; a macro followed by a block. (c-forward-decl-or-cast-1 (c-point 'bosws) nil nil)))) (c-add-stmt-syntax 'defun-open nil t containing-sexp paren-state)) ;; CASE B.4: Continued statement with block open. The most ;; accurate analysis is perhaps `statement-cont' together with ;; `block-open' but we play DWIM and use `substatement-open' ;; instead. The rationaly is that this typically is a macro ;; followed by a block which makes it very similar to a ;; statement with a substatement block. (t (c-add-stmt-syntax 'substatement-open nil nil containing-sexp paren-state)) )) ;; CASE C: iostream insertion or extraction operator ((and (looking-at "\\(<<\\|>>\\)\\([^=]\\|$\\)") (save-excursion (goto-char beg-of-same-or-containing-stmt) ;; If there is no preceding streamop in the statement ;; then indent this line as a normal statement-cont. (when (c-syntactic-re-search-forward "\\(<<\\|>>\\)\\([^=]\\|$\\)" indent-point 'move t t) (c-add-syntax 'stream-op (c-point 'boi)) t)))) ;; CASE E: In the "K&R region" of a function declared inside a ;; normal block. C.f. case B.3. ((and (save-excursion ;; Check that the next token is a '{'. This works as ;; long as no language that allows nested function ;; definitions allows stuff like member init lists, K&R ;; declarations or throws clauses there. ;; ;; Note that we do a forward search for something ahead ;; of the indentation line here. That's not good since ;; the user might not have typed it yet. Unfortunately ;; it's exceedingly tricky to recognize a function ;; prototype in a code block without resorting to this. (c-forward-syntactic-ws) (eq (char-after) ?{)) (not (c-at-statement-start-p)) (eq (c-beginning-of-statement-1 containing-sexp nil nil t) 'same) (save-excursion (let ((c-recognize-typeless-decls nil)) ;; Turn off recognition of constructs that lacks a ;; type in this case, since that's more likely to be ;; a macro followed by a block. (c-forward-decl-or-cast-1 (c-point 'bosws) nil nil)))) (c-add-stmt-syntax 'func-decl-cont nil t containing-sexp paren-state)) ;; CASE D: continued statement. (t (c-beginning-of-statement-1 containing-sexp) (c-add-stmt-syntax 'statement-cont nil nil containing-sexp paren-state)) ))) ;; The next autoload was added by RMS on 2005/8/9 - don't know why (ACM, ;; 2005/11/29). ;;;###autoload (defun c-guess-basic-syntax () "Return the syntactic context of the current line." (save-excursion (beginning-of-line) (c-save-buffer-state ((indent-point (point)) (case-fold-search nil) ;; A whole ugly bunch of various temporary variables. Have ;; to declare them here since it's not possible to declare ;; a variable with only the scope of a cond test and the ;; following result clauses, and most of this function is a ;; single gigantic cond. :P literal char-before-ip before-ws-ip char-after-ip macro-start in-macro-expr c-syntactic-context placeholder c-in-literal-cache step-type tmpsymbol keyword injava-inher special-brace-list tmp-pos ;; The following record some positions for the containing ;; declaration block if we're directly within one: ;; `containing-decl-open' is the position of the open ;; brace. `containing-decl-start' is the start of the ;; declaration. `containing-decl-kwd' is the keyword ;; symbol of the keyword that tells what kind of block it ;; is. containing-decl-open containing-decl-start containing-decl-kwd ;; The open paren of the closest surrounding sexp or nil if ;; there is none. containing-sexp ;; The position after the closest preceding brace sexp ;; (nested sexps are ignored), or the position after ;; `containing-sexp' if there is none, or (point-min) if ;; `containing-sexp' is nil. lim ;; The paren state outside `containing-sexp', or at ;; `indent-point' if `containing-sexp' is nil. (paren-state (c-parse-state)) ;; There's always at most one syntactic element which got ;; an anchor pos. It's stored in syntactic-relpos. syntactic-relpos (c-stmt-delim-chars c-stmt-delim-chars)) ;; Check if we're directly inside an enclosing declaration ;; level block. (when (and (setq containing-sexp (c-most-enclosing-brace paren-state)) (progn (goto-char containing-sexp) (eq (char-after) ?{)) (setq placeholder (c-looking-at-decl-block (c-most-enclosing-brace paren-state containing-sexp) t))) (setq containing-decl-open containing-sexp containing-decl-start (point) containing-sexp nil) (goto-char placeholder) (setq containing-decl-kwd (and (looking-at c-keywords-regexp) (c-keyword-sym (match-string 1))))) ;; Init some position variables. (if c-state-cache (progn (setq containing-sexp (car paren-state) paren-state (cdr paren-state)) (if (consp containing-sexp) (progn (setq lim (cdr containing-sexp)) (if (cdr c-state-cache) ;; Ignore balanced paren. The next entry ;; can't be another one. (setq containing-sexp (car (cdr c-state-cache)) paren-state (cdr paren-state)) ;; If there is no surrounding open paren then ;; put the last balanced pair back on paren-state. (setq paren-state (cons containing-sexp paren-state) containing-sexp nil))) (setq lim (1+ containing-sexp)))) (setq lim (point-min))) ;; If we're in a parenthesis list then ',' delimits the ;; "statements" rather than being an operator (with the ;; exception of the "for" clause). This difference is ;; typically only noticeable when statements are used in macro ;; arglists. (when (and containing-sexp (eq (char-after containing-sexp) ?\()) (setq c-stmt-delim-chars c-stmt-delim-chars-with-comma)) ;; cache char before and after indent point, and move point to ;; the most likely position to perform the majority of tests (goto-char indent-point) (c-backward-syntactic-ws lim) (setq before-ws-ip (point) char-before-ip (char-before)) (goto-char indent-point) (skip-chars-forward " \t") (setq char-after-ip (char-after)) ;; are we in a literal? (setq literal (c-in-literal lim)) ;; now figure out syntactic qualities of the current line (cond ;; CASE 1: in a string. ((eq literal 'string) (c-add-syntax 'string (c-point 'bopl))) ;; CASE 2: in a C or C++ style comment. ((and (memq literal '(c c++)) ;; This is a kludge for XEmacs where we use ;; `buffer-syntactic-context', which doesn't correctly ;; recognize "\*/" to end a block comment. ;; `parse-partial-sexp' which is used by ;; `c-literal-limits' will however do that in most ;; versions, which results in that we get nil from ;; `c-literal-limits' even when `c-in-literal' claims ;; we're inside a comment. (setq placeholder (c-literal-limits lim))) (c-add-syntax literal (car placeholder))) ;; CASE 3: in a cpp preprocessor macro continuation. ((and (save-excursion (when (c-beginning-of-macro) (setq macro-start (point)))) (/= macro-start (c-point 'boi)) (progn (setq tmpsymbol 'cpp-macro-cont) (or (not c-syntactic-indentation-in-macros) (save-excursion (goto-char macro-start) ;; If at the beginning of the body of a #define ;; directive then analyze as cpp-define-intro ;; only. Go on with the syntactic analysis ;; otherwise. in-macro-expr is set if we're in a ;; cpp expression, i.e. before the #define body ;; or anywhere in a non-#define directive. (if (c-forward-to-cpp-define-body) (let ((indent-boi (c-point 'boi indent-point))) (setq in-macro-expr (> (point) indent-boi) tmpsymbol 'cpp-define-intro) (= (point) indent-boi)) (setq in-macro-expr t) nil))))) (c-add-syntax tmpsymbol macro-start) (setq macro-start nil)) ;; CASE 11: an else clause? ((looking-at "else\\>[^_]") (c-beginning-of-statement-1 containing-sexp) (c-add-stmt-syntax 'else-clause nil t containing-sexp paren-state)) ;; CASE 12: while closure of a do/while construct? ((and (looking-at "while\\>[^_]") (save-excursion (prog1 (eq (c-beginning-of-statement-1 containing-sexp) 'beginning) (setq placeholder (point))))) (goto-char placeholder) (c-add-stmt-syntax 'do-while-closure nil t containing-sexp paren-state)) ;; CASE 13: A catch or finally clause? This case is simpler ;; than if-else and do-while, because a block is required ;; after every try, catch and finally. ((save-excursion (and (cond ((c-major-mode-is 'c++-mode) (looking-at "catch\\>[^_]")) ((c-major-mode-is 'java-mode) (looking-at "\\(catch\\|finally\\)\\>[^_]"))) (and (c-safe (c-backward-syntactic-ws) (c-backward-sexp) t) (eq (char-after) ?{) (c-safe (c-backward-syntactic-ws) (c-backward-sexp) t) (if (eq (char-after) ?\() (c-safe (c-backward-sexp) t) t)) (looking-at "\\(try\\|catch\\)\\>[^_]") (setq placeholder (point)))) (goto-char placeholder) (c-add-stmt-syntax 'catch-clause nil t containing-sexp paren-state)) ;; CASE 18: A substatement we can recognize by keyword. ((save-excursion (and c-opt-block-stmt-key (not (eq char-before-ip ?\;)) (not (c-at-vsemi-p before-ws-ip)) (not (memq char-after-ip '(?\) ?\] ?,))) (or (not (eq char-before-ip ?})) (c-looking-at-inexpr-block-backward c-state-cache)) (> (point) (progn ;; Ought to cache the result from the ;; c-beginning-of-statement-1 calls here. (setq placeholder (point)) (while (eq (setq step-type (c-beginning-of-statement-1 lim)) 'label)) (if (eq step-type 'previous) (goto-char placeholder) (setq placeholder (point)) (if (and (eq step-type 'same) (not (looking-at c-opt-block-stmt-key))) ;; Step up to the containing statement if we ;; stayed in the same one. (let (step) (while (eq (setq step (c-beginning-of-statement-1 lim)) 'label)) (if (eq step 'up) (setq placeholder (point)) ;; There was no containing statement afterall. (goto-char placeholder))))) placeholder)) (if (looking-at c-block-stmt-2-key) ;; Require a parenthesis after these keywords. ;; Necessary to catch e.g. synchronized in Java, ;; which can be used both as statement and ;; modifier. (and (zerop (c-forward-token-2 1 nil)) (eq (char-after) ?\()) (looking-at c-opt-block-stmt-key)))) (if (eq step-type 'up) ;; CASE 18A: Simple substatement. (progn (goto-char placeholder) (cond ((eq char-after-ip ?{) (c-add-stmt-syntax 'substatement-open nil nil containing-sexp paren-state)) ((save-excursion (goto-char indent-point) (back-to-indentation) (c-forward-label)) (c-add-stmt-syntax 'substatement-label nil nil containing-sexp paren-state)) (t (c-add-stmt-syntax 'substatement nil nil containing-sexp paren-state)))) ;; CASE 18B: Some other substatement. This is shared ;; with case 10. (c-guess-continued-construct indent-point char-after-ip placeholder lim paren-state))) ;; CASE 14: A case or default label ((looking-at c-label-kwds-regexp) (if containing-sexp (progn (goto-char containing-sexp) (setq lim (c-most-enclosing-brace c-state-cache containing-sexp)) (c-backward-to-block-anchor lim) (c-add-stmt-syntax 'case-label nil t lim paren-state)) ;; Got a bogus label at the top level. In lack of better ;; alternatives, anchor it on (point-min). (c-add-syntax 'case-label (point-min)))) ;; CASE 15: any other label ((save-excursion (back-to-indentation) (and (not (looking-at c-syntactic-ws-start)) (c-forward-label))) (cond (containing-decl-open (setq placeholder (c-add-class-syntax 'inclass containing-decl-open containing-decl-start containing-decl-kwd paren-state)) ;; Append access-label with the same anchor point as ;; inclass gets. (c-append-syntax 'access-label placeholder)) (containing-sexp (goto-char containing-sexp) (setq lim (c-most-enclosing-brace c-state-cache containing-sexp)) (save-excursion (setq tmpsymbol (if (and (eq (c-beginning-of-statement-1 lim) 'up) (looking-at "switch\\>[^_]")) ;; If the surrounding statement is a switch then ;; let's analyze all labels as switch labels, so ;; that they get lined up consistently. 'case-label 'label))) (c-backward-to-block-anchor lim) (c-add-stmt-syntax tmpsymbol nil t lim paren-state)) (t ;; A label on the top level. Treat it as a class ;; context. (point-min) is the closest we get to the ;; class open brace. (c-add-syntax 'access-label (point-min))))) ;; CASE 4: In-expression statement. C.f. cases 7B, 16A and ;; 17E. ((setq placeholder (c-looking-at-inexpr-block (c-safe-position containing-sexp paren-state) containing-sexp ;; Have to turn on the heuristics after ;; the point even though it doesn't work ;; very well. C.f. test case class-16.pike. t)) (setq tmpsymbol (assq (car placeholder) '((inexpr-class . class-open) (inexpr-statement . block-open)))) (if tmpsymbol ;; It's a statement block or an anonymous class. (setq tmpsymbol (cdr tmpsymbol)) ;; It's a Pike lambda. Check whether we are between the ;; lambda keyword and the argument list or at the defun ;; opener. (setq tmpsymbol (if (eq char-after-ip ?{) 'inline-open 'lambda-intro-cont))) (goto-char (cdr placeholder)) (back-to-indentation) (c-add-stmt-syntax tmpsymbol nil t (c-most-enclosing-brace c-state-cache (point)) paren-state) (unless (eq (point) (cdr placeholder)) (c-add-syntax (car placeholder)))) ;; CASE 5: Line is inside a declaration level block or at top level. ((or containing-decl-open (null containing-sexp)) (cond ;; CASE 5A: we are looking at a defun, brace list, class, ;; or inline-inclass method opening brace ((setq special-brace-list (or (and c-special-brace-lists (c-looking-at-special-brace-list)) (eq char-after-ip ?{))) (cond ;; CASE 5A.1: Non-class declaration block open. ((save-excursion (let (tmp) (and (eq char-after-ip ?{) (setq tmp (c-looking-at-decl-block containing-sexp t)) (progn (setq placeholder (point)) (goto-char tmp) (looking-at c-symbol-key)) (c-keyword-member (c-keyword-sym (setq keyword (match-string 0))) 'c-other-block-decl-kwds)))) (goto-char placeholder) (c-add-stmt-syntax (if (string-equal keyword "extern") ;; Special case for extern-lang-open. 'extern-lang-open (intern (concat keyword "-open"))) nil t containing-sexp paren-state)) ;; CASE 5A.2: we are looking at a class opening brace ((save-excursion (goto-char indent-point) (skip-chars-forward " \t") (and (eq (char-after) ?{) (c-looking-at-decl-block containing-sexp t) (setq placeholder (point)))) (c-add-syntax 'class-open placeholder)) ;; CASE 5A.3: brace list open ((save-excursion (c-beginning-of-decl-1 lim) (while (looking-at c-specifier-key) (goto-char (match-end 1)) (c-forward-syntactic-ws indent-point)) (setq placeholder (c-point 'boi)) (or (consp special-brace-list) (and (or (save-excursion (goto-char indent-point) (setq tmpsymbol nil) (while (and (> (point) placeholder) (zerop (c-backward-token-2 1 t)) (/= (char-after) ?=)) (and c-opt-inexpr-brace-list-key (not tmpsymbol) (looking-at c-opt-inexpr-brace-list-key) (setq tmpsymbol 'topmost-intro-cont))) (eq (char-after) ?=)) (looking-at c-brace-list-key)) (save-excursion (while (and (< (point) indent-point) (zerop (c-forward-token-2 1 t)) (not (memq (char-after) '(?\; ?\())))) (not (memq (char-after) '(?\; ?\())) )))) (if (and (not c-auto-newline-analysis) (c-major-mode-is 'java-mode) (eq tmpsymbol 'topmost-intro-cont)) ;; We're in Java and have found that the open brace ;; belongs to a "new Foo[]" initialization list, ;; which means the brace list is part of an ;; expression and not a top level definition. We ;; therefore treat it as any topmost continuation ;; even though the semantically correct symbol still ;; is brace-list-open, on the same grounds as in ;; case B.2. (progn (c-beginning-of-statement-1 lim) (c-add-syntax 'topmost-intro-cont (c-point 'boi))) (c-add-syntax 'brace-list-open placeholder))) ;; CASE 5A.4: inline defun open ((and containing-decl-open (not (c-keyword-member containing-decl-kwd 'c-other-block-decl-kwds))) (c-add-syntax 'inline-open) (c-add-class-syntax 'inclass containing-decl-open containing-decl-start containing-decl-kwd paren-state)) ;; CASE 5A.5: ordinary defun open (t (goto-char placeholder) (if (or containing-decl-open macro-start) (c-add-syntax 'defun-open (c-point 'boi)) ;; Bogus to use bol here, but it's the legacy. (c-add-syntax 'defun-open (c-point 'bol))) ))) ;; CASE 5B: After a function header but before the body (or ;; the ending semicolon if there's no body). ((save-excursion (when (setq placeholder (c-just-after-func-arglist-p lim)) (setq tmp-pos (point)))) (cond ;; CASE 5B.1: Member init list. ((eq (char-after tmp-pos) ?:) (if (or (> tmp-pos indent-point) (= (c-point 'bosws) (1+ tmp-pos))) (progn ;; There is no preceding member init clause. ;; Indent relative to the beginning of indentation ;; for the topmost-intro line that contains the ;; prototype's open paren. (goto-char placeholder) (c-add-syntax 'member-init-intro (c-point 'boi))) ;; Indent relative to the first member init clause. (goto-char (1+ tmp-pos)) (c-forward-syntactic-ws) (c-add-syntax 'member-init-cont (point)))) ;; CASE 5B.2: K&R arg decl intro ((and c-recognize-knr-p (c-in-knr-argdecl lim)) (c-beginning-of-statement-1 lim) (c-add-syntax 'knr-argdecl-intro (c-point 'boi)) (if containing-decl-open (c-add-class-syntax 'inclass containing-decl-open containing-decl-start containing-decl-kwd paren-state))) ;; CASE 5B.4: Nether region after a C++ or Java func ;; decl, which could include a `throws' declaration. (t (c-beginning-of-statement-1 lim) (c-add-syntax 'func-decl-cont (c-point 'boi)) ))) ;; CASE 5C: inheritance line. could be first inheritance ;; line, or continuation of a multiple inheritance ((or (and (c-major-mode-is 'c++-mode) (progn (when (eq char-after-ip ?,) (skip-chars-forward " \t") (forward-char)) (looking-at c-opt-postfix-decl-spec-key))) (and (or (eq char-before-ip ?:) ;; watch out for scope operator (save-excursion (and (eq char-after-ip ?:) (c-safe (forward-char 1) t) (not (eq (char-after) ?:)) ))) (save-excursion (c-backward-syntactic-ws lim) (if (eq char-before-ip ?:) (progn (forward-char -1) (c-backward-syntactic-ws lim))) (back-to-indentation) (looking-at c-class-key))) ;; for Java (and (c-major-mode-is 'java-mode) (let ((fence (save-excursion (c-beginning-of-statement-1 lim) (point))) cont done) (save-excursion (while (not done) (cond ((looking-at c-opt-postfix-decl-spec-key) (setq injava-inher (cons cont (point)) done t)) ((or (not (c-safe (c-forward-sexp -1) t)) (<= (point) fence)) (setq done t)) ) (setq cont t))) injava-inher) (not (c-crosses-statement-barrier-p (cdr injava-inher) (point))) )) (cond ;; CASE 5C.1: non-hanging colon on an inher intro ((eq char-after-ip ?:) (c-beginning-of-statement-1 lim) (c-add-syntax 'inher-intro (c-point 'boi)) ;; don't add inclass symbol since relative point already ;; contains any class offset ) ;; CASE 5C.2: hanging colon on an inher intro ((eq char-before-ip ?:) (c-beginning-of-statement-1 lim) (c-add-syntax 'inher-intro (c-point 'boi)) (if containing-decl-open (c-add-class-syntax 'inclass containing-decl-open containing-decl-start containing-decl-kwd paren-state))) ;; CASE 5C.3: in a Java implements/extends (injava-inher (let ((where (cdr injava-inher)) (cont (car injava-inher))) (goto-char where) (cond ((looking-at "throws\\>[^_]") (c-add-syntax 'func-decl-cont (progn (c-beginning-of-statement-1 lim) (c-point 'boi)))) (cont (c-add-syntax 'inher-cont where)) (t (c-add-syntax 'inher-intro (progn (goto-char (cdr injava-inher)) (c-beginning-of-statement-1 lim) (point)))) ))) ;; CASE 5C.4: a continued inheritance line (t (c-beginning-of-inheritance-list lim) (c-add-syntax 'inher-cont (point)) ;; don't add inclass symbol since relative point already ;; contains any class offset ))) ;; CASE 5D: this could be a top-level initialization, a ;; member init list continuation, or a template argument ;; list continuation. ((save-excursion ;; Note: We use the fact that lim always is after any ;; preceding brace sexp. (if c-recognize-<>-arglists (while (and (progn (c-syntactic-skip-backward "^;,=<>" lim t) (> (point) lim)) (or (when c-overloadable-operators-regexp (when (setq placeholder (c-after-special-operator-id lim)) (goto-char placeholder) t)) (cond ((eq (char-before) ?>) (or (c-backward-<>-arglist nil lim) (backward-char)) t) ((eq (char-before) ?<) (backward-char) (if (save-excursion (c-forward-<>-arglist nil)) (progn (forward-char) nil) t)) (t nil))))) ;; NB: No c-after-special-operator-id stuff in this ;; clause - we assume only C++ needs it. (c-syntactic-skip-backward "^;,=" lim t)) (memq (char-before) '(?, ?= ?<))) (cond ;; CASE 5D.3: perhaps a template list continuation? ((and (c-major-mode-is 'c++-mode) (save-excursion (save-restriction (c-with-syntax-table c++-template-syntax-table (goto-char indent-point) (setq placeholder (c-up-list-backward)) (and placeholder (eq (char-after placeholder) ?<)))))) (c-with-syntax-table c++-template-syntax-table (goto-char placeholder) (c-beginning-of-statement-1 lim t) (if (save-excursion (c-backward-syntactic-ws lim) (eq (char-before) ?<)) ;; In a nested template arglist. (progn (goto-char placeholder) (c-syntactic-skip-backward "^,;" lim t) (c-forward-syntactic-ws)) (back-to-indentation))) ;; FIXME: Should use c-add-stmt-syntax, but it's not yet ;; template aware. (c-add-syntax 'template-args-cont (point))) ;; CASE 5D.4: perhaps a multiple inheritance line? ((and (c-major-mode-is 'c++-mode) (save-excursion (c-beginning-of-statement-1 lim) (setq placeholder (point)) (if (looking-at "static\\>[^_]") (c-forward-token-2 1 nil indent-point)) (and (looking-at c-class-key) (zerop (c-forward-token-2 2 nil indent-point)) (if (eq (char-after) ?<) (c-with-syntax-table c++-template-syntax-table (zerop (c-forward-token-2 1 t indent-point))) t) (eq (char-after) ?:)))) (goto-char placeholder) (c-add-syntax 'inher-cont (c-point 'boi))) ;; CASE 5D.5: Continuation of the "expression part" of a ;; top level construct. (t (while (and (eq (car (c-beginning-of-decl-1 containing-sexp)) 'same) (save-excursion (c-backward-syntactic-ws) (eq (char-before) ?})))) (c-add-stmt-syntax (if (eq char-before-ip ?,) ;; A preceding comma at the top level means that a ;; new variable declaration starts here. Use ;; topmost-intro-cont for it, for consistency with ;; the first variable declaration. C.f. case 5N. 'topmost-intro-cont 'statement-cont) nil nil containing-sexp paren-state)) )) ;; CASE 5F: Close of a non-class declaration level block. ((and (eq char-after-ip ?}) (c-keyword-member containing-decl-kwd 'c-other-block-decl-kwds)) ;; This is inconsistent: Should use `containing-decl-open' ;; here if it's at boi, like in case 5J. (goto-char containing-decl-start) (c-add-stmt-syntax (if (string-equal (symbol-name containing-decl-kwd) "extern") ;; Special case for compatibility with the ;; extern-lang syntactic symbols. 'extern-lang-close (intern (concat (symbol-name containing-decl-kwd) "-close"))) nil t (c-most-enclosing-brace paren-state (point)) paren-state)) ;; CASE 5G: we are looking at the brace which closes the ;; enclosing nested class decl ((and containing-sexp (eq char-after-ip ?}) (eq containing-decl-open containing-sexp)) (c-add-class-syntax 'class-close containing-decl-open containing-decl-start containing-decl-kwd paren-state)) ;; CASE 5H: we could be looking at subsequent knr-argdecls ((and c-recognize-knr-p (not (eq char-before-ip ?})) (save-excursion (setq placeholder (cdr (c-beginning-of-decl-1 lim))) (and placeholder ;; Do an extra check to avoid tripping up on ;; statements that occur in invalid contexts ;; (e.g. in macro bodies where we don't really ;; know the context of what we're looking at). (not (and c-opt-block-stmt-key (looking-at c-opt-block-stmt-key))))) (< placeholder indent-point)) (goto-char placeholder) (c-add-syntax 'knr-argdecl (point))) ;; CASE 5I: ObjC method definition. ((and c-opt-method-key (looking-at c-opt-method-key)) (c-beginning-of-statement-1 nil t) (if (= (point) indent-point) ;; Handle the case when it's the first (non-comment) ;; thing in the buffer. Can't look for a 'same return ;; value from cbos1 since ObjC directives currently ;; aren't recognized fully, so that we get 'same ;; instead of 'previous if it moved over a preceding ;; directive. (goto-char (point-min))) (c-add-syntax 'objc-method-intro (c-point 'boi))) ;; CASE 5P: AWK pattern or function or continuation ;; thereof. ((c-major-mode-is 'awk-mode) (setq placeholder (point)) (c-add-stmt-syntax (if (and (eq (c-beginning-of-statement-1) 'same) (/= (point) placeholder)) 'topmost-intro-cont 'topmost-intro) nil nil containing-sexp paren-state)) ;; CASE 5N: At a variable declaration that follows a class ;; definition or some other block declaration that doesn't ;; end at the closing '}'. C.f. case 5D.5. ((progn (c-backward-syntactic-ws lim) (and (eq (char-before) ?}) (save-excursion (let ((start (point))) (if (and c-state-cache (consp (car c-state-cache)) (eq (cdar c-state-cache) (point))) ;; Speed up the backward search a bit. (goto-char (caar c-state-cache))) (c-beginning-of-decl-1 containing-sexp) (setq placeholder (point)) (if (= start (point)) ;; The '}' is unbalanced. nil (c-end-of-decl-1) (>= (point) indent-point)))))) (goto-char placeholder) (c-add-stmt-syntax 'topmost-intro-cont nil nil containing-sexp paren-state)) ;; NOTE: The point is at the end of the previous token here. ;; CASE 5J: we are at the topmost level, make ;; sure we skip back past any access specifiers ((and ;; A macro continuation line is never at top level. (not (and macro-start (> indent-point macro-start))) (save-excursion (setq placeholder (point)) (or (memq char-before-ip '(?\; ?{ ?} nil)) (c-at-vsemi-p before-ws-ip) (when (and (eq char-before-ip ?:) (eq (c-beginning-of-statement-1 lim) 'label)) (c-backward-syntactic-ws lim) (setq placeholder (point))) (and (c-major-mode-is 'objc-mode) (catch 'not-in-directive (c-beginning-of-statement-1 lim) (setq placeholder (point)) (while (and (c-forward-objc-directive) (< (point) indent-point)) (c-forward-syntactic-ws) (if (>= (point) indent-point) (throw 'not-in-directive t)) (setq placeholder (point))) nil))))) ;; For historic reasons we anchor at bol of the last ;; line of the previous declaration. That's clearly ;; highly bogus and useless, and it makes our lives hard ;; to remain compatible. :P (goto-char placeholder) (c-add-syntax 'topmost-intro (c-point 'bol)) (if containing-decl-open (if (c-keyword-member containing-decl-kwd 'c-other-block-decl-kwds) (progn (goto-char containing-decl-open) (unless (= (point) (c-point 'boi)) (goto-char containing-decl-start)) (c-add-stmt-syntax (if (string-equal (symbol-name containing-decl-kwd) "extern") ;; Special case for compatibility with the ;; extern-lang syntactic symbols. 'inextern-lang (intern (concat "in" (symbol-name containing-decl-kwd)))) nil t (c-most-enclosing-brace paren-state (point)) paren-state)) (c-add-class-syntax 'inclass containing-decl-open containing-decl-start containing-decl-kwd paren-state))) (when (and c-syntactic-indentation-in-macros macro-start (/= macro-start (c-point 'boi indent-point))) (c-add-syntax 'cpp-define-intro) (setq macro-start nil))) ;; CASE 5K: we are at an ObjC method definition ;; continuation line. ((and c-opt-method-key (save-excursion (c-beginning-of-statement-1 lim) (beginning-of-line) (when (looking-at c-opt-method-key) (setq placeholder (point))))) (c-add-syntax 'objc-method-args-cont placeholder)) ;; CASE 5L: we are at the first argument of a template ;; arglist that begins on the previous line. ((and c-recognize-<>-arglists (eq (char-before) ?<) (not (and c-overloadable-operators-regexp (c-after-special-operator-id lim)))) (c-beginning-of-statement-1 (c-safe-position (point) paren-state)) (c-add-syntax 'template-args-cont (c-point 'boi))) ;; CASE 5Q: we are at a statement within a macro. (macro-start (c-beginning-of-statement-1 containing-sexp) (c-add-stmt-syntax 'statement nil t containing-sexp paren-state)) ;; CASE 5M: we are at a topmost continuation line (t (c-beginning-of-statement-1 (c-safe-position (point) paren-state)) (when (c-major-mode-is 'objc-mode) (setq placeholder (point)) (while (and (c-forward-objc-directive) (< (point) indent-point)) (c-forward-syntactic-ws) (setq placeholder (point))) (goto-char placeholder)) (c-add-syntax 'topmost-intro-cont (c-point 'boi))) )) ;; (CASE 6 has been removed.) ;; CASE 7: line is an expression, not a statement. Most ;; likely we are either in a function prototype or a function ;; call argument list ((not (or (and c-special-brace-lists (save-excursion (goto-char containing-sexp) (c-looking-at-special-brace-list))) (eq (char-after containing-sexp) ?{))) (cond ;; CASE 7A: we are looking at the arglist closing paren. ;; C.f. case 7F. ((memq char-after-ip '(?\) ?\])) (goto-char containing-sexp) (setq placeholder (c-point 'boi)) (if (and (c-safe (backward-up-list 1) t) (>= (point) placeholder)) (progn (forward-char) (skip-chars-forward " \t")) (goto-char placeholder)) (c-add-stmt-syntax 'arglist-close (list containing-sexp) t (c-most-enclosing-brace paren-state (point)) paren-state)) ;; CASE 7B: Looking at the opening brace of an ;; in-expression block or brace list. C.f. cases 4, 16A ;; and 17E. ((and (eq char-after-ip ?{) (progn (setq placeholder (c-inside-bracelist-p (point) paren-state)) (if placeholder (setq tmpsymbol '(brace-list-open . inexpr-class)) (setq tmpsymbol '(block-open . inexpr-statement) placeholder (cdr-safe (c-looking-at-inexpr-block (c-safe-position containing-sexp paren-state) containing-sexp))) ;; placeholder is nil if it's a block directly in ;; a function arglist. That makes us skip out of ;; this case. ))) (goto-char placeholder) (back-to-indentation) (c-add-stmt-syntax (car tmpsymbol) nil t (c-most-enclosing-brace paren-state (point)) paren-state) (if (/= (point) placeholder) (c-add-syntax (cdr tmpsymbol)))) ;; CASE 7C: we are looking at the first argument in an empty ;; argument list. Use arglist-close if we're actually ;; looking at a close paren or bracket. ((memq char-before-ip '(?\( ?\[)) (goto-char containing-sexp) (setq placeholder (c-point 'boi)) (if (and (c-safe (backward-up-list 1) t) (>= (point) placeholder)) (progn (forward-char) (skip-chars-forward " \t")) (goto-char placeholder)) (c-add-stmt-syntax 'arglist-intro (list containing-sexp) t (c-most-enclosing-brace paren-state (point)) paren-state)) ;; CASE 7D: we are inside a conditional test clause. treat ;; these things as statements ((progn (goto-char containing-sexp) (and (c-safe (c-forward-sexp -1) t) (looking-at "\\[^_]"))) (goto-char (1+ containing-sexp)) (c-forward-syntactic-ws indent-point) (if (eq char-before-ip ?\;) (c-add-syntax 'statement (point)) (c-add-syntax 'statement-cont (point)) )) ;; CASE 7E: maybe a continued ObjC method call. This is the ;; case when we are inside a [] bracketed exp, and what ;; precede the opening bracket is not an identifier. ((and c-opt-method-key (eq (char-after containing-sexp) ?\[) (progn (goto-char (1- containing-sexp)) (c-backward-syntactic-ws (c-point 'bod)) (if (not (looking-at c-symbol-key)) (c-add-syntax 'objc-method-call-cont containing-sexp)) ))) ;; CASE 7F: we are looking at an arglist continuation line, ;; but the preceding argument is on the same line as the ;; opening paren. This case includes multi-line ;; mathematical paren groupings, but we could be on a ;; for-list continuation line. C.f. case 7A. ((progn (goto-char (1+ containing-sexp)) (< (save-excursion (c-forward-syntactic-ws) (point)) (c-point 'bonl))) (goto-char containing-sexp) (setq placeholder (c-point 'boi)) (if (and (c-safe (backward-up-list 1) t) (>= (point) placeholder)) (progn (forward-char) (skip-chars-forward " \t")) (goto-char placeholder)) (c-add-stmt-syntax 'arglist-cont-nonempty (list containing-sexp) t (c-most-enclosing-brace c-state-cache (point)) paren-state)) ;; CASE 7G: we are looking at just a normal arglist ;; continuation line (t (c-forward-syntactic-ws indent-point) (c-add-syntax 'arglist-cont (c-point 'boi))) )) ;; CASE 8: func-local multi-inheritance line ((and (c-major-mode-is 'c++-mode) (save-excursion (goto-char indent-point) (skip-chars-forward " \t") (looking-at c-opt-postfix-decl-spec-key))) (goto-char indent-point) (skip-chars-forward " \t") (cond ;; CASE 8A: non-hanging colon on an inher intro ((eq char-after-ip ?:) (c-backward-syntactic-ws lim) (c-add-syntax 'inher-intro (c-point 'boi))) ;; CASE 8B: hanging colon on an inher intro ((eq char-before-ip ?:) (c-add-syntax 'inher-intro (c-point 'boi))) ;; CASE 8C: a continued inheritance line (t (c-beginning-of-inheritance-list lim) (c-add-syntax 'inher-cont (point)) ))) ;; CASE 9: we are inside a brace-list ((and (not (c-major-mode-is 'awk-mode)) ; Maybe this isn't needed (ACM, 2002/3/29) (setq special-brace-list (or (and c-special-brace-lists ;;;; ALWAYS NIL FOR AWK!! (save-excursion (goto-char containing-sexp) (c-looking-at-special-brace-list))) (c-inside-bracelist-p containing-sexp paren-state)))) (cond ;; CASE 9A: In the middle of a special brace list opener. ((and (consp special-brace-list) (save-excursion (goto-char containing-sexp) (eq (char-after) ?\()) (eq char-after-ip (car (cdr special-brace-list)))) (goto-char (car (car special-brace-list))) (skip-chars-backward " \t") (if (and (bolp) (assoc 'statement-cont (setq placeholder (c-guess-basic-syntax)))) (setq c-syntactic-context placeholder) (c-beginning-of-statement-1 (c-safe-position (1- containing-sexp) paren-state)) (c-forward-token-2 0) (while (looking-at c-specifier-key) (goto-char (match-end 1)) (c-forward-syntactic-ws)) (c-add-syntax 'brace-list-open (c-point 'boi)))) ;; CASE 9B: brace-list-close brace ((if (consp special-brace-list) ;; Check special brace list closer. (progn (goto-char (car (car special-brace-list))) (save-excursion (goto-char indent-point) (back-to-indentation) (or ;; We were between the special close char and the `)'. (and (eq (char-after) ?\)) (eq (1+ (point)) (cdr (car special-brace-list)))) ;; We were before the special close char. (and (eq (char-after) (cdr (cdr special-brace-list))) (zerop (c-forward-token-2)) (eq (1+ (point)) (cdr (car special-brace-list))))))) ;; Normal brace list check. (and (eq char-after-ip ?}) (c-safe (goto-char (c-up-list-backward (point))) t) (= (point) containing-sexp))) (if (eq (point) (c-point 'boi)) (c-add-syntax 'brace-list-close (point)) (setq lim (c-most-enclosing-brace c-state-cache (point))) (c-beginning-of-statement-1 lim) (c-add-stmt-syntax 'brace-list-close nil t lim paren-state))) (t ;; Prepare for the rest of the cases below by going to the ;; token following the opening brace (if (consp special-brace-list) (progn (goto-char (car (car special-brace-list))) (c-forward-token-2 1 nil indent-point)) (goto-char containing-sexp)) (forward-char) (let ((start (point))) (c-forward-syntactic-ws indent-point) (goto-char (max start (c-point 'bol)))) (c-skip-ws-forward indent-point) (cond ;; CASE 9C: we're looking at the first line in a brace-list ((= (point) indent-point) (if (consp special-brace-list) (goto-char (car (car special-brace-list))) (goto-char containing-sexp)) (if (eq (point) (c-point 'boi)) (c-add-syntax 'brace-list-intro (point)) (setq lim (c-most-enclosing-brace c-state-cache (point))) (c-beginning-of-statement-1 lim) (c-add-stmt-syntax 'brace-list-intro nil t lim paren-state))) ;; CASE 9D: this is just a later brace-list-entry or ;; brace-entry-open (t (if (or (eq char-after-ip ?{) (and c-special-brace-lists (save-excursion (goto-char indent-point) (c-forward-syntactic-ws (c-point 'eol)) (c-looking-at-special-brace-list (point))))) (c-add-syntax 'brace-entry-open (point)) (c-add-syntax 'brace-list-entry (point)) )) )))) ;; CASE 10: A continued statement or top level construct. ((and (not (memq char-before-ip '(?\; ?:))) (not (c-at-vsemi-p before-ws-ip)) (or (not (eq char-before-ip ?})) (c-looking-at-inexpr-block-backward c-state-cache)) (> (point) (save-excursion (c-beginning-of-statement-1 containing-sexp) (setq placeholder (point)))) (/= placeholder containing-sexp)) ;; This is shared with case 18. (c-guess-continued-construct indent-point char-after-ip placeholder containing-sexp paren-state)) ;; CASE 16: block close brace, possibly closing the defun or ;; the class ((eq char-after-ip ?}) ;; From here on we have the next containing sexp in lim. (setq lim (c-most-enclosing-brace paren-state)) (goto-char containing-sexp) (cond ;; CASE 16E: Closing a statement block? This catches ;; cases where it's preceded by a statement keyword, ;; which works even when used in an "invalid" context, ;; e.g. a macro argument. ((c-after-conditional) (c-backward-to-block-anchor lim) (c-add-stmt-syntax 'block-close nil t lim paren-state)) ;; CASE 16A: closing a lambda defun or an in-expression ;; block? C.f. cases 4, 7B and 17E. ((setq placeholder (c-looking-at-inexpr-block (c-safe-position containing-sexp paren-state) nil)) (setq tmpsymbol (if (eq (car placeholder) 'inlambda) 'inline-close 'block-close)) (goto-char containing-sexp) (back-to-indentation) (if (= containing-sexp (point)) (c-add-syntax tmpsymbol (point)) (goto-char (cdr placeholder)) (back-to-indentation) (c-add-stmt-syntax tmpsymbol nil t (c-most-enclosing-brace paren-state (point)) paren-state) (if (/= (point) (cdr placeholder)) (c-add-syntax (car placeholder))))) ;; CASE 16B: does this close an inline or a function in ;; a non-class declaration level block? ((save-excursion (and lim (progn (goto-char lim) (c-looking-at-decl-block (c-most-enclosing-brace paren-state lim) nil)) (setq placeholder (point)))) (c-backward-to-decl-anchor lim) (back-to-indentation) (if (save-excursion (goto-char placeholder) (looking-at c-other-decl-block-key)) (c-add-syntax 'defun-close (point)) (c-add-syntax 'inline-close (point)))) ;; CASE 16F: Can be a defun-close of a function declared ;; in a statement block, e.g. in Pike or when using gcc ;; extensions, but watch out for macros followed by ;; blocks. Let it through to be handled below. ;; C.f. cases B.3 and 17G. ((save-excursion (and (not (c-at-statement-start-p)) (eq (c-beginning-of-statement-1 lim nil nil t) 'same) (setq placeholder (point)) (let ((c-recognize-typeless-decls nil)) ;; Turn off recognition of constructs that ;; lacks a type in this case, since that's more ;; likely to be a macro followed by a block. (c-forward-decl-or-cast-1 (c-point 'bosws) nil nil)))) (back-to-indentation) (if (/= (point) containing-sexp) (goto-char placeholder)) (c-add-stmt-syntax 'defun-close nil t lim paren-state)) ;; CASE 16C: If there is an enclosing brace then this is ;; a block close since defun closes inside declaration ;; level blocks have been handled above. (lim ;; If the block is preceded by a case/switch label on ;; the same line, we anchor at the first preceding label ;; at boi. The default handling in c-add-stmt-syntax ;; really fixes it better, but we do like this to keep ;; the indentation compatible with version 5.28 and ;; earlier. C.f. case 17H. (while (and (/= (setq placeholder (point)) (c-point 'boi)) (eq (c-beginning-of-statement-1 lim) 'label))) (goto-char placeholder) (if (looking-at c-label-kwds-regexp) (c-add-syntax 'block-close (point)) (goto-char containing-sexp) ;; c-backward-to-block-anchor not necessary here; those ;; situations are handled in case 16E above. (c-add-stmt-syntax 'block-close nil t lim paren-state))) ;; CASE 16D: Only top level defun close left. (t (goto-char containing-sexp) (c-backward-to-decl-anchor lim) (c-add-stmt-syntax 'defun-close nil nil (c-most-enclosing-brace paren-state) paren-state)) )) ;; CASE 17: Statement or defun catchall. (t (goto-char indent-point) ;; Back up statements until we find one that starts at boi. (while (let* ((prev-point (point)) (last-step-type (c-beginning-of-statement-1 containing-sexp))) (if (= (point) prev-point) (progn (setq step-type (or step-type last-step-type)) nil) (setq step-type last-step-type) (/= (point) (c-point 'boi))))) (cond ;; CASE 17B: continued statement ((and (eq step-type 'same) (/= (point) indent-point)) (c-add-stmt-syntax 'statement-cont nil nil containing-sexp paren-state)) ;; CASE 17A: After a case/default label? ((progn (while (and (eq step-type 'label) (not (looking-at c-label-kwds-regexp))) (setq step-type (c-beginning-of-statement-1 containing-sexp))) (eq step-type 'label)) (c-add-stmt-syntax (if (eq char-after-ip ?{) 'statement-case-open 'statement-case-intro) nil t containing-sexp paren-state)) ;; CASE 17D: any old statement ((progn (while (eq step-type 'label) (setq step-type (c-beginning-of-statement-1 containing-sexp))) (eq step-type 'previous)) (c-add-stmt-syntax 'statement nil t containing-sexp paren-state) (if (eq char-after-ip ?{) (c-add-syntax 'block-open))) ;; CASE 17I: Inside a substatement block. ((progn ;; The following tests are all based on containing-sexp. (goto-char containing-sexp) ;; From here on we have the next containing sexp in lim. (setq lim (c-most-enclosing-brace paren-state containing-sexp)) (c-after-conditional)) (c-backward-to-block-anchor lim) (c-add-stmt-syntax 'statement-block-intro nil t lim paren-state) (if (eq char-after-ip ?{) (c-add-syntax 'block-open))) ;; CASE 17E: first statement in an in-expression block. ;; C.f. cases 4, 7B and 16A. ((setq placeholder (c-looking-at-inexpr-block (c-safe-position containing-sexp paren-state) nil)) (setq tmpsymbol (if (eq (car placeholder) 'inlambda) 'defun-block-intro 'statement-block-intro)) (back-to-indentation) (if (= containing-sexp (point)) (c-add-syntax tmpsymbol (point)) (goto-char (cdr placeholder)) (back-to-indentation) (c-add-stmt-syntax tmpsymbol nil t (c-most-enclosing-brace c-state-cache (point)) paren-state) (if (/= (point) (cdr placeholder)) (c-add-syntax (car placeholder)))) (if (eq char-after-ip ?{) (c-add-syntax 'block-open))) ;; CASE 17F: first statement in an inline, or first ;; statement in a top-level defun. we can tell this is it ;; if there are no enclosing braces that haven't been ;; narrowed out by a class (i.e. don't use bod here). ((save-excursion (or (not (setq placeholder (c-most-enclosing-brace paren-state))) (and (progn (goto-char placeholder) (eq (char-after) ?{)) (c-looking-at-decl-block (c-most-enclosing-brace paren-state (point)) nil)))) (c-backward-to-decl-anchor lim) (back-to-indentation) (c-add-syntax 'defun-block-intro (point))) ;; CASE 17G: First statement in a function declared inside ;; a normal block. This can occur in Pike and with ;; e.g. the gcc extensions, but watch out for macros ;; followed by blocks. C.f. cases B.3 and 16F. ((save-excursion (and (not (c-at-statement-start-p)) (eq (c-beginning-of-statement-1 lim nil nil t) 'same) (setq placeholder (point)) (let ((c-recognize-typeless-decls nil)) ;; Turn off recognition of constructs that lacks ;; a type in this case, since that's more likely ;; to be a macro followed by a block. (c-forward-decl-or-cast-1 (c-point 'bosws) nil nil)))) (back-to-indentation) (if (/= (point) containing-sexp) (goto-char placeholder)) (c-add-stmt-syntax 'defun-block-intro nil t lim paren-state)) ;; CASE 17H: First statement in a block. (t ;; If the block is preceded by a case/switch label on the ;; same line, we anchor at the first preceding label at ;; boi. The default handling in c-add-stmt-syntax is ;; really fixes it better, but we do like this to keep the ;; indentation compatible with version 5.28 and earlier. ;; C.f. case 16C. (while (and (/= (setq placeholder (point)) (c-point 'boi)) (eq (c-beginning-of-statement-1 lim) 'label))) (goto-char placeholder) (if (looking-at c-label-kwds-regexp) (c-add-syntax 'statement-block-intro (point)) (goto-char containing-sexp) ;; c-backward-to-block-anchor not necessary here; those ;; situations are handled in case 17I above. (c-add-stmt-syntax 'statement-block-intro nil t lim paren-state)) (if (eq char-after-ip ?{) (c-add-syntax 'block-open))) )) ) ;; now we need to look at any modifiers (goto-char indent-point) (skip-chars-forward " \t") ;; are we looking at a comment only line? (when (and (looking-at c-comment-start-regexp) (/= (c-forward-token-2 0 nil (c-point 'eol)) 0)) (c-append-syntax 'comment-intro)) ;; we might want to give additional offset to friends (in C++). (when (and c-opt-friend-key (looking-at c-opt-friend-key)) (c-append-syntax 'friend)) ;; Set syntactic-relpos. (let ((p c-syntactic-context)) (while (and p (if (integerp (c-langelem-pos (car p))) (progn (setq syntactic-relpos (c-langelem-pos (car p))) nil) t)) (setq p (cdr p)))) ;; Start of or a continuation of a preprocessor directive? (if (and macro-start (eq macro-start (c-point 'boi)) (not (and (c-major-mode-is 'pike-mode) (eq (char-after (1+ macro-start)) ?\")))) (c-append-syntax 'cpp-macro) (when (and c-syntactic-indentation-in-macros macro-start) (if in-macro-expr (when (or (< syntactic-relpos macro-start) (not (or (assq 'arglist-intro c-syntactic-context) (assq 'arglist-cont c-syntactic-context) (assq 'arglist-cont-nonempty c-syntactic-context) (assq 'arglist-close c-syntactic-context)))) ;; If inside a cpp expression, i.e. anywhere in a ;; cpp directive except a #define body, we only let ;; through the syntactic analysis that is internal ;; in the expression. That means the arglist ;; elements, if they are anchored inside the cpp ;; expression. (setq c-syntactic-context nil) (c-add-syntax 'cpp-macro-cont macro-start)) (when (and (eq macro-start syntactic-relpos) (not (assq 'cpp-define-intro c-syntactic-context)) (save-excursion (goto-char macro-start) (or (not (c-forward-to-cpp-define-body)) (<= (point) (c-point 'boi indent-point))))) ;; Inside a #define body and the syntactic analysis is ;; anchored on the start of the #define. In this case ;; we add cpp-define-intro to get the extra ;; indentation of the #define body. (c-add-syntax 'cpp-define-intro))))) ;; return the syntax c-syntactic-context))) ;; Indentation calculation. (defun c-evaluate-offset (offset langelem symbol) ;; offset can be a number, a function, a variable, a list, or one of ;; the symbols + or - ;; ;; This function might do hidden buffer changes. (let ((res (cond ((numberp offset) offset) ((vectorp offset) offset) ((null offset) nil) ((eq offset '+) c-basic-offset) ((eq offset '-) (- c-basic-offset)) ((eq offset '++) (* 2 c-basic-offset)) ((eq offset '--) (* 2 (- c-basic-offset))) ((eq offset '*) (/ c-basic-offset 2)) ((eq offset '/) (/ (- c-basic-offset) 2)) ((functionp offset) (c-evaluate-offset (funcall offset (cons (c-langelem-sym langelem) (c-langelem-pos langelem))) langelem symbol)) ((listp offset) (cond ((eq (car offset) 'quote) (c-benign-error "The offset %S for %s was mistakenly quoted" offset symbol) nil) ((memq (car offset) '(min max)) (let (res val (method (car offset))) (setq offset (cdr offset)) (while offset (setq val (c-evaluate-offset (car offset) langelem symbol)) (cond ((not val)) ((not res) (setq res val)) ((integerp val) (if (vectorp res) (c-benign-error "\ Error evaluating offset %S for %s: \ Cannot combine absolute offset %S with relative %S in `%s' method" (car offset) symbol res val method) (setq res (funcall method res val)))) (t (if (integerp res) (c-benign-error "\ Error evaluating offset %S for %s: \ Cannot combine relative offset %S with absolute %S in `%s' method" (car offset) symbol res val method) (setq res (vector (funcall method (aref res 0) (aref val 0))))))) (setq offset (cdr offset))) res)) ((eq (car offset) 'add) (let (res val) (setq offset (cdr offset)) (while offset (setq val (c-evaluate-offset (car offset) langelem symbol)) (cond ((not val)) ((not res) (setq res val)) ((integerp val) (if (vectorp res) (setq res (vector (+ (aref res 0) val))) (setq res (+ res val)))) (t (if (vectorp res) (c-benign-error "\ Error evaluating offset %S for %s: \ Cannot combine absolute offsets %S and %S in `add' method" (car offset) symbol res val) (setq res val)))) ; Override. (setq offset (cdr offset))) res)) (t (let (res) (when (eq (car offset) 'first) (setq offset (cdr offset))) (while (and (not res) offset) (setq res (c-evaluate-offset (car offset) langelem symbol) offset (cdr offset))) res)))) ((and (symbolp offset) (boundp offset)) (symbol-value offset)) (t (c-benign-error "Unknown offset format %S for %s" offset symbol) nil)))) (if (or (null res) (integerp res) (and (vectorp res) (= (length res) 1) (integerp (aref res 0)))) res (c-benign-error "Error evaluating offset %S for %s: Got invalid value %S" offset symbol res) nil))) (defun c-calc-offset (langelem) ;; Get offset from LANGELEM which is a list beginning with the ;; syntactic symbol and followed by any analysis data it provides. ;; That data may be zero or more elements, but if at least one is ;; given then the first is the anchor position (or nil). The symbol ;; is matched against `c-offsets-alist' and the offset calculated ;; from that is returned. ;; ;; This function might do hidden buffer changes. (let* ((symbol (c-langelem-sym langelem)) (match (assq symbol c-offsets-alist)) (offset (cdr-safe match))) (if match (setq offset (c-evaluate-offset offset langelem symbol)) (if c-strict-syntax-p (c-benign-error "No offset found for syntactic symbol %s" symbol)) (setq offset 0)) (if (vectorp offset) offset (or (and (numberp offset) offset) (and (symbolp offset) (symbol-value offset)) 0)) )) (defun c-get-offset (langelem) ;; This is a compatibility wrapper for `c-calc-offset' in case ;; someone is calling it directly. It takes an old style syntactic ;; element on the form (SYMBOL . ANCHOR-POS) and converts it to the ;; new list form. ;; ;; This function might do hidden buffer changes. (if (c-langelem-pos langelem) (c-calc-offset (list (c-langelem-sym langelem) (c-langelem-pos langelem))) (c-calc-offset langelem))) (defun c-get-syntactic-indentation (langelems) ;; Calculate the syntactic indentation from a syntactic description ;; as returned by `c-guess-syntax'. ;; ;; Note that topmost-intro always has an anchor position at bol, for ;; historical reasons. It's often used together with other symbols ;; that has more sane positions. Since we always use the first ;; found anchor position, we rely on that these other symbols always ;; precede topmost-intro in the LANGELEMS list. ;; ;; This function might do hidden buffer changes. (let ((indent 0) anchor) (while langelems (let* ((c-syntactic-element (car langelems)) (res (c-calc-offset c-syntactic-element))) (if (vectorp res) ;; Got an absolute column that overrides any indentation ;; we've collected so far, but not the relative ;; indentation we might get for the nested structures ;; further down the langelems list. (setq indent (elt res 0) anchor (point-min)) ; A position at column 0. ;; Got a relative change of the current calculated ;; indentation. (setq indent (+ indent res)) ;; Use the anchor position from the first syntactic ;; element with one. (unless anchor (setq anchor (c-langelem-pos (car langelems))))) (setq langelems (cdr langelems)))) (if anchor (+ indent (save-excursion (goto-char anchor) (current-column))) indent))) (cc-provide 'cc-engine) ;;; arch-tag: 149add18-4673-4da5-ac47-6805e4eae089 ;;; cc-engine.el ends here