Provided by: libarchive-dev_3.4.0-2ubuntu1.4_amd64 bug

NAME

     tar — format of tape archive files

DESCRIPTION

     The tar archive format collects any number of files, directories, and other file system
     objects (symbolic links, device nodes, etc.) into a single stream of bytes.  The format was
     originally designed to be used with tape drives that operate with fixed-size blocks, but is
     widely used as a general packaging mechanism.

   General Format
     A tar archive consists of a series of 512-byte records.  Each file system object requires a
     header record which stores basic metadata (pathname, owner, permissions, etc.) and zero or
     more records containing any file data.  The end of the archive is indicated by two records
     consisting entirely of zero bytes.

     For compatibility with tape drives that use fixed block sizes, programs that read or write
     tar files always read or write a fixed number of records with each I/O operation.  These
     “blocks” are always a multiple of the record size.  The maximum block size supported by
     early implementations was 10240 bytes or 20 records.  This is still the default for most
     implementations although block sizes of 1MiB (2048 records) or larger are commonly used with
     modern high-speed tape drives.  (Note: the terms “block” and “record” here are not entirely
     standard; this document follows the convention established by John Gilmore in documenting
     pdtar.)

   Old-Style Archive Format
     The original tar archive format has been extended many times to include additional
     information that various implementors found necessary.  This section describes the variant
     implemented by the tar command included in Version 7 AT&T UNIX, which seems to be the
     earliest widely-used version of the tar program.

     The header record for an old-style tar archive consists of the following:

           struct header_old_tar {
                   char name[100];
                   char mode[8];
                   char uid[8];
                   char gid[8];
                   char size[12];
                   char mtime[12];
                   char checksum[8];
                   char linkflag[1];
                   char linkname[100];
                   char pad[255];
           };
     All unused bytes in the header record are filled with nulls.

     name    Pathname, stored as a null-terminated string.  Early tar implementations only stored
             regular files (including hardlinks to those files).  One common early convention
             used a trailing "/" character to indicate a directory name, allowing directory
             permissions and owner information to be archived and restored.

     mode    File mode, stored as an octal number in ASCII.

     uid, gid
             User id and group id of owner, as octal numbers in ASCII.

     size    Size of file, as octal number in ASCII.  For regular files only, this indicates the
             amount of data that follows the header.  In particular, this field was ignored by
             early tar implementations when extracting hardlinks.  Modern writers should always
             store a zero length for hardlink entries.

     mtime   Modification time of file, as an octal number in ASCII.  This indicates the number
             of seconds since the start of the epoch, 00:00:00 UTC January 1, 1970.  Note that
             negative values should be avoided here, as they are handled inconsistently.

     checksum
             Header checksum, stored as an octal number in ASCII.  To compute the checksum, set
             the checksum field to all spaces, then sum all bytes in the header using unsigned
             arithmetic.  This field should be stored as six octal digits followed by a null and
             a space character.  Note that many early implementations of tar used signed
             arithmetic for the checksum field, which can cause interoperability problems when
             transferring archives between systems.  Modern robust readers compute the checksum
             both ways and accept the header if either computation matches.

     linkflag, linkname
             In order to preserve hardlinks and conserve tape, a file with multiple links is only
             written to the archive the first time it is encountered.  The next time it is
             encountered, the linkflag is set to an ASCII ‘1’ and the linkname field holds the
             first name under which this file appears.  (Note that regular files have a null
             value in the linkflag field.)

     Early tar implementations varied in how they terminated these fields.  The tar command in
     Version 7 AT&T UNIX used the following conventions (this is also documented in early BSD
     manpages): the pathname must be null-terminated; the mode, uid, and gid fields must end in a
     space and a null byte; the size and mtime fields must end in a space; the checksum is
     terminated by a null and a space.  Early implementations filled the numeric fields with
     leading spaces.  This seems to have been common practice until the IEEE Std 1003.1-1988
     (“POSIX.1”) standard was released.  For best portability, modern implementations should fill
     the numeric fields with leading zeros.

   Pre-POSIX Archives
     An early draft of IEEE Std 1003.1-1988 (“POSIX.1”) served as the basis for John Gilmore's
     pdtar program and many system implementations from the late 1980s and early 1990s.  These
     archives generally follow the POSIX ustar format described below with the following
     variations:
            The magic value consists of the five characters “ustar” followed by a space.  The
             version field contains a space character followed by a null.
            The numeric fields are generally filled with leading spaces (not leading zeros as
             recommended in the final standard).
            The prefix field is often not used, limiting pathnames to the 100 characters of old-
             style archives.

   POSIX ustar Archives
     IEEE Std 1003.1-1988 (“POSIX.1”) defined a standard tar file format to be read and written
     by compliant implementations of tar(1).  This format is often called the “ustar” format,
     after the magic value used in the header.  (The name is an acronym for “Unix Standard TAR”.)
     It extends the historic format with new fields:

           struct header_posix_ustar {
                   char name[100];
                   char mode[8];
                   char uid[8];
                   char gid[8];
                   char size[12];
                   char mtime[12];
                   char checksum[8];
                   char typeflag[1];
                   char linkname[100];
                   char magic[6];
                   char version[2];
                   char uname[32];
                   char gname[32];
                   char devmajor[8];
                   char devminor[8];
                   char prefix[155];
                   char pad[12];
           };

     typeflag
             Type of entry.  POSIX extended the earlier linkflag field with several new type
             values:
             “0”     Regular file.  NUL should be treated as a synonym, for compatibility
                     purposes.
             “1”     Hard link.
             “2”     Symbolic link.
             “3”     Character device node.
             “4”     Block device node.
             “5”     Directory.
             “6”     FIFO node.
             “7”     Reserved.
             Other   A POSIX-compliant implementation must treat any unrecognized typeflag value
                     as a regular file.  In particular, writers should ensure that all entries
                     have a valid filename so that they can be restored by readers that do not
                     support the corresponding extension.  Uppercase letters "A" through "Z" are
                     reserved for custom extensions.  Note that sockets and whiteout entries are
                     not archivable.
             It is worth noting that the size field, in particular, has different meanings
             depending on the type.  For regular files, of course, it indicates the amount of
             data following the header.  For directories, it may be used to indicate the total
             size of all files in the directory, for use by operating systems that pre-allocate
             directory space.  For all other types, it should be set to zero by writers and
             ignored by readers.

     magic   Contains the magic value “ustar” followed by a NUL byte to indicate that this is a
             POSIX standard archive.  Full compliance requires the uname and gname fields be
             properly set.

     version
             Version.  This should be “00” (two copies of the ASCII digit zero) for POSIX
             standard archives.

     uname, gname
             User and group names, as null-terminated ASCII strings.  These should be used in
             preference to the uid/gid values when they are set and the corresponding names exist
             on the system.

     devmajor, devminor
             Major and minor numbers for character device or block device entry.

     name, prefix
             If the pathname is too long to fit in the 100 bytes provided by the standard format,
             it can be split at any / character with the first portion going into the prefix
             field.  If the prefix field is not empty, the reader will prepend the prefix value
             and a / character to the regular name field to obtain the full pathname.  The
             standard does not require a trailing / character on directory names, though most
             implementations still include this for compatibility reasons.

     Note that all unused bytes must be set to NUL.

     Field termination is specified slightly differently by POSIX than by previous
     implementations.  The magic, uname, and gname fields must have a trailing NUL.  The
     pathname, linkname, and prefix fields must have a trailing NUL unless they fill the entire
     field.  (In particular, it is possible to store a 256-character pathname if it happens to
     have a / as the 156th character.)  POSIX requires numeric fields to be zero-padded in the
     front, and requires them to be terminated with either space or NUL characters.

     Currently, most tar implementations comply with the ustar format, occasionally extending it
     by adding new fields to the blank area at the end of the header record.

   Numeric Extensions
     There have been several attempts to extend the range of sizes or times supported by
     modifying how numbers are stored in the header.

     One obvious extension to increase the size of files is to eliminate the terminating
     characters from the various numeric fields.  For example, the standard only allows the size
     field to contain 11 octal digits, reserving the twelfth byte for a trailing NUL character.
     Allowing 12 octal digits allows file sizes up to 64 GB.

     Another extension, utilized by GNU tar, star, and other newer tar implementations, permits
     binary numbers in the standard numeric fields.  This is flagged by setting the high bit of
     the first byte.  The remainder of the field is treated as a signed twos-complement value.
     This permits 95-bit values for the length and time fields and 63-bit values for the uid,
     gid, and device numbers.  In particular, this provides a consistent way to handle negative
     time values.  GNU tar supports this extension for the length, mtime, ctime, and atime
     fields.  Joerg Schilling's star program and the libarchive library support this extension
     for all numeric fields.  Note that this extension is largely obsoleted by the extended
     attribute record provided by the pax interchange format.

     Another early GNU extension allowed base-64 values rather than octal.  This extension was
     short-lived and is no longer supported by any implementation.

   Pax Interchange Format
     There are many attributes that cannot be portably stored in a POSIX ustar archive.  IEEE Std
     1003.1-2001 (“POSIX.1”) defined a “pax interchange format” that uses two new types of
     entries to hold text-formatted metadata that applies to following entries.  Note that a pax
     interchange format archive is a ustar archive in every respect.  The new data is stored in
     ustar-compatible archive entries that use the “x” or “g” typeflag.  In particular, older
     implementations that do not fully support these extensions will extract the metadata into
     regular files, where the metadata can be examined as necessary.

     An entry in a pax interchange format archive consists of one or two standard ustar entries,
     each with its own header and data.  The first optional entry stores the extended attributes
     for the following entry.  This optional first entry has an "x" typeflag and a size field
     that indicates the total size of the extended attributes.  The extended attributes
     themselves are stored as a series of text-format lines encoded in the portable UTF-8
     encoding.  Each line consists of a decimal number, a space, a key string, an equals sign, a
     value string, and a new line.  The decimal number indicates the length of the entire line,
     including the initial length field and the trailing newline.  An example of such a field is:
           25 ctime=1084839148.1212\n
     Keys in all lowercase are standard keys.  Vendors can add their own keys by prefixing them
     with an all uppercase vendor name and a period.  Note that, unlike the historic header,
     numeric values are stored using decimal, not octal.  A description of some common keys
     follows:

     atime, ctime, mtime
             File access, inode change, and modification times.  These fields can be negative or
             include a decimal point and a fractional value.

     hdrcharset
             The character set used by the pax extension values.  By default, all textual values
             in the pax extended attributes are assumed to be in UTF-8, including pathnames, user
             names, and group names.  In some cases, it is not possible to translate local
             conventions into UTF-8.  If this key is present and the value is the six-character
             ASCII string “BINARY”, then all textual values are assumed to be in a platform-
             dependent multi-byte encoding.  Note that there are only two valid values for this
             key: “BINARY” or “ISO-IR 10646 2000 UTF-8”.  No other values are permitted by the
             standard, and the latter value should generally not be used as it is the default
             when this key is not specified.  In particular, this flag should not be used as a
             general mechanism to allow filenames to be stored in arbitrary encodings.

     uname, uid, gname, gid
             User name, group name, and numeric UID and GID values.  The user name and group name
             stored here are encoded in UTF8 and can thus include non-ASCII characters.  The UID
             and GID fields can be of arbitrary length.

     linkpath
             The full path of the linked-to file.  Note that this is encoded in UTF8 and can thus
             include non-ASCII characters.

     path    The full pathname of the entry.  Note that this is encoded in UTF8 and can thus
             include non-ASCII characters.

     realtime.*, security.*
             These keys are reserved and may be used for future standardization.

     size    The size of the file.  Note that there is no length limit on this field, allowing
             conforming archives to store files much larger than the historic 8GB limit.

     SCHILY.*
             Vendor-specific attributes used by Joerg Schilling's star implementation.

     SCHILY.acl.access, SCHILY.acl.default, SCHILY.acl.ace
             Stores the access, default and NFSv4 ACLs as textual strings in a format that is an
             extension of the format specified by POSIX.1e draft 17.  In particular, each user or
             group access specification can include an additional colon-separated field with the
             numeric UID or GID.  This allows ACLs to be restored on systems that may not have
             complete user or group information available (such as when NIS/YP or LDAP services
             are temporarily unavailable).

     SCHILY.devminor, SCHILY.devmajor
             The full minor and major numbers for device nodes.

     SCHILY.fflags
             The file flags.

     SCHILY.realsize
             The full size of the file on disk.  XXX explain? XXX

     SCHILY.dev, SCHILY.ino, SCHILY.nlinks
             The device number, inode number, and link count for the entry.  In particular, note
             that a pax interchange format archive using Joerg Schilling's SCHILY.* extensions
             can store all of the data from struct stat.

     LIBARCHIVE.*
             Vendor-specific attributes used by the libarchive library and programs that use it.

     LIBARCHIVE.creationtime
             The time when the file was created.  (This should not be confused with the POSIX
             “ctime” attribute, which refers to the time when the file metadata was last
             changed.)

     LIBARCHIVE.xattr.namespace.key
             Libarchive stores POSIX.1e-style extended attributes using keys of this form.  The
             key value is URL-encoded: All non-ASCII characters and the two special characters
             “=” and “%” are encoded as “%” followed by two uppercase hexadecimal digits.  The
             value of this key is the extended attribute value encoded in base 64.  XXX Detail
             the base-64 format here XXX

     VENDOR.*
             XXX document other vendor-specific extensions XXX

     Any values stored in an extended attribute override the corresponding values in the regular
     tar header.  Note that compliant readers should ignore the regular fields when they are
     overridden.  This is important, as existing archivers are known to store non-compliant
     values in the standard header fields in this situation.  There are no limits on length for
     any of these fields.  In particular, numeric fields can be arbitrarily large.  All text
     fields are encoded in UTF8.  Compliant writers should store only portable 7-bit ASCII
     characters in the standard ustar header and use extended attributes whenever a text value
     contains non-ASCII characters.

     In addition to the x entry described above, the pax interchange format also supports a g
     entry.  The g entry is identical in format, but specifies attributes that serve as defaults
     for all subsequent archive entries.  The g entry is not widely used.

     Besides the new x and g entries, the pax interchange format has a few other minor variations
     from the earlier ustar format.  The most troubling one is that hardlinks are permitted to
     have data following them.  This allows readers to restore any hardlink to a file without
     having to rewind the archive to find an earlier entry.  However, it creates complications
     for robust readers, as it is no longer clear whether or not they should ignore the size
     field for hardlink entries.

   GNU Tar Archives
     The GNU tar program started with a pre-POSIX format similar to that described earlier and
     has extended it using several different mechanisms: It added new fields to the empty space
     in the header (some of which was later used by POSIX for conflicting purposes); it allowed
     the header to be continued over multiple records; and it defined new entries that modify
     following entries (similar in principle to the x entry described above, but each GNU special
     entry is single-purpose, unlike the general-purpose x entry).  As a result, GNU tar archives
     are not POSIX compatible, although more lenient POSIX-compliant readers can successfully
     extract most GNU tar archives.

           struct header_gnu_tar {
                   char name[100];
                   char mode[8];
                   char uid[8];
                   char gid[8];
                   char size[12];
                   char mtime[12];
                   char checksum[8];
                   char typeflag[1];
                   char linkname[100];
                   char magic[6];
                   char version[2];
                   char uname[32];
                   char gname[32];
                   char devmajor[8];
                   char devminor[8];
                   char atime[12];
                   char ctime[12];
                   char offset[12];
                   char longnames[4];
                   char unused[1];
                   struct {
                           char offset[12];
                           char numbytes[12];
                   } sparse[4];
                   char isextended[1];
                   char realsize[12];
                   char pad[17];
           };

     typeflag
             GNU tar uses the following special entry types, in addition to those defined by
             POSIX:

             7       GNU tar treats type "7" records identically to type "0" records, except on
                     one obscure RTOS where they are used to indicate the pre-allocation of a
                     contiguous file on disk.

             D       This indicates a directory entry.  Unlike the POSIX-standard "5" typeflag,
                     the header is followed by data records listing the names of files in this
                     directory.  Each name is preceded by an ASCII "Y" if the file is stored in
                     this archive or "N" if the file is not stored in this archive.  Each name is
                     terminated with a null, and an extra null marks the end of the name list.
                     The purpose of this entry is to support incremental backups; a program
                     restoring from such an archive may wish to delete files on disk that did not
                     exist in the directory when the archive was made.

                     Note that the "D" typeflag specifically violates POSIX, which requires that
                     unrecognized typeflags be restored as normal files.  In this case, restoring
                     the "D" entry as a file could interfere with subsequent creation of the
                     like-named directory.

             K       The data for this entry is a long linkname for the following regular entry.

             L       The data for this entry is a long pathname for the following regular entry.

             M       This is a continuation of the last file on the previous volume.  GNU multi-
                     volume archives guarantee that each volume begins with a valid entry header.
                     To ensure this, a file may be split, with part stored at the end of one
                     volume, and part stored at the beginning of the next volume.  The "M"
                     typeflag indicates that this entry continues an existing file.  Such entries
                     can only occur as the first or second entry in an archive (the latter only
                     if the first entry is a volume label).  The size field specifies the size of
                     this entry.  The offset field at bytes 369-380 specifies the offset where
                     this file fragment begins.  The realsize field specifies the total size of
                     the file (which must equal size plus offset).  When extracting, GNU tar
                     checks that the header file name is the one it is expecting, that the header
                     offset is in the correct sequence, and that the sum of offset and size is
                     equal to realsize.

             N       Type "N" records are no longer generated by GNU tar.  They contained a list
                     of files to be renamed or symlinked after extraction; this was originally
                     used to support long names.  The contents of this record are a text
                     description of the operations to be done, in the form “Rename %s to %s\n” or
                     “Symlink %s to %s\n”; in either case, both filenames are escaped using K&R C
                     syntax.  Due to security concerns, "N" records are now generally ignored
                     when reading archives.

             S       This is a “sparse” regular file.  Sparse files are stored as a series of
                     fragments.  The header contains a list of fragment offset/length pairs.  If
                     more than four such entries are required, the header is extended as
                     necessary with “extra” header extensions (an older format that is no longer
                     used), or “sparse” extensions.

             V       The name field should be interpreted as a tape/volume header name.  This
                     entry should generally be ignored on extraction.

     magic   The magic field holds the five characters “ustar” followed by a space.  Note that
             POSIX ustar archives have a trailing null.

     version
             The version field holds a space character followed by a null.  Note that POSIX ustar
             archives use two copies of the ASCII digit “0”.

     atime, ctime
             The time the file was last accessed and the time of last change of file information,
             stored in octal as with mtime.

     longnames
             This field is apparently no longer used.

     Sparse offset / numbytes
             Each such structure specifies a single fragment of a sparse file.  The two fields
             store values as octal numbers.  The fragments are each padded to a multiple of 512
             bytes in the archive.  On extraction, the list of fragments is collected from the
             header (including any extension headers), and the data is then read and written to
             the file at appropriate offsets.

     isextended
             If this is set to non-zero, the header will be followed by additional “sparse
             header” records.  Each such record contains information about as many as 21
             additional sparse blocks as shown here:

                   struct gnu_sparse_header {
                           struct {
                                   char offset[12];
                                   char numbytes[12];
                           } sparse[21];
                           char    isextended[1];
                           char    padding[7];
                   };

     realsize
             A binary representation of the file's complete size, with a much larger range than
             the POSIX file size.  In particular, with M type files, the current entry is only a
             portion of the file.  In that case, the POSIX size field will indicate the size of
             this entry; the realsize field will indicate the total size of the file.

   GNU tar pax archives
     GNU tar 1.14 (XXX check this XXX) and later will write pax interchange format archives when
     you specify the --posix flag.  This format follows the pax interchange format closely, using
     some SCHILY tags and introducing new keywords to store sparse file information.  There have
     been three iterations of the sparse file support, referred to as “0.0”, “0.1”, and “1.0”.

     GNU.sparse.numblocks, GNU.sparse.offset, GNU.sparse.numbytes, GNU.sparse.size
             The “0.0” format used an initial GNU.sparse.numblocks attribute to indicate the
             number of blocks in the file, a pair of GNU.sparse.offset and GNU.sparse.numbytes to
             indicate the offset and size of each block, and a single GNU.sparse.size to indicate
             the full size of the file.  This is not the same as the size in the tar header
             because the latter value does not include the size of any holes.  This format
             required that the order of attributes be preserved and relied on readers accepting
             multiple appearances of the same attribute names, which is not officially permitted
             by the standards.

     GNU.sparse.map
             The “0.1” format used a single attribute that stored a comma-separated list of
             decimal numbers.  Each pair of numbers indicated the offset and size, respectively,
             of a block of data.  This does not work well if the archive is extracted by an
             archiver that does not recognize this extension, since many pax implementations
             simply discard unrecognized attributes.

     GNU.sparse.major, GNU.sparse.minor, GNU.sparse.name, GNU.sparse.realsize
             The “1.0” format stores the sparse block map in one or more 512-byte blocks
             prepended to the file data in the entry body.  The pax attributes indicate the
             existence of this map (via the GNU.sparse.major and GNU.sparse.minor fields) and the
             full size of the file.  The GNU.sparse.name holds the true name of the file.  To
             avoid confusion, the name stored in the regular tar header is a modified name so
             that extraction errors will be apparent to users.

   Solaris Tar
     XXX More Details Needed XXX

     Solaris tar (beginning with SunOS XXX 5.7 ?? XXX) supports an “extended” format that is
     fundamentally similar to pax interchange format, with the following differences:
            Extended attributes are stored in an entry whose type is X, not x, as used by pax
             interchange format.  The detailed format of this entry appears to be the same as
             detailed above for the x entry.
            An additional A header is used to store an ACL for the following regular entry.  The
             body of this entry contains a seven-digit octal number followed by a zero byte,
             followed by the textual ACL description.  The octal value is the number of ACL
             entries plus a constant that indicates the ACL type: 01000000 for POSIX.1e ACLs and
             03000000 for NFSv4 ACLs.

   AIX Tar
     XXX More details needed XXX

     AIX Tar uses a ustar-formatted header with the type A for storing coded ACL information.
     Unlike the Solaris format, AIX tar writes this header after the regular file body to which
     it applies.  The pathname in this header is either NFS4 or AIXC to indicate the type of ACL
     stored.  The actual ACL is stored in platform-specific binary format.

   Mac OS X Tar
     The tar distributed with Apple's Mac OS X stores most regular files as two separate files in
     the tar archive.  The two files have the same name except that the first one has “._”
     prepended to the last path element.  This special file stores an AppleDouble-encoded binary
     blob with additional metadata about the second file, including ACL, extended attributes, and
     resources.  To recreate the original file on disk, each separate file can be extracted and
     the Mac OS X copyfile() function can be used to unpack the separate metadata file and apply
     it to th regular file.  Conversely, the same function provides a “pack” option to encode the
     extended metadata from a file into a separate file whose contents can then be put into a tar
     archive.

     Note that the Apple extended attributes interact badly with long filenames.  Since each file
     is stored with the full name, a separate set of extensions needs to be included in the
     archive for each one, doubling the overhead required for files with long names.

   Summary of tar type codes
     The following list is a condensed summary of the type codes used in tar header records
     generated by different tar implementations.  More details about specific implementations can
     be found above:
     NUL  Early tar programs stored a zero byte for regular files.
     0    POSIX standard type code for a regular file.
     1    POSIX standard type code for a hard link description.
     2    POSIX standard type code for a symbolic link description.
     3    POSIX standard type code for a character device node.
     4    POSIX standard type code for a block device node.
     5    POSIX standard type code for a directory.
     6    POSIX standard type code for a FIFO.
     7    POSIX reserved.
     7    GNU tar used for pre-allocated files on some systems.
     A    Solaris tar ACL description stored prior to a regular file header.
     A    AIX tar ACL description stored after the file body.
     D    GNU tar directory dump.
     K    GNU tar long linkname for the following header.
     L    GNU tar long pathname for the following header.
     M    GNU tar multivolume marker, indicating the file is a continuation of a file from the
          previous volume.
     N    GNU tar long filename support.  Deprecated.
     S    GNU tar sparse regular file.
     V    GNU tar tape/volume header name.
     X    Solaris tar general-purpose extension header.
     g    POSIX pax interchange format global extensions.
     x    POSIX pax interchange format per-file extensions.

SEE ALSO

     ar(1), pax(1), tar(1)

STANDARDS

     The tar utility is no longer a part of POSIX or the Single Unix Standard.  It last appeared
     in Version 2 of the Single UNIX Specification (“SUSv2”).  It has been supplanted in
     subsequent standards by pax(1).  The ustar format is currently part of the specification for
     the pax(1) utility.  The pax interchange file format is new with IEEE Std 1003.1-2001
     (“POSIX.1”).

HISTORY

     A tar command appeared in Seventh Edition Unix, which was released in January, 1979.  It
     replaced the tp program from Fourth Edition Unix which in turn replaced the tap program from
     First Edition Unix.  John Gilmore's pdtar public-domain implementation (circa 1987) was
     highly influential and formed the basis of GNU tar (circa 1988).  Joerg Shilling's star
     archiver is another open-source (CDDL) archiver (originally developed circa 1985) which
     features complete support for pax interchange format.

     This documentation was written as part of the libarchive and bsdtar project by Tim Kientzle
     <kientzle@FreeBSD.org>.