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	Applying Patches To The Linux Kernel
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	------------------------------------
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	Original by: Jesper Juhl, August 2005
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	Last update: 2006-01-05
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A frequently asked question on the Linux Kernel Mailing List is how to apply
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a patch to the kernel or, more specifically, what base kernel a patch for
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one of the many trees/branches should be applied to. Hopefully this document
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will explain this to you.
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In addition to explaining how to apply and revert patches, a brief
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description of the different kernel trees (and examples of how to apply
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their specific patches) is also provided.
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What is a patch?
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---
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 A patch is a small text document containing a delta of changes between two
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different versions of a source tree. Patches are created with the `diff'
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program.
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To correctly apply a patch you need to know what base it was generated from
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and what new version the patch will change the source tree into. These
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should both be present in the patch file metadata or be possible to deduce
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from the filename.
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How do I apply or revert a patch?
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---
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 You apply a patch with the `patch' program. The patch program reads a diff
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(or patch) file and makes the changes to the source tree described in it.
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Patches for the Linux kernel are generated relative to the parent directory
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holding the kernel source dir.
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This means that paths to files inside the patch file contain the name of the
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kernel source directories it was generated against (or some other directory
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names like "a/" and "b/").
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Since this is unlikely to match the name of the kernel source dir on your
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local machine (but is often useful info to see what version an otherwise
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unlabeled patch was generated against) you should change into your kernel
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source directory and then strip the first element of the path from filenames
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in the patch file when applying it (the -p1 argument to `patch' does this).
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To revert a previously applied patch, use the -R argument to patch.
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So, if you applied a patch like this:
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	patch -p1 < ../patch-x.y.z
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You can revert (undo) it like this:
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	patch -R -p1 < ../patch-x.y.z
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How do I feed a patch/diff file to `patch'?
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---
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 This (as usual with Linux and other UNIX like operating systems) can be
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done in several different ways.
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In all the examples below I feed the file (in uncompressed form) to patch
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via stdin using the following syntax:
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	patch -p1 < path/to/patch-x.y.z
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If you just want to be able to follow the examples below and don't want to
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know of more than one way to use patch, then you can stop reading this
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section here.
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Patch can also get the name of the file to use via the -i argument, like
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this:
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	patch -p1 -i path/to/patch-x.y.z
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If your patch file is compressed with gzip or bzip2 and you don't want to
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uncompress it before applying it, then you can feed it to patch like this
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instead:
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	zcat path/to/patch-x.y.z.gz | patch -p1
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	bzcat path/to/patch-x.y.z.bz2 | patch -p1
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If you wish to uncompress the patch file by hand first before applying it
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(what I assume you've done in the examples below), then you simply run
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gunzip or bunzip2 on the file -- like this:
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	gunzip patch-x.y.z.gz
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	bunzip2 patch-x.y.z.bz2
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Which will leave you with a plain text patch-x.y.z file that you can feed to
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patch via stdin or the -i argument, as you prefer.
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A few other nice arguments for patch are -s which causes patch to be silent
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except for errors which is nice to prevent errors from scrolling out of the
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screen too fast, and --dry-run which causes patch to just print a listing of
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what would happen, but doesn't actually make any changes. Finally --verbose
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tells patch to print more information about the work being done.
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Common errors when patching
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---
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 When patch applies a patch file it attempts to verify the sanity of the
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file in different ways.
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Checking that the file looks like a valid patch file & checking the code
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around the bits being modified matches the context provided in the patch are
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just two of the basic sanity checks patch does.
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If patch encounters something that doesn't look quite right it has two
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options. It can either refuse to apply the changes and abort or it can try
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to find a way to make the patch apply with a few minor changes.
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One example of something that's not 'quite right' that patch will attempt to
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fix up is if all the context matches, the lines being changed match, but the
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line numbers are different. This can happen, for example, if the patch makes
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a change in the middle of the file but for some reasons a few lines have
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been added or removed near the beginning of the file. In that case
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everything looks good it has just moved up or down a bit, and patch will
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usually adjust the line numbers and apply the patch.
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Whenever patch applies a patch that it had to modify a bit to make it fit
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it'll tell you about it by saying the patch applied with 'fuzz'.
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You should be wary of such changes since even though patch probably got it
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right it doesn't /always/ get it right, and the result will sometimes be
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wrong.
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When patch encounters a change that it can't fix up with fuzz it rejects it
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outright and leaves a file with a .rej extension (a reject file). You can
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read this file to see exactly what change couldn't be applied, so you can
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go fix it up by hand if you wish.
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If you don't have any third-party patches applied to your kernel source, but
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only patches from kernel.org and you apply the patches in the correct order,
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and have made no modifications yourself to the source files, then you should
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never see a fuzz or reject message from patch. If you do see such messages
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anyway, then there's a high risk that either your local source tree or the
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patch file is corrupted in some way. In that case you should probably try
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re-downloading the patch and if things are still not OK then you'd be advised
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to start with a fresh tree downloaded in full from kernel.org.
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Let's look a bit more at some of the messages patch can produce.
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If patch stops and presents a "File to patch:" prompt, then patch could not
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find a file to be patched. Most likely you forgot to specify -p1 or you are
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in the wrong directory. Less often, you'll find patches that need to be
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applied with -p0 instead of -p1 (reading the patch file should reveal if
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this is the case -- if so, then this is an error by the person who created
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the patch but is not fatal).
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If you get "Hunk #2 succeeded at 1887 with fuzz 2 (offset 7 lines)." or a
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message similar to that, then it means that patch had to adjust the location
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of the change (in this example it needed to move 7 lines from where it
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expected to make the change to make it fit).
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The resulting file may or may not be OK, depending on the reason the file
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was different than expected.
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This often happens if you try to apply a patch that was generated against a
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different kernel version than the one you are trying to patch.
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If you get a message like "Hunk #3 FAILED at 2387.", then it means that the
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patch could not be applied correctly and the patch program was unable to
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fuzz its way through. This will generate a .rej file with the change that
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caused the patch to fail and also a .orig file showing you the original
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content that couldn't be changed.
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If you get "Reversed (or previously applied) patch detected!  Assume -R? [n]"
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then patch detected that the change contained in the patch seems to have
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already been made.
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If you actually did apply this patch previously and you just re-applied it
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in error, then just say [n]o and abort this patch. If you applied this patch
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previously and actually intended to revert it, but forgot to specify -R,
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then you can say [y]es here to make patch revert it for you.
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This can also happen if the creator of the patch reversed the source and
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destination directories when creating the patch, and in that case reverting
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the patch will in fact apply it.
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A message similar to "patch: **** unexpected end of file in patch" or "patch
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unexpectedly ends in middle of line" means that patch could make no sense of
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the file you fed to it. Either your download is broken, you tried to feed
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patch a compressed patch file without uncompressing it first, or the patch
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file that you are using has been mangled by a mail client or mail transfer
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agent along the way somewhere, e.g., by splitting a long line into two lines.
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Often these warnings can easily be fixed by joining (concatenating) the
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two lines that had been split.
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As I already mentioned above, these errors should never happen if you apply
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a patch from kernel.org to the correct version of an unmodified source tree.
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So if you get these errors with kernel.org patches then you should probably
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assume that either your patch file or your tree is broken and I'd advise you
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to start over with a fresh download of a full kernel tree and the patch you
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wish to apply.
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Are there any alternatives to `patch'?
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---
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 Yes there are alternatives.
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 You can use the `interdiff' program (http://cyberelk.net/tim/patchutils/) to
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generate a patch representing the differences between two patches and then
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apply the result.
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This will let you move from something like 2.6.12.2 to 2.6.12.3 in a single
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step. The -z flag to interdiff will even let you feed it patches in gzip or
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bzip2 compressed form directly without the use of zcat or bzcat or manual
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decompression.
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Here's how you'd go from 2.6.12.2 to 2.6.12.3 in a single step:
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	interdiff -z ../patch-2.6.12.2.bz2 ../patch-2.6.12.3.gz | patch -p1
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Although interdiff may save you a step or two you are generally advised to
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do the additional steps since interdiff can get things wrong in some cases.
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 Another alternative is `ketchup', which is a python script for automatic
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downloading and applying of patches (http://www.selenic.com/ketchup/).
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 Other nice tools are diffstat, which shows a summary of changes made by a
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patch; lsdiff, which displays a short listing of affected files in a patch
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file, along with (optionally) the line numbers of the start of each patch;
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and grepdiff, which displays a list of the files modified by a patch where
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the patch contains a given regular expression.
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Where can I download the patches?
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---
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 The patches are available at http://kernel.org/
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Most recent patches are linked from the front page, but they also have
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specific homes.
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The 2.6.x.y (-stable) and 2.6.x patches live at
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 ftp://ftp.kernel.org/pub/linux/kernel/v2.6/
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The -rc patches live at
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 ftp://ftp.kernel.org/pub/linux/kernel/v2.6/testing/
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The -git patches live at
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 ftp://ftp.kernel.org/pub/linux/kernel/v2.6/snapshots/
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The -mm kernels live at
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 ftp://ftp.kernel.org/pub/linux/kernel/people/akpm/patches/2.6/
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In place of ftp.kernel.org you can use ftp.cc.kernel.org, where cc is a
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country code. This way you'll be downloading from a mirror site that's most
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likely geographically closer to you, resulting in faster downloads for you,
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less bandwidth used globally and less load on the main kernel.org servers --
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these are good things, so do use mirrors when possible.
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The 2.6.x kernels
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---
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 These are the base stable releases released by Linus. The highest numbered
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release is the most recent.
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If regressions or other serious flaws are found, then a -stable fix patch
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will be released (see below) on top of this base. Once a new 2.6.x base
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kernel is released, a patch is made available that is a delta between the
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previous 2.6.x kernel and the new one.
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To apply a patch moving from 2.6.11 to 2.6.12, you'd do the following (note
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that such patches do *NOT* apply on top of 2.6.x.y kernels but on top of the
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base 2.6.x kernel -- if you need to move from 2.6.x.y to 2.6.x+1 you need to
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first revert the 2.6.x.y patch).
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Here are some examples:
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# moving from 2.6.11 to 2.6.12
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$ cd ~/linux-2.6.11			# change to kernel source dir
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$ patch -p1 < ../patch-2.6.12		# apply the 2.6.12 patch
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$ cd ..
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$ mv linux-2.6.11 linux-2.6.12		# rename source dir
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# moving from 2.6.11.1 to 2.6.12
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$ cd ~/linux-2.6.11.1			# change to kernel source dir
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$ patch -p1 -R < ../patch-2.6.11.1	# revert the 2.6.11.1 patch
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					# source dir is now 2.6.11
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$ patch -p1 < ../patch-2.6.12		# apply new 2.6.12 patch
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$ cd ..
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$ mv linux-2.6.11.1 linux-2.6.12		# rename source dir
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The 2.6.x.y kernels
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---
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 Kernels with 4-digit versions are -stable kernels. They contain small(ish)
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critical fixes for security problems or significant regressions discovered
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in a given 2.6.x kernel.
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This is the recommended branch for users who want the most recent stable
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kernel and are not interested in helping test development/experimental
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versions.
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If no 2.6.x.y kernel is available, then the highest numbered 2.6.x kernel is
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the current stable kernel.
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 note: the -stable team usually do make incremental patches available as well
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 as patches against the latest mainline release, but I only cover the
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 non-incremental ones below. The incremental ones can be found at
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 ftp://ftp.kernel.org/pub/linux/kernel/v2.6/incr/
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These patches are not incremental, meaning that for example the 2.6.12.3
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patch does not apply on top of the 2.6.12.2 kernel source, but rather on top
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of the base 2.6.12 kernel source .
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So, in order to apply the 2.6.12.3 patch to your existing 2.6.12.2 kernel
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source you have to first back out the 2.6.12.2 patch (so you are left with a
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base 2.6.12 kernel source) and then apply the new 2.6.12.3 patch.
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Here's a small example:
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$ cd ~/linux-2.6.12.2			# change into the kernel source dir
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$ patch -p1 -R < ../patch-2.6.12.2	# revert the 2.6.12.2 patch
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$ patch -p1 < ../patch-2.6.12.3		# apply the new 2.6.12.3 patch
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$ cd ..
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$ mv linux-2.6.12.2 linux-2.6.12.3	# rename the kernel source dir
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The -rc kernels
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---
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 These are release-candidate kernels. These are development kernels released
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by Linus whenever he deems the current git (the kernel's source management
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tool) tree to be in a reasonably sane state adequate for testing.
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These kernels are not stable and you should expect occasional breakage if
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you intend to run them. This is however the most stable of the main
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development branches and is also what will eventually turn into the next
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stable kernel, so it is important that it be tested by as many people as
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possible.
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This is a good branch to run for people who want to help out testing
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development kernels but do not want to run some of the really experimental
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stuff (such people should see the sections about -git and -mm kernels below).
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The -rc patches are not incremental, they apply to a base 2.6.x kernel, just
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like the 2.6.x.y patches described above. The kernel version before the -rcN
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suffix denotes the version of the kernel that this -rc kernel will eventually
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turn into.
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So, 2.6.13-rc5 means that this is the fifth release candidate for the 2.6.13
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kernel and the patch should be applied on top of the 2.6.12 kernel source.
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Here are 3 examples of how to apply these patches:
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# first an example of moving from 2.6.12 to 2.6.13-rc3
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$ cd ~/linux-2.6.12			# change into the 2.6.12 source dir
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$ patch -p1 < ../patch-2.6.13-rc3	# apply the 2.6.13-rc3 patch
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$ cd ..
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$ mv linux-2.6.12 linux-2.6.13-rc3	# rename the source dir
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# now let's move from 2.6.13-rc3 to 2.6.13-rc5
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$ cd ~/linux-2.6.13-rc3			# change into the 2.6.13-rc3 dir
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$ patch -p1 -R < ../patch-2.6.13-rc3	# revert the 2.6.13-rc3 patch
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$ patch -p1 < ../patch-2.6.13-rc5	# apply the new 2.6.13-rc5 patch
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$ cd ..
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$ mv linux-2.6.13-rc3 linux-2.6.13-rc5	# rename the source dir
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# finally let's try and move from 2.6.12.3 to 2.6.13-rc5
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$ cd ~/linux-2.6.12.3			# change to the kernel source dir
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$ patch -p1 -R < ../patch-2.6.12.3	# revert the 2.6.12.3 patch
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$ patch -p1 < ../patch-2.6.13-rc5	# apply new 2.6.13-rc5 patch
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$ cd ..
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$ mv linux-2.6.12.3 linux-2.6.13-rc5	# rename the kernel source dir
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The -git kernels
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---
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 These are daily snapshots of Linus' kernel tree (managed in a git
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repository, hence the name).
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These patches are usually released daily and represent the current state of
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Linus's tree. They are more experimental than -rc kernels since they are
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generated automatically without even a cursory glance to see if they are
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sane.
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-git patches are not incremental and apply either to a base 2.6.x kernel or
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a base 2.6.x-rc kernel -- you can see which from their name.
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A patch named 2.6.12-git1 applies to the 2.6.12 kernel source and a patch
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named 2.6.13-rc3-git2 applies to the source of the 2.6.13-rc3 kernel.
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Here are some examples of how to apply these patches:
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# moving from 2.6.12 to 2.6.12-git1
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$ cd ~/linux-2.6.12			# change to the kernel source dir
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$ patch -p1 < ../patch-2.6.12-git1	# apply the 2.6.12-git1 patch
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$ cd ..
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$ mv linux-2.6.12 linux-2.6.12-git1	# rename the kernel source dir
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# moving from 2.6.12-git1 to 2.6.13-rc2-git3
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$ cd ~/linux-2.6.12-git1		# change to the kernel source dir
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$ patch -p1 -R < ../patch-2.6.12-git1	# revert the 2.6.12-git1 patch
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					# we now have a 2.6.12 kernel
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$ patch -p1 < ../patch-2.6.13-rc2	# apply the 2.6.13-rc2 patch
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					# the kernel is now 2.6.13-rc2
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$ patch -p1 < ../patch-2.6.13-rc2-git3	# apply the 2.6.13-rc2-git3 patch
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					# the kernel is now 2.6.13-rc2-git3
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$ cd ..
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$ mv linux-2.6.12-git1 linux-2.6.13-rc2-git3	# rename source dir
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The -mm kernels
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---
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 These are experimental kernels released by Andrew Morton.
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The -mm tree serves as a sort of proving ground for new features and other
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experimental patches.
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Once a patch has proved its worth in -mm for a while Andrew pushes it on to
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Linus for inclusion in mainline.
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Although it's encouraged that patches flow to Linus via the -mm tree, this
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is not always enforced.
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Subsystem maintainers (or individuals) sometimes push their patches directly
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to Linus, even though (or after) they have been merged and tested in -mm (or
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sometimes even without prior testing in -mm).
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You should generally strive to get your patches into mainline via -mm to
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ensure maximum testing.
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This branch is in constant flux and contains many experimental features, a
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lot of debugging patches not appropriate for mainline etc., and is the most
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experimental of the branches described in this document.
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These kernels are not appropriate for use on systems that are supposed to be
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stable and they are more risky to run than any of the other branches (make
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sure you have up-to-date backups -- that goes for any experimental kernel but
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even more so for -mm kernels).
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These kernels in addition to all the other experimental patches they contain
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usually also contain any changes in the mainline -git kernels available at
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the time of release.
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Testing of -mm kernels is greatly appreciated since the whole point of the
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tree is to weed out regressions, crashes, data corruption bugs, build
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breakage (and any other bug in general) before changes are merged into the
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more stable mainline Linus tree.
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But testers of -mm should be aware that breakage in this tree is more common
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than in any other tree.
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The -mm kernels are not released on a fixed schedule, but usually a few -mm
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kernels are released in between each -rc kernel (1 to 3 is common).
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The -mm kernels apply to either a base 2.6.x kernel (when no -rc kernels
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have been released yet) or to a Linus -rc kernel.
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Here are some examples of applying the -mm patches:
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# moving from 2.6.12 to 2.6.12-mm1
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$ cd ~/linux-2.6.12			# change to the 2.6.12 source dir
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$ patch -p1 < ../2.6.12-mm1		# apply the 2.6.12-mm1 patch
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$ cd ..
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$ mv linux-2.6.12 linux-2.6.12-mm1	# rename the source appropriately
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# moving from 2.6.12-mm1 to 2.6.13-rc3-mm3
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$ cd ~/linux-2.6.12-mm1
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$ patch -p1 -R < ../2.6.12-mm1		# revert the 2.6.12-mm1 patch
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					# we now have a 2.6.12 source
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$ patch -p1 < ../patch-2.6.13-rc3	# apply the 2.6.13-rc3 patch
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					# we now have a 2.6.13-rc3 source
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$ patch -p1 < ../2.6.13-rc3-mm3		# apply the 2.6.13-rc3-mm3 patch
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$ cd ..
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$ mv linux-2.6.12-mm1 linux-2.6.13-rc3-mm3	# rename the source dir
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This concludes this list of explanations of the various kernel trees.
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I hope you are now clear on how to apply the various patches and help testing
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the kernel.
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Thank you's to Randy Dunlap, Rolf Eike Beer, Linus Torvalds, Bodo Eggert,
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Johannes Stezenbach, Grant Coady, Pavel Machek and others that I may have
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forgotten for their reviews and contributions to this document.
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