This is ../info/lispref.info, produced by makeinfo version 4.0 from lispref/lispref.texi. INFO-DIR-SECTION XEmacs Editor START-INFO-DIR-ENTRY * Lispref: (lispref). XEmacs Lisp Reference Manual. END-INFO-DIR-ENTRY Edition History: GNU Emacs Lisp Reference Manual Second Edition (v2.01), May 1993 GNU Emacs Lisp Reference Manual Further Revised (v2.02), August 1993 Lucid Emacs Lisp Reference Manual (for 19.10) First Edition, March 1994 XEmacs Lisp Programmer's Manual (for 19.12) Second Edition, April 1995 GNU Emacs Lisp Reference Manual v2.4, June 1995 XEmacs Lisp Programmer's Manual (for 19.13) Third Edition, July 1995 XEmacs Lisp Reference Manual (for 19.14 and 20.0) v3.1, March 1996 XEmacs Lisp Reference Manual (for 19.15 and 20.1, 20.2, 20.3) v3.2, April, May, November 1997 XEmacs Lisp Reference Manual (for 21.0) v3.3, April 1998 Copyright (C) 1990, 1991, 1992, 1993, 1994, 1995 Free Software Foundation, Inc. Copyright (C) 1994, 1995 Sun Microsystems, Inc. Copyright (C) 1995, 1996 Ben Wing. Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice are preserved on all copies. Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that this permission notice may be stated in a translation approved by the Foundation. Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided also that the section entitled "GNU General Public License" is included exactly as in the original, and provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that the section entitled "GNU General Public License" may be included in a translation approved by the Free Software Foundation instead of in the original English.  File: lispref.info, Node: Regexp Example, Prev: Syntax of Regexps, Up: Regular Expressions Complex Regexp Example ---------------------- Here is a complicated regexp, used by XEmacs to recognize the end of a sentence together with any whitespace that follows. It is the value of the variable `sentence-end'. First, we show the regexp as a string in Lisp syntax to distinguish spaces from tab characters. The string constant begins and ends with a double-quote. `\"' stands for a double-quote as part of the string, `\\' for a backslash as part of the string, `\t' for a tab and `\n' for a newline. "[.?!][]\"')}]*\\($\\| $\\|\t\\| \\)[ \t\n]*" In contrast, if you evaluate the variable `sentence-end', you will see the following: sentence-end => "[.?!][]\"')}]*\\($\\| $\\| \\| \\)[ ]*" In this output, tab and newline appear as themselves. This regular expression contains four parts in succession and can be deciphered as follows: `[.?!]' The first part of the pattern is a character set that matches any one of three characters: period, question mark, and exclamation mark. The match must begin with one of these three characters. `[]\"')}]*' The second part of the pattern matches any closing braces and quotation marks, zero or more of them, that may follow the period, question mark or exclamation mark. The `\"' is Lisp syntax for a double-quote in a string. The `*' at the end indicates that the immediately preceding regular expression (a character set, in this case) may be repeated zero or more times. `\\($\\| $\\|\t\\| \\)' The third part of the pattern matches the whitespace that follows the end of a sentence: the end of a line, or a tab, or two spaces. The double backslashes mark the parentheses and vertical bars as regular expression syntax; the parentheses delimit a group and the vertical bars separate alternatives. The dollar sign is used to match the end of a line. `[ \t\n]*' Finally, the last part of the pattern matches any additional whitespace beyond the minimum needed to end a sentence.  File: lispref.info, Node: Regexp Search, Next: POSIX Regexps, Prev: Regular Expressions, Up: Searching and Matching Regular Expression Searching ============================ In XEmacs, you can search for the next match for a regexp either incrementally or not. Incremental search commands are described in the `The XEmacs Reference Manual'. *Note Regular Expression Search: (emacs)Regexp Search. Here we describe only the search functions useful in programs. The principal one is `re-search-forward'. - Command: re-search-forward regexp &optional limit noerror repeat This function searches forward in the current buffer for a string of text that is matched by the regular expression REGEXP. The function skips over any amount of text that is not matched by REGEXP, and leaves point at the end of the first match found. It returns the new value of point. If LIMIT is non-`nil' (it must be a position in the current buffer), then it is the upper bound to the search. No match extending after that position is accepted. What happens when the search fails depends on the value of NOERROR. If NOERROR is `nil', a `search-failed' error is signaled. If NOERROR is `t', `re-search-forward' does nothing and returns `nil'. If NOERROR is neither `nil' nor `t', then `re-search-forward' moves point to LIMIT (or the end of the buffer) and returns `nil'. If REPEAT is supplied (it must be a positive number), then the search is repeated that many times (each time starting at the end of the previous time's match). If these successive searches succeed, the function succeeds, moving point and returning its new value. Otherwise the search fails. In the following example, point is initially before the `T'. Evaluating the search call moves point to the end of that line (between the `t' of `hat' and the newline). ---------- Buffer: foo ---------- I read "-!-The cat in the hat comes back" twice. ---------- Buffer: foo ---------- (re-search-forward "[a-z]+" nil t 5) => 27 ---------- Buffer: foo ---------- I read "The cat in the hat-!- comes back" twice. ---------- Buffer: foo ---------- - Command: re-search-backward regexp &optional limit noerror repeat This function searches backward in the current buffer for a string of text that is matched by the regular expression REGEXP, leaving point at the beginning of the first text found. This function is analogous to `re-search-forward', but they are not simple mirror images. `re-search-forward' finds the match whose beginning is as close as possible to the starting point. If `re-search-backward' were a perfect mirror image, it would find the match whose end is as close as possible. However, in fact it finds the match whose beginning is as close as possible. The reason is that matching a regular expression at a given spot always works from beginning to end, and starts at a specified beginning position. A true mirror-image of `re-search-forward' would require a special feature for matching regexps from end to beginning. It's not worth the trouble of implementing that. - Function: string-match regexp string &optional start This function returns the index of the start of the first match for the regular expression REGEXP in STRING, or `nil' if there is no match. If START is non-`nil', the search starts at that index in STRING. For example, (string-match "quick" "The quick brown fox jumped quickly.") => 4 (string-match "quick" "The quick brown fox jumped quickly." 8) => 27 The index of the first character of the string is 0, the index of the second character is 1, and so on. After this function returns, the index of the first character beyond the match is available as `(match-end 0)'. *Note Match Data::. (string-match "quick" "The quick brown fox jumped quickly." 8) => 27 (match-end 0) => 32 - Function: split-string string &optional pattern This function splits STRING to substrings delimited by PATTERN, and returns a list of substrings. If PATTERN is omitted, it defaults to `[ \f\t\n\r\v]+', which means that it splits STRING by white-space. (split-string "foo bar") => ("foo" "bar") (split-string "something") => ("something") (split-string "a:b:c" ":") => ("a" "b" "c") (split-string ":a::b:c" ":") => ("" "a" "" "b" "c") - Function: split-path path This function splits a search path into a list of strings. The path components are separated with the characters specified with `path-separator'. Under Unix, `path-separator' will normally be `:', while under Windows, it will be `;'. - Function: looking-at regexp This function determines whether the text in the current buffer directly following point matches the regular expression REGEXP. "Directly following" means precisely that: the search is "anchored" and it can succeed only starting with the first character following point. The result is `t' if so, `nil' otherwise. This function does not move point, but it updates the match data, which you can access using `match-beginning' and `match-end'. *Note Match Data::. In this example, point is located directly before the `T'. If it were anywhere else, the result would be `nil'. ---------- Buffer: foo ---------- I read "-!-The cat in the hat comes back" twice. ---------- Buffer: foo ---------- (looking-at "The cat in the hat$") => t  File: lispref.info, Node: POSIX Regexps, Next: Search and Replace, Prev: Regexp Search, Up: Searching and Matching POSIX Regular Expression Searching ================================== The usual regular expression functions do backtracking when necessary to handle the `\|' and repetition constructs, but they continue this only until they find _some_ match. Then they succeed and report the first match found. This section describes alternative search functions which perform the full backtracking specified by the POSIX standard for regular expression matching. They continue backtracking until they have tried all possibilities and found all matches, so they can report the longest match, as required by POSIX. This is much slower, so use these functions only when you really need the longest match. In Emacs versions prior to 19.29, these functions did not exist, and the functions described above implemented full POSIX backtracking. - Function: posix-search-forward regexp &optional limit noerror repeat This is like `re-search-forward' except that it performs the full backtracking specified by the POSIX standard for regular expression matching. - Function: posix-search-backward regexp &optional limit noerror repeat This is like `re-search-backward' except that it performs the full backtracking specified by the POSIX standard for regular expression matching. - Function: posix-looking-at regexp This is like `looking-at' except that it performs the full backtracking specified by the POSIX standard for regular expression matching. - Function: posix-string-match regexp string &optional start This is like `string-match' except that it performs the full backtracking specified by the POSIX standard for regular expression matching.  File: lispref.info, Node: Search and Replace, Next: Match Data, Prev: POSIX Regexps, Up: Searching and Matching Search and Replace ================== - Function: perform-replace from-string replacements query-flag regexp-flag delimited-flag &optional repeat-count map This function is the guts of `query-replace' and related commands. It searches for occurrences of FROM-STRING and replaces some or all of them. If QUERY-FLAG is `nil', it replaces all occurrences; otherwise, it asks the user what to do about each one. If REGEXP-FLAG is non-`nil', then FROM-STRING is considered a regular expression; otherwise, it must match literally. If DELIMITED-FLAG is non-`nil', then only replacements surrounded by word boundaries are considered. The argument REPLACEMENTS specifies what to replace occurrences with. If it is a string, that string is used. It can also be a list of strings, to be used in cyclic order. If REPEAT-COUNT is non-`nil', it should be an integer. Then it specifies how many times to use each of the strings in the REPLACEMENTS list before advancing cyclicly to the next one. Normally, the keymap `query-replace-map' defines the possible user responses for queries. The argument MAP, if non-`nil', is a keymap to use instead of `query-replace-map'. - Variable: query-replace-map This variable holds a special keymap that defines the valid user responses for `query-replace' and related functions, as well as `y-or-n-p' and `map-y-or-n-p'. It is unusual in two ways: * The "key bindings" are not commands, just symbols that are meaningful to the functions that use this map. * Prefix keys are not supported; each key binding must be for a single event key sequence. This is because the functions don't use read key sequence to get the input; instead, they read a single event and look it up "by hand." Here are the meaningful "bindings" for `query-replace-map'. Several of them are meaningful only for `query-replace' and friends. `act' Do take the action being considered--in other words, "yes." `skip' Do not take action for this question--in other words, "no." `exit' Answer this question "no," and give up on the entire series of questions, assuming that the answers will be "no." `act-and-exit' Answer this question "yes," and give up on the entire series of questions, assuming that subsequent answers will be "no." `act-and-show' Answer this question "yes," but show the results--don't advance yet to the next question. `automatic' Answer this question and all subsequent questions in the series with "yes," without further user interaction. `backup' Move back to the previous place that a question was asked about. `edit' Enter a recursive edit to deal with this question--instead of any other action that would normally be taken. `delete-and-edit' Delete the text being considered, then enter a recursive edit to replace it. `recenter' Redisplay and center the window, then ask the same question again. `quit' Perform a quit right away. Only `y-or-n-p' and related functions use this answer. `help' Display some help, then ask again.  File: lispref.info, Node: Match Data, Next: Searching and Case, Prev: Search and Replace, Up: Searching and Matching The Match Data ============== XEmacs keeps track of the positions of the start and end of segments of text found during a regular expression search. This means, for example, that you can search for a complex pattern, such as a date in an Rmail message, and then extract parts of the match under control of the pattern. Because the match data normally describe the most recent search only, you must be careful not to do another search inadvertently between the search you wish to refer back to and the use of the match data. If you can't avoid another intervening search, you must save and restore the match data around it, to prevent it from being overwritten. * Menu: * Simple Match Data:: Accessing single items of match data, such as where a particular subexpression started. * Replacing Match:: Replacing a substring that was matched. * Entire Match Data:: Accessing the entire match data at once, as a list. * Saving Match Data:: Saving and restoring the match data.  File: lispref.info, Node: Simple Match Data, Next: Replacing Match, Up: Match Data Simple Match Data Access ------------------------ This section explains how to use the match data to find out what was matched by the last search or match operation. You can ask about the entire matching text, or about a particular parenthetical subexpression of a regular expression. The COUNT argument in the functions below specifies which. If COUNT is zero, you are asking about the entire match. If COUNT is positive, it specifies which subexpression you want. Recall that the subexpressions of a regular expression are those expressions grouped with escaped parentheses, `\(...\)'. The COUNTth subexpression is found by counting occurrences of `\(' from the beginning of the whole regular expression. The first subexpression is numbered 1, the second 2, and so on. Only regular expressions can have subexpressions--after a simple string search, the only information available is about the entire match. - Function: match-string count &optional in-string This function returns, as a string, the text matched in the last search or match operation. It returns the entire text if COUNT is zero, or just the portion corresponding to the COUNTth parenthetical subexpression, if COUNT is positive. If COUNT is out of range, or if that subexpression didn't match anything, the value is `nil'. If the last such operation was done against a string with `string-match', then you should pass the same string as the argument IN-STRING. Otherwise, after a buffer search or match, you should omit IN-STRING or pass `nil' for it; but you should make sure that the current buffer when you call `match-string' is the one in which you did the searching or matching. - Function: match-beginning count This function returns the position of the start of text matched by the last regular expression searched for, or a subexpression of it. If COUNT is zero, then the value is the position of the start of the entire match. Otherwise, COUNT specifies a subexpression in the regular expression, and the value of the function is the starting position of the match for that subexpression. The value is `nil' for a subexpression inside a `\|' alternative that wasn't used in the match. - Function: match-end count This function is like `match-beginning' except that it returns the position of the end of the match, rather than the position of the beginning. Here is an example of using the match data, with a comment showing the positions within the text: (string-match "\\(qu\\)\\(ick\\)" "The quick fox jumped quickly.") ;0123456789 => 4 (match-string 0 "The quick fox jumped quickly.") => "quick" (match-string 1 "The quick fox jumped quickly.") => "qu" (match-string 2 "The quick fox jumped quickly.") => "ick" (match-beginning 1) ; The beginning of the match => 4 ; with `qu' is at index 4. (match-beginning 2) ; The beginning of the match => 6 ; with `ick' is at index 6. (match-end 1) ; The end of the match => 6 ; with `qu' is at index 6. (match-end 2) ; The end of the match => 9 ; with `ick' is at index 9. Here is another example. Point is initially located at the beginning of the line. Searching moves point to between the space and the word `in'. The beginning of the entire match is at the 9th character of the buffer (`T'), and the beginning of the match for the first subexpression is at the 13th character (`c'). (list (re-search-forward "The \\(cat \\)") (match-beginning 0) (match-beginning 1)) => (9 9 13) ---------- Buffer: foo ---------- I read "The cat -!-in the hat comes back" twice. ^ ^ 9 13 ---------- Buffer: foo ---------- (In this case, the index returned is a buffer position; the first character of the buffer counts as 1.)  File: lispref.info, Node: Replacing Match, Next: Entire Match Data, Prev: Simple Match Data, Up: Match Data Replacing the Text That Matched ------------------------------- This function replaces the text matched by the last search with REPLACEMENT. - Function: replace-match replacement &optional fixedcase literal string This function replaces the text in the buffer (or in STRING) that was matched by the last search. It replaces that text with REPLACEMENT. If you did the last search in a buffer, you should specify `nil' for STRING. Then `replace-match' does the replacement by editing the buffer; it leaves point at the end of the replacement text, and returns `t'. If you did the search in a string, pass the same string as STRING. Then `replace-match' does the replacement by constructing and returning a new string. If FIXEDCASE is non-`nil', then the case of the replacement text is not changed; otherwise, the replacement text is converted to a different case depending upon the capitalization of the text to be replaced. If the original text is all upper case, the replacement text is converted to upper case. If the first word of the original text is capitalized, then the first word of the replacement text is capitalized. If the original text contains just one word, and that word is a capital letter, `replace-match' considers this a capitalized first word rather than all upper case. If `case-replace' is `nil', then case conversion is not done, regardless of the value of FIXED-CASE. *Note Searching and Case::. If LITERAL is non-`nil', then REPLACEMENT is inserted exactly as it is, the only alterations being case changes as needed. If it is `nil' (the default), then the character `\' is treated specially. If a `\' appears in REPLACEMENT, then it must be part of one of the following sequences: `\&' `\&' stands for the entire text being replaced. `\N' `\N', where N is a digit, stands for the text that matched the Nth subexpression in the original regexp. Subexpressions are those expressions grouped inside `\(...\)'. `\\' `\\' stands for a single `\' in the replacement text.  File: lispref.info, Node: Entire Match Data, Next: Saving Match Data, Prev: Replacing Match, Up: Match Data Accessing the Entire Match Data ------------------------------- The functions `match-data' and `set-match-data' read or write the entire match data, all at once. - Function: match-data This function returns a newly constructed list containing all the information on what text the last search matched. Element zero is the position of the beginning of the match for the whole expression; element one is the position of the end of the match for the expression. The next two elements are the positions of the beginning and end of the match for the first subexpression, and so on. In general, element number 2N corresponds to `(match-beginning N)'; and element number 2N + 1 corresponds to `(match-end N)'. All the elements are markers or `nil' if matching was done on a buffer, and all are integers or `nil' if matching was done on a string with `string-match'. (In Emacs 18 and earlier versions, markers were used even for matching on a string, except in the case of the integer 0.) As always, there must be no possibility of intervening searches between the call to a search function and the call to `match-data' that is intended to access the match data for that search. (match-data) => (# # # #) - Function: set-match-data match-list This function sets the match data from the elements of MATCH-LIST, which should be a list that was the value of a previous call to `match-data'. If MATCH-LIST refers to a buffer that doesn't exist, you don't get an error; that sets the match data in a meaningless but harmless way. `store-match-data' is an alias for `set-match-data'.  File: lispref.info, Node: Saving Match Data, Prev: Entire Match Data, Up: Match Data Saving and Restoring the Match Data ----------------------------------- When you call a function that may do a search, you may need to save and restore the match data around that call, if you want to preserve the match data from an earlier search for later use. Here is an example that shows the problem that arises if you fail to save the match data: (re-search-forward "The \\(cat \\)") => 48 (foo) ; Perhaps `foo' does ; more searching. (match-end 0) => 61 ; Unexpected result--not 48! You can save and restore the match data with `save-match-data': - Macro: save-match-data body... This special form executes BODY, saving and restoring the match data around it. You can use `set-match-data' together with `match-data' to imitate the effect of the special form `save-match-data'. This is useful for writing code that can run in Emacs 18. Here is how: (let ((data (match-data))) (unwind-protect ... ; May change the original match data. (set-match-data data))) Emacs automatically saves and restores the match data when it runs process filter functions (*note Filter Functions::) and process sentinels (*note Sentinels::).  File: lispref.info, Node: Searching and Case, Next: Standard Regexps, Prev: Match Data, Up: Searching and Matching Searching and Case ================== By default, searches in Emacs ignore the case of the text they are searching through; if you specify searching for `FOO', then `Foo' or `foo' is also considered a match. Regexps, and in particular character sets, are included: thus, `[aB]' would match `a' or `A' or `b' or `B'. If you do not want this feature, set the variable `case-fold-search' to `nil'. Then all letters must match exactly, including case. This is a buffer-local variable; altering the variable affects only the current buffer. (*Note Intro to Buffer-Local::.) Alternatively, you may change the value of `default-case-fold-search', which is the default value of `case-fold-search' for buffers that do not override it. Note that the user-level incremental search feature handles case distinctions differently. When given a lower case letter, it looks for a match of either case, but when given an upper case letter, it looks for an upper case letter only. But this has nothing to do with the searching functions Lisp functions use. - User Option: case-replace This variable determines whether the replacement functions should preserve case. If the variable is `nil', that means to use the replacement text verbatim. A non-`nil' value means to convert the case of the replacement text according to the text being replaced. The function `replace-match' is where this variable actually has its effect. *Note Replacing Match::. - User Option: case-fold-search This buffer-local variable determines whether searches should ignore case. If the variable is `nil' they do not ignore case; otherwise they do ignore case. - Variable: default-case-fold-search The value of this variable is the default value for `case-fold-search' in buffers that do not override it. This is the same as `(default-value 'case-fold-search)'.  File: lispref.info, Node: Standard Regexps, Prev: Searching and Case, Up: Searching and Matching Standard Regular Expressions Used in Editing ============================================ This section describes some variables that hold regular expressions used for certain purposes in editing: - Variable: page-delimiter This is the regexp describing line-beginnings that separate pages. The default value is `"^\014"' (i.e., `"^^L"' or `"^\C-l"'); this matches a line that starts with a formfeed character. The following two regular expressions should _not_ assume the match always starts at the beginning of a line; they should not use `^' to anchor the match. Most often, the paragraph commands do check for a match only at the beginning of a line, which means that `^' would be superfluous. When there is a nonzero left margin, they accept matches that start after the left margin. In that case, a `^' would be incorrect. However, a `^' is harmless in modes where a left margin is never used. - Variable: paragraph-separate This is the regular expression for recognizing the beginning of a line that separates paragraphs. (If you change this, you may have to change `paragraph-start' also.) The default value is `"[ \t\f]*$"', which matches a line that consists entirely of spaces, tabs, and form feeds (after its left margin). - Variable: paragraph-start This is the regular expression for recognizing the beginning of a line that starts _or_ separates paragraphs. The default value is `"[ \t\n\f]"', which matches a line starting with a space, tab, newline, or form feed (after its left margin). - Variable: sentence-end This is the regular expression describing the end of a sentence. (All paragraph boundaries also end sentences, regardless.) The default value is: "[.?!][]\"')}]*\\($\\| $\\|\t\\| \\)[ \t\n]*" This means a period, question mark or exclamation mark, followed optionally by a closing parenthetical character, followed by tabs, spaces or new lines. For a detailed explanation of this regular expression, see *Note Regexp Example::.  File: lispref.info, Node: Syntax Tables, Next: Abbrevs, Prev: Searching and Matching, Up: Top Syntax Tables ************* A "syntax table" specifies the syntactic textual function of each character. This information is used by the parsing commands, the complex movement commands, and others to determine where words, symbols, and other syntactic constructs begin and end. The current syntax table controls the meaning of the word motion functions (*note Word Motion::) and the list motion functions (*note List Motion::) as well as the functions in this chapter. * Menu: * Basics: Syntax Basics. Basic concepts of syntax tables. * Desc: Syntax Descriptors. How characters are classified. * Syntax Table Functions:: How to create, examine and alter syntax tables. * Motion and Syntax:: Moving over characters with certain syntaxes. * Parsing Expressions:: Parsing balanced expressions using the syntax table. * Standard Syntax Tables:: Syntax tables used by various major modes. * Syntax Table Internals:: How syntax table information is stored.  File: lispref.info, Node: Syntax Basics, Next: Syntax Descriptors, Up: Syntax Tables Syntax Table Concepts ===================== A "syntax table" provides Emacs with the information that determines the syntactic use of each character in a buffer. This information is used by the parsing commands, the complex movement commands, and others to determine where words, symbols, and other syntactic constructs begin and end. The current syntax table controls the meaning of the word motion functions (*note Word Motion::) and the list motion functions (*note List Motion::) as well as the functions in this chapter. Under XEmacs 20, a syntax table is a particular subtype of the primitive char table type (*note Char Tables::), and each element of the char table is an integer that encodes the syntax of the character in question, or a cons of such an integer and a matching character (for characters with parenthesis syntax). Under XEmacs 19, a syntax table is a vector of 256 elements; it contains one entry for each of the 256 possible characters in an 8-bit byte. Each element is an integer that encodes the syntax of the character in question. (The matching character, if any, is embedded in the bits of this integer.) Syntax tables are used only for moving across text, not for the Emacs Lisp reader. XEmacs Lisp uses built-in syntactic rules when reading Lisp expressions, and these rules cannot be changed. Each buffer has its own major mode, and each major mode has its own idea of the syntactic class of various characters. For example, in Lisp mode, the character `;' begins a comment, but in C mode, it terminates a statement. To support these variations, XEmacs makes the choice of syntax table local to each buffer. Typically, each major mode has its own syntax table and installs that table in each buffer that uses that mode. Changing this table alters the syntax in all those buffers as well as in any buffers subsequently put in that mode. Occasionally several similar modes share one syntax table. *Note Example Major Modes::, for an example of how to set up a syntax table. A syntax table can inherit the data for some characters from the standard syntax table, while specifying other characters itself. The "inherit" syntax class means "inherit this character's syntax from the standard syntax table." Most major modes' syntax tables inherit the syntax of character codes 0 through 31 and 128 through 255. This is useful with character sets such as ISO Latin-1 that have additional alphabetic characters in the range 128 to 255. Just changing the standard syntax for these characters affects all major modes. - Function: syntax-table-p object This function returns `t' if OBJECT is a vector of length 256 elements. This means that the vector may be a syntax table. However, according to this test, any vector of length 256 is considered to be a syntax table, no matter what its contents.  File: lispref.info, Node: Syntax Descriptors, Next: Syntax Table Functions, Prev: Syntax Basics, Up: Syntax Tables Syntax Descriptors ================== This section describes the syntax classes and flags that denote the syntax of a character, and how they are represented as a "syntax descriptor", which is a Lisp string that you pass to `modify-syntax-entry' to specify the desired syntax. XEmacs defines a number of "syntax classes". Each syntax table puts each character into one class. There is no necessary relationship between the class of a character in one syntax table and its class in any other table. Each class is designated by a mnemonic character, which serves as the name of the class when you need to specify a class. Usually the designator character is one that is frequently in that class; however, its meaning as a designator is unvarying and independent of what syntax that character currently has. A syntax descriptor is a Lisp string that specifies a syntax class, a matching character (used only for the parenthesis classes) and flags. The first character is the designator for a syntax class. The second character is the character to match; if it is unused, put a space there. Then come the characters for any desired flags. If no matching character or flags are needed, one character is sufficient. For example, the descriptor for the character `*' in C mode is `. 23' (i.e., punctuation, matching character slot unused, second character of a comment-starter, first character of an comment-ender), and the entry for `/' is `. 14' (i.e., punctuation, matching character slot unused, first character of a comment-starter, second character of a comment-ender). * Menu: * Syntax Class Table:: Table of syntax classes. * Syntax Flags:: Additional flags each character can have.  File: lispref.info, Node: Syntax Class Table, Next: Syntax Flags, Up: Syntax Descriptors Table of Syntax Classes ----------------------- Here is a table of syntax classes, the characters that stand for them, their meanings, and examples of their use. - Syntax class: whitespace character "Whitespace characters" (designated with ` ' or `-') separate symbols and words from each other. Typically, whitespace characters have no other syntactic significance, and multiple whitespace characters are syntactically equivalent to a single one. Space, tab, newline and formfeed are almost always classified as whitespace. - Syntax class: word constituent "Word constituents" (designated with `w') are parts of normal English words and are typically used in variable and command names in programs. All upper- and lower-case letters, and the digits, are typically word constituents. - Syntax class: symbol constituent "Symbol constituents" (designated with `_') are the extra characters that are used in variable and command names along with word constituents. For example, the symbol constituents class is used in Lisp mode to indicate that certain characters may be part of symbol names even though they are not part of English words. These characters are `$&*+-_<>'. In standard C, the only non-word-constituent character that is valid in symbols is underscore (`_'). - Syntax class: punctuation character "Punctuation characters" (`.') are those characters that are used as punctuation in English, or are used in some way in a programming language to separate symbols from one another. Most programming language modes, including Emacs Lisp mode, have no characters in this class since the few characters that are not symbol or word constituents all have other uses. - Syntax class: open parenthesis character - Syntax class: close parenthesis character Open and close "parenthesis characters" are characters used in dissimilar pairs to surround sentences or expressions. Such a grouping is begun with an open parenthesis character and terminated with a close. Each open parenthesis character matches a particular close parenthesis character, and vice versa. Normally, XEmacs indicates momentarily the matching open parenthesis when you insert a close parenthesis. *Note Blinking::. The class of open parentheses is designated with `(', and that of close parentheses with `)'. In English text, and in C code, the parenthesis pairs are `()', `[]', and `{}'. In XEmacs Lisp, the delimiters for lists and vectors (`()' and `[]') are classified as parenthesis characters. - Syntax class: string quote "String quote characters" (designated with `"') are used in many languages, including Lisp and C, to delimit string constants. The same string quote character appears at the beginning and the end of a string. Such quoted strings do not nest. The parsing facilities of XEmacs consider a string as a single token. The usual syntactic meanings of the characters in the string are suppressed. The Lisp modes have two string quote characters: double-quote (`"') and vertical bar (`|'). `|' is not used in XEmacs Lisp, but it is used in Common Lisp. C also has two string quote characters: double-quote for strings, and single-quote (`'') for character constants. English text has no string quote characters because English is not a programming language. Although quotation marks are used in English, we do not want them to turn off the usual syntactic properties of other characters in the quotation. - Syntax class: escape An "escape character" (designated with `\') starts an escape sequence such as is used in C string and character constants. The character `\' belongs to this class in both C and Lisp. (In C, it is used thus only inside strings, but it turns out to cause no trouble to treat it this way throughout C code.) Characters in this class count as part of words if `words-include-escapes' is non-`nil'. *Note Word Motion::. - Syntax class: character quote A "character quote character" (designated with `/') quotes the following character so that it loses its normal syntactic meaning. This differs from an escape character in that only the character immediately following is ever affected. Characters in this class count as part of words if `words-include-escapes' is non-`nil'. *Note Word Motion::. This class is used for backslash in TeX mode. - Syntax class: paired delimiter "Paired delimiter characters" (designated with `$') are like string quote characters except that the syntactic properties of the characters between the delimiters are not suppressed. Only TeX mode uses a paired delimiter presently--the `$' that both enters and leaves math mode. - Syntax class: expression prefix An "expression prefix operator" (designated with `'') is used for syntactic operators that are part of an expression if they appear next to one. These characters in Lisp include the apostrophe, `'' (used for quoting), the comma, `,' (used in macros), and `#' (used in the read syntax for certain data types). - Syntax class: comment starter - Syntax class: comment ender The "comment starter" and "comment ender" characters are used in various languages to delimit comments. These classes are designated with `<' and `>', respectively. English text has no comment characters. In Lisp, the semicolon (`;') starts a comment and a newline or formfeed ends one. - Syntax class: inherit This syntax class does not specify a syntax. It says to look in the standard syntax table to find the syntax of this character. The designator for this syntax code is `@'.  File: lispref.info, Node: Syntax Flags, Prev: Syntax Class Table, Up: Syntax Descriptors Syntax Flags ------------ In addition to the classes, entries for characters in a syntax table can include flags. There are six possible flags, represented by the characters `1', `2', `3', `4', `b' and `p'. All the flags except `p' are used to describe multi-character comment delimiters. The digit flags indicate that a character can _also_ be part of a comment sequence, in addition to the syntactic properties associated with its character class. The flags are independent of the class and each other for the sake of characters such as `*' in C mode, which is a punctuation character, _and_ the second character of a start-of-comment sequence (`/*'), _and_ the first character of an end-of-comment sequence (`*/'). The flags for a character C are: * `1' means C is the start of a two-character comment-start sequence. * `2' means C is the second character of such a sequence. * `3' means C is the start of a two-character comment-end sequence. * `4' means C is the second character of such a sequence. * `b' means that C as a comment delimiter belongs to the alternative "b" comment style. Emacs supports two comment styles simultaneously in any one syntax table. This is for the sake of C++. Each style of comment syntax has its own comment-start sequence and its own comment-end sequence. Each comment must stick to one style or the other; thus, if it starts with the comment-start sequence of style "b", it must also end with the comment-end sequence of style "b". The two comment-start sequences must begin with the same character; only the second character may differ. Mark the second character of the "b"-style comment-start sequence with the `b' flag. A comment-end sequence (one or two characters) applies to the "b" style if its first character has the `b' flag set; otherwise, it applies to the "a" style. The appropriate comment syntax settings for C++ are as follows: `/' `124b' `*' `23' newline `>b' This defines four comment-delimiting sequences: `/*' This is a comment-start sequence for "a" style because the second character, `*', does not have the `b' flag. `//' This is a comment-start sequence for "b" style because the second character, `/', does have the `b' flag. `*/' This is a comment-end sequence for "a" style because the first character, `*', does not have the `b' flag newline This is a comment-end sequence for "b" style, because the newline character has the `b' flag. * `p' identifies an additional "prefix character" for Lisp syntax. These characters are treated as whitespace when they appear between expressions. When they appear within an expression, they are handled according to their usual syntax codes. The function `backward-prefix-chars' moves back over these characters, as well as over characters whose primary syntax class is prefix (`''). *Note Motion and Syntax::.  File: lispref.info, Node: Syntax Table Functions, Next: Motion and Syntax, Prev: Syntax Descriptors, Up: Syntax Tables Syntax Table Functions ====================== In this section we describe functions for creating, accessing and altering syntax tables. - Function: make-syntax-table &optional table This function creates a new syntax table. Character codes 0 through 31 and 128 through 255 are set up to inherit from the standard syntax table. The other character codes are set up by copying what the standard syntax table says about them. Most major mode syntax tables are created in this way. - Function: copy-syntax-table &optional table This function constructs a copy of TABLE and returns it. If TABLE is not supplied (or is `nil'), it returns a copy of the current syntax table. Otherwise, an error is signaled if TABLE is not a syntax table. - Command: modify-syntax-entry char syntax-descriptor &optional table This function sets the syntax entry for CHAR according to SYNTAX-DESCRIPTOR. The syntax is changed only for TABLE, which defaults to the current buffer's syntax table, and not in any other syntax table. The argument SYNTAX-DESCRIPTOR specifies the desired syntax; this is a string beginning with a class designator character, and optionally containing a matching character and flags as well. *Note Syntax Descriptors::. This function always returns `nil'. The old syntax information in the table for this character is discarded. An error is signaled if the first character of the syntax descriptor is not one of the twelve syntax class designator characters. An error is also signaled if CHAR is not a character. Examples: ;; Put the space character in class whitespace. (modify-syntax-entry ?\ " ") => nil ;; Make `$' an open parenthesis character, ;; with `^' as its matching close. (modify-syntax-entry ?$ "(^") => nil ;; Make `^' a close parenthesis character, ;; with `$' as its matching open. (modify-syntax-entry ?^ ")$") => nil ;; Make `/' a punctuation character, ;; the first character of a start-comment sequence, ;; and the second character of an end-comment sequence. ;; This is used in C mode. (modify-syntax-entry ?/ ". 14") => nil - Function: char-syntax character This function returns the syntax class of CHARACTER, represented by its mnemonic designator character. This _only_ returns the class, not any matching parenthesis or flags. An error is signaled if CHAR is not a character. The following examples apply to C mode. The first example shows that the syntax class of space is whitespace (represented by a space). The second example shows that the syntax of `/' is punctuation. This does not show the fact that it is also part of comment-start and -end sequences. The third example shows that open parenthesis is in the class of open parentheses. This does not show the fact that it has a matching character, `)'. (char-to-string (char-syntax ?\ )) => " " (char-to-string (char-syntax ?/)) => "." (char-to-string (char-syntax ?\()) => "(" - Function: set-syntax-table table &optional buffer This function makes TABLE the syntax table for BUFFER, which defaults to the current buffer if omitted. It returns TABLE. - Function: syntax-table &optional buffer This function returns the syntax table for BUFFER, which defaults to the current buffer if omitted.  File: lispref.info, Node: Motion and Syntax, Next: Parsing Expressions, Prev: Syntax Table Functions, Up: Syntax Tables Motion and Syntax ================= This section describes functions for moving across characters in certain syntax classes. None of these functions exists in Emacs version 18 or earlier. - Function: skip-syntax-forward syntaxes &optional limit buffer This function moves point forward across characters having syntax classes mentioned in SYNTAXES. It stops when it encounters the end of the buffer, or position LIMIT (if specified), or a character it is not supposed to skip. Optional argument BUFFER defaults to the current buffer if omitted. - Function: skip-syntax-backward syntaxes &optional limit buffer This function moves point backward across characters whose syntax classes are mentioned in SYNTAXES. It stops when it encounters the beginning of the buffer, or position LIMIT (if specified), or a character it is not supposed to skip. Optional argument BUFFER defaults to the current buffer if omitted. - Function: backward-prefix-chars &optional buffer This function moves point backward over any number of characters with expression prefix syntax. This includes both characters in the expression prefix syntax class, and characters with the `p' flag. Optional argument BUFFER defaults to the current buffer if omitted.