| Allegro CL version 8.1 Unrevised from 8.0 to 8.1. 8.0 version | ||||||||
This document contains the following sections:
1.0 IntroductionThis document describes functionality that does not naturally fit in any of the other overview documents.
The functions fasl-write and fasl-read provide a mechanism for writing Lisp data and subsequently reading it back into a Lisp image. It can handle many of the common Lisp data types. It can optionally detect circularity and structure sharing in the data and recreate the same topology up to eql-ness of components. The data is written in a binary file format similar to that used for compiled Lisp files, not in ASCII.
Among the advantages of fasl-read and fasl-write over standard Common Lisp read and print functions is that data does not have to be converted to its printed representation prior to being written (that conversion takes a significant amount of time for complex objects). The main disadvantage is that the files (unlike ASCII files with printed representations of Lisp objects) are not at all portable between versions of Lisp (or even between versions of Allegro CL on different platforms or between major releases of Allegro CL).
Not all Lisp objects may be written with fasl-write (and thus are not available to be read by fasl-read). The objects that cannot be written are CLOS objects, streams, stacks, or c-allocated data (cstructs). You can use fasl-open to open a file suitable for numerous fasl-write's. (fasl-read reads all of whatever file is specified to it.)
fasl-read reads the
entire contents of its argument file. However, fasl-write, if its argument is a stream rather
than a filename, writes data to the stream but does not close it. Thus
you can open a stream and do multiple fasl-write's to it. The stream must have
:element-type (unsigned-byte 8). fasl-open opens an appropriate
stream, as shown in the example.
Here is a simple-minded example to show the correct syntax and give an idea of the effect:
(excl:fasl-write '(a b #1=#:c (#1#) #*1011 #(1 2 3)
1 1.1 1.1d0 1/2
#c(1 1) #c(1.5 1.5) "abc")
"test.fw")
(excl:fasl-read "test.fw")
(setq f (fasl-open "test2.fw"))
(excl:fasl-write '(a b c) f)
(excl:fasl-write '#1=(a b . #1#) f t)
(excl:fasl-write '#(1 2 3 4.5) f)
(close f)
(excl:fasl-read "test2.fw")
fasl-read and fasl-write require the compiler so they are not available in application images without the compiler.
The table describes those extensions to Common Lisp that do not naturally fit elsewhere in the documentation. We only provide brief information in the table. Please follow the link to the documentation page for a full description.
| Name | Arguments | Notes |
| excl:dribble-bug | &optional file | This function is an extension of the Common Lisp function dribble.
dribble-bug called with the optional file
calls several information functions whose output is then placed at the beginning of the
dribble file. See also excl:*dribble-bug-hooks*. |
| excl:uncompile | function-name | If the function function-name was compiled with the compile function (as opposed to having been in a file that was compiled with compile-file and subsequently loaded), then the function is `uncompiled,' i.e. its function definition is replaced by the original interpreted definition. This function will only work when
definitions are saved. See the description page for excl:uncompile and the page for |
| excl:bignump | object | These functions, like similar ones in standard Common Lisp return t if object is of the type specified, and nil otherwise. |
| excl:fixnump | ||
| excl:ratiop | ||
| excl:single-float-p | ||
| excl:file-older-p | file-1 file-2 | If file-1 and file-2 both exist, and if file-1 is older than file-2, this function returns t. Otherwise, it returns nil. |
| excl:if* | test-form {then then-form+ | thenret} {elseif else-test-form {then else-then-form+ | thenret}}* [else else-form+] | This extension to cl:if allows symbols like then, else, elseif, and thenret in the body allowing a complex number of cases and outcomes to be specified. |
| excl:named-readtable | name &optional errorp | This function looks up a readtable by name. name must be a symbol, but it is coerced to a keyword (so readtables are named by keywords). setf may be used to associate a name to a readtable. The association can be broken by setting to nil. See also with-named-readtable. |
| excl:prefixp | prefix sequence |
This function returns non-nil if
sequence starts with prefix,
returning the index in sequence where prefix ends (so
(prefixp "foo" "foobar") returns 3). While this can
be done using regular-expression matching (see
regexp.htm), this function is easier to use for very
simple cases.
|
A pll file can be used in association with a Lisp image. It contains constant code vectors and strings that can be shared among many Lisp objects. When an image uses a pll file and a function is compiled, the new codevector is compared to codevectors in the pll file. If a match is found, the match is used and no new codevector is allocated. Similarly, if a constant string is specified (with excl:pure-string) and a matching string appears in the pll file, no new string is allocated and the match is used. Strings in a pll file cannot be modified. Attempting to do so causes an error. (Neither can codevectors be modified but there is no user-visible way to modify codevectors as there is with strings.)
Strings and codevectors in a pll file are not also (after
being garbage collected) in the Lisp heap. Thus if a string has been
successfully purified, it will not be in the heap after a global gc. A
total count of strings and codevectors is shown in the output of
(room t).
pll files are created with the cvdcvt program described next.
cvdcvt
Arguments: [
-o outfilename] [-u] [file1 file2]A .pll file,
outfilename, is created holding all the unique code vectors and strings. Ifoutfilenameis omitted it defaults to code.blob.If
-uis specified, then no duplications of strings are done, otherwise for every string that has no lowercase characters in it and at least one uppercase character, a lowercase copy is added to the output file. This is the default and is useful forset-case-mode. If no files are specified, stdin is used..str (string) files and .cvs (code vector) files are combined without redundancies; if two files of the same extension have identical objects, the object from the file specified first to cvdcvt is retained, and the latter object is removed from the output. This allows for files (.cvs files especially) to be arranged by code vectors in order of execution, to provide for locality of reference. Those .cvs files that were produced by training techniques should be placed first in order to have the desired effect.
As said in the description, pll files are built out of cvs files and str files. cvs files are created with sys:write-codevectors and can be created by sys:flush-codevectors. str files are created with record-strings. See also record-code-vectors.
The following functions can be used to associate a pll file with an image, to find out which pll file is used with an image, and to use strings in the pll file.
| Name | Arguments | Notes |
| excl:pll-file | [none] | Return the location of the current .pll file, or nil if there is no .pll file associated with this Lisp. |
| excl:use-pll-file | name &key (global-gc t) | Associates the current Lisp with the pll file specified by name. It is an error to associate an image already using a pll file with another pll file. |
| excl:pure-string | x | When not in the body of sys:record-strings, returns a pure-string if there is one identical to the argument and a heap-allocated string if there isn't. When in the body of sys:record-strings, also write the string to the str file being created. |
Allegro CL provides various encoding and encrypting algorithms. It has provided MD5 support for some time and now also provides SHA1 support, support for the RC4 cipher algorithm, and support for the HMAC keyed hash algorithm which works with MD5 and SHA1.
MD5 and SHA1 are cryptographic hash functions. A hash function takes a long string (or message) of any length as input and produces a 128-bit output. The output of MD5 and SHA1 is sometimes termed a message digest. This digest can be sent along (or in addition to) a message. Comparing the digest sent to the digest produced with MD5 or SHA1 applied to the message can verify that the message received is the one sent.
The keyed-hash algorithm HMAC is designed to work with algorithms MD5 and SHA1 (and other algorithms not supported at this time). Keyed hash algorithms work by utilizing an existing hash function (such as MD5 or SHA1) and using a secret "key" as part of the information to hash. If one party sends a message to another party and also includes an HMAC with the message, the receiver (if he/she shares the same secret key) can verify that the message hasn't been altered by running the message through the HMAC functions using the same key. If the two HMACs match, then the message is considered, with high probability, to be unaltered
RC4 is a stream cipher algorithm. It is used to encrypt streams of data.
The functions available are:
Allegro CL provides support for Base64 encoding within Lisp. Base64 encoding is a 64-bit representation scheme that uses the ASCII characters A-Z, a-z, 0-9, + and /. Since padding could be needed in converting multiples of 8-bits into base64, = characters are used, when necessary, as padding at the end of a converted string. Base64 encoding is described in the RFC2045 document (www.ietf.org/rfc/rfc2045.txt).
These functions provide the Base64 support in Allegro CL:
Here are some examples, first using integer-to-base64-string and base64-string-to-integer:
cl-user(2): (integer-to-base64-string #xfeedfacefeedface) "/u36zv7t+s4=" cl-user(3): (base64-string-to-integer "/u36zv7t+s4=") 18369614222061337294 cl-user(4): (format t "~x" *) feedfacefeedface nil cl-user(5):
And now using usb8-array-to-base64-string and base64-string-to-usb8-array:
;; The encoding results may differ between Windows and
;; UNIX/Linux/Mac OS X (the transcript is from a
;; UNIX machine).
cl-user(5): (setq a (string-to-octets
(setq s
"
(defun deep-thought ()
(sleep (years2secs 7500000))
42)
")
:external-format (crlf-base-ef :latin1)))
#(10 40 100 101 102 117 110 32 100 101 ...)
cl-user(6): (usb8-array-to-base64-string a)
"CihkZWZ1biBkZWVwLXRob3VnaHQgKCkKICAoc2xlZXAgKHllYXJz
MnNlY3MgNzUwMDAwMCkpCiAgNDIpCgA="
cl-user(7): (base64-string-to-usb8-array *)
#(10 40 100 101 102 117 110 32 100 101 ...)
cl-user(8): (setq a2 *)
#(10 40 100 101 102 117 110 32 100 101 ...)
cl-user(9): (equalp a a2)
t
cl-user(10): (octets-to-string a2 :external-format (crlf-base-ef :latin1))
"
(defun deep-thought ()
(sleep (years2secs 7500000))
42)
"
61
61
cl-user(11):
Allegro CL provides implementations of some publicly available encryption algorithms: blowfish (see Section 7.1 Support for Blowfish encryption) and rsa (see Section 7.2 Support for rsa encryption). Please note that we make no claims about the actual security provided by these encryption schemes.
The Blowfish algorithm, described on this page (and links from it), is a high speed symmetric cryptographic algorithm (or cipher). The same key is used to encrypt and decrypt the data. Blowfish encrypts blocks of 64 bits (8 octets) at a time. The functions below can automatically pad out the data to encrypt to be a multiple of 8 octets. Blowfish was designed by Bruce Schneier, a leading authority on cryptography and author of the book Applied Cryptography. Schneier writes in his book published in 1996: "I know of no successful cryptanalysis against Blowfish."
Here are some examples of Blowfish encryption and decryption:
;; Example 1. string encrypting
cl-user(12): (blowfish-encrypt "my secret message"
:key "my key")
#(57 27 110 242 191 19 182 150 1 5 ...)
24
cl-user(13): (blowfish-decrypt * :key "my key" :string t)
"my secret message"
cl-user(14):
;; Example 2. (unsigned-byte 8) encrypting:
;; Here we allocate an (unsigned-byte 8) array with a size
;; that is a multiple of 8 and fill it with data.
;; We can do in-place encryption and decryption.
;; We specify no padding (since otherwise 8 bytes of padding would
;; have to be added and there's no room in this array for that):
;; Create our array:
cl-user(12): (setq aa (make-array 8 :element-type '(unsigned-byte 8)
:initial-contents '(2 4 6 8 10 12 14 16)))
#(2 4 6 8 10 12 14 16)
;; Encrypt it in place
cl-user(13): (blowfish-encrypt aa :key "my key"
:in-place t :pad nil)
#(129 144 108 210 20 227 10 58)
8
;; Verify that it has been modified:
cl-user(14): aa
#(129 144 108 210 20 227 10 58)
;; Now decrypt in place. Notice how the arguments to
;; blowfish-decrypt match those to blowfish-encrypt:
cl-user(15): (blowfish-decrypt aa :key "my key"
:in-place t :pad nil)
#(2 4 6 8 10 12 14 16)
cl-user(16):
;; And verify that the array is now back to normal:
cl-user(16): aa
#(2 4 6 8 10 12 14 16)
cl-user(17):
;; Example 3. use of contexts
;; Create context which holds the key processed by
;; blowfish to prepare it for encryption/decryption:
cl-user(21): (setq cc (blowfish-init "my key"))
#(141 90 172 196 250 88 140 57 179 211 ...)
;; Encrypt something using the context:
cl-user(22): (blowfish-encrypt "my message" :context cc)
#(75 202 37 143 4 243 181 205 211 126 ...)
16
;; And now decrypt it using the same context
;; to show the original string
cl-user(23): (blowfish-decrypt * :context cc :string t)
"my message"
cl-user(24):
It is a common practice to send Blowfish keys to intended recipients using their RSA public keys. See Section 7.2 Support for rsa encryption for information on RSA encryption.
RSA is a public key cipher named after its inventors: Rivest, Shamir and Adleman. A public key cipher differs from a symmetric cipher like Blowfish (see Section 7.1 Support for Blowfish encryption) in two important ways:
With RSA you can encrypt with the Public key and decrypt with the Private key or encrypt with the Private key and decrypt with the Public key. Typically one encrypts with the Public key to send a message to the person with the Private key.
RSA has never been proven to be secure. However the obvious way to crack the encryption involves factoring a very large number. There is no published way of factoring a large number that's better than a brute force attempt of trying all possible factors. Thus by making the key big enough you can be sure that it won't be possible to compute the factors by brute force search in a very long time. There may be other ways to crack RSA encryption that are simply not published yet.
One major downside to RSA is that it is roughly 1000 times slower to encrypt and decrypt than a symmetric cipher like Blowfish. As a result people usually use RSA as means of transmitting a key for a symmetric cipher. For example if Alice wants to send Bob a large document securely she'll first go to Bob's web site and copy down his Public RSA key. Then she'll use a random number generator to create a 64 bit blowfish key. She'll encrypt the blowfish key with Bob's Public key and send the result to Bob. Then she'll encrypt her document using Blowfish and the key she generated. Bob will decrypt the first message from Alice using his Private RSA key. That will give him the Blowfish key he'll need to decrypt the second message from Alice.
Because the public key is known to all you have to be careful to not encrypt small values with an RSA public key since that gives you very little security. For example, suppose you decide to encrypt a 4 digit security code using an RSA public key. A person willing to steal your code need only encrypt the values 0000 through 9999 and compare them to your encrypted value to determine what the value encrypted was. If you want to encrypt a 4 digit security code XXXX then it's best to encrypt instead YYYYYYYYXXXX where the Y's are digits chosen randomly.
An RSA key pair consists of three integers: a modulus, a private exponent and a public exponent. The only number that must be kept secret is the private exponent. The public exponent is usually one of a set of common small numbers. The Allegro RSA key generator always chooses 17 as the public exponent.
An RSA key is represented in Allegro as a vector of three values:
t if this is the public key, nil if this is the private key. This value is to help
you distinguish one key from the other and is not used in the
encryption/decryption code.
RSA is a block cipher: a sequence of octets is encrypted at once. The block size isn't fixed but is usually determined by the size of the modulus. In order to encrypt data whose length is not a multiple of the block size padding is done at the end of the value and information about the padding is added to the value. The format of this padding information is not standard among rsa encryption functions, thus you can't expect any function except rsa-decrypt to be able to decrypt a value encrypted with rsa-encrypt.
The functions associated with RSA encryption and decryption are:
Because RSA encryption is resource intensive compared to symetric encoders like Blowfish, it is a common practice to encode using Blowfish and send Blowfish keys to intended recipients using their RSA public keys. See Section 7.1 Support for Blowfish encryption for information on Blowfish encryption.
Here are some examples of Blowfish encryption and decryption:
;; A call to generate-rsa-keys, such as the following, can take ;; on the order of 10 minutes to complete. The example call ;; could have been made with ':verbose t' to get progress ;; information as it runs. ;; ;; The return value is a list of the public and ;; private keys, both of which are vectors. This list ;; is made the value of the variable 'keys'. cl-user(12): (setq keys (generate-rsa-keys :verbose nil)) (#(t 4696616306992156162791359909817969438301590857320651704912\ 5099728659553054438846018512904176959283177314807123575693727\ 9515543419344057970899365859403176313951068268266882944649562\ 1008090347981854919956845970556254842289211552574616675107428\ 9213609596618613446079618857135830766959762009927055865884710\ 796501 17) #(nil 46966163069921561627913599098179694383015908573206517049125\ 09972865955305443884601851290417695928317731480712357569372795\ 15543419344057970899365859403176313951068268266882944649562100\ 80903479818549199568459705562548422892115525746166751074289213\ 609596618613446079618857135830766959762009927055865884710796501 38678016645817756634752375727912689491895454119111249334573\ 61154124904369189081436818709755749588026367101763117998307007\ 77506345342165387799477766567321557421166007590816670669406236\ 43773618649101682703783799537062586749082756929026484684965113\ 373035085734095558864183533679809881862774879514342408924287321)) ;; Here we encrypt with the public key and decrypt with the private key ;; we could have encrypted with the private key and decrypted with the ;; public key as well. cl-user(13): (rsa-encrypt "my secret message" (car keys)) #(102 136 69 180 180 27 185 63 132 137 ...) cl-user(14): (rsa-decrypt * (cadr keys) :string t) "my secret message" cl-user(15):
The inflate module allows you to open streams to files with
gzip compressed data and to uncompress the data while reading the
file. To load the inflate module, evaluate (require
:inflate). Symbols in the inflate module are in the
util.zip package.
The functions util.zip:inflate and util.zip:skip-gzip-header can
be applied to instances of the class util.zip:inflate-stream.
Arguments: input-stream output-stream
The compressed information from the input-stream is read and the uncompressed information is written to the output-stream.
Both streams must support (unsigned-byte 8) element reading and writing.
Arguments: input-stream
If the input stream is positioned on the header of a gzip'ed file then
skip that header. input-stream is not an instance
of the class util.zip:inflate-stream. It is
simply an input stream (opened, for example, with open. The file position must be moved to the
beginning of the compressed data before unziping, and onlt at that
point should an instance of util.zip:inflate-stream be
created (see util.zip:inflate-stream).
If the input stream is not positioned on a gzip header then nothing is done.
The stream class for instances of files containing comressed gzip'ed data. Instances of this class are suitable as arguments to util.zip:inflate.
To create an instance of this class, do the following:
(make-instance 'inflate-stream :input-handle <stream created in 1>)
The call to make-instance will return a stream which can be read to recover the uncompressed data.
Closing the inflate-stream will also close the stream created in step 1.
Suppose we have a compressed file foo.cl.gz. Uncompressed the file looks like:
;; file foo.cl begin (in-package :user) (defpackage :foo (:use :cl :excl)) (defun foo (y) (bar y)) ;; file foo.cl end
In the following transcript, we open the file, strip the gzip header, create an inflate-stream instance, read the file line by line, close the inflate-stream, and close the file. We could also inflate the while file by calling inflate.
cl-user(2): (require :inflate)
; Fast loading /tmp_mnt/net/quadra/acl/7.0/bin/linux86/code/inflate.fasl
; Fast loading from bundle code/iodefs.fasl.
; Fast loading from bundle code/iordefs.fasl.
t
cl-user(3): (setq s (open "foo.cl.gz" :direction :input))
#<file-simple-stream #P"foo.cl.gz" for input pos 0 @ #x71805b7a>
cl-user(4): (util.zip:skip-gzip-header s)
t
cl-user(5): (setq is
(make-instance 'util.zip:inflate-stream :input-handle s))
#<util.zip:inflate-stream [not completely built] @ #x718dd00a>
cl-user(6): (read-line is nil s)
";; file foo.cl begin"
nil
cl-user(7): (read-line is nil s)
"(in-package :user)"
nil
cl-user(8): (read-line is nil s)
""
nil
cl-user(9): (read-line is nil s)
"(defpackage :foo (:use :cl :excl))"
nil
cl-user(10): (read-line is nil s)
"(defun foo (y) (bar y))"
nil
cl-user(11): (read-line is nil s)
""
nil
cl-user(12): (read-line is nil s)
";; file foo.cl end"
t
cl-user(13): (read-line is nil s)
#<file-simple-stream #P"foo.cl.gz" for input pos 0 @ #x71805b7a>
cl-user(14): (close is) ;; this also closes is.
t
cl-user(15):
The source code to the gzip utility is included with the Allegro CL distribution, in [Allegro directory]/src/inflate.cl.
PAM stands for Pluggable Authentication Modules. It is a flexible mechanism for authenticating users. An Allegro CL module provides a Lisp wrapper around the PAM API on Linux, Solaris, and some other unixlike operating systems. We do not discuss PAM in detail here. See www.kernel.org/pub/linux/libs/pam/FAQ.
PAM is supported on the following platforms:
PAM is not supported in Allegro CL on the following platforms:
The PAM API is is loaded by evaluating (require
:pam). Symbols naming functionality are in the
util.pam package. Depending on your system configuration, your
program may be required to run with 'root' privileges to successfully
make use of PAM.
There is one class and several operators defined in the pam module. They are:
pam (class)
The class of pam objects. A pam object is
created by pam-start.
Arguments: service-name user &key conversation data
This function provides a wrapper around the pam_start(3) PAM
library function. service-name should be
a string naming the desired PAM service.
user may be nil
or a string.
If conversation is specified, it should be
a function (or a symbol naming a function) which will perform the PAM
"conversation", when necessary. data is
optional user-defined data that will be passed to the conversation
function. If conversation is nil (the default), a default conversation function
will be used. For more information on conversation functions, see
Section 9.1 PAM conversation functions.
This function returns a pam object on success. You will
pass this object to other functions and methods. If pam-start
fails, an error is signalled.
Arguments: pam &optional status
The default method is analogous to the pam_end(3) PAM library
function. pam must be a pam object returned by pam-start. If
status is specified, it should be an
integer. See the pam_end(3) description (in PAM documentation
not supplied here) for details on the use of
status. If status is nil, excl.osi:*pam-success* will
be used.
This method returns t on success, otherwise
it signals an error.
Arguments: (var &rest rest) &body body
with-pam is a convenience macro which evaluates body with var bound to the result of calling pam-start with the arguments specified in rest. pam-end will be called when body terminates, either normally or abnormally.
(util.pam:with-pam (pam "login" "jimmy") (format t "This is the body~%"))
Arguments: pam &key flags password
This default method is analogous to the pam_authenticate(3) PAM library function. pam must be a pam object returned by pam-start. If password is specified, it should be a string. It will be used when needed if the default conversation (see pam-start) is used. If flags is specified, it should be an integer.
On success, this function returns t.
If the call is not successful, the function returns two values,
nil and a status value. The status value
will be a keyword or an integer. Possible status value keywords are:
:auth-err
:cred-insufficient
:authinfo-unavail
:user-unknown
:max-tries
If pam_authenticate(3) returns an unrecognized status code, it will be returned without being converted to a keyword.
Arguments: pam microseconds
This method is used to request a delay of at least the specified number of microseconds (which must be an integer) before returning from an unsuccessful pam-authenticate call. Setting a delay slows down attempts to rapidly try different passwords for an account.
If multiple calls to set-pam-fail-delay are made, the largest requested delay will be used. On some systems, it is possible that the PAM modules themselves may request delays, so you might notice a delay longer than one you requested (and in particular, you might notice a delay even though you hadn't called set-pam-fail-delay).
The actual delay will is computed pseudorandomly and may differ by as much as 25% above or below the maximum requested value.
Regardless of the success or failure of a pam-authenticate call, the delay is set back to 0 before returning from pam-authenticate. This means that you should generally call set-pam-fail-delay before each call to pam-authenticate.
The default conversation function will display prompts and request
input from *terminal-io*.
If the password argument is supplied to pam-authenticate, it is probable
that no interaction with *terminal-io* will occur
at all. However, if your system configuration or application has
different requirements, you can provide your own conversation
function.
The conversation function will be called by the PAM API when it needs to collect information to move the authentication process along.
If you supply your own conversation function, it should accept two required arguments, and one keyword argument:
Arguments: messages data &key password
messages will be a list of pam-message
structures. data will be the same value
that was supplied to pam-start.
password will be the password that was
passed to pam-authenticate (and may
possibly be nil).
The conversation function should return a list of pam-response structures. The list must have the same length as the messages list. The first entry in the list should be the response that corresponds to the first message. The second entry should correspond to the second message, and so forth. See pam_conv(3) for details.
The pam-message structure has two slots, style and
message. The style slot will be one of the
following keywords (:prompt-echo-off, :prompt-echo-on,
:error, :text) or an integer (indicating an unrecognized
style). message will be a string which may be used
to prompt the user.
The pam-response structure has two slots, response and
code. response should be a string with the
data requested by the corresponding message. code
should be an integer (the default is 0). Again, see
pam_conv(3) for details.
The popular system definition facility, asdf, is included with
Allegro CL. Evaluate (require :asdf) to load it
into a running Lisp. See [Allegro
directory]/code/asdf.readme for more information,
[Allegro directory]/code/asdf.license for the
license, and [Allegro directory]/src/asdf.lisp for
the source code. asdf documentation can be found on the web
at
http://constantly.at/lisp/asdf/.
Allegro CL provides support for extracting contents from tar files. To use this facility, evaluate
(require :tar)
The tar functions are named by symbols exported from the util.tar package. The tar facility was added in a patch. You must have loaded the patch to use it. See sys:update-allegro.
The tar functions take streams (rather than pathnames) as arguments. util.tar:list-tar lists the contents of the tar file. util.tar:extract-tar extracts the contents into a specified directory.
Here are example forms using the tar functions:
(with-open-file (s "foo.tgz") (util.tar:list-tar s :gzip t)) (with-open-file (s "foo.tgz") (util.tar:extract-tar s :gzip t :directory "tmp/"))
Arguments: stream &key gzip
List, to *terminal-io*,
the contents of stream, which should be a
stream opened to a tar file. If stream is
compressed with gzip compression, specify a
non-nil value
for gzip. bzip2 compression is not
supported.
Arguments: stream &key gzip directory verbose
Extract, to directory, the contents
of stream, which should be a stream opened
to a tar file. If stream is compressed with gzip
compression, specify a non-nil value
for gzip. bzip2 compression is not
supported.
directory defaults
to nil, which means extract to the current
directory (as returned by current-directory).
If verbose is specified
non-nil, information about what is being done
will be printed.
Copyright (c) 1998-2009, Franz Inc. Oakland, CA., USA. All rights reserved.
Documentation for Allegro CL version 8.1. This page was not revised from the 8.0 page.
Created 2009.8.24.
| Allegro CL version 8.1 Unrevised from 8.0 to 8.1. 8.0 version | ||||||||