169 lines
6.1 KiB
Plaintext
169 lines
6.1 KiB
Plaintext
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Notes on Filesystem Layout
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--------------------------
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These notes describe what mkcramfs generates. Kernel requirements are
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a bit looser, e.g. it doesn't care if the <file_data> items are
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swapped around (though it does care that directory entries (inodes) in
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a given directory are contiguous, as this is used by readdir).
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All data is currently in host-endian format; neither mkcramfs nor the
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kernel ever do swabbing. (See section `Block Size' below.)
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<filesystem>:
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<superblock>
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<directory_structure>
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<data>
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<superblock>: struct cramfs_super (see cramfs_fs.h).
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<directory_structure>:
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For each file:
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struct cramfs_inode (see cramfs_fs.h).
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Filename. Not generally null-terminated, but it is
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null-padded to a multiple of 4 bytes.
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The order of inode traversal is described as "width-first" (not to be
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confused with breadth-first); i.e. like depth-first but listing all of
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a directory's entries before recursing down its subdirectories: the
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same order as `ls -AUR' (but without the /^\..*:$/ directory header
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lines); put another way, the same order as `find -type d -exec
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ls -AU1 {} \;'.
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Beginning in 2.4.7, directory entries are sorted. This optimization
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allows cramfs_lookup to return more quickly when a filename does not
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exist, speeds up user-space directory sorts, etc.
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<data>:
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One <file_data> for each file that's either a symlink or a
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regular file of non-zero st_size.
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<file_data>:
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nblocks * <block_pointer>
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(where nblocks = (st_size - 1) / blksize + 1)
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nblocks * <block>
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padding to multiple of 4 bytes
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The i'th <block_pointer> for a file stores the byte offset of the
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*end* of the i'th <block> (i.e. one past the last byte, which is the
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same as the start of the (i+1)'th <block> if there is one). The first
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<block> immediately follows the last <block_pointer> for the file.
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<block_pointer>s are each 32 bits long.
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The order of <file_data>'s is a depth-first descent of the directory
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tree, i.e. the same order as `find -size +0 \( -type f -o -type l \)
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-print'.
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<block>: The i'th <block> is the output of zlib's compress function
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applied to the i'th blksize-sized chunk of the input data.
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(For the last <block> of the file, the input may of course be smaller.)
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Each <block> may be a different size. (See <block_pointer> above.)
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<block>s are merely byte-aligned, not generally u32-aligned.
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Holes
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-----
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This kernel supports cramfs holes (i.e. [efficient representation of]
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blocks in uncompressed data consisting entirely of NUL bytes), but by
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default mkcramfs doesn't test for & create holes, since cramfs in
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kernels up to at least 2.3.39 didn't support holes. Run mkcramfs
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with -z if you want it to create files that can have holes in them.
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Tools
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-----
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The cramfs user-space tools, including mkcramfs and cramfsck, are
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located at <http://sourceforge.net/projects/cramfs/>.
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Future Development
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==================
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Block Size
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----------
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(Block size in cramfs refers to the size of input data that is
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compressed at a time. It's intended to be somewhere around
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PAGE_SIZE for cramfs_readpage's convenience.)
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The superblock ought to indicate the block size that the fs was
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written for, since comments in <linux/pagemap.h> indicate that
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PAGE_SIZE may grow in future (if I interpret the comment
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correctly).
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Currently, mkcramfs #define's PAGE_SIZE as 4096 and uses that
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for blksize, whereas Linux-2.3.39 uses its PAGE_SIZE, which in
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turn is defined as PAGE_SIZE (which can be as large as 32KB on arm).
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This discrepancy is a bug, though it's not clear which should be
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changed.
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One option is to change mkcramfs to take its PAGE_SIZE from
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<asm/page.h>. Personally I don't like this option, but it does
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require the least amount of change: just change `#define
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PAGE_SIZE (4096)' to `#include <asm/page.h>'. The disadvantage
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is that the generated cramfs cannot always be shared between different
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kernels, not even necessarily kernels of the same architecture if
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PAGE_SIZE is subject to change between kernel versions
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(currently possible with arm and ia64).
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The remaining options try to make cramfs more sharable.
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One part of that is addressing endianness. The two options here are
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`always use little-endian' (like ext2fs) or `writer chooses
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endianness; kernel adapts at runtime'. Little-endian wins because of
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code simplicity and little CPU overhead even on big-endian machines.
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The cost of swabbing is changing the code to use the le32_to_cpu
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etc. macros as used by ext2fs. We don't need to swab the compressed
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data, only the superblock, inodes and block pointers.
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The other part of making cramfs more sharable is choosing a block
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size. The options are:
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1. Always 4096 bytes.
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2. Writer chooses blocksize; kernel adapts but rejects blocksize >
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PAGE_SIZE.
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3. Writer chooses blocksize; kernel adapts even to blocksize >
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PAGE_SIZE.
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It's easy enough to change the kernel to use a smaller value than
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PAGE_SIZE: just make cramfs_readpage read multiple blocks.
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The cost of option 1 is that kernels with a larger PAGE_SIZE
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value don't get as good compression as they can.
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The cost of option 2 relative to option 1 is that the code uses
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variables instead of #define'd constants. The gain is that people
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with kernels having larger PAGE_SIZE can make use of that if
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they don't mind their cramfs being inaccessible to kernels with
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smaller PAGE_SIZE values.
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Option 3 is easy to implement if we don't mind being CPU-inefficient:
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e.g. get readpage to decompress to a buffer of size MAX_BLKSIZE (which
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must be no larger than 32KB) and discard what it doesn't need.
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Getting readpage to read into all the covered pages is harder.
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The main advantage of option 3 over 1, 2, is better compression. The
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cost is greater complexity. Probably not worth it, but I hope someone
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will disagree. (If it is implemented, then I'll re-use that code in
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e2compr.)
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Another cost of 2 and 3 over 1 is making mkcramfs use a different
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block size, but that just means adding and parsing a -b option.
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Inode Size
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----------
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Given that cramfs will probably be used for CDs etc. as well as just
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silicon ROMs, it might make sense to expand the inode a little from
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its current 12 bytes. Inodes other than the root inode are followed
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by filename, so the expansion doesn't even have to be a multiple of 4
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bytes.
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