1 @c This is part of the paxutils manual.
2 @c Copyright (C) 2006, 2014 Free Software Foundation, Inc.
3 @c This file is distributed under GFDL 1.1 or any later version
4 @c published by the Free Software Foundation.
7 * Standard:: Basic Tar Format
8 * Extensions:: @acronym{GNU} Extensions to the Archive Format
9 * Sparse Formats:: Storing Sparse Files
15 @unnumberedsec Basic Tar Format
18 While an archive may contain many files, the archive itself is a
19 single ordinary file. Like any other file, an archive file can be
20 written to a storage device such as a tape or disk, sent through a
21 pipe or over a network, saved on the active file system, or even
22 stored in another archive. An archive file is not easy to read or
23 manipulate without using the @command{tar} utility or Tar mode in
26 Physically, an archive consists of a series of file entries terminated
27 by an end-of-archive entry, which consists of two 512 blocks of zero
29 entry usually describes one of the files in the archive (an
30 @dfn{archive member}), and consists of a file header and the contents
31 of the file. File headers contain file names and statistics, checksum
32 information which @command{tar} uses to detect file corruption, and
33 information about file types.
35 Archives are permitted to have more than one member with the same
36 member name. One way this situation can occur is if more than one
37 version of a file has been stored in the archive. For information
38 about adding new versions of a file to an archive, see @ref{update}.
40 In addition to entries describing archive members, an archive may
41 contain entries which @command{tar} itself uses to store information.
42 @xref{label}, for an example of such an archive entry.
44 A @command{tar} archive file contains a series of blocks. Each block
45 contains @code{BLOCKSIZE} bytes. Although this format may be thought
46 of as being on magnetic tape, other media are often used.
48 Each file archived is represented by a header block which describes
49 the file, followed by zero or more blocks which give the contents
50 of the file. At the end of the archive file there are two 512-byte blocks
51 filled with binary zeros as an end-of-file marker. A reasonable system
52 should write such end-of-file marker at the end of an archive, but
53 must not assume that such a block exists when reading an archive. In
54 particular @GNUTAR{} always issues a warning if it does not encounter it.
56 The blocks may be @dfn{blocked} for physical I/O operations.
57 Each record of @var{n} blocks (where @var{n} is set by the
58 @option{--blocking-factor=@var{512-size}} (@option{-b @var{512-size}}) option to @command{tar}) is written with a single
59 @w{@samp{write ()}} operation. On magnetic tapes, the result of
60 such a write is a single record. When writing an archive,
61 the last record of blocks should be written at the full size, with
62 blocks after the zero block containing all zeros. When reading
63 an archive, a reasonable system should properly handle an archive
64 whose last record is shorter than the rest, or which contains garbage
65 records after a zero block.
67 The header block is defined in C as follows. In the @GNUTAR{}
68 distribution, this is part of file @file{src/tar.h}:
74 All characters in header blocks are represented by using 8-bit
75 characters in the local variant of ASCII. Each field within the
76 structure is contiguous; that is, there is no padding used within
77 the structure. Each character on the archive medium is stored
80 Bytes representing the contents of files (after the header block
81 of each file) are not translated in any way and are not constrained
82 to represent characters in any character set. The @command{tar} format
83 does not distinguish text files from binary files, and no translation
84 of file contents is performed.
86 The @code{name}, @code{linkname}, @code{magic}, @code{uname}, and
87 @code{gname} are null-terminated character strings. All other fields
88 are zero-filled octal numbers in ASCII. Each numeric field of width
89 @var{w} contains @var{w} minus 1 digits, and a null.
91 The @code{name} field is the file name of the file, with directory names
92 (if any) preceding the file name, separated by slashes.
94 @FIXME{how big a name before field overflows?}
96 The @code{mode} field provides nine bits specifying file permissions
97 and three bits to specify the Set @acronym{UID}, Set @acronym{GID}, and Save Text
98 (@dfn{sticky}) modes. Values for these bits are defined above.
99 When special permissions are required to create a file with a given
100 mode, and the user restoring files from the archive does not hold such
101 permissions, the mode bit(s) specifying those special permissions
102 are ignored. Modes which are not supported by the operating system
103 restoring files from the archive will be ignored. Unsupported modes
104 should be faked up when creating or updating an archive; e.g., the
105 group permission could be copied from the @emph{other} permission.
107 The @code{uid} and @code{gid} fields are the numeric user and group
108 @acronym{ID} of the file owners, respectively. If the operating system does
109 not support numeric user or group @acronym{ID}s, these fields should
112 The @code{size} field is the size of the file in bytes; linked files
113 are archived with this field specified as zero.
115 The @code{mtime} field is the data modification time of the file at
116 the time it was archived. It is the ASCII representation of the octal
117 value of the last time the file's contents were modified, represented
118 as an integer number of
119 seconds since January 1, 1970, 00:00 Coordinated Universal Time.
121 The @code{chksum} field is the ASCII representation of the octal value
122 of the simple sum of all bytes in the header block. Each 8-bit
123 byte in the header is added to an unsigned integer, initialized to
124 zero, the precision of which shall be no less than seventeen bits.
125 When calculating the checksum, the @code{chksum} field is treated as
126 if it were all blanks.
128 The @code{typeflag} field specifies the type of file archived. If a
129 particular implementation does not recognize or permit the specified
130 type, the file will be extracted as if it were a regular file. As this
131 action occurs, @command{tar} issues a warning to the standard error.
133 The @code{atime} and @code{ctime} fields are used in making incremental
134 backups; they store, respectively, the particular file's access and
137 The @code{offset} is used by the @option{--multi-volume} (@option{-M}) option, when
138 making a multi-volume archive. The offset is number of bytes into
139 the file that we need to restart at to continue the file on the next
140 tape, i.e., where we store the location that a continued file is
143 The following fields were added to deal with sparse files. A file
144 is @dfn{sparse} if it takes in unallocated blocks which end up being
145 represented as zeros, i.e., no useful data. A test to see if a file
146 is sparse is to look at the number blocks allocated for it versus the
147 number of characters in the file; if there are fewer blocks allocated
148 for the file than would normally be allocated for a file of that
149 size, then the file is sparse. This is the method @command{tar} uses to
150 detect a sparse file, and once such a file is detected, it is treated
151 differently from non-sparse files.
153 Sparse files are often @code{dbm} files, or other database-type files
154 which have data at some points and emptiness in the greater part of
155 the file. Such files can appear to be very large when an @samp{ls
156 -l} is done on them, when in truth, there may be a very small amount
157 of important data contained in the file. It is thus undesirable
158 to have @command{tar} think that it must back up this entire file, as
159 great quantities of room are wasted on empty blocks, which can lead
160 to running out of room on a tape far earlier than is necessary.
161 Thus, sparse files are dealt with so that these empty blocks are
162 not written to the tape. Instead, what is written to the tape is a
163 description, of sorts, of the sparse file: where the holes are, how
164 big the holes are, and how much data is found at the end of the hole.
165 This way, the file takes up potentially far less room on the tape,
166 and when the file is extracted later on, it will look exactly the way
167 it looked beforehand. The following is a description of the fields
168 used to handle a sparse file:
170 The @code{sp} is an array of @code{struct sparse}. Each @code{struct
171 sparse} contains two 12-character strings which represent an offset
172 into the file and a number of bytes to be written at that offset.
173 The offset is absolute, and not relative to the offset in preceding
176 The header can hold four of these @code{struct sparse} at the moment;
177 if more are needed, they are not stored in the header.
179 The @code{isextended} flag is set when an @code{extended_header}
180 is needed to deal with a file. Note that this means that this flag
181 can only be set when dealing with a sparse file, and it is only set
182 in the event that the description of the file will not fit in the
183 allotted room for sparse structures in the header. In other words,
184 an extended_header is needed.
186 The @code{extended_header} structure is used for sparse files which
187 need more sparse structures than can fit in the header. The header can
188 fit 4 such structures; if more are needed, the flag @code{isextended}
189 gets set and the next block is an @code{extended_header}.
191 Each @code{extended_header} structure contains an array of 21
192 sparse structures, along with a similar @code{isextended} flag
193 that the header had. There can be an indeterminate number of such
194 @code{extended_header}s to describe a sparse file.
199 @itemx @code{AREGTYPE}
200 These flags represent a regular file. In order to be compatible
201 with older versions of @command{tar}, a @code{typeflag} value of
202 @code{AREGTYPE} should be silently recognized as a regular file.
203 New archives should be created using @code{REGTYPE}. Also, for
204 backward compatibility, @command{tar} treats a regular file whose name
205 ends with a slash as a directory.
208 This flag represents a file linked to another file, of any type,
209 previously archived. Such files are identified in Unix by each
210 file having the same device and inode number. The linked-to name is
211 specified in the @code{linkname} field with a trailing null.
214 This represents a symbolic link to another file. The linked-to name
215 is specified in the @code{linkname} field with a trailing null.
218 @itemx @code{BLKTYPE}
219 These represent character special files and block special files
220 respectively. In this case the @code{devmajor} and @code{devminor}
221 fields will contain the major and minor device numbers respectively.
222 Operating systems may map the device specifications to their own
223 local specification, or may ignore the entry.
226 This flag specifies a directory or sub-directory. The directory
227 name in the @code{name} field should end with a slash. On systems where
228 disk allocation is performed on a directory basis, the @code{size} field
229 will contain the maximum number of bytes (which may be rounded to
230 the nearest disk block allocation unit) which the directory may
231 hold. A @code{size} field of zero indicates no such limiting. Systems
232 which do not support limiting in this manner should ignore the
235 @item @code{FIFOTYPE}
236 This specifies a FIFO special file. Note that the archiving of a
237 FIFO file archives the existence of this file and not its contents.
239 @item @code{CONTTYPE}
240 This specifies a contiguous file, which is the same as a normal
241 file except that, in operating systems which support it, all its
242 space is allocated contiguously on the disk. Operating systems
243 which do not allow contiguous allocation should silently treat this
244 type as a normal file.
246 @item @code{A} @dots{} @code{Z}
247 These are reserved for custom implementations. Some of these are
248 used in the @acronym{GNU} modified format, as described below.
252 Other values are reserved for specification in future revisions of
253 the P1003 standard, and should not be used by any @command{tar} program.
255 The @code{magic} field indicates that this archive was output in
256 the P1003 archive format. If this field contains @code{TMAGIC},
257 the @code{uname} and @code{gname} fields will contain the ASCII
258 representation of the owner and group of the file respectively.
259 If found, the user and group @acronym{ID}s are used rather than the values in
260 the @code{uid} and @code{gid} fields.
262 For references, see ISO/IEC 9945-1:1990 or IEEE Std 1003.1-1990, pages
263 169-173 (section 10.1) for @cite{Archive/Interchange File Format}; and
264 IEEE Std 1003.2-1992, pages 380-388 (section 4.48) and pages 936-940
265 (section E.4.48) for @cite{pax - Portable archive interchange}.
268 @unnumberedsec @acronym{GNU} Extensions to the Archive Format
271 The @acronym{GNU} format uses additional file types to describe new types of
272 files in an archive. These are listed below.
275 @item GNUTYPE_DUMPDIR
277 This represents a directory and a list of files created by the
278 @option{--incremental} (@option{-G}) option. The @code{size} field gives the total
279 size of the associated list of files. Each file name is preceded by
280 either a @samp{Y} (the file should be in this archive) or an @samp{N}.
281 (The file is a directory, or is not stored in the archive.) Each file
282 name is terminated by a null. There is an additional null after the
285 @item GNUTYPE_MULTIVOL
287 This represents a file continued from another volume of a multi-volume
288 archive created with the @option{--multi-volume} (@option{-M}) option. The original
289 type of the file is not given here. The @code{size} field gives the
290 maximum size of this piece of the file (assuming the volume does
291 not end before the file is written out). The @code{offset} field
292 gives the offset from the beginning of the file where this part of
293 the file begins. Thus @code{size} plus @code{offset} should equal
294 the original size of the file.
298 This flag indicates that we are dealing with a sparse file. Note
299 that archiving a sparse file requires special operations to find
300 holes in the file, which mark the positions of these holes, along
301 with the number of bytes of data to be found after the hole.
305 This file type is used to mark the volume header that was given with
306 the @option{--label=@var{archive-label}} (@option{-V @var{archive-label}}) option when the archive was created. The @code{name}
307 field contains the @code{name} given after the @option{--label=@var{archive-label}} (@option{-V @var{archive-label}}) option.
308 The @code{size} field is zero. Only the first file in each volume
309 of an archive should have this type.
313 You may have trouble reading a @acronym{GNU} format archive on a
314 non-@acronym{GNU} system if the options @option{--incremental} (@option{-G}),
315 @option{--multi-volume} (@option{-M}), @option{--sparse} (@option{-S}), or @option{--label=@var{archive-label}} (@option{-V @var{archive-label}}) were
316 used when writing the archive. In general, if @command{tar} does not
317 use the @acronym{GNU}-added fields of the header, other versions of
318 @command{tar} should be able to read the archive. Otherwise, the
319 @command{tar} program will give an error, the most likely one being a
323 @unnumberedsec Storing Sparse Files
327 @unnumberedsec Format of the Incremental Snapshot Files
328 @include snapshot.texi
331 @unnumberedsec Dumpdir
332 @include dumpdir.texi