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emacs/doc/lispref/syntax.texi

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@c -*-texinfo-*-
@c This is part of the GNU Emacs Lisp Reference Manual.
@c Copyright (C) 1990-1995, 1998-1999, 2001-2011
@c Free Software Foundation, Inc.
@c See the file elisp.texi for copying conditions.
@setfilename ../../info/syntax
@node Syntax Tables, Abbrevs, Searching and Matching, Top
@chapter Syntax Tables
@cindex parsing buffer text
@cindex syntax table
@cindex text parsing
A @dfn{syntax table} specifies the syntactic textual function of each
character. This information is used by the @dfn{parsing functions}, 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 (@pxref{Word Motion})
and the list motion functions (@pxref{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.
* Syntax Properties:: Overriding syntax with text properties.
* 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.
* Categories:: Another way of classifying character syntax.
@end menu
@node Syntax Basics
@section Syntax Table Concepts
@ifnottex
A @dfn{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 (@pxref{Word Motion}) and the
list motion functions (@pxref{List Motion}) as well as the functions in
this chapter.
@end ifnottex
A syntax table is a char-table (@pxref{Char-Tables}). The element at
index @var{c} describes the character with code @var{c}. The element's
value should be a list that encodes the syntax of the character in
question.
Syntax tables are used only for moving across text, not for the Emacs
Lisp reader. Emacs Lisp uses built-in syntactic rules when reading Lisp
expressions, and these rules cannot be changed. (Some Lisp systems
provide ways to redefine the read syntax, but we decided to leave this
feature out of Emacs Lisp for simplicity.)
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 @samp{;} begins a comment, but in C mode, it
terminates a statement. To support these variations, Emacs 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.
@xref{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.'' Just changing the standard syntax for a
character affects all syntax tables that inherit from it.
@defun syntax-table-p object
This function returns @code{t} if @var{object} is a syntax table.
@end defun
@node Syntax Descriptors
@section Syntax Descriptors
@cindex syntax class
This section describes the syntax classes and flags that denote the
syntax of a character, and how they are represented as a @dfn{syntax
descriptor}, which is a Lisp string that you pass to
@code{modify-syntax-entry} to specify the syntax you want.
The syntax table specifies a syntax class for each character. 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 often assigned that class; however,
its meaning as a designator is unvarying and independent of what syntax
that character currently has. Thus, @samp{\} as a designator character
always gives ``escape character'' syntax, regardless of what syntax
@samp{\} currently has.
@cindex syntax descriptor
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 syntax descriptor for the character @samp{*} in C
mode is @samp{@w{. 23}} (i.e., punctuation, matching character slot
unused, second character of a comment-starter, first character of a
comment-ender), and the entry for @samp{/} is @samp{@w{. 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.
@end menu
@node Syntax Class Table
@subsection Table of Syntax Classes
Here is a table of syntax classes, the characters that stand for them,
their meanings, and examples of their use.
@deffn {Syntax class} @w{whitespace character}
@dfn{Whitespace characters} (designated by @w{@samp{@ }} or @samp{-})
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 classified as whitespace in almost all major
modes.
@end deffn
@deffn {Syntax class} @w{word constituent}
@dfn{Word constituents} (designated by @samp{w}) are parts of words in
human languages, and are typically used in variable and command names
in programs. All upper- and lower-case letters, and the digits, are
typically word constituents.
@end deffn
@deffn {Syntax class} @w{symbol constituent}
@dfn{Symbol constituents} (designated by @samp{_}) 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 @samp{$&*+-_<>}. In standard C, the only non-word-constituent
character that is valid in symbols is underscore (@samp{_}).
@end deffn
@deffn {Syntax class} @w{punctuation character}
@dfn{Punctuation characters} (designated by @samp{.}) 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.
Some programming language modes, such as Emacs Lisp mode, have no
characters in this class since the few characters that are not symbol or
word constituents all have other uses. Other programming language modes,
such as C mode, use punctuation syntax for operators.
@end deffn
@deffn {Syntax class} @w{open parenthesis character}
@deffnx {Syntax class} @w{close parenthesis character}
@cindex parenthesis syntax
Open and close @dfn{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, Emacs indicates momentarily the
matching open parenthesis when you insert a close parenthesis.
@xref{Blinking}.
The class of open parentheses is designated by @samp{(}, and that of
close parentheses by @samp{)}.
In English text, and in C code, the parenthesis pairs are @samp{()},
@samp{[]}, and @samp{@{@}}. In Emacs Lisp, the delimiters for lists and
vectors (@samp{()} and @samp{[]}) are classified as parenthesis
characters.
@end deffn
@deffn {Syntax class} @w{string quote}
@dfn{String quote characters} (designated by @samp{"}) 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 Emacs 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 (@samp{"})
and vertical bar (@samp{|}). @samp{|} is not used in Emacs Lisp, but it
is used in Common Lisp. C also has two string quote characters:
double-quote for strings, and single-quote (@samp{'}) 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.
@end deffn
@deffn {Syntax class} @w{escape-syntax character}
An @dfn{escape character} (designated by @samp{\}) starts an escape
sequence such as is used in C string and character constants. The
character @samp{\} 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
@code{words-include-escapes} is non-@code{nil}. @xref{Word Motion}.
@end deffn
@deffn {Syntax class} @w{character quote}
A @dfn{character quote character} (designated by @samp{/}) 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
@code{words-include-escapes} is non-@code{nil}. @xref{Word Motion}.
This class is used for backslash in @TeX{} mode.
@end deffn
@deffn {Syntax class} @w{paired delimiter}
@dfn{Paired delimiter characters} (designated by @samp{$}) 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 @samp{$} that both enters and
leaves math mode.
@end deffn
@deffn {Syntax class} @w{expression prefix}
An @dfn{expression prefix operator} (designated by @samp{'}) is used for
syntactic operators that are considered as part of an expression if they
appear next to one. In Lisp modes, these characters include the
apostrophe, @samp{'} (used for quoting), the comma, @samp{,} (used in
macros), and @samp{#} (used in the read syntax for certain data types).
@end deffn
@deffn {Syntax class} @w{comment starter}
@deffnx {Syntax class} @w{comment ender}
@cindex comment syntax
The @dfn{comment starter} and @dfn{comment ender} characters are used in
various languages to delimit comments. These classes are designated
by @samp{<} and @samp{>}, respectively.
English text has no comment characters. In Lisp, the semicolon
(@samp{;}) starts a comment and a newline or formfeed ends one.
@end deffn
@deffn {Syntax class} @w{inherit standard syntax}
This syntax class does not specify a particular syntax. It says to look
in the standard syntax table to find the syntax of this character. The
designator for this syntax class is @samp{@@}.
@end deffn
@deffn {Syntax class} @w{generic comment delimiter}
A @dfn{generic comment delimiter} (designated by @samp{!}) starts
or ends a special kind of comment. @emph{Any} generic comment delimiter
matches @emph{any} generic comment delimiter, but they cannot match
a comment starter or comment ender; generic comment delimiters can only
match each other.
This syntax class is primarily meant for use with the
@code{syntax-table} text property (@pxref{Syntax Properties}). You can
mark any range of characters as forming a comment, by giving the first
and last characters of the range @code{syntax-table} properties
identifying them as generic comment delimiters.
@end deffn
@deffn {Syntax class} @w{generic string delimiter}
A @dfn{generic string delimiter} (designated by @samp{|}) starts or ends
a string. This class differs from the string quote class in that @emph{any}
generic string delimiter can match any other generic string delimiter; but
they do not match ordinary string quote characters.
This syntax class is primarily meant for use with the
@code{syntax-table} text property (@pxref{Syntax Properties}). You can
mark any range of characters as forming a string constant, by giving the
first and last characters of the range @code{syntax-table} properties
identifying them as generic string delimiters.
@end deffn
@node Syntax Flags
@subsection Syntax Flags
@cindex syntax flags
In addition to the classes, entries for characters in a syntax table
can specify flags. There are eight possible flags, represented by the
characters @samp{1}, @samp{2}, @samp{3}, @samp{4}, @samp{b}, @samp{c},
@samp{n}, and @samp{p}.
All the flags except @samp{p} are used to describe comment
delimiters. The digit flags are used for comment delimiters made up
of 2 characters. They indicate that a character can @emph{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 @samp{*} in
C mode, which is a punctuation character, @emph{and} the second
character of a start-of-comment sequence (@samp{/*}), @emph{and} the
first character of an end-of-comment sequence (@samp{*/}). The flags
@samp{b}, @samp{c}, and @samp{n} are used to qualify the corresponding
comment delimiter.
Here is a table of the possible flags for a character @var{c},
and what they mean:
@itemize @bullet
@item
@samp{1} means @var{c} is the start of a two-character comment-start
sequence.
@item
@samp{2} means @var{c} is the second character of such a sequence.
@item
@samp{3} means @var{c} is the start of a two-character comment-end
sequence.
@item
@samp{4} means @var{c} is the second character of such a sequence.
@item
@samp{b} means that @var{c} as a comment delimiter belongs to the
alternative ``b'' comment style. For a two-character comment starter,
this flag is only significant on the second char, and for a 2-character
comment ender it is only significant on the first char.
@item
@samp{c} means that @var{c} as a comment delimiter belongs to the
alternative ``c'' comment style. For a two-character comment
delimiter, @samp{c} on either character makes it of style ``c''.
@item
@samp{n} on a comment delimiter character specifies
that this kind of comment can be nested. For a two-character
comment delimiter, @samp{n} on either character makes it
nestable.
Emacs supports several comment styles simultaneously in any one syntax
table. A comment style is a set of flags @samp{b}, @samp{c}, and
@samp{n}, so there can be up to 8 different comment styles.
Each comment delimiter has a style and only matches comment delimiters
of the same style. Thus if a comment starts with the comment-start
sequence of style ``bn'', it will extend until the next matching
comment-end sequence of style ``bn''.
The appropriate comment syntax settings for C++ can be as follows:
@table @asis
@item @samp{/}
@samp{124}
@item @samp{*}
@samp{23b}
@item newline
@samp{>}
@end table
This defines four comment-delimiting sequences:
@table @asis
@item @samp{/*}
This is a comment-start sequence for ``b'' style because the
second character, @samp{*}, has the @samp{b} flag.
@item @samp{//}
This is a comment-start sequence for ``a'' style because the second
character, @samp{/}, does not have the @samp{b} flag.
@item @samp{*/}
This is a comment-end sequence for ``b'' style because the first
character, @samp{*}, does have the @samp{b} flag.
@item newline
This is a comment-end sequence for ``a'' style, because the newline
character does not have the @samp{b} flag.
@end table
@item
@c Emacs 19 feature
@samp{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 classes.
The function @code{backward-prefix-chars} moves back over these
characters, as well as over characters whose primary syntax class is
prefix (@samp{'}). @xref{Motion and Syntax}.
@end itemize
@node Syntax Table Functions
@section Syntax Table Functions
In this section we describe functions for creating, accessing and
altering syntax tables.
@defun make-syntax-table &optional table
This function creates a new syntax table, with all values initialized
to @code{nil}. If @var{table} is non-@code{nil}, it becomes the
parent of the new syntax table, otherwise the standard syntax table is
the parent. Like all char-tables, a syntax table inherits from its
parent. Thus the original syntax of all characters in the returned
syntax table is determined by the parent. @xref{Char-Tables}.
Most major mode syntax tables are created in this way.
@end defun
@defun copy-syntax-table &optional table
This function constructs a copy of @var{table} and returns it. If
@var{table} is not supplied (or is @code{nil}), it returns a copy of the
standard syntax table. Otherwise, an error is signaled if @var{table} is
not a syntax table.
@end defun
@deffn Command modify-syntax-entry char syntax-descriptor &optional table
This function sets the syntax entry for @var{char} according to
@var{syntax-descriptor}. @var{char} can be a character, or a cons
cell of the form @code{(@var{min} . @var{max})}; in the latter case,
the function sets the syntax entries for all characters in the range
between @var{min} and @var{max}, inclusive.
The syntax is changed only for @var{table}, which defaults to the
current buffer's syntax table, and not in any other syntax table. The
argument @var{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. @xref{Syntax
Descriptors}.
This function always returns @code{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 seventeen syntax class designator characters. An error is also
signaled if @var{char} is not a character.
@example
@group
@exdent @r{Examples:}
;; @r{Put the space character in class whitespace.}
(modify-syntax-entry ?\s " ")
@result{} nil
@end group
@group
;; @r{Make @samp{$} an open parenthesis character,}
;; @r{with @samp{^} as its matching close.}
(modify-syntax-entry ?$ "(^")
@result{} nil
@end group
@group
;; @r{Make @samp{^} a close parenthesis character,}
;; @r{with @samp{$} as its matching open.}
(modify-syntax-entry ?^ ")$")
@result{} nil
@end group
@group
;; @r{Make @samp{/} a punctuation character,}
;; @r{the first character of a start-comment sequence,}
;; @r{and the second character of an end-comment sequence.}
;; @r{This is used in C mode.}
(modify-syntax-entry ?/ ". 14")
@result{} nil
@end group
@end example
@end deffn
@defun char-syntax character
This function returns the syntax class of @var{character}, represented
by its mnemonic designator character. This returns @emph{only} the
class, not any matching parenthesis or flags.
An error is signaled if @var{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 @samp{/} 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, @samp{)}.
@example
@group
(string (char-syntax ?\s))
@result{} " "
@end group
@group
(string (char-syntax ?/))
@result{} "."
@end group
@group
(string (char-syntax ?\())
@result{} "("
@end group
@end example
We use @code{string} to make it easier to see the character returned by
@code{char-syntax}.
@end defun
@defun set-syntax-table table
This function makes @var{table} the syntax table for the current buffer.
It returns @var{table}.
@end defun
@defun syntax-table
This function returns the current syntax table, which is the table for
the current buffer.
@end defun
@defmac with-syntax-table @var{table} @var{body}@dots{}
This macro executes @var{body} using @var{table} as the current syntax
table. It returns the value of the last form in @var{body}, after
restoring the old current syntax table.
Since each buffer has its own current syntax table, we should make that
more precise: @code{with-syntax-table} temporarily alters the current
syntax table of whichever buffer is current at the time the macro
execution starts. Other buffers are not affected.
@end defmac
@node Syntax Properties
@section Syntax Properties
@kindex syntax-table @r{(text property)}
When the syntax table is not flexible enough to specify the syntax of
a language, you can use @code{syntax-table} text properties to
override the syntax table for specific character occurrences in the
buffer. @xref{Text Properties}. You can use Font Lock mode to set
@code{syntax-table} text properties. @xref{Setting Syntax
Properties}.
The valid values of @code{syntax-table} text property are:
@table @asis
@item @var{syntax-table}
If the property value is a syntax table, that table is used instead of
the current buffer's syntax table to determine the syntax for this
occurrence of the character.
@item @code{(@var{syntax-code} . @var{matching-char})}
A cons cell of this format specifies the syntax for this
occurrence of the character. (@pxref{Syntax Table Internals})
@item @code{nil}
If the property is @code{nil}, the character's syntax is determined from
the current syntax table in the usual way.
@end table
@defvar parse-sexp-lookup-properties
If this is non-@code{nil}, the syntax scanning functions pay attention
to syntax text properties. Otherwise they use only the current syntax
table.
@end defvar
@node Motion and Syntax
@section Motion and Syntax
This section describes functions for moving across characters that
have certain syntax classes.
@defun skip-syntax-forward syntaxes &optional limit
This function moves point forward across characters having syntax
classes mentioned in @var{syntaxes} (a string of syntax class
characters). It stops when it encounters the end of the buffer, or
position @var{limit} (if specified), or a character it is not supposed
to skip.
If @var{syntaxes} starts with @samp{^}, then the function skips
characters whose syntax is @emph{not} in @var{syntaxes}.
The return value is the distance traveled, which is a nonnegative
integer.
@end defun
@defun skip-syntax-backward syntaxes &optional limit
This function moves point backward across characters whose syntax
classes are mentioned in @var{syntaxes}. It stops when it encounters
the beginning of the buffer, or position @var{limit} (if specified), or
a character it is not supposed to skip.
If @var{syntaxes} starts with @samp{^}, then the function skips
characters whose syntax is @emph{not} in @var{syntaxes}.
The return value indicates the distance traveled. It is an integer that
is zero or less.
@end defun
@defun backward-prefix-chars
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 @samp{p} flag.
@end defun
@node Parsing Expressions
@section Parsing Expressions
This section describes functions for parsing and scanning balanced
expressions, also known as @dfn{sexps}. Basically, a sexp is either a
balanced parenthetical grouping, a string, or a symbol name (a
sequence of characters whose syntax is either word constituent or
symbol constituent). However, characters whose syntax is expression
prefix are treated as part of the sexp if they appear next to it.
The syntax table controls the interpretation of characters, so these
functions can be used for Lisp expressions when in Lisp mode and for C
expressions when in C mode. @xref{List Motion}, for convenient
higher-level functions for moving over balanced expressions.
A character's syntax controls how it changes the state of the
parser, rather than describing the state itself. For example, a
string delimiter character toggles the parser state between
``in-string'' and ``in-code,'' but the syntax of characters does not
directly say whether they are inside a string. For example (note that
15 is the syntax code for generic string delimiters),
@example
(put-text-property 1 9 'syntax-table '(15 . nil))
@end example
@noindent
does not tell Emacs that the first eight chars of the current buffer
are a string, but rather that they are all string delimiters. As a
result, Emacs treats them as four consecutive empty string constants.
@menu
* Motion via Parsing:: Motion functions that work by parsing.
* Position Parse:: Determining the syntactic state of a position.
* Parser State:: How Emacs represents a syntactic state.
* Low-Level Parsing:: Parsing across a specified region.
* Control Parsing:: Parameters that affect parsing.
@end menu
@node Motion via Parsing
@subsection Motion Commands Based on Parsing
This section describes simple point-motion functions that operate
based on parsing expressions.
@defun scan-lists from count depth
This function scans forward @var{count} balanced parenthetical groupings
from position @var{from}. It returns the position where the scan stops.
If @var{count} is negative, the scan moves backwards.
If @var{depth} is nonzero, parenthesis depth counting begins from that
value. The only candidates for stopping are places where the depth in
parentheses becomes zero; @code{scan-lists} counts @var{count} such
places and then stops. Thus, a positive value for @var{depth} means go
out @var{depth} levels of parenthesis.
Scanning ignores comments if @code{parse-sexp-ignore-comments} is
non-@code{nil}.
If the scan reaches the beginning or end of the buffer (or its
accessible portion), and the depth is not zero, an error is signaled.
If the depth is zero but the count is not used up, @code{nil} is
returned.
@end defun
@defun scan-sexps from count
This function scans forward @var{count} sexps from position @var{from}.
It returns the position where the scan stops. If @var{count} is
negative, the scan moves backwards.
Scanning ignores comments if @code{parse-sexp-ignore-comments} is
non-@code{nil}.
If the scan reaches the beginning or end of (the accessible part of) the
buffer while in the middle of a parenthetical grouping, an error is
signaled. If it reaches the beginning or end between groupings but
before count is used up, @code{nil} is returned.
@end defun
@defun forward-comment count
This function moves point forward across @var{count} complete comments
(that is, including the starting delimiter and the terminating
delimiter if any), plus any whitespace encountered on the way. It
moves backward if @var{count} is negative. If it encounters anything
other than a comment or whitespace, it stops, leaving point at the
place where it stopped. This includes (for instance) finding the end
of a comment when moving forward and expecting the beginning of one.
The function also stops immediately after moving over the specified
number of complete comments. If @var{count} comments are found as
expected, with nothing except whitespace between them, it returns
@code{t}; otherwise it returns @code{nil}.
This function cannot tell whether the ``comments'' it traverses are
embedded within a string. If they look like comments, it treats them
as comments.
@end defun
To move forward over all comments and whitespace following point, use
@code{(forward-comment (buffer-size))}. @code{(buffer-size)} is a good
argument to use, because the number of comments in the buffer cannot
exceed that many.
@node Position Parse
@subsection Finding the Parse State for a Position
For syntactic analysis, such as in indentation, often the useful
thing is to compute the syntactic state corresponding to a given buffer
position. This function does that conveniently.
@defun syntax-ppss &optional pos
This function returns the parser state (see next section) that the
parser would reach at position @var{pos} starting from the beginning
of the buffer. This is equivalent to @code{(parse-partial-sexp
(point-min) @var{pos})}, except that @code{syntax-ppss} uses a cache
to speed up the computation. Due to this optimization, the 2nd value
(previous complete subexpression) and 6th value (minimum parenthesis
depth) of the returned parser state are not meaningful.
@end defun
@code{syntax-ppss} automatically hooks itself to
@code{before-change-functions} to keep its cache consistent. But
updating can fail if @code{syntax-ppss} is called while
@code{before-change-functions} is temporarily let-bound, or if the
buffer is modified without obeying the hook, such as when using
@code{inhibit-modification-hooks}. For this reason, it is sometimes
necessary to flush the cache manually.
@defun syntax-ppss-flush-cache beg &rest ignored-args
This function flushes the cache used by @code{syntax-ppss}, starting
at position @var{beg}. The remaining arguments, @var{ignored-args},
are ignored; this function accepts them so that it can be directly
used on hooks such as @code{before-change-functions} (@pxref{Change
Hooks}).
@end defun
Major modes can make @code{syntax-ppss} run faster by specifying
where it needs to start parsing.
@defvar syntax-begin-function
If this is non-@code{nil}, it should be a function that moves to an
earlier buffer position where the parser state is equivalent to
@code{nil}---in other words, a position outside of any comment,
string, or parenthesis. @code{syntax-ppss} uses it to further
optimize its computations, when the cache gives no help.
@end defvar
@node Parser State
@subsection Parser State
@cindex parser state
A @dfn{parser state} is a list of ten elements describing the final
state of parsing text syntactically as part of an expression. The
parsing functions in the following sections return a parser state as
the value, and in some cases accept one as an argument also, so that
you can resume parsing after it stops. Here are the meanings of the
elements of the parser state:
@enumerate 0
@item
The depth in parentheses, counting from 0. @strong{Warning:} this can
be negative if there are more close parens than open parens between
the start of the defun and point.
@item
@cindex innermost containing parentheses
The character position of the start of the innermost parenthetical
grouping containing the stopping point; @code{nil} if none.
@item
@cindex previous complete subexpression
The character position of the start of the last complete subexpression
terminated; @code{nil} if none.
@item
@cindex inside string
Non-@code{nil} if inside a string. More precisely, this is the
character that will terminate the string, or @code{t} if a generic
string delimiter character should terminate it.
@item
@cindex inside comment
@code{t} if inside a comment (of either style),
or the comment nesting level if inside a kind of comment
that can be nested.
@item
@cindex quote character
@code{t} if point is just after a quote character.
@item
The minimum parenthesis depth encountered during this scan.
@item
What kind of comment is active: @code{nil} for a comment of style
``a'' or when not inside a comment, @code{t} for a comment of style
``b,'' and @code{syntax-table} for a comment that should be ended by a
generic comment delimiter character.
@item
The string or comment start position. While inside a comment, this is
the position where the comment began; while inside a string, this is the
position where the string began. When outside of strings and comments,
this element is @code{nil}.
@item
Internal data for continuing the parsing. The meaning of this
data is subject to change; it is used if you pass this list
as the @var{state} argument to another call.
@end enumerate
Elements 1, 2, and 6 are ignored in a state which you pass as an
argument to continue parsing, and elements 8 and 9 are used only in
trivial cases. Those elements serve primarily to convey information
to the Lisp program which does the parsing.
One additional piece of useful information is available from a
parser state using this function:
@defun syntax-ppss-toplevel-pos state
This function extracts, from parser state @var{state}, the last
position scanned in the parse which was at top level in grammatical
structure. ``At top level'' means outside of any parentheses,
comments, or strings.
The value is @code{nil} if @var{state} represents a parse which has
arrived at a top level position.
@end defun
We have provided this access function rather than document how the
data is represented in the state, because we plan to change the
representation in the future.
@node Low-Level Parsing
@subsection Low-Level Parsing
The most basic way to use the expression parser is to tell it
to start at a given position with a certain state, and parse up to
a specified end position.
@defun parse-partial-sexp start limit &optional target-depth stop-before state stop-comment
This function parses a sexp in the current buffer starting at
@var{start}, not scanning past @var{limit}. It stops at position
@var{limit} or when certain criteria described below are met, and sets
point to the location where parsing stops. It returns a parser state
describing the status of the parse at the point where it stops.
@cindex parenthesis depth
If the third argument @var{target-depth} is non-@code{nil}, parsing
stops if the depth in parentheses becomes equal to @var{target-depth}.
The depth starts at 0, or at whatever is given in @var{state}.
If the fourth argument @var{stop-before} is non-@code{nil}, parsing
stops when it comes to any character that starts a sexp. If
@var{stop-comment} is non-@code{nil}, parsing stops when it comes to the
start of a comment. If @var{stop-comment} is the symbol
@code{syntax-table}, parsing stops after the start of a comment or a
string, or the end of a comment or a string, whichever comes first.
If @var{state} is @code{nil}, @var{start} is assumed to be at the top
level of parenthesis structure, such as the beginning of a function
definition. Alternatively, you might wish to resume parsing in the
middle of the structure. To do this, you must provide a @var{state}
argument that describes the initial status of parsing. The value
returned by a previous call to @code{parse-partial-sexp} will do
nicely.
@end defun
@node Control Parsing
@subsection Parameters to Control Parsing
@defvar multibyte-syntax-as-symbol
If this variable is non-@code{nil}, @code{scan-sexps} treats all
non-@acronym{ASCII} characters as symbol constituents regardless
of what the syntax table says about them. (However, text properties
can still override the syntax.)
@end defvar
@defopt parse-sexp-ignore-comments
@cindex skipping comments
If the value is non-@code{nil}, then comments are treated as
whitespace by the functions in this section and by @code{forward-sexp},
@code{scan-lists} and @code{scan-sexps}.
@end defopt
@vindex parse-sexp-lookup-properties
The behavior of @code{parse-partial-sexp} is also affected by
@code{parse-sexp-lookup-properties} (@pxref{Syntax Properties}).
You can use @code{forward-comment} to move forward or backward over
one comment or several comments.
@node Standard Syntax Tables
@section Some Standard Syntax Tables
Most of the major modes in Emacs have their own syntax tables. Here
are several of them:
@defun standard-syntax-table
This function returns the standard syntax table, which is the syntax
table used in Fundamental mode.
@end defun
@defvar text-mode-syntax-table
The value of this variable is the syntax table used in Text mode.
@end defvar
@defvar c-mode-syntax-table
The value of this variable is the syntax table for C-mode buffers.
@end defvar
@defvar emacs-lisp-mode-syntax-table
The value of this variable is the syntax table used in Emacs Lisp mode
by editing commands. (It has no effect on the Lisp @code{read}
function.)
@end defvar
@node Syntax Table Internals
@section Syntax Table Internals
@cindex syntax table internals
Lisp programs don't usually work with the elements directly; the
Lisp-level syntax table functions usually work with syntax descriptors
(@pxref{Syntax Descriptors}). Nonetheless, here we document the
internal format. This format is used mostly when manipulating
syntax properties.
Each element of a syntax table is a cons cell of the form
@code{(@var{syntax-code} . @var{matching-char})}. The @sc{car},
@var{syntax-code}, is an integer that encodes the syntax class, and any
flags. The @sc{cdr}, @var{matching-char}, is non-@code{nil} if
a character to match was specified.
This table gives the value of @var{syntax-code} which corresponds
to each syntactic type.
@multitable @columnfractions .05 .3 .3 .31
@item
@tab
@i{Integer} @i{Class}
@tab
@i{Integer} @i{Class}
@tab
@i{Integer} @i{Class}
@item
@tab
0 @ @ whitespace
@tab
5 @ @ close parenthesis
@tab
10 @ @ character quote
@item
@tab
1 @ @ punctuation
@tab
6 @ @ expression prefix
@tab
11 @ @ comment-start
@item
@tab
2 @ @ word
@tab
7 @ @ string quote
@tab
12 @ @ comment-end
@item
@tab
3 @ @ symbol
@tab
8 @ @ paired delimiter
@tab
13 @ @ inherit
@item
@tab
4 @ @ open parenthesis
@tab
9 @ @ escape
@tab
14 @ @ generic comment
@item
@tab
15 @ generic string
@end multitable
For example, the usual syntax value for @samp{(} is @code{(4 . 41)}.
(41 is the character code for @samp{)}.)
The flags are encoded in higher order bits, starting 16 bits from the
least significant bit. This table gives the power of two which
corresponds to each syntax flag.
@multitable @columnfractions .05 .3 .3 .3
@item
@tab
@i{Prefix} @i{Flag}
@tab
@i{Prefix} @i{Flag}
@tab
@i{Prefix} @i{Flag}
@item
@tab
@samp{1} @ @ @code{(lsh 1 16)}
@tab
@samp{4} @ @ @code{(lsh 1 19)}
@tab
@samp{b} @ @ @code{(lsh 1 21)}
@item
@tab
@samp{2} @ @ @code{(lsh 1 17)}
@tab
@samp{p} @ @ @code{(lsh 1 20)}
@tab
@samp{n} @ @ @code{(lsh 1 22)}
@item
@tab
@samp{3} @ @ @code{(lsh 1 18)}
@end multitable
@defun string-to-syntax @var{desc}
This function returns the internal form corresponding to the syntax
descriptor @var{desc}, a cons cell @code{(@var{syntax-code}
. @var{matching-char})}.
@end defun
@defun syntax-after pos
This function returns the syntax code of the character in the buffer
after position @var{pos}, taking account of syntax properties as well
as the syntax table. If @var{pos} is outside the buffer's accessible
portion (@pxref{Narrowing, accessible portion}), this function returns
@code{nil}.
@end defun
@defun syntax-class syntax
This function returns the syntax class of the syntax code
@var{syntax}. (It masks off the high 16 bits that hold the flags
encoded in the syntax descriptor.) If @var{syntax} is @code{nil}, it
returns @code{nil}; this is so evaluating the expression
@example
(syntax-class (syntax-after pos))
@end example
@noindent
where @code{pos} is outside the buffer's accessible portion, will
yield @code{nil} without throwing errors or producing wrong syntax
class codes.
@end defun
@node Categories
@section Categories
@cindex categories of characters
@cindex character categories
@dfn{Categories} provide an alternate way of classifying characters
syntactically. You can define several categories as needed, then
independently assign each character to one or more categories. Unlike
syntax classes, categories are not mutually exclusive; it is normal for
one character to belong to several categories.
@cindex category table
Each buffer has a @dfn{category table} which records which categories
are defined and also which characters belong to each category. Each
category table defines its own categories, but normally these are
initialized by copying from the standard categories table, so that the
standard categories are available in all modes.
Each category has a name, which is an @acronym{ASCII} printing character in
the range @w{@samp{ }} to @samp{~}. You specify the name of a category
when you define it with @code{define-category}.
The category table is actually a char-table (@pxref{Char-Tables}).
The element of the category table at index @var{c} is a @dfn{category
set}---a bool-vector---that indicates which categories character @var{c}
belongs to. In this category set, if the element at index @var{cat} is
@code{t}, that means category @var{cat} is a member of the set, and that
character @var{c} belongs to category @var{cat}.
For the next three functions, the optional argument @var{table}
defaults to the current buffer's category table.
@defun define-category char docstring &optional table
This function defines a new category, with name @var{char} and
documentation @var{docstring}, for the category table @var{table}.
@end defun
@defun category-docstring category &optional table
This function returns the documentation string of category @var{category}
in category table @var{table}.
@example
(category-docstring ?a)
@result{} "ASCII"
(category-docstring ?l)
@result{} "Latin"
@end example
@end defun
@defun get-unused-category &optional table
This function returns a category name (a character) which is not
currently defined in @var{table}. If all possible categories are in use
in @var{table}, it returns @code{nil}.
@end defun
@defun category-table
This function returns the current buffer's category table.
@end defun
@defun category-table-p object
This function returns @code{t} if @var{object} is a category table,
otherwise @code{nil}.
@end defun
@defun standard-category-table
This function returns the standard category table.
@end defun
@defun copy-category-table &optional table
This function constructs a copy of @var{table} and returns it. If
@var{table} is not supplied (or is @code{nil}), it returns a copy of the
standard category table. Otherwise, an error is signaled if @var{table}
is not a category table.
@end defun
@defun set-category-table table
This function makes @var{table} the category table for the current
buffer. It returns @var{table}.
@end defun
@defun make-category-table
This creates and returns an empty category table. In an empty category
table, no categories have been allocated, and no characters belong to
any categories.
@end defun
@defun make-category-set categories
This function returns a new category set---a bool-vector---whose initial
contents are the categories listed in the string @var{categories}. The
elements of @var{categories} should be category names; the new category
set has @code{t} for each of those categories, and @code{nil} for all
other categories.
@example
(make-category-set "al")
@result{} #&128"\0\0\0\0\0\0\0\0\0\0\0\0\2\20\0\0"
@end example
@end defun
@defun char-category-set char
This function returns the category set for character @var{char} in the
current buffer's category table. This is the bool-vector which
records which categories the character @var{char} belongs to. The
function @code{char-category-set} does not allocate storage, because
it returns the same bool-vector that exists in the category table.
@example
(char-category-set ?a)
@result{} #&128"\0\0\0\0\0\0\0\0\0\0\0\0\2\20\0\0"
@end example
@end defun
@defun category-set-mnemonics category-set
This function converts the category set @var{category-set} into a string
containing the characters that designate the categories that are members
of the set.
@example
(category-set-mnemonics (char-category-set ?a))
@result{} "al"
@end example
@end defun
@defun modify-category-entry char category &optional table reset
This function modifies the category set of @var{char} in category
table @var{table} (which defaults to the current buffer's category
table). @var{char} can be a character, or a cons cell of the form
@code{(@var{min} . @var{max})}; in the latter case, the function
modifies the category sets of all characters in the range between
@var{min} and @var{max}, inclusive.
Normally, it modifies a category set by adding @var{category} to it.
But if @var{reset} is non-@code{nil}, then it deletes @var{category}
instead.
@end defun
@deffn Command describe-categories &optional buffer-or-name
This function describes the category specifications in the current
category table. It inserts the descriptions in a buffer, and then
displays that buffer. If @var{buffer-or-name} is non-@code{nil}, it
describes the category table of that buffer instead.
@end deffn