[net-next-2.6.git] / Documentation / early-userspace / README

Early userspace support
=======================

Last update: 2004-12-20 tlh


"Early userspace" is a set of libraries and programs that provide
various pieces of functionality that are important enough to be
available while a Linux kernel is coming up, but that don't need to be
run inside the kernel itself.

It consists of several major infrastructure components:

- gen_init_cpio, a program that builds a cpio-format archive
  containing a root filesystem image.  This archive is compressed, and
  the compressed image is linked into the kernel image.
- initramfs, a chunk of code that unpacks the compressed cpio image
  midway through the kernel boot process.
- klibc, a userspace C library, currently packaged separately, that is
  optimized for correctness and small size.

The cpio file format used by initramfs is the "newc" (aka "cpio -H newc")
format, and is documented in the file "buffer-format.txt".  There are
two ways to add an early userspace image: specify an existing cpio
archive to be used as the image or have the kernel build process build
the image from specifications.

CPIO ARCHIVE method

You can create a cpio archive that contains the early userspace image.
Your cpio archive should be specified in CONFIG_INITRAMFS_SOURCE and it
will be used directly.  Only a single cpio file may be specified in
CONFIG_INITRAMFS_SOURCE and directory and file names are not allowed in
combination with a cpio archive.

IMAGE BUILDING method

The kernel build process can also build an early userspace image from
source parts rather than supplying a cpio archive.  This method provides
a way to create images with root-owned files even though the image was
built by an unprivileged user.

The image is specified as one or more sources in
CONFIG_INITRAMFS_SOURCE.  Sources can be either directories or files -
cpio archives are *not* allowed when building from sources.

A source directory will have it and all of its contents packaged.  The
specified directory name will be mapped to '/'.  When packaging a
directory, limited user and group ID translation can be performed.
INITRAMFS_ROOT_UID can be set to a user ID that needs to be mapped to
user root (0).  INITRAMFS_ROOT_GID can be set to a group ID that needs
to be mapped to group root (0).

A source file must be directives in the format required by the
usr/gen_init_cpio utility (run 'usr/gen_init_cpio --help' to get the
file format).  The directives in the file will be passed directly to
usr/gen_init_cpio.

When a combination of directories and files are specified then the
initramfs image will be an aggregate of all of them.  In this way a user
can create a 'root-image' directory and install all files into it.
Because device-special files cannot be created by a unprivileged user,
special files can be listed in a 'root-files' file.  Both 'root-image'
and 'root-files' can be listed in CONFIG_INITRAMFS_SOURCE and a complete
early userspace image can be built by an unprivileged user.

As a technical note, when directories and files are specified, the
entire CONFIG_INITRAMFS_SOURCE is passed to
scripts/gen_initramfs_list.sh.  This means that CONFIG_INITRAMFS_SOURCE
can really be interpreted as any legal argument to
gen_initramfs_list.sh.  If a directory is specified as an argument then
the contents are scanned, uid/gid translation is performed, and
usr/gen_init_cpio file directives are output.  If a directory is
specified as an arugemnt to scripts/gen_initramfs_list.sh then the
contents of the file are simply copied to the output.  All of the output
directives from directory scanning and file contents copying are
processed by usr/gen_init_cpio.

See also 'scripts/gen_initramfs_list.sh -h'.

Where's this all leading?
=========================

The klibc distribution contains some of the necessary software to make
early userspace useful.  The klibc distribution is currently
maintained separately from the kernel, but this may change early in
the 2.7 era (it missed the boat for 2.5).

You can obtain somewhat infrequent snapshots of klibc from
ftp://ftp.kernel.org/pub/linux/libs/klibc/

For active users, you are better off using the klibc git
repository, at http://git.kernel.org/?p=libs/klibc/klibc.git

The standalone klibc distribution currently provides three components,
in addition to the klibc library:

- ipconfig, a program that configures network interfaces.  It can
  configure them statically, or use DHCP to obtain information
  dynamically (aka "IP autoconfiguration").
- nfsmount, a program that can mount an NFS filesystem.
- kinit, the "glue" that uses ipconfig and nfsmount to replace the old
  support for IP autoconfig, mount a filesystem over NFS, and continue
  system boot using that filesystem as root.

kinit is built as a single statically linked binary to save space.

Eventually, several more chunks of kernel functionality will hopefully
move to early userspace:

- Almost all of init/do_mounts* (the beginning of this is already in
  place)
- ACPI table parsing
- Insert unwieldy subsystem that doesn't really need to be in kernel
  space here

If kinit doesn't meet your current needs and you've got bytes to burn,
the klibc distribution includes a small Bourne-compatible shell (ash)
and a number of other utilities, so you can replace kinit and build
custom initramfs images that meet your needs exactly.

For questions and help, you can sign up for the early userspace
mailing list at http://www.zytor.com/mailman/listinfo/klibc

How does it work?
=================

The kernel has currently 3 ways to mount the root filesystem:

a) all required device and filesystem drivers compiled into the kernel, no
   initrd.  init/main.c:init() will call prepare_namespace() to mount the
   final root filesystem, based on the root= option and optional init= to run
   some other init binary than listed at the end of init/main.c:init().

b) some device and filesystem drivers built as modules and stored in an
   initrd.  The initrd must contain a binary '/linuxrc' which is supposed to
   load these driver modules.  It is also possible to mount the final root
   filesystem via linuxrc and use the pivot_root syscall.  The initrd is
   mounted and executed via prepare_namespace().

c) using initramfs.  The call to prepare_namespace() must be skipped.
   This means that a binary must do all the work.  Said binary can be stored
   into initramfs either via modifying usr/gen_init_cpio.c or via the new
   initrd format, an cpio archive.  It must be called "/init".  This binary
   is responsible to do all the things prepare_namespace() would do.

   To maintain backwards compatibility, the /init binary will only run if it
   comes via an initramfs cpio archive.  If this is not the case,
   init/main.c:init() will run prepare_namespace() to mount the final root
   and exec one of the predefined init binaries.

Bryan O'Sullivan <bos@serpentine.com>
Commit	Line	Data
1da177e4 LT	1	Early userspace support
	2	=======================
	3
	4	Last update: 2004-12-20 tlh
	5
	6
	7	"Early userspace" is a set of libraries and programs that provide
	8	various pieces of functionality that are important enough to be
	9	available while a Linux kernel is coming up, but that don't need to be
	10	run inside the kernel itself.
	11
	12	It consists of several major infrastructure components:
	13
	14	- gen_init_cpio, a program that builds a cpio-format archive
	15	containing a root filesystem image. This archive is compressed, and
	16	the compressed image is linked into the kernel image.
	17	- initramfs, a chunk of code that unpacks the compressed cpio image
	18	midway through the kernel boot process.
	19	- klibc, a userspace C library, currently packaged separately, that is
	20	optimized for correctness and small size.
	21
1810732e	22	The cpio file format used by initramfs is the "newc" (aka "cpio -H newc")
1da177e4 LT	23	format, and is documented in the file "buffer-format.txt". There are
	24	two ways to add an early userspace image: specify an existing cpio
	25	archive to be used as the image or have the kernel build process build
	26	the image from specifications.
	27
	28	CPIO ARCHIVE method
	29
	30	You can create a cpio archive that contains the early userspace image.
b2d1a8ad	31	Your cpio archive should be specified in CONFIG_INITRAMFS_SOURCE and it
1da177e4 LT	32	will be used directly. Only a single cpio file may be specified in
	33	CONFIG_INITRAMFS_SOURCE and directory and file names are not allowed in
	34	combination with a cpio archive.
	35
	36	IMAGE BUILDING method
	37
	38	The kernel build process can also build an early userspace image from
	39	source parts rather than supplying a cpio archive. This method provides
	40	a way to create images with root-owned files even though the image was
	41	built by an unprivileged user.
	42
	43	The image is specified as one or more sources in
	44	CONFIG_INITRAMFS_SOURCE. Sources can be either directories or files -
	45	cpio archives are not allowed when building from sources.
	46
1810732e	47	A source directory will have it and all of its contents packaged. The
1da177e4 LT	48	specified directory name will be mapped to '/'. When packaging a
	49	directory, limited user and group ID translation can be performed.
	50	INITRAMFS_ROOT_UID can be set to a user ID that needs to be mapped to
	51	user root (0). INITRAMFS_ROOT_GID can be set to a group ID that needs
	52	to be mapped to group root (0).
	53
	54	A source file must be directives in the format required by the
	55	usr/gen_init_cpio utility (run 'usr/gen_init_cpio --help' to get the
	56	file format). The directives in the file will be passed directly to
	57	usr/gen_init_cpio.
	58
	59	When a combination of directories and files are specified then the
	60	initramfs image will be an aggregate of all of them. In this way a user
	61	can create a 'root-image' directory and install all files into it.
	62	Because device-special files cannot be created by a unprivileged user,
	63	special files can be listed in a 'root-files' file. Both 'root-image'
	64	and 'root-files' can be listed in CONFIG_INITRAMFS_SOURCE and a complete
	65	early userspace image can be built by an unprivileged user.
	66
	67	As a technical note, when directories and files are specified, the
	68	entire CONFIG_INITRAMFS_SOURCE is passed to
	69	scripts/gen_initramfs_list.sh. This means that CONFIG_INITRAMFS_SOURCE
	70	can really be interpreted as any legal argument to
	71	gen_initramfs_list.sh. If a directory is specified as an argument then
	72	the contents are scanned, uid/gid translation is performed, and
	73	usr/gen_init_cpio file directives are output. If a directory is
	74	specified as an arugemnt to scripts/gen_initramfs_list.sh then the
	75	contents of the file are simply copied to the output. All of the output
	76	directives from directory scanning and file contents copying are
	77	processed by usr/gen_init_cpio.
	78
	79	See also 'scripts/gen_initramfs_list.sh -h'.
	80
	81	Where's this all leading?
	82	=========================
	83
	84	The klibc distribution contains some of the necessary software to make
	85	early userspace useful. The klibc distribution is currently
	86	maintained separately from the kernel, but this may change early in
	87	the 2.7 era (it missed the boat for 2.5).
	88
	89	You can obtain somewhat infrequent snapshots of klibc from
	90	ftp://ftp.kernel.org/pub/linux/libs/klibc/
	91
fda6ab8b CB	92	For active users, you are better off using the klibc git
fda6ab8b CB	93	repository, at http://git.kernel.org/?p=libs/klibc/klibc.git
1da177e4 LT	94
	95	The standalone klibc distribution currently provides three components,
	96	in addition to the klibc library:
	97
	98	- ipconfig, a program that configures network interfaces. It can
	99	configure them statically, or use DHCP to obtain information
	100	dynamically (aka "IP autoconfiguration").
	101	- nfsmount, a program that can mount an NFS filesystem.
	102	- kinit, the "glue" that uses ipconfig and nfsmount to replace the old
	103	support for IP autoconfig, mount a filesystem over NFS, and continue
	104	system boot using that filesystem as root.
	105
	106	kinit is built as a single statically linked binary to save space.
	107
	108	Eventually, several more chunks of kernel functionality will hopefully
	109	move to early userspace:
	110
	111	- Almost all of init/do_mounts* (the beginning of this is already in
	112	place)
	113	- ACPI table parsing
	114	- Insert unwieldy subsystem that doesn't really need to be in kernel
	115	space here
	116
	117	If kinit doesn't meet your current needs and you've got bytes to burn,
	118	the klibc distribution includes a small Bourne-compatible shell (ash)
	119	and a number of other utilities, so you can replace kinit and build
	120	custom initramfs images that meet your needs exactly.
	121
	122	For questions and help, you can sign up for the early userspace
	123	mailing list at http://www.zytor.com/mailman/listinfo/klibc
	124
	125	How does it work?
	126	=================
	127
	128	The kernel has currently 3 ways to mount the root filesystem:
	129
	130	a) all required device and filesystem drivers compiled into the kernel, no
	131	initrd. init/main.c:init() will call prepare_namespace() to mount the
	132	final root filesystem, based on the root= option and optional init= to run
	133	some other init binary than listed at the end of init/main.c:init().
	134
	135	b) some device and filesystem drivers built as modules and stored in an
	136	initrd. The initrd must contain a binary '/linuxrc' which is supposed to
	137	load these driver modules. It is also possible to mount the final root
	138	filesystem via linuxrc and use the pivot_root syscall. The initrd is
	139	mounted and executed via prepare_namespace().
	140
	141	c) using initramfs. The call to prepare_namespace() must be skipped.
	142	This means that a binary must do all the work. Said binary can be stored
	143	into initramfs either via modifying usr/gen_init_cpio.c or via the new
	144	initrd format, an cpio archive. It must be called "/init". This binary
	145	is responsible to do all the things prepare_namespace() would do.
	146
1810732e	147	To maintain backwards compatibility, the /init binary will only run if it
1da177e4 LT	148	comes via an initramfs cpio archive. If this is not the case,
	149	init/main.c:init() will run prepare_namespace() to mount the final root
	150	and exec one of the predefined init binaries.
	151
	152	Bryan O'Sullivan <bos@serpentine.com>