xz-analysis-mirror/doc/file-format.txt

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The .lzma File Format
---------------------
0. Preface
0.1. Copyright Notices
0.2. Changes
1. Conventions
1.1. Byte and Its Representation
1.2. Multibyte Integers
2. Stream
2.1. Stream Types
2.1.1. Single-Block Stream
2.1.2. Multi-Block Stream
2.2. Stream Header
2.2.1. Header Magic Bytes
2.2.2. Stream Flags
2.2.3. CRC32
3. Block
3.1. Block Header
3.1.1. Block Flags
3.1.2. Compressed Size
3.1.3. Uncompressed Size
3.1.4. List of Filter Flags
3.1.4.1. Misc
3.1.4.2. External ID
3.1.4.3. External Size of Properties
3.1.4.4. Filter Properties
3.1.5. CRC32
3.1.6. Header Padding
3.2. Compressed Data
3.3. Block Footer
3.3.1. Check
3.3.2. Stream Footer
3.3.2.1. Uncompressed Size
3.3.2.2. Backward Size
3.3.2.3. Stream Flags
3.3.2.4. Footer Magic Bytes
3.3.3. Footer Padding
4. Filters
4.1. Detecting when All Data Has Been Decoded
4.1.1. With Uncompressed Size
4.1.2. With End of Input
4.1.3. With End of Payload Marker
4.2. Alignment
4.3. Filters
4.3.1. Copy
4.3.2. Subblock
4.3.2.1. Format of the Encoded Output
4.3.3. Delta
4.3.3.1. Format of the Encoded Output
4.3.4. LZMA
4.3.4.1. LZMA Properties
4.3.4.2. Dictionary Flags
4.3.5. Branch/Call/Jump Filters for Executables
5. Metadata
5.1. Metadata Flags
5.2. Size of Header Metadata Block
5.3. Total Size
5.4. Uncompressed Size
5.5. Index
5.5.1. Number of Data Blocks
5.5.2. Total Sizes
5.5.3. Uncompressed Sizes
5.6. Extra
5.6.1. 0x00: Dummy/Padding
5.6.2. 0x01: OpenPGP Signature
5.6.3. 0x02: Filter Information
5.6.4. 0x03: Comment
5.6.5. 0x04: List of Checks
5.6.6. 0x05: Original Filename
5.6.7. 0x07: Modification Time
5.6.8. 0x09: High-Resolution Modification Time
5.6.9. 0x0B: MIME Type
5.6.10. 0x0D: Homepage URL
6. Custom Filter and Extra Record IDs
6.1. Reserved Custom Filter ID Ranges
7. Cyclic Redundancy Checks
8. References
8.1. Normative References
8.2. Informative References
0. Preface
This document describes the .lzma file format (filename suffix
`.lzma', MIME type `application/x-lzma'). It is intended that
this format replace the format used by the LZMA_Alone tool
included in LZMA SDK up to and including version 4.57.
IMPORTANT: The version described in this document is a
draft, NOT a final, official version. Changes
are possible.
0.1. Copyright Notices
Copyright (C) 2006, 2007 Lasse Collin <lasse.collin@tukaani.org>
Copyright (C) 2006 Ville Koskinen <w-ber@iki.fi>
Copying and distribution of this file, with or without
modification, are permitted in any medium without royalty
provided the copyright notice and this notice are preserved.
Modified versions must be marked as such.
All source code examples given in this document are put into
the public domain by the authors of this document.
Thanks for helping with this document goes to Igor Pavlov,
Mark Adler and Mikko Pouru.
0.2. Changes
Last modified: 2008-02-01 19:25+0200
(A changelog will be kept once the first official version
is made.)
1. Conventions
The keywords `must', `must not', `required', `should',
`should not', `recommended', `may', and `optional' in this
document are to be interpreted as described in [RFC-2119].
These words are not capitalized in this document.
Indicating a warning means displaying a message, returning
appropriate exit status, or something else to let the user
know that something worth warning occurred. The operation
should still finish if a warning is indicated.
Indicating an error means displaying a message, returning
appropriate exit status, or something else to let the user
know that something prevented successfully finishing the
operation. The operation must be aborted once an error has
been indicated.
1.1. Byte and Its Representation
In this document, byte is always 8 bits.
A `nul byte' has all bits unset. That is, the value of a nul
byte is 0x00.
To represent byte blocks, this document uses notation that
is similar to the notation used in [RFC-1952]:
+-------+
| Foo | One byte.
+-------+
+---+---+
| Foo | Two bytes; that is, some of the vertical bars
+---+---+ can be missing.
+=======+
| Foo | Zero or more bytes.
+=======+
In this document, a boxed byte or a byte sequence declared
using this notation is called `a field'. The example field
above would be called called `the Foo field' or plain `Foo'.
1.2. Multibyte Integers
Multibyte integers of static length, such as CRC values,
are stored in little endian byte order (least significant
byte first).
When smaller values are more likely than bigger values (e.g.
file sizes), multibyte integers are encoded in a simple
variable-length representation:
- Numbers in the range [0, 127] are copied as is, and take
one byte of space.
- Bigger numbers will occupy two or more bytes. The lowest
seven bits of every byte are used for data; the highest
(eighth) bit indicates either that
0) the byte is in the middle of the byte sequence, or
1) the byte is the first or the last byte.
For now, the value of the variable-length integers is limited
to 63 bits, which limits the encoded size of the integer to
nine bytes. These limits may be increased in future if needed.
Note that the encoding is not as optimal as it could be. For
example, it is possible to encode the number 42 using any
number of bytes between one and nine. This is convenient
for non-streamed encoders, that write Compressed Size or
Uncompressed Size fields to the Block Header (see Section 3.1)
after the Compressed Data field is written to the disk.
In several situations, the decoder needs to compare that two
fields contain identical information. When comparing fields
using the encoding described in this Section, the decoder must
consider two fields identical if their decoded values are
identical; it does not matter if the encoded variable-length
representations differ.
The following C code illustrates encoding and decoding 63-bit
variables; the highest bit of uint64_t must be unset. The
functions return the number of bytes occupied by the integer
(1-9), or zero on error.
#include <sys/types.h>
#include <inttypes.h>
size_t
encode(uint8_t buf[static 9], uint64_t num)
{
if (num >= (UINT64_C(1) << (9 * 7)))
return 0;
if (num <= 0x7F) {
buf[0] = num;
return 1;
}
buf[0] = (num & 0x7F) | 0x80;
num >>= 7;
size_t i = 1;
while (num >= 0x80) {
buf[i++] = num & 0x7F;
num >>= 7;
}
buf[i++] = num | 0x80;
return i;
}
size_t
decode(const uint8_t buf[], size_t size_max, uint64_t *num)
{
if (size_max == 0)
return 0;
if (size_max > 9)
size_max = 9;
*num = buf[0] & 0x7F;
if (!(buf[0] & 0x80))
return 1;
size_t i = 1;
do {
if (i == size_max)
return 0;
*num |= (uint64_t)(buf[i] & 0x7F) << (7 * i);
} while (!(buf[i++] & 0x80));
return i;
}
size_t
decode_reverse(const uint8_t buf[], size_t size_max,
uint64_t *num)
{
if (size_max == 0)
return 0;
const size_t end = size_max > 9 ? size_max - 9 : 0;
size_t i = size_max - 1;
*num = buf[i] & 0x7F;
if (!(buf[i] & 0x80))
return 1;
do {
if (i-- == end)
return 0;
*num <<= 7;
*num |= buf[i] & 0x7F;
} while (!(buf[i] & 0x80));
return size_max - i;
}
2. Stream
+========+========+========+
| Stream | Stream | Stream | ...
+========+========+========+
A file contains usually only one Stream. However, it is
possible to concatenate multiple Streams together with no
additional processing. It is up to the implementation to
decide if the decoder will continue decoding from the next
Stream once the end of the first Stream has been reached.
2.1. Stream Types
There are two types of Streams: Single-Block Streams and
Multi-Block Streams. Decoders conforming to this specification
must support at least Single-Block Streams. Supporting
Multi-Block Streams is optional. If the decoder supports only
Single-Block Streams, the documentation of the decoder should
mention this fact clearly.
2.1.1. Single-Block Stream
+===============+============+
| Stream Header | Data Block |
+===============+============+
As the name says, a Single-Block Stream has exactly one Block.
The Block must be a Data Block; Metadata Blocks are not allowed
in Single-Block Streams.
2.1.2. Multi-Block Stream
+===============+=======================+
| Stream Header | Header Metadata Block |
+===============+=======================+
+============+ +============+=======================+
---> | Data Block | ... | Data Block | Footer Metadata Block |
+============+ +============+=======================+
Notes:
- Stream Header is mandatory.
- Header Metadata Block is optional.
- Each Multi-Block Stream has at least one Data Block. The
maximum number of Data Blocks is not limited.
- Footer Metadata Block is mandatory.
2.2. Stream Header
+---+---+---+---+---+---+--------------+--+--+--+--+
| Header Magic Bytes | Stream Flags | CRC32 |
+---+---+---+---+---+---+--------------+--+--+--+--+
2.2.1. Header Magic Bytes
The first six (6) bytes of the Stream are so called Header
Magic Bytes. They can be used to identify the file type.
Using a C array and ASCII:
const uint8_t HEADER_MAGIC[6]
= { 0xFF, 'L', 'Z', 'M', 'A', 0x00 };
In plain hexadecimal:
FF 4C 5A 4D 41 00
Notes:
- The first byte (0xFF) was chosen so that the files cannot
be erroneously detected as being in LZMA_Alone format, in
which the first byte is in the the range [0x00, 0xE0].
- The sixth byte (0x00) was chosen to prevent applications
from misdetecting the file as a text file.
2.2.2. Stream Flags
Bit(s) Mask Description
0-2 0x07 Type of Check (see Section 3.3.1):
ID Size Check name
0x00 0 bytes None
0x01 4 bytes CRC32
0x02 4 bytes (Reserved)
0x03 8 bytes CRC64
0x04 16 bytes (Reserved)
0x05 32 bytes SHA-256
0x06 32 bytes (Reserved)
0x07 64 bytes (Reserved)
3 0x08 The CRC32 field is present in Block Headers.
4 0x10 If unset, this is a Single-Block Stream; if set,
this is a Multi-Block Stream.
5-7 0xE0 Reserved for future use; must be zero for now.
Implementations must support at least the Check IDs 0x00 (None)
and 0x01 (CRC32). Supporting other Check IDs is optional. If an
unsupported Check is used, the decoder must indicate a warning
or error.
If any reserved bit is set, the decoder must indicate an error.
It is possible that there is a new field present which the
decoder is not aware of, and can thus parse the Stream Header
incorrectly.
2.2.3. CRC32
The CRC32 is calculated from the Stream Flags field. It is
stored as an unsigned 32-bit little endian integer. If the
calculated value does not match the stored one, the decoder
must indicate an error.
Note that this field is always present; the bit in Stream Flags
controls only presence of CRC32 in Block Headers.
3. Block
+==============+=================+==============+
| Block Header | Compressed Data | Block Footer |
+==============+=================+==============+
There are two types of Blocks:
- Data Blocks hold the actual compressed data.
- Metadata Blocks hold the Index, Extra, and a few other
non-data fields (see Section 5).
The type of the Block is indicated by the corresponding bit
in the Block Flags field (see Section 3.1.1).
3.1. Block Header
+------+------+=================+===================+
| Block Flags | Compressed Size | Uncompressed Size |
+------+------+=================+===================+
+======================+--+--+--+--+================+
---> | List of Filter Flags | CRC32 | Header Padding |
+======================+--+--+--+--+================+
3.1.1. Block Flags
The first byte of the Block Flags field is a bit field:
Bit(s) Mask Description
0-2 0x07 Number of filters (0-7)
3 0x08 Use End of Payload Marker (even if
Uncompressed Size is stored to Block Header).
4 0x10 The Compressed Size field is present.
5 0x20 The Uncompressed Size field is present.
6 0x40 Reserved for future use; must be zero for now.
7 0x80 This is a Metadata Block.
The second byte of the Block Flags field is also a bit field:
Bit(s) Mask Description
0-4 0x1F Size of the Header Padding field (0-31 bytes)
5-7 0xE0 Reserved for future use; must be zero for now.
The decoder must indicate an error if End of Payload Marker
is not used and Uncompressed Size is not stored to the Block
Header. Because of this, the first byte of Block Flags can
never be a nul byte. This is useful when detecting beginning
of the Block after Footer Padding (see Section 3.3.3).
If any reserved bit is set, the decoder must indicate an error.
It is possible that there is a new field present which the
decoder is not aware of, and can thus parse the Block Header
incorrectly.
3.1.2. Compressed Size
This field is present only if the appropriate bit is set in
the Block Flags field (see Section 3.1.1).
This field contains the size of the Compressed Data field.
The size is stored using the encoding described in Section 1.2.
If the Compressed Size does not match the real size of the
Compressed Data field, the decoder must indicate an error.
Having the Compressed Size field in the Block Header can be
useful for multithreaded decoding when seeking is not possible.
If the Blocks are small enough, the decoder can read multiple
Blocks into its internal buffer, and decode the Blocks in
parallel.
Compressed Size can also be useful when seeking forwards to
a specific location in streamed mode: the decoder can quickly
skip over irrelevant Blocks, without decoding them.
3.1.3. Uncompressed Size
This field is present only if the appropriate bit is set in
the Block Flags field (see Section 3.1.1).
The Uncompressed Size field contains the size of the Block
after uncompressing.
Storing Uncompressed Size serves several purposes:
- The decoder will know when all of the data has been
decoded without an explicit End of Payload Marker.
- The decoder knows how much memory it needs to allocate
for a temporary buffer in multithreaded mode.
- Simple error detection: wrong size indicates a broken file.
- Sometimes it is useful to know the file size without
uncompressing the file.
It should be noted that the only reliable way to find out what
the real uncompressed size is is to uncompress the Block,
because the Block Header and Metadata Block fields may contain
(intentionally or unintentionally) invalid information.
Uncompressed Size is stored using the encoding described in
Section 1.2. If the Uncompressed Size does not match the
real uncompressed size, the decoder must indicate an error.
3.1.4. List of Filter Flags
+================+================+ +================+
| Filter 0 Flags | Filter 1 Flags | ... | Filter n Flags |
+================+================+ +================+
The number of Filter Flags fields is stored in the Block Flags
field (see Section 3.1.1). As a special case, if the number of
Filter Flags fields is zero, it is equivalent to having the
Copy filter as the only filter.
The format of each Filter Flags field is as follows:
+------+=============+=============================+
| Misc | External ID | External Size of Properties |
+------+=============+=============================+
+===================+
---> | Filter Properties |
+===================+
The list of officially defined Filter IDs and the formats of
their Filter Properties are described in Section 4.3.
3.1.4.1. Misc
To save space, the most commonly used Filter IDs and the
Size of Filter Properties are encoded in a single byte.
Depending on the contents of the Misc field, Filter ID is
the value of the Misc or External ID field.
Value Filter ID Size of Filter Properties
0x00 - 0x1F Misc 0 bytes
0x20 - 0x3F Misc 1 byte
0x40 - 0x5F Misc 2 bytes
0x60 - 0x7F Misc 3 bytes
0x80 - 0x9F Misc 4 bytes
0xA0 - 0xBF Misc 5 bytes
0xC0 - 0xDF Misc 6 bytes
0xE0 - 0xFE External ID 0-30 bytes
0xFF External ID External Size of Properties
The following code demonstrates parsing the Misc field and,
when needed, the External ID and External Size of Properties
fields.
uint64_t id;
uint64_t properties_size;
uint8_t misc = read_byte();
if (misc >= 0xE0) {
id = read_variable_length_integer();
if (misc == 0xFF)
properties_size = read_variable_length_integer();
else
properties_size = misc - 0xE0;
} else {
id = misc;
properties_size = misc / 0x20;
}
3.1.4.2. External ID
This field is present only if the Misc field contains a value
that indicates usage of External ID. The External ID is stored
using the encoding described in Section 1.2.
3.1.4.3. External Size of Properties
This field is present only if the Misc field contains a value
that indicates usage of External Size of Properties. The size
of Filter Properties is stored using the encoding described in
Section 1.2.
3.1.4.4. Filter Properties
Size of this field depends on the Misc field (Section 3.1.4.1)
and, if present, External Size of Properties field (Section
3.1.4.3). The format of this field is depends on the selected
filter; see Section 4.3 for details.
3.1.5. CRC32
This field is present only if the appropriate bit is set in
the Stream Flags field (see Section 2.2.2).
The CRC32 is calculated over everything in the Block Header
field except the Header Padding field and the CRC32 field
itself. It is stored as an unsigned 32-bit little endian
integer. If the calculated value does not match the stored
one, the decoder must indicate an error.
3.1.6. Header Padding
This field contains as many nul bytes as indicated by the value
stored in the Header Flags field. If the Header Padding field
contains any non-nul bytes, the decoder must indicate an error.
The intent of the Header Padding field is to allow alignment
of Compressed Data. The usefulness of alignment is described
in Section 4.3.
3.2. Compressed Data
The format of Compressed Data depends on Block Flags and List
of Filter Flags. Excluding the descriptions of the simplest
filters in Section 4, the format of the filter-specific encoded
data is out of scope of this document.
Note a special case: if End of Payload Marker (see Section
3.1.1) is not used and Uncompressed Size is zero, the size
of the Compressed Data field is always zero.
3.3. Block Footer
+=======+===============+================+
| Check | Stream Footer | Footer Padding |
+=======+===============+================+
3.3.1. Check
The type and size of the Check field depends on which bits
are set in the Stream Flags field (see Section 2.2.2).
The Check, when used, is calculated from the original
uncompressed data. If the calculated Check does not match the
stored one, the decoder must indicate an error. If the selected
type of Check is not supported by the decoder, it must indicate
a warning or error.
3.3.2. Stream Footer
+===================+===============+--------------+
| Uncompressed Size | Backward Size | Stream Flags |
+===================+===============+--------------+
+----------+---------+
---> | Footer Magic Bytes |
+----------+---------+
Stream Footer is present only in
- Data Block of a Single-Block Stream; and
- Footer Metadata Block of a Multi-Block Stream.
The Stream Footer field is placed inside Block Footer, because
no padding is allowed between Check and Stream Footer.
3.3.2.1. Uncompressed Size
This field is present only in the Data Block of a Single-Block
Stream if Uncompressed Size is not stored to the Block Header
(see Section 3.1.1). Without the Uncompressed Size field in
Stream Footer it would not be possible to quickly find out
the Uncompressed Size of the Stream in all cases.
Uncompressed Size is stored using the encoding described in
Section 1.2. If the stored value does not match the real
uncompressed size of the Single-Block Stream, the decoder must
indicate an error.
3.3.2.2. Backward Size
This field contains the total size of the Block Header,
Compressed Data, Check, and Uncompressed Size fields. The
value is stored using the encoding described in Section 1.2.
If the Backward Size does not match the real total size of
the appropriate fields, the decoder must indicate an error.
Implementations reading the Stream backwards should notice
that the value in this field can never be zero.
3.3.2.3. Stream Flags
This is a copy of the Stream Flags field from the Stream
Header. The information stored to Stream Flags is needed
when parsing the Stream backwards.
3.3.2.4. Footer Magic Bytes
As the last step of the decoding process, the decoder must
verify the existence of Footer Magic Bytes. If they are not
found, an error must be indicated.
Using a C array and ASCII:
const uint8_t FOOTER_MAGIC[2] = { 'Y', 'Z' };
In hexadecimal:
59 5A
The primary reason to have Footer Magic Bytes is to make
it easier to detect incomplete files quickly, without
uncompressing. If the file does not end with Footer Magic Bytes
(excluding Footer Padding described in Section 3.3.3), it
cannot be undamaged, unless someone has intentionally appended
garbage after the end of the Stream. (Appending garbage at the
end of the file does not prevent uncompressing the file, but
may give a warning or error depending on the decoder
implementation.)
3.3.3. Footer Padding
In certain situations it is convenient to be able to pad
Blocks or Streams to be multiples of, for example, 512 bytes.
Footer Padding makes this possible. Note that this is in no
way required to enforce alignment in the way described in
Section 4.3; the Header Padding field is enough for that.
When Footer Padding is used, it must contain only nul bytes.
Any non-nul byte should be considered as the beginning of
a new Block or Stream.
The possibility of Padding should be taken into account when
designing an application that wants to find out information
about a Stream by parsing Footer Metadata Block.
Support for Padding was inspired by a related note in
[GNU-tar].
4. Filters
The Block Flags field defines how many filters are used. When
more than one filter is used, the filters are chained; that is,
the output of one filter is the input of another filter. The
following figure illustrates the direction of data flow.
v Uncompressed Data ^
| Filter 0 |
Encoder | Filter 1 | Decoder
| ... |
| Filter n |
v Compressed Data ^
The filters are independent from each other, except that they
must cooperate a little to make it possible, in all cases, to
detect when all of the data has been decoded. In addition, the
filters should cooperate in the encoder to keep the alignment
optimal.
4.1. Detecting when All Data Has Been Decoded
There must be a way for the decoder to detect when all of the
Compressed Data has been decoded. This is simple when only
one filter is used, but a bit more complex when multiple
filters are chained.
This file format supports three methods to detect when all of
the data has been decoded:
- Uncompressed size
- End of Input
- End of Payload Marker
In both encoder and decoder, filters are initialized starting
from the first filter in the chain. For each filter, one of
these three methods is used.
4.1.1. With Uncompressed Size
This method is the only method supported by all filters.
It must be used when uncompressed size is known by the
filter-specific encoder or decoder. In practice this means
that Uncompressed Size has been stored to the Block Header.
In case of the first filter in the chain, the uncompressed size
given to the filter-specific encoder or decoder equals the
Uncompressed Size stored in the Block Header. For the rest of
the filters in the chain, uncompressed size is the size of the
output data of the previous filter in the chain.
Note that when Use End of Payload Marker bit is set in Block
Flags, Uncompressed Size is considered to be unknown even if
it was present in the Block Header. Thus, if End of Payload
Marker is used, uncompressed size of all of the filters in
the chain is unknown, and can never be used to detect when
all of the data has been decoded.
Once the correct number of bytes has been written out, the
filter-specific decoder indicates to its caller that all of
the data has been decoded. If the filter-specific decoder
detects End of Input or End of Payload Marker before the
correct number of bytes is decoded, the decoder must indicate
an error.
4.1.2. With End of Input
Most filters will know that all of the data has been decoded
when the End of Input data has been reached. Once the filter
knows that it has received the input data in its entirety,
it finishes its job, and indicates to its caller that all of
the data has been decoded. The filter-specific decoder must
indicate an error if it detects End of Payload Marker.
Note that this method can work only when the filter is not
the last filter in the chain, because only another filter
can indicate the End of Input data. In practice this means,
that a filter later in the chain must support embedding
End of Payload Marker.
When a filter that cannot embed End of Payload Marker is the
last filter in the chain, Subblock filter is appended to the
chain as an implicit filter. In the simplest case, this occurs
when no filters are specified, and the End of Payload Marker
bit is set in Block Flags.
4.1.3. With End of Payload Marker
End of Payload Marker is a filter-specific bit sequence that
indicates the end of data. It is supported by only a few
filters. It is used when uncompressed size is unknown, and
the filter
- doesn't support End of Input; or
- is the last filter in the chain.
End of Payload Marker is embedded at the end of the encoded
data by the filter-specific encoder. When the filter-specific
decoder detects the embedded End of Payload Marker, the decoder
knows that all of the data has been decoded. Then it finishes
its job, and indicates to its caller that all of the data has
been decoded. If the filter-specific decoder detects End of
Input before End of Payload Marker, the decoder must indicate
an error.
If the filter supports both End of Input and End of Payload
Marker, the former is used, unless the filter is the last
filter in the chain.
4.2. Alignment
Some filters give better compression ratio or are faster
when the input or output data is aligned. For optimal results,
the encoder should try to enforce proper alignment when
possible. Not enforcing alignment in the encoder is not
an error. Thus, the decoder must be able to handle files with
suboptimal alignment.
Alignment of uncompressed input data is usually the job of
the application producing the data. For example, to get the
best results, an archiver tool should make sure that all
PowerPC executable files in the archive stream start at
offsets that are multiples of four bytes.
Some filters, for example LZMA, can be configured to take
advantage of specified alignment of input data. Note that
taking advantage of aligned input can be benefical also when
a filter is not the first filter in the chain. For example,
if you compress PowerPC executables, you may want to use the
PowerPC filter and chain that with the LZMA filter. Because not
only the input but also the output alignment of the PowerPC
filter is four bytes, it is now benefical to set LZMA settings
so that the LZMA encoder can take advantage of its
four-byte-aligned input data.
The output of the last filter in the chain is stored to the
Compressed Data field. Aligning Compressed Data appropriately
can increase
- speed, if the filtered data is handled multiple bytes at
a time by the filter-specific encoder and decoder,
because accessing aligned data in computer memory is
usually faster; and
- compression ratio, if the output data is later compressed
with an external compression tool.
Compressed Data in a Stream can be aligned by using the Header
Padding field in the Block Header.
4.3. Filters
4.3.1. Copy
This is a dummy filter that simply copies all data from input
to output unmodified.
Filter ID: 0x00
Size of Filter Properties: 0 bytes
Changes size of data: No
Detecting when all of the data has been decoded:
Uncompressed size: Yes
End of Payload Marker: No
End of Input: Yes
Preferred alignment:
Input data: 1 byte
Output data: 1 byte
4.3.2. Subblock
The Subblock filter can be used to
- embed End of Payload Marker when the otherwise last
filter in the chain does not support embedding it; and
- apply additional filters in the middle of a Block.
Filter ID: 0x01
Size of Filter Properties: 0 bytes
Changes size of data: Yes, unpredictably
Detecting when all of the data has been decoded:
Uncompressed size: Yes
End of Payload Marker: Yes
End of Input: Yes
Preferred alignment:
Input data: 1 byte
Output data: Freely adjustable
4.3.2.1. Format of the Encoded Output
The encoded data from the Subblock filter consist of zero or
more Subblocks:
+==========+==========+
| Subblock | Subblock | ...
+==========+==========+
Each Subblock contains two fields:
+----------------+===============+
| Subblock Flags | Subblock Data |
+----------------+===============+
Subblock Flags is a bitfield:
Bits Mask Description
0-3 0x0F The interpretation of these bits depend on
the Subblock Type:
- 0x20 Bits 0-3 for Size
- 0x30 Bits 0-3 for Repeat Count
- Other These bits must be zero.
4-7 0xF0 Subblock Type:
- 0x00: Padding
- 0x10: End of Payload Marker
- 0x20: Data
- 0x30: Repeating Data
- 0x40: Set Subfilter
- 0x50: Unset Subfilter
If some other value is detected, the decoder
must indicate an error.
The format of the Subblock Data field depends on Subblock Type.
Subblocks with the Subblock Type 0x00 (Padding) don't have a
Subblock Data field. These Subblocks can be useful for fixing
alignment. There can be at maximum of 31 consecutive Subblocks
with this Subblock Type; if there are more, the decoder must
indicate an error.
Subblock with the Subblock Type 0x10 (End of Payload Marker)
doesn't have a Subblock Data field. The decoder must indicate
an error if this Subblock Type is detected when Subfilter is
enabled, or when the Subblock filter is not supposed to embed
the End of Payload Marker.
Subblocks with the Subblock Type 0x20 (Data) contain the rest
of the Size, which is followed by Size + 1 bytes in the Data
field (that is, Data can never be empty):
+------+------+------+======+
| Bits 4-27 for Size | Data |
+------+------+------+======+
Subblocks with the Subblock Type 0x30 (Repeating Data) contain
the rest of the Repeat Count, the Size of the Data, and finally
the actual Data to be repeated:
+---------+---------+--------+------+======+
| Bits 4-27 for Repeat Count | Size | Data |
+---------+---------+--------+------+======+
The size of the Data field is Size + 1. It is repeated Repeat
Count + 1 times. That is, the minimum size of Data is one byte;
the maximum size of Data is 256 bytes. The minimum number of
repeats is one; the maximum number of repeats is 2^28.
If Subfilter is not used, the Data field of Subblock Types 0x20
and 0x30 is the output of the decoded Subblock filter. If
Subfilter is used, Data is the input of the Subfilter, and the
decoded output of the Subfilter is the decoded output of the
Subblock filter.
Subblocks with the Subblock Type 0x40 (Set Subfilter) contain
a Filter Flags field in Subblock Data:
+==============+
| Filter Flags |
+==============+
It is an error to set the Subfilter to Filter ID 0x00 (Copy)
or 0x01 (Subblock). All the other Filter IDs are allowed.
The decoder must indicate an error if this Subblock Type is
detected when a Subfilter is already enabled.
Subblocks with the Subblock Type 0x50 (Unset Subfilter) don't
have a Subblock Data field. There must be at least one Subblock
with Subblock Type 0x20 or 0x30 between Subblocks with Subblock
Type 0x40 and 0x50; if there isn't, the decoder must indicate
an error.
Subblock Types 0x40 and 0x50 are always used as a pair: If the
Subblock filter has been enabled with Subblock Type 0x40, it
must always be disabled later with Subblock Type 0x50.
Disabling must be done even if the Subfilter used End of
Payload Marker; after the Subfilter has detected End of Payload
Marker, the next Subblock that is not Padding must unset the
Subfilter.
When the Subblock filter is used as an implicit filter to embed
End of Payload marker, the Subblock Types 0x40 and 0x50 (Set or
Unset Subfilter) must not be used. The decoder must indicate an
error if it detects any of these Subblock Types in an implicit
Subblock filter.
The following code illustrates the basic structure of a
Subblock decoder.
uint32_t consecutive_padding = 0;
bool got_output_with_subfilter = false;
while (true) {
uint32_t size;
uint32_t repeat;
uint8_t flags = read_byte();
if (flags != 0)
consecutive_padding = 0;
switch (flags >> 4) {
case 0:
// Padding
if (flags & 0x0F)
return DATA_ERROR;
if (++consecutive_padding == 32)
return DATA_ERROR;
break;
case 1:
// End of Payload Marker
if (flags & 0x0F)
return DATA_ERROR;
if (subfilter_enabled || !allow_eopm)
return DATA_ERROR;
break;
case 2:
// Data
size = flags & 0x0F;
for (size_t i = 4; i < 28; i += 8)
size |= (uint32_t)(read_byte()) << i;
// If any output is produced, this will
// set got_output_with_subfilter to true.
copy_data(size);
break;
case 3:
// Repeating Data
repeat = flags & 0x0F;
for (size_t i = 4; i < 28; i += 8)
repeat |= (uint32_t)(read_byte()) << i;
size = read_byte();
// If any output is produced, this will
// set got_output_with_subfilter to true.
copy_repeating_data(size, repeat);
break;
case 4:
// Set Subfilter
if (flags & 0x0F)
return DATA_ERROR;
if (subfilter_enabled)
return DATA_ERROR;
got_output_with_subfilter = false;
set_subfilter();
break;
case 5:
// Unset Subfilter
if (flags & 0x0F)
return DATA_ERROR;
if (!subfilter_enabled)
return DATA_ERROR;
if (!got_output_with_subfilter)
return DATA_ERROR;
unset_subfilter();
break;
default:
return DATA_ERROR;
}
}
4.3.3. Delta
The Delta filter may increase compression ratio when the value
of the next byte correlates with the value of an earlier byte
at specified distance.
Filter ID: 0x20
Size of Filter Properties: 1 byte
Changes size of data: No
Detecting when all of the data has been decoded:
Uncompressed size: Yes
End of Payload Marker: No
End of Input: Yes
Preferred alignment:
Input data: 1 byte
Output data: Same as the original input data
The Properties byte indicates the delta distance, which can be
1-256 bytes backwards from the current byte: 0x00 indicates
distance of 1 byte and 0xFF distance of 256 bytes.
4.3.3.1. Format of the Encoded Output
The code below illustrates both encoding and decoding with
the Delta filter.
// Distance is in the range [1, 256].
const unsigned int distance = get_properties_byte() + 1;
uint8_t pos = 0;
uint8_t delta[256];
memset(delta, 0, sizeof(delta));
while (1) {
const int byte = read_byte();
if (byte == EOF)
break;
uint8_t tmp = delta[(uint8_t)(distance + pos)];
if (is_encoder) {
tmp = (uint8_t)(byte) - tmp;
delta[pos] = (uint8_t)(byte);
} else {
tmp = (uint8_t)(byte) + tmp;
delta[pos] = tmp;
}
write_byte(tmp);
--pos;
}
4.3.4. LZMA
LZMA (Lempel-Ziv-Markov chain-Algorithm) is a general-purporse
compression algorithm with high compression ratio and fast
decompression. LZMA based on LZ77 and range coding algorithms.
Filter ID: 0x40
Size of Filter Properties: 2 bytes
Changes size of data: Yes, unpredictably
Detecting when all of the data has been decoded:
Uncompressed size: Yes
End of Payload Marker: Yes
End of Input: No
Preferred alignment:
Input data: Adjustable to 1/2/4/8/16 byte(s)
Output data: 1 byte
At the time of writing, there is no other documentation about
how LZMA works than the source code in LZMA SDK. Once such
documentation gets written, it will probably be published as
a separate document, because including the documentation here
would lengthen this document considerably.
The format of the Filter Properties field is as follows:
+-----------------+------------------+
| LZMA Properties | Dictionary Flags |
+-----------------+------------------+
4.3.4.1. LZMA Properties
The LZMA Properties field contains three properties. An
abbreviation is given in parentheses, followed by the value
range of the property. The field consists of
1) the number of literal context bits (lc, [0, 8]);
2) the number of literal position bits (lp, [0, 4]); and
3) the number of position bits (pb, [0, 4]).
They are encoded using the following formula:
LZMA Properties = (pb * 5 + lp) * 9 + lc
The following C code illustrates a straightforward way to
decode the properties:
uint8_t lc, lp, pb;
uint8_t prop = get_lzma_properties() & 0xFF;
if (prop > (4 * 5 + 4) * 9 + 8)
return LZMA_PROPERTIES_ERROR;
pb = prop / (9 * 5);
prop -= pb * 9 * 5;
lp = prop / 9;
lc = prop - lp * 9;
4.3.4.2. Dictionary Flags
Currently the lowest six bits of the Dictionary Flags field
are in use:
Bits Mask Description
0-5 0x3F Dictionary Size
6-7 0xC0 Reserved for future use; must be zero for now.
Dictionary Size is encoded with one-bit mantissa and five-bit
exponent. To avoid wasting space, one-byte dictionary has its
own special value.
Raw value Mantissa Exponent Dictionary size
0 1 0 1 byte
1 2 0 2 bytes
2 3 0 3 bytes
3 2 1 4 bytes
4 3 1 6 bytes
5 2 2 8 bytes
6 3 2 12 bytes
7 2 3 16 bytes
8 3 3 24 bytes
9 2 4 32 bytes
... ... ... ...
61 2 30 2 GiB
62 3 30 3 GiB
63 2 31 4 GiB (*)
(*) The real maximum size of the dictionary is one byte
less than 4 GiB, because the distance of 4 GiB is
reserved for End of Payload Marker.
Instead of having a table in the decoder, the dictionary size
can be decoded using the following C code:
uint64_t dictionary_size;
const uint8_t bits = get_dictionary_flags() & 0x3F;
if (bits == 0) {
dictionary_size = 1;
} else {
dictionary_size = 2 | ((bits + 1) & 1);
dictionary_size = dictionary_size << ((bits - 1) / 2);
}
4.3.5. Branch/Call/Jump Filters for Executables
These filters convert relative branch, call, and jump
instructions to their absolute counterparts in executable
files. This conversion increases redundancy and thus
compression ratio.
Size of Filter Properties: 0 or 4 bytes
Changes size of data: No
Detecting when all of the data has been decoded:
Uncompressed size: Yes
End of Payload Marker: No
End of Input: Yes
Below is the list of filters in this category. The alignment
is the same for both input and output data.
Filter ID Alignment Description
0x04 1 byte x86 filter (BCJ)
0x05 4 bytes PowerPC (big endian) filter
0x06 16 bytes IA64 filter
0x07 4 bytes ARM (little endian) filter
0x08 2 bytes ARM Thumb (little endian) filter
0x09 4 bytes SPARC filter
If the size of Filter Properties is four bytes, the Filter
Properties field contains the start offset used for address
conversions. It is stored as an unsigned 32-bit little endian
integer. If the size of Filter Properties is zero, the start
offset is zero.
Setting the start offset may be useful if an executable has
multiple sections, and there are many cross-section calls.
Taking advantage of this feature usually requires usage of
the Subblock filter.
5. Metadata
Metadata is stored in Metadata Blocks, which can be in the
beginning or at the end of a Multi-Block Stream. Because of
Blocks, it is possible to compress Metadata in the same way
as the actual data is compressed. This Section describes the
format of the data stored in Metadata Blocks.
+----------------+===============================+
| Metadata Flags | Size of Header Metadata Block |
+----------------+===============================+
+============+===================+=======+=======+
---> | Total Size | Uncompressed Size | Index | Extra |
+============+===================+=======+=======+
Stream must be parseable backwards. That is, there must be
a way to locate the beginning of the Stream by starting from
the end of the Stream. Thus, the Footer Metadata Block must
contain the Total Size field or the Index field. If the Stream
has Header Metadata Block, also the Size of Header Metadata
Block field must be present in Footer Metadata Block.
It must be possible to quickly locate the Blocks in
non-streamed mode. Thus, the Index field must be present
at least in one Metadata Block.
If the above conditions are not met, the decoder must indicate
an error.
There should be no additional data after the last field. If
there is, the the decoder should indicate an error.
5.1. Metadata Flags
This field describes which fields are present in a Metadata
Block:
Bit(s) Mask Desription
0 0x01 Size of Header Metadata Block is present.
1 0x02 Total Size is present.
2 0x04 Uncompressed Size is present.
3 0x08 Index is present.
4-6 0x70 Reserve for future use; must be zero for now.
7 0x80 Extra is present.
If any reserved bit is set, the decoder must indicate an error.
It is possible that there is a new field present which the
decoder is not aware of, and can thus parse the Metadata
incorrectly.
5.2. Size of Header Metadata Block
This field is present only if the appropriate bit is set in
the Metadata Flags field (see Section 5.1).
Size of Header Metadata Block is needed to make it possible to
parse the Stream backwards. The size is stored using the
encoding described in Section 1.2. The decoder must verify that
that the value stored in this field is non-zero. In Footer
Metadata Block, the decoder must also verify that the stored
size matches the real size of Header Metadata Block. In the
Header Meatadata Block, the value of this field is ignored as
long as it is not zero.
5.3. Total Size
This field is present only if the appropriate bit is set in the
Metadata Flags field (see Section 5.1).
This field contains the total size of the Data Blocks in the
Stream. Total Size is stored using the encoding described in
Section 1.2. If the stored value does not match the real total
size of the Data Blocks, the decoder must indicate an error.
The value of this field must be non-zero.
Total Size can be used to quickly locate the beginning or end
of the Stream. This can be useful for example when doing
random-access reading, and the Index field is not in the
Metadata Block currently being read.
It is useless to have both Total Size and Index in the same
Metadata Block, because Total Size can be calculated from the
Index field.
5.4. Uncompressed Size
This field is present only if the appropriate bit is set in the
Metadata Flags field (see Section 5.1).
This field contains the total uncompressed size of the Data
Blocks in the Stream. Uncompresssed Size is stored using the
encoding described in Section 1.2. If the stored value does not
match the real uncompressed size of the Data Blocks, the
decoder must indicate an error.
It is useless to have both Uncompressed Size and Index in
the same Metadata Block, because Uncompressed Size can be
calculated from the Index field.
5.5. Index
+=======================+=============+====================+
| Number of Data Blocks | Total Sizes | Uncompressed Sizes |
+=======================+=============+====================+
Index serves several purporses. Using it, one can
- verify that all Blocks in a Stream have been processed;
- find out the Uncompressed Size of a Stream; and
- quickly access the beginning of any Block (random access).
5.5.1. Number of Data Blocks
This field contains the number of Data Blocks in the Stream.
The value is stored using the encoding described in Section
1.2. If the decoder has decoded all the Data Blocks of the
Stream, and then notices that the Number of Records doesn't
match the real number of Data Blocks, the decoder must
indicate an error. The value of this field must be non-zero.
5.5.2. Total Sizes
+============+============+
| Total Size | Total Size | ...
+============+============+
This field lists the Total Sizes of every Data Block in the
Stream. There are as many Total Size fields as indicated by
the Number of Data Blocks field.
Total Size is the size of Block Header, Compressed Data, and
Block Footer. It is stored using the encoding described in
Section 1.2. If the Total Sizes do not match the real sizes
of respective Blocks, the decoder should indicate an error.
All the Total Size fields must have a non-zero value.
5.5.3. Uncompressed Sizes
+===================+===================+
| Uncompressed Size | Uncompressed Size | ...
+===================+===================+
This field lists the Uncompressed Sizes of every Data Block
in the Stream. There are as many Uncompressed Size fields as
indicated by the Number of Records field.
Uncompressed Sizes are stored using the encoding described
in Section 1.2. If the Uncompressed Sizes do not match the
real sizes of respective Blocks, the decoder shoud indicate
an error.
5.6. Extra
This field is present only if the appropriate bit is set in the
Metadata Flags field (see Section 5.1). Note that the bit does
not indicate that there is any data in the Extra field; it only
indicates that Extra may be non-empty.
The Extra field contains only information that is not required
to properly uncompress the Stream or to do random-access
reading. Supporting the Extra field is optional. In case the
decoder doesn't support the Extra field, it should silently
ignore it.
Extra consists of zero or more Records:
+========+========+
| Record | Record | ...
+========+========+
Excluding Records with Record ID 0x00, each Record contains
three fields:
+==========+==============+======+
| Reord ID | Size of Data | Data |
+==========+==============+======+
The Record ID and Size of Data are stored using the encoding
described in Section 1.2. Data can be binary or UTF-8
[RFC-3629] strings. Non-UTF-8 strings should be avoided.
Because the Size of Data is known, there is no need to
terminate strings with a nul byte, although doing so should
not be considered an error.
The Record IDs are divided in two categories:
- Safe-to-Copy Records may be preserved as is when the
Stream is modified in ways that don't change the actual
uncompressed data. Examples of such operatings include
recompressing and adding, modifying, or deleting unrelated
Extra Records.
- Unsafe-to-Copy Records should be removed (and possibly
recreated) when any kind of changes are made to the Stream.
When the actual uncompressed data is modified, all Records
should be removed (and possibly recreated), unless the
application knows that the Data stored to the Record(s) is
still valid.
The following subsections describe the standard Record IDs and
the format of their Data fields. Safe-to-Copy Records have an
odd ID, while Unsafe-to-Copy Records have an even ID.
5.6.1. 0x00: Dummy/Padding
This Record is special, because it doesn't have the Size of
Data or Data fields.
Dummy Records can be used, for example, to fill Metadata Block
when a few bytes of extra space has been reserved for it. There
can be any number of Dummy Records.
5.6.2. 0x01: OpenPGP Signature
OpenPGP signature is computed from uncompressed data. The
signature can be used to verify that the contents of a Stream
has been created by a trustworthy source.
If the decoder supports decoding concatenated Streams, it
must indicate an error when verifying OpenPGP signatures if
there is more than one Stream.
OpenPGP format is documented in [RFC-2440].
5.6.3. 0x02: Filter Information
The Filter Information Record contains information about the
filters used in the Stream. This field can be used to quickly
- display which filters are used in each Block;
- check if all the required filters are supported by the
current decoder version; and
- check how much memory is required to decode each Block.
The format of the Filter Information field is as follows:
+=================+=================+
| Block 0 Filters | Block 1 Filters | ...
+=================+=================+
There can be at maximum of as many Block Filters fields as
there are Data Blocks in the Stream. The format of the Block
Filters field is as follows:
+------------------+======================+============+
| Block Properties | List of Filter Flags | Subfilters |
+------------------+======================+============+
Block Properties is a bitfield:
Bit(s) Mask Description
0-2 0x07 Number of filters (0-7)
3 0x08 End of Payload Marker is used.
4 0x10 The Subfilters field is present.
5-7 0xE0 Reserved for future use; must be zero for now.
The contents of the List of Filter Flags field must match the
List of Filter Flags field in the respective Block Header.
The Subfilters field may be present only if the List of Filter
Flags contains a Filter Flags field for a Subblock filter. The
format of the Subfilters field is as follows:
+======================+=========================+
| Number of Subfilters | List of Subfilter Flags |
+======================+=========================+
The value stored in the Number of Subfilters field is stored
using the encoding described in Section 1.2. The List of
Subfilter Flags field contains as many Filter Flags fields
as indicated by the Number of Subfilters field. These Filter
Flags fields list some or all the Subfilters used via the
Subblock filter. The order of the listed Subfilters is not
significant.
Decoders supporting this Record should indicate a warning or
error if this Record contains Filter Flags that are not
actually used by the respective Blocks.
5.6.4. 0x03: Comment
Free-form comment is stored in UTF-8 [RFC-3629] encoding.
The beginning of a new line should be indicated using the
ASCII Line Feed character (0x0A). When the Line Feed character
is not the native way to indicate new line in the underlying
operating system, the encoder and decoder should convert the
newline characters to and from Line Feeds.
5.6.5. 0x04: List of Checks
+=======+=======+
| Check | Check | ...
+=======+=======+
There are as many Check fields as there are Blocks in the
Stream. The size of Check fields depend on Stream Flags
(see Section 2.2.2).
Decoders supporting this Record should indicate a warning or
error if the Checks don't match the respective Blocks.
5.6.6. 0x05: Original Filename
Original filename is stored in UTF-8 [RFC-3629] encoding.
The filename must not include any path, only the filename
itself. Special care must be taken to prevent directory
traversal vulnerabilities.
When files are moved between different operating systems, it
is possible that filename valid in the source system is not
valid in the target system. It is implementation defined how
the decoder handles this kind of situations.
5.6.7. 0x07: Modification Time
Modification time is stored as POSIX time, as an unsigned
little endian integer. The number of bits depends on the
Size of Data field. Note that the usage of unsigned integer
limits the earliest representable time to 1970-01-01T00:00:00.
5.6.8. 0x09: High-Resolution Modification Time
This Record extends the `0x04: Modification time' Record with
a subsecond time information. There are two supported formats
of this field, which can be distinguished by looking at the
Size of Data field.
Size Data
3 [0; 9,999,999] times 100 nanoseconds
4 [0; 999,999,999] nanoseconds
The value is stored as an unsigned 24-bit or 32-bit little
endian integer.
5.6.9. 0x0B: MIME Type
MIME type of the uncompressed Stream. This can be used to
detect the content type. [IANA-MIME]
5.6.10. 0x0D: Homepage URL
This field can be used, for example, when distributing software
packages (sources or binaries). The field would indicate the
homepage of the program.
For details on how to encode URLs, see [RFC-1738].
6. Custom Filter and Extra Record IDs
If a developer wants to use custom Filter or Extra Record IDs,
he has two choices. The first choice is to contact Lasse Collin
and ask him to allocate a range of IDs for the developer.
The second choice is to generate a 40-bit random integer,
which the developer can use as his personal Developer ID.
To minimalize the risk of collisions, Developer ID has to be
a randomly generated integer, not manually selected "hex word".
The following command, which works on many free operating
systems, can be used to generate Developer ID:
dd if=/dev/urandom bs=5 count=1 | hexdump
The developer can then use his Developer ID to create unique
(well, hopefully unique) Filter and Extra Record IDs.
Bits Mask Description
0-15 0x0000_0000_0000_FFFF Filter or Extra Record ID
16-55 0x00FF_FFFF_FFFF_0000 Developer ID
56-62 0x7F00_0000_0000_0000 Static prefix: 0x7F
The resulting 63-bit integer will use 9 bytes of space when
stored using the encoding described in Section 1.2. To get
a shorter ID, see the beginning of this Section how to
request a custom ID range.
Note that Filter and Metadata Record IDs are in their own
namespaces. That is, you can use the same ID value as Filter ID
and Metadata Record ID, and the meanings of the IDs do not need
to be related to each other.
6.1. Reserved Custom Filter ID Ranges
Range Description
0x0000_0000 - 0x0000_00DF IDs fitting into the Misc field
0x0002_0000 - 0x0007_FFFF Reserved to ease .7z compatibility
0x0200_0000 - 0x07FF_FFFF Reserved to ease .7z compatibility
7. Cyclic Redundancy Checks
There are several incompatible variations to calculate CRC32
and CRC64. For simplicity and clarity, complete examples are
provided to calculate the checks as they are used in this file
format. Implementations may use different code as long as it
gives identical results.
The program below reads data from standard input, calculates
the CRC32 and CRC64 values, and prints the calculated values
as big endian hexadecimal strings to standard output.
#include <sys/types.h>
#include <inttypes.h>
#include <stdio.h>
uint32_t crc32_table[256];
uint64_t crc64_table[256];
void
init(void)
{
static const uint32_t poly32 = UINT32_C(0xEDB88320);
static const uint64_t poly64
= UINT64_C(0xC96C5795D7870F42);
for (size_t i = 0; i < 256; ++i) {
uint32_t crc32 = i;
uint64_t crc64 = i;
for (size_t j = 0; j < 8; ++j) {
if (crc32 & 1)
crc32 = (crc32 >> 1) ^ poly32;
else
crc32 >>= 1;
if (crc64 & 1)
crc64 = (crc64 >> 1) ^ poly64;
else
crc64 >>= 1;
}
crc32_table[i] = crc32;
crc64_table[i] = crc64;
}
}
uint32_t
crc32(const uint8_t *buf, size_t size, uint32_t crc)
{
crc = ~crc;
for (size_t i = 0; i < size; ++i)
crc = crc32_table[buf[i] ^ (crc & 0xFF)]
^ (crc >> 8);
return ~crc;
}
uint64_t
crc64(const uint8_t *buf, size_t size, uint64_t crc)
{
crc = ~crc;
for (size_t i = 0; i < size; ++i)
crc = crc64_table[buf[i] ^ (crc & 0xFF)]
^ (crc >> 8);
return ~crc;
}
int
main()
{
init();
uint32_t value32 = 0;
uint64_t value64 = 0;
uint64_t total_size = 0;
uint8_t buf[8192];
while (1) {
const size_t buf_size = fread(buf, 1, 8192, stdin);
if (buf_size == 0)
break;
total_size += buf_size;
value32 = crc32(buf, buf_size, value32);
value64 = crc64(buf, buf_size, value64);
}
printf("Bytes: %" PRIu64 "\n", total_size);
printf("CRC-32: 0x%08" PRIX32 "\n", value32);
printf("CRC-64: 0x%016" PRIX64 "\n", value64);
return 0;
}
8. References
8.1. Normative References
[RFC-1738]
Uniform Resource Locators (URL)
http://www.ietf.org/rfc/rfc1738.txt
[RFC-2119]
Key words for use in RFCs to Indicate Requirement Levels
http://www.ietf.org/rfc/rfc2119.txt
[RFC-2440]
OpenPGP Message Format
http://www.ietf.org/rfc/rfc2440.txt
[RFC-3629]
UTF-8, a transformation format of ISO 10646
http://www.ietf.org/rfc/rfc3629.txt
[IANA-MIME]
MIME Media Types
http://www.iana.org/assignments/media-types/
8.2. Informative References
LZMA SDK - The original LZMA implementation
http://7-zip.org/sdk.html
LZMA Utils - LZMA adapted to POSIX-like systems
http://tukaani.org/lzma/
[RFC-1952]
GZIP file format specification version 4.3
http://www.ietf.org/rfc/rfc1952.txt
- Notation of byte boxes in section `2.1. Overall conventions'
[GNU-tar]
GNU tar 1.16.1 manual
http://www.gnu.org/software/tar/manual/html_node/Blocking-Factor.html
- Node 9.4.2 `Blocking Factor', paragraph that begins
`gzip will complain about trailing garbage'
- Note that this URL points to the latest version of the
manual, and may some day not contain the note which is in
1.16.1. For the exact version of the manual, download GNU
tar 1.16.1: ftp://ftp.gnu.org/pub/gnu/tar/tar-1.16.1.tar.gz