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Message-Id: <20170816173536.1879-1-nicolas.pitre@linaro.org>
Date: Wed, 16 Aug 2017 13:35:31 -0400
From: Nicolas Pitre <nicolas.pitre@...aro.org>
To: Alexander Viro <viro@...iv.linux.org.uk>
Cc: linux-fsdevel@...r.kernel.org, linux-embedded@...r.kernel.org,
linux-kernel@...r.kernel.org,
Chris Brandt <Chris.Brandt@...esas.com>
Subject: [PATCH v2 0/5] cramfs refresh for embedded usage
This series brings a nice refresh to the cramfs filesystem, adding the
following capabilities:
- Direct memory access, bypassing the block and/or MTD layers entirely.
- Ability to store individual data blocks uncompressed.
- Ability to locate individual data blocks anywhere in the filesystem.
The end result is a very tight filesystem that can be accessed directly
from ROM without any other subsystem underneath. Also this allows for
user space XIP which is a very important feature for tiny embedded
systems.
Why cramfs?
Because cramfs is very simple and small. With CONFIG_CRAMFS_BLOCK=n and
CONFIG_CRAMFS_PHYSMEM=y the cramfs driver may use as little as 3704 bytes
of code. That's many times smaller than squashfs. And the runtime memory
usage is also much less with cramfs than squashfs. It packs very tightly
already compared to romfs which has no compression support. And the cramfs
format was simple to extend, allowing for both compressed and uncompressed
blocks within the same file.
Why not accessing ROM via MTD?
The MTD layer is nice and flexible. It also represents a huge overhead
considering its core with no other enabled options weights 19KB.
That's many times the size of the cramfs code for something that
essentially boils down to a glorified argument parser and a call to
memremap() in this case. And if someone still wants to use cramfs via
MTD then it is already possible with mtdblock.
Why not using DAX?
DAX stands for "Direct Access" and is a generic kernel layer helping
with the necessary tasks involved with XIP. It is tailored for large
writable filesystems and relies on the presence of an MMU. It also has
the following shortcoming: "The DAX code does not work correctly on
architectures which have virtually mapped caches such as ARM, MIPS and
SPARC." That makes it unsuitable for a large portion of the intended
targets for this series. And due to the read-only nature of cramfs, it is
possible to achieve the intended result with a much simpler approach making
DAX somewhat overkill in this context.
The maximum size of a cramfs image can't exceed 272MB. In practice it is
likely to be much much less. Given this series is concerned with small
memory systems, even in the MMU case there is always plenty of vmalloc
space left to map it all and even a 272MB memremap() wouldn't be a
problem. If it is then maybe your system is big enough with large
resources to manage already and you're pretty unlikely to be using cramfs
in the first place.
Of course, while this cramfs remains backward compatible with existing
filesystem images, a newer mkcramfs version is necessary to take advantage
of the extended data layout. I created a version of mkcramfs that
detects ELF files and marks text+rodata segments for XIP and compresses the
rest of those ELF files automatically.
So here it is. I'm also willing to step up as cramfs maintainer given
that no sign of any maintenance activities appeared for years.
This series is also available based on v4.13-rc4 via git here:
http://git.linaro.org/people/nicolas.pitre/linux xipcramfs
Changes from v1:
- Improved mmap() support by adding the ability to partially populate a
mapping and lazily split the non directly mapable pages to a separate
vma at fault time (thanks to Chris Brandt for testing).
- Clarified the documentation some more.
diffstat:
Documentation/filesystems/cramfs.txt | 42 ++
MAINTAINERS | 4 +-
fs/cramfs/Kconfig | 39 +-
fs/cramfs/README | 31 +-
fs/cramfs/inode.c | 621 +++++++++++++++++++++++++----
include/uapi/linux/cramfs_fs.h | 20 +-
init/do_mounts.c | 8 +
7 files changed, 688 insertions(+), 77 deletions(-)
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