.. SPDX-License-Identifier: GPL-2.0

===========================================
Cramfs - cram a filesystem onto a small ROM
===========================================

cramfs is designed to be simple and small, and to compress things well.

It uses the zlib routines to compress a file one page at a time, and
allows random page access.  The meta-data is not compressed, but is
expressed in a very terse representation to make it use much less
diskspace than traditional filesystems.

You can't write to a cramfs filesystem (making it compressible and
compact also makes it _very_ hard to update on-the-fly), so you have to
create the disk image with the "mkcramfs" utility.


Usage Notes
-----------

File sizes are limited to less than 16MB.

Maximum filesystem size is a little over 256MB.  (The last file on the
filesystem is allowed to extend past 256MB.)

Only the low 8 bits of gid are stored.  The current version of
mkcramfs simply truncates to 8 bits, which is a potential security
issue.

Hard links are not preserved.  mkcramfs deduplicates files with
identical content, but two names for the same on-disk inode in the
source tree become two separate (content-shared) entries in the
image, and cramfs always reports a link count of 1.

Cramfs directories have no ``.`` or ``..`` entries.  Directories (like
every other file on cramfs) always have a link count of 1.  (There's
no need to use -noleaf in ``find``, btw.)

No timestamps are stored in a cramfs, so these default to the epoch
(1970 GMT).  Recently-accessed files may have updated timestamps, but
the update lasts only as long as the inode is cached in memory, after
which the timestamp reverts to 1970, i.e. moves backwards in time.

The on-disk layout is host-endian: the kernel does not swab, and
refuses to mount an image whose endianness does not match the CPU.
For cross-builds, mkcramfs -B / -L forces the output endianness so
that a host of one endianness can produce an image for a target of
the other.

The on-disk block size is fixed at 4096 bytes.  On systems with a
larger PAGE_SIZE you can change the #define in mkcramfs.c, with the
caveat that the resulting image will only be readable on kernels
configured for the same PAGE_SIZE.


Memory Mapped cramfs image
--------------------------

The CRAMFS_MTD Kconfig option adds support for loading data directly from
a physical linear memory range (usually non volatile memory like Flash)
instead of going through the block device layer. This saves some memory
since no intermediate buffering is necessary to hold the data before
decompressing.

And when data blocks are kept uncompressed and properly aligned, they will
automatically be mapped directly into user space whenever possible providing
eXecute-In-Place (XIP) from ROM of read-only segments. Data segments mapped
read-write (hence they have to be copied to RAM) may still be compressed in
the cramfs image in the same file along with non compressed read-only
segments. Both MMU and no-MMU systems are supported. This is particularly
handy for tiny embedded systems with very tight memory constraints.

The location of the cramfs image in memory is system dependent. You must
know the proper physical address where the cramfs image is located and
configure an MTD device for it. Also, that MTD device must be supported
by a map driver that implements the "point" method. Examples of such
MTD drivers are cfi_cmdset_0001 (Intel/Sharp CFI flash) or physmap
(Flash device in physical memory map). MTD partitions based on such devices
are fine too. Then that device should be specified with the "mtd:" prefix
as the mount device argument. For example, to mount the MTD device named
"fs_partition" on the /mnt directory::

    $ mount -t cramfs mtd:fs_partition /mnt

To boot a kernel with this as root filesystem, suffice to specify
something like "root=mtd:fs_partition" on the kernel command line.


Tools
-----

A version of mkcramfs that can take advantage of the latest capabilities
described above can be found here:

https://github.com/npitre/cramfs-tools


For /usr/share/magic
--------------------

=====	=======================	=======================
0	ulelong	0x28cd3d45	Linux cramfs offset 0
>4	ulelong	x		size %d
>8	ulelong	x		flags 0x%x
>12	ulelong	x		future 0x%x
>16	string	>\0		signature "%.16s"
>32	ulelong	x		fsid.crc 0x%x
>36	ulelong	x		fsid.edition %d
>40	ulelong	x		fsid.blocks %d
>44	ulelong	x		fsid.files %d
>48	string	>\0		name "%.16s"
512	ulelong	0x28cd3d45	Linux cramfs offset 512
>516	ulelong	x		size %d
>520	ulelong	x		flags 0x%x
>524	ulelong	x		future 0x%x
>528	string	>\0		signature "%.16s"
>544	ulelong	x		fsid.crc 0x%x
>548	ulelong	x		fsid.edition %d
>552	ulelong	x		fsid.blocks %d
>556	ulelong	x		fsid.files %d
>560	string	>\0		name "%.16s"
=====	=======================	=======================


Hacker Notes
------------

See fs/cramfs/README for filesystem layout and implementation notes.