Custom Initramfs

initramfs is a root filesystem that is embedded into the kernel and loaded at an early stage of the boot process. It is Article description::the successor of initrd. It provides early userspace which can do things the kernel can't easily do by itself during the boot process.

Using initramfs is optional. By default, the kernel initializes hardware using built-in drivers, mounts the specified root partition, loads the init system of the installed Linux distribution. The init system then loads additional modules and starts services until it eventually allows you to log in. This is a good default behavior and sufficient for many users. initramfs is for users with advanced requirements; for users who need to do things as early as possible, even before the root partition is mounted.

Here are some examples of what you can do with initramfs:


 * Mount the root partition (for encrypted, logical, and otherwise special partitions);
 * Provide a minimalistic rescue shell (if something goes wrong);
 * Customize the boot process (e.g. print a welcome message, boot splash, etc.);
 * Load modules (e.g. third party drivers);
 * Anything the kernel can't do (as long as you can do it in user space, e.g. by executing commands).

If you don't have advanced requirements, you don't need initramfs.

Prerequisites
There are countless ways to make an initramfs. You can choose not to create an initramfs at all but let tools, such as Genkernel or Dracut, do the work for you. If you are lucky, one of them does what you want out of the box, and you don't need to bother with how initramfs works and what it does anymore. If you're unlucky, they don't do what you want and you have to extend their functionality, or even build an initramfs all by yourself.

An initramfs contains at least one file called. This file is executed by the kernel as the main init process (PID 1). It has to do all the work. In addition, there can be any number of additional files and directories that are required by. They are usually files you'll also find on any other root filesystem, such as for device nodes,  for kernel information,  for binaries, and so on. The structure of an initramfs can be simple, or it can be complicated, depending on what you are planning to do.

When the kernel mounts the initramfs, your target root partition is not yet mounted, so you can't access any of your files. That means there is nothing but the initramfs. So everything you need, everything you want, you have to include it in your initramfs. If you want a shell, you have to include it in your initramfs. If you want to mount something, you need a mount utility. If you need to load a module, your initramfs has to provide both the module, as well as a utility to load it. If the utility depends on libraries in order to work, you have to include the libraries as well. This seems complicated, and it is, because the initramfs has to function independently.

Basics
In this section you will learn the easy and straightforward way to initramfs creation. You will make a functional - albeit minimalistic - initramfs which you then can extend according to your own requirements.

Directory structure
Create a basic initramfs directory structure that will later become your initramfs root. For consistency, we'll work in, but any location would do. If you choose another location, please adapt accordingly.

Device nodes
Most things the initramfs does will require a couple of device nodes to be present, especially the device for the root partition. Throughout this document, will be used as example device. Copy basic device nodes from the root filesystem to the initramfs example location:

Which devices you need exactly depends entirely on what you are going to use initramfs for. Please adapt to your own needs.

Applications
Any binary you want to execute at boot needs to be copied into your initramfs layout. You also need to copy any libraries that your binaries require. To see what libraries any particular binary requires, use the tool. For example, the binary requires:

Here you see that for to work in your initramfs, you not only need to copy  to your, but also  and  to your. The exception is which is provided by the kernel.

Some applications might depend on other files and libraries to work. For example, needs a terminfo file  from, so you have to copy it to your initramfs as well. To find these dependencies, tools like and  prove to be most helpful.

Busybox
Instead of collecting countless utilities and libraries (and never seeing the end of it), you can just use. It's a set of utilities for rescue and embedded systems, it contains a shell, utilities like, , , , , and many more - all in a single binary called. For to work properly in a initramfs, you need to emerge it with the   USE flag enabled, then copy the  binary into your initramfs layout as :

Init
The file structure of your initramfs is almost complete. The only thing that is missing is itself, the executable in the root of the initramfs that is executed by the kernel. Because includes a fully functional shell, this means you can write your  binary as a simple shell script (instead of making it a complicated application written in Assembler or C that you'd have to compile).

The following example shows a minimalistic shell script, based on the shell:

This example needs some device nodes to work, mainly the root block device. Change the script and copy the corresponding node to fit your needs.

Don't forget to make the file executable:

Packaging
Your initramfs now has to be made available to the kernel at boot time. This is done by packaging it as a compressed cpio archive. This archive is then either embedded directly into the kernel image, or stored as a separate file which can be loaded by the bootloader during the boot process. Both methods perform equally well, simply choose the method you prefer.

Kernel configuration
With either method, you need to enable Initial RAM filesystem and RAM disk (initramfs/initrd) support.

Embedding into the Kernel
If you want the initramfs to be embedded into the kernel image, set Initramfs source file(s) to the root of your initramfs, (e.g. ):

Now when you compile your kernel it will automatically put the files into a cpio archive and embed it into the kernel image. You will need to rebuild your kernel any time you make any changes to your initramfs.

Creating a separate file
If you want to use a standalone archive file, you need to adjust the kernel settings accordingly:

For this example is sufficient.

You can create a standalone archive file by running the following commands:

This will create a file called in your. You now need to instruct your bootloader to load this file along with the kernel.

Using GRUB
In case of GRUB, you do this with the initrd line:

In order to make this usable with, the filename must be included in the GRUB helper scripts:

After applying the changes, the file will be recognized running ; the output may look like the following:

Using EFI stub kernel
See EFI_stub_kernel

External file list
An external file list, or cpio list, describes files to be included into the initramfs. This file list is processed by an utility that comes with the Linux kernel,. It can be used for both embedded and standalone initramfs, either by using it as directly or by running the utility from a shell. This lets you build the initramfs dynamically, always using the latest files from your system, but compared to populating a real directory, it is less intuitive and requires more knowledge in regards to device nodes and such. The command will prove as very useful to get information from special block or character devices.

A minimalistic list may look like so:

Create the cpio archive, compress it and move it to :

After that update the entries of your bootloader!

Instead of creating the list manually, there is the possibility to let the cpio list and archive be generated and compressed by two tools, which are provided by the kernel source files. It might be needed to compile these first; this is documented here.

Using the before created directory structure in it may be executed like the following:

The script creates a cpio list by analyzing all directories and files within. It then executes to generate the cpio archive file and finally compresses it using ; according to the filename suffix. The directory has to be changed before, since the shell script uses a relative path to.

In order to comprehend, all steps can be done manually:

The file can now be moved to.

Finalizing
You can now reboot your machine. On boot, the kernel will extract the files from your initramfs archive automatically and execute your script, which in turn should then take care of mounting your root partition and execute the init system of your installed Linux distribution.

Functionality
Now that you've covered the initramfs basics, in this section you will learn how to extend your script with more advanced functionality.

Rescue shell
If you want to be dropped to a rescue shell if an error occurs, you can add the following function to your and call it when something goes wrong.

In the example below, the rescue_shell will be executed if the root partition fails to mount:

Dynamic devices
For populating dynamically, you can use either devtmpfs or mdev. Please note that the kernel can take some time detecting devices (such as external USB drives), so you may also have to add a sleep statement to your script.

devtmpfs
Provided by the kernel, devtmpfs is designed to offer device nodes during early boot.

You can include the following snippet in your script to have it mount at boot:

Don't forget to unmount it again in the cleanup phase of the script:

mdev
Although devtmpfs is the preferred solution today, you can alternatively use mdev, the udev replacement of.

For mdev to work, you have to make a symlink to  in your initramfs.

Then add the following snippet to your, after mounting and :

Mount by UUID or label
With Dynamic devices enabled, you might prefer to use UUID or label to mount the root partition instead of using a static device name. For that purpose, comes with a utility called.

Doing it this way is simple, but it means that your UUID or label is hardcoded in the. Alternatively, you can also use Kernel parameters.

Kernel parameters
If you want to use kernel parameters instead of hardcoding device names or UUIDs, you will have to parse. There are many ways to do so, the following method is just an example to give you the general idea. It uses string manipulation of the shell and only supports  parameters. Add the following function to your and call it whenever you need a kernel parameter.

The function is called with the name of the kernel parameter you are interested in. In the example below, it uses the root parameter to mount the root partition.

It works for both  and   but will fail when the parameter is missing.

LVM
If your root partition is located on a logical volume, you need to include the LVM binary in your initramfs. You can get a static binary by enabling the  USE flag for. Copy it to your initramfs directory.

Now you can enable your LVM root partition in. This example assumes that your volume group is called VG, and your root volume is called root. Replace them with the names you chose when creating the volume.

The root partition may then be called or.

Recent versions of rely on  to create the named LV device nodes, but there is no udev in a simple initramfs. The following choices are available:


 * Use as shown above (simplest solution)
 * Mount by UUID or label instead of using . It works because is happy with just
 * Build a LVM binary with the  USE flag (specifically for the initramfs only!)
 * Disable udev dependency by including a minimal in the initramfs:

Software RAID
Normally the Linux kernel will automatically scan for any "Linux raid autodetect" partitions and start as many software RAIDs as it can find. But if you use an initramfs, the kernel will not automatically scan for RAIDs until it is told to. In the following example instructs the kernel to scan for software RAIDs and start as many as it can find. This will actually start all autodetected arrays, not just :

mdadm
Without "Linux raid autodetect" partitions, or if you need an advanced RAID setup, you have to include mdadm in your initramfs. You can get a static binary by enabling the  USE flag for.

Copy the binary and your  into your initramfs:

Edit the in your initramfs to your liking. An example follows:

This will scan all  devices and assemble the RAID device fitting the UUID 627125a5:abce6b82:6c738e49:50adadae.

Now you can initialize your Software RAID in :

With this, you should be able to mount your root partition.

DM-Crypt
If your root partition is LUKS encrypted, you need to include the cryptsetup binary in your initramfs. You can get a static binary by setting the  USE flag for. Copy it to your initramfs directory. Since cryptsetup also often requires the use of the kernel's random device, include them as well.

Recompile the package with the new USE flags. For example:

It might also be needed to compile the package with the   USE flag:

After that copy over the binary files:

Now you can unlock your encrypted root partition in :

Once you entered your passphrase, your root partition will be available as.

Encrypted keyfile
If you need encrypted keyfiles, use to encrypt them. It keeps your initramfs simple as that's the encryption tool you already have - no need to add other binaries. Plus, unlike some of the alternatives, it offers a nice password prompt.

The following example creates a random 512 byte key, encrypted with LUKS, and adds it to your LUKS container.

Unlocking the root device using this key in your can then be done like this:

As before, your root partition should then be available as.

Networking
If you need networking in your initramfs, all required network related drivers have to be built into your kernel, and you'll have to configure the network interfaces in your. How exactly this has to be done, depends on your network situation. The following sections cover only the most common cases.

Static IP
If your network situation allows you to use a static network IP, you can set it up using the and  commands, both of which are included in Busybox. This is by far the easiest solution, so if it's at all possible, go for it.

DHCP
To obtain a dynamic IP address from your network's DHCP server, you need a DHCP client. Busybox comes with a minimalistic DHCP client called, which is sufficient for most users. Unfortunately, has a dependency: it requires the help of a separate script to actually configure the network interface. An example for such a script is included in the Busybox distribution, but it's not installed by Gentoo. You will have to obtain it directly from the Busybox tarball (it's called ) or download it from the Busybox project page.

Copy the script to your initramfs and make it executable.

Edit the script's first line to read #!/bin/busybox sh or create a symlink for :

Now, you can obtain a dynamic IP address for eth0 using DHCP:

DNS
Your network should be up and running now. However, that's only if you know exactly which IPs to talk to. If all you have is a host or domain name, it's a different story entirely. In that case, you need to be able to resolve hostnames. Unfortunately, this is where our luck leaves us. Until now, everything could be done with just the static binary of Busybox - however, this is not the case with DNS.

This is because itself dynamically includes additional libraries for DNS lookups. As long as you don't need that functionality, you're fine, but if you need it, you have no choice but to include those libraries in your initramfs. The only alternative would be building Busybox against another libc such as, however that would go beyond the scope of this article.

This is a good chance to demonstrate how to use to reveal hidden dependencies.

As you can see, the command accesses quite a lot of files, some of which are mandatory for it to work.

Copy the necessary libraries to your initramfs:

Create a with at least one useable nameserver. Note that this step may be done automatically if you use DHCP.

With this, DNS lookups should now work for you.

Troubleshooting
The following section tries to provide help with common issues and pitfalls you may run into.

Static vs. dynamic binaries
Any custom binaries you need to use in your initramfs before mounting have to be fully functional, independent from any files you may have installed on your root partition. This is much easier to achieve with static binaries (which usually work as single file) than with dynamic binaries (which need any number of additional libraries to work).

Gentoo provides static binaries for some ebuilds. Check if the ebuild for your binary offers a  or   USE flag. This is by far the easiest method to get a static binary, but unfortunately only a select few ebuilds support it.

Many applications also offer static builds with an option in their configure scripts. There is no standard name for the option, it may be  or something similar. When compiling a package manually, check the list of available options by using to see if the package supports building static binaries.

You can check whether or not a binary is static by using the command. The command is also very useful to find out about additional dependencies. By using it is possible to see which files a certain package has brought into your system, some of which may also be candidates for additional dependencies of that package.

Including libraries into your initramfs in order to make a dynamic executable work is a last resort only. It makes the initramfs much larger than necessary and harder to maintain, as the dependencies might change with every update of the program in question.

lddtree
If you decide to go with dynamic binaries, comes with a Python script  which will handle the collection of libraries for you:

That will copy the binary and all its libraries to your initramfs structure - but not any of the runtime dependencies. For more details refer to.

Kernel panics
When working with initramfs and writing custom init scripts for it, you may experience the following kernel panic on boot:

Kernel panic - not syncing: Attempted to kill init!

This is not an error in the kernel, but an error in your script. This script is executed as the init process with PID 1. Unlike other processes, the PID 1 init process is special. It is the only process that is started by the kernel on boot. It's the process that takes care of starting other processes (boot process, init scripts) which in turn start other processes (daemons, login prompts, X), which in turn start other processes (bash, window manager, browser, ...). The init process is the mother of all other processes, and therefore it mustn't be killed. On shutdown, it's again the init process that takes care of cleaning up by shutting down other processes first, then running processes that will unmount the filesystems, until it is safe to actually do a shutdown without corrupting anything.

If you have some error in your script, that causes the init process to end, this basically means there are no processes left to run, there is nothing that could take care of cleaning up, and the kernel has no choice but to panic. For this reason there are some things in that you can't do like you can do them in a normal shell script, like using return or exit, or letting the script just run a series of commands and then simply end.

If you want to end, you have to pass the responsibility of the init process to another process using exec. See the examples above how exec is used to either run /sbin/init of the mounted root partition or to run a rescue shell in case something went wrong.

Job control
While working with initramfs, especially the Rescue shell, you may come across this message:

/bin/sh: can't access tty; job control turned off

The lack of job control is usually not a problem, since is not supposed to be interactive. However, if you want to work with the Busybox shell on a regular basis, being unable to control programs with + or + can easily become a huge issue. In worst case, if job control is not available, and a program refuses to quit, you have to reboot.

The job control section in the Busybox FAQ offers some help here. You can either use

or

to start a shell on tty1 with job control enabled.

Salvaging
If for whatever reason you lost your structure, but you still got either the kernel image with the built-in initramfs, or the separate cpio archive, it's possible to salvage it from there. Although it may be easier to just redo it from scratch - if you've done it once, doing it again should be a piece of cake. So this is just in case.

Dismantling the Kernel
You can skip this step if your initramfs is a separate cpio archive already. Otherwise, you'll have to get the built-in cpio archive out of the kernel image. To do that, you have to dismantle it, which isn't easy, since the kernel image is a combination of boot sector and compressed archive itself. It also depends on the compression you are using for your kernel and for your initramfs. For simplicity, this example assumes bzip2 - however, the principle is the same for other compression methods.

The utility of choice when dismantling kernel images is. It analyzes arbitrary files for known signatures, and prints their offsets. While there are usually a bunch of false matches in the output, it should be easy to pick the correct ones.

A less sophisticated method would be to use to search for signatures. For bzip2, this is BZh. For gzip, use  $'\x1f'$'\x8b' .

In this case the offset we are looking for is 15949 bytes. Now you can extract the compressed kernel image:

Now, you have the uncompressed kernel image. Somewhere within this image resides the compressed initramfs archive, so just iterate the previous process to find it. Depending on your kernel configuration, you're looking for another bzip2, gzip, or cpio container.

Suppose the offset is 171424 bytes this time. Now you can extract the initramfs cpio archive:

If you want to verify that you actually got a cpio archive from that, use the command:

Extracting the cpio archive
If your initramfs cpio archive was a separate file, it needs to be uncompressed first.

To extract the uncompressed, you can do so with the following command:

With this, you should have successfully recovered your initramfs structure.

Integrated initramfs does not always update
If your initramfs is integrated into your kernel (instead of using a separate file), there's a possibility that a does not actually update it every time. So you might be making changes to your initramfs but actually keep booting using your old, buggy one. In this case you have to manually delete the integrated image to force the kernel to integrate a fresh initramfs archive:

Alternatively, you could also, but then the entire kernel will need to be recompiled.

Command not found
In Gentoo, busybox is configured as standalone shell by default, which allows busybox to execute its own applets directly. Without this setting, Busybox commands (,, ...) won't work unless there is explicitly a symlink created for them. You can do this at the top of your script:

Alternatively, you can create the symlinks directly in so they will already be included in your initramfs.

Disappearing root
If your encrypted root (with cryptsetup/LUKS), for example, is disappearing after the command you can recreate the device by entering:

Variations for switch_root
Some init setups require proc, sys and dev to be mounted before starting up. If you find you are having trouble with in your initramfs setup try replacing the  command with a  in your init script.

For example, replace this.

With this.

Examples
See Custom_Initramfs/Examples for fully functional examples of finished scripts.

External resources

 * Official initramfs documentation locally ( less ) or online at kernel.org
 * Linux® From Scratch - About initramfs
 * Update your initramfs using pure Bash