1
0
mirror of https://git.savannah.gnu.org/git/emacs.git synced 2024-12-14 09:39:42 +00:00
emacs/doc/lispref/modes.texi
2018-01-31 19:59:12 +01:00

4190 lines
168 KiB
Plaintext

@c -*-texinfo-*-
@c This is part of the GNU Emacs Lisp Reference Manual.
@c Copyright (C) 1990-1995, 1998-1999, 2001-2018 Free Software
@c Foundation, Inc.
@c See the file elisp.texi for copying conditions.
@node Modes
@chapter Major and Minor Modes
@cindex mode
A @dfn{mode} is a set of definitions that customize Emacs behavior
in useful ways. There are two varieties of modes: @dfn{minor modes},
which provide features that users can turn on and off while editing;
and @dfn{major modes}, which are used for editing or interacting with
a particular kind of text. Each buffer has exactly one @dfn{major
mode} at a time.
This chapter describes how to write both major and minor modes, how to
indicate them in the mode line, and how they run hooks supplied by the
user. For related topics such as keymaps and syntax tables, see
@ref{Keymaps}, and @ref{Syntax Tables}.
@menu
* Hooks:: How to use hooks; how to write code that provides hooks.
* Major Modes:: Defining major modes.
* Minor Modes:: Defining minor modes.
* Mode Line Format:: Customizing the text that appears in the mode line.
* Imenu:: Providing a menu of definitions made in a buffer.
* Font Lock Mode:: How modes can highlight text according to syntax.
* Auto-Indentation:: How to teach Emacs to indent for a major mode.
* Desktop Save Mode:: How modes can have buffer state saved between
Emacs sessions.
@end menu
@node Hooks
@section Hooks
@cindex hooks
A @dfn{hook} is a variable where you can store a function or functions
to be called on a particular occasion by an existing program. Emacs
provides hooks for the sake of customization. Most often, hooks are set
up in the init file (@pxref{Init File}), but Lisp programs can set them also.
@xref{Standard Hooks}, for a list of some standard hook variables.
@cindex normal hook
Most of the hooks in Emacs are @dfn{normal hooks}. These variables
contain lists of functions to be called with no arguments. By
convention, whenever the hook name ends in @samp{-hook}, that tells
you it is normal. We try to make all hooks normal, as much as
possible, so that you can use them in a uniform way.
Every major mode command is supposed to run a normal hook called the
@dfn{mode hook} as one of the last steps of initialization. This makes
it easy for a user to customize the behavior of the mode, by overriding
the buffer-local variable assignments already made by the mode. Most
minor mode functions also run a mode hook at the end. But hooks are
used in other contexts too. For example, the hook @code{suspend-hook}
runs just before Emacs suspends itself (@pxref{Suspending Emacs}).
The recommended way to add a hook function to a hook is by calling
@code{add-hook} (@pxref{Setting Hooks}). The hook functions may be any
of the valid kinds of functions that @code{funcall} accepts (@pxref{What
Is a Function}). Most normal hook variables are initially void;
@code{add-hook} knows how to deal with this. You can add hooks either
globally or buffer-locally with @code{add-hook}.
@cindex abnormal hook
If the hook variable's name does not end with @samp{-hook}, that
indicates it is probably an @dfn{abnormal hook}. That means the hook
functions are called with arguments, or their return values are used
in some way. The hook's documentation says how the functions are
called. You can use @code{add-hook} to add a function to an abnormal
hook, but you must write the function to follow the hook's calling
convention. By convention, abnormal hook names end in @samp{-functions}.
@cindex single-function hook
If the variable's name ends in @samp{-function}, then its value is
just a single function, not a list of functions. @code{add-hook} cannot be
used to modify such a @emph{single function hook}, and you have to use
@code{add-function} instead (@pxref{Advising Functions}).
@menu
* Running Hooks:: How to run a hook.
* Setting Hooks:: How to put functions on a hook, or remove them.
@end menu
@node Running Hooks
@subsection Running Hooks
In this section, we document the @code{run-hooks} function, which is
used to run a normal hook. We also document the functions for running
various kinds of abnormal hooks.
@defun run-hooks &rest hookvars
This function takes one or more normal hook variable names as
arguments, and runs each hook in turn. Each argument should be a
symbol that is a normal hook variable. These arguments are processed
in the order specified.
If a hook variable has a non-@code{nil} value, that value should be a
list of functions. @code{run-hooks} calls all the functions, one by
one, with no arguments.
The hook variable's value can also be a single function---either a
lambda expression or a symbol with a function definition---which
@code{run-hooks} calls. But this usage is obsolete.
If the hook variable is buffer-local, the buffer-local variable will
be used instead of the global variable. However, if the buffer-local
variable contains the element @code{t}, the global hook variable will
be run as well.
@end defun
@defun run-hook-with-args hook &rest args
This function runs an abnormal hook by calling all the hook functions in
@var{hook}, passing each one the arguments @var{args}.
@end defun
@defun run-hook-with-args-until-failure hook &rest args
This function runs an abnormal hook by calling each hook function in
turn, stopping if one of them fails by returning @code{nil}. Each
hook function is passed the arguments @var{args}. If this function
stops because one of the hook functions fails, it returns @code{nil};
otherwise it returns a non-@code{nil} value.
@end defun
@defun run-hook-with-args-until-success hook &rest args
This function runs an abnormal hook by calling each hook function,
stopping if one of them succeeds by returning a non-@code{nil}
value. Each hook function is passed the arguments @var{args}. If this
function stops because one of the hook functions returns a
non-@code{nil} value, it returns that value; otherwise it returns
@code{nil}.
@end defun
@node Setting Hooks
@subsection Setting Hooks
Here's an example that uses a mode hook to turn on Auto Fill mode when
in Lisp Interaction mode:
@example
(add-hook 'lisp-interaction-mode-hook 'auto-fill-mode)
@end example
@defun add-hook hook function &optional append local
This function is the handy way to add function @var{function} to hook
variable @var{hook}. You can use it for abnormal hooks as well as for
normal hooks. @var{function} can be any Lisp function that can accept
the proper number of arguments for @var{hook}. For example,
@example
(add-hook 'text-mode-hook 'my-text-hook-function)
@end example
@noindent
adds @code{my-text-hook-function} to the hook called @code{text-mode-hook}.
If @var{function} is already present in @var{hook} (comparing using
@code{equal}), then @code{add-hook} does not add it a second time.
If @var{function} has a non-@code{nil} property
@code{permanent-local-hook}, then @code{kill-all-local-variables} (or
changing major modes) won't delete it from the hook variable's local
value.
For a normal hook, hook functions should be designed so that the order
in which they are executed does not matter. Any dependence on the order
is asking for trouble. However, the order is predictable: normally,
@var{function} goes at the front of the hook list, so it is executed
first (barring another @code{add-hook} call). If the optional argument
@var{append} is non-@code{nil}, the new hook function goes at the end of
the hook list and is executed last.
@code{add-hook} can handle the cases where @var{hook} is void or its
value is a single function; it sets or changes the value to a list of
functions.
If @var{local} is non-@code{nil}, that says to add @var{function} to the
buffer-local hook list instead of to the global hook list. This makes
the hook buffer-local and adds @code{t} to the buffer-local value. The
latter acts as a flag to run the hook functions in the default value as
well as in the local value.
@end defun
@defun remove-hook hook function &optional local
This function removes @var{function} from the hook variable
@var{hook}. It compares @var{function} with elements of @var{hook}
using @code{equal}, so it works for both symbols and lambda
expressions.
If @var{local} is non-@code{nil}, that says to remove @var{function}
from the buffer-local hook list instead of from the global hook list.
@end defun
@node Major Modes
@section Major Modes
@cindex major mode
@cindex major mode command
Major modes specialize Emacs for editing or interacting with
particular kinds of text. Each buffer has exactly one major mode at a
time. Every major mode is associated with a @dfn{major mode command},
whose name should end in @samp{-mode}. This command takes care of
switching to that mode in the current buffer, by setting various
buffer-local variables such as a local keymap. @xref{Major Mode
Conventions}. Note that unlike minor modes there is no way to ``turn
off'' a major mode, instead the buffer must be switched to a different
one.
The least specialized major mode is called @dfn{Fundamental mode},
which has no mode-specific definitions or variable settings.
@deffn Command fundamental-mode
This is the major mode command for Fundamental mode. Unlike other mode
commands, it does @emph{not} run any mode hooks (@pxref{Major Mode
Conventions}), since you are not supposed to customize this mode.
@end deffn
The easiest way to write a major mode is to use the macro
@code{define-derived-mode}, which sets up the new mode as a variant of
an existing major mode. @xref{Derived Modes}. We recommend using
@code{define-derived-mode} even if the new mode is not an obvious
derivative of another mode, as it automatically enforces many coding
conventions for you. @xref{Basic Major Modes}, for common modes to
derive from.
The standard GNU Emacs Lisp directory tree contains the code for
several major modes, in files such as @file{text-mode.el},
@file{texinfo.el}, @file{lisp-mode.el}, and @file{rmail.el}. You can
study these libraries to see how modes are written.
@defopt major-mode
The buffer-local value of this variable holds the symbol for the current
major mode. Its default value holds the default major mode for new
buffers. The standard default value is @code{fundamental-mode}.
If the default value is @code{nil}, then whenever Emacs creates a new
buffer via a command such as @kbd{C-x b} (@code{switch-to-buffer}), the
new buffer is put in the major mode of the previously current buffer.
As an exception, if the major mode of the previous buffer has a
@code{mode-class} symbol property with value @code{special}, the new
buffer is put in Fundamental mode (@pxref{Major Mode Conventions}).
@end defopt
@menu
* Major Mode Conventions:: Coding conventions for keymaps, etc.
* Auto Major Mode:: How Emacs chooses the major mode automatically.
* Mode Help:: Finding out how to use a mode.
* Derived Modes:: Defining a new major mode based on another major
mode.
* Basic Major Modes:: Modes that other modes are often derived from.
* Mode Hooks:: Hooks run at the end of major mode functions.
* Tabulated List Mode:: Parent mode for buffers containing tabulated data.
* Generic Modes:: Defining a simple major mode that supports
comment syntax and Font Lock mode.
* Example Major Modes:: Text mode and Lisp modes.
@end menu
@node Major Mode Conventions
@subsection Major Mode Conventions
@cindex major mode conventions
@cindex conventions for writing major modes
The code for every major mode should follow various coding
conventions, including conventions for local keymap and syntax table
initialization, function and variable names, and hooks.
If you use the @code{define-derived-mode} macro, it will take care of
many of these conventions automatically. @xref{Derived Modes}. Note
also that Fundamental mode is an exception to many of these conventions,
because it represents the default state of Emacs.
The following list of conventions is only partial. Each major mode
should aim for consistency in general with other Emacs major modes, as
this makes Emacs as a whole more coherent. It is impossible to list
here all the possible points where this issue might come up; if the
Emacs developers point out an area where your major mode deviates from
the usual conventions, please make it compatible.
@itemize @bullet
@item
Define a major mode command whose name ends in @samp{-mode}. When
called with no arguments, this command should switch to the new mode in
the current buffer by setting up the keymap, syntax table, and
buffer-local variables in an existing buffer. It should not change the
buffer's contents.
@item
Write a documentation string for this command that describes the special
commands available in this mode. @xref{Mode Help}.
The documentation string may include the special documentation
substrings, @samp{\[@var{command}]}, @samp{\@{@var{keymap}@}}, and
@samp{\<@var{keymap}>}, which allow the help display to adapt
automatically to the user's own key bindings. @xref{Keys in
Documentation}.
@item
The major mode command should start by calling
@code{kill-all-local-variables}. This runs the normal hook
@code{change-major-mode-hook}, then gets rid of the buffer-local
variables of the major mode previously in effect. @xref{Creating
Buffer-Local}.
@item
The major mode command should set the variable @code{major-mode} to the
major mode command symbol. This is how @code{describe-mode} discovers
which documentation to print.
@item
The major mode command should set the variable @code{mode-name} to the
``pretty'' name of the mode, usually a string (but see @ref{Mode Line
Data}, for other possible forms). The name of the mode appears
in the mode line.
@item
Calling the major mode command twice in direct succession should not
fail and should do the same thing as calling the command only once.
In other words, the major mode command should be idempotent.
@item
@cindex functions in modes
Since all global names are in the same name space, all the global
variables, constants, and functions that are part of the mode should
have names that start with the major mode name (or with an abbreviation
of it if the name is long). @xref{Coding Conventions}.
@item
In a major mode for editing some kind of structured text, such as a
programming language, indentation of text according to structure is
probably useful. So the mode should set @code{indent-line-function}
to a suitable function, and probably customize other variables
for indentation. @xref{Auto-Indentation}.
@item
@cindex keymaps in modes
The major mode should usually have its own keymap, which is used as the
local keymap in all buffers in that mode. The major mode command should
call @code{use-local-map} to install this local map. @xref{Active
Keymaps}, for more information.
This keymap should be stored permanently in a global variable named
@code{@var{modename}-mode-map}. Normally the library that defines the
mode sets this variable.
@xref{Tips for Defining}, for advice about how to write the code to set
up the mode's keymap variable.
@item
The key sequences bound in a major mode keymap should usually start with
@kbd{C-c}, followed by a control character, a digit, or @kbd{@{},
@kbd{@}}, @kbd{<}, @kbd{>}, @kbd{:} or @kbd{;}. The other punctuation
characters are reserved for minor modes, and ordinary letters are
reserved for users.
A major mode can also rebind the keys @kbd{M-n}, @kbd{M-p} and
@kbd{M-s}. The bindings for @kbd{M-n} and @kbd{M-p} should normally
be some kind of moving forward and backward, but this does not
necessarily mean cursor motion.
It is legitimate for a major mode to rebind a standard key sequence if
it provides a command that does the same job in a way better
suited to the text this mode is used for. For example, a major mode
for editing a programming language might redefine @kbd{C-M-a} to
move to the beginning of a function in a way that works better for
that language.
It is also legitimate for a major mode to rebind a standard key
sequence whose standard meaning is rarely useful in that mode. For
instance, minibuffer modes rebind @kbd{M-r}, whose standard meaning is
rarely of any use in the minibuffer. Major modes such as Dired or
Rmail that do not allow self-insertion of text can reasonably redefine
letters and other printing characters as special commands.
@item
Major modes for editing text should not define @key{RET} to do
anything other than insert a newline. However, it is ok for
specialized modes for text that users don't directly edit, such as
Dired and Info modes, to redefine @key{RET} to do something entirely
different.
@item
Major modes should not alter options that are primarily a matter of user
preference, such as whether Auto-Fill mode is enabled. Leave this to
each user to decide. However, a major mode should customize other
variables so that Auto-Fill mode will work usefully @emph{if} the user
decides to use it.
@item
@cindex syntax tables in modes
The mode may have its own syntax table or may share one with other
related modes. If it has its own syntax table, it should store this in
a variable named @code{@var{modename}-mode-syntax-table}. @xref{Syntax
Tables}.
@item
If the mode handles a language that has a syntax for comments, it should
set the variables that define the comment syntax. @xref{Options for
Comments,, Options Controlling Comments, emacs, The GNU Emacs Manual}.
@item
@cindex abbrev tables in modes
The mode may have its own abbrev table or may share one with other
related modes. If it has its own abbrev table, it should store this
in a variable named @code{@var{modename}-mode-abbrev-table}. If the
major mode command defines any abbrevs itself, it should pass @code{t}
for the @var{system-flag} argument to @code{define-abbrev}.
@xref{Defining Abbrevs}.
@item
The mode should specify how to do highlighting for Font Lock mode, by
setting up a buffer-local value for the variable
@code{font-lock-defaults} (@pxref{Font Lock Mode}).
@item
Each face that the mode defines should, if possible, inherit from an
existing Emacs face. @xref{Basic Faces}, and @ref{Faces for Font Lock}.
@item
The mode should specify how Imenu should find the definitions or
sections of a buffer, by setting up a buffer-local value for the
variable @code{imenu-generic-expression}, for the two variables
@code{imenu-prev-index-position-function} and
@code{imenu-extract-index-name-function}, or for the variable
@code{imenu-create-index-function} (@pxref{Imenu}).
@item
The mode can specify a local value for
@code{eldoc-documentation-function} to tell ElDoc mode how to handle
this mode.
@item
The mode can specify how to complete various keywords by adding one or
more buffer-local entries to the special hook
@code{completion-at-point-functions}. @xref{Completion in Buffers}.
@item
@cindex buffer-local variables in modes
To make a buffer-local binding for an Emacs customization variable, use
@code{make-local-variable} in the major mode command, not
@code{make-variable-buffer-local}. The latter function would make the
variable local to every buffer in which it is subsequently set, which
would affect buffers that do not use this mode. It is undesirable for a
mode to have such global effects. @xref{Buffer-Local Variables}.
With rare exceptions, the only reasonable way to use
@code{make-variable-buffer-local} in a Lisp package is for a variable
which is used only within that package. Using it on a variable used by
other packages would interfere with them.
@item
@cindex mode hook
@cindex major mode hook
Each major mode should have a normal @dfn{mode hook} named
@code{@var{modename}-mode-hook}. The very last thing the major mode command
should do is to call @code{run-mode-hooks}. This runs the normal
hook @code{change-major-mode-after-body-hook}, the mode hook, the
function @code{hack-local-variables} (when the buffer is visiting a file),
and then the normal hook @code{after-change-major-mode-hook}.
@xref{Mode Hooks}.
@item
The major mode command may start by calling some other major mode
command (called the @dfn{parent mode}) and then alter some of its
settings. A mode that does this is called a @dfn{derived mode}. The
recommended way to define one is to use the @code{define-derived-mode}
macro, but this is not required. Such a mode should call the parent
mode command inside a @code{delay-mode-hooks} form. (Using
@code{define-derived-mode} does this automatically.) @xref{Derived
Modes}, and @ref{Mode Hooks}.
@item
If something special should be done if the user switches a buffer from
this mode to any other major mode, this mode can set up a buffer-local
value for @code{change-major-mode-hook} (@pxref{Creating Buffer-Local}).
@item
If this mode is appropriate only for specially-prepared text produced by
the mode itself (rather than by the user typing at the keyboard or by an
external file), then the major mode command symbol should have a
property named @code{mode-class} with value @code{special}, put on as
follows:
@kindex mode-class @r{(property)}
@cindex @code{special} modes
@example
(put 'funny-mode 'mode-class 'special)
@end example
@noindent
This tells Emacs that new buffers created while the current buffer is in
Funny mode should not be put in Funny mode, even though the default
value of @code{major-mode} is @code{nil}. By default, the value of
@code{nil} for @code{major-mode} means to use the current buffer's major
mode when creating new buffers (@pxref{Auto Major Mode}), but with such
@code{special} modes, Fundamental mode is used instead. Modes such as
Dired, Rmail, and Buffer List use this feature.
The function @code{view-buffer} does not enable View mode in buffers
whose mode-class is special, because such modes usually provide their
own View-like bindings.
The @code{define-derived-mode} macro automatically marks the derived
mode as special if the parent mode is special. Special mode is a
convenient parent for such modes to inherit from; @xref{Basic Major
Modes}.
@item
If you want to make the new mode the default for files with certain
recognizable names, add an element to @code{auto-mode-alist} to select
the mode for those file names (@pxref{Auto Major Mode}). If you
define the mode command to autoload, you should add this element in
the same file that calls @code{autoload}. If you use an autoload
cookie for the mode command, you can also use an autoload cookie for
the form that adds the element (@pxref{autoload cookie}). If you do
not autoload the mode command, it is sufficient to add the element in
the file that contains the mode definition.
@item
@cindex mode loading
The top-level forms in the file defining the mode should be written so
that they may be evaluated more than once without adverse consequences.
For instance, use @code{defvar} or @code{defcustom} to set mode-related
variables, so that they are not reinitialized if they already have a
value (@pxref{Defining Variables}).
@end itemize
@node Auto Major Mode
@subsection How Emacs Chooses a Major Mode
@cindex major mode, automatic selection
When Emacs visits a file, it automatically selects a major mode for
the buffer based on information in the file name or in the file itself.
It also processes local variables specified in the file text.
@deffn Command normal-mode &optional find-file
This function establishes the proper major mode and buffer-local
variable bindings for the current buffer. It calls
@code{set-auto-mode} (see below). As of Emacs 26.1, it no longer
runs @code{hack-local-variables}, this now being done in
@code{run-mode-hooks} at the initialization of major modes
(@pxref{Mode Hooks}).
If the @var{find-file} argument to @code{normal-mode} is non-@code{nil},
@code{normal-mode} assumes that the @code{find-file} function is calling
it. In this case, it may process local variables in the @samp{-*-}
line or at the end of the file. The variable
@code{enable-local-variables} controls whether to do so. @xref{File
Variables, , Local Variables in Files, emacs, The GNU Emacs Manual},
for the syntax of the local variables section of a file.
If you run @code{normal-mode} interactively, the argument
@var{find-file} is normally @code{nil}. In this case,
@code{normal-mode} unconditionally processes any file local variables.
The function calls @code{set-auto-mode} to choose and set a major
mode. If this does not specify a mode, the buffer stays in the major
mode determined by the default value of @code{major-mode} (see below).
@cindex file mode specification error
@code{normal-mode} uses @code{condition-case} around the call to the
major mode command, so errors are caught and reported as a @samp{File
mode specification error}, followed by the original error message.
@end deffn
@defun set-auto-mode &optional keep-mode-if-same
@cindex visited file mode
This function selects and sets the major mode that is appropriate
for the current buffer. It bases its decision (in order of
precedence) on the @w{@samp{-*-}} line, on any @samp{mode:} local
variable near the end of a file, on the @w{@samp{#!}} line (using
@code{interpreter-mode-alist}), on the text at the beginning of the
buffer (using @code{magic-mode-alist}), and finally on the visited
file name (using @code{auto-mode-alist}). @xref{Choosing Modes, , How
Major Modes are Chosen, emacs, The GNU Emacs Manual}. If
@code{enable-local-variables} is @code{nil}, @code{set-auto-mode} does
not check the @w{@samp{-*-}} line, or near the end of the file, for
any mode tag.
@vindex inhibit-local-variables-regexps
There are some file types where it is not appropriate to scan the file
contents for a mode specifier. For example, a tar archive may happen to
contain, near the end of the file, a member file that has a local
variables section specifying a mode for that particular file. This
should not be applied to the containing tar file. Similarly, a tiff
image file might just happen to contain a first line that seems to
match the @w{@samp{-*-}} pattern. For these reasons, both these file
extensions are members of the list @code{inhibit-local-variables-regexps}.
Add patterns to this list to prevent Emacs searching them for local
variables of any kind (not just mode specifiers).
If @var{keep-mode-if-same} is non-@code{nil}, this function does not
call the mode command if the buffer is already in the proper major
mode. For instance, @code{set-visited-file-name} sets this to
@code{t} to avoid killing buffer local variables that the user may
have set.
@end defun
@defun set-buffer-major-mode buffer
This function sets the major mode of @var{buffer} to the default value of
@code{major-mode}; if that is @code{nil}, it uses the
current buffer's major mode (if that is suitable). As an exception,
if @var{buffer}'s name is @file{*scratch*}, it sets the mode to
@code{initial-major-mode}.
The low-level primitives for creating buffers do not use this function,
but medium-level commands such as @code{switch-to-buffer} and
@code{find-file-noselect} use it whenever they create buffers.
@end defun
@defopt initial-major-mode
@cindex @file{*scratch*}
The value of this variable determines the major mode of the initial
@file{*scratch*} buffer. The value should be a symbol that is a major
mode command. The default value is @code{lisp-interaction-mode}.
@end defopt
@defvar interpreter-mode-alist
This variable specifies major modes to use for scripts that specify a
command interpreter in a @samp{#!} line. Its value is an alist with
elements of the form @code{(@var{regexp} . @var{mode})}; this says to
use mode @var{mode} if the file specifies an interpreter which matches
@code{\\`@var{regexp}\\'}. For example, one of the default elements
is @code{("python[0-9.]*" . python-mode)}.
@end defvar
@defvar magic-mode-alist
This variable's value is an alist with elements of the form
@code{(@var{regexp} . @var{function})}, where @var{regexp} is a
regular expression and @var{function} is a function or @code{nil}.
After visiting a file, @code{set-auto-mode} calls @var{function} if
the text at the beginning of the buffer matches @var{regexp} and
@var{function} is non-@code{nil}; if @var{function} is @code{nil},
@code{auto-mode-alist} gets to decide the mode.
@end defvar
@defvar magic-fallback-mode-alist
This works like @code{magic-mode-alist}, except that it is handled
only if @code{auto-mode-alist} does not specify a mode for this file.
@end defvar
@defvar auto-mode-alist
This variable contains an association list of file name patterns
(regular expressions) and corresponding major mode commands. Usually,
the file name patterns test for suffixes, such as @samp{.el} and
@samp{.c}, but this need not be the case. An ordinary element of the
alist looks like @code{(@var{regexp} . @var{mode-function})}.
For example,
@smallexample
@group
(("\\`/tmp/fol/" . text-mode)
("\\.texinfo\\'" . texinfo-mode)
("\\.texi\\'" . texinfo-mode)
@end group
@group
("\\.el\\'" . emacs-lisp-mode)
("\\.c\\'" . c-mode)
("\\.h\\'" . c-mode)
@dots{})
@end group
@end smallexample
When you visit a file whose expanded file name (@pxref{File Name
Expansion}), with version numbers and backup suffixes removed using
@code{file-name-sans-versions} (@pxref{File Name Components}), matches
a @var{regexp}, @code{set-auto-mode} calls the corresponding
@var{mode-function}. This feature enables Emacs to select the proper
major mode for most files.
If an element of @code{auto-mode-alist} has the form @code{(@var{regexp}
@var{function} t)}, then after calling @var{function}, Emacs searches
@code{auto-mode-alist} again for a match against the portion of the file
name that did not match before. This feature is useful for
uncompression packages: an entry of the form @code{("\\.gz\\'"
@var{function} t)} can uncompress the file and then put the uncompressed
file in the proper mode according to the name sans @samp{.gz}.
Here is an example of how to prepend several pattern pairs to
@code{auto-mode-alist}. (You might use this sort of expression in your
init file.)
@smallexample
@group
(setq auto-mode-alist
(append
;; @r{File name (within directory) starts with a dot.}
'(("/\\.[^/]*\\'" . fundamental-mode)
;; @r{File name has no dot.}
("/[^\\./]*\\'" . fundamental-mode)
;; @r{File name ends in @samp{.C}.}
("\\.C\\'" . c++-mode))
auto-mode-alist))
@end group
@end smallexample
@end defvar
@node Mode Help
@subsection Getting Help about a Major Mode
@cindex mode help
@cindex help for major mode
@cindex documentation for major mode
The @code{describe-mode} function provides information about major
modes. It is normally bound to @kbd{C-h m}. It uses the value of the
variable @code{major-mode} (@pxref{Major Modes}), which is why every
major mode command needs to set that variable.
@deffn Command describe-mode &optional buffer
This command displays the documentation of the current buffer's major
mode and minor modes. It uses the @code{documentation} function to
retrieve the documentation strings of the major and minor mode
commands (@pxref{Accessing Documentation}).
If called from Lisp with a non-@code{nil} @var{buffer} argument, this
function displays the documentation for that buffer's major and minor
modes, rather than those of the current buffer.
@end deffn
@node Derived Modes
@subsection Defining Derived Modes
@cindex derived mode
The recommended way to define a new major mode is to derive it from an
existing one using @code{define-derived-mode}. If there is no closely
related mode, you should inherit from either @code{text-mode},
@code{special-mode}, or @code{prog-mode}. @xref{Basic Major Modes}. If
none of these are suitable, you can inherit from @code{fundamental-mode}
(@pxref{Major Modes}).
@defmac define-derived-mode variant parent name docstring keyword-args@dots{} body@dots{}
This macro defines @var{variant} as a major mode command, using
@var{name} as the string form of the mode name. @var{variant} and
@var{parent} should be unquoted symbols.
The new command @var{variant} is defined to call the function
@var{parent}, then override certain aspects of that parent mode:
@itemize @bullet
@item
The new mode has its own sparse keymap, named
@code{@var{variant}-map}. @code{define-derived-mode}
makes the parent mode's keymap the parent of the new map, unless
@code{@var{variant}-map} is already set and already has a parent.
@item
The new mode has its own syntax table, kept in the variable
@code{@var{variant}-syntax-table}, unless you override this using the
@code{:syntax-table} keyword (see below). @code{define-derived-mode}
makes the parent mode's syntax-table the parent of
@code{@var{variant}-syntax-table}, unless the latter is already set
and already has a parent different from the standard syntax table.
@item
The new mode has its own abbrev table, kept in the variable
@code{@var{variant}-abbrev-table}, unless you override this using the
@code{:abbrev-table} keyword (see below).
@item
The new mode has its own mode hook, @code{@var{variant}-hook}. It
runs this hook, after running the hooks of its ancestor modes, with
@code{run-mode-hooks}, as the last thing it does, apart from running
any @code{:after-hook} form it may have. @xref{Mode Hooks}.
@end itemize
In addition, you can specify how to override other aspects of
@var{parent} with @var{body}. The command @var{variant}
evaluates the forms in @var{body} after setting up all its usual
overrides, just before running the mode hooks.
If @var{parent} has a non-@code{nil} @code{mode-class} symbol
property, then @code{define-derived-mode} sets the @code{mode-class}
property of @var{variant} to the same value. This ensures, for
example, that if @var{parent} is a special mode, then @var{variant} is
also a special mode (@pxref{Major Mode Conventions}).
You can also specify @code{nil} for @var{parent}. This gives the new
mode no parent. Then @code{define-derived-mode} behaves as described
above, but, of course, omits all actions connected with @var{parent}.
The argument @var{docstring} specifies the documentation string for the
new mode. @code{define-derived-mode} adds some general information
about the mode's hook, followed by the mode's keymap, at the end of this
documentation string. If you omit @var{docstring},
@code{define-derived-mode} generates a documentation string.
The @var{keyword-args} are pairs of keywords and values. The values,
except for @code{:after-hook}'s, are evaluated. The following
keywords are currently supported:
@table @code
@item :syntax-table
You can use this to explicitly specify a syntax table for the new
mode. If you specify a @code{nil} value, the new mode uses the same
syntax table as @var{parent}, or the standard syntax table if
@var{parent} is @code{nil}. (Note that this does @emph{not} follow
the convention used for non-keyword arguments that a @code{nil} value
is equivalent with not specifying the argument.)
@item :abbrev-table
You can use this to explicitly specify an abbrev table for the new
mode. If you specify a @code{nil} value, the new mode uses the same
abbrev table as @var{parent}, or @code{fundamental-mode-abbrev-table}
if @var{parent} is @code{nil}. (Again, a @code{nil} value is
@emph{not} equivalent to not specifying this keyword.)
@item :group
If this is specified, the value should be the customization group for
this mode. (Not all major modes have one.) The command
@code{customize-mode} uses this. @code{define-derived-mode} does
@emph{not} automatically define the specified customization group.
@item :after-hook
This optional keyword specifies a single Lisp form to evaluate as the
final act of the mode function, after the mode hooks have been run.
It should not be quoted. Since the form might be evaluated after the
mode function has terminated, it should not access any element of the
mode function's local state. An @code{:after-hook} form is useful for
setting up aspects of the mode which depend on the user's settings,
which in turn may have been changed in a mode hook.
@end table
Here is a hypothetical example:
@example
(defvar hypertext-mode-map
(let ((map (make-sparse-keymap)))
(define-key map [down-mouse-3] 'do-hyper-link)
map))
(define-derived-mode hypertext-mode
text-mode "Hypertext"
"Major mode for hypertext."
(setq-local case-fold-search nil))
@end example
Do not write an @code{interactive} spec in the definition;
@code{define-derived-mode} does that automatically.
@end defmac
@defun derived-mode-p &rest modes
This function returns non-@code{nil} if the current major mode is
derived from any of the major modes given by the symbols @var{modes}.
@end defun
@node Basic Major Modes
@subsection Basic Major Modes
Apart from Fundamental mode, there are three major modes that other
major modes commonly derive from: Text mode, Prog mode, and Special
mode. While Text mode is useful in its own right (e.g., for editing
files ending in @file{.txt}), Prog mode and Special mode exist mainly to
let other modes derive from them.
@vindex prog-mode-hook
As far as possible, new major modes should be derived, either directly
or indirectly, from one of these three modes. One reason is that this
allows users to customize a single mode hook
(e.g., @code{prog-mode-hook}) for an entire family of relevant modes
(e.g., all programming language modes).
@deffn Command text-mode
Text mode is a major mode for editing human languages. It defines the
@samp{"} and @samp{\} characters as having punctuation syntax
(@pxref{Syntax Class Table}), and binds @kbd{M-@key{TAB}} to
@code{ispell-complete-word} (@pxref{Spelling,,, emacs, The GNU Emacs
Manual}).
An example of a major mode derived from Text mode is HTML mode.
@xref{HTML Mode,,SGML and HTML Modes, emacs, The GNU Emacs Manual}.
@end deffn
@deffn Command prog-mode
Prog mode is a basic major mode for buffers containing programming
language source code. Most of the programming language major modes
built into Emacs are derived from it.
Prog mode binds @code{parse-sexp-ignore-comments} to @code{t}
(@pxref{Motion via Parsing}) and @code{bidi-paragraph-direction} to
@code{left-to-right} (@pxref{Bidirectional Display}).
@end deffn
@deffn Command special-mode
Special mode is a basic major mode for buffers containing text that is
produced specially by Emacs, rather than directly from a file. Major
modes derived from Special mode are given a @code{mode-class} property
of @code{special} (@pxref{Major Mode Conventions}).
Special mode sets the buffer to read-only. Its keymap defines several
common bindings, including @kbd{q} for @code{quit-window} and @kbd{g}
for @code{revert-buffer} (@pxref{Reverting}).
An example of a major mode derived from Special mode is Buffer Menu
mode, which is used by the @file{*Buffer List*} buffer. @xref{List
Buffers,,Listing Existing Buffers, emacs, The GNU Emacs Manual}.
@end deffn
In addition, modes for buffers of tabulated data can inherit from
Tabulated List mode, which is in turn derived from Special mode.
@xref{Tabulated List Mode}.
@node Mode Hooks
@subsection Mode Hooks
Every major mode command should finish by running the mode-independent
normal hook @code{change-major-mode-after-body-hook}, its mode hook,
and the normal hook @code{after-change-major-mode-hook}.
It does this by calling @code{run-mode-hooks}. If the major mode is a
derived mode, that is if it calls another major mode (the parent mode)
in its body, it should do this inside @code{delay-mode-hooks} so that
the parent won't run these hooks itself. Instead, the derived mode's
call to @code{run-mode-hooks} runs the parent's mode hook too.
@xref{Major Mode Conventions}.
Emacs versions before Emacs 22 did not have @code{delay-mode-hooks}.
Versions before 24 did not have @code{change-major-mode-after-body-hook}.
When user-implemented major modes do not use @code{run-mode-hooks} and
have not been updated to use these newer features, they won't entirely
follow these conventions: they may run the parent's mode hook too early,
or fail to run @code{after-change-major-mode-hook}. If you encounter
such a major mode, please correct it to follow these conventions.
When you define a major mode using @code{define-derived-mode}, it
automatically makes sure these conventions are followed. If you
define a major mode ``by hand'', not using @code{define-derived-mode},
use the following functions to handle these conventions automatically.
@defun run-mode-hooks &rest hookvars
Major modes should run their mode hook using this function. It is
similar to @code{run-hooks} (@pxref{Hooks}), but it also runs
@code{change-major-mode-after-body-hook}, @code{hack-local-variables}
(when the buffer is visiting a file) (@pxref{File Local Variables}),
and @code{after-change-major-mode-hook}. The last thing it does is to
evaluate any @code{:after-hook} forms declared by parent modes
(@pxref{Derived Modes}).
When this function is called during the execution of a
@code{delay-mode-hooks} form, it does not run the hooks or
@code{hack-local-variables} or evaluate the forms immediately.
Instead, it arranges for the next call to @code{run-mode-hooks} to run
them.
@end defun
@defmac delay-mode-hooks body@dots{}
When one major mode command calls another, it should do so inside of
@code{delay-mode-hooks}.
This macro executes @var{body}, but tells all @code{run-mode-hooks}
calls during the execution of @var{body} to delay running their hooks.
The hooks will actually run during the next call to
@code{run-mode-hooks} after the end of the @code{delay-mode-hooks}
construct.
@end defmac
@defvar change-major-mode-after-body-hook
This is a normal hook run by @code{run-mode-hooks}. It is run before
the mode hooks.
@end defvar
@defvar after-change-major-mode-hook
This is a normal hook run by @code{run-mode-hooks}. It is run at the
very end of every properly-written major mode command.
@end defvar
@node Tabulated List Mode
@subsection Tabulated List mode
@cindex Tabulated List mode
Tabulated List mode is a major mode for displaying tabulated data,
i.e., data consisting of @dfn{entries}, each entry occupying one row of
text with its contents divided into columns. Tabulated List mode
provides facilities for pretty-printing rows and columns, and sorting
the rows according to the values in each column. It is derived from
Special mode (@pxref{Basic Major Modes}).
Tabulated List mode is intended to be used as a parent mode by a more
specialized major mode. Examples include Process Menu mode
(@pxref{Process Information}) and Package Menu mode (@pxref{Package
Menu,,, emacs, The GNU Emacs Manual}).
@findex tabulated-list-mode
Such a derived mode should use @code{define-derived-mode} in the usual
way, specifying @code{tabulated-list-mode} as the second argument
(@pxref{Derived Modes}). The body of the @code{define-derived-mode}
form should specify the format of the tabulated data, by assigning
values to the variables documented below; optionally, it can then call
the function @code{tabulated-list-init-header}, which will populate a
header with the names of the columns.
The derived mode should also define a @dfn{listing command}. This,
not the mode command, is what the user calls (e.g., @kbd{M-x
list-processes}). The listing command should create or switch to a
buffer, turn on the derived mode, specify the tabulated data, and
finally call @code{tabulated-list-print} to populate the buffer.
@defvar tabulated-list-format
This buffer-local variable specifies the format of the Tabulated List
data. Its value should be a vector. Each element of the vector
represents a data column, and should be a list @code{(@var{name}
@var{width} @var{sort})}, where
@itemize
@item
@var{name} is the column's name (a string).
@item
@var{width} is the width to reserve for the column (an integer). This
is meaningless for the last column, which runs to the end of each line.
@item
@var{sort} specifies how to sort entries by the column. If @code{nil},
the column cannot be used for sorting. If @code{t}, the column is
sorted by comparing string values. Otherwise, this should be a
predicate function for @code{sort} (@pxref{Rearrangement}), which
accepts two arguments with the same form as the elements of
@code{tabulated-list-entries} (see below).
@end itemize
@end defvar
@defvar tabulated-list-entries
This buffer-local variable specifies the entries displayed in the
Tabulated List buffer. Its value should be either a list, or a
function.
If the value is a list, each list element corresponds to one entry, and
should have the form @w{@code{(@var{id} @var{contents})}}, where
@itemize
@item
@var{id} is either @code{nil}, or a Lisp object that identifies the
entry. If the latter, the cursor stays on the same entry when
re-sorting entries. Comparison is done with @code{equal}.
@item
@var{contents} is a vector with the same number of elements as
@code{tabulated-list-format}. Each vector element is either a string,
which is inserted into the buffer as-is, or a list @code{(@var{label}
. @var{properties})}, which means to insert a text button by calling
@code{insert-text-button} with @var{label} and @var{properties} as
arguments (@pxref{Making Buttons}).
There should be no newlines in any of these strings.
@end itemize
Otherwise, the value should be a function which returns a list of the
above form when called with no arguments.
@end defvar
@defvar tabulated-list-revert-hook
This normal hook is run prior to reverting a Tabulated List buffer. A
derived mode can add a function to this hook to recompute
@code{tabulated-list-entries}.
@end defvar
@defvar tabulated-list-printer
The value of this variable is the function called to insert an entry at
point, including its terminating newline. The function should accept
two arguments, @var{id} and @var{contents}, having the same meanings as
in @code{tabulated-list-entries}. The default value is a function which
inserts an entry in a straightforward way; a mode which uses Tabulated
List mode in a more complex way can specify another function.
@end defvar
@defvar tabulated-list-sort-key
The value of this variable specifies the current sort key for the
Tabulated List buffer. If it is @code{nil}, no sorting is done.
Otherwise, it should have the form @code{(@var{name} . @var{flip})},
where @var{name} is a string matching one of the column names in
@code{tabulated-list-format}, and @var{flip}, if non-@code{nil}, means
to invert the sort order.
@end defvar
@defun tabulated-list-init-header
This function computes and sets @code{header-line-format} for the
Tabulated List buffer (@pxref{Header Lines}), and assigns a keymap to
the header line to allow sorting entries by clicking on column headers.
Modes derived from Tabulated List mode should call this after setting
the above variables (in particular, only after setting
@code{tabulated-list-format}).
@end defun
@defun tabulated-list-print &optional remember-pos update
This function populates the current buffer with entries. It should be
called by the listing command. It erases the buffer, sorts the entries
specified by @code{tabulated-list-entries} according to
@code{tabulated-list-sort-key}, then calls the function specified by
@code{tabulated-list-printer} to insert each entry.
If the optional argument @var{remember-pos} is non-@code{nil}, this
function looks for the @var{id} element on the current line, if any, and
tries to move to that entry after all the entries are (re)inserted.
If the optional argument @var{update} is non-@code{nil}, this function
will only erase or add entries that have changed since the last print.
This is several times faster if most entries haven't changed since the
last time this function was called. The only difference in outcome is
that tags placed via @code{tabulated-list-put-tag} will not be removed
from entries that haven't changed (normally all tags are removed).
@end defun
@node Generic Modes
@subsection Generic Modes
@cindex generic mode
@dfn{Generic modes} are simple major modes with basic support for
comment syntax and Font Lock mode. To define a generic mode, use the
macro @code{define-generic-mode}. See the file @file{generic-x.el}
for some examples of the use of @code{define-generic-mode}.
@defmac define-generic-mode mode comment-list keyword-list font-lock-list auto-mode-list function-list &optional docstring
This macro defines a generic mode command named @var{mode} (a symbol,
not quoted). The optional argument @var{docstring} is the
documentation for the mode command. If you do not supply it,
@code{define-generic-mode} generates one by default.
The argument @var{comment-list} is a list in which each element is
either a character, a string of one or two characters, or a cons cell.
A character or a string is set up in the mode's syntax table as a
comment starter. If the entry is a cons cell, the @sc{car} is set
up as a comment starter and the @sc{cdr} as a comment ender.
(Use @code{nil} for the latter if you want comments to end at the end
of the line.) Note that the syntax table mechanism has limitations
about what comment starters and enders are actually possible.
@xref{Syntax Tables}.
The argument @var{keyword-list} is a list of keywords to highlight
with @code{font-lock-keyword-face}. Each keyword should be a string.
Meanwhile, @var{font-lock-list} is a list of additional expressions to
highlight. Each element of this list should have the same form as an
element of @code{font-lock-keywords}. @xref{Search-based
Fontification}.
The argument @var{auto-mode-list} is a list of regular expressions to
add to the variable @code{auto-mode-alist}. They are added by the execution
of the @code{define-generic-mode} form, not by expanding the macro call.
Finally, @var{function-list} is a list of functions for the mode
command to call for additional setup. It calls these functions just
before it runs the mode hook variable @code{@var{mode}-hook}.
@end defmac
@node Example Major Modes
@subsection Major Mode Examples
Text mode is perhaps the simplest mode besides Fundamental mode.
Here are excerpts from @file{text-mode.el} that illustrate many of
the conventions listed above:
@smallexample
@group
;; @r{Create the syntax table for this mode.}
(defvar text-mode-syntax-table
(let ((st (make-syntax-table)))
(modify-syntax-entry ?\" ". " st)
(modify-syntax-entry ?\\ ". " st)
;; Add 'p' so M-c on 'hello' leads to 'Hello', not 'hello'.
(modify-syntax-entry ?' "w p" st)
st)
"Syntax table used while in `text-mode'.")
@end group
;; @r{Create the keymap for this mode.}
@group
(defvar text-mode-map
(let ((map (make-sparse-keymap)))
(define-key map "\e\t" 'ispell-complete-word)
map)
"Keymap for `text-mode'.
Many other modes, such as `mail-mode', `outline-mode' and
`indented-text-mode', inherit all the commands defined in this map.")
@end group
@end smallexample
Here is how the actual mode command is defined now:
@smallexample
@group
(define-derived-mode text-mode nil "Text"
"Major mode for editing text written for humans to read.
In this mode, paragraphs are delimited only by blank or white lines.
You can thus get the full benefit of adaptive filling
(see the variable `adaptive-fill-mode').
\\@{text-mode-map@}
Turning on Text mode runs the normal hook `text-mode-hook'."
@end group
@group
(set (make-local-variable 'text-mode-variant) t)
(set (make-local-variable 'require-final-newline)
mode-require-final-newline)
(set (make-local-variable 'indent-line-function) 'indent-relative))
@end group
@end smallexample
@noindent
(The last line is redundant nowadays, since @code{indent-relative} is
the default value, and we'll delete it in a future version.)
@cindex @file{lisp-mode.el}
The three Lisp modes (Lisp mode, Emacs Lisp mode, and Lisp Interaction
mode) have more features than Text mode and the code is correspondingly
more complicated. Here are excerpts from @file{lisp-mode.el} that
illustrate how these modes are written.
Here is how the Lisp mode syntax and abbrev tables are defined:
@cindex syntax table example
@smallexample
@group
;; @r{Create mode-specific table variables.}
(defvar lisp-mode-abbrev-table nil)
(define-abbrev-table 'lisp-mode-abbrev-table ())
(defvar lisp-mode-syntax-table
(let ((table (copy-syntax-table emacs-lisp-mode-syntax-table)))
(modify-syntax-entry ?\[ "_ " table)
(modify-syntax-entry ?\] "_ " table)
(modify-syntax-entry ?# "' 14" table)
(modify-syntax-entry ?| "\" 23bn" table)
table)
"Syntax table used in `lisp-mode'.")
@end group
@end smallexample
The three modes for Lisp share much of their code. For instance,
each calls the following function to set various variables:
@smallexample
@group
(defun lisp-mode-variables (&optional syntax keywords-case-insensitive)
(when syntax
(set-syntax-table lisp-mode-syntax-table))
(setq local-abbrev-table lisp-mode-abbrev-table)
@dots{}
@end group
@end smallexample
@noindent
Amongst other things, this function sets up the @code{comment-start}
variable to handle Lisp comments:
@smallexample
@group
(make-local-variable 'comment-start)
(setq comment-start ";")
@dots{}
@end group
@end smallexample
Each of the different Lisp modes has a slightly different keymap. For
example, Lisp mode binds @kbd{C-c C-z} to @code{run-lisp}, but the other
Lisp modes do not. However, all Lisp modes have some commands in
common. The following code sets up the common commands:
@smallexample
@group
(defvar lisp-mode-shared-map
(let ((map (make-sparse-keymap)))
(define-key map "\e\C-q" 'indent-sexp)
(define-key map "\177" 'backward-delete-char-untabify)
map)
"Keymap for commands shared by all sorts of Lisp modes.")
@end group
@end smallexample
@noindent
And here is the code to set up the keymap for Lisp mode:
@smallexample
@group
(defvar lisp-mode-map
(let ((map (make-sparse-keymap))
(menu-map (make-sparse-keymap "Lisp")))
(set-keymap-parent map lisp-mode-shared-map)
(define-key map "\e\C-x" 'lisp-eval-defun)
(define-key map "\C-c\C-z" 'run-lisp)
@dots{}
map)
"Keymap for ordinary Lisp mode.
All commands in `lisp-mode-shared-map' are inherited by this map.")
@end group
@end smallexample
@noindent
Finally, here is the major mode command for Lisp mode:
@smallexample
@group
(define-derived-mode lisp-mode prog-mode "Lisp"
"Major mode for editing Lisp code for Lisps other than GNU Emacs Lisp.
Commands:
Delete converts tabs to spaces as it moves back.
Blank lines separate paragraphs. Semicolons start comments.
\\@{lisp-mode-map@}
Note that `run-lisp' may be used either to start an inferior Lisp job
or to switch back to an existing one.
@end group
@group
Entry to this mode calls the value of `lisp-mode-hook'
if that value is non-nil."
(lisp-mode-variables nil t)
(set (make-local-variable 'find-tag-default-function)
'lisp-find-tag-default)
(set (make-local-variable 'comment-start-skip)
"\\(\\(^\\|[^\\\\\n]\\)\\(\\\\\\\\\\)*\\)\\(;+\\|#|\\) *")
(setq imenu-case-fold-search t))
@end group
@end smallexample
@node Minor Modes
@section Minor Modes
@cindex minor mode
A @dfn{minor mode} provides optional features that users may enable or
disable independently of the choice of major mode. Minor modes can be
enabled individually or in combination.
Most minor modes implement features that are independent of the major
mode, and can thus be used with most major modes. For example, Auto
Fill mode works with any major mode that permits text insertion. A few
minor modes, however, are specific to a particular major mode. For
example, Diff Auto Refine mode is a minor mode that is intended to be
used only with Diff mode.
Ideally, a minor mode should have its desired effect regardless of the
other minor modes in effect. It should be possible to activate and
deactivate minor modes in any order.
@defvar minor-mode-list
The value of this variable is a list of all minor mode commands.
@end defvar
@menu
* Minor Mode Conventions:: Tips for writing a minor mode.
* Keymaps and Minor Modes:: How a minor mode can have its own keymap.
* Defining Minor Modes:: A convenient facility for defining minor modes.
@end menu
@node Minor Mode Conventions
@subsection Conventions for Writing Minor Modes
@cindex minor mode conventions
@cindex conventions for writing minor modes
There are conventions for writing minor modes just as there are for
major modes. These conventions are described below. The easiest way to
follow them is to use the macro @code{define-minor-mode}.
@xref{Defining Minor Modes}.
@itemize @bullet
@item
@cindex mode variable
Define a variable whose name ends in @samp{-mode}. We call this the
@dfn{mode variable}. The minor mode command should set this variable.
The value will be @code{nil} if the mode is disabled, and non-@code{nil}
if the mode is enabled. The variable should be buffer-local if the
minor mode is buffer-local.
This variable is used in conjunction with the @code{minor-mode-alist} to
display the minor mode name in the mode line. It also determines
whether the minor mode keymap is active, via @code{minor-mode-map-alist}
(@pxref{Controlling Active Maps}). Individual commands or hooks can
also check its value.
@item
Define a command, called the @dfn{mode command}, whose name is the same
as the mode variable. Its job is to set the value of the mode variable,
plus anything else that needs to be done to actually enable or disable
the mode's features.
The mode command should accept one optional argument. If called
interactively with no prefix argument, it should toggle the mode
(i.e., enable if it is disabled, and disable if it is enabled). If
called interactively with a prefix argument, it should enable the mode
if the argument is positive and disable it otherwise.
If the mode command is called from Lisp (i.e., non-interactively), it
should enable the mode if the argument is omitted or @code{nil}; it
should toggle the mode if the argument is the symbol @code{toggle};
otherwise it should treat the argument in the same way as for an
interactive call with a numeric prefix argument, as described above.
The following example shows how to implement this behavior (it is
similar to the code generated by the @code{define-minor-mode} macro):
@example
(interactive (list (or current-prefix-arg 'toggle)))
(let ((enable (if (eq arg 'toggle)
(not foo-mode) ; @r{this mode's mode variable}
(> (prefix-numeric-value arg) 0))))
(if enable
@var{do-enable}
@var{do-disable}))
@end example
The reason for this somewhat complex behavior is that it lets users
easily toggle the minor mode interactively, and also lets the minor mode
be easily enabled in a mode hook, like this:
@example
(add-hook 'text-mode-hook 'foo-mode)
@end example
@noindent
This behaves correctly whether or not @code{foo-mode} was already
enabled, since the @code{foo-mode} mode command unconditionally enables
the minor mode when it is called from Lisp with no argument. Disabling
a minor mode in a mode hook is a little uglier:
@example
(add-hook 'text-mode-hook (lambda () (foo-mode -1)))
@end example
@noindent
However, this is not very commonly done.
Enabling or disabling a minor mode twice in direct succession should
not fail and should do the same thing as enabling or disabling it only
once. In other words, the minor mode command should be idempotent.
@item
Add an element to @code{minor-mode-alist} for each minor mode
(@pxref{Definition of minor-mode-alist}), if you want to indicate the
minor mode in the mode line. This element should be a list of the
following form:
@smallexample
(@var{mode-variable} @var{string})
@end smallexample
Here @var{mode-variable} is the variable that controls enabling of the
minor mode, and @var{string} is a short string, starting with a space,
to represent the mode in the mode line. These strings must be short so
that there is room for several of them at once.
When you add an element to @code{minor-mode-alist}, use @code{assq} to
check for an existing element, to avoid duplication. For example:
@smallexample
@group
(unless (assq 'leif-mode minor-mode-alist)
(push '(leif-mode " Leif") minor-mode-alist))
@end group
@end smallexample
@noindent
or like this, using @code{add-to-list} (@pxref{List Variables}):
@smallexample
@group
(add-to-list 'minor-mode-alist '(leif-mode " Leif"))
@end group
@end smallexample
@end itemize
In addition, several major mode conventions apply to minor modes as
well: those regarding the names of global symbols, the use of a hook at
the end of the initialization function, and the use of keymaps and other
tables.
The minor mode should, if possible, support enabling and disabling via
Custom (@pxref{Customization}). To do this, the mode variable should be
defined with @code{defcustom}, usually with @code{:type 'boolean}. If
just setting the variable is not sufficient to enable the mode, you
should also specify a @code{:set} method which enables the mode by
invoking the mode command. Note in the variable's documentation string
that setting the variable other than via Custom may not take effect.
Also, mark the definition with an autoload cookie (@pxref{autoload
cookie}), and specify a @code{:require} so that customizing the variable
will load the library that defines the mode. For example:
@smallexample
@group
;;;###autoload
(defcustom msb-mode nil
"Toggle msb-mode.
Setting this variable directly does not take effect;
use either \\[customize] or the function `msb-mode'."
:set 'custom-set-minor-mode
:initialize 'custom-initialize-default
:version "20.4"
:type 'boolean
:group 'msb
:require 'msb)
@end group
@end smallexample
@node Keymaps and Minor Modes
@subsection Keymaps and Minor Modes
Each minor mode can have its own keymap, which is active when the mode
is enabled. To set up a keymap for a minor mode, add an element to the
alist @code{minor-mode-map-alist}. @xref{Definition of minor-mode-map-alist}.
@cindex @code{self-insert-command}, minor modes
One use of minor mode keymaps is to modify the behavior of certain
self-inserting characters so that they do something else as well as
self-insert. (Another way to customize @code{self-insert-command} is
through @code{post-self-insert-hook}, see @ref{Commands for
Insertion}. Apart from this, the facilities for customizing
@code{self-insert-command} are limited to special cases, designed for
abbrevs and Auto Fill mode. Do not try substituting your own
definition of @code{self-insert-command} for the standard one. The
editor command loop handles this function specially.)
Minor modes may bind commands to key sequences consisting of @kbd{C-c}
followed by a punctuation character. However, sequences consisting of
@kbd{C-c} followed by one of @kbd{@{@}<>:;}, or a control character or
digit, are reserved for major modes. Also, @kbd{C-c @var{letter}} is
reserved for users. @xref{Key Binding Conventions}.
@node Defining Minor Modes
@subsection Defining Minor Modes
The macro @code{define-minor-mode} offers a convenient way of
implementing a mode in one self-contained definition.
@defmac define-minor-mode mode doc [init-value [lighter [keymap]]] keyword-args@dots{} body@dots{}
This macro defines a new minor mode whose name is @var{mode} (a
symbol). It defines a command named @var{mode} to toggle the minor
mode, with @var{doc} as its documentation string.
The toggle command takes one optional (prefix) argument.
If called interactively with no argument it toggles the mode on or off.
A positive prefix argument enables the mode, any other prefix argument
disables it. From Lisp, an argument of @code{toggle} toggles the mode,
whereas an omitted or @code{nil} argument enables the mode.
This makes it easy to enable the minor mode in a major mode hook, for example.
If @var{doc} is @code{nil}, the macro supplies a default documentation string
explaining the above.
By default, it also defines a variable named @var{mode}, which is set to
@code{t} or @code{nil} by enabling or disabling the mode. The variable
is initialized to @var{init-value}. Except in unusual circumstances
(see below), this value must be @code{nil}.
The string @var{lighter} says what to display in the mode line
when the mode is enabled; if it is @code{nil}, the mode is not displayed
in the mode line.
The optional argument @var{keymap} specifies the keymap for the minor
mode. If non-@code{nil}, it should be a variable name (whose value is
a keymap), a keymap, or an alist of the form
@example
(@var{key-sequence} . @var{definition})
@end example
@noindent
where each @var{key-sequence} and @var{definition} are arguments
suitable for passing to @code{define-key} (@pxref{Changing Key
Bindings}). If @var{keymap} is a keymap or an alist, this also
defines the variable @code{@var{mode}-map}.
The above three arguments @var{init-value}, @var{lighter}, and
@var{keymap} can be (partially) omitted when @var{keyword-args} are
used. The @var{keyword-args} consist of keywords followed by
corresponding values. A few keywords have special meanings:
@table @code
@item :group @var{group}
Custom group name to use in all generated @code{defcustom} forms.
Defaults to @var{mode} without the possible trailing @samp{-mode}.
@strong{Warning:} don't use this default group name unless you have
written a @code{defgroup} to define that group properly. @xref{Group
Definitions}.
@item :global @var{global}
If non-@code{nil}, this specifies that the minor mode should be global
rather than buffer-local. It defaults to @code{nil}.
One of the effects of making a minor mode global is that the
@var{mode} variable becomes a customization variable. Toggling it
through the Customize interface turns the mode on and off, and its
value can be saved for future Emacs sessions (@pxref{Saving
Customizations,,, emacs, The GNU Emacs Manual}. For the saved
variable to work, you should ensure that the @code{define-minor-mode}
form is evaluated each time Emacs starts; for packages that are not
part of Emacs, the easiest way to do this is to specify a
@code{:require} keyword.
@item :init-value @var{init-value}
This is equivalent to specifying @var{init-value} positionally.
@item :lighter @var{lighter}
This is equivalent to specifying @var{lighter} positionally.
@item :keymap @var{keymap}
This is equivalent to specifying @var{keymap} positionally.
@item :variable @var{place}
This replaces the default variable @var{mode}, used to store the state
of the mode. If you specify this, the @var{mode} variable is not
defined, and any @var{init-value} argument is unused. @var{place}
can be a different named variable (which you must define yourself), or
anything that can be used with the @code{setf} function
(@pxref{Generalized Variables}).
@var{place} can also be a cons @code{(@var{get} . @var{set})},
where @var{get} is an expression that returns the current state,
and @var{set} is a function of one argument (a state) that sets it.
@item :after-hook @var{after-hook}
This defines a single Lisp form which is evaluated after the mode hooks
have run. It should not be quoted.
@end table
Any other keyword arguments are passed directly to the
@code{defcustom} generated for the variable @var{mode}.
The command named @var{mode} first performs the standard actions such as
setting the variable named @var{mode} and then executes the @var{body}
forms, if any. It then runs the mode hook variable
@code{@var{mode}-hook} and finishes by evaluating any form in
@code{:after-hook}.
@end defmac
The initial value must be @code{nil} except in cases where (1) the
mode is preloaded in Emacs, or (2) it is painless for loading to
enable the mode even though the user did not request it. For
instance, if the mode has no effect unless something else is enabled,
and will always be loaded by that time, enabling it by default is
harmless. But these are unusual circumstances. Normally, the
initial value must be @code{nil}.
@findex easy-mmode-define-minor-mode
The name @code{easy-mmode-define-minor-mode} is an alias
for this macro.
Here is an example of using @code{define-minor-mode}:
@smallexample
(define-minor-mode hungry-mode
"Toggle Hungry mode.
Interactively with no argument, this command toggles the mode.
A positive prefix argument enables the mode, any other prefix
argument disables it. From Lisp, argument omitted or nil enables
the mode, `toggle' toggles the state.
When Hungry mode is enabled, the control delete key
gobbles all preceding whitespace except the last.
See the command \\[hungry-electric-delete]."
;; The initial value.
nil
;; The indicator for the mode line.
" Hungry"
;; The minor mode bindings.
'(([C-backspace] . hungry-electric-delete))
:group 'hunger)
@end smallexample
@noindent
This defines a minor mode named ``Hungry mode'', a command named
@code{hungry-mode} to toggle it, a variable named @code{hungry-mode}
which indicates whether the mode is enabled, and a variable named
@code{hungry-mode-map} which holds the keymap that is active when the
mode is enabled. It initializes the keymap with a key binding for
@kbd{C-@key{DEL}}. It puts the variable @code{hungry-mode} into
custom group @code{hunger}. There are no @var{body} forms---many
minor modes don't need any.
Here's an equivalent way to write it:
@smallexample
(define-minor-mode hungry-mode
"Toggle Hungry mode.
...rest of documentation as before..."
;; The initial value.
:init-value nil
;; The indicator for the mode line.
:lighter " Hungry"
;; The minor mode bindings.
:keymap
'(([C-backspace] . hungry-electric-delete)
([C-M-backspace]
. (lambda ()
(interactive)
(hungry-electric-delete t))))
:group 'hunger)
@end smallexample
@defmac define-globalized-minor-mode global-mode mode turn-on keyword-args@dots{}
This defines a global toggle named @var{global-mode} whose meaning is
to enable or disable the buffer-local minor mode @var{mode} in all
buffers. To turn on the minor mode in a buffer, it uses the function
@var{turn-on}; to turn off the minor mode, it calls @var{mode} with
@minus{}1 as argument.
Globally enabling the mode also affects buffers subsequently created
by visiting files, and buffers that use a major mode other than
Fundamental mode; but it does not detect the creation of a new buffer
in Fundamental mode.
This defines the customization option @var{global-mode} (@pxref{Customization}),
which can be toggled in the Customize interface to turn the minor mode on
and off. As with @code{define-minor-mode}, you should ensure that the
@code{define-globalized-minor-mode} form is evaluated each time Emacs
starts, for example by providing a @code{:require} keyword.
Use @code{:group @var{group}} in @var{keyword-args} to specify the
custom group for the mode variable of the global minor mode.
Generally speaking, when you define a globalized minor mode, you should
also define a non-globalized version, so that people can use (or
disable) it in individual buffers. This also allows them to disable a
globally enabled minor mode in a specific major mode, by using that
mode's hook.
@end defmac
@node Mode Line Format
@section Mode Line Format
@cindex mode line
Each Emacs window (aside from minibuffer windows) typically has a mode
line at the bottom, which displays status information about the buffer
displayed in the window. The mode line contains information about the
buffer, such as its name, associated file, depth of recursive editing,
and major and minor modes. A window can also have a @dfn{header
line}, which is much like the mode line but appears at the top of the
window.
This section describes how to control the contents of the mode line
and header line. We include it in this chapter because much of the
information displayed in the mode line relates to the enabled major and
minor modes.
@menu
* Base: Mode Line Basics. Basic ideas of mode line control.
* Data: Mode Line Data. The data structure that controls the mode line.
* Top: Mode Line Top. The top level variable, mode-line-format.
* Mode Line Variables:: Variables used in that data structure.
* %-Constructs:: Putting information into a mode line.
* Properties in Mode:: Using text properties in the mode line.
* Header Lines:: Like a mode line, but at the top.
* Emulating Mode Line:: Formatting text as the mode line would.
@end menu
@node Mode Line Basics
@subsection Mode Line Basics
The contents of each mode line are specified by the buffer-local
variable @code{mode-line-format} (@pxref{Mode Line Top}). This variable
holds a @dfn{mode line construct}: a template that controls what is
displayed on the buffer's mode line. The value of
@code{header-line-format} specifies the buffer's header line in the same
way. All windows for the same buffer use the same
@code{mode-line-format} and @code{header-line-format} unless a
@code{mode-line-format} or @code{header-line-format} parameter has been
specified for that window (@pxref{Window Parameters}).
For efficiency, Emacs does not continuously recompute each window's
mode line and header line. It does so when circumstances appear to call
for it---for instance, if you change the window configuration, switch
buffers, narrow or widen the buffer, scroll, or modify the buffer. If
you alter any of the variables referenced by @code{mode-line-format} or
@code{header-line-format} (@pxref{Mode Line Variables}), or any other
data structures that affect how text is displayed (@pxref{Display}), you
should use the function @code{force-mode-line-update} to update the
display.
@defun force-mode-line-update &optional all
This function forces Emacs to update the current buffer's mode line and
header line, based on the latest values of all relevant variables,
during its next redisplay cycle. If the optional argument @var{all} is
non-@code{nil}, it forces an update for all mode lines and header lines.
This function also forces an update of the menu bar and frame title.
@end defun
The selected window's mode line is usually displayed in a different
color using the face @code{mode-line}. Other windows' mode lines appear
in the face @code{mode-line-inactive} instead. @xref{Faces}.
@node Mode Line Data
@subsection The Data Structure of the Mode Line
@cindex mode line construct
The mode line contents are controlled by a data structure called a
@dfn{mode line construct}, made up of lists, strings, symbols, and
numbers kept in buffer-local variables. Each data type has a specific
meaning for the mode line appearance, as described below. The same data
structure is used for constructing frame titles (@pxref{Frame Titles})
and header lines (@pxref{Header Lines}).
A mode line construct may be as simple as a fixed string of text,
but it usually specifies how to combine fixed strings with variables'
values to construct the text. Many of these variables are themselves
defined to have mode line constructs as their values.
Here are the meanings of various data types as mode line constructs:
@table @code
@cindex percent symbol in mode line
@item @var{string}
A string as a mode line construct appears verbatim except for
@dfn{@code{%}-constructs} in it. These stand for substitution of
other data; see @ref{%-Constructs}.
If parts of the string have @code{face} properties, they control
display of the text just as they would text in the buffer. Any
characters which have no @code{face} properties are displayed, by
default, in the face @code{mode-line} or @code{mode-line-inactive}
(@pxref{Standard Faces,,, emacs, The GNU Emacs Manual}). The
@code{help-echo} and @code{keymap} properties in @var{string} have
special meanings. @xref{Properties in Mode}.
@item @var{symbol}
A symbol as a mode line construct stands for its value. The value of
@var{symbol} is used as a mode line construct, in place of @var{symbol}.
However, the symbols @code{t} and @code{nil} are ignored, as is any
symbol whose value is void.
There is one exception: if the value of @var{symbol} is a string, it is
displayed verbatim: the @code{%}-constructs are not recognized.
Unless @var{symbol} is marked as risky (i.e., it has a
non-@code{nil} @code{risky-local-variable} property), all text
properties specified in @var{symbol}'s value are ignored. This includes
the text properties of strings in @var{symbol}'s value, as well as all
@code{:eval} and @code{:propertize} forms in it. (The reason for this
is security: non-risky variables could be set automatically from file
variables without prompting the user.)
@item (@var{string} @var{rest}@dots{})
@itemx (@var{list} @var{rest}@dots{})
A list whose first element is a string or list means to process all the
elements recursively and concatenate the results. This is the most
common form of mode line construct.
@item (:eval @var{form})
A list whose first element is the symbol @code{:eval} says to evaluate
@var{form}, and use the result as a string to display. Make sure this
evaluation cannot load any files, as doing so could cause infinite
recursion.
@item (:propertize @var{elt} @var{props}@dots{})
A list whose first element is the symbol @code{:propertize} says to
process the mode line construct @var{elt} recursively, then add the text
properties specified by @var{props} to the result. The argument
@var{props} should consist of zero or more pairs @var{text-property}
@var{value}.
@item (@var{symbol} @var{then} @var{else})
A list whose first element is a symbol that is not a keyword specifies
a conditional. Its meaning depends on the value of @var{symbol}. If
@var{symbol} has a non-@code{nil} value, the second element,
@var{then}, is processed recursively as a mode line construct.
Otherwise, the third element, @var{else}, is processed recursively.
You may omit @var{else}; then the mode line construct displays nothing
if the value of @var{symbol} is @code{nil} or void.
@item (@var{width} @var{rest}@dots{})
A list whose first element is an integer specifies truncation or
padding of the results of @var{rest}. The remaining elements
@var{rest} are processed recursively as mode line constructs and
concatenated together. When @var{width} is positive, the result is
space filled on the right if its width is less than @var{width}. When
@var{width} is negative, the result is truncated on the right to
@minus{}@var{width} columns if its width exceeds @minus{}@var{width}.
For example, the usual way to show what percentage of a buffer is above
the top of the window is to use a list like this: @code{(-3 "%p")}.
@end table
@node Mode Line Top
@subsection The Top Level of Mode Line Control
The variable in overall control of the mode line is
@code{mode-line-format}.
@defopt mode-line-format
The value of this variable is a mode line construct that controls the
contents of the mode-line. It is always buffer-local in all buffers.
If you set this variable to @code{nil} in a buffer, that buffer does not
have a mode line. (A window that is just one line tall also does not
display a mode line.)
@end defopt
The default value of @code{mode-line-format} is designed to use the
values of other variables such as @code{mode-line-position} and
@code{mode-line-modes} (which in turn incorporates the values of the
variables @code{mode-name} and @code{minor-mode-alist}). Very few
modes need to alter @code{mode-line-format} itself. For most
purposes, it is sufficient to alter some of the variables that
@code{mode-line-format} either directly or indirectly refers to.
If you do alter @code{mode-line-format} itself, the new value should
use the same variables that appear in the default value (@pxref{Mode
Line Variables}), rather than duplicating their contents or displaying
the information in another fashion. This way, customizations made by
the user or by Lisp programs (such as @code{display-time} and major
modes) via changes to those variables remain effective.
Here is a hypothetical example of a @code{mode-line-format} that might
be useful for Shell mode (in reality, Shell mode does not set
@code{mode-line-format}):
@example
@group
(setq mode-line-format
(list "-"
'mode-line-mule-info
'mode-line-modified
'mode-line-frame-identification
"%b--"
@end group
@group
;; @r{Note that this is evaluated while making the list.}
;; @r{It makes a mode line construct which is just a string.}
(getenv "HOST")
@end group
":"
'default-directory
" "
'global-mode-string
" %[("
'(:eval (mode-line-mode-name))
'mode-line-process
'minor-mode-alist
"%n"
")%]--"
@group
'(which-func-mode ("" which-func-format "--"))
'(line-number-mode "L%l--")
'(column-number-mode "C%c--")
'(-3 "%p")))
@end group
@end example
@noindent
(The variables @code{line-number-mode}, @code{column-number-mode}
and @code{which-func-mode} enable particular minor modes; as usual,
these variable names are also the minor mode command names.)
@node Mode Line Variables
@subsection Variables Used in the Mode Line
This section describes variables incorporated by the standard value of
@code{mode-line-format} into the text of the mode line. There is
nothing inherently special about these variables; any other variables
could have the same effects on the mode line if the value of
@code{mode-line-format} is changed to use them. However, various parts
of Emacs set these variables on the understanding that they will control
parts of the mode line; therefore, practically speaking, it is essential
for the mode line to use them. Also see
@ref{Optional Mode Line,,, emacs, The GNU Emacs Manual}.
@defvar mode-line-mule-info
This variable holds the value of the mode line construct that displays
information about the language environment, buffer coding system, and
current input method. @xref{Non-ASCII Characters}.
@end defvar
@defvar mode-line-modified
This variable holds the value of the mode line construct that displays
whether the current buffer is modified. Its default value displays
@samp{**} if the buffer is modified, @samp{--} if the buffer is not
modified, @samp{%%} if the buffer is read only, and @samp{%*} if the
buffer is read only and modified.
Changing this variable does not force an update of the mode line.
@end defvar
@defvar mode-line-frame-identification
This variable identifies the current frame. Its default value
displays @code{" "} if you are using a window system which can show
multiple frames, or @code{"-%F "} on an ordinary terminal which shows
only one frame at a time.
@end defvar
@defvar mode-line-buffer-identification
This variable identifies the buffer being displayed in the window.
Its default value displays the buffer name, padded with spaces to at
least 12 columns.
@end defvar
@defvar mode-line-position
This variable indicates the position in the buffer. Its default value
displays the buffer percentage and, optionally, the buffer size, the
line number and the column number.
@end defvar
@defopt mode-line-percent-position
This option is used in @code{mode-line-position}. Its value specifies
both the buffer percentage to display (one of @code{nil}, @code{"%o"},
@code{"%p"}, @code{"%P"} or @code{"%q"}, @pxref{%-Constructs}) and a
width to space-fill or truncate to. You are recommended to set this
option with the @code{customize-variable} facility.
@end defopt
@defvar vc-mode
The variable @code{vc-mode}, buffer-local in each buffer, records
whether the buffer's visited file is maintained with version control,
and, if so, which kind. Its value is a string that appears in the mode
line, or @code{nil} for no version control.
@end defvar
@defvar mode-line-modes
This variable displays the buffer's major and minor modes. Its
default value also displays the recursive editing level, information
on the process status, and whether narrowing is in effect.
@end defvar
@defvar mode-line-remote
This variable is used to show whether @code{default-directory} for the
current buffer is remote.
@end defvar
@defvar mode-line-client
This variable is used to identify @code{emacsclient} frames.
@end defvar
The following three variables are used in @code{mode-line-modes}:
@defvar mode-name
This buffer-local variable holds the ``pretty'' name of the current
buffer's major mode. Each major mode should set this variable so that
the mode name will appear in the mode line. The value does not have
to be a string, but can use any of the data types valid in a mode-line
construct (@pxref{Mode Line Data}). To compute the string that will
identify the mode name in the mode line, use @code{format-mode-line}
(@pxref{Emulating Mode Line}).
@end defvar
@defvar mode-line-process
This buffer-local variable contains the mode line information on process
status in modes used for communicating with subprocesses. It is
displayed immediately following the major mode name, with no intervening
space. For example, its value in the @file{*shell*} buffer is
@code{(":%s")}, which allows the shell to display its status along
with the major mode as: @samp{(Shell:run)}. Normally this variable
is @code{nil}.
@end defvar
@defvar mode-line-front-space
This variable is displayed at the front of the mode line. By default,
this construct is displayed right at the beginning of the mode line,
except that if there is a memory-full message, it is displayed first.
@end defvar
@defvar mode-line-end-spaces
This variable is displayed at the end of the mode line.
@end defvar
@defvar mode-line-misc-info
Mode line construct for miscellaneous information. By default, this
shows the information specified by @code{global-mode-string}.
@end defvar
@defvar minor-mode-alist
@anchor{Definition of minor-mode-alist}
This variable holds an association list whose elements specify how the
mode line should indicate that a minor mode is active. Each element of
the @code{minor-mode-alist} should be a two-element list:
@example
(@var{minor-mode-variable} @var{mode-line-string})
@end example
More generally, @var{mode-line-string} can be any mode line construct.
It appears in the mode line when the value of @var{minor-mode-variable}
is non-@code{nil}, and not otherwise. These strings should begin with
spaces so that they don't run together. Conventionally, the
@var{minor-mode-variable} for a specific mode is set to a non-@code{nil}
value when that minor mode is activated.
@code{minor-mode-alist} itself is not buffer-local. Each variable
mentioned in the alist should be buffer-local if its minor mode can be
enabled separately in each buffer.
@end defvar
@defvar global-mode-string
This variable holds a mode line construct that, by default, appears in
the mode line just after the @code{which-func-mode} minor mode if set,
else after @code{mode-line-modes}. The command @code{display-time} sets
@code{global-mode-string} to refer to the variable
@code{display-time-string}, which holds a string containing the time and
load information.
The @samp{%M} construct substitutes the value of
@code{global-mode-string}, but that is obsolete, since the variable is
included in the mode line from @code{mode-line-format}.
@end defvar
Here is a simplified version of the default value of
@code{mode-line-format}. The real default value also
specifies addition of text properties.
@example
@group
("-"
mode-line-mule-info
mode-line-modified
mode-line-frame-identification
mode-line-buffer-identification
@end group
" "
mode-line-position
(vc-mode vc-mode)
" "
@group
mode-line-modes
(which-func-mode ("" which-func-format "--"))
(global-mode-string ("--" global-mode-string))
"-%-")
@end group
@end example
@node %-Constructs
@subsection @code{%}-Constructs in the Mode Line
Strings used as mode line constructs can use certain
@code{%}-constructs to substitute various kinds of data. The
following is a list of the defined @code{%}-constructs, and what they
mean.
In any construct except @samp{%%}, you can add a decimal integer
after the @samp{%} to specify a minimum field width. If the width is
less, the field is padded to that width. Purely numeric constructs
(@samp{c}, @samp{i}, @samp{I}, and @samp{l}) are padded by inserting
spaces to the left, and others are padded by inserting spaces to the
right.
@table @code
@item %b
The current buffer name, obtained with the @code{buffer-name} function.
@xref{Buffer Names}.
@item %c
The current column number of point, counting from zero starting at the
left margin of the window.
@item %C
The current column number of point, counting from one starting at the
left margin of the window.
@item %e
When Emacs is nearly out of memory for Lisp objects, a brief message
saying so. Otherwise, this is empty.
@item %f
The visited file name, obtained with the @code{buffer-file-name}
function. @xref{Buffer File Name}.
@item %F
The title (only on a window system) or the name of the selected frame.
@xref{Basic Parameters}.
@item %i
The size of the accessible part of the current buffer; basically
@code{(- (point-max) (point-min))}.
@item %I
Like @samp{%i}, but the size is printed in a more readable way by using
@samp{k} for 10^3, @samp{M} for 10^6, @samp{G} for 10^9, etc., to
abbreviate.
@item %l
The current line number of point, counting within the accessible portion
of the buffer.
@item %n
@samp{Narrow} when narrowing is in effect; nothing otherwise (see
@code{narrow-to-region} in @ref{Narrowing}).
@item %o
The degree of @dfn{travel} of the window through (the visible portion
of) the buffer, i.e. the size of the text above the top of the window
expressed as a percentage of all the text outside the window, or
@samp{Top}, @samp{Bottom} or @samp{All}.
@item %p
The percentage of the buffer text above the @strong{top} of window, or
@samp{Top}, @samp{Bottom} or @samp{All}. Note that the default mode
line construct truncates this to three characters.
@item %P
The percentage of the buffer text that is above the @strong{bottom} of
the window (which includes the text visible in the window, as well as
the text above the top), plus @samp{Top} if the top of the buffer is
visible on screen; or @samp{Bottom} or @samp{All}.
@item %q
The percentages of text above both the @strong{top} and the
@strong{bottom} of the window, separated by @samp{-}, or @samp{All}.
@item %s
The status of the subprocess belonging to the current buffer, obtained with
@code{process-status}. @xref{Process Information}.
@item %z
The mnemonics of keyboard, terminal, and buffer coding systems.
@item %Z
Like @samp{%z}, but including the end-of-line format.
@item %*
@samp{%} if the buffer is read only (see @code{buffer-read-only}); @*
@samp{*} if the buffer is modified (see @code{buffer-modified-p}); @*
@samp{-} otherwise. @xref{Buffer Modification}.
@item %+
@samp{*} if the buffer is modified (see @code{buffer-modified-p}); @*
@samp{%} if the buffer is read only (see @code{buffer-read-only}); @*
@samp{-} otherwise. This differs from @samp{%*} only for a modified
read-only buffer. @xref{Buffer Modification}.
@item %&
@samp{*} if the buffer is modified, and @samp{-} otherwise.
@item %[
An indication of the depth of recursive editing levels (not counting
minibuffer levels): one @samp{[} for each editing level.
@xref{Recursive Editing}.
@item %]
One @samp{]} for each recursive editing level (not counting minibuffer
levels).
@item %-
Dashes sufficient to fill the remainder of the mode line.
@item %%
The character @samp{%}---this is how to include a literal @samp{%} in a
string in which @code{%}-constructs are allowed.
@end table
The following two @code{%}-constructs are still supported, but they are
obsolete, since you can get the same results with the variables
@code{mode-name} and @code{global-mode-string}.
@table @code
@item %m
The value of @code{mode-name}.
@item %M
The value of @code{global-mode-string}.
@end table
@node Properties in Mode
@subsection Properties in the Mode Line
@cindex text properties in the mode line
Certain text properties are meaningful in the
mode line. The @code{face} property affects the appearance of text; the
@code{help-echo} property associates help strings with the text, and
@code{keymap} can make the text mouse-sensitive.
There are four ways to specify text properties for text in the mode
line:
@enumerate
@item
Put a string with a text property directly into the mode line data
structure.
@item
Put a text property on a mode line %-construct such as @samp{%12b}; then
the expansion of the %-construct will have that same text property.
@item
Use a @code{(:propertize @var{elt} @var{props}@dots{})} construct to
give @var{elt} a text property specified by @var{props}.
@item
Use a list containing @code{:eval @var{form}} in the mode line data
structure, and make @var{form} evaluate to a string that has a text
property.
@end enumerate
You can use the @code{keymap} property to specify a keymap. This
keymap only takes real effect for mouse clicks; binding character keys
and function keys to it has no effect, since it is impossible to move
point into the mode line.
When the mode line refers to a variable which does not have a
non-@code{nil} @code{risky-local-variable} property, any text
properties given or specified within that variable's values are
ignored. This is because such properties could otherwise specify
functions to be called, and those functions could come from file
local variables.
@node Header Lines
@subsection Window Header Lines
@cindex header line (of a window)
@cindex window header line
A window can have a @dfn{header line} at the top, just as it can have
a mode line at the bottom. The header line feature works just like the
mode line feature, except that it's controlled by
@code{header-line-format}:
@defvar header-line-format
This variable, local in every buffer, specifies how to display the
header line, for windows displaying the buffer. The format of the value
is the same as for @code{mode-line-format} (@pxref{Mode Line Data}).
It is normally @code{nil}, so that ordinary buffers have no header line.
@end defvar
@defun window-header-line-height &optional window
This function returns the height in pixels of @var{window}'s header
line. @var{window} must be a live window, and defaults to the
selected window.
@end defun
A window that is just one line tall never displays a header line. A
window that is two lines tall cannot display both a mode line and a
header line at once; if it has a mode line, then it does not display a
header line.
@node Emulating Mode Line
@subsection Emulating Mode Line Formatting
You can use the function @code{format-mode-line} to compute the text
that would appear in a mode line or header line based on a certain
mode line construct.
@defun format-mode-line format &optional face window buffer
This function formats a line of text according to @var{format} as if it
were generating the mode line for @var{window}, but it also returns the
text as a string. The argument @var{window} defaults to the selected
window. If @var{buffer} is non-@code{nil}, all the information used is
taken from @var{buffer}; by default, it comes from @var{window}'s
buffer.
The value string normally has text properties that correspond to the
faces, keymaps, etc., that the mode line would have. Any character for
which no @code{face} property is specified by @var{format} gets a
default value determined by @var{face}. If @var{face} is @code{t}, that
stands for either @code{mode-line} if @var{window} is selected,
otherwise @code{mode-line-inactive}. If @var{face} is @code{nil} or
omitted, that stands for the default face. If @var{face} is an integer,
the value returned by this function will have no text properties.
You can also specify other valid faces as the value of @var{face}.
If specified, that face provides the @code{face} property for characters
whose face is not specified by @var{format}.
Note that using @code{mode-line}, @code{mode-line-inactive}, or
@code{header-line} as @var{face} will actually redisplay the mode line
or the header line, respectively, using the current definitions of the
corresponding face, in addition to returning the formatted string.
(Other faces do not cause redisplay.)
For example, @code{(format-mode-line header-line-format)} returns the
text that would appear in the selected window's header line (@code{""}
if it has no header line). @code{(format-mode-line header-line-format
'header-line)} returns the same text, with each character
carrying the face that it will have in the header line itself, and also
redraws the header line.
@end defun
@node Imenu
@section Imenu
@cindex Imenu
@dfn{Imenu} is a feature that lets users select a definition or
section in the buffer, from a menu which lists all of them, to go
directly to that location in the buffer. Imenu works by constructing
a buffer index which lists the names and buffer positions of the
definitions, or other named portions of the buffer; then the user can
choose one of them and move point to it. Major modes can add a menu
bar item to use Imenu using @code{imenu-add-to-menubar}.
@deffn Command imenu-add-to-menubar name
This function defines a local menu bar item named @var{name}
to run Imenu.
@end deffn
The user-level commands for using Imenu are described in the Emacs
Manual (@pxref{Imenu,, Imenu, emacs, the Emacs Manual}). This section
explains how to customize Imenu's method of finding definitions or
buffer portions for a particular major mode.
The usual and simplest way is to set the variable
@code{imenu-generic-expression}:
@defvar imenu-generic-expression
This variable, if non-@code{nil}, is a list that specifies regular
expressions for finding definitions for Imenu. Simple elements of
@code{imenu-generic-expression} look like this:
@example
(@var{menu-title} @var{regexp} @var{index})
@end example
Here, if @var{menu-title} is non-@code{nil}, it says that the matches
for this element should go in a submenu of the buffer index;
@var{menu-title} itself specifies the name for the submenu. If
@var{menu-title} is @code{nil}, the matches for this element go directly
in the top level of the buffer index.
The second item in the list, @var{regexp}, is a regular expression
(@pxref{Regular Expressions}); anything in the buffer that it matches
is considered a definition, something to mention in the buffer index.
The third item, @var{index}, is a non-negative integer that indicates
which subexpression in @var{regexp} matches the definition's name.
An element can also look like this:
@example
(@var{menu-title} @var{regexp} @var{index} @var{function} @var{arguments}@dots{})
@end example
Each match for this element creates an index item, and when the index
item is selected by the user, it calls @var{function} with arguments
consisting of the item name, the buffer position, and @var{arguments}.
For Emacs Lisp mode, @code{imenu-generic-expression} could look like
this:
@c should probably use imenu-syntax-alist and \\sw rather than [-A-Za-z0-9+]
@example
@group
((nil "^\\s-*(def\\(un\\|subst\\|macro\\|advice\\)\
\\s-+\\([-A-Za-z0-9+]+\\)" 2)
@end group
@group
("*Vars*" "^\\s-*(def\\(var\\|const\\)\
\\s-+\\([-A-Za-z0-9+]+\\)" 2)
@end group
@group
("*Types*"
"^\\s-*\
(def\\(type\\|struct\\|class\\|ine-condition\\)\
\\s-+\\([-A-Za-z0-9+]+\\)" 2))
@end group
@end example
Setting this variable makes it buffer-local in the current buffer.
@end defvar
@defvar imenu-case-fold-search
This variable controls whether matching against the regular
expressions in the value of @code{imenu-generic-expression} is
case-sensitive: @code{t}, the default, means matching should ignore
case.
Setting this variable makes it buffer-local in the current buffer.
@end defvar
@defvar imenu-syntax-alist
This variable is an alist of syntax table modifiers to use while
processing @code{imenu-generic-expression}, to override the syntax table
of the current buffer. Each element should have this form:
@example
(@var{characters} . @var{syntax-description})
@end example
The @sc{car}, @var{characters}, can be either a character or a string.
The element says to give that character or characters the syntax
specified by @var{syntax-description}, which is passed to
@code{modify-syntax-entry} (@pxref{Syntax Table Functions}).
This feature is typically used to give word syntax to characters which
normally have symbol syntax, and thus to simplify
@code{imenu-generic-expression} and speed up matching.
For example, Fortran mode uses it this way:
@example
(setq imenu-syntax-alist '(("_$" . "w")))
@end example
The @code{imenu-generic-expression} regular expressions can then use
@samp{\\sw+} instead of @samp{\\(\\sw\\|\\s_\\)+}. Note that this
technique may be inconvenient when the mode needs to limit the initial
character of a name to a smaller set of characters than are allowed in
the rest of a name.
Setting this variable makes it buffer-local in the current buffer.
@end defvar
Another way to customize Imenu for a major mode is to set the
variables @code{imenu-prev-index-position-function} and
@code{imenu-extract-index-name-function}:
@defvar imenu-prev-index-position-function
If this variable is non-@code{nil}, its value should be a function that
finds the next definition to put in the buffer index, scanning
backward in the buffer from point. It should return @code{nil} if it
doesn't find another definition before point. Otherwise it should
leave point at the place it finds a definition and return any
non-@code{nil} value.
Setting this variable makes it buffer-local in the current buffer.
@end defvar
@defvar imenu-extract-index-name-function
If this variable is non-@code{nil}, its value should be a function to
return the name for a definition, assuming point is in that definition
as the @code{imenu-prev-index-position-function} function would leave
it.
Setting this variable makes it buffer-local in the current buffer.
@end defvar
The last way to customize Imenu for a major mode is to set the
variable @code{imenu-create-index-function}:
@defvar imenu-create-index-function
This variable specifies the function to use for creating a buffer
index. The function should take no arguments, and return an index
alist for the current buffer. It is called within
@code{save-excursion}, so where it leaves point makes no difference.
The index alist can have three types of elements. Simple elements
look like this:
@example
(@var{index-name} . @var{index-position})
@end example
Selecting a simple element has the effect of moving to position
@var{index-position} in the buffer. Special elements look like this:
@example
(@var{index-name} @var{index-position} @var{function} @var{arguments}@dots{})
@end example
Selecting a special element performs:
@example
(funcall @var{function}
@var{index-name} @var{index-position} @var{arguments}@dots{})
@end example
A nested sub-alist element looks like this:
@example
(@var{menu-title} . @var{sub-alist})
@end example
It creates the submenu @var{menu-title} specified by @var{sub-alist}.
The default value of @code{imenu-create-index-function} is
@code{imenu-default-create-index-function}. This function calls the
value of @code{imenu-prev-index-position-function} and the value of
@code{imenu-extract-index-name-function} to produce the index alist.
However, if either of these two variables is @code{nil}, the default
function uses @code{imenu-generic-expression} instead.
Setting this variable makes it buffer-local in the current buffer.
@end defvar
@node Font Lock Mode
@section Font Lock Mode
@cindex Font Lock mode
@dfn{Font Lock mode} is a buffer-local minor mode that automatically
attaches @code{face} properties to certain parts of the buffer based on
their syntactic role. How it parses the buffer depends on the major
mode; most major modes define syntactic criteria for which faces to use
in which contexts. This section explains how to customize Font Lock for
a particular major mode.
Font Lock mode finds text to highlight in two ways: through
syntactic parsing based on the syntax table, and through searching
(usually for regular expressions). Syntactic fontification happens
first; it finds comments and string constants and highlights them.
Search-based fontification happens second.
@menu
* Font Lock Basics:: Overview of customizing Font Lock.
* Search-based Fontification:: Fontification based on regexps.
* Customizing Keywords:: Customizing search-based fontification.
* Other Font Lock Variables:: Additional customization facilities.
* Levels of Font Lock:: Each mode can define alternative levels
so that the user can select more or less.
* Precalculated Fontification:: How Lisp programs that produce the buffer
contents can also specify how to fontify it.
* Faces for Font Lock:: Special faces specifically for Font Lock.
* Syntactic Font Lock:: Fontification based on syntax tables.
* Multiline Font Lock:: How to coerce Font Lock into properly
highlighting multiline constructs.
@end menu
@node Font Lock Basics
@subsection Font Lock Basics
The Font Lock functionality is based on several basic functions.
Each of these calls the function specified by the corresponding
variable. This indirection allows major and minor modes to modify the
way fontification works in the buffers of that mode, and even use the
Font Lock mechanisms for features that have nothing to do with
fontification. (This is why the description below says ``should''
when it describes what the functions do: the mode can customize the
values of the corresponding variables to do something entirely
different.) The variables mentioned below are described in @ref{Other
Font Lock Variables}.
@ftable @code
@item font-lock-fontify-buffer
This function should fontify the current buffer's accessible portion,
by calling the function specified by
@code{font-lock-fontify-buffer-function}.
@item font-lock-unfontify-buffer
Used when turning Font Lock off to remove the fontification. Calls
the function specified by @code{font-lock-unfontify-buffer-function}.
@item font-lock-fontify-region beg end &optional loudly
Should fontify the region between @var{beg} and @var{end}. If
@var{loudly} is non-@code{nil}, should display status messages while
fontifying. Calls the function specified by
@code{font-lock-fontify-region-function}.
@item font-lock-unfontify-region beg end
Should remove fontification from the region between @var{beg} and
@var{end}. Calls the function specified by
@code{font-lock-unfontify-region-function}.
@item font-lock-flush &optional beg end
This function should mark the fontification of the region between
@var{beg} and @var{end} as outdated. If not specified or @code{nil},
@var{beg} and @var{end} default to the beginning and end of the
buffer's accessible portion. Calls the function specified by
@code{font-lock-flush-function}.
@item font-lock-ensure &optional beg end
This function should make sure the region between @var{beg} and
@var{end} has been fontified. The optional arguments @var{beg} and
@var{end} default to the beginning and the end of the buffer's
accessible portion. Calls the function specified by
@code{font-lock-ensure-function}.
@end ftable
There are several variables that control how Font Lock mode highlights
text. But major modes should not set any of these variables directly.
Instead, they should set @code{font-lock-defaults} as a buffer-local
variable. The value assigned to this variable is used, if and when Font
Lock mode is enabled, to set all the other variables.
@defvar font-lock-defaults
This variable is set by modes to specify how to fontify text in that
mode. It automatically becomes buffer-local when set. If its value
is @code{nil}, Font Lock mode does no highlighting, and you can use
the @samp{Faces} menu (under @samp{Edit} and then @samp{Text
Properties} in the menu bar) to assign faces explicitly to text in the
buffer.
If non-@code{nil}, the value should look like this:
@example
(@var{keywords} [@var{keywords-only} [@var{case-fold}
[@var{syntax-alist} @var{other-vars}@dots{}]]])
@end example
The first element, @var{keywords}, indirectly specifies the value of
@code{font-lock-keywords} which directs search-based fontification.
It can be a symbol, a variable or a function whose value is the list
to use for @code{font-lock-keywords}. It can also be a list of
several such symbols, one for each possible level of fontification.
The first symbol specifies the @samp{mode default} level of
fontification, the next symbol level 1 fontification, the next level 2,
and so on. The @samp{mode default} level is normally the same as level
1. It is used when @code{font-lock-maximum-decoration} has a @code{nil}
value. @xref{Levels of Font Lock}.
The second element, @var{keywords-only}, specifies the value of the
variable @code{font-lock-keywords-only}. If this is omitted or
@code{nil}, syntactic fontification (of strings and comments) is also
performed. If this is non-@code{nil}, syntactic fontification is not
performed. @xref{Syntactic Font Lock}.
The third element, @var{case-fold}, specifies the value of
@code{font-lock-keywords-case-fold-search}. If it is non-@code{nil},
Font Lock mode ignores case during search-based fontification.
If the fourth element, @var{syntax-alist}, is non-@code{nil}, it should
be a list of cons cells of the form @code{(@var{char-or-string}
. @var{string})}. These are used to set up a syntax table for syntactic
fontification; the resulting syntax table is stored in
@code{font-lock-syntax-table}. If @var{syntax-alist} is omitted or
@code{nil}, syntactic fontification uses the syntax table returned by
the @code{syntax-table} function. @xref{Syntax Table Functions}.
All the remaining elements (if any) are collectively called
@var{other-vars}. Each of these elements should have the form
@code{(@var{variable} . @var{value})}---which means, make
@var{variable} buffer-local and then set it to @var{value}. You can
use these @var{other-vars} to set other variables that affect
fontification, aside from those you can control with the first five
elements. @xref{Other Font Lock Variables}.
@end defvar
If your mode fontifies text explicitly by adding
@code{font-lock-face} properties, it can specify @code{(nil t)} for
@code{font-lock-defaults} to turn off all automatic fontification.
However, this is not required; it is possible to fontify some things
using @code{font-lock-face} properties and set up automatic
fontification for other parts of the text.
@node Search-based Fontification
@subsection Search-based Fontification
The variable which directly controls search-based fontification is
@code{font-lock-keywords}, which is typically specified via the
@var{keywords} element in @code{font-lock-defaults}.
@defvar font-lock-keywords
The value of this variable is a list of the keywords to highlight. Lisp
programs should not set this variable directly. Normally, the value is
automatically set by Font Lock mode, using the @var{keywords} element in
@code{font-lock-defaults}. The value can also be altered using the
functions @code{font-lock-add-keywords} and
@code{font-lock-remove-keywords} (@pxref{Customizing Keywords}).
@end defvar
Each element of @code{font-lock-keywords} specifies how to find
certain cases of text, and how to highlight those cases. Font Lock mode
processes the elements of @code{font-lock-keywords} one by one, and for
each element, it finds and handles all matches. Ordinarily, once
part of the text has been fontified already, this cannot be overridden
by a subsequent match in the same text; but you can specify different
behavior using the @var{override} element of a @var{subexp-highlighter}.
Each element of @code{font-lock-keywords} should have one of these
forms:
@table @code
@item @var{regexp}
Highlight all matches for @var{regexp} using
@code{font-lock-keyword-face}. For example,
@example
;; @r{Highlight occurrences of the word @samp{foo}}
;; @r{using @code{font-lock-keyword-face}.}
"\\<foo\\>"
@end example
Be careful when composing these regular expressions; a poorly written
pattern can dramatically slow things down! The function
@code{regexp-opt} (@pxref{Regexp Functions}) is useful for calculating
optimal regular expressions to match several keywords.
@item @var{function}
Find text by calling @var{function}, and highlight the matches
it finds using @code{font-lock-keyword-face}.
When @var{function} is called, it receives one argument, the limit of
the search; it should begin searching at point, and not search beyond the
limit. It should return non-@code{nil} if it succeeds, and set the
match data to describe the match that was found. Returning @code{nil}
indicates failure of the search.
Fontification will call @var{function} repeatedly with the same limit,
and with point where the previous invocation left it, until
@var{function} fails. On failure, @var{function} need not reset point
in any particular way.
@item (@var{matcher} . @var{subexp})
In this kind of element, @var{matcher} is either a regular
expression or a function, as described above. The @sc{cdr},
@var{subexp}, specifies which subexpression of @var{matcher} should be
highlighted (instead of the entire text that @var{matcher} matched).
@example
;; @r{Highlight the @samp{bar} in each occurrence of @samp{fubar},}
;; @r{using @code{font-lock-keyword-face}.}
("fu\\(bar\\)" . 1)
@end example
If you use @code{regexp-opt} to produce the regular expression
@var{matcher}, you can use @code{regexp-opt-depth} (@pxref{Regexp
Functions}) to calculate the value for @var{subexp}.
@item (@var{matcher} . @var{facespec})
In this kind of element, @var{facespec} is an expression whose value
specifies the face to use for highlighting. In the simplest case,
@var{facespec} is a Lisp variable (a symbol) whose value is a face
name.
@example
;; @r{Highlight occurrences of @samp{fubar},}
;; @r{using the face which is the value of @code{fubar-face}.}
("fubar" . fubar-face)
@end example
However, @var{facespec} can also evaluate to a list of this form:
@example
(face @var{face} @var{prop1} @var{val1} @var{prop2} @var{val2}@dots{})
@end example
@noindent
to specify the face @var{face} and various additional text properties
to put on the text that matches. If you do this, be sure to add the
other text property names that you set in this way to the value of
@code{font-lock-extra-managed-props} so that the properties will also
be cleared out when they are no longer appropriate. Alternatively,
you can set the variable @code{font-lock-unfontify-region-function} to
a function that clears these properties. @xref{Other Font Lock
Variables}.
@item (@var{matcher} . @var{subexp-highlighter})
In this kind of element, @var{subexp-highlighter} is a list
which specifies how to highlight matches found by @var{matcher}.
It has the form:
@example
(@var{subexp} @var{facespec} [@var{override} [@var{laxmatch}]])
@end example
The @sc{car}, @var{subexp}, is an integer specifying which subexpression
of the match to fontify (0 means the entire matching text). The second
subelement, @var{facespec}, is an expression whose value specifies the
face, as described above.
The last two values in @var{subexp-highlighter}, @var{override} and
@var{laxmatch}, are optional flags. If @var{override} is @code{t},
this element can override existing fontification made by previous
elements of @code{font-lock-keywords}. If it is @code{keep}, then
each character is fontified if it has not been fontified already by
some other element. If it is @code{prepend}, the face specified by
@var{facespec} is added to the beginning of the @code{font-lock-face}
property. If it is @code{append}, the face is added to the end of the
@code{font-lock-face} property.
If @var{laxmatch} is non-@code{nil}, it means there should be no error
if there is no subexpression numbered @var{subexp} in @var{matcher}.
Obviously, fontification of the subexpression numbered @var{subexp} will
not occur. However, fontification of other subexpressions (and other
regexps) will continue. If @var{laxmatch} is @code{nil}, and the
specified subexpression is missing, then an error is signaled which
terminates search-based fontification.
Here are some examples of elements of this kind, and what they do:
@smallexample
;; @r{Highlight occurrences of either @samp{foo} or @samp{bar}, using}
;; @r{@code{foo-bar-face}, even if they have already been highlighted.}
;; @r{@code{foo-bar-face} should be a variable whose value is a face.}
("foo\\|bar" 0 foo-bar-face t)
;; @r{Highlight the first subexpression within each occurrence}
;; @r{that the function @code{fubar-match} finds,}
;; @r{using the face which is the value of @code{fubar-face}.}
(fubar-match 1 fubar-face)
@end smallexample
@item (@var{matcher} . @var{anchored-highlighter})
In this kind of element, @var{anchored-highlighter} specifies how to
highlight text that follows a match found by @var{matcher}. So a
match found by @var{matcher} acts as the anchor for further searches
specified by @var{anchored-highlighter}. @var{anchored-highlighter}
is a list of the following form:
@example
(@var{anchored-matcher} @var{pre-form} @var{post-form}
@var{subexp-highlighters}@dots{})
@end example
Here, @var{anchored-matcher}, like @var{matcher}, is either a regular
expression or a function. After a match of @var{matcher} is found,
point is at the end of the match. Now, Font Lock evaluates the form
@var{pre-form}. Then it searches for matches of
@var{anchored-matcher} and uses @var{subexp-highlighters} to highlight
these. A @var{subexp-highlighter} is as described above. Finally,
Font Lock evaluates @var{post-form}.
The forms @var{pre-form} and @var{post-form} can be used to initialize
before, and cleanup after, @var{anchored-matcher} is used. Typically,
@var{pre-form} is used to move point to some position relative to the
match of @var{matcher}, before starting with @var{anchored-matcher}.
@var{post-form} might be used to move back, before resuming with
@var{matcher}.
After Font Lock evaluates @var{pre-form}, it does not search for
@var{anchored-matcher} beyond the end of the line. However, if
@var{pre-form} returns a buffer position that is greater than the
position of point after @var{pre-form} is evaluated, then the position
returned by @var{pre-form} is used as the limit of the search instead.
It is generally a bad idea to return a position greater than the end
of the line; in other words, the @var{anchored-matcher} search should
not span lines.
For example,
@smallexample
;; @r{Highlight occurrences of the word @samp{item} following}
;; @r{an occurrence of the word @samp{anchor} (on the same line)}
;; @r{in the value of @code{item-face}.}
("\\<anchor\\>" "\\<item\\>" nil nil (0 item-face))
@end smallexample
Here, @var{pre-form} and @var{post-form} are @code{nil}. Therefore
searching for @samp{item} starts at the end of the match of
@samp{anchor}, and searching for subsequent instances of @samp{anchor}
resumes from where searching for @samp{item} concluded.
@item (@var{matcher} @var{highlighters}@dots{})
This sort of element specifies several @var{highlighter} lists for a
single @var{matcher}. A @var{highlighter} list can be of the type
@var{subexp-highlighter} or @var{anchored-highlighter} as described
above.
For example,
@smallexample
;; @r{Highlight occurrences of the word @samp{anchor} in the value}
;; @r{of @code{anchor-face}, and subsequent occurrences of the word}
;; @r{@samp{item} (on the same line) in the value of @code{item-face}.}
("\\<anchor\\>" (0 anchor-face)
("\\<item\\>" nil nil (0 item-face)))
@end smallexample
@item (eval . @var{form})
Here @var{form} is an expression to be evaluated the first time
this value of @code{font-lock-keywords} is used in a buffer.
Its value should have one of the forms described in this table.
@end table
@strong{Warning:} Do not design an element of @code{font-lock-keywords}
to match text which spans lines; this does not work reliably.
For details, see @xref{Multiline Font Lock}.
You can use @var{case-fold} in @code{font-lock-defaults} to specify
the value of @code{font-lock-keywords-case-fold-search} which says
whether search-based fontification should be case-insensitive.
@defvar font-lock-keywords-case-fold-search
Non-@code{nil} means that regular expression matching for the sake of
@code{font-lock-keywords} should be case-insensitive.
@end defvar
@node Customizing Keywords
@subsection Customizing Search-Based Fontification
You can use @code{font-lock-add-keywords} to add additional
search-based fontification rules to a major mode, and
@code{font-lock-remove-keywords} to remove rules.
@defun font-lock-add-keywords mode keywords &optional how
This function adds highlighting @var{keywords}, for the current buffer
or for major mode @var{mode}. The argument @var{keywords} should be a
list with the same format as the variable @code{font-lock-keywords}.
If @var{mode} is a symbol which is a major mode command name, such as
@code{c-mode}, the effect is that enabling Font Lock mode in
@var{mode} will add @var{keywords} to @code{font-lock-keywords}.
Calling with a non-@code{nil} value of @var{mode} is correct only in
your @file{~/.emacs} file.
If @var{mode} is @code{nil}, this function adds @var{keywords} to
@code{font-lock-keywords} in the current buffer. This way of calling
@code{font-lock-add-keywords} is usually used in mode hook functions.
By default, @var{keywords} are added at the beginning of
@code{font-lock-keywords}. If the optional argument @var{how} is
@code{set}, they are used to replace the value of
@code{font-lock-keywords}. If @var{how} is any other non-@code{nil}
value, they are added at the end of @code{font-lock-keywords}.
Some modes provide specialized support you can use in additional
highlighting patterns. See the variables
@code{c-font-lock-extra-types}, @code{c++-font-lock-extra-types},
and @code{java-font-lock-extra-types}, for example.
@strong{Warning:} Major mode commands must not call
@code{font-lock-add-keywords} under any circumstances, either directly
or indirectly, except through their mode hooks. (Doing so would lead to
incorrect behavior for some minor modes.) They should set up their
rules for search-based fontification by setting
@code{font-lock-keywords}.
@end defun
@defun font-lock-remove-keywords mode keywords
This function removes @var{keywords} from @code{font-lock-keywords}
for the current buffer or for major mode @var{mode}. As in
@code{font-lock-add-keywords}, @var{mode} should be a major mode
command name or @code{nil}. All the caveats and requirements for
@code{font-lock-add-keywords} apply here too. The argument
@var{keywords} must exactly match the one used by the corresponding
@code{font-lock-add-keywords}.
@end defun
For example, the following code adds two fontification patterns for C
mode: one to fontify the word @samp{FIXME}, even in comments, and
another to fontify the words @samp{and}, @samp{or} and @samp{not} as
keywords.
@smallexample
(font-lock-add-keywords 'c-mode
'(("\\<\\(FIXME\\):" 1 font-lock-warning-face prepend)
("\\<\\(and\\|or\\|not\\)\\>" . font-lock-keyword-face)))
@end smallexample
@noindent
This example affects only C mode proper. To add the same patterns to C
mode @emph{and} all modes derived from it, do this instead:
@smallexample
(add-hook 'c-mode-hook
(lambda ()
(font-lock-add-keywords nil
'(("\\<\\(FIXME\\):" 1 font-lock-warning-face prepend)
("\\<\\(and\\|or\\|not\\)\\>" .
font-lock-keyword-face)))))
@end smallexample
@node Other Font Lock Variables
@subsection Other Font Lock Variables
This section describes additional variables that a major mode can
set by means of @var{other-vars} in @code{font-lock-defaults}
(@pxref{Font Lock Basics}).
@defvar font-lock-mark-block-function
If this variable is non-@code{nil}, it should be a function that is
called with no arguments, to choose an enclosing range of text for
refontification for the command @kbd{M-o M-o}
(@code{font-lock-fontify-block}).
The function should report its choice by placing the region around it.
A good choice is a range of text large enough to give proper results,
but not too large so that refontification becomes slow. Typical values
are @code{mark-defun} for programming modes or @code{mark-paragraph} for
textual modes.
@end defvar
@defvar font-lock-extra-managed-props
This variable specifies additional properties (other than
@code{font-lock-face}) that are being managed by Font Lock mode. It
is used by @code{font-lock-default-unfontify-region}, which normally
only manages the @code{font-lock-face} property. If you want Font
Lock to manage other properties as well, you must specify them in a
@var{facespec} in @code{font-lock-keywords} as well as add them to
this list. @xref{Search-based Fontification}.
@end defvar
@defvar font-lock-fontify-buffer-function
Function to use for fontifying the buffer. The default value is
@code{font-lock-default-fontify-buffer}.
@end defvar
@defvar font-lock-unfontify-buffer-function
Function to use for unfontifying the buffer. This is used when
turning off Font Lock mode. The default value is
@code{font-lock-default-unfontify-buffer}.
@end defvar
@defvar font-lock-fontify-region-function
Function to use for fontifying a region. It should take two
arguments, the beginning and end of the region, and an optional third
argument @var{verbose}. If @var{verbose} is non-@code{nil}, the
function should print status messages. The default value is
@code{font-lock-default-fontify-region}.
@end defvar
@defvar font-lock-unfontify-region-function
Function to use for unfontifying a region. It should take two
arguments, the beginning and end of the region. The default value is
@code{font-lock-default-unfontify-region}.
@end defvar
@defvar font-lock-flush-function
Function to use for declaring that a region's fontification is out of
date. It takes two arguments, the beginning and end of the region.
The default value of this variable is
@code{font-lock-after-change-function}.
@end defvar
@defvar font-lock-ensure-function
Function to use for making sure a region of the current buffer has
been fontified. It is called with two arguments, the beginning and
end of the region. The default value of this variable is a function
that calls @code{font-lock-default-fontify-buffer} if the buffer is
not fontified; the effect is to make sure the entire accessible
portion of the buffer is fontified.
@end defvar
@defun jit-lock-register function &optional contextual
This function tells Font Lock mode to run the Lisp function
@var{function} any time it has to fontify or refontify part of the
current buffer. It calls @var{function} before calling the default
fontification functions, and gives it two arguments, @var{start} and
@var{end}, which specify the region to be fontified or refontified.
The optional argument @var{contextual}, if non-@code{nil}, forces Font
Lock mode to always refontify a syntactically relevant part of the
buffer, and not just the modified lines. This argument can usually be
omitted.
@end defun
@defun jit-lock-unregister function
If @var{function} was previously registered as a fontification
function using @code{jit-lock-register}, this function unregisters it.
@end defun
@node Levels of Font Lock
@subsection Levels of Font Lock
Some major modes offer three different levels of fontification. You
can define multiple levels by using a list of symbols for @var{keywords}
in @code{font-lock-defaults}. Each symbol specifies one level of
fontification; it is up to the user to choose one of these levels,
normally by setting @code{font-lock-maximum-decoration} (@pxref{Font
Lock,,, emacs, the GNU Emacs Manual}). The chosen level's symbol value
is used to initialize @code{font-lock-keywords}.
Here are the conventions for how to define the levels of
fontification:
@itemize @bullet
@item
Level 1: highlight function declarations, file directives (such as include or
import directives), strings and comments. The idea is speed, so only
the most important and top-level components are fontified.
@item
Level 2: in addition to level 1, highlight all language keywords,
including type names that act like keywords, as well as named constant
values. The idea is that all keywords (either syntactic or semantic)
should be fontified appropriately.
@item
Level 3: in addition to level 2, highlight the symbols being defined in
function and variable declarations, and all builtin function names,
wherever they appear.
@end itemize
@node Precalculated Fontification
@subsection Precalculated Fontification
Some major modes such as @code{list-buffers} and @code{occur}
construct the buffer text programmatically. The easiest way for them
to support Font Lock mode is to specify the faces of text when they
insert the text in the buffer.
The way to do this is to specify the faces in the text with the
special text property @code{font-lock-face} (@pxref{Special
Properties}). When Font Lock mode is enabled, this property controls
the display, just like the @code{face} property. When Font Lock mode
is disabled, @code{font-lock-face} has no effect on the display.
It is ok for a mode to use @code{font-lock-face} for some text and
also use the normal Font Lock machinery. But if the mode does not use
the normal Font Lock machinery, it should not set the variable
@code{font-lock-defaults}.
@node Faces for Font Lock
@subsection Faces for Font Lock
@cindex faces for font lock
@cindex font lock faces
Font Lock mode can highlight using any face, but Emacs defines several
faces specifically for Font Lock to use to highlight text. These
@dfn{Font Lock faces} are listed below. They can also be used by major
modes for syntactic highlighting outside of Font Lock mode (@pxref{Major
Mode Conventions}).
Each of these symbols is both a face name, and a variable whose
default value is the symbol itself. Thus, the default value of
@code{font-lock-comment-face} is @code{font-lock-comment-face}.
The faces are listed with descriptions of their typical usage, and in
order of greater to lesser prominence. If a mode's syntactic
categories do not fit well with the usage descriptions, the faces can be
assigned using the ordering as a guide.
@table @code
@item font-lock-warning-face
@vindex font-lock-warning-face
for a construct that is peculiar, or that greatly changes the meaning of
other text, like @samp{;;;###autoload} in Emacs Lisp and @samp{#error}
in C.
@item font-lock-function-name-face
@vindex font-lock-function-name-face
for the name of a function being defined or declared.
@item font-lock-variable-name-face
@vindex font-lock-variable-name-face
for the name of a variable being defined or declared.
@item font-lock-keyword-face
@vindex font-lock-keyword-face
for a keyword with special syntactic significance, like @samp{for} and
@samp{if} in C.
@item font-lock-comment-face
@vindex font-lock-comment-face
for comments.
@item font-lock-comment-delimiter-face
@vindex font-lock-comment-delimiter-face
for comments delimiters, like @samp{/*} and @samp{*/} in C@. On most
terminals, this inherits from @code{font-lock-comment-face}.
@item font-lock-type-face
@vindex font-lock-type-face
for the names of user-defined data types.
@item font-lock-constant-face
@vindex font-lock-constant-face
for the names of constants, like @samp{NULL} in C.
@item font-lock-builtin-face
@vindex font-lock-builtin-face
for the names of built-in functions.
@item font-lock-preprocessor-face
@vindex font-lock-preprocessor-face
for preprocessor commands. This inherits, by default, from
@code{font-lock-builtin-face}.
@item font-lock-string-face
@vindex font-lock-string-face
for string constants.
@item font-lock-doc-face
@vindex font-lock-doc-face
for documentation strings in the code. This inherits, by default, from
@code{font-lock-string-face}.
@item font-lock-negation-char-face
@vindex font-lock-negation-char-face
for easily-overlooked negation characters.
@end table
@node Syntactic Font Lock
@subsection Syntactic Font Lock
@cindex syntactic font lock
Syntactic fontification uses a syntax table (@pxref{Syntax Tables}) to
find and highlight syntactically relevant text. If enabled, it runs
prior to search-based fontification. The variable
@code{font-lock-syntactic-face-function}, documented below, determines
which syntactic constructs to highlight. There are several variables
that affect syntactic fontification; you should set them by means of
@code{font-lock-defaults} (@pxref{Font Lock Basics}).
Whenever Font Lock mode performs syntactic fontification on a stretch
of text, it first calls the function specified by
@code{syntax-propertize-function}. Major modes can use this to apply
@code{syntax-table} text properties to override the buffer's syntax
table in special cases. @xref{Syntax Properties}.
@defvar font-lock-keywords-only
If the value of this variable is non-@code{nil}, Font Lock does not do
syntactic fontification, only search-based fontification based on
@code{font-lock-keywords}. It is normally set by Font Lock mode based
on the @var{keywords-only} element in @code{font-lock-defaults}.
@end defvar
@defvar font-lock-syntax-table
This variable holds the syntax table to use for fontification of
comments and strings. It is normally set by Font Lock mode based on the
@var{syntax-alist} element in @code{font-lock-defaults}. If this value
is @code{nil}, syntactic fontification uses the buffer's syntax table
(the value returned by the function @code{syntax-table}; @pxref{Syntax
Table Functions}).
@end defvar
@defvar font-lock-syntactic-face-function
If this variable is non-@code{nil}, it should be a function to determine
which face to use for a given syntactic element (a string or a comment).
The value is normally set through an @var{other-vars} element in
@code{font-lock-defaults}.
The function is called with one argument, the parse state at point
returned by @code{parse-partial-sexp}, and should return a face. The
default value returns @code{font-lock-comment-face} for comments and
@code{font-lock-string-face} for strings (@pxref{Faces for Font Lock}).
@end defvar
@node Multiline Font Lock
@subsection Multiline Font Lock Constructs
@cindex multiline font lock
Normally, elements of @code{font-lock-keywords} should not match
across multiple lines; that doesn't work reliably, because Font Lock
usually scans just part of the buffer, and it can miss a multi-line
construct that crosses the line boundary where the scan starts. (The
scan normally starts at the beginning of a line.)
Making elements that match multiline constructs work properly has
two aspects: correct @emph{identification} and correct
@emph{rehighlighting}. The first means that Font Lock finds all
multiline constructs. The second means that Font Lock will correctly
rehighlight all the relevant text when a multiline construct is
changed---for example, if some of the text that was previously part of
a multiline construct ceases to be part of it. The two aspects are
closely related, and often getting one of them to work will appear to
make the other also work. However, for reliable results you must
attend explicitly to both aspects.
There are three ways to ensure correct identification of multiline
constructs:
@itemize
@item
Add a function to @code{font-lock-extend-region-functions} that does
the @emph{identification} and extends the scan so that the scanned
text never starts or ends in the middle of a multiline construct.
@item
Use the @code{font-lock-fontify-region-function} hook similarly to
extend the scan so that the scanned text never starts or ends in the
middle of a multiline construct.
@item
Somehow identify the multiline construct right when it gets inserted
into the buffer (or at any point after that but before font-lock
tries to highlight it), and mark it with a @code{font-lock-multiline}
which will instruct font-lock not to start or end the scan in the
middle of the construct.
@end itemize
There are three ways to do rehighlighting of multiline constructs:
@itemize
@item
Place a @code{font-lock-multiline} property on the construct. This
will rehighlight the whole construct if any part of it is changed. In
some cases you can do this automatically by setting the
@code{font-lock-multiline} variable, which see.
@item
Make sure @code{jit-lock-contextually} is set and rely on it doing its
job. This will only rehighlight the part of the construct that
follows the actual change, and will do it after a short delay.
This only works if the highlighting of the various parts of your
multiline construct never depends on text in subsequent lines.
Since @code{jit-lock-contextually} is activated by default, this can
be an attractive solution.
@item
Place a @code{jit-lock-defer-multiline} property on the construct.
This works only if @code{jit-lock-contextually} is used, and with the
same delay before rehighlighting, but like @code{font-lock-multiline},
it also handles the case where highlighting depends on
subsequent lines.
@end itemize
@menu
* Font Lock Multiline:: Marking multiline chunks with a text property.
* Region to Refontify:: Controlling which region gets refontified
after a buffer change.
@end menu
@node Font Lock Multiline
@subsubsection Font Lock Multiline
One way to ensure reliable rehighlighting of multiline Font Lock
constructs is to put on them the text property @code{font-lock-multiline}.
It should be present and non-@code{nil} for text that is part of a
multiline construct.
When Font Lock is about to highlight a range of text, it first
extends the boundaries of the range as necessary so that they do not
fall within text marked with the @code{font-lock-multiline} property.
Then it removes any @code{font-lock-multiline} properties from the
range, and highlights it. The highlighting specification (mostly
@code{font-lock-keywords}) must reinstall this property each time,
whenever it is appropriate.
@strong{Warning:} don't use the @code{font-lock-multiline} property
on large ranges of text, because that will make rehighlighting slow.
@defvar font-lock-multiline
If the @code{font-lock-multiline} variable is set to @code{t}, Font
Lock will try to add the @code{font-lock-multiline} property
automatically on multiline constructs. This is not a universal
solution, however, since it slows down Font Lock somewhat. It can
miss some multiline constructs, or make the property larger or smaller
than necessary.
For elements whose @var{matcher} is a function, the function should
ensure that submatch 0 covers the whole relevant multiline construct,
even if only a small subpart will be highlighted. It is often just as
easy to add the @code{font-lock-multiline} property by hand.
@end defvar
The @code{font-lock-multiline} property is meant to ensure proper
refontification; it does not automatically identify new multiline
constructs. Identifying the requires that Font Lock mode operate on
large enough chunks at a time. This will happen by accident on many
cases, which may give the impression that multiline constructs magically
work. If you set the @code{font-lock-multiline} variable
non-@code{nil}, this impression will be even stronger, since the
highlighting of those constructs which are found will be properly
updated from then on. But that does not work reliably.
To find multiline constructs reliably, you must either manually place
the @code{font-lock-multiline} property on the text before Font Lock
mode looks at it, or use @code{font-lock-fontify-region-function}.
@node Region to Refontify
@subsubsection Region to Fontify after a Buffer Change
When a buffer is changed, the region that Font Lock refontifies is
by default the smallest sequence of whole lines that spans the change.
While this works well most of the time, sometimes it doesn't---for
example, when a change alters the syntactic meaning of text on an
earlier line.
You can enlarge (or even reduce) the region to refontify by setting
the following variable:
@defvar font-lock-extend-after-change-region-function
This buffer-local variable is either @code{nil} or a function for Font
Lock mode to call to determine the region to scan and fontify.
The function is given three parameters, the standard @var{beg},
@var{end}, and @var{old-len} from @code{after-change-functions}
(@pxref{Change Hooks}). It should return either a cons of the
beginning and end buffer positions (in that order) of the region to
fontify, or @code{nil} (which means choose the region in the standard
way). This function needs to preserve point, the match-data, and the
current restriction. The region it returns may start or end in the
middle of a line.
Since this function is called after every buffer change, it should be
reasonably fast.
@end defvar
@node Auto-Indentation
@section Automatic Indentation of code
For programming languages, an important feature of a major mode is to
provide automatic indentation. There are two parts: one is to decide what
is the right indentation of a line, and the other is to decide when to
reindent a line. By default, Emacs reindents a line whenever you
type a character in @code{electric-indent-chars}, which by default only
includes Newline. Major modes can add chars to @code{electric-indent-chars}
according to the syntax of the language.
Deciding what is the right indentation is controlled in Emacs by
@code{indent-line-function} (@pxref{Mode-Specific Indent}). For some modes,
the @emph{right} indentation cannot be known reliably, typically because
indentation is significant so several indentations are valid but with different
meanings. In that case, the mode should set @code{electric-indent-inhibit} to
make sure the line is not constantly re-indented against the user's wishes.
Writing a good indentation function can be difficult and to a large extent it
is still a black art. Many major mode authors will start by writing a simple
indentation function that works for simple cases, for example by comparing with
the indentation of the previous text line. For most programming languages that
are not really line-based, this tends to scale very poorly: improving
such a function to let it handle more diverse situations tends to become more
and more difficult, resulting in the end with a large, complex, unmaintainable
indentation function which nobody dares to touch.
A good indentation function will usually need to actually parse the
text, according to the syntax of the language. Luckily, it is not
necessary to parse the text in as much detail as would be needed
for a compiler, but on the other hand, the parser embedded in the
indentation code will want to be somewhat friendly to syntactically
incorrect code.
Good maintainable indentation functions usually fall into two categories:
either parsing forward from some safe starting point until the
position of interest, or parsing backward from the position of interest.
Neither of the two is a clearly better choice than the other: parsing
backward is often more difficult than parsing forward because
programming languages are designed to be parsed forward, but for the
purpose of indentation it has the advantage of not needing to
guess a safe starting point, and it generally enjoys the property
that only a minimum of text will be analyzed to decide the indentation
of a line, so indentation will tend to be less affected by syntax errors in
some earlier unrelated piece of code. Parsing forward on the other hand
is usually easier and has the advantage of making it possible to
reindent efficiently a whole region at a time, with a single parse.
Rather than write your own indentation function from scratch, it is
often preferable to try and reuse some existing ones or to rely
on a generic indentation engine. There are sadly few such
engines. The CC-mode indentation code (used with C, C++, Java, Awk
and a few other such modes) has been made more generic over the years,
so if your language seems somewhat similar to one of those languages,
you might try to use that engine. @c FIXME: documentation?
Another one is SMIE which takes an approach in the spirit
of Lisp sexps and adapts it to non-Lisp languages.
@menu
* SMIE:: A simple minded indentation engine.
@end menu
@node SMIE
@subsection Simple Minded Indentation Engine
@cindex SMIE
SMIE is a package that provides a generic navigation and indentation
engine. Based on a very simple parser using an operator precedence
grammar, it lets major modes extend the sexp-based navigation of Lisp
to non-Lisp languages as well as provide a simple to use but reliable
auto-indentation.
Operator precedence grammar is a very primitive technology for parsing
compared to some of the more common techniques used in compilers.
It has the following characteristics: its parsing power is very limited,
and it is largely unable to detect syntax errors, but it has the
advantage of being algorithmically efficient and able to parse forward
just as well as backward. In practice that means that SMIE can use it
for indentation based on backward parsing, that it can provide both
@code{forward-sexp} and @code{backward-sexp} functionality, and that it
will naturally work on syntactically incorrect code without any extra
effort. The downside is that it also means that most programming
languages cannot be parsed correctly using SMIE, at least not without
resorting to some special tricks (@pxref{SMIE Tricks}).
@menu
* SMIE setup:: SMIE setup and features.
* Operator Precedence Grammars:: A very simple parsing technique.
* SMIE Grammar:: Defining the grammar of a language.
* SMIE Lexer:: Defining tokens.
* SMIE Tricks:: Working around the parser's limitations.
* SMIE Indentation:: Specifying indentation rules.
* SMIE Indentation Helpers:: Helper functions for indentation rules.
* SMIE Indentation Example:: Sample indentation rules.
* SMIE Customization:: Customizing indentation.
@end menu
@node SMIE setup
@subsubsection SMIE Setup and Features
SMIE is meant to be a one-stop shop for structural navigation and
various other features which rely on the syntactic structure of code, in
particular automatic indentation. The main entry point is
@code{smie-setup} which is a function typically called while setting
up a major mode.
@defun smie-setup grammar rules-function &rest keywords
Setup SMIE navigation and indentation.
@var{grammar} is a grammar table generated by @code{smie-prec2->grammar}.
@var{rules-function} is a set of indentation rules for use on
@code{smie-rules-function}.
@var{keywords} are additional arguments, which can include the following
keywords:
@itemize
@item
@code{:forward-token} @var{fun}: Specify the forward lexer to use.
@item
@code{:backward-token} @var{fun}: Specify the backward lexer to use.
@end itemize
@end defun
Calling this function is sufficient to make commands such as
@code{forward-sexp}, @code{backward-sexp}, and @code{transpose-sexps} be
able to properly handle structural elements other than just the paired
parentheses already handled by syntax tables. For example, if the
provided grammar is precise enough, @code{transpose-sexps} can correctly
transpose the two arguments of a @code{+} operator, taking into account
the precedence rules of the language.
Calling @code{smie-setup} is also sufficient to make @key{TAB}
indentation work in the expected way, extends
@code{blink-matching-paren} to apply to elements like
@code{begin...end}, and provides some commands that you can bind in
the major mode keymap.
@deffn Command smie-close-block
This command closes the most recently opened (and not yet closed) block.
@end deffn
@deffn Command smie-down-list &optional arg
This command is like @code{down-list} but it also pays attention to
nesting of tokens other than parentheses, such as @code{begin...end}.
@end deffn
@node Operator Precedence Grammars
@subsubsection Operator Precedence Grammars
SMIE's precedence grammars simply give to each token a pair of
precedences: the left-precedence and the right-precedence. We say
@code{T1 < T2} if the right-precedence of token @code{T1} is less than
the left-precedence of token @code{T2}. A good way to read this
@code{<} is as a kind of parenthesis: if we find @code{... T1 something
T2 ...} then that should be parsed as @code{... T1 (something T2 ...}
rather than as @code{... T1 something) T2 ...}. The latter
interpretation would be the case if we had @code{T1 > T2}. If we have
@code{T1 = T2}, it means that token T2 follows token T1 in the same
syntactic construction, so typically we have @code{"begin" = "end"}.
Such pairs of precedences are sufficient to express left-associativity
or right-associativity of infix operators, nesting of tokens like
parentheses and many other cases.
@c Let's leave this undocumented to leave it more open for change!
@c @defvar smie-grammar
@c The value of this variable is an alist specifying the left and right
@c precedence of each token. It is meant to be initialized by using one of
@c the functions below.
@c @end defvar
@defun smie-prec2->grammar table
This function takes a @emph{prec2} grammar @var{table} and returns an
alist suitable for use in @code{smie-setup}. The @emph{prec2}
@var{table} is itself meant to be built by one of the functions below.
@end defun
@defun smie-merge-prec2s &rest tables
This function takes several @emph{prec2} @var{tables} and merges them
into a new @emph{prec2} table.
@end defun
@defun smie-precs->prec2 precs
This function builds a @emph{prec2} table from a table of precedences
@var{precs}. @var{precs} should be a list, sorted by precedence (for
example @code{"+"} will come before @code{"*"}), of elements of the form
@code{(@var{assoc} @var{op} ...)}, where each @var{op} is a token that
acts as an operator; @var{assoc} is their associativity, which can be
either @code{left}, @code{right}, @code{assoc}, or @code{nonassoc}.
All operators in a given element share the same precedence level
and associativity.
@end defun
@defun smie-bnf->prec2 bnf &rest resolvers
This function lets you specify the grammar using a BNF notation.
It accepts a @var{bnf} description of the grammar along with a set of
conflict resolution rules @var{resolvers}, and
returns a @emph{prec2} table.
@var{bnf} is a list of nonterminal definitions of the form
@code{(@var{nonterm} @var{rhs1} @var{rhs2} ...)} where each @var{rhs}
is a (non-empty) list of terminals (aka tokens) or non-terminals.
Not all grammars are accepted:
@itemize
@item
An @var{rhs} cannot be an empty list (an empty list is never needed,
since SMIE allows all non-terminals to match the empty string anyway).
@item
An @var{rhs} cannot have 2 consecutive non-terminals: each pair of
non-terminals needs to be separated by a terminal (aka token).
This is a fundamental limitation of operator precedence grammars.
@end itemize
Additionally, conflicts can occur:
@itemize
@item
The returned @emph{prec2} table holds constraints between pairs of tokens, and
for any given pair only one constraint can be present: T1 < T2,
T1 = T2, or T1 > T2.
@item
A token can be an @code{opener} (something similar to an open-paren),
a @code{closer} (like a close-paren), or @code{neither} of the two
(e.g., an infix operator, or an inner token like @code{"else"}).
@end itemize
Precedence conflicts can be resolved via @var{resolvers}, which
is a list of @emph{precs} tables (see @code{smie-precs->prec2}): for
each precedence conflict, if those @code{precs} tables
specify a particular constraint, then the conflict is resolved by using
this constraint instead, else a conflict is reported and one of the
conflicting constraints is picked arbitrarily and the others are
simply ignored.
@end defun
@node SMIE Grammar
@subsubsection Defining the Grammar of a Language
@cindex SMIE grammar
@cindex grammar, SMIE
The usual way to define the SMIE grammar of a language is by
defining a new global variable that holds the precedence table by
giving a set of BNF rules.
For example, the grammar definition for a small Pascal-like language
could look like:
@example
@group
(require 'smie)
(defvar sample-smie-grammar
(smie-prec2->grammar
(smie-bnf->prec2
@end group
@group
'((id)
(inst ("begin" insts "end")
("if" exp "then" inst "else" inst)
(id ":=" exp)
(exp))
(insts (insts ";" insts) (inst))
(exp (exp "+" exp)
(exp "*" exp)
("(" exps ")"))
(exps (exps "," exps) (exp)))
@end group
@group
'((assoc ";"))
'((assoc ","))
'((assoc "+") (assoc "*")))))
@end group
@end example
@noindent
A few things to note:
@itemize
@item
The above grammar does not explicitly mention the syntax of function
calls: SMIE will automatically allow any sequence of sexps, such as
identifiers, balanced parentheses, or @code{begin ... end} blocks
to appear anywhere anyway.
@item
The grammar category @code{id} has no right hand side: this does not
mean that it can match only the empty string, since as mentioned any
sequence of sexps can appear anywhere anyway.
@item
Because non terminals cannot appear consecutively in the BNF grammar, it
is difficult to correctly handle tokens that act as terminators, so the
above grammar treats @code{";"} as a statement @emph{separator} instead,
which SMIE can handle very well.
@item
Separators used in sequences (such as @code{","} and @code{";"} above)
are best defined with BNF rules such as @code{(foo (foo "separator" foo) ...)}
which generate precedence conflicts which are then resolved by giving
them an explicit @code{(assoc "separator")}.
@item
The @code{("(" exps ")")} rule was not needed to pair up parens, since
SMIE will pair up any characters that are marked as having paren syntax
in the syntax table. What this rule does instead (together with the
definition of @code{exps}) is to make it clear that @code{","} should
not appear outside of parentheses.
@item
Rather than have a single @emph{precs} table to resolve conflicts, it is
preferable to have several tables, so as to let the BNF part of the
grammar specify relative precedences where possible.
@item
Unless there is a very good reason to prefer @code{left} or
@code{right}, it is usually preferable to mark operators as associative,
using @code{assoc}. For that reason @code{"+"} and @code{"*"} are
defined above as @code{assoc}, although the language defines them
formally as left associative.
@end itemize
@node SMIE Lexer
@subsubsection Defining Tokens
@cindex SMIE lexer
@cindex defining tokens, SMIE
SMIE comes with a predefined lexical analyzer which uses syntax tables
in the following way: any sequence of characters that have word or
symbol syntax is considered a token, and so is any sequence of
characters that have punctuation syntax. This default lexer is
often a good starting point but is rarely actually correct for any given
language. For example, it will consider @code{"2,+3"} to be composed
of 3 tokens: @code{"2"}, @code{",+"}, and @code{"3"}.
To describe the lexing rules of your language to SMIE, you need
2 functions, one to fetch the next token, and another to fetch the
previous token. Those functions will usually first skip whitespace and
comments and then look at the next chunk of text to see if it
is a special token. If so it should skip the token and
return a description of this token. Usually this is simply the string
extracted from the buffer, but it can be anything you want.
For example:
@example
@group
(defvar sample-keywords-regexp
(regexp-opt '("+" "*" "," ";" ">" ">=" "<" "<=" ":=" "=")))
@end group
@group
(defun sample-smie-forward-token ()
(forward-comment (point-max))
(cond
((looking-at sample-keywords-regexp)
(goto-char (match-end 0))
(match-string-no-properties 0))
(t (buffer-substring-no-properties
(point)
(progn (skip-syntax-forward "w_")
(point))))))
@end group
@group
(defun sample-smie-backward-token ()
(forward-comment (- (point)))
(cond
((looking-back sample-keywords-regexp (- (point) 2) t)
(goto-char (match-beginning 0))
(match-string-no-properties 0))
(t (buffer-substring-no-properties
(point)
(progn (skip-syntax-backward "w_")
(point))))))
@end group
@end example
Notice how those lexers return the empty string when in front of
parentheses. This is because SMIE automatically takes care of the
parentheses defined in the syntax table. More specifically if the lexer
returns @code{nil} or an empty string, SMIE tries to handle the corresponding
text as a sexp according to syntax tables.
@node SMIE Tricks
@subsubsection Living With a Weak Parser
The parsing technique used by SMIE does not allow tokens to behave
differently in different contexts. For most programming languages, this
manifests itself by precedence conflicts when converting the
BNF grammar.
Sometimes, those conflicts can be worked around by expressing the
grammar slightly differently. For example, for Modula-2 it might seem
natural to have a BNF grammar that looks like this:
@example
...
(inst ("IF" exp "THEN" insts "ELSE" insts "END")
("CASE" exp "OF" cases "END")
...)
(cases (cases "|" cases)
(caselabel ":" insts)
("ELSE" insts))
...
@end example
But this will create conflicts for @code{"ELSE"}: on the one hand, the
IF rule implies (among many other things) that @code{"ELSE" = "END"};
but on the other hand, since @code{"ELSE"} appears within @code{cases},
which appears left of @code{"END"}, we also have @code{"ELSE" > "END"}.
We can solve the conflict either by using:
@example
...
(inst ("IF" exp "THEN" insts "ELSE" insts "END")
("CASE" exp "OF" cases "END")
("CASE" exp "OF" cases "ELSE" insts "END")
...)
(cases (cases "|" cases) (caselabel ":" insts))
...
@end example
or
@example
...
(inst ("IF" exp "THEN" else "END")
("CASE" exp "OF" cases "END")
...)
(else (insts "ELSE" insts))
(cases (cases "|" cases) (caselabel ":" insts) (else))
...
@end example
Reworking the grammar to try and solve conflicts has its downsides, tho,
because SMIE assumes that the grammar reflects the logical structure of
the code, so it is preferable to keep the BNF closer to the intended
abstract syntax tree.
Other times, after careful consideration you may conclude that those
conflicts are not serious and simply resolve them via the
@var{resolvers} argument of @code{smie-bnf->prec2}. Usually this is
because the grammar is simply ambiguous: the conflict does not affect
the set of programs described by the grammar, but only the way those
programs are parsed. This is typically the case for separators and
associative infix operators, where you want to add a resolver like
@code{'((assoc "|"))}. Another case where this can happen is for the
classic @emph{dangling else} problem, where you will use @code{'((assoc
"else" "then"))}. It can also happen for cases where the conflict is
real and cannot really be resolved, but it is unlikely to pose a problem
in practice.
Finally, in many cases some conflicts will remain despite all efforts to
restructure the grammar. Do not despair: while the parser cannot be
made more clever, you can make the lexer as smart as you want. So, the
solution is then to look at the tokens involved in the conflict and to
split one of those tokens into 2 (or more) different tokens. E.g., if
the grammar needs to distinguish between two incompatible uses of the
token @code{"begin"}, make the lexer return different tokens (say
@code{"begin-fun"} and @code{"begin-plain"}) depending on which kind of
@code{"begin"} it finds. This pushes the work of distinguishing the
different cases to the lexer, which will thus have to look at the
surrounding text to find ad-hoc clues.
@node SMIE Indentation
@subsubsection Specifying Indentation Rules
@cindex indentation rules, SMIE
Based on the provided grammar, SMIE will be able to provide automatic
indentation without any extra effort. But in practice, this default
indentation style will probably not be good enough. You will want to
tweak it in many different cases.
SMIE indentation is based on the idea that indentation rules should be
as local as possible. To this end, it relies on the idea of
@emph{virtual} indentation, which is the indentation that a particular
program point would have if it were at the beginning of a line.
Of course, if that program point is indeed at the beginning of a line,
its virtual indentation is its current indentation. But if not, then
SMIE uses the indentation algorithm to compute the virtual indentation
of that point. Now in practice, the virtual indentation of a program
point does not have to be identical to the indentation it would have if
we inserted a newline before it. To see how this works, the SMIE rule
for indentation after a @code{@{} in C does not care whether the
@code{@{} is standing on a line of its own or is at the end of the
preceding line. Instead, these different cases are handled in the
indentation rule that decides how to indent before a @code{@{}.
Another important concept is the notion of @emph{parent}: The
@emph{parent} of a token, is the head token of the nearest enclosing
syntactic construct. For example, the parent of an @code{else} is the
@code{if} to which it belongs, and the parent of an @code{if}, in turn,
is the lead token of the surrounding construct. The command
@code{backward-sexp} jumps from a token to its parent, but there are
some caveats: for @emph{openers} (tokens which start a construct, like
@code{if}), you need to start with point before the token, while for
others you need to start with point after the token.
@code{backward-sexp} stops with point before the parent token if that is
the @emph{opener} of the token of interest, and otherwise it stops with
point after the parent token.
SMIE indentation rules are specified using a function that takes two
arguments @var{method} and @var{arg} where the meaning of @var{arg} and the
expected return value depend on @var{method}.
@var{method} can be:
@itemize
@item
@code{:after}, in which case @var{arg} is a token and the function
should return the @var{offset} to use for indentation after @var{arg}.
@item
@code{:before}, in which case @var{arg} is a token and the function
should return the @var{offset} to use to indent @var{arg} itself.
@item
@code{:elem}, in which case the function should return either the offset
to use to indent function arguments (if @var{arg} is the symbol
@code{arg}) or the basic indentation step (if @var{arg} is the symbol
@code{basic}).
@item
@code{:list-intro}, in which case @var{arg} is a token and the function
should return non-@code{nil} if the token is followed by a list of
expressions (not separated by any token) rather than an expression.
@end itemize
When @var{arg} is a token, the function is called with point just before
that token. A return value of @code{nil} always means to fallback on the
default behavior, so the function should return @code{nil} for arguments it
does not expect.
@var{offset} can be:
@itemize
@item
@code{nil}: use the default indentation rule.
@item
@code{(column . @var{column})}: indent to column @var{column}.
@item
@var{number}: offset by @var{number}, relative to a base token which is
the current token for @code{:after} and its parent for @code{:before}.
@end itemize
@node SMIE Indentation Helpers
@subsubsection Helper Functions for Indentation Rules
SMIE provides various functions designed specifically for use in the
indentation rules function (several of those functions break if used in
another context). These functions all start with the prefix
@code{smie-rule-}.
@defun smie-rule-bolp
Return non-@code{nil} if the current token is the first on the line.
@end defun
@defun smie-rule-hanging-p
Return non-@code{nil} if the current token is @emph{hanging}.
A token is @emph{hanging} if it is the last token on the line
and if it is preceded by other tokens: a lone token on a line is not
hanging.
@end defun
@defun smie-rule-next-p &rest tokens
Return non-@code{nil} if the next token is among @var{tokens}.
@end defun
@defun smie-rule-prev-p &rest tokens
Return non-@code{nil} if the previous token is among @var{tokens}.
@end defun
@defun smie-rule-parent-p &rest parents
Return non-@code{nil} if the current token's parent is among @var{parents}.
@end defun
@defun smie-rule-sibling-p
Return non-@code{nil} if the current token's parent is actually a
sibling. This is the case for example when the parent of a @code{","}
is just the previous @code{","}.
@end defun
@defun smie-rule-parent &optional offset
Return the proper offset to align the current token with the parent.
If non-@code{nil}, @var{offset} should be an integer giving an
additional offset to apply.
@end defun
@defun smie-rule-separator method
Indent current token as a @emph{separator}.
By @emph{separator}, we mean here a token whose sole purpose is to
separate various elements within some enclosing syntactic construct, and
which does not have any semantic significance in itself (i.e., it would
typically not exist as a node in an abstract syntax tree).
Such a token is expected to have an associative syntax and be closely
tied to its syntactic parent. Typical examples are @code{","} in lists
of arguments (enclosed inside parentheses), or @code{";"} in sequences
of instructions (enclosed in a @code{@{...@}} or @code{begin...end}
block).
@var{method} should be the method name that was passed to
@code{smie-rules-function}.
@end defun
@node SMIE Indentation Example
@subsubsection Sample Indentation Rules
Here is an example of an indentation function:
@example
(defun sample-smie-rules (kind token)
(pcase (cons kind token)
(`(:elem . basic) sample-indent-basic)
(`(,_ . ",") (smie-rule-separator kind))
(`(:after . ":=") sample-indent-basic)
(`(:before . ,(or `"begin" `"(" `"@{")))
(if (smie-rule-hanging-p) (smie-rule-parent)))
(`(:before . "if")
(and (not (smie-rule-bolp)) (smie-rule-prev-p "else")
(smie-rule-parent)))))
@end example
@noindent
A few things to note:
@itemize
@item
The first case indicates the basic indentation increment to use.
If @code{sample-indent-basic} is @code{nil}, then SMIE uses the global
setting @code{smie-indent-basic}. The major mode could have set
@code{smie-indent-basic} buffer-locally instead, but that
is discouraged.
@item
The rule for the token @code{","} make SMIE try to be more clever when
the comma separator is placed at the beginning of lines. It tries to
outdent the separator so as to align the code after the comma; for
example:
@example
x = longfunctionname (
arg1
, arg2
);
@end example
@item
The rule for indentation after @code{":="} exists because otherwise
SMIE would treat @code{":="} as an infix operator and would align the
right argument with the left one.
@item
The rule for indentation before @code{"begin"} is an example of the use
of virtual indentation: This rule is used only when @code{"begin"} is
hanging, which can happen only when @code{"begin"} is not at the
beginning of a line. So this is not used when indenting
@code{"begin"} itself but only when indenting something relative to this
@code{"begin"}. Concretely, this rule changes the indentation from:
@example
if x > 0 then begin
dosomething(x);
end
@end example
to
@example
if x > 0 then begin
dosomething(x);
end
@end example
@item
The rule for indentation before @code{"if"} is similar to the one for
@code{"begin"}, but where the purpose is to treat @code{"else if"}
as a single unit, so as to align a sequence of tests rather than indent
each test further to the right. This function does this only in the
case where the @code{"if"} is not placed on a separate line, hence the
@code{smie-rule-bolp} test.
If we know that the @code{"else"} is always aligned with its @code{"if"}
and is always at the beginning of a line, we can use a more efficient
rule:
@example
((equal token "if")
(and (not (smie-rule-bolp))
(smie-rule-prev-p "else")
(save-excursion
(sample-smie-backward-token)
(cons 'column (current-column)))))
@end example
The advantage of this formulation is that it reuses the indentation of
the previous @code{"else"}, rather than going all the way back to the
first @code{"if"} of the sequence.
@end itemize
@c In some sense this belongs more in the Emacs manual.
@node SMIE Customization
@subsubsection Customizing Indentation
If you are using a mode whose indentation is provided by SMIE, you can
customize the indentation to suit your preferences. You can do this
on a per-mode basis (using the option @code{smie-config}), or a
per-file basis (using the function @code{smie-config-local} in a
file-local variable specification).
@defopt smie-config
This option lets you customize indentation on a per-mode basis.
It is an alist with elements of the form @code{(@var{mode} . @var{rules})}.
For the precise form of rules, see the variable's documentation; but
you may find it easier to use the command @code{smie-config-guess}.
@end defopt
@deffn Command smie-config-guess
This command tries to work out appropriate settings to produce
your preferred style of indentation. Simply call the command while
visiting a file that is indented with your style.
@end deffn
@deffn Command smie-config-save
Call this command after using @code{smie-config-guess}, to save your
settings for future sessions.
@end deffn
@deffn Command smie-config-show-indent &optional move
This command displays the rules that are used to indent the current
line.
@end deffn
@deffn Command smie-config-set-indent
This command adds a local rule to adjust the indentation of the current line.
@end deffn
@defun smie-config-local rules
This function adds @var{rules} as indentation rules for the current buffer.
These add to any mode-specific rules defined by the @code{smie-config} option.
To specify custom indentation rules for a specific file, add an entry
to the file's local variables of the form:
@code{eval: (smie-config-local '(@var{rules}))}.
@end defun
@node Desktop Save Mode
@section Desktop Save Mode
@cindex desktop save mode
@dfn{Desktop Save Mode} is a feature to save the state of Emacs from
one session to another. The user-level commands for using Desktop
Save Mode are described in the GNU Emacs Manual (@pxref{Saving Emacs
Sessions,,, emacs, the GNU Emacs Manual}). Modes whose buffers visit
a file, don't have to do anything to use this feature.
For buffers not visiting a file to have their state saved, the major
mode must bind the buffer local variable @code{desktop-save-buffer} to
a non-@code{nil} value.
@defvar desktop-save-buffer
If this buffer-local variable is non-@code{nil}, the buffer will have
its state saved in the desktop file at desktop save. If the value is
a function, it is called at desktop save with argument
@var{desktop-dirname}, and its value is saved in the desktop file along
with the state of the buffer for which it was called. When file names
are returned as part of the auxiliary information, they should be
formatted using the call
@example
(desktop-file-name @var{file-name} @var{desktop-dirname})
@end example
@end defvar
For buffers not visiting a file to be restored, the major mode must
define a function to do the job, and that function must be listed in
the alist @code{desktop-buffer-mode-handlers}.
@defvar desktop-buffer-mode-handlers
Alist with elements
@example
(@var{major-mode} . @var{restore-buffer-function})
@end example
The function @var{restore-buffer-function} will be called with
argument list
@example
(@var{buffer-file-name} @var{buffer-name} @var{desktop-buffer-misc})
@end example
and it should return the restored buffer.
Here @var{desktop-buffer-misc} is the value returned by the function
optionally bound to @code{desktop-save-buffer}.
@end defvar