LIBARCHIVE_INTERNALS
Section: C Library Functions (3)
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NAME
libarchive_internals
- description of libarchive internal interfaces
OVERVIEW
The
libarchive
library provides a flexible interface for reading and writing
streaming archive files such as tar and cpio.
Internally, it follows a modular layered design that should
make it easy to add new archive and compression formats.
GENERAL ARCHITECTURE
Externally, libarchive exposes most operations through an
opaque, object-style interface.
The
archive_entry3
objects store information about a single filesystem object.
The rest of the library provides facilities to write
archive_entry3
objects to archive files,
read them from archive files,
and write them to disk.
(There are plans to add a facility to read
archive_entry3
objects from disk as well.)
The read and write APIs each have four layers: a public API
layer, a format layer that understands the archive file format,
a compression layer, and an I/O layer.
The I/O layer is completely exposed to clients who can replace
it entirely with their own functions.
In order to provide as much consistency as possible for clients,
some public functions are virtualized.
Eventually, it should be possible for clients to open
an archive or disk writer, and then use a single set of
code to select and write entries, regardless of the target.
READ ARCHITECTURE
From the outside, clients use the
archive_read3
API to manipulate an
archive
object to read entries and bodies from an archive stream.
Internally, the
archive
object is cast to an
archive_read
object, which holds all read-specific data.
The API has four layers:
The lowest layer is the I/O layer.
This layer can be overridden by clients, but most clients use
the packaged I/O callbacks provided, for example, by
archive_read_open_memory3,
and
archive_read_open_fd3.
The compression layer calls the I/O layer to
read bytes and decompresses them for the format layer.
The format layer unpacks a stream of uncompressed bytes and
creates
archive_entry
objects from the incoming data.
The API layer tracks overall state
(for example, it prevents clients from reading data before reading a header)
and invokes the format and compression layer operations
through registered function pointers.
In particular, the API layer drives the format-detection process:
When opening the archive, it reads an initial block of data
and offers it to each registered compression handler.
The one with the highest bid is initialized with the first block.
Similarly, the format handlers are polled to see which handler
is the best for each archive.
(Prior to 2.4.0, the format bidders were invoked for each
entry, but this design hindered error recovery.)
I/O Layer and Client Callbacks
The read API goes to some lengths to be nice to clients.
As a result, there are few restrictions on the behavior of
the client callbacks.
The client read callback is expected to provide a block
of data on each call.
A zero-length return does indicate end of file, but otherwise
blocks may be as small as one byte or as large as the entire file.
In particular, blocks may be of different sizes.
The client skip callback returns the number of bytes actually
skipped, which may be much smaller than the skip requested.
The only requirement is that the skip not be larger.
In particular, clients are allowed to return zero for any
skip that they don't want to handle.
The skip callback must never be invoked with a negative value.
Keep in mind that not all clients are reading from disk:
clients reading from networks may provide different-sized
blocks on every request and cannot skip at all;
advanced clients may use
mmap(2)
to read the entire file into memory at once and return the
entire file to libarchive as a single block;
other clients may begin asynchronous I/O operations for the
next block on each request.
Decompresssion Layer
The decompression layer not only handles decompression,
it also buffers data so that the format handlers see a
much nicer I/O model.
The decompression API is a two stage peek/consume model.
A read_ahead request specifies a minimum read amount;
the decompression layer must provide a pointer to at least
that much data.
If more data is immediately available, it should return more:
the format layer handles bulk data reads by asking for a minimum
of one byte and then copying as much data as is available.
A subsequent call to the
Fn consume
function advances the read pointer.
Note that data returned from a
Fn read_ahead
call is guaranteed to remain in place until
the next call to
Fn read_ahead .
Intervening calls to
Fn consume
should not cause the data to move.
Skip requests must always be handled exactly.
Decompression handlers that cannot seek forward should
not register a skip handler;
the API layer fills in a generic skip handler that reads and discards data.
A decompression handler has a specific lifecycle:
- Registration/Configuration
-
When the client invokes the public support function,
the decompression handler invokes the internal
Fn __archive_read_register_compression
function to provide bid and initialization functions.
This function returns
NULL
on error or else a pointer to a
struct decompressor_t
This structure contains a
void * config
slot that can be used for storing any customization information.
- Bid
-
The bid function is invoked with a pointer and size of a block of data.
The decompressor can access its config data
through the
decompressor
element of the
archive_read
object.
The bid function is otherwise stateless.
In particular, it must not perform any I/O operations.
The value returned by the bid function indicates its suitability
for handling this data stream.
A bid of zero will ensure that this decompressor is never invoked.
Return zero if magic number checks fail.
Otherwise, your initial implementation should return the number of bits
actually checked.
For example, if you verify two full bytes and three bits of another
byte, bid 19.
Note that the initial block may be very short;
be careful to only inspect the data you are given.
(The current decompressors require two bytes for correct bidding.)
- Initialize
-
The winning bidder will have its init function called.
This function should initialize the remaining slots of the
struct decompressor_t
object pointed to by the
decompressor
element of the
archive_read
object.
In particular, it should allocate any working data it needs
in the
data
slot of that structure.
The init function is called with the block of data that
was used for tasting.
At this point, the decompressor is responsible for all I/O
requests to the client callbacks.
The decompressor is free to read more data as and when
necessary.
- Satisfy I/O requests
-
The format handler will invoke the
read_ahead
consume
and
skip
functions as needed.
- Finish
-
The finish method is called only once when the archive is closed.
It should release anything stored in the
data
and
config
slots of the
decompressor
object.
It should not invoke the client close callback.
Format Layer
The read formats have a similar lifecycle to the decompression handlers:
- Registration
-
Allocate your private data and initialize your pointers.
- Bid
-
Formats bid by invoking the
Fn read_ahead
decompression method but not calling the
Fn consume
method.
This allows each bidder to look ahead in the input stream.
Bidders should not look further ahead than necessary, as long
look aheads put pressure on the decompression layer to buffer
lots of data.
Most formats only require a few hundred bytes of look ahead;
look aheads of a few kilobytes are reasonable.
(The ISO9660 reader sometimes looks ahead by 48k, which
should be considered an upper limit.)
- Read header
-
The header read is usually the most complex part of any format.
There are a few strategies worth mentioning:
For formats such as tar or cpio, reading and parsing the header is
straightforward since headers alternate with data.
For formats that store all header data at the beginning of the file,
the first header read request may have to read all headers into
memory and store that data, sorted by the location of the file
data.
Subsequent header read requests will skip forward to the
beginning of the file data and return the corresponding header.
- Read Data
-
The read data interface supports sparse files; this requires that
each call return a block of data specifying the file offset and
size.
This may require you to carefully track the location so that you
can return accurate file offsets for each read.
Remember that the decompressor will return as much data as it has.
Generally, you will want to request one byte,
examine the return value to see how much data is available, and
possibly trim that to the amount you can use.
You should invoke consume for each block just before you return it.
- Skip All Data
-
The skip data call should skip over all file data and trailing padding.
This is called automatically by the API layer just before each
header read.
It is also called in response to the client calling the public
Fn data_skip
function.
- Cleanup
-
On cleanup, the format should release all of its allocated memory.
API Layer
XXX to do XXX
WRITE ARCHITECTURE
The write API has a similar set of four layers:
an API layer, a format layer, a compression layer, and an I/O layer.
The registration here is much simpler because only
one format and one compression can be registered at a time.
I/O Layer and Client Callbacks
XXX To be written XXX
Compression Layer
XXX To be written XXX
Format Layer
XXX To be written XXX
API Layer
XXX To be written XXX
WRITE_DISK ARCHITECTURE
The write_disk API is intended to look just like the write API
to clients.
Since it does not handle multiple formats or compression, it
is not layered internally.
GENERAL SERVICES
The
archive_read
archive_write
and
archive_write_disk
objects all contain an initial
archive
object which provides common support for a set of standard services.
(Recall that ANSI/ISO C90 guarantees that you can cast freely between
a pointer to a structure and a pointer to the first element of that
structure.)
The
archive
object has a magic value that indicates which API this object
is associated with,
slots for storing error information,
and function pointers for virtualized API functions.
MISCELLANEOUS NOTES
Connecting existing archiving libraries into libarchive is generally
quite difficult.
In particular, many existing libraries strongly assume that you
are reading from a file; they seek forwards and backwards as necessary
to locate various pieces of information.
In contrast, libarchive never seeks backwards in its input, which
sometimes requires very different approaches.
For example, libarchive's ISO9660 support operates very differently
from most ISO9660 readers.
The libarchive support utilizes a work-queue design that
keeps a list of known entries sorted by their location in the input.
Whenever libarchive's ISO9660 implementation is asked for the next
header, checks this list to find the next item on the disk.
Directories are parsed when they are encountered and new
items are added to the list.
This design relies heavily on the ISO9660 image being optimized so that
directories always occur earlier on the disk than the files they
describe.
Depending on the specific format, such approaches may not be possible.
The ZIP format specification, for example, allows archivers to store
key information only at the end of the file.
In theory, it is possible to create ZIP archives that cannot
be read without seeking.
Fortunately, such archives are very rare, and libarchive can read
most ZIP archives, though it cannot always extract as much information
as a dedicated ZIP program.
SEE ALSO
archive_entry3,
archive_read3,
archive_write3,
archive_write_disk3
libarchive(3),
HISTORY
The
libarchive
library first appeared in
Fx 5.3 .
AUTHORS
An -nosplit
The
libarchive
library was written by
An Tim Kientzle Aq
kientzle@acm.org .
Index
- NAME
-
- OVERVIEW
-
- GENERAL ARCHITECTURE
-
- READ ARCHITECTURE
-
- I/O Layer and Client Callbacks
-
- Decompresssion Layer
-
- Format Layer
-
- API Layer
-
- WRITE ARCHITECTURE
-
- I/O Layer and Client Callbacks
-
- Compression Layer
-
- Format Layer
-
- API Layer
-
- WRITE_DISK ARCHITECTURE
-
- GENERAL SERVICES
-
- MISCELLANEOUS NOTES
-
- SEE ALSO
-
- HISTORY
-
- AUTHORS
-