This is ../info/ccmode, produced by makeinfo version 4.2 from cc-mode.texi. INFO-DIR-SECTION Emacs START-INFO-DIR-ENTRY * CC Mode: (ccmode). Emacs mode for editing C, C++, Objective-C, Java, Pike, and IDL code. END-INFO-DIR-ENTRY Copyright (C) 1995, 96, 97, 98, 99, 2000, 2001 Free Software Foundation, Inc. Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.1 or any later version published by the Free Software Foundation; with the Invariant Sections being "The GNU Manifesto", "Distribution" and "GNU GENERAL PUBLIC LICENSE", with the Front-Cover texts being "A GNU Manual", and with the Back-Cover Texts as in (a) below. A copy of the license is included in the section entitled "GNU Free Documentation License" in the Emacs manual. (a) The FSF's Back-Cover Text is: "You have freedom to copy and modify this GNU Manual, like GNU software. Copies published by the Free Software Foundation raise funds for GNU development." This document is part of a collection distributed under the GNU Free Documentation License. If you want to distribute this document separately from the collection, you can do so by adding a copy of the license to the document, as described in section 6 of the license.  File: ccmode, Node: Movement Commands, Next: Other Commands, Prev: Indentation Commands, Up: Commands Movement Commands ================= CC Mode contains some useful command for moving around in C code. `M-x c-beginning-of-defun' Moves point back to the least-enclosing brace. This function is analogous to the Emacs built-in command `beginning-of-defun', except it eliminates the constraint that the top-level opening brace must be in column zero. See `beginning-of-defun' for more information. Depending on the coding style being used, you might prefer `c-beginning-of-defun' to `beginning-of-defun'. If so, consider binding `C-M-a' to the former instead. For backwards compatibility reasons, the default binding remains in effect. `M-x c-end-of-defun' Moves point to the end of the current top-level definition. This function is analogous to the Emacs built-in command `end-of-defun', except it eliminates the constraint that the top-level opening brace of the defun must be in column zero. See `beginning-of-defun' for more information. Depending on the coding style being used, you might prefer `c-end-of-defun' to `end-of-defun'. If so, consider binding `C-M-e' to the former instead. For backwards compatibility reasons, the default binding remains in effect. `C-c C-u' (`c-up-conditional') Move point back to the containing preprocessor conditional, leaving the mark behind. A prefix argument acts as a repeat count. With a negative argument, move point forward to the end of the containing preprocessor conditional. `#elif' is treated like `#else' followed by `#if', so the function stops at them when going backward, but not when going forward. `M-x c-up-conditional-with-else' A variety of `c-up-conditional' that also stops at `#else' lines. Normally those lines are ignored. `M-x c-down-conditional' Move point forward into the next nested preprocessor conditional, leaving the mark behind. A prefix argument acts as a repeat count. With a negative argument, move point backward into the previous nested preprocessor conditional. `#elif' is treated like `#else' followed by `#if', so the function stops at them when going forward, but not when going backward. `M-x c-down-conditional-with-else' A variety of `c-down-conditional' that also stops at `#else' lines. Normally those lines are ignored. `C-c C-p' (`c-backward-conditional') Move point back over a preprocessor conditional, leaving the mark behind. A prefix argument acts as a repeat count. With a negative argument, move forward. `C-c C-n' (`c-forward-conditional') Move point forward across a preprocessor conditional, leaving the mark behind. A prefix argument acts as a repeat count. With a negative argument, move backward. `M-a' (`c-beginning-of-statement') Move point to the beginning of the innermost C statement. If point is already at the beginning of a statement, move to the beginning of the closest preceding statement, even if that means moving into a block (you can use `M-C-b' to move over a balanced block). With prefix argument N, move back N - 1 statements. If point is within or next to a comment or a string which spans more than one line, this command moves by sentences instead of statements. When called from a program, this function takes three optional arguments: the repetition count, a buffer position limit which is the farthest back to search for the syntactic context, and a flag saying whether to do sentence motion in or near comments and multiline strings. `M-e' (`c-end-of-statement') Move point to the end of the innermost C statement. If point is at the end of a statement, move to the end of the next statement, even if it's inside a nested block (use `M-C-f' to move to the other side of the block). With prefix argument N, move forward N - 1 statements. If point is within or next to a comment or a string which spans more than one line, this command moves by sentences instead of statements. When called from a program, this function takes three optional arguments: the repetition count, a buffer position limit which is the farthest back to search for the syntactic context, and a flag saying whether to do sentence motion in or near comments and multiline strings. `M-x c-forward-into-nomenclature' A popular programming style, especially for object-oriented languages such as C++ is to write symbols in a mixed case format, where the first letter of each word is capitalized, and not separated by underscores. E.g. `SymbolsWithMixedCaseAndNoUnderlines'. This command moves point forward to next capitalized word. With prefix argument N, move N times. `M-x c-backward-into-nomenclature' Move point backward to beginning of the next capitalized word. With prefix argument N, move N times. If N is negative, move forward.  File: ccmode, Node: Other Commands, Prev: Movement Commands, Up: Commands Other Commands ============== CC Mode contains a few other useful commands: `C-c :' (`c-scope-operator') In C++, it is also sometimes desirable to insert the double-colon scope operator without performing the electric behavior of colon insertion. `C-c :' does just this. `C-c C-\' (`c-backslash-region') This function is handy when editing macros split over several lines by ending each line with a backslash. It inserts and aligns, or deletes these end-of-line backslashes in the current region. With no prefix argument, it inserts any missing backslashes and aligns them to the column specified by the `c-backslash-column' style variable. With a prefix argument, it deletes any backslashes. The function does not modify blank lines at the start of the region. If the region ends at the start of a line, it always deletes the backslash (if any) at the end of the previous line.  File: ccmode, Node: Customizing Indentation, Next: Syntactic Symbols, Prev: Commands, Up: Top Customizing Indentation *********************** The style variable `c-offsets-alist' contains the mappings between syntactic symbols and the offsets to apply for those symbols. It's set at mode initialization from a _style_ you may specify. Styles are groupings of syntactic symbol offsets and other style variable values. Most likely, you'll find that one of the pre-defined styles will suit your needs. *Note Styles::, for an explanation of how to set up named styles. Only syntactic symbols not already bound on `c-offsets-alist' will be set from styles. This means that any association you set on it, be it before or after mode initialization, will not be changed. The `c-offsets-alist' variable may therefore be used from e.g. the Customization interface(1) to easily change indentation offsets without having to bother about styles. Initially `c-offsets-alist' is empty, so that all syntactic symbols are set by the style system. You can use the command `C-c C-o' (`c-set-offset') as the way to set offsets, both interactively and from your mode hook(2). The offset associated with any particular syntactic symbol can be any of an integer, a function or lambda expression, a variable name, a vector, a list, or one of the following symbols: `+', `-', `++', `--', `*', or `/'. Those last special symbols describe an offset in multiples of the value of the style variable `c-basic-offset'. By defining a style's indentation in terms of this fundamental variable, you can change the amount of whitespace given to an indentation level while maintaining the same basic shape of your code. Here are the values that the special symbols correspond to: `+' `c-basic-offset' times 1 `-' `c-basic-offset' times -1 `++' `c-basic-offset' times 2 `--' `c-basic-offset' times -2 `*' `c-basic-offset' times 0.5 `/' `c-basic-offset' times -0.5 When a function is used as offset, it's called an "indentation function". Such functions are useful when more context than just the syntactic symbol is needed to get the desired indentation. *Note Indentation Functions::, and *Note Custom Indentation Functions::, for details about them. If the offset is a vector, its first element sets the absolute indentation column, which will override any relative indentation. The offset can also be a list, in which case it is evaluated recursively using the semantics described above. The first element of the list that returns a non-`nil' value succeeds and the evaluation stops. If none of the list elements return a non-`nil' value, then an offset of 0 (zero) is used(3). So, for example, because most of the default offsets are defined in terms of `+', `-', and `0', if you like the general indentation style, but you use 4 spaces instead of 2 spaces per level, you can probably achieve your style just by changing `c-basic-offset' like so(4): _M-x set-variable RET_ Set variable: _c-basic-offset RET_ Set c-basic-offset to value: _4 RET_ This would change int add( int val, int incr, int doit ) { if( doit ) { return( val + incr ); } return( val ); } to int add( int val, int incr, int doit ) { if( doit ) { return( val + incr ); } return( val ); } To change indentation styles more radically, you will want to change the offsets associated with other syntactic symbols. First, I'll show you how to do that interactively, then I'll describe how to make changes to your `.emacs' file so that your changes are more permanent. * Menu: * Interactive Customization:: * Permanent Customization:: * Hooks:: * Styles:: * Advanced Customizations:: ---------- Footnotes ---------- (1) Available in Emacs 20 and later, and XEmacs 19.15 and later. (2) Obviously, you use the key binding interactively, and the function call programmatically! (3) There is however a variable `c-strict-syntax-p' that, when set to non-`nil', will cause an error to be signalled in that case. It's now considered obsolete since it doesn't work well with some of the alignment functions that now returns `nil' instead of zero to be more usable in lists. You should therefore leave `c-strict-syntax-p' set to `nil'. (4) You can try this interactively in a C buffer by typing the text that appears in italics.  File: ccmode, Node: Interactive Customization, Next: Permanent Customization, Up: Customizing Indentation Interactive Customization ========================= As an example of how to customize indentation, let's change the style of this example(1): 1: int add( int val, int incr, int doit ) 2: { 3: if( doit ) 4: { 5: return( val + incr ); 6: } 7: return( val ); 8: } to: 1: int add( int val, int incr, int doit ) 2: { 3: if( doit ) 4: { 5: return( val + incr ); 6: } 7: return( val ); 8: } In other words, we want to change the indentation of braces that open a block following a condition so that the braces line up under the conditional, instead of being indented. Notice that the construct we want to change starts on line 4. To change the indentation of a line, we need to see which syntactic components affect the offset calculations for that line. Hitting `C-c C-s' on line 4 yields: ((substatement-open . 44)) so we know that to change the offset of the open brace, we need to change the indentation for the `substatement-open' syntactic symbol. To do this interactively, just hit `C-c C-o'. This prompts you for the syntactic symbol to change, providing a reasonable default. In this case, the default is `substatement-open', which is just the syntactic symbol we want to change! After you hit return, CC Mode will then prompt you for the new offset value, with the old value as the default. The default in this case is `+', but we want no extra indentation so enter `0' and `RET'. This will associate the offset 0 with the syntactic symbol `substatement-open'. To check your changes quickly, just hit `C-c C-q' (`c-indent-defun') to reindent the entire function. The example should now look like: 1: int add( int val, int incr, int doit ) 2: { 3: if( doit ) 4: { 5: return( val + incr ); 6: } 7: return( val ); 8: } Notice how just changing the open brace offset on line 4 is all we needed to do. Since the other affected lines are indented relative to line 4, they are automatically indented the way you'd expect. For more complicated examples, this may not always work. The general approach to take is to always start adjusting offsets for lines higher up in the file, then re-indent and see if any following lines need further adjustments. ---------- Footnotes ---------- (1) In this an subsequent examples, the original code is formatted using the `gnu' style unless otherwise indicated. *Note Styles::.  File: ccmode, Node: Permanent Customization, Next: Hooks, Prev: Interactive Customization, Up: Customizing Indentation Permanent Customization ======================= To make your changes permanent, you need to add some lisp code to your `.emacs' file. CC Mode supports many different ways to be configured, from the straightforward way by setting variables globally in `.emacs' or in the Customization interface, to the complex and precisely controlled way by using styles and hook functions. The simplest way of customizing CC Mode permanently is to set the variables in your `.emacs' with `setq' and similar commands. So to make the setting of `substatement-open' permanent, add this to the `.emacs' file: (require 'cc-mode) (c-set-offset 'substatement-open 0) The `require' line is only needed once in the beginning to make sure CC Mode is loaded so that the `c-set-offset' function is defined. You can also use the more user friendly Customization interface, but this manual does not cover how that works. Variables set like this at the top level in `.emacs' take effect in all CC Mode buffers, regardless of language. The indentation style related variables, e.g. `c-basic-offset', that you don't set this way get their value from the style system (*note Styles::), and they therefore depend on the setting of `c-default-style'. Note that if you use Customize, this means that the greyed-out default values presented there might not be the ones you actually get, since the actual values depend on the style, which may very well be different for different languages. If you want to make more advanced configurations, e.g. language-specific customization, global variable settings isn't enough. For that you can use the language hooks, see *Note Hooks::, and/or the style system, see *Note Styles::. By default, all style variables are global, so that every buffer will share the same style settings. This is fine if you primarily edit one style of code, but if you edit several languages and want to use different styles for them, you need finer control by making the style variables buffer local. The recommended way to do this is to set the variable `c-style-variables-are-local-p' to `t'. The variables will be made buffer local when CC Mode is activated in a buffer for the first time in the Emacs session. Note that once the style variables are made buffer local, they cannot be made global again, without restarting Emacs.  File: ccmode, Node: Hooks, Next: Styles, Prev: Permanent Customization, Up: Customizing Indentation Hooks ===== CC Mode provides several hooks that you can use to customize the mode according to your coding style. Each language mode has its own hook, adhering to standard Emacs major mode conventions. There is also one general hook and one package initialization hook: * `c-mode-hook' -- For C buffers only. * `c++-mode-hook' -- For C++ buffers only. * `objc-mode-hook' -- For Objective-C buffers only. * `java-mode-hook' -- For Java buffers only. * `idl-mode-hook' -- For CORBA IDL buffers only. * `pike-mode-hook' -- For Pike buffers only. * `c-mode-common-hook' -- Common across all languages. * `c-initialization-hook' -- Hook run only once per Emacs session, when CC Mode is initialized. The language hooks get run as the last thing when you enter that language mode. The `c-mode-common-hook' is run by all supported modes _before_ the language specific hook, and thus can contain customizations that are common across all languages. Most of the examples in this section will assume you are using the common hook. Note that all the language-specific mode setup that CC Mode does is done prior to both `c-mode-common-hook' and the language specific hook. That includes installing the indentation style, which can be mode specific (and also is by default for Java mode). Thus, any style settings done in `c-mode-common-hook' will override whatever language-specific style is chosen by `c-default-style'. Here's a simplified example of what you can add to your `.emacs' file to do things whenever any CC Mode language is edited. See the Emacs manuals for more information on customizing Emacs via hooks. *Note Sample .emacs File::, for a more complete sample `.emacs' file. (defun my-c-mode-common-hook () ;; my customizations for all of c-mode and related modes (no-case-fold-search) ) (add-hook 'c-mode-common-hook 'my-c-mode-common-hook)  File: ccmode, Node: Styles, Next: Advanced Customizations, Prev: Hooks, Up: Customizing Indentation Styles ====== Most people only need to edit code formatted in just a few well-defined and consistent styles. For example, their organization might impose a "blessed" style that all its programmers must conform to. Similarly, people who work on GNU software will have to use the GNU coding style. Some shops are more lenient, allowing a variety of coding styles, and as programmers come and go, there could be a number of styles in use. For this reason, CC Mode makes it convenient for you to set up logical groupings of customizations called "styles", associate a single name for any particular style, and pretty easily start editing new or existing code using these styles. The variables that the style system affect are called "style variables". They are handled specially in several ways: * Style variables are by default global variables, i.e. they have the same value in all Emacs buffers. However, they can instead be made always buffer local by setting `c-style-variables-are-local-p' to non-`nil' before CC Mode is initialized. * The default value of any style variable (with two exceptions -- see below) is the special symbol `set-from-style'. Variables that are still set to that symbol when a CC Mode buffer is initialized will be set according to the current style, otherwise they will keep their current value(1). Note that when we talk about the "default value" for a style variable, we don't mean the `set-from-style' symbol that all style variables are set to initially, but instead the value it will get at mode initialization when neither a style nor a global setting has set its value. The style variable `c-offsets-alist' is handled a little differently from the other style variables. It's an association list, and is thus by default set to the empty list, `nil'. When the style system is initialized, any syntactic symbols already on it are kept -- only the missing ones are filled in from the chosen style. The style variable `c-special-indent-hook' is also handled in a special way. Styles may only add more functions on this hook, so the global settings on it are always preserved(2). * The global settings of style variables get captured in the special `user' style, which is used as the base for all the other styles. *Note Built-in Styles::, for details. The style variables are: `c-basic-offset', `c-comment-only-line-offset', `c-block-comment-prefix', `c-comment-prefix-regexp', `c-cleanup-list', `c-hanging-braces-alist', `c-hanging-colons-alist', `c-hanging-semi&comma-criteria', `c-backslash-column', `c-special-indent-hook', `c-label-minimum-indentation', and `c-offsets-alist'. * Menu: * Built-in Styles:: * Adding Styles:: * File Styles:: ---------- Footnotes ---------- (1) This is a big change from versions of CC Mode earlier than 5.26, where such settings would get overridden by the style system unless special precautions were taken. That was changed since it was counterintuitive and confusing, especially to novice users. If your configuration depends on the old overriding behavior, you can set the variable `c-old-style-variable-behavior' to non-`nil'. (2) This did not change in version 5.26.  File: ccmode, Node: Built-in Styles, Next: Adding Styles, Up: Styles Built-in Styles --------------- If you're lucky, one of CC Mode's built-in styles might be just what you're looking for. These include: * `gnu' -- Coding style blessed by the Free Software Foundation for C code in GNU programs. * `k&r' -- The classic Kernighan and Ritchie style for C code. * `bsd' -- Also known as "Allman style" after Eric Allman. * `whitesmith' -- Popularized by the examples that came with Whitesmiths C, an early commercial C compiler. * `stroustrup' -- The classic Stroustrup style for C++ code. * `ellemtel' -- Popular C++ coding standards as defined by "Programming in C++, Rules and Recommendations," Erik Nyquist and Mats Henricson, Ellemtel(1). * `linux' -- C coding standard for Linux (the kernel). * `python' -- C coding standard for Python extension modules(2). * `java' -- The style for editing Java code. Note that the default value for `c-default-style' installs this style when you enter `java-mode'. * `user' -- This is a special style for several reasons. First, the CC Mode customizations you do by using either the Customization interface, or by writing `setq''s at the top level of your `.emacs' file, will be captured in the `user' style. Also, all other styles implicitly inherit their settings from `user' style. This means that for any styles you add via `c-add-style' (*note Adding Styles::) you need only define the differences between your new style and `user' style. The default style in all newly created buffers is `gnu', but you can change this by setting variable `c-default-style'. Although the `user' style is not the default style, any style variable settings you do with the Customization interface or on the top level in your `.emacs' file will by default override the style system, so you don't need to set `c-default-style' to `user' to see the effect of these settings. `c-default-style' takes either a style name string, or an association list of major mode symbols to style names. Thus you can control exactly which default style is used for which CC Mode language mode. Here are the rules: 1. When `c-default-style' is a string, it must be an existing style name as found in `c-style-alist'. This style is then used for all modes. 2. When `c-default-style' is an association list, the current major mode is looked up to find a style name string. In this case, this style is always used exactly as specified and an error will occur if the named style does not exist. 3. If `c-default-style' is an association list, but the current major mode isn't found, then the special symbol `other' is looked up. If this value is found, the associated style is used. 4. If `other' is not found, then the `gnu' style is used. 5. In all cases, the style described in `c-default-style' is installed _before_ the language hooks are run, so you can always override this setting by including an explicit call to `c-set-style' in your language mode hook, or in `c-mode-common-hook'. If you'd like to experiment with these built-in styles you can simply type the following in a CC Mode buffer: C-c . STYLE-NAME RET `C-c .' runs the command `c-set-style'. Note that all style names are case insensitive, even the ones you define. Setting a style in this way does _not_ automatically re-indent your file. For commands that you can use to view the effect of your changes, see *Note Commands::. Note that for BOCM compatibility, `gnu' is the default style, and any non-style based customizations you make (i.e. in `c-mode-common-hook' in your `.emacs' file) will be based on `gnu' style unless you set `c-default-style' or do a `c-set-style' as the first thing in your hook. The variable `c-indentation-style' always contains the buffer's current style name, as a string. ---------- Footnotes ---------- (1) This document is available at `http://www.doc.ic.ac.uk/lab/cplus/c++.rules/' among other places. (2) Python is a high level scripting language with a C/C++ foreign function interface. For more information, see `http://www.python.org/'.  File: ccmode, Node: Adding Styles, Next: File Styles, Prev: Built-in Styles, Up: Styles Adding Styles ------------- If none of the built-in styles is appropriate, you'll probably want to add a new "style definition". Styles are kept in the `c-style-alist' variable, but you should never modify this variable directly. Instead, CC Mode provides the function `c-add-style' that you can use to easily add new styles or change existing styles. This function takes two arguments, a STYLENAME string, and an association list DESCRIPTION of style customizations. If STYLENAME is not already in `c-style-alist', the new style is added, otherwise the style is changed to the new DESCRIPTION. This function also takes an optional third argument, which if non-`nil', automatically applies the new style to the current buffer. The sample `.emacs' file provides a concrete example of how a new style can be added and automatically set. *Note Sample .emacs File::.  File: ccmode, Node: File Styles, Prev: Adding Styles, Up: Styles File Styles ----------- The Emacs manual describes how you can customize certain variables on a per-file basis by including a "Local Variable" block at the end of the file. So far, you've only seen a functional interface to CC Mode customization, which is highly inconvenient for use in a Local Variable block. CC Mode provides two variables that make it easier for you to customize your style on a per-file basis. The variable `c-file-style' can be set to a style name string. When the file is visited, CC Mode will automatically set the file's style to this style using `c-set-style'. Another variable, `c-file-offsets', takes an association list similar to what is allowed in `c-offsets-alist'. When the file is visited, CC Mode will automatically institute these offsets using `c-set-offset'. Note that file style settings (i.e. `c-file-style') are applied before file offset settings (i.e. `c-file-offsets'). Also, if either of these are set in a file's local variable section, all the style variable values are made local to that buffer.  File: ccmode, Node: Advanced Customizations, Prev: Styles, Up: Customizing Indentation Advanced Customizations ======================= For most users, CC Mode will support their coding styles with very little need for more advanced customizations. Usually, one of the standard styles defined in `c-style-alist' will do the trick. At most, perhaps one of the syntactic symbol offsets will need to be tweaked slightly, or maybe `c-basic-offset' will need to be changed. However, some styles require a more flexible framework for customization, and one of the real strengths of CC Mode is that the syntactic analysis model provides just such a framework. This allows you to implement custom indentation calculations for situations not handled by the mode directly. * Menu: * Custom Indentation Functions:: * Custom Brace and Colon Hanging:: * Customizing Semi-colons and Commas:: * Other Special Indentations::  File: ccmode, Node: Custom Indentation Functions, Next: Custom Brace and Colon Hanging, Up: Advanced Customizations Custom Indentation Functions ---------------------------- The most flexible way to customize CC Mode is by writing custom indentation functions, and associating them with specific syntactic symbols (*note Syntactic Symbols::). CC Mode itself uses indentation functions to provide more sophisticated indentation, for example when lining up C++ stream operator blocks: 1: void main(int argc, char**) 2: { 3: cout << "There were " 4: << argc 5: << "arguments passed to the program" 6: << endl; 7: } In this example, lines 4 through 6 are assigned the `stream-op' syntactic symbol. Here, `stream-op' has an offset of `+', and with a `c-basic-offset' of 2, you can see that lines 4 through 6 are simply indented two spaces to the right of line 3. But perhaps we'd like CC Mode to be a little more intelligent so that it aligns all the `<<' symbols in lines 3 through 6. To do this, we have to write a custom indentation function which finds the column of first stream operator on the first line of the statement. Here is sample lisp code implementing this: (defun c-lineup-streamop (langelem) ;; lineup stream operators (save-excursion (let* ((relpos (cdr langelem)) (curcol (progn (goto-char relpos) (current-column)))) (re-search-forward "<<\\|>>" (c-point 'eol) 'move) (goto-char (match-beginning 0)) (- (current-column) curcol)))) Indentation functions take a single argument, which is a syntactic component cons cell (*note Syntactic Analysis::). The function returns an integer offset value that will be added to the running total indentation for the line. Note that what actually gets returned is the difference between the column that the first stream operator is on, and the column of the buffer relative position passed in the function's argument. Remember that CC Mode automatically adds in the column of the component's relative buffer position and we don't the column offset added in twice. The function should return `nil' if it's used in a situation where it doesn't want to do any decision. If the function is used in a list expression (*note Customizing Indentation::), that will cause CC Mode to go on and check the next entry in the list. Now, to associate the function `c-lineup-streamop' with the `stream-op' syntactic symbol, we can add something like the following to our `c++-mode-hook'(1): (c-set-offset 'stream-op 'c-lineup-streamop) Now the function looks like this after re-indenting (using `C-c C-q'): 1: void main(int argc, char**) 2: { 3: cout << "There were " 4: << argc 5: << " arguments passed to the program" 6: << endl; 7: } Custom indentation functions can be as simple or as complex as you like, and any syntactic symbol that appears in `c-offsets-alist' can have a custom indentation function associated with it. CC Mode comes with an extensive set of predefined indentation functions, not all of which are used by the default styles. So there's a good chance the function you want already exists. *Note Indentation Functions::, for a list of them. If you have written an indentation function that you think is generally useful, you're very welcome to contribute it; please contact . ---------- Footnotes ---------- (1) It probably makes more sense to add this to `c++-mode-hook' than `c-mode-common-hook' since stream operators are only relevant for C++.  File: ccmode, Node: Custom Brace and Colon Hanging, Next: Customizing Semi-colons and Commas, Prev: Custom Indentation Functions, Up: Advanced Customizations Custom Brace and Colon Hanging ------------------------------ Syntactic symbols aren't the only place where you can customize CC Mode with the lisp equivalent of callback functions. Brace "hanginess" can also be determined by custom functions associated with syntactic symbols on the `c-hanging-braces-alist' style variable. Remember that ACTION's are typically a list containing some combination of the symbols `before' and `after' (*note Hanging Braces::). However, an ACTION can also be a function which gets called when a brace matching that syntactic symbol is entered. These ACTION functions are called with two arguments: the syntactic symbol for the brace, and the buffer position at which the brace was inserted. The ACTION function is expected to return a list containing some combination of `before' and `after', including neither of them (i.e. `nil'). This return value has the normal brace hanging semantics. As an example, CC Mode itself uses this feature to dynamically determine the hanginess of braces which close "do-while" constructs: void do_list( int count, char** atleast_one_string ) { int i=0; do { handle_string( atleast_one_string[i] ); i++; } while( i < count ); } CC Mode assigns the `block-close' syntactic symbol to the brace that closes the `do' construct, and normally we'd like the line that follows a `block-close' brace to begin on a separate line. However, with "do-while" constructs, we want the `while' clause to follow the closing brace. To do this, we associate the `block-close' symbol with the ACTION function `c-snug-do-while': (defun c-snug-do-while (syntax pos) "Dynamically calculate brace hanginess for do-while statements. Using this function, `while' clauses that end a `do-while' block will remain on the same line as the brace that closes that block. See `c-hanging-braces-alist' for how to utilize this function as an ACTION associated with `block-close' syntax." (save-excursion (let (langelem) (if (and (eq syntax 'block-close) (setq langelem (assq 'block-close c-syntactic-context)) (progn (goto-char (cdr langelem)) (if (= (following-char) ?{) (forward-sexp -1)) (looking-at "\\[^_]"))) '(before) '(before after))))) This function simply looks to see if the brace closes a "do-while" clause and if so, returns the list `(before)' indicating that a newline should be inserted before the brace, but not after it. In all other cases, it returns the list `(before after)' so that the brace appears on a line by itself. During the call to the brace hanging ACTION function, the variable `c-syntactic-context' is bound to the full syntactic analysis list. Note that for symmetry, colon hanginess should be customizable by allowing function symbols as ACTIONs on the `c-hanging-colon-alist' style variable. Since no use has actually been found for this feature, it isn't currently implemented!  File: ccmode, Node: Customizing Semi-colons and Commas, Next: Other Special Indentations, Prev: Custom Brace and Colon Hanging, Up: Advanced Customizations Customizing Semi-colons and Commas ---------------------------------- You can also customize the insertion of newlines after semi-colons and commas, when the auto-newline minor mode is enabled (*note Minor Modes::). This is controlled by the style variable `c-hanging-semi&comma-criteria', which contains a list of functions that are called in the order they appear. Each function is called with zero arguments, and is expected to return one of the following values: * non-`nil' -- A newline is inserted, and no more functions from the list are called. * `stop' -- No more functions from the list are called, but no newline is inserted. * `nil' -- No determination is made, and the next function in the list is called. If every function in the list is called without a determination being made, then no newline is added. The default value for this variable is a list containing a single function which inserts newlines only after semi-colons which do not appear inside parenthesis lists (i.e. those that separate `for'-clause statements). Here's an example of a criteria function, provided by CC Mode, that will prevent newlines from being inserted after semicolons when there is a non-blank following line. Otherwise, it makes no determination. To use, add this to the front of the `c-hanging-semi&comma-criteria' list. (defun c-semi&comma-no-newlines-before-nonblanks () (save-excursion (if (and (eq last-command-char ?\;) (zerop (forward-line 1)) (not (looking-at "^[ \t]*$"))) 'stop nil))) The function `c-semi&comma-inside-parenlist' is what prevents newlines from being inserted inside the parenthesis list of `for' statements. In addition to `c-semi&comma-no-newlines-before-nonblanks' described above, CC Mode also comes with the criteria function `c-semi&comma-no-newlines-for-oneline-inliners', which suppresses newlines after semicolons inside one-line inline method definitions (i.e. in C++ or Java).  File: ccmode, Node: Other Special Indentations, Prev: Customizing Semi-colons and Commas, Up: Advanced Customizations Other Special Indentations -------------------------- In `gnu' style (*note Built-in Styles::), a minimum indentation is imposed on lines inside top-level constructs. This minimum indentation is controlled by the style variable `c-label-minimum-indentation'. The default value for this variable is 1. One other customization variable is available in CC Mode: The style variable `c-special-indent-hook'. This is a standard hook variable that is called after every line is indented by CC Mode. You can use it to do any special indentation or line adjustments your style dictates, such as adding extra indentation to constructors or destructor declarations in a class definition, etc. Note however, that you should not change point or mark inside your `c-special-indent-hook' functions (i.e. you'll probably want to wrap your function in a `save-excursion'). Setting `c-special-indent-hook' in your style definition is handled slightly differently than other variables. In your style definition, you should set the value for `c-special-indent-hook' to a function or list of functions, which will be appended to `c-special-indent-hook' using `add-hook'. That way, the current setting for the buffer local value of `c-special-indent-hook' won't be overridden. Normally, the standard Emacs command `M-;' (`indent-for-comment') will indent comment only lines to `comment-column'. Some users however, prefer that `M-;' act just like `TAB' for purposes of indenting comment-only lines; i.e. they want the comments to always indent as they would for normal code, regardless of whether `TAB' or `M-;' were used. This behavior is controlled by the variable `c-indent-comments-syntactically-p'. When `nil' (the default), `M-;' indents comment-only lines to `comment-column', otherwise, they are indented just as they would be if `TAB' were typed. Note that this has no effect for comment lines that are inserted with `M-;' at the end of regular code lines. These comments will always start at `comment-column'.