The GNU coding standards, last updated June 10, 2008.
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Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with no Invariant Sections, with no Front-Cover Texts, and with no Back-Cover Texts. A copy of the license is included in the section entitled “GNU Free Documentation License”.
The GNU Coding Standards were written by Richard Stallman and other GNU Project volunteers. Their purpose is to make the GNU system clean, consistent, and easy to install. This document can also be read as a guide to writing portable, robust and reliable programs. It focuses on programs written in C, but many of the rules and principles are useful even if you write in another programming language. The rules often state reasons for writing in a certain way.
This release of the GNU Coding Standards was last updated June 10, 2008.
If you did not obtain this file directly from the GNU project and recently, please check for a newer version. You can get the GNU Coding Standards from the GNU web server in many different formats, including the Texinfo source, PDF, HTML, DVI, plain text, and more, at: http://www.gnu.org/prep/standards/.
Corrections or suggestions for this document should be sent to bug-standards@gnu.org. If you make a suggestion, please include a suggested new wording for it; our time is limited. We prefer a context diff to the standards.texi or make-stds.texi files, but if you don't have those files, please mail your suggestion anyway.
These standards cover the minimum of what is important when writing a GNU package. Likely, the need for additional standards will come up. Sometimes, you might suggest that such standards be added to this document. If you think your standards would be generally useful, please do suggest them.
You should also set standards for your package on many questions not addressed or not firmly specified here. The most important point is to be self-consistent—try to stick to the conventions you pick, and try to document them as much as possible. That way, your program will be more maintainable by others.
The GNU Hello program serves as an example of how to follow the GNU coding standards for a trivial program. http://www.gnu.org/software/hello/hello.html.
This chapter discusses how you can make sure that GNU software avoids legal difficulties, and other related issues.
Don't in any circumstances refer to Unix source code for or during your work on GNU! (Or to any other proprietary programs.)
If you have a vague recollection of the internals of a Unix program, this does not absolutely mean you can't write an imitation of it, but do try to organize the imitation internally along different lines, because this is likely to make the details of the Unix version irrelevant and dissimilar to your results.
For example, Unix utilities were generally optimized to minimize memory use; if you go for speed instead, your program will be very different. You could keep the entire input file in memory and scan it there instead of using stdio. Use a smarter algorithm discovered more recently than the Unix program. Eliminate use of temporary files. Do it in one pass instead of two (we did this in the assembler).
Or, on the contrary, emphasize simplicity instead of speed. For some applications, the speed of today's computers makes simpler algorithms adequate.
Or go for generality. For example, Unix programs often have static tables or fixed-size strings, which make for arbitrary limits; use dynamic allocation instead. Make sure your program handles NULs and other funny characters in the input files. Add a programming language for extensibility and write part of the program in that language.
Or turn some parts of the program into independently usable libraries. Or use a simple garbage collector instead of tracking precisely when to free memory, or use a new GNU facility such as obstacks.
If the program you are working on is copyrighted by the Free Software Foundation, then when someone else sends you a piece of code to add to the program, we need legal papers to use it—just as we asked you to sign papers initially. Each person who makes a nontrivial contribution to a program must sign some sort of legal papers in order for us to have clear title to the program; the main author alone is not enough.
So, before adding in any contributions from other people, please tell us, so we can arrange to get the papers. Then wait until we tell you that we have received the signed papers, before you actually use the contribution.
This applies both before you release the program and afterward. If you receive diffs to fix a bug, and they make significant changes, we need legal papers for that change.
This also applies to comments and documentation files. For copyright law, comments and code are just text. Copyright applies to all kinds of text, so we need legal papers for all kinds.
We know it is frustrating to ask for legal papers; it's frustrating for us as well. But if you don't wait, you are going out on a limb—for example, what if the contributor's employer won't sign a disclaimer? You might have to take that code out again!
You don't need papers for changes of a few lines here or there, since they are not significant for copyright purposes. Also, you don't need papers if all you get from the suggestion is some ideas, not actual code which you use. For example, if someone sent you one implementation, but you write a different implementation of the same idea, you don't need to get papers.
The very worst thing is if you forget to tell us about the other contributor. We could be very embarrassed in court some day as a result.
We have more detailed advice for maintainers of programs; if you have reached the stage of actually maintaining a program for GNU (whether released or not), please ask us for a copy. It is also available online for your perusal: http://www.gnu.org/prep/maintain/.
Please do not include any trademark acknowledgements in GNU software packages or documentation.
Trademark acknowledgements are the statements that such-and-such is a trademark of so-and-so. The GNU Project has no objection to the basic idea of trademarks, but these acknowledgements feel like kowtowing, and there is no legal requirement for them, so we don't use them.
What is legally required, as regards other people's trademarks, is to avoid using them in ways which a reader might reasonably understand as naming or labeling our own programs or activities. For example, since “Objective C” is (or at least was) a trademark, we made sure to say that we provide a “compiler for the Objective C language” rather than an “Objective C compiler”. The latter would have been meant as a shorter way of saying the former, but it does not explicitly state the relationship, so it could be misinterpreted as using “Objective C” as a label for the compiler rather than for the language.
Please don't use “win” as an abbreviation for Microsoft Windows in GNU software or documentation. In hacker terminology, calling something a “win” is a form of praise. If you wish to praise Microsoft Windows when speaking on your own, by all means do so, but not in GNU software. Usually we write the name “Windows” in full, but when brevity is very important (as in file names and sometimes symbol names), we abbreviate it to “w”. For instance, the files and functions in Emacs that deal with Windows start with ‘w32’.
This chapter discusses some of the issues you should take into account when designing your program.
When you want to use a language that gets compiled and runs at high speed, the best language to use is C. Using another language is like using a non-standard feature: it will cause trouble for users. Even if GCC supports the other language, users may find it inconvenient to have to install the compiler for that other language in order to build your program. For example, if you write your program in C++, people will have to install the GNU C++ compiler in order to compile your program.
C has one other advantage over C++ and other compiled languages: more people know C, so more people will find it easy to read and modify the program if it is written in C.
So in general it is much better to use C, rather than the comparable alternatives.
But there are two exceptions to that conclusion:
Many programs are designed to be extensible: they include an interpreter for a language that is higher level than C. Often much of the program is written in that language, too. The Emacs editor pioneered this technique.
The standard extensibility interpreter for GNU software is Guile (http://www.gnu.org/software/guile/), which implements the language Scheme (an especially clean and simple dialect of Lisp). Guile also includes bindings for GTK+/GNOME, making it practical to write modern GUI functionality within Guile. We don't reject programs written in other “scripting languages” such as Perl and Python, but using Guile is very important for the overall consistency of the GNU system.
With occasional exceptions, utility programs and libraries for GNU should be upward compatible with those in Berkeley Unix, and upward compatible with Standard C if Standard C specifies their behavior, and upward compatible with posix if posix specifies their behavior.
When these standards conflict, it is useful to offer compatibility modes for each of them.
Standard C and posix prohibit many kinds of extensions. Feel free to make the extensions anyway, and include a ‘--ansi’, ‘--posix’, or ‘--compatible’ option to turn them off. However, if the extension has a significant chance of breaking any real programs or scripts, then it is not really upward compatible. So you should try to redesign its interface to make it upward compatible.
Many GNU programs suppress extensions that conflict with posix if the
environment variable POSIXLY_CORRECT is defined (even if it is
defined with a null value). Please make your program recognize this
variable if appropriate.
When a feature is used only by users (not by programs or command
files), and it is done poorly in Unix, feel free to replace it
completely with something totally different and better. (For example,
vi is replaced with Emacs.) But it is nice to offer a compatible
feature as well. (There is a free vi clone, so we offer it.)
Additional useful features are welcome regardless of whether there is any precedent for them.
Many GNU facilities that already exist support a number of convenient extensions over the comparable Unix facilities. Whether to use these extensions in implementing your program is a difficult question.
On the one hand, using the extensions can make a cleaner program. On the other hand, people will not be able to build the program unless the other GNU tools are available. This might cause the program to work on fewer kinds of machines.
With some extensions, it might be easy to provide both alternatives.
For example, you can define functions with a “keyword” INLINE
and define that as a macro to expand into either inline or
nothing, depending on the compiler.
In general, perhaps it is best not to use the extensions if you can straightforwardly do without them, but to use the extensions if they are a big improvement.
An exception to this rule are the large, established programs (such as Emacs) which run on a great variety of systems. Using GNU extensions in such programs would make many users unhappy, so we don't do that.
Another exception is for programs that are used as part of compilation: anything that must be compiled with other compilers in order to bootstrap the GNU compilation facilities. If these require the GNU compiler, then no one can compile them without having them installed already. That would be extremely troublesome in certain cases.
1989 Standard C is widespread enough now that it is ok to use its features in new programs. There is one exception: do not ever use the “trigraph” feature of Standard C.
1999 Standard C is not widespread yet, so please do not require its features in programs. It is ok to use its features if they are present.
However, it is easy to support pre-standard compilers in most programs, so if you know how to do that, feel free. If a program you are maintaining has such support, you should try to keep it working.
To support pre-standard C, instead of writing function definitions in standard prototype form,
int
foo (int x, int y)
...
write the definition in pre-standard style like this,
int
foo (x, y)
int x, y;
...
and use a separate declaration to specify the argument prototype:
int foo (int, int);
You need such a declaration anyway, in a header file, to get the benefit of prototypes in all the files where the function is called. And once you have the declaration, you normally lose nothing by writing the function definition in the pre-standard style.
This technique does not work for integer types narrower than int.
If you think of an argument as being of a type narrower than int,
declare it as int instead.
There are a few special cases where this technique is hard to use. For
example, if a function argument needs to hold the system type
dev_t, you run into trouble, because dev_t is shorter than
int on some machines; but you cannot use int instead,
because dev_t is wider than int on some machines. There
is no type you can safely use on all machines in a non-standard
definition. The only way to support non-standard C and pass such an
argument is to check the width of dev_t using Autoconf and choose
the argument type accordingly. This may not be worth the trouble.
In order to support pre-standard compilers that do not recognize prototypes, you may want to use a preprocessor macro like this:
/* Declare the prototype for a general external function. */
#if defined (__STDC__) || defined (WINDOWSNT)
#define P_(proto) proto
#else
#define P_(proto) ()
#endif
When supporting configuration options already known when building your
program we prefer using if (... ) over conditional compilation,
as in the former case the compiler is able to perform more extensive
checking of all possible code paths.
For example, please write
if (HAS_FOO)
...
else
...
instead of:
#ifdef HAS_FOO
...
#else
...
#endif
A modern compiler such as GCC will generate exactly the same code in
both cases, and we have been using similar techniques with good success
in several projects. Of course, the former method assumes that
HAS_FOO is defined as either 0 or 1.
While this is not a silver bullet solving all portability problems, and is not always appropriate, following this policy would have saved GCC developers many hours, or even days, per year.
In the case of function-like macros like REVERSIBLE_CC_MODE in
GCC which cannot be simply used in if( ...) statements, there is
an easy workaround. Simply introduce another macro
HAS_REVERSIBLE_CC_MODE as in the following example:
#ifdef REVERSIBLE_CC_MODE
#define HAS_REVERSIBLE_CC_MODE 1
#else
#define HAS_REVERSIBLE_CC_MODE 0
#endif
This chapter describes conventions for writing robust software. It also describes general standards for error messages, the command line interface, and how libraries should behave.
The GNU Project regards standards published by other organizations as suggestions, not orders. We consider those standards, but we do not “obey” them. In developing a GNU program, you should implement an outside standard's specifications when that makes the GNU system better overall in an objective sense. When it doesn't, you shouldn't.
In most cases, following published standards is convenient for users—it means that their programs or scripts will work more portably. For instance, GCC implements nearly all the features of Standard C as specified by that standard. C program developers would be unhappy if it did not. And GNU utilities mostly follow specifications of POSIX.2; shell script writers and users would be unhappy if our programs were incompatible.
But we do not follow either of these specifications rigidly, and there are specific points on which we decided not to follow them, so as to make the GNU system better for users.
For instance, Standard C says that nearly all extensions to C are prohibited. How silly! GCC implements many extensions, some of which were later adopted as part of the standard. If you want these constructs to give an error message as “required” by the standard, you must specify ‘--pedantic’, which was implemented only so that we can say “GCC is a 100% implementation of the standard,” not because there is any reason to actually use it.
POSIX.2 specifies that ‘df’ and ‘du’ must output sizes by default in units of 512 bytes. What users want is units of 1k, so that is what we do by default. If you want the ridiculous behavior “required” by POSIX, you must set the environment variable ‘POSIXLY_CORRECT’ (which was originally going to be named ‘POSIX_ME_HARDER’).
GNU utilities also depart from the letter of the POSIX.2 specification when they support long-named command-line options, and intermixing options with ordinary arguments. This minor incompatibility with POSIX is never a problem in practice, and it is very useful.
In particular, don't reject a new feature, or remove an old one, merely because a standard says it is “forbidden” or “deprecated.”
Avoid arbitrary limits on the length or number of any data structure, including file names, lines, files, and symbols, by allocating all data structures dynamically. In most Unix utilities, “long lines are silently truncated”. This is not acceptable in a GNU utility.
Utilities reading files should not drop NUL characters, or any other nonprinting characters including those with codes above 0177. The only sensible exceptions would be utilities specifically intended for interface to certain types of terminals or printers that can't handle those characters. Whenever possible, try to make programs work properly with sequences of bytes that represent multibyte characters, using encodings such as UTF-8 and others.
Check every system call for an error return, unless you know you wish to
ignore errors. Include the system error text (from perror or
equivalent) in every error message resulting from a failing
system call, as well as the name of the file if any and the name of the
utility. Just “cannot open foo.c” or “stat failed” is not
sufficient.
Check every call to malloc or realloc to see if it
returned zero. Check realloc even if you are making the block
smaller; in a system that rounds block sizes to a power of 2,
realloc may get a different block if you ask for less space.
In Unix, realloc can destroy the storage block if it returns
zero. GNU realloc does not have this bug: if it fails, the
original block is unchanged. Feel free to assume the bug is fixed. If
you wish to run your program on Unix, and wish to avoid lossage in this
case, you can use the GNU malloc.
You must expect free to alter the contents of the block that was
freed. Anything you want to fetch from the block, you must fetch before
calling free.
If malloc fails in a noninteractive program, make that a fatal
error. In an interactive program (one that reads commands from the
user), it is better to abort the command and return to the command
reader loop. This allows the user to kill other processes to free up
virtual memory, and then try the command again.
Use getopt_long to decode arguments, unless the argument syntax
makes this unreasonable.
When static storage is to be written in during program execution, use explicit C code to initialize it. Reserve C initialized declarations for data that will not be changed.
Try to avoid low-level interfaces to obscure Unix data structures (such
as file directories, utmp, or the layout of kernel memory), since these
are less likely to work compatibly. If you need to find all the files
in a directory, use readdir or some other high-level interface.
These are supported compatibly by GNU.
The preferred signal handling facilities are the BSD variant of
signal, and the posix sigaction function; the
alternative USG signal interface is an inferior design.
Nowadays, using the posix signal functions may be the easiest way
to make a program portable. If you use signal, then on GNU/Linux
systems running GNU libc version 1, you should include
bsd/signal.h instead of signal.h, so as to get BSD
behavior. It is up to you whether to support systems where
signal has only the USG behavior, or give up on them.
In error checks that detect “impossible” conditions, just abort. There is usually no point in printing any message. These checks indicate the existence of bugs. Whoever wants to fix the bugs will have to read the source code and run a debugger. So explain the problem with comments in the source. The relevant data will be in variables, which are easy to examine with the debugger, so there is no point moving them elsewhere.
Do not use a count of errors as the exit status for a program. That does not work, because exit status values are limited to 8 bits (0 through 255). A single run of the program might have 256 errors; if you try to return 256 as the exit status, the parent process will see 0 as the status, and it will appear that the program succeeded.
If you make temporary files, check the TMPDIR environment
variable; if that variable is defined, use the specified directory
instead of /tmp.
In addition, be aware that there is a possible security problem when creating temporary files in world-writable directories. In C, you can avoid this problem by creating temporary files in this manner:
fd = open(filename, O_WRONLY | O_CREAT | O_EXCL, 0600);
or by using the mkstemps function from libiberty.
In bash, use set -C to avoid this problem.
Try to make library functions reentrant. If they need to do dynamic
storage allocation, at least try to avoid any nonreentrancy aside from
that of malloc itself.
Here are certain name conventions for libraries, to avoid name conflicts.
Choose a name prefix for the library, more than two characters long. All external function and variable names should start with this prefix. In addition, there should only be one of these in any given library member. This usually means putting each one in a separate source file.
An exception can be made when two external symbols are always used together, so that no reasonable program could use one without the other; then they can both go in the same file.
External symbols that are not documented entry points for the user should have names beginning with ‘_’. The ‘_’ should be followed by the chosen name prefix for the library, to prevent collisions with other libraries. These can go in the same files with user entry points if you like.
Static functions and variables can be used as you like and need not fit any naming convention.
Error messages from compilers should look like this:
source-file-name:lineno: message
If you want to mention the column number, use one of these formats:
source-file-name:lineno:column: message
source-file-name:lineno.column: message
Line numbers should start from 1 at the beginning of the file, and column numbers should start from 1 at the beginning of the line. (Both of these conventions are chosen for compatibility.) Calculate column numbers assuming that space and all ASCII printing characters have equal width, and assuming tab stops every 8 columns.
The error message can also give both the starting and ending positions of the erroneous text. There are several formats so that you can avoid redundant information such as a duplicate line number. Here are the possible formats:
source-file-name:lineno-1.column-1-lineno-2.column-2: message
source-file-name:lineno-1.column-1-column-2: message
source-file-name:lineno-1-lineno-2: message
When an error is spread over several files, you can use this format:
file-1:lineno-1.column-1-file-2:lineno-2.column-2: message
Error messages from other noninteractive programs should look like this:
program:source-file-name:lineno: message
when there is an appropriate source file, or like this:
program: message
when there is no relevant source file.
If you want to mention the column number, use this format:
program:source-file-name:lineno:column: message
In an interactive program (one that is reading commands from a terminal), it is better not to include the program name in an error message. The place to indicate which program is running is in the prompt or with the screen layout. (When the same program runs with input from a source other than a terminal, it is not interactive and would do best to print error messages using the noninteractive style.)
The string message should not begin with a capital letter when it follows a program name and/or file name, because that isn't the beginning of a sentence. (The sentence conceptually starts at the beginning of the line.) Also, it should not end with a period.
Error messages from interactive programs, and other messages such as usage messages, should start with a capital letter. But they should not end with a period.
Please don't make the behavior of a utility depend on the name used to invoke it. It is useful sometimes to make a link to a utility with a different name, and that should not change what it does.
Instead, use a run time option or a compilation switch or both to select among the alternate behaviors.
Likewise, please don't make the behavior of the program depend on the type of output device it is used with. Device independence is an important principle of the system's design; do not compromise it merely to save someone from typing an option now and then. (Variation in error message syntax when using a terminal is ok, because that is a side issue that people do not depend on.)
If you think one behavior is most useful when the output is to a terminal, and another is most useful when the output is a file or a pipe, then it is usually best to make the default behavior the one that is useful with output to a terminal, and have an option for the other behavior.
Compatibility requires certain programs to depend on the type of output
device. It would be disastrous if ls or sh did not do so
in the way all users expect. In some of these cases, we supplement the
program with a preferred alternate version that does not depend on the
output device type. For example, we provide a dir program much
like ls except that its default output format is always
multi-column format.
When you write a program that provides a graphical user interface, please make it work with X Windows and the GTK+ toolkit unless the functionality specifically requires some alternative (for example, “displaying jpeg images while in console mode”).
In addition, please provide a command-line interface to control the functionality. (In many cases, the graphical user interface can be a separate program which invokes the command-line program.) This is so that the same jobs can be done from scripts.
Please also consider providing a CORBA interface (for use from GNOME), a library interface (for use from C), and perhaps a keyboard-driven console interface (for use by users from console mode). Once you are doing the work to provide the functionality and the graphical interface, these won't be much extra work.
It is a good idea to follow the posix guidelines for the
command-line options of a program. The easiest way to do this is to use
getopt to parse them. Note that the GNU version of getopt
will normally permit options anywhere among the arguments unless the
special argument ‘--’ is used. This is not what posix
specifies; it is a GNU extension.
Please define long-named options that are equivalent to the
single-letter Unix-style options. We hope to make GNU more user
friendly this way. This is easy to do with the GNU function
getopt_long.
One of the advantages of long-named options is that they can be consistent from program to program. For example, users should be able to expect the “verbose” option of any GNU program which has one, to be spelled precisely ‘--verbose’. To achieve this uniformity, look at the table of common long-option names when you choose the option names for your program (see Option Table).
It is usually a good idea for file names given as ordinary arguments to be input files only; any output files would be specified using options (preferably ‘-o’ or ‘--output’). Even if you allow an output file name as an ordinary argument for compatibility, try to provide an option as another way to specify it. This will lead to more consistency among GNU utilities, and fewer idiosyncrasies for users to remember.
All programs should support two standard options: ‘--version’ and ‘--help’. CGI programs should accept these as command-line options, and also if given as the PATH_INFO; for instance, visiting http://example.org/p.cgi/–help in a browser should output the same information as invoking ‘p.cgi --help’ from the command line.
The standard --version option should direct the program to
print information about its name, version, origin and legal status,
all on standard output, and then exit successfully. Other options and
arguments should be ignored once this is seen, and the program should
not perform its normal function.
The first line is meant to be easy for a program to parse; the version number proper starts after the last space. In addition, it contains the canonical name for this program, in this format:
GNU Emacs 19.30
The program's name should be a constant string; don't compute it
from argv[0]. The idea is to state the standard or canonical
name for the program, not its file name. There are other ways to find
out the precise file name where a command is found in PATH.
If the program is a subsidiary part of a larger package, mention the package name in parentheses, like this:
emacsserver (GNU Emacs) 19.30
If the package has a version number which is different from this program's version number, you can mention the package version number just before the close-parenthesis.
If you need to mention the version numbers of libraries which are distributed separately from the package which contains this program, you can do so by printing an additional line of version info for each library you want to mention. Use the same format for these lines as for the first line.
Please do not mention all of the libraries that the program uses “just for completeness”—that would produce a lot of unhelpful clutter. Please mention library version numbers only if you find in practice that they are very important to you in debugging.
The following line, after the version number line or lines, should be a copyright notice. If more than one copyright notice is called for, put each on a separate line.
Next should follow a line stating the license, preferably using one of abbrevations below, and a brief statement that the program is free software, and that users are free to copy and change it. Also mention that there is no warranty, to the extent permitted by law. See recommended wording below.
It is ok to finish the output with a list of the major authors of the program, as a way of giving credit.
Here's an example of output that follows these rules:
GNU hello 2.3
Copyright (C) 2007 Free Software Foundation, Inc.
License GPLv3+: GNU GPL version 3 or later <http://gnu.org/licenses/gpl.html>
This is free software: you are free to change and redistribute it.
There is NO WARRANTY, to the extent permitted by law.
You should adapt this to your program, of course, filling in the proper year, copyright holder, name of program, and the references to distribution terms, and changing the rest of the wording as necessary.
This copyright notice only needs to mention the most recent year in which changes were made—there's no need to list the years for previous versions' changes. You don't have to mention the name of the program in these notices, if that is inconvenient, since it appeared in the first line. (The rules are different for copyright notices in source files; see Copyright Notices.)
Translations of the above lines must preserve the validity of the copyright notices (see Internationalization). If the translation's character set supports it, the ‘(C)’ should be replaced with the copyright symbol, as follows:
©
Write the word “Copyright” exactly like that, in English. Do not translate it into another language. International treaties recognize the English word “Copyright”; translations into other languages do not have legal significance.
Finally, here is the table of our suggested license abbreviations. Any abbreviation can be followed by ‘vversion[+]’, meaning that particular version, or later versions with the ‘+’, as shown above.
In the case of exceptions for extra permissions with the GPL, we use ‘/’ for a separator; the version number can follow the license abbreviation as usual, as in the examples below.
More information about these licenses and many more are on the GNU licensing web pages, http://www.gnu.org/licenses/license-list.html.
The standard --help option should output brief documentation
for how to invoke the program, on standard output, then exit
successfully. Other options and arguments should be ignored once this
is seen, and the program should not perform its normal function.
Near the end of the ‘--help’ option's output there should be a line that says where to mail bug reports. It should have this format:
Report bugs to mailing-address.
Here is a table of long options used by GNU programs. It is surely incomplete, but we aim to list all the options that a new program might want to be compatible with. If you use names not already in the table, please send bug-standards@gnu.org a list of them, with their meanings, so we can update the table.
tar.
du, ls, nm, stty, uname,
and unexpand.
diff.
ls.
etags, tee, time;
‘-r’ in tar.
cp.
shar.
m4.
diff.
gawk.
make.
make.
recode.
wdiff.
ptx.
wdiff.
ctags.
shar.
tac.
cpio and diff.
shar.
cpio and tar.
head and tail.
ptx.
head, split, and tail.
etags.
tar.
chgrp and chown.
ls.
recode.
su;
‘-x’ in GDB.
tar.
gawk.
tar and shar.
tar.
tar.
diff.
gawk.
ptx, recode, and wdiff;
‘-W copyright’ in gawk.
who.
du.
tar and cpio.
shar.
ctags.
touch.
make and m4;
‘-t’ in Bison.
m4.
ctags.
tar.
chgrp, chown, cpio, du,
ls, and tar.
du.
recode.
look.
tar.
csplit.
ls, it
means to show directories themselves rather than their contents. In
rm and ln, it means to not treat links to directories
specially.
strip.
strip.
make.
diff.
csplit.
wdiff.
wdiff.
diff.
make.
xargs.
makeinfo.
m4.
ls.
tar.
xargs.
unshar.
diff.
sed.
nm.
cpio;
‘-x’ in tar.
finger.
su.
m4.
gawk, info, make, mt,
sed, and tar.
gawk.
ls.
tar.
makeinfo.
ptx.
tail.
makeinfo.
cp, ln, mv, and rm.
shar.
ls, time, and ptx.
m4.
ptx.
tar.
ul.
recode.
install.
tar and shar.
m4.
objdump and recode
who.
shar.
ls.
makeinfo, output HTML.
who.
diff.
ls;
‘-x’ in recode.
diff.
ls.
diff.
look and ptx;
‘-i’ in diff and wdiff.
make.
ptx.
etags.
tee.
diff.
diff.
tar.
etags;
‘-I’ in m4.
make.
tar.
expand.
diff.
ls.
cp, ln, mv, rm;
‘-e’ in m4;
‘-p’ in xargs;
‘-w’ in tar.
shar.
date
make.
make.
make.
csplit.
du and ls.
etags.
wdiff.
shar.
split.
split, head, and tail.
cpio.
gawk.
cpio;
‘-l’ in recode.
tar.
ls.
make.
su.
uname.
ptx.
hello and uname.
cpio.
make.
xargs.
xargs.
xargs.
make.
xargs.
who.
who.
diff.
shar.
install, mkdir, and mkfifo.
tar.
tar.
m4.
shar.
make.
make.
shar.
shar.
wdiff.
touch.
etags.
wdiff.
cp.
wdiff.
make.
shar.
gprof.
etags.
nm.
makeinfo.
gprof.
gprof.
shar.
makeinfo.
emacsclient.
info.
uname.
cpio.
objdump.
xargs.
cat.
cat.
nm.
cpio and ls.
tar.
make.
tar, cp, and du.
ptx.
gprof.
gprof.
getopt, fdlist, fdmount,
fdmountd, and fdumount.
shar.
rm.
unshar.
install.
diff.
makeinfo.
mkdir and rmdir.
ul.
cpio.
finger.
cpio and tar.
gawk.
m4.
csplit.
tar and cp.
su.
cpio.
tar.
tar.
diff.
cmp.
make.
make.
nm.
nm.
wdiff.
ed.
shar.
make.
shar
ls.
diff.
gawk.
tar.
make.
tar.
chgrp, chown, cp, ls, diff,
and rm.
touch.
ptx.
tac and etags.
uname.
m4.
objdump.
cpio.
xargs.
diff.
cpio.
ls and nm.
diff.
ptx.
tar.
tar.
stty.
ptx.
du.
tac.
recode to chose files or pipes for sequencing passes.
su.
cat.
diff.
cat.
diff.
cat.
ls.
ls.
gawk.
tar.
diff.
unshar.
shar.
cat.
wdiff.
wdiff.
tar and diff to specify which file within
a directory to start processing with.
wdiff.
shar.
make.
recode.
install.
strip.
strip.
shar.
cp, ln, mv.
csplit.
gprof.
du.
ln.
objdump.
m4.
uname.
expand and unexpand.
ls.
tput and ul.
‘-t’ in wdiff.
diff.
shar.
ls and touch.
tar.
du.
make, ranlib, and recode.
m4.
hello;
‘-W traditional’ in gawk;
‘-G’ in ed, m4, and ptx.
ctags.
ctags.
ptx.
tar.
cpio.
m4.
nm.
cp, ctags, mv, tar.
gawk; same as ‘--help’.
shar.
shar.
tar.
cp, ln, mv.
ctags.
tar.
make.
shar.
ls and ptx.
ptx.
who.
gprof.
If a program typically uses just a few meg of memory, don't bother making any effort to reduce memory usage. For example, if it is impractical for other reasons to operate on files more than a few meg long, it is reasonable to read entire input files into memory to operate on them.
However, for programs such as cat or tail, that can
usefully operate on very large files, it is important to avoid using a
technique that would artificially limit the size of files it can handle.
If a program works by lines and could be applied to arbitrary
user-supplied input files, it should keep only a line in memory, because
this is not very hard and users will want to be able to operate on input
files that are bigger than will fit in memory all at once.
If your program creates complicated data structures, just make them in
memory and give a fatal error if malloc returns zero.
Programs should be prepared to operate when /usr and /etc are read-only file systems. Thus, if the program manages log files, lock files, backup files, score files, or any other files which are modified for internal purposes, these files should not be stored in /usr or /etc.
There are two exceptions. /etc is used to store system configuration information; it is reasonable for a program to modify files in /etc when its job is to update the system configuration. Also, if the user explicitly asks to modify one file in a directory, it is reasonable for the program to store other files in the same directory.
This chapter provides advice on how best to use the C language when writing GNU software.
It is important to put the open-brace that starts the body of a C function in column one, so that they will start a defun. Several tools look for open-braces in column one to find the beginnings of C functions. These tools will not work on code not formatted that way.
Avoid putting open-brace, open-parenthesis or open-bracket in column
one when they are inside a function, so that they won't start a defun.
The open-brace that starts a struct body can go in column one
if you find it useful to treat that definition as a defun.
It is also important for function definitions to start the name of the function in column one. This helps people to search for function definitions, and may also help certain tools recognize them. Thus, using Standard C syntax, the format is this:
static char *
concat (char *s1, char *s2)
{
...
}
or, if you want to use traditional C syntax, format the definition like this:
static char *
concat (s1, s2) /* Name starts in column one here */
char *s1, *s2;
{ /* Open brace in column one here */
...
}
In Standard C, if the arguments don't fit nicely on one line, split it like this:
int
lots_of_args (int an_integer, long a_long, short a_short,
double a_double, float a_float)
...
The rest of this section gives our recommendations for other aspects of
C formatting style, which is also the default style of the indent
program in version 1.2 and newer. It corresponds to the options
-nbad -bap -nbc -bbo -bl -bli2 -bls -ncdb -nce -cp1 -cs -di2
-ndj -nfc1 -nfca -hnl -i2 -ip5 -lp -pcs -psl -nsc -nsob
We don't think of these recommendations as requirements, because it causes no problems for users if two different programs have different formatting styles.
But whatever style you use, please use it consistently, since a mixture of styles within one program tends to look ugly. If you are contributing changes to an existing program, please follow the style of that program.
For the body of the function, our recommended style looks like this:
if (x < foo (y, z))
haha = bar[4] + 5;
else
{
while (z)
{
haha += foo (z, z);
z--;
}
return ++x + bar ();
}
We find it easier to read a program when it has spaces before the open-parentheses and after the commas. Especially after the commas.
When you split an expression into multiple lines, split it before an operator, not after one. Here is the right way:
if (foo_this_is_long && bar > win (x, y, z)
&& remaining_condition)
Try to avoid having two operators of different precedence at the same level of indentation. For example, don't write this:
mode = (inmode[j] == VOIDmode
|| GET_MODE_SIZE (outmode[j]) > GET_MODE_SIZE (inmode[j])
? outmode[j] : inmode[j]);
Instead, use extra parentheses so that the indentation shows the nesting:
mode = ((inmode[j] == VOIDmode
|| (GET_MODE_SIZE (outmode[j]) > GET_MODE_SIZE (inmode[j])))
? outmode[j] : inmode[j]);
Insert extra parentheses so that Emacs will indent the code properly. For example, the following indentation looks nice if you do it by hand,
v = rup->ru_utime.tv_sec*1000 + rup->ru_utime.tv_usec/1000
+ rup->ru_stime.tv_sec*1000 + rup->ru_stime.tv_usec/1000;
but Emacs would alter it. Adding a set of parentheses produces something that looks equally nice, and which Emacs will preserve:
v = (rup->ru_utime.tv_sec*1000 + rup->ru_utime.tv_usec/1000
+ rup->ru_stime.tv_sec*1000 + rup->ru_stime.tv_usec/1000);
Format do-while statements like this:
do
{
a = foo (a);
}
while (a > 0);
Please use formfeed characters (control-L) to divide the program into pages at logical places (but not within a function). It does not matter just how long the pages are, since they do not have to fit on a printed page. The formfeeds should appear alone on lines by themselves.
Every program should start with a comment saying briefly what it is for. Example: ‘fmt - filter for sim