SubmittingPatches, SubmitChecklist and CodingStyle


How to Get Your Change Into the Linux Kernel or Care And Operation Of Your Linus Torvalds For a person or company who wishes to submit a change to the Linux kernel, the process can sometimes be daunting if you're not familiar with "the system." This text is a collection of suggestions which can greatly increase the chances of your change being accepted. Read Documentation/SubmitChecklist for a list of items to check before submitting code. If you are submitting a driver, also read Documentation/SubmittingDrivers. -------------------------------------------- SECTION 1 - CREATING AND SENDING YOUR CHANGE -------------------------------------------- 1) "diff -up" ------------ Use "diff -up" or "diff -uprN" to create patches. All changes to the Linux kernel occur in the form of patches, as generated by diff(1). When creating your patch, make sure to create it in "unified diff" format, as supplied by the '-u' argument to diff(1). Also, please use the '-p' argument which shows which C function each change is in - that makes the resultant diff a lot easier to read. Patches should be based in the root kernel source directory, not in any lower subdirectory. To create a patch for a single file, it is often sufficient to do: SRCTREE= linux-2.6 MYFILE= drivers/net/mydriver.c cd $SRCTREE cp $MYFILE $MYFILE.orig vi $MYFILE # make your change cd .. diff -up $SRCTREE/$MYFILE{.orig,} > /tmp/patch To create a patch for multiple files, you should unpack a "vanilla", or unmodified kernel source tree, and generate a diff against your own source tree. For example: MYSRC= /devel/linux-2.6 tar xvfz linux-2.6.12.tar.gz mv linux-2.6.12 linux-2.6.12-vanilla diff -uprN -X linux-2.6.12-vanilla/Documentation/dontdiff \ linux-2.6.12-vanilla $MYSRC > /tmp/patch "dontdiff" is a list of files which are generated by the kernel during the build process, and should be ignored in any diff(1)-generated patch. The "dontdiff" file is included in the kernel tree in 2.6.12 and later. Make sure your patch does not include any extra files which do not belong in a patch submission. Make sure to review your patch -after- generated it with diff(1), to ensure accuracy. If your changes produce a lot of deltas, you may want to look into splitting them into individual patches which modify things in logical stages. This will facilitate easier reviewing by other kernel developers, very important if you want your patch accepted. There are a number of scripts which can aid in this: Quilt: http://savannah.nongnu.org/projects/quilt Andrew Morton's patch scripts: http://userweb.kernel.org/~akpm/stuff/patch-scripts.tar.gz Instead of these scripts, quilt is the recommended patch management tool (see above). 2) Describe your changes. Describe the technical detail of the change(s) your patch includes. Be as specific as possible. The WORST descriptions possible include things like "update driver X", "bug fix for driver X", or "this patch includes updates for subsystem X. Please apply." The maintainer will thank you if you write your patch description in a form which can be easily pulled into Linux's source code management system, git, as a "commit log". See #15, below. If your description starts to get long, that's a sign that you probably need to split up your patch. See #3, next. When you submit or resubmit a patch or patch series, include the complete patch description and justification for it. Don't just say that this is version N of the patch (series). Don't expect the patch merger to refer back to earlier patch versions or referenced URLs to find the patch description and put that into the patch. I.e., the patch (series) and its description should be self-contained. This benefits both the patch merger(s) and reviewers. Some reviewers probably didn't even receive earlier versions of the patch. If the patch fixes a logged bug entry, refer to that bug entry by number and URL. If you want to refer to a specific commit, don't just refer to the SHA-1 ID of the commit. Please also include the oneline summary of the commit, to make it easier for reviewers to know what it is about. Example: Commit e21d2170f36602ae2708 ("video: remove unnecessary platform_set_drvdata()") removed the unnecessary platform_set_drvdata(), but left the variable "dev" unused, delete it. 3) Separate your changes. Separate _logical changes_ into a single patch file. For example, if your changes include both bug fixes and performance enhancements for a single driver, separate those changes into two or more patches. If your changes include an API update, and a new driver which uses that new API, separate those into two patches. On the other hand, if you make a single change to numerous files, group those changes into a single patch. Thus a single logical change is contained within a single patch. If one patch depends on another patch in order for a change to be complete, that is OK. Simply note "this patch depends on patch X" in your patch description. If you cannot condense your patch set into a smaller set of patches, then only post say 15 or so at a time(那么一次只发出,比如15个patch)and wait for review and integration. 4) Style check your changes. Check your patch for basic style violations, details of which can be found in Documentation/CodingStyle. Failure to do so simply wastes the reviewers time and will get your patch rejected, probably without even being read. At a minimum you should check your patches with the patch style checker prior to submission (scripts/checkpatch.pl). You should be able to justify all violations that remain in your patch. 5) Select e-mail destination. Look through the MAINTAINERS file and the source code, and determine if your change applies to a specific subsystem of the kernel, with an assigned maintainer. If so, e-mail that person. The script scripts/get_maintainer.pl can be very useful at this step. If no maintainer is listed, or the maintainer does not respond, send your patch to the primary Linux kernel developer's mailing list, linux-kernel@vger.kernel.org. Most kernel developers monitor this e-mail list, and can comment on your changes. Do not send more than 15 patches at once to the vger mailing lists!!! Linus Torvalds is the final arbiter of all changes accepted into the Linux kernel. His e-mail address is <torvalds@linux-foundation.org>. He gets a lot of e-mail, so typically you should do your best to -avoid- sending him e-mail. Patches which are bug fixes, are "obvious" changes, or similarly require little discussion should be sent or CC'd to Linus. Patches which require discussion or do not have a clear advantage should usually be sent first to linux-kernel. Only after the patch is discussed should the patch then be submitted to Linus. 6) Select your CC (e-mail carbon copy) list. Unless you have a reason NOT to do so, CC linux-kernel@vger.kernel.org. Other kernel developers besides Linus need to be aware of your change, so that they may comment on it and offer code review and suggestions. linux-kernel is the primary Linux kernel developer mailing list. Other mailing lists are available for specific subsystems, such as USB, framebuffer devices, the VFS, the SCSI subsystem, etc. See the MAINTAINERS file for a mailing list that relates specifically to your change. Majordomo lists of VGER.KERNEL.ORG at: <http://vger.kernel.org/vger-lists.html> If changes affect userland-kernel interfaces, please send the MAN-PAGES maintainer (as listed in the MAINTAINERS file) a man-pages patch, or at least a notification of the change, so that some information makes its way into the manual pages. Even if the maintainer did not respond in step #5, make sure to ALWAYS copy the maintainer when you change their code. For small patches you may want to CC the Trivial Patch Monkey trivial@kernel.org which collects "trivial" patches. Have a look into the MAINTAINERS file for its current manager. Trivial patches must qualify for one of the following rules: Spelling fixes in documentation Spelling fixes which could break grep(1) Warning fixes (cluttering with useless warnings is bad) Compilation fixes (only if they are actually correct) Runtime fixes (only if they actually fix things) Removing use of deprecated functions/macros (eg. check_region) Contact detail and documentation fixes Non-portable code replaced by portable code (even in arch-specific, since people copy, as long as it's trivial) Any fix by the author/maintainer of the file (ie. patch monkey in re-transmission mode) 7) No MIME, no links, no compression, no attachments. Just plain text. Linus and other kernel developers need to be able to read and comment on the changes you are submitting. It is important for a kernel developer to be able to "quote" your changes, using standard e-mail tools, so that they may comment on specific portions of your code. For this reason, all patches should be submitting e-mail "inline". WARNING: Be wary of your editor's word-wrap corrupting your patch, if you choose to cut-n-paste your patch. Do not attach the patch as a MIME attachment, compressed or not. Many popular e-mail applications will not always transmit a MIME attachment as plain text, making it impossible to comment on your code. A MIME attachment also takes Linus a bit more time to process, decreasing the likelihood of your MIME-attached change being accepted. Exception: If your mailer is mangling patches then someone may ask you to re-send them using MIME. See Documentation/email-clients.txt for hints about configuring your e-mail client so that it sends your patches untouched. 8) E-mail size. When sending patches to Linus, always follow step #7. Large changes are not appropriate for mailing lists, and some maintainers. If your patch, uncompressed, exceeds 300 kB in size, it is preferred that you store your patch on an Internet-accessible server, and provide instead a URL (link) pointing to your patch. 9) Name your kernel version. It is important to note, either in the subject line or in the patch description, the kernel version to which this patch applies. If the patch does not apply cleanly to the latest kernel version, Linus will not apply it. 10) Don't get discouraged. Re-submit. After you have submitted your change, be patient and wait. If Linus likes your change and applies it, it will appear in the next version of the kernel that he releases. However, if your change doesn't appear in the next version of the kernel, there could be any number of reasons. It's YOUR job to narrow down those reasons, correct what was wrong, and submit your updated change. It is quite common for Linus to "drop" your patch without comment. That's the nature of the system. If he drops your patch, it could be due to * Your patch did not apply cleanly to the latest kernel version. * Your patch was not sufficiently discussed on linux-kernel. * A style issue (see section 2). * An e-mail formatting issue (re-read this section). * A technical problem with your change. * He gets tons of e-mail, and yours got lost in the shuffle. * You are being annoying. When in doubt, solicit comments on linux-kernel mailing list. 11) Include PATCH in the subject Due to high e-mail traffic to Linus, and to linux-kernel, it is common convention to prefix your subject line with [PATCH]. This lets Linus and other kernel developers more easily distinguish patches from other e-mail discussions. 12) Sign your work To improve tracking of who did what, especially with patches that can percolate to their final resting place in the kernel through several layers of maintainers, we've introduced a "sign-off" procedure on patches that are being emailed around. The sign-off is a simple line at the end of the explanation for the patch, which certifies that you wrote it or otherwise have the right to pass it on as an open-source patch. The rules are pretty simple: if you can certify the below: Developer's Certificate of Origin 1.1 By making a contribution to this project, I certify that: (a) The contribution was created in whole or in part by me and I have the right to submit it under the open source license indicated in the file; or (b) The contribution is based upon previous work that, to the best of my knowledge, is covered under an appropriate open source license and I have the right under that license to submit that work with modifications, whether created in whole or in part by me, under the same open source license (unless I am permitted to submit under a different license), as indicated in the file; or (c) The contribution was provided directly to me by some other person who certified (a), (b) or (c) and I have not modified it. (d) I understand and agree that this project and the contribution are public and that a record of the contribution (including all personal information I submit with it, including my sign-off) is maintained indefinitely and may be redistributed consistent with this project or the open source license(s) involved. then you just add a line saying Signed-off-by: Random J Developer <random@developer.example.org> using your real name (sorry, no pseudonyms or anonymous contributions.) Some people also put extra tags at the end. They'll just be ignored for now, but you can do this to mark internal company procedures or just point out some special detail about the sign-off. If you are a subsystem or branch maintainer, sometimes you need to slightly modify patches you receive in order to merge them, because the code is not exactly the same in your tree and the submitters'. If you stick strictly to rule (c), you should ask the submitter to rediff, but this is a totally counter-productive waste of time and energy. Rule (b) allows you to adjust the code, but then it is very impolite to change one submitter's code and make him endorse your bugs. To solve this problem, it is recommended that you add a line between the last Signed-off-by header and yours, indicating the nature of your changes. While there is nothing mandatory about this, it seems like prepending the description with your mail and/or name, all enclosed in square brackets, is noticeable enough to make it obvious that you are responsible for last-minute changes. Example : Signed-off-by: Random J Developer <random@developer.example.org> [lucky@maintainer.example.org: struct foo moved from foo.c to foo.h] Signed-off-by: Lucky K Maintainer <lucky@maintainer.example.org> This practise is particularly helpful if you maintain a stable branch and want at the same time to credit the author, track changes, merge the fix, and protect the submitter from complaints. Note that under no circumstances can you change the author's identity (the From header), as it is the one which appears in the changelog. Special note to back-porters: It seems to be a common and useful practise to insert an indication of the origin of a patch at the top of the commit message (just after the subject line) to facilitate tracking. For instance, here's what we see in 2.6-stable : Date: Tue May 13 19:10:30 2008 +0000 SCSI: libiscsi regression in 2.6.25: fix nop timer handling commit 4cf1043593db6a337f10e006c23c69e5fc93e722 upstream And here's what appears in 2.4 : Date: Tue May 13 22:12:27 2008 +0200 wireless, airo: waitbusy() won't delay [backport of 2.6 commit b7acbdfbd1f277c1eb23f344f899cfa4cd0bf36a] Whatever the format, this information provides a valuable help to people tracking your trees, and to people trying to trouble-shoot bugs in your tree. 13) When to use Acked-by: and Cc: The Signed-off-by: tag indicates that the signer was involved in the development of the patch, or that he/she was in the patch's delivery path. If a person was not directly involved in the preparation or handling of a patch but wishes to signify and record their approval of it then they can arrange to have an Acked-by: line added to the patch's changelog. Acked-by: is often used by the maintainer of the affected code when that maintainer neither contributed to nor forwarded the patch. Acked-by: is not as formal as Signed-off-by:. It is a record that the acker has at least reviewed the patch and has indicated acceptance. Hence patch mergers will sometimes manually convert an acker's "yep, looks good to me" into an Acked-by:. Acked-by: does not necessarily indicate acknowledgement of the entire patch. For example, if a patch affects multiple subsystems and has an Acked-by: from one subsystem maintainer then this usually indicates acknowledgement of just the part which affects that maintainer's code. Judgement should be used here. When in doubt people should refer to the original discussion in the mailing list archives. If a person has had the opportunity to comment on a patch, but has not provided such comments, you may optionally add a "Cc:" tag to the patch. This is the only tag which might be added without an explicit action by the person it names. This tag documents that potentially interested parties have been included in the discussion 14) Using Reported-by:, Tested-by:, Reviewed-by: and Suggested-by: If this patch fixes a problem reported by somebody else, consider adding a Reported-by: tag to credit the reporter for their contribution. Please note that this tag should not be added without the reporter's permission, especially if the problem was not reported in a public forum. That said, if we diligently credit our bug reporters, they will, hopefully, be inspired to help us again in the future. A Tested-by: tag indicates that the patch has been successfully tested (in some environment) by the person named. This tag informs maintainers that some testing has been performed, provides a means to locate testers for future patches, and ensures credit for the testers. Reviewed-by:, instead, indicates that the patch has been reviewed and found acceptable according to the Reviewer's Statement: Reviewer's statement of oversight By offering my Reviewed-by: tag, I state that: (a) I have carried out a technical review of this patch to evaluate its appropriateness and readiness for inclusion into the mainline kernel. (b) Any problems, concerns, or questions relating to the patch have been communicated back to the submitter. I am satisfied with the submitter's response to my comments. (c) While there may be things that could be improved with this submission, I believe that it is, at this time, (1) a worthwhile modification to the kernel, and (2) free of known issues which would argue against its inclusion. (d) While I have reviewed the patch and believe it to be sound, I do not (unless explicitly stated elsewhere) make any warranties or guarantees that it will achieve its stated purpose or function properly in any given situation. A Reviewed-by tag is a statement of opinion that the patch is an appropriate modification of the kernel without any remaining serious technical issues. Any interested reviewer (who has done the work) can offer a Reviewed-by tag for a patch. This tag serves to give credit to reviewers and to inform maintainers of the degree of review which has been done on the patch. Reviewed-by: tags, when supplied by reviewers known to understand the subject area and to perform thorough reviews, will normally increase the likelihood of your patch getting into the kernel. A Suggested-by: tag indicates that the patch idea is suggested by the person named and ensures credit to the person for the idea. Please note that this tag should not be added without the reporter's permission, especially if the idea was not posted in a public forum. That said, if we diligently credit our idea reporters, they will, hopefully, be inspired to help us again in the future. 15) The canonical patch format The canonical patch subject line is: Subject: [PATCH 001/123] subsystem: summary phrase The canonical patch message body contains the following: - A "from" line specifying the patch author. - An empty line. - The body of the explanation, which will be copied to the permanent changelog to describe this patch. - The "Signed-off-by:" lines, described above, which will also go in the changelog. - A marker line containing simply "---". - Any additional comments not suitable for the changelog. - The actual patch (diff output). The Subject line format makes it very easy to sort the emails alphabetically by subject line - pretty much any email reader will support that - since because the sequence number is zero-padded, the numerical and alphabetic sort is the same. The "subsystem" in the email's Subject should identify which area or subsystem of the kernel is being patched. The "summary phrase" in the email's Subject should concisely describe the patch which that email contains. The "summary phrase" should not be a filename. Do not use the same "summary phrase" for every patch in a whole patch series (where a "patch series" is an ordered sequence of multiple, related patches). Bear in mind that the "summary phrase" of your email becomes a globally-unique identifier for that patch. It propagates all the way into the git changelog. The "summary phrase" may later be used in developer discussions which refer to the patch. People will want to google for the "summary phrase" to read discussion regarding that patch. It will also be the only thing that people may quickly see when, two or three months later, they are going through perhaps thousands of patches using tools such as "gitk" or "git log --oneline". For these reasons, the "summary" must be no more than 70-75 characters, and it must describe both what the patch changes, as well as why the patch might be necessary. It is challenging to be both succinct and descriptive, but that is what a well-written summary should do. The "summary phrase" may be prefixed by tags enclosed in square brackets: "Subject: [PATCH tag] <summary phrase>". The tags are not considered part of the summary phrase, but describe how the patch should be treated. Common tags might include a version descriptor if the multiple versions of the patch have been sent out in response to comments (i.e., "v1, v2, v3"), or "RFC" to indicate a request for comments. If there are four patches in a patch series the individual patches may be numbered like this: 1/4, 2/4, 3/4, 4/4. This assures that developers understand the order in which the patches should be applied and that they have reviewed or applied all of the patches in the patch series. A couple of example Subjects: Subject: [patch 2/5] ext2: improve scalability of bitmap searching Subject: [PATCHv2 001/207] x86: fix eflags tracking The "from" line must be the very first line in the message body, and has the form: From: Original Author <author@example.com> The "from" line specifies who will be credited as the author of the patch in the permanent changelog. If the "from" line is missing, then the "From:" line from the email header will be used to determine the patch author in the changelog. The explanation body will be committed to the permanent source changelog, so should make sense to a competent reader who has long since forgotten the immediate details of the discussion that might have led to this patch. Including symptoms of the failure which the patch addresses (kernel log messages, oops messages, etc.) is especially useful for people who might be searching the commit logs looking for the applicable patch. If a patch fixes a compile failure, it may not be necessary to include _all_ of the compile failures; just enough that it is likely that someone searching for the patch can find it. As in the "summary phrase", it is important to be both succinct as well as descriptive. The "---" marker line serves the essential purpose of marking for patch handling tools where the changelog message ends. One good use for the additional comments after the "---" marker is for a diffstat, to show what files have changed, and the number of inserted and deleted lines per file. A diffstat is especially useful on bigger patches. Other comments relevant only to the moment or the maintainer, not suitable for the permanent changelog, should also go here. A good example of such comments might be "patch changelogs" which describe what has changed between the v1 and v2 version of the patch. If you are going to include a diffstat after the "---" marker, please use diffstat options "-p 1 -w 70" so that filenames are listed from the top of the kernel source tree and don't use too much horizontal space (easily fit in 80 columns, maybe with some indentation). See more details on the proper patch format in the following references. 16) Sending "git pull" requests (from Linus emails) Please write the git repo address and branch name alone on the same line so that I can't even by mistake pull from the wrong branch, and so that a triple-click just selects the whole thing. So the proper format is something along the lines of: "Please pull from git://jdelvare.pck.nerim.net/jdelvare-2.6 i2c-for-linus to get these changes:" so that I don't have to hunt-and-peck for the address and inevitably get it wrong (actually, I've only gotten it wrong a few times, and checking against the diffstat tells me when I get it wrong, but I'm just a lot more comfortable when I don't have to "look for" the right thing to pull, and double-check that I have the right branch-name). Please use "git diff -M --stat --summary" to generate the diffstat: the -M enables rename detection, and the summary enables a summary of new/deleted or renamed files. With rename detection, the statistics are rather different [...] because git will notice that a fair number of the changes are renames. ----------------------------------- SECTION 2 - HINTS, TIPS, AND TRICKS ----------------------------------- This section lists many of the common "rules" associated with code submitted to the kernel. There are always exceptions... but you must have a really good reason for doing so. You could probably call this section Linus Computer Science 101. 1) Read Documentation/CodingStyle Nuff said. If your code deviates too much from this, it is likely to be rejected without further review, and without comment. One significant exception is when moving code from one file to another -- in this case you should not modify the moved code at all in the same patch which moves it. This clearly delineates the act of moving the code and your changes. This greatly aids review of the actual differences and allows tools to better track the history of the code itself. Check your patches with the patch style checker prior to submission (scripts/checkpatch.pl). The style checker should be viewed as a guide not as the final word. If your code looks better with a violation then its probably best left alone. The checker reports at three levels: - ERROR: things that are very likely to be wrong - WARNING: things requiring careful review - CHECK: things requiring thought You should be able to justify all violations that remain in your patch. 2) #ifdefs are ugly Code cluttered with ifdefs is difficult to read and maintain. Don't do it. Instead, put your ifdefs in a header, and conditionally define 'static inline' functions, or macros, which are used in the code. Let the compiler optimize away the "no-op" case. Simple example, of poor code: dev = alloc_etherdev (sizeof(struct funky_private)); if (!dev) return -ENODEV; #ifdef CONFIG_NET_FUNKINESS init_funky_net(dev); #endif Cleaned-up example: (in header) #ifndef CONFIG_NET_FUNKINESS static inline void init_funky_net (struct net_device *d) {} #endif (in the code itself) dev = alloc_etherdev (sizeof(struct funky_private)); if (!dev) return -ENODEV; init_funky_net(dev); 3) 'static inline' is better than a macro Static inline functions are greatly preferred over macros. They provide type safety, have no length limitations, no formatting limitations, and under gcc they are as cheap as macros. Macros should only be used for cases where a static inline is clearly suboptimal [there are a few, isolated cases of this in fast paths], or where it is impossible to use a static inline function [such as string-izing]. 'static inline' is preferred over 'static __inline__', 'extern inline', and 'extern __inline__'. 4) Don't over-design. Don't try to anticipate nebulous future cases which may or may not be useful: "Make it as simple as you can, and no simpler." ---------------------- SECTION 3 - REFERENCES ---------------------- Andrew Morton, "The perfect patch" (tpp). <http://userweb.kernel.org/~akpm/stuff/tpp.txt> Jeff Garzik, "Linux kernel patch submission format". <http://linux.yyz.us/patch-format.html> Greg Kroah-Hartman, "How to piss off a kernel subsystem maintainer". <http://www.kroah.com/log/linux/maintainer.html> <http://www.kroah.com/log/linux/maintainer-02.html> <http://www.kroah.com/log/linux/maintainer-03.html> <http://www.kroah.com/log/linux/maintainer-04.html> <http://www.kroah.com/log/linux/maintainer-05.html> NO!!!! No more huge patch bombs to linux-kernel@vger.kernel.org people! <http://marc.theaimsgroup.com/?l=linux-kernel&m=112112749912944&w=2> Kernel Documentation/CodingStyle: <http://users.sosdg.org/~qiyong/lxr/source/Documentation/CodingStyle> Linus Torvalds's mail on the canonical patch format: <http://lkml.org/lkml/2005/4/7/183> Andi Kleen, "On submitting kernel patches" Some strategies to get difficult or controversial changes in. http://halobates.de/on-submitting-patches.pdf --



Linux Kernel patch submission checklist
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

Here are some basic things that developers should do if they want to see their
kernel patch submissions accepted more quickly.

These are all above and beyond the documentation that is provided in
Documentation/SubmittingPatches and elsewhere regarding submitting Linux
kernel patches.


1: If you use a facility then #include the file that defines/declares
   that facility.  Don't depend on other header files pulling in ones
   that you use.

2: Builds cleanly with applicable or modified CONFIG options =y, =m, and
   =n.  No gcc warnings/errors, no linker warnings/errors.

2b: Passes allnoconfig, allmodconfig

2c: Builds successfully when using O=builddir

3: Builds on multiple CPU architectures by using local cross-compile tools
   or some other build farm.

4: ppc64 is a good architecture for cross-compilation checking because it
   tends to use `unsigned long' for 64-bit quantities.

5: Check your patch for general style as detailed in
   Documentation/CodingStyle.  Check for trivial violations with the
   patch style checker prior to submission (scripts/checkpatch.pl).
   You should be able to justify all violations that remain in
   your patch.

6: Any new or modified CONFIG options don't muck up the config menu.

7: All new Kconfig options have help text.

8: Has been carefully reviewed with respect to relevant Kconfig
   combinations.  This is very hard to get right with testing -- brainpower
   pays off here.

9: Check cleanly with sparse.

10: Use 'make checkstack' and 'make namespacecheck' and fix any problems
    that they find.  Note: checkstack does not point out problems explicitly,
    but any one function that uses more than 512 bytes on the stack is a
    candidate for change.

11: Include kernel-doc to document global kernel APIs.  (Not required for
    static functions, but OK there also.) Use 'make htmldocs' or 'make
    mandocs' to check the kernel-doc and fix any issues.

12: Has been tested with CONFIG_PREEMPT, CONFIG_DEBUG_PREEMPT,
    CONFIG_DEBUG_SLAB, CONFIG_DEBUG_PAGEALLOC, CONFIG_DEBUG_MUTEXES,
    CONFIG_DEBUG_SPINLOCK, CONFIG_DEBUG_ATOMIC_SLEEP, CONFIG_PROVE_RCU
    and CONFIG_DEBUG_OBJECTS_RCU_HEAD all simultaneously enabled.

13: Has been build- and runtime tested with and without CONFIG_SMP and
    CONFIG_PREEMPT.

14: If the patch affects IO/Disk, etc: has been tested with and without
    CONFIG_LBDAF.

15: All codepaths have been exercised with all lockdep features enabled.

16: All new /proc entries are documented under Documentation/

17: All new kernel boot parameters are documented in
    Documentation/kernel-parameters.txt.

18: All new module parameters are documented with MODULE_PARM_DESC()

19: All new userspace interfaces are documented in Documentation/ABI/.
    See Documentation/ABI/README for more information.
    Patches that change userspace interfaces should be CCed to
    linux-api@vger.kernel.org.

20: Check that it all passes `make headers_check'.

21: Has been checked with injection of at least slab and page-allocation
    failures.  See Documentation/fault-injection/.

    If the new code is substantial, addition of subsystem-specific fault
    injection might be appropriate.

22: Newly-added code has been compiled with `gcc -W' (use "make
    EXTRA_CFLAGS=-W").  This will generate lots of noise, but is good for
    finding bugs like "warning: comparison between signed and unsigned".

23: Tested after it has been merged into the -mm patchset to make sure
    that it still works with all of the other queued patches and various
    changes in the VM, VFS, and other subsystems.

24: All memory barriers {e.g., barrier(), rmb(), wmb()} need a comment in the
    source code that explains the logic of what they are doing and why.

25: If any ioctl's are added by the patch, then also update
    Documentation/ioctl/ioctl-number.txt.

26: If your modified source code depends on or uses any of the kernel
    APIs or features that are related to the following kconfig symbols,
    then test multiple builds with the related kconfig symbols disabled
    and/or =m (if that option is available) [not all of these at the
    same time, just various/random combinations of them]:

    CONFIG_SMP, CONFIG_SYSFS, CONFIG_PROC_FS, CONFIG_INPUT, CONFIG_PCI,
    CONFIG_BLOCK, CONFIG_PM, CONFIG_MAGIC_SYSRQ,
    CONFIG_NET, CONFIG_INET=n (but latter with CONFIG_NET=y)






Linux kernel coding style This is a short document describing the preferred coding style for the linux kernel. Coding style is very personal, and I won't _force_ my views on anybody, but this is what goes for anything that I have to be able to maintain, and I'd prefer it for most other things too. Please at least consider the points made here. First off, I'd suggest printing out a copy of the GNU coding standards, and NOT read it. Burn them, it's a great symbolic gesture. Anyway, here goes: Chapter 1: Indentation Tabs are 8 characters, and thus indentations are also 8 characters. There are heretic movements that try to make indentations 4 (or even 2!) characters deep, and that is akin to trying to define the value of PI to be 3. Rationale: The whole idea behind indentation is to clearly define where a block of control starts and ends. Especially when you've been looking at your screen for 20 straight hours, you'll find it a lot easier to see how the indentation works if you have large indentations. Now, some people will claim that having 8-character indentations makes the code move too far to the right, and makes it hard to read on a 80-character terminal screen. The answer to that is that if you need more than 3 levels of indentation, you're screwed anyway, and should fix your program. In short, 8-char indents make things easier to read, and have the added benefit of warning you when you're nesting your functions too deep. Heed that warning. The preferred way to ease multiple indentation levels in a switch statement is to align the "switch" and its subordinate "case" labels in the same column instead of "double-indenting" the "case" labels. E.g.: switch (suffix) { case 'G': case 'g': mem <<= 30; break; case 'M': case 'm': mem <<= 20; break; case 'K': case 'k': mem <<= 10; /* fall through */ default: break; } Don't put multiple statements on a single line unless you have something to hide: if (condition) do_this; do_something_everytime; Don't put multiple assignments on a single line either. Kernel coding style is super simple. Avoid tricky expressions. Outside of comments, documentation and except in Kconfig, spaces are never used for indentation, and the above example is deliberately broken. Get a decent editor and don't leave whitespace at the end of lines. Chapter 2: Breaking long lines and strings Coding style is all about readability and maintainability using commonly available tools. The limit on the length of lines is 80 columns and this is a strongly preferred limit. Statements longer than 80 columns will be broken into sensible chunks, unless exceeding 80 columns significantly increases readability and does not hide information. Descendants are always substantially shorter than the parent and are placed substantially to the right. The same applies to function headers with a long argument list. However, never break user-visible strings such as printk messages, because that breaks the ability to grep for them. Chapter 3: Placing Braces and Spaces The other issue that always comes up in C styling is the placement of braces. Unlike the indent size, there are few technical reasons to choose one placement strategy over the other, but the preferred way, as shown to us by the prophets Kernighan and Ritchie, is to put the opening brace last on the line, and put the closing brace first, thusly: if (x is true) { we do y } This applies to all non-function statement blocks (if, switch, for, while, do). E.g.: switch (action) { case KOBJ_ADD: return "add"; case KOBJ_REMOVE: return "remove"; case KOBJ_CHANGE: return "change"; default: return NULL; } However, there is one special case, namely functions: they have the opening brace at the beginning of the next line, thus: int function(int x) { body of function } Heretic people all over the world have claimed that this inconsistency is ... well ... inconsistent, but all right-thinking people know that (a) K&R are _right_ and (b) K&R are right. Besides, functions are special anyway (you can't nest them in C). Note that the closing brace is empty on a line of its own, _except_ in the cases where it is followed by a continuation of the same statement, ie a "while" in a do-statement or an "else" in an if-statement, like this: do { body of do-loop } while (condition); and if (x == y) { .. } else if (x > y) { ... } else { .... } Rationale: K&R. Also, note that this brace-placement also minimizes the number of empty (or almost empty) lines, without any loss of readability. Thus, as the supply of new-lines on your screen is not a renewable resource (think 25-line terminal screens here), you have more empty lines to put comments on. Do not unnecessarily use braces where a single statement will do. if (condition) action(); and if (condition) do_this(); else do_that(); This does not apply if only one branch of a conditional statement is a single statement; in the latter case use braces in both branches: if (condition) { do_this(); do_that(); } else { otherwise(); } 3.1: Spaces Linux kernel style for use of spaces depends (mostly) on function-versus-keyword usage. Use a space after (most) keywords. The notable exceptions are sizeof, typeof, alignof, and __attribute__, which look somewhat like functions (and are usually used with parentheses in Linux, although they are not required in the language, as in: "sizeof info" after "struct fileinfo info;" is declared). So use a space after these keywords: if, switch, case, for, do, while but not with sizeof, typeof, alignof, or __attribute__. E.g., s = sizeof(struct file); Do not add spaces around (inside) parenthesized expressions. This example is *bad*: s = sizeof( struct file ); When declaring pointer data or a function that returns a pointer type, the preferred use of '*' is adjacent to the data name or function name and not adjacent to the type name. Examples: char *linux_banner; unsigned long long memparse(char *ptr, char **retptr); char *match_strdup(substring_t *s); Use one space around (on each side of) most binary and ternary operators, such as any of these: = + - < > * / % | & ^ <= >= == != ? : but no space after unary operators: & * + - ~ ! sizeof typeof alignof __attribute__ defined no space before the postfix increment & decrement unary operators: ++ -- no space after the prefix increment & decrement unary operators: ++ -- and no space around the '.' and "->" structure member operators. Do not leave trailing whitespace at the ends of lines. Some editors with "smart" indentation will insert whitespace at the beginning of new lines as appropriate, so you can start typing the next line of code right away. However, some such editors do not remove the whitespace if you end up not putting a line of code there, such as if you leave a blank line. As a result, you end up with lines containing trailing whitespace. Git will warn you about patches that introduce trailing whitespace, and can optionally strip the trailing whitespace for you; however, if applying a series of patches, this may make later patches in the series fail by changing their context lines. Chapter 4: Naming C is a Spartan language, and so should your naming be. Unlike Modula-2 and Pascal programmers, C programmers do not use cute names like ThisVariableIsATemporaryCounter. A C programmer would call that variable "tmp", which is much easier to write, and not the least more difficult to understand. HOWEVER, while mixed-case names are frowned upon, descriptive names for global variables are a must. To call a global function "foo" is a shooting offense. GLOBAL variables (to be used only if you _really_ need them) need to have descriptive names, as do global functions. If you have a function that counts the number of active users, you should call that "count_active_users()" or similar, you should _not_ call it "cntusr()". Encoding the type of a function into the name (so-called Hungarian notation) is brain damaged - the compiler knows the types anyway and can check those, and it only confuses the programmer. No wonder MicroSoft makes buggy programs. LOCAL variable names should be short, and to the point. If you have some random integer loop counter, it should probably be called "i". Calling it "loop_counter" is non-productive, if there is no chance of it being mis-understood. Similarly, "tmp" can be just about any type of variable that is used to hold a temporary value. If you are afraid to mix up your local variable names, you have another problem, which is called the function-growth-hormone-imbalance syndrome. See chapter 6 (Functions). Chapter 5: Typedefs Please don't use things like "vps_t". It's a _mistake_ to use typedef for structures and pointers. When you see a vps_t a; in the source, what does it mean? In contrast, if it says struct virtual_container *a; you can actually tell what "a" is. Lots of people think that typedefs "help readability". Not so. They are useful only for: (a) totally opaque objects (where the typedef is actively used to _hide_ what the object is). Example: "pte_t" etc. opaque objects that you can only access using the proper accessor functions. NOTE! Opaqueness and "accessor functions" are not good in themselves. The reason we have them for things like pte_t etc. is that there really is absolutely _zero_ portably accessible information there. (b) Clear integer types, where the abstraction _helps_ avoid confusion whether it is "int" or "long". u8/u16/u32 are perfectly fine typedefs, although they fit into category (d) better than here. NOTE! Again - there needs to be a _reason_ for this. If something is "unsigned long", then there's no reason to do typedef unsigned long myflags_t; but if there is a clear reason for why it under certain circumstances might be an "unsigned int" and under other configurations might be "unsigned long", then by all means go ahead and use a typedef. (c) when you use sparse to literally create a _new_ type for type-checking. (d) New types which are identical to standard C99 types, in certain exceptional circumstances. Although it would only take a short amount of time for the eyes and brain to become accustomed to the standard types like 'uint32_t', some people object to their use anyway. Therefore, the Linux-specific 'u8/u16/u32/u64' types and their signed equivalents which are identical to standard types are permitted -- although they are not mandatory in new code of your own. When editing existing code which already uses one or the other set of types, you should conform to the existing choices in that code. (e) Types safe for use in userspace. In certain structures which are visible to userspace, we cannot require C99 types and cannot use the 'u32' form above. Thus, we use __u32 and similar types in all structures which are shared with userspace. Maybe there are other cases too, but the rule should basically be to NEVER EVER use a typedef unless you can clearly match one of those rules. In general, a pointer, or a struct that has elements that can reasonably be directly accessed should _never_ be a typedef. Chapter 6: Functions Functions should be short and sweet, and do just one thing. They should fit on one or two screenfuls of text (the ISO/ANSI screen size is 80x24, as we all know), and do one thing and do that well. The maximum length of a function is inversely proportional to the complexity and indentation level of that function. So, if you have a conceptually simple function that is just one long (but simple) case-statement, where you have to do lots of small things for a lot of different cases, it's OK to have a longer function. However, if you have a complex function, and you suspect that a less-than-gifted first-year high-school student might not even understand what the function is all about, you should adhere to the maximum limits all the more closely. Use helper functions with descriptive names (you can ask the compiler to in-line them if you think it's performance-critical, and it will probably do a better job of it than you would have done). Another measure of the function is the number of local variables. They shouldn't exceed 5-10, or you're doing something wrong. Re-think the function, and split it into smaller pieces. A human brain can generally easily keep track of about 7 different things, anything more and it gets confused. You know you're brilliant, but maybe you'd like to understand what you did 2 weeks from now. In source files, separate functions with one blank line. If the function is exported, the EXPORT* macro for it should follow immediately after the closing function brace line. E.g.: int system_is_up(void) { return system_state == SYSTEM_RUNNING; } EXPORT_SYMBOL(system_is_up); In function prototypes, include parameter names with their data types. Although this is not required by the C language, it is preferred in Linux because it is a simple way to add valuable information for the reader. Chapter 7: Centralized exiting of functions Albeit deprecated by some people, the equivalent of the goto statement is used frequently by compilers in form of the unconditional jump instruction. The goto statement comes in handy when a function exits from multiple locations and some common work such as cleanup has to be done. If there is no cleanup needed then just return directly. The rationale is: - unconditional statements are easier to understand and follow - nesting is reduced - errors by not updating individual exit points when making modifications are prevented - saves the compiler work to optimize redundant code away ;) int fun(int a) { int result = 0; char *buffer = kmalloc(SIZE); if (buffer == NULL) return -ENOMEM; if (condition1) { while (loop1) { ... } result = 1; goto out; } ... out: kfree(buffer); return result; } Chapter 8: Commenting Comments are good, but there is also a danger of over-commenting. NEVER try to explain HOW your code works in a comment: it's much better to write the code so that the _working_ is obvious, and it's a waste of time to explain badly written code. Generally, you want your comments to tell WHAT your code does, not HOW. Also, try to avoid putting comments inside a function body: if the function is so complex that you need to separately comment parts of it, you should probably go back to chapter 6 for a while. You can make small comments to note or warn about something particularly clever (or ugly), but try to avoid excess. Instead, put the comments at the head of the function, telling people what it does, and possibly WHY it does it. When commenting the kernel API functions, please use the kernel-doc format. See the files Documentation/kernel-doc-nano-HOWTO.txt and scripts/kernel-doc for details. Linux style for comments is the C89 "/* ... */" style. Don't use C99-style "// ..." comments. The preferred style for long (multi-line) comments is: /* * This is the preferred style for multi-line * comments in the Linux kernel source code. * Please use it consistently. * * Description: A column of asterisks on the left side, * with beginning and ending almost-blank lines. */ For files in net/ and drivers/net/ the preferred style for long (multi-line) comments is a little different. /* The preferred comment style for files in net/ and drivers/net * looks like this. * * It is nearly the same as the generally preferred comment style, * but there is no initial almost-blank line. */ It's also important to comment data, whether they are basic types or derived types. To this end, use just one data declaration per line (no commas for multiple data declarations). This leaves you room for a small comment on each item, explaining its use. Chapter 9: You've made a mess of it That's OK, we all do. You've probably been told by your long-time Unix user helper that "GNU emacs" automatically formats the C sources for you, and you've noticed that yes, it does do that, but the defaults it uses are less than desirable (in fact, they are worse than random typing - an infinite number of monkeys typing into GNU emacs would never make a good program). So, you can either get rid of GNU emacs, or change it to use saner values. To do the latter, you can stick the following in your .emacs file: (defun c-lineup-arglist-tabs-only (ignored) "Line up argument lists by tabs, not spaces" (let* ((anchor (c-langelem-pos c-syntactic-element)) (column (c-langelem-2nd-pos c-syntactic-element)) (offset (- (1+ column) anchor)) (steps (floor offset c-basic-offset))) (* (max steps 1) c-basic-offset))) (add-hook 'c-mode-common-hook (lambda () ;; Add kernel style (c-add-style "linux-tabs-only" '("linux" (c-offsets-alist (arglist-cont-nonempty c-lineup-gcc-asm-reg c-lineup-arglist-tabs-only)))))) (add-hook 'c-mode-hook (lambda () (let ((filename (buffer-file-name))) ;; Enable kernel mode for the appropriate files (when (and filename (string-match (expand-file-name "~/src/linux-trees") filename)) (setq indent-tabs-mode t) (c-set-style "linux-tabs-only"))))) This will make emacs go better with the kernel coding style for C files below ~/src/linux-trees. But even if you fail in getting emacs to do sane formatting, not everything is lost: use "indent". Now, again, GNU indent has the same brain-dead settings that GNU emacs has, which is why you need to give it a few command line options. However, that's not too bad, because even the makers of GNU indent recognize the authority of K&R (the GNU people aren't evil, they are just severely misguided in this matter), so you just give indent the options "-kr -i8" (stands for "K&R, 8 character indents"), or use "scripts/Lindent", which indents in the latest style. "indent" has a lot of options, and especially when it comes to comment re-formatting you may want to take a look at the man page. But remember: "indent" is not a fix for bad programming. Chapter 10: Kconfig configuration files For all of the Kconfig* configuration files throughout the source tree, the indentation is somewhat different. Lines under a "config" definition are indented with one tab, while help text is indented an additional two spaces. Example: config AUDIT bool "Auditing support" depends on NET help Enable auditing infrastructure that can be used with another kernel subsystem, such as SELinux (which requires this for logging of avc messages output). Does not do system-call auditing without CONFIG_AUDITSYSCALL. Seriously dangerous features (such as write support for certain filesystems) should advertise this prominently in their prompt string: config ADFS_FS_RW bool "ADFS write support (DANGEROUS)" depends on ADFS_FS ... For full documentation on the configuration files, see the file Documentation/kbuild/kconfig-language.txt. Chapter 11: Data structures Data structures that have visibility outside the single-threaded environment they are created and destroyed in should always have reference counts. In the kernel, garbage collection doesn't exist (and outside the kernel garbage collection is slow and inefficient), which means that you absolutely _have_ to reference count all your uses. Reference counting means that you can avoid locking, and allows multiple users to have access to the data structure in parallel - and not having to worry about the structure suddenly going away from under them just because they slept or did something else for a while. Note that locking is _not_ a replacement for reference counting. Locking is used to keep data structures coherent, while reference counting is a memory management technique. Usually both are needed, and they are not to be confused with each other. Many data structures can indeed have two levels of reference counting, when there are users of different "classes". The subclass count counts the number of subclass users, and decrements the global count just once when the subclass count goes to zero. Examples of this kind of "multi-level-reference-counting" can be found in memory management ("struct mm_struct": mm_users and mm_count), and in filesystem code ("struct super_block": s_count and s_active). Remember: if another thread can find your data structure, and you don't have a reference count on it, you almost certainly have a bug. Chapter 12: Macros, Enums and RTL Names of macros defining constants and labels in enums are capitalized. #define CONSTANT 0x12345 Enums are preferred when defining several related constants. CAPITALIZED macro names are appreciated but macros resembling functions may be named in lower case. Generally, inline functions are preferable to macros resembling functions. Macros with multiple statements should be enclosed in a do - while block: #define macrofun(a, b, c) \ do { \ if (a == 5) \ do_this(b, c); \ } while (0) Things to avoid when using macros: 1) macros that affect control flow: #define FOO(x) \ do { \ if (blah(x) < 0) \ return -EBUGGERED; \ } while(0) is a _very_ bad idea. It looks like a function call but exits the "calling" function; don't break the internal parsers of those who will read the code. 2) macros that depend on having a local variable with a magic name: #define FOO(val) bar(index, val) might look like a good thing, but it's confusing as hell when one reads the code and it's prone to breakage from seemingly innocent changes. 3) macros with arguments that are used as l-values: FOO(x) = y; will bite you if somebody e.g. turns FOO into an inline function. 4) forgetting about precedence: macros defining constants using expressions must enclose the expression in parentheses. Beware of similar issues with macros using parameters. #define CONSTANT 0x4000 #define CONSTEXP (CONSTANT | 3) The cpp manual deals with macros exhaustively. The gcc internals manual also covers RTL which is used frequently with assembly language in the kernel. Chapter 13: Printing kernel messages Kernel developers like to be seen as literate. Do mind the spelling of kernel messages to make a good impression. Do not use crippled words like "dont"; use "do not" or "don't" instead. Make the messages concise, clear, and unambiguous. Kernel messages do not have to be terminated with a period. Printing numbers in parentheses (%d) adds no value and should be avoided. There are a number of driver model diagnostic macros in <linux/device.h> which you should use to make sure messages are matched to the right device and driver, and are tagged with the right level: dev_err(), dev_warn(), dev_info(), and so forth. For messages that aren't associated with a particular device, <linux/printk.h> defines pr_debug() and pr_info(). Coming up with good debugging messages can be quite a challenge; and once you have them, they can be a huge help for remote troubleshooting. Such messages should be compiled out when the DEBUG symbol is not defined (that is, by default they are not included). When you use dev_dbg() or pr_debug(), that's automatic. Many subsystems have Kconfig options to turn on -DDEBUG. A related convention uses VERBOSE_DEBUG to add dev_vdbg() messages to the ones already enabled by DEBUG. Chapter 14: Allocating memory The kernel provides the following general purpose memory allocators: kmalloc(), kzalloc(), kmalloc_array(), kcalloc(), vmalloc(), and vzalloc(). Please refer to the API documentation for further information about them. The preferred form for passing a size of a struct is the following: p = kmalloc(sizeof(*p), ...); The alternative form where struct name is spelled out hurts readability and introduces an opportunity for a bug when the pointer variable type is changed but the corresponding sizeof that is passed to a memory allocator is not. Casting the return value which is a void pointer is redundant. The conversion from void pointer to any other pointer type is guaranteed by the C programming language. The preferred form for allocating an array is the following: p = kmalloc_array(n, sizeof(...), ...); The preferred form for allocating a zeroed array is the following: p = kcalloc(n, sizeof(...), ...); Both forms check for overflow on the allocation size n * sizeof(...), and return NULL if that occurred. Chapter 15: The inline disease There appears to be a common misperception that gcc has a magic "make me faster" speedup option called "inline". While the use of inlines can be appropriate (for example as a means of replacing macros, see Chapter 12), it very often is not. Abundant use of the inline keyword leads to a much bigger kernel, which in turn slows the system as a whole down, due to a bigger icache footprint for the CPU and simply because there is less memory available for the pagecache. Just think about it; a pagecache miss causes a disk seek, which easily takes 5 milliseconds. There are a LOT of cpu cycles that can go into these 5 milliseconds. A reasonable rule of thumb is to not put inline at functions that have more than 3 lines of code in them. An exception to this rule are the cases where a parameter is known to be a compiletime constant, and as a result of this constantness you *know* the compiler will be able to optimize most of your function away at compile time. For a good example of this later case, see the kmalloc() inline function. Often people argue that adding inline to functions that are static and used only once is always a win since there is no space tradeoff. While this is technically correct, gcc is capable of inlining these automatically without help, and the maintenance issue of removing the inline when a second user appears outweighs the potential value of the hint that tells gcc to do something it would have done anyway. Chapter 16: Function return values and names Functions can return values of many different kinds, and one of the most common is a value indicating whether the function succeeded or failed. Such a value can be represented as an error-code integer (-Exxx = failure, 0 = success) or a "succeeded" boolean (0 = failure, non-zero = success). Mixing up these two sorts of representations is a fertile source of difficult-to-find bugs. If the C language included a strong distinction between integers and booleans then the compiler would find these mistakes for us... but it doesn't. To help prevent such bugs, always follow this convention: If the name of a function is an action or an imperative command, the function should return an error-code integer. If the name is a predicate, the function should return a "succeeded" boolean. For example, "add work" is a command, and the add_work() function returns 0 for success or -EBUSY for failure. In the same way, "PCI device present" is a predicate, and the pci_dev_present() function returns 1 if it succeeds in finding a matching device or 0 if it doesn't. All EXPORTed functions must respect this convention, and so should all public functions. Private (static) functions need not, but it is recommended that they do. Functions whose return value is the actual result of a computation, rather than an indication of whether the computation succeeded, are not subject to this rule. Generally they indicate failure by returning some out-of-range result. Typical examples would be functions that return pointers; they use NULL or the ERR_PTR mechanism to report failure. Chapter 17: Don't re-invent the kernel macros The header file include/linux/kernel.h contains a number of macros that you should use, rather than explicitly coding some variant of them yourself. For example, if you need to calculate the length of an array, take advantage of the macro #define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0])) Similarly, if you need to calculate the size of some structure member, use #define FIELD_SIZEOF(t, f) (sizeof(((t*)0)->f)) There are also min() and max() macros that do strict type checking if you need them. Feel free to peruse that header file to see what else is already defined that you shouldn't reproduce in your code. Chapter 18: Editor modelines and other cruft Some editors can interpret configuration information embedded in source files, indicated with special markers. For example, emacs interprets lines marked like this: -*- mode: c -*- Or like this: /* Local Variables: compile-command: "gcc -DMAGIC_DEBUG_FLAG foo.c" End: */ Vim interprets markers that look like this: /* vim:set sw=8 noet */ Do not include any of these in source files. People have their own personal editor configurations, and your source files should not override them. This includes markers for indentation and mode configuration. People may use their own custom mode, or may have some other magic method for making indentation work correctly. Chapter 19: Inline assembly In architecture-specific code, you may need to use inline assembly to interface with CPU or platform functionality. Don't hesitate to do so when necessary. However, don't use inline assembly gratuitously when C can do the job. You can and should poke hardware from C when possible. Consider writing simple helper functions that wrap common bits of inline assembly, rather than repeatedly writing them with slight variations. Remember that inline assembly can use C parameters. Large, non-trivial assembly functions should go in .S files, with corresponding C prototypes defined in C header files. The C prototypes for assembly functions should use "asmlinkage". You may need to mark your asm statement as volatile, to prevent GCC from removing it if GCC doesn't notice any side effects. You don't always need to do so, though, and doing so unnecessarily can limit optimization. When writing a single inline assembly statement containing multiple instructions, put each instruction on a separate line in a separate quoted string, and end each string except the last with \n\t to properly indent the next instruction in the assembly output: asm ("magic %reg1, #42\n\t" "more_magic %reg2, %reg3" : /* outputs */ : /* inputs */ : /* clobbers */); Appendix I: References The C Programming Language, Second Edition by Brian W. Kernighan and Dennis M. Ritchie. Prentice Hall, Inc., 1988. ISBN 0-13-110362-8 (paperback), 0-13-110370-9 (hardback). URL: http://cm.bell-labs.com/cm/cs/cbook/ The Practice of Programming by Brian W. Kernighan and Rob Pike. Addison-Wesley, Inc., 1999. ISBN 0-201-61586-X. URL: http://cm.bell-labs.com/cm/cs/tpop/ GNU manuals - where in compliance with K&R and this text - for cpp, gcc, gcc internals and indent, all available from http://www.gnu.org/manual/ WG14 is the international standardization working group for the programming language C, URL: http://www.open-std.org/JTC1/SC22/WG14/ Kernel CodingStyle, by greg@kroah.com at OLS 2002: http://www.kroah.com/linux/talks/ols_2002_kernel_codingstyle_talk/html/

 

posted @ 2014-02-10 21:14  baihuahua  阅读(455)  评论(0编辑  收藏  举报