Tar
Tar.create
— Functioncreate(
[ predicate, ] dir, [ tarball ];
[ skeleton, ] [ portable = false ]
) -> tarball
predicate :: String --> Bool
dir :: AbstractString
tarball :: Union{AbstractString, AbstractCmd, IO}
skeleton :: Union{AbstractString, AbstractCmd, IO}
portable :: Bool
Create a tar archive ("tarball") of the directory dir
. The resulting archive is written to the path tarball
or if no path is specified, a temporary path is created and returned by the function call. If tarball
is an IO object then the tarball content is written to that handle instead (the handle is left open).
If a predicate
function is passed, it is called on each system path that is encountered while recursively searching dir
and path
is only included in the tarball if predicate(path)
is true. If predicate(path)
returns false for a directory, then the directory is excluded entirely: nothing under that directory will be included in the archive.
If the skeleton
keyword is passed then the file or IO handle given is used as a "skeleton" to generate the tarball. You create a skeleton file by passing the skeleton
keyword to the extract
command. If create
is called with that skeleton file and the extracted files haven't changed, an identical tarball is recreated. The skeleton
and predicate
arguments cannot be used together.
If the portable
flag is true then path names are checked for validity on Windows, which ensures that they don't contain illegal characters or have names that are reserved. See https://stackoverflow.com/a/31976060/659248 for details.
Tar.extract
— Functionextract(
[ predicate, ] tarball, [ dir ];
[ skeleton = <none>, ]
[ copy_symlinks = <auto>, ]
[ set_permissions = true, ]
) -> dir
predicate :: Header --> Bool
tarball :: Union{AbstractString, AbstractCmd, IO}
dir :: AbstractString
skeleton :: Union{AbstractString, AbstractCmd, IO}
copy_symlinks :: Bool
set_permissions :: Bool
Extract a tar archive ("tarball") located at the path tarball
into the directory dir
. If tarball
is an IO object instead of a path, then the archive contents will be read from that IO stream. The archive is extracted to dir
which must either be an existing empty directory or a non-existent path which can be created as a new directory. If dir
is not specified, the archive is extracted into a temporary directory which is returned by extract
.
If a predicate
function is passed, it is called on each Header
object that is encountered while extracting tarball
and the entry is only extracted if the predicate(hdr)
is true. This can be used to selectively extract only parts of an archive, to skip entries that cause extract
to throw an error, or to record what is extracted during the extraction process.
Before it is passed to the predicate function, the Header
object is somewhat modified from the raw header in the tarball: the path
field is normalized to remove .
entries and replace multiple consecutive slashes with a single slash. If the entry has type :hardlink
, the link target path is normalized the same way so that it will match the path of the target entry; the size field is set to the size of the target path (which must be an already-seen file).
If the skeleton
keyword is passed then a "skeleton" of the extracted tarball is written to the file or IO handle given. This skeleton file can be used to recreate an identical tarball by passing the skeleton
keyword to the create
function. The skeleton
and predicate
arguments cannot be used together.
If copy_symlinks
is true
then instead of extracting symbolic links as such, they will be extracted as copies of what they link to if they are internal to the tarball and if it is possible to do so. Non-internal symlinks, such as a link to /etc/passwd
will not be copied. Symlinks which are in any way cyclic will also not be copied and will instead be skipped. By default, extract
will detect whether symlinks can be created in dir
or not and will automatically copy symlinks if they cannot be created.
If set_permissions
is false
, no permissions are set on the extracted files.
Tar.list
— Functionlist(tarball; [ strict = true ]) -> Vector{Header}
list(callback, tarball; [ strict = true ])
callback :: Header, [ <data> ] --> Any
tarball :: Union{AbstractString, AbstractCmd, IO}
strict :: Bool
List the contents of a tar archive ("tarball") located at the path tarball
. If tarball
is an IO handle, read the tar contents from that stream. Returns a vector of Header
structs. See Header
for details.
If a callback
is provided then instead of returning a vector of headers, the callback is called on each Header
. This can be useful if the number of items in the tarball is large or if you want examine items prior to an error in the tarball. If the callback
function can accept a second argument of either type Vector{UInt8}
or Vector{Pair{Symbol, String}}
then it will be called with a representation of the raw header data either as a single byte vector or as a vector of pairs mapping field names to the raw data for that field (if these fields are concatenated together, the result is the raw data of the header).
By default list
will error if it encounters any tarball contents which the extract
function would refuse to extract. With strict=false
it will skip these checks and list all the the contents of the tar file whether extract
would extract them or not. Beware that malicious tarballs can do all sorts of crafty and unexpected things to try to trick you into doing something bad.
If the tarball
argument is a skeleton file (see extract
and create
) then list
will detect that from the file header and appropriately list or iterate the headers of the skeleton file.
Tar.rewrite
— Functionrewrite(
[ predicate, ] old_tarball, [ new_tarball ];
[ portable = false, ]
) -> new_tarball
predicate :: Header --> Bool
old_tarball :: Union{AbstractString, AbstractCmd, IO}
new_tarball :: Union{AbstractString, AbstractCmd, IO}
portable :: Bool
Rewrite old_tarball
to the standard format that create
generates, while also checking that it doesn't contain anything that would cause extract
to raise an error. This is functionally equivalent to doing
Tar.create(Tar.extract(predicate, old_tarball), new_tarball)
However, it never extracts anything to disk and instead uses the seek
function to navigate the old tarball's data. If no new_tarball
argument is passed, the new tarball is written to a temporary file whose path is returned.
If a predicate
function is passed, it is called on each Header
object that is encountered while extracting old_tarball
and the entry is skipped unless predicate(hdr)
is true. This can be used to selectively rewrite only parts of an archive, to skip entries that would cause extract
to throw an error, or to record what content is encountered during the rewrite process.
Before it is passed to the predicate function, the Header
object is somewhat modified from the raw header in the tarball: the path
field is normalized to remove .
entries and replace multiple consecutive slashes with a single slash. If the entry has type :hardlink
, the link target path is normalized the same way so that it will match the path of the target entry; the size field is set to the size of the target path (which must be an already-seen file).
If the portable
flag is true then path names are checked for validity on Windows, which ensures that they don't contain illegal characters or have names that are reserved. See https://stackoverflow.com/a/31976060/659248 for details.
Tar.tree_hash
— Functiontree_hash([ predicate, ] tarball;
[ algorithm = "git-sha1", ]
[ skip_empty = false ]) -> hash::String
predicate :: Header --> Bool
tarball :: Union{AbstractString, AbstractCmd, IO}
algorithm :: AbstractString
skip_empty :: Bool
Compute a tree hash value for the file tree that the tarball contains. By default, this uses git's tree hashing algorithm with the SHA1 secure hash function (like current versions of git). This means that for any tarball whose file tree git can represent—i.e. one with only files, symlinks and non-empty directories—the hash value computed by this function will be the same as the hash value git would compute for that file tree. Note that tarballs can represent file trees with empty directories, which git cannot store, and this function can generate hashes for those, which will, by default (see skip_empty
below for how to change this behavior), differ from the hash of a tarball which omits those empty directories. In short, the hash function agrees with git on all trees which git can represent, but extends (in a consistent way) the domain of hashable trees to other trees which git cannot represent.
If a predicate
function is passed, it is called on each Header
object that is encountered while processing tarball
and an entry is only hashed if predicate(hdr)
is true. This can be used to selectively hash only parts of an archive, to skip entries that cause extract
to throw an error, or to record what is extracted during the hashing process.
Before it is passed to the predicate function, the Header
object is somewhat modified from the raw header in the tarball: the path
field is normalized to remove .
entries and replace multiple consecutive slashes with a single slash. If the entry has type :hardlink
, the link target path is normalized the same way so that it will match the path of the target entry; the size field is set to the size of the target path (which must be an already-seen file).
Currently supported values for algorithm
are git-sha1
(the default) and git-sha256
, which uses the same basic algorithm as git-sha1
but replaces the SHA1 hash function with SHA2-256, the hash function that git will transition to using in the future (due to known attacks on SHA1). Support for other file tree hashing algorithms may be added in the future.
The skip_empty
option controls whether directories in the tarball which recursively contain no files or symlinks are included in the hash or ignored. In general, if you are hashing the content of a tarball or a file tree, you care about all directories, not just non-empty ones, so including these in the computed hash is the default. So why does this function even provide the option to skip empty directories? Because git refuses to store empty directories and will ignore them if you try to add them to a repo. So if you compute a reference tree hash by by adding files to a git repo and then asking git for the tree hash, the hash value that you get will match the hash value computed by tree_hash
with skip_empty=true
. In other words, this option allows tree_hash
to emulate how git would hash a tree with empty directories. If you are hashing trees that may contain empty directories (i.e. do not come from a git repo), however, it is recommended that you hash them using a tool (such as this one) that does not ignore empty directories.
Tar.Header
— TypeThe Header
type is a struct representing the essential metadata for a single record in a tar file with this definition:
struct Header
path :: String # path relative to the root
type :: Symbol # type indicator (see below)
mode :: UInt16 # mode/permissions (best viewed in octal)
size :: Int64 # size of record data in bytes
link :: String # target path of a symlink
end
Types are represented with the following symbols: file
, hardlink
, symlink
, chardev
, blockdev
, directory
, fifo
, or for unknown types, the typeflag character as a symbol. Note that extract
refuses to extract records types other than file
, symlink
and directory
; list
will only list other kinds of records if called with strict=false
.
The tar format includes various other metadata about records, including user and group IDs, user and group names, and timestamps. The Tar
package, by design, completely ignores these. When creating tar files, these fields are always set to zero/empty. When reading tar files, these fields are ignored aside from verifying header checksums for each header record for all fields.