nbdkit-data-plugin - nbdkit plugin for serving data from the command line
nbdkit data [data=]'0 1 2 3 @0x1fe 0x55 0xaa'
[size=SIZE] [allocator=sparse|malloc|zstd]
nbdkit data base64='aGVsbG8gbmJka2l0IHVzZXI='
[size=SIZE] [allocator=sparse|malloc|zstd]
nbdkit data raw='binary_data'
[size=SIZE] [allocator=sparse|malloc|zstd]
nbdkit-data-plugin
is a plugin for nbdkit(1) which serves a small amount of data specified directly on the command line. The plugin gets its name from the data:
URI scheme used by web browsers. This is mainly useful for testing NBD clients.
You can serve data read-only using the -r flag, or read-write. Any writes are thrown away when nbdkit exits.
Most operating systems have command line size limits which are quite a lot smaller than any desirable disk image, so specifying a large, fully populated disk image on the command line would not be possible. However you can specify a small amount of data at the beginning of the image, possibly followed by zeroes (using the size
parameter to pad the image to the full size), or use the data
parameter creatively to make mostly sparse disk images.
The size
parameter can specify any virtual size up to the maximum supported by nbdkit (2⁶³-1 bytes).
nbdkit data ' ( 0x55 0xAA )*2048 '
nbdkit data ' ( "Hello" )*2000 ' size=8192
The first command creates a disk containing 4096 bytes filled with the repeating bytes 0x55 0xAA. The second command repeats HelloHelloHello...
, truncating the disk to exactly 8192 bytes.
See also nbdkit-pattern-plugin(3).
nbdkit data '
@0x1be # MBR first partition entry
0 # Partition status
0 2 0 # CHS start
0x83 # Partition type (Linux)
0x20 0x20 0 # CHS last sector
le32:1 # LBA first sector
le32:0x7ff # LBA number of sectors
@0x1fe # Boot signature
0x55 0xaa
' size=1M
A more flexible way to create partitions is to use nbdkit-partitioning-plugin(1). To create a data string from an existing disk use the disk2data.pl
script provided in the nbdkit sources (https://gitlab.com/nbdkit/nbdkit/blob/master/plugins/data/disk2data.pl).
nbdkit data ' <file1 @^512 <file2 @^512 <file3 @^512 '
Local binary files file1, file2 and file3 are copied into the disk image. Regardless of the size of these files, they will all be aligned to 512-byte sector boundaries. Furthermore because of the final alignment operation (@^512
) the total size of the disk will also be rounded to a whole number of sectors.
nbdkit data ' </dev/urandom[:512]*16 '
The expression </dev/urandom[:512]
reads 512 bytes (one sector) of randomness from the system. The same random data is repeated over 16 sectors.
nbdkit data base64=MTIz size=1M
The above command serves the bytes 0x31 0x32 0x33
(which is the base64 decoding of MTIz
), followed by 1M - 3 bytes of zeroes.
$ nbdkit data raw='Hello, world!' --run 'nbdcopy "$uri" - | cat'
Hello, world!
This works by creating a disk containing the string "Hello, world!"
. nbdcopy(1) connects to the server using an NBD URI ("$uri"
) and copies the disk to stdout (-
). The extra cat(1) is needed because nbdcopy refuses to write raw disk data to a terminal.
Exactly one of the data
, base64
or raw
parameters must be supplied.
Specify the disk data using a simple compact format. See "DATA FORMAT" below.
data=
is a magic config key and may be omitted in most cases. See "Magic parameters" in nbdkit(1).
The base64
parameter can be used to supply binary data encoded in base64 on the command line.
This is only supported if nbdkit was compiled with GnuTLS ≥ 3.6.0. You can find out by checking if:
$ nbdkit data --dump-plugin
contains:
data_base64=yes
The raw
parameter can be used to supply raw binary data directly on the command line.
It is usually quite difficult to do this unless you are running nbdkit from another program (see nbdkit-captive(1)). One particular problem is that the data must not contain zero bytes (ie. \0
) since those will be processed in C to mean the end of the string. In almost all cases it is better to use base64 encoding or the custom data
format.
The data is truncated or extended to the size specified.
This parameter is optional: If omitted the size is defined by the size of the data
, raw
or base64
parameter.
(nbdkit ≥ 1.22)
Select the backend allocation strategy. See "ALLOCATORS" in nbdkit-memory-plugin(1). The default is sparse.
The data
parameter lets you specify small disk images in a simple, compact format. It is a string containing a list of bytes which are written into the disk image sequentially. You can move the virtual offset where bytes are written using @offset
.
nbdkit data '0 1 2 3 @0x1fe 0x55 0xaa'
creates:
total size 0x200 = 512 bytes (1 sector)
┌──────┬──────┬──────┬──────┬───────── ── ── ───┬──────┬──────┐
│ 0 │ 1 │ 2 │ 3 │ 0 0 ... 0 │ 0x55 │ 0xaa │
└──────┴──────┴──────┴──────┴───────── ── ── ───┴──────┴──────┘
↑
offset 0x1fe
In this example the size is implied by the data. But you could also use the size
parameter to either truncate or extend (with zeroes) the disk image. Another way to write the same disk would be this, where we align the offset to the end of the sector and move back 2 bytes to write the signature:
nbdkit data '0 1 2 3 @^0x200 @-2 le16:0xaa55'
Fields in the string can be:
Write a byte at the current offset and advance the offset by 1. The byte may be specified as either decimal, octal (prefixed by 0
) or hexadecimal (prefixed by 0x
). To add repeated bytes use the *
operator (eg. 0xFF*16
).
(nbdkit ≥ 1.28)
Write a word expressed in little endian (le) or big endian (be) of length 16/32/64 bits and advance the offset by 2/4/8. The word may be specified in decimal, octal or hexadecimal. For example:
nbdkit data ' be32:0x1 '
generates the 4 byte sequence 0 0 0 1
.
Moves the current offset to OFFSET
. The offset may be specified as either decimal, octal (prefixed by 0
) or hexadecimal (prefixed by 0x
). Offset @0
is the first byte of the disk.
(nbdkit ≥ 1.22)
Add or subtract N
from the current offset.
(nbdkit ≥ 1.22)
If the current offset is not a multiple of ALIGNMENT
then the offset is moved forward to the next multiple. The next byte written will be aligned to ALIGNMENT
.
(nbdkit ≥ 1.8)
Read the contents of binary FILE into the disk image at the current offset. The offset is incremented by the size of the file. The filename can be a relative or absolute path, but cannot contain whitespace in the name.
(nbdkit ≥ 1.24, not Windows)
Substitute the output of the shell script or external program as a binary blob and advance the offset by the length in bytes of the output. You can use this to create more complex test patterns. For example this produces a 32K disk image with an incrementing test pattern in groups of 4 bytes:
nbdkit data ' <( i=0
while :; do
printf "%04d" $i; i=$((i+1))
done )[:32768] '
The script may contain (
and )
characters, but they must be in matching pairs. A script can produce a finite amount of output; or (as in the example) an infinite amount which must be truncated using the [:len]
slice operator.
Scripts must be idempotent, producing the same output each time they are run. This is because optimizations might change the order of evaluation or number of times the script is called and you could get different output in a future version of nbdkit.
Note that the script is passed to /bin/sh. On some platforms like Debian this might not be a full-featured shell.
(nbdkit ≥ 1.22)
Write a string into the image at the current offset and advance the offset by the length of the string. To include special characters in the string you can escape them in the same way as C strings (eg. a double quote character within the string should be written \"
). Be careful with shell quoting around the whole data parameter.
(nbdkit ≥ 1.24)
Group a set of expressions into a single expression.
( ... )
recursively creates a new data parser so any expression can appear inside, including nested ( ... )
. Note that offsets and alignments within the subpattern are relative to the start of the subpattern, not relative to the final disk image.
(nbdkit ≥ 1.24)
Repeat the expression N
times. The offset is incremented by the length of the expression × N. For example to create a repeating pattern of 0x55, 0xAA for 512 (2×256) bytes do:
nbdkit data '( 0x55 0xAA ) * 256'
(nbdkit ≥ 1.24)
Take a slice of the expression. Slices are [start:end+1] where start and end are the first and last byte offsets of the expression desired. Either or both may be omitted. [:len] means to take the first len bytes. [start:] means to take bytes from offset start to the end of the expression.
(nbdkit ≥ 1.24)
Assign an expression to a name which can be used later. Names can be used in the current scope (or any scopes nested within the current scope), but disappear at the end of the current scope. Names start with a backslash character followed by one or more alphanumeric, dash and underscore. For example this makes two identical sectors both containing a boot signature at the end:
nbdkit data ' ( 0x55 0xAA ) -> \boot-signature
( @0x1fe \boot-signature ) -> \sector
\sector \sector '
(nbdkit ≥ 1.24)
Substitute command line parameters or environment variables. The variable is written in the same language as the data
parameter, and when substituted it creates a nested scope like ( ... )
expressions. These are all equivalent:
nbdkit data '$pattern*16' pattern='0x55 0xAA'
export pattern='0x55 0xAA'
nbdkit data '$pattern*16'
nbdkit data '( 0x55 0xAA )*16'
(nbdkit ≥ 1.24)
#
begins a comment stretching to the end of the current line.
This script can convert from small disk images into the data format described above.
It is provided in the nbdkit sources. See https://gitlab.com/nbdkit/nbdkit/blob/master/plugins/data/disk2data.pl
The plugin.
Use nbdkit --dump-config
to find the location of $plugindir
.
nbdkit-data-plugin
first appeared in nbdkit 1.6.
nbdkit(1), nbdkit-captive(1), nbdkit-plugin(3), nbdkit-info-plugin(1), nbdkit-memory-plugin(1), nbdkit-null-plugin(1), nbdkit-ones-plugin(1), nbdkit-partitioning-plugin(1), nbdkit-pattern-plugin(1), nbdkit-random-plugin(1), nbdkit-sparse-random-plugin(1), nbdkit-tmpdisk-plugin(1), nbdkit-zero-plugin(1), https://gitlab.com/nbdkit/nbdkit/blob/master/plugins/data/disk2data.pl, https://en.wikipedia.org/wiki/Base64.
Richard W.M. Jones
Copyright Red Hat
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