Hooray! Thanks for your interest in working on the Linux kernel. The next step is to [:OPWApply:apply] to OPW, and use this tutorial to create your first patch to the Linux kernel. Warning: this is still a work in progress. We'll announce on the opw-kernel mailing list when this tutorial is finished. Please [https://live.gnome.org/OutreachProgramForWomen#Application_Process turn in your application] to express interest in the kernel project, and sign up for the [https://groups.google.com/forum/#!forum/opw-kernel opw-kernel mailing list]. == Intro == If you run into any issues with this tutorial, please ask questions on the #kernel-opw IRC channel on irc.oftc.net, or on the [https://groups.google.com/forum/#!forum/opw-kernel opw-kernel mailing list]. This tutorial will cover how to get your first patch submitted. We would love it if accepted interns could test their kernel code on a computer running Linux, however, to get applicants started, this tutorial will describe how to set Linux up in a virtual machine. You can run Linux from within Windows (or even run Linux on Linux!) from a virtual machine (VM). This tutorial will show you how to: [[TableOfContents(0)]] == Hardware Requirements == You need a system with virtualization (VT-d), at least 4GB of RAM, and 40GB of free hard drive space in order to run Linux in a VM. == Alternatives == If your system doesn't meet those requirements, you will need to be running Linux, or dual boot your machine so you can run both Linux and Windows. We strongly suggest you use the [http://www.ubuntu.com/download/desktop/thank-you?distro=desktop&bits=64&release=lts Ubuntu 12.04 64-bit version]. If your machine doesn't have 64-bit support, you can use the [http://www.ubuntu.com/download/desktop/thank-you?release=lts&bits=32&distro=desktop&status=zeroc 32-bit version]. Once you have Ubuntu installed, please follow the directions [:OPWfirstpatchAlt:here]. If you already have Linux working on a system, please follow the directions [:OPWfirstpatchAlt:here]. = Install VMPlayer = Go to the [http://www.vmware.com/products/player/ VMPlayer website] and click the 'download' link. Download the VMPlayer that's appropriate for your operating system (e.g. Windows or Linux 64-bit), and install it. == Linux installation instructions == The [http://www.vmware.com/products/player/ VMPlayer download] comes as a .bundle file. That's a binary executable, that will launch a setup wizard. First, change to the directory where you downloaded the VMPlayer binary by using the command {{{cd}}}. Tip: {{{cd}}} changes the current working directory to a different directory. You can learn more about any command by reading the manual pages. Simply prefix the command with the word "man", e.g. {{{man cd}}}. Next, check to see if the file is executable. Run this command: {{{ ls -l}}} Then look at at the file's listing, and see if it has the executable ("x") bit set: {{{ $ ls -l total 181056 -rw-rw-r-- 1 sarah sarah 185386101 Apr 26 22:19 VMware-Player-5.0.2-1031769.x86_64.bundle}}} If it doesn't show the executable bit, make the file executable by running: {{{ chmod a+x VMware-Player-5.0.2-1031769.x86_64.bundle}}} Then execute the binary by prefixing it with a ./ and running it as the root user with sudo: {{{ sudo ./VMware-Player-5.0.2-1031769.x86_64.bundle}}} Tip: Be careful about what you run as root! The root user has access to all the files on your system, so you usually don't want to run arbitrary commands as root. Always run commands without sudo, and without changing to a root terminal, where ever possible. = Download our Linux VM image = Next, you'll need to install [http://www.7-zip.org/ 7zip], which will help you decompress the compressed VM image. The homepage has instructions for installing it under Windows. Under Ubuntu, you can install 7zip by running: {{{ sudo aptitude install p7zip}}} Next, download the VM image and uncompress it with 7zip. Start VMPlayer, choose "Open a Virtual Machine", and open the "OPW kernel Ubuntu 12.04 64-bit.vmx" file. Before you start the VM, you need to make some adjustments to the emulated hardware. Click "Edit virtual machine settings". Now, adjust the amount of memory available to the VM to be the recommended amount of memory. You also want to adjust the number of CPUs available to the guest. It should not be more CPUs than you have available (e.g. if you have a dual core, it should not be more than 2). Click the 'Save' button. Once you've adjusted the emulated hardware, start the VM by clicking "Play virtual machine". Select "I copied it". If a "Removable devices" window pops up, click "ok". On the Software Updates window, click "Download and install". The password for the VM image is "{{{LinuxRules!}}}" (yes, this includes the exclamation point). If you want to change the password, you can do so by opening a terminal and typing the {{{`passwd`}}} command. Please wait for the software updates to download and install before you start using the VM. Otherwise the VM will be very VERY slow. = Explore the kernel tree = [[Anchor(opw-first-patch-native-start)]] First, open a terminal, by clicking the black screen icon with the "{{{>_}}}" text in it. Tip: You can exit out of a terminal tab or window by pressing {{{d}}} at any time. This is the recommended way of closing the terminal, since it won't kill any processes you have running in the background. Get used to exiting the terminal this way by opening and closing the terminal a couple times. The VM Image already has Linus' git tree checked out for you. Change directories to that git checkout: {{{ cd git/kernels/linux/}}} This is the Linux kernel tree. You can explore it by using the {{{`ls`}}} and {{{`cd`}}} commands. If you run {{{`ls}}}, you'll see several different folders: {{{ intern@ubuntu:~/git/kernels/linux$ ls arch init modules.order System.map block ipc Module.symvers tags COPYING Kbuild net tools CREDITS Kconfig README usr crypto kernel REPORTING-BUGS virt Documentation lib samples vmlinux drivers MAINTAINERS scripts vmlinux.o extra_certificates Makefile security x509.genkey firmware mm signing_key.priv fs Module.markers signing_key.x509 include modules.builtin sound }}} There's more to this directory than meets the eye! If you run ls -A, you'll see there's a hidden directory called {{{.git}}}. This contains all the meta information that git uses to track branches, remote repositories, and changes to files in the local directory. You can view the commit history by running {{{ git log}}} If you want a more compact form, you can run a command to see just the "short description" for each commit, with an abbrevated git commit ID: {{{ git log --pretty=oneline --abbrev-commit}}} = Play with some git basics = Git is a distributed revision control system, which means you can hack on your version of the code without having to coordinate with other developers. Think of your git checkout as a separate copy of Linus' kernel respository. Git includes support for branches. Each branch can contain a completely different set of patches. Kernel developers typically use one branch per patchset. For example, you might have one branch that includes bug fixes, and another branch that contains commits for a new feature you're working on. You can run {{{`git branch`}}} to see which branch you're on, and what other branches are available: {{{ intern@ubuntu:~/git/kernels/linux$ git branch * master }}} In this case, there is only one branch, called master. The start indicates that the "master" branch is the one you are currently on. In git speak, we say that you currently have the master branch "checked out". Create a new branch called 'staging', and checkout that branch by running: {{{ git checkout -b staging}}} Now if you run git branch, you'll see that there are two branches, and you are currently on the "staging" branch: {{{ intern@ubuntu:~/git/kernels/linux$ git branch master * staging }}} You can also use the git branch command to show branches on Linus' repository (the remote repository). Run the command: {{{intern@ubuntu:~/git/kernels/linux$ git branch -a master * staging remotes/origin/HEAD -> origin/master remotes/origin/master}}} The first remote repository that is used to create the git checkout is called "origin". For now, just remember that "origin" means Linus' remote git repository. = Update your kernel = When you create patches, you want to create them on top of the latest kernel from Linus. If your patch is out-of-date and doesn't apply to the latest tree, it may be rejected. You'll need to use git to fetch the latest changes: {{{ git fetch origin}}} The third word in that command is the name of the remote repository you are fetching from. That command will fetch the changes from Linus' tree, but it won't actually change in files in the working copy (i.e. the files in this directory). If you run: {{{ git log}}} You will see that your current working directory still points to the original commit (3.9). So where are Linus' current changes? The answer is that git stores the changes in a special hidden directory called {{{.git}}}. You can view the history of Linus' repository by giving git log the "master" branch of the "origin" remote repository (i.e. Linus' master branch): {{{ git log origin/master}}} Next, we need to update our branch to include the changes in Linus' tree. The safest way to do this is to "rebase" your branch. This means that if you have any commits on your branch, they will be placed on top of Linus' commits. Sometimes you may have to edit your commits if there are conflicts, but you should ask your mentor for help with this. For now, run: {{{ git rebase origin/master}}} If you run {{{`git log`}}} to show your staging branch history and then {{{`git log origin/master`}}} to show Linus' master branch history, you should see that they have exactly the same commits. = Configure the kernel = The next step is to create a configuration file, compile the new kernel, and install it. The first thing to know is that the Linux kernel is completely configurable. Each driver can be separately configured to be installed or not. There are three choices for driver installation: * disable the driver completely, * build the driver into the main kernel file (vmlinuz), * or build it as a module. If you build the driver into the main kernel file, it will be loaded at boot time. The downside is that the kernel will have to load more code at boot for drivers that may not even corespond to hardware on the system. To avoid this, kernel developers often compile drivers as "modules". A module is a stand-alone .ko driver file that is loaded when the kernel detects hardware that matches the driver. For example, you could configure your wifi driver as a module, and the kernel will load it when it detects the wifi card. The Linux kernel make system uses a special file called {{{.config}}} that stores what drivers are compiled in, or compiled as modules. Most Linux distributions store the .config file they used to compile your distro kernel in the /boot/ directory: {{{ intern@ubuntu:~/git/kernels/linux$ ls /boot/ abi-3.5.0-23-generic initrd.img-3.9.0-rc8+ abi-3.5.0-27-generic memtest86+.bin config-3.5.0-23-generic memtest86+_multiboot.bin config-3.5.0-27-generic System.map-3.5.0-23-generic config-3.9.0 System.map-3.5.0-27-generic grub System.map-3.9.0 initrd.img-3.5.0-23-generic vmlinuz-3.5.0-23-generic initrd.img-3.5.0-27-generic vmlinuz-3.5.0-27-generic initrd.img-3.9.0 vmlinuz-3.9.0 }}} You can duplicate the distro's configuration by copying one of the config-* files to a .config file in your git tree. This has already been done for you in the VM image. = Compile the kernel = Next, you'll need to run {{{make}}} to compile your new kernel. Optionally, make can take a flag that indicates how many threads to spawn to start separate compilations. Usually you want to pick a number that is equal to the number of CPUs you have in your machine. For example, if you had a dual core system, you would run: {{{ make -j2}}} That may take a while. I would suggest reading some of the [http://lwn.net/Kernel/LDD3/ Linux Device Drivers book] while you're waiting. = Set up vim = First, we need to make sure to enable the C indentation module in our default text editor (vim). Turning on this module will ensure that lines automatically get indented to the right level as you're editing. It saves you from hitting a lot. You can turn on automatic indentation based on the file type by adding this line to the .vimrc file in your home directory: {{{ filetype plugin indent on}}} Tip: Vim is a simple text editor that has a couple modes. It starts out in standard mode, and you can move the cursor down or up with the arrow keys (or the 'j' or 'k' keys), and move the cursor left or right with the arrow keys (or the 'h' and 'l' keys). You can go into "Insert mode" by typing 'i'. Now you can change text. To get back into standard mode, type . To write a file, get into standard mode, and type :w. To quit vim, type :q. If you want to learn more about vim, the [http://vim-adventures.com/ VIM adventures game] is quite fun. You'll also want to add a couple more lines, to turn syntax highlighting on, and show the file name in the terminal title bar: {{{ syn on se title}}} = Make a driver change = These next couple of steps will allow you to make a change to a driver, and test that you've correctly compiled and installed the modified driver. One driver that's included in all VM images is the e1000 driver, the Intel ethernet driver. (Interns running Linux natively may want to use {{{lsmod}}} to see what other drivers they have loaded, and pick one from that list to modify.) The e1000 driver is found in the networking portion of the kernel: {{{ intern@ubuntu:~/git/kernels/linux$ ls drivers/net/ethernet/intel/e1000/ e1000_ethtool.c e1000.h e1000_hw.c e1000_hw.h e1000_main.c e1000_osdep.h e1000_param.c Makefile }}} Let's make a small change to the probe function of the e1000 driver. A probe function is called when the driver is loaded. Let's edit e1000_main.c: {{{ vim drivers/net/ethernet/intel/e1000/e1000_main.c}}} Next, find the probe function. You can search for text by typing '/' in standard mode. Once you've found the probe function, add a printk line to it: {{{ static int e1000_probe(struct pci_dev *pdev, const struct pci_device_id *ent) { struct net_device *netdev; struct e1000_adapter *adapter; struct e1000_hw *hw; printk(KERN_DEBUG "I can modify the Linux kernel!\n"); static int cards_found = 0; }}} Then type {{{:wq}}} to save the file and quit. A printk function causes a message to be written to the kernel log buffer, which can then be viewed using the {{{dmesg}}} command. = Compile your changes = Recompile your kernel, by running {{{make}}} (with an optional {{{-jN}}} flag): {{{ make -j2}}} You may need to fixed some compilation errors. Also fix any new warnings that are due to your changes. In the Linux kernel, we strive to make sure that drivers do not produce warnings on anyone's system (this includes 32-bit and 64-bit systems, as well as different architectures, such as PPC, ARM, or x86). New features or bug fix patches that add additional warnings may not get merged. = Install your changes = After you've compiled the driver, you need to install your changes by running: {{{ sudo make modules_install install}}} = Test your changes = Since you've compiled a completely new kernel, you need to reboot into that new kernel in order to test your module changes. Reboot your VM (or computer), and then run: {{{ dmesg | less}}} Search for your printk in the log file by typing "/I can modify". You should be able to find this message within the driver output during boot. If you don't see this message, ask for help on the #kernel-opw IRC channel on irc.oftc.net, or on the [https://groups.google.com/forum/#!forum/opw-kernel opw-kernel mailing list] == Revert your changes == Since that was just a simple test, and you probably don't want to commit that change, you can revert your changes. Exit out of your editor by typing {{{:q}}} and running this command: {{{ git reset --hard HEAD}}} That will revert '''ALL FILES''' in your current working directory to the last known commit (the HEAD commit), wiping out all your uncommited changes. Read the git reset manual for more information on ways to reset the state for specific files. = Set up git = Next, you'll get to do some useful modifications to the kernel, create your first git commit, and send out your first patch. Before you make your first commit using git, you'll need to do some setup. First, you need to tell git what your name and email address is, so that it can be used in the authorship information in the git commit. Create a file called {{{.gitconfig}}} and add lines like these to it: {{{ [user] name = Your Name email = your.email@example.com }}} Git includes some "hooks" for scripts that can be run before specific git commands are executed. The "pre-commit" hook is run before you make a git commit with the {{{`git commit``}}} command. Linux kernel developer have very stringent guidelines for [http://lxr.linux.no/#linux/Documentation/CodingStyle coding style]. They're so picky, they created a script called [http://lxr.linux.no/#linux/scripts/checkpatch.pl checkpatch.pl] that you can run over your patches to make sure the patch compiles to the kernel coding style. To ensure that you create good commits that comply with the coding style, you can run checkpatch.pl over your commit with the "pre-commit" hook. That means git will refuse to commit your changes if it doesn't compily with kernel coding style (unless you pass {{{git commit}}} the -n flag to bypass git hooks). Edit the {{{.git/hooks/pre-commit}}} file and add the following line: {{{ exec git diff --cached | scripts/checkpatch.pl --no-signoff -}}} = Understand patch best practices = Before you create your patch, we suggest you read about PatchPhilosophy. That document will help you create patches that are easy to read, and have a better chance of being applied by maintainers. = Find a driver to clean up = The staging tree, in {{{drivers/staging/}}} is full of drivers that are not quite up to kernel coding style, or that use deprecated API. Drivers get placed here in order to get cleaned up. Some drivers have a TODO file in their parent directory, that lists things that need to be done to it: {{{ find drivers/staging -name TODO}}} You can either tackle one of those TODO items, or you can do a simple coding style cleanup. == Running checkpatch.pl == If you pick a driver in staging, you can run the script that checks whether a file conforms to kernel coding style: {{{ perl scripts/checkpatch.pl -f drivers/staging/csr/* | less}}} Pick a warning, and try to fix it. == Recompiling the driver == You'll need to make sure the driver you're changing is configured as a module. Run: {{{ make menuconfig}}} This opens up a text-based GUI that allows you to explore the configuration options. Use the arrow keys to go to {{{Device Drivers -> }}} and hit . Then go down to {{{Staging drivers}}}. At any time, you can hit '?', which will show you the help text for that kernel configuration option. You can search for the driver you're modifying by '/', in order to get the driver's longer name. Make sure the driver you're working on is compiled as a module ('M'), instead of being built-in ('*'). You can change a driver to being compiled as a module by typing 'm' when the driver is selected in the menu. Hitting will change the driver to being built-in. Once you've enabled the driver you're modifying, use or the right arrow key to move the cursor from 'Select' to 'Exit' and hit . Continue to do this until you get to the main menu. When it asks you to save your configuration, chose 'Yes'. Then recompile the kernel with: {{{ make -j2}}} You should reboot your kernel, load the driver with {{{modprobe}}}. You'll be able to see that the driver is loaded by running {{{lsmod}}}. Loading the driver at least makes sure that the driver probe function works. == Reloading modules == If you're running on an updated kernel, you can test your changes (after running {{{`make -j2 && make modules_install`}}}) by simply unloading and reloading the driver: {{{ sudo modprobe -r sudo modprobe }}} How do you know what the module name is? If you've compiled the driver as a module, there should be a .ko file in the parent directory. For example, after we configure the CSR driver to be compiled as a module, we can run this command: {{{ intern@ubuntu:~/git/kernel/linux$ ls drivers/staging/csr/*.ko drivers/staging/csr/csr_helper.ko drivers/staging/csr/csr_wifi.ko }}} So, there are two drivers that we need to load with modprobe. You can load those drivers one at a time by passing modprobe the base filename: {{{ sudo modprobe csr_wifi }}} To ensure the driver got loaded, you can run: {{{ lsmod | less}}} In this case, you'll notice that both the csr_wifi and csr_helper modules got loaded. This is because the csr_wifi driver depends on the csr_helper driver, and modprobe automatically figured out it needed to load the csr_helper driver before it loaded the csr_wifi driver. = Committing your changes = In this example, assume we've addressed a warning in the CSR driver, modified the file, recompiled the driver, and tested our changes. == Viewing your changes === Git keeps track of changes in the working directory. Git can be told to ignore binary files (like .o or .ko files), so it won't track changes to those files. You can see which files have been modified by running: {{{ git status}}} git can also show you a diff stat of what changed: {{{ git diff}}} == Commiting your changes == Assuming we want to include all of our changes in one git commit, you can use git to add the changed file to the list of changes to be committed (the "staging area"): {{{ git add }}} If you run {{{`git diff`}}} again, you'll notice it doesn't list any changed files. That's because, by default, git diff only shows you the unstaged changes. If you run this command instead, you'll see the staged changes: {{{ git diff --cached}}} That command will show you the changes to be committed. == Reverting your staged changes == If you don't want to commit those changes, you can remove those changes from the staging area by running: {{{ git reset }}} == Committing parts of files == You can also add parts of files to the staging area by using the {{-p}} flag: {{{ git add -p}}} That will allow you to add hunks of the file to the staging area, or even edit hunks that you want to commit. This is useful, for instance, if you've made whitespace changes, and also made a camel-case variable name fix, but those changes are on the same line. You can edit the line to revert the camel-case name change, and just add the whitespace change to the staging area. Then when you commit, you will just be committing the whitespace change. == Committing changes == Finally, you can commit your staged changes: {{{ git commit -s}}} That will add the Signed-off-by line that is needed at the end of your patch description. Make sure that when you create your patch, you follow the PatchPhilosophy guidelines. Make sure to include a blank line between your short description (what will become the Subject line of your patch) and the body of your patch. Make sure there is a blank line between the body of your patch and your Signed-off-by line. == Editing your commits === If you should need to edit your commit message, you can run {{{ git commit --amend}}} Tip: If you add new changes to the staging area with git add, when you run the above command, it will include those changes along with the previously commited changes. == Viewing your commit == Make sure your commit looks fine by running these commands: {{{ git show HEAD}}} This will show the latest commit. If you want git to show a different commit, you can pass the commit ID (the long number that's shown in {{{`git log`}}}, or the short number that's shown in {{{`git log --pretty=oneline --abbrev-commit`}}}). Read the "Specifying Revisions section" of the {{{`git rev-parse`}}} manual page for more details on what you can in place of a commit ID. You'll also want to make sure your commit looks fine when you run these two commands: {{{ git log}}} {{{ git log --pretty=oneline --abbrev-commit}}} = Submit a patch = The first step to submitting a patch is to create and send a patch as an email. You cannot send patches as attachments to the mailing list. Instead, you will have to craft a special email, and send the patch inline. == Set up email == You'll need to be able to send email from the Linux VM image. The VM image comes installed with esmtp, which is a mail transport agent. It routes email to your mail server, such as gmail. To know what information to give esmtp, you will need to look up your mail server settings. == Gmail set up == In gmail, go click the gear icon, go to "Settings", go to the tab "Forwarding POP/IMAP", and click the "Configuration instructions" link at the very bottom of the page. Then click "I want to set up IMAP". At the bottom of the page, under the paragraph about configuring your mail client, select "Other". Note the outgoing mail server information, and copy it into the .esmtprc file, as shown in the next section. == Configure esmtp == Edit the .esmtprc in your home directory, and add lines like this: {{{ identity "my.email@gmail.com" hostname smtp.gmail.com:587 username "my.email@gmail.com" password "ThisIsNotARealPassWord" starttls required }}} Next, set up the mail client, mutt, with some defaults, but creating a .muttrc file in your homedirectory: {{{ set sendmail="/usr/bin/esmtp" set envelope_from=yes set from="Your Name " set use_from=yes }}} Now you should be able to send mail from your account.