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393 lines
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393 lines
16 KiB
Plaintext
@c This node must have no pointers.
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@node Cryptographic Functions
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@c @node Cryptographic Functions, Debugging Support, System Configuration, Top
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@chapter DES Encryption and Password Handling
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@c %MENU% DES encryption and password handling
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On many systems, it is unnecessary to have any kind of user
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authentication; for instance, a workstation which is not connected to a
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network probably does not need any user authentication, because to use
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the machine an intruder must have physical access.
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Sometimes, however, it is necessary to be sure that a user is authorized
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to use some service a machine provides---for instance, to log in as a
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particular user id (@pxref{Users and Groups}). One traditional way of
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doing this is for each user to choose a secret @dfn{password}; then, the
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system can ask someone claiming to be a user what the user's password
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is, and if the person gives the correct password then the system can
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grant the appropriate privileges.
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If all the passwords are just stored in a file somewhere, then this file
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has to be very carefully protected. To avoid this, passwords are run
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through a @dfn{one-way function}, a function which makes it difficult to
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work out what its input was by looking at its output, before storing in
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the file.
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@Theglibc{} provides a one-way function that is compatible with
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the behavior of the @code{crypt} function introduced in FreeBSD 2.0.
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It supports two one-way algorithms: one based on the MD5
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message-digest algorithm that is compatible with modern BSD systems,
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and the other based on the Data Encryption Standard (DES) that is
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compatible with Unix systems.
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It also provides support for Secure RPC, and some library functions that
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can be used to perform normal DES encryption.
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@menu
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* Legal Problems:: This software can get you locked up, or worse.
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* getpass:: Prompting the user for a password.
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* crypt:: A one-way function for passwords.
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* DES Encryption:: Routines for DES encryption.
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@end menu
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@node Legal Problems
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@section Legal Problems
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Because of the continuously changing state of the law, it's not possible
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to provide a definitive survey of the laws affecting cryptography.
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Instead, this section warns you of some of the known trouble spots; this
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may help you when you try to find out what the laws of your country are.
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Some countries require that you have a licence to use, possess, or import
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cryptography. These countries are believed to include Byelorussia,
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Burma, India, Indonesia, Israel, Kazakhstan, Pakistan, Russia, and Saudi
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Arabia.
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Some countries restrict the transmission of encrypted messages by radio;
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some telecommunications carriers restrict the transmission of encrypted
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messages over their network.
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Many countries have some form of export control for encryption software.
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The Wassenaar Arrangement is a multilateral agreement between 33
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countries (Argentina, Australia, Austria, Belgium, Bulgaria, Canada, the
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Czech Republic, Denmark, Finland, France, Germany, Greece, Hungary,
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Ireland, Italy, Japan, Luxembourg, the Netherlands, New Zealand, Norway,
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Poland, Portugal, the Republic of Korea, Romania, the Russian
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Federation, the Slovak Republic, Spain, Sweden, Switzerland, Turkey,
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Ukraine, the United Kingdom and the United States) which restricts some
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kinds of encryption exports. Different countries apply the arrangement
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in different ways; some do not allow the exception for certain kinds of
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``public domain'' software (which would include this library), some
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only restrict the export of software in tangible form, and others impose
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significant additional restrictions.
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The United States has additional rules. This software would generally
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be exportable under 15 CFR 740.13(e), which permits exports of
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``encryption source code'' which is ``publicly available'' and which is
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``not subject to an express agreement for the payment of a licensing fee or
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royalty for commercial production or sale of any product developed with
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the source code'' to most countries.
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The rules in this area are continuously changing. If you know of any
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information in this manual that is out-of-date, please report it to
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the bug database. @xref{Reporting Bugs}.
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@node getpass
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@section Reading Passwords
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When reading in a password, it is desirable to avoid displaying it on
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the screen, to help keep it secret. The following function handles this
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in a convenient way.
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@comment unistd.h
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@comment BSD
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@deftypefun {char *} getpass (const char *@var{prompt})
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@code{getpass} outputs @var{prompt}, then reads a string in from the
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terminal without echoing it. It tries to connect to the real terminal,
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@file{/dev/tty}, if possible, to encourage users not to put plaintext
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passwords in files; otherwise, it uses @code{stdin} and @code{stderr}.
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@code{getpass} also disables the INTR, QUIT, and SUSP characters on the
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terminal using the @code{ISIG} terminal attribute (@pxref{Local Modes}).
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The terminal is flushed before and after @code{getpass}, so that
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characters of a mistyped password are not accidentally visible.
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In other C libraries, @code{getpass} may only return the first
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@code{PASS_MAX} bytes of a password. @Theglibc{} has no limit, so
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@code{PASS_MAX} is undefined.
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The prototype for this function is in @file{unistd.h}. @code{PASS_MAX}
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would be defined in @file{limits.h}.
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@end deftypefun
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This precise set of operations may not suit all possible situations. In
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this case, it is recommended that users write their own @code{getpass}
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substitute. For instance, a very simple substitute is as follows:
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@smallexample
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@include mygetpass.c.texi
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@end smallexample
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The substitute takes the same parameters as @code{getline}
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(@pxref{Line Input}); the user must print any prompt desired.
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@node crypt
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@section Encrypting Passwords
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@comment crypt.h
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@comment BSD, SVID
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@deftypefun {char *} crypt (const char *@var{key}, const char *@var{salt})
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The @code{crypt} function takes a password, @var{key}, as a string, and
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a @var{salt} character array which is described below, and returns a
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printable ASCII string which starts with another salt. It is believed
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that, given the output of the function, the best way to find a @var{key}
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that will produce that output is to guess values of @var{key} until the
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original value of @var{key} is found.
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The @var{salt} parameter does two things. Firstly, it selects which
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algorithm is used, the MD5-based one or the DES-based one. Secondly, it
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makes life harder for someone trying to guess passwords against a file
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containing many passwords; without a @var{salt}, an intruder can make a
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guess, run @code{crypt} on it once, and compare the result with all the
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passwords. With a @var{salt}, the intruder must run @code{crypt} once
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for each different salt.
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For the MD5-based algorithm, the @var{salt} should consist of the string
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@code{$1$}, followed by up to 8 characters, terminated by either
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another @code{$} or the end of the string. The result of @code{crypt}
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will be the @var{salt}, followed by a @code{$} if the salt didn't end
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with one, followed by 22 characters from the alphabet
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@code{./0-9A-Za-z}, up to 34 characters total. Every character in the
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@var{key} is significant.
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For the DES-based algorithm, the @var{salt} should consist of two
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characters from the alphabet @code{./0-9A-Za-z}, and the result of
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@code{crypt} will be those two characters followed by 11 more from the
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same alphabet, 13 in total. Only the first 8 characters in the
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@var{key} are significant.
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The MD5-based algorithm has no limit on the useful length of the
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password used, and is slightly more secure. It is therefore preferred
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over the DES-based algorithm.
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When the user enters their password for the first time, the @var{salt}
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should be set to a new string which is reasonably random. To verify a
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password against the result of a previous call to @code{crypt}, pass
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the result of the previous call as the @var{salt}.
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@end deftypefun
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The following short program is an example of how to use @code{crypt} the
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first time a password is entered. Note that the @var{salt} generation
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is just barely acceptable; in particular, it is not unique between
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machines, and in many applications it would not be acceptable to let an
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attacker know what time the user's password was last set.
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@smallexample
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@include genpass.c.texi
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@end smallexample
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The next program shows how to verify a password. It prompts the user
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for a password and prints ``Access granted.'' if the user types
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@code{GNU libc manual}.
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@smallexample
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@include testpass.c.texi
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@end smallexample
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@comment crypt.h
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@comment GNU
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@deftypefun {char *} crypt_r (const char *@var{key}, const char *@var{salt}, {struct crypt_data *} @var{data})
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The @code{crypt_r} function does the same thing as @code{crypt}, but
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takes an extra parameter which includes space for its result (among
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other things), so it can be reentrant. @code{data@w{->}initialized} must be
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cleared to zero before the first time @code{crypt_r} is called.
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The @code{crypt_r} function is a GNU extension.
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@end deftypefun
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The @code{crypt} and @code{crypt_r} functions are prototyped in the
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header @file{crypt.h}.
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@node DES Encryption
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@section DES Encryption
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The Data Encryption Standard is described in the US Government Federal
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Information Processing Standards (FIPS) 46-3 published by the National
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Institute of Standards and Technology. The DES has been very thoroughly
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analyzed since it was developed in the late 1970s, and no new
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significant flaws have been found.
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However, the DES uses only a 56-bit key (plus 8 parity bits), and a
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machine has been built in 1998 which can search through all possible
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keys in about 6 days, which cost about US$200000; faster searches would
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be possible with more money. This makes simple DES insecure for most
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purposes, and NIST no longer permits new US government systems
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to use simple DES.
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For serious encryption functionality, it is recommended that one of the
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many free encryption libraries be used instead of these routines.
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The DES is a reversible operation which takes a 64-bit block and a
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64-bit key, and produces another 64-bit block. Usually the bits are
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numbered so that the most-significant bit, the first bit, of each block
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is numbered 1.
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Under that numbering, every 8th bit of the key (the 8th, 16th, and so
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on) is not used by the encryption algorithm itself. But the key must
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have odd parity; that is, out of bits 1 through 8, and 9 through 16, and
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so on, there must be an odd number of `1' bits, and this completely
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specifies the unused bits.
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@comment crypt.h
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@comment BSD, SVID
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@deftypefun void setkey (const char *@var{key})
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The @code{setkey} function sets an internal data structure to be an
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expanded form of @var{key}. @var{key} is specified as an array of 64
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bits each stored in a @code{char}, the first bit is @code{key[0]} and
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the 64th bit is @code{key[63]}. The @var{key} should have the correct
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parity.
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@end deftypefun
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@comment crypt.h
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@comment BSD, SVID
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@deftypefun void encrypt (char *@var{block}, int @var{edflag})
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The @code{encrypt} function encrypts @var{block} if
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@var{edflag} is 0, otherwise it decrypts @var{block}, using a key
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previously set by @code{setkey}. The result is
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placed in @var{block}.
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Like @code{setkey}, @var{block} is specified as an array of 64 bits each
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stored in a @code{char}, but there are no parity bits in @var{block}.
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@end deftypefun
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@comment crypt.h
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@comment GNU
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@deftypefun void setkey_r (const char *@var{key}, {struct crypt_data *} @var{data})
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@comment crypt.h
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@comment GNU
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@deftypefunx void encrypt_r (char *@var{block}, int @var{edflag}, {struct crypt_data *} @var{data})
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These are reentrant versions of @code{setkey} and @code{encrypt}. The
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only difference is the extra parameter, which stores the expanded
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version of @var{key}. Before calling @code{setkey_r} the first time,
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@code{data->initialized} must be cleared to zero.
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@end deftypefun
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The @code{setkey_r} and @code{encrypt_r} functions are GNU extensions.
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@code{setkey}, @code{encrypt}, @code{setkey_r}, and @code{encrypt_r} are
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defined in @file{crypt.h}.
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@deftypefun int ecb_crypt (char *@var{key}, char *@var{blocks}, unsigned @var{len}, unsigned @var{mode})
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The function @code{ecb_crypt} encrypts or decrypts one or more blocks
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using DES. Each block is encrypted independently.
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The @var{blocks} and the @var{key} are stored packed in 8-bit bytes, so
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that the first bit of the key is the most-significant bit of
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@code{key[0]} and the 63rd bit of the key is stored as the
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least-significant bit of @code{key[7]}. The @var{key} should have the
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correct parity.
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@var{len} is the number of bytes in @var{blocks}. It should be a
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multiple of 8 (so that there is a whole number of blocks to encrypt).
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@var{len} is limited to a maximum of @code{DES_MAXDATA} bytes.
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The result of the encryption replaces the input in @var{blocks}.
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The @var{mode} parameter is the bitwise OR of two of the following:
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@vtable @code
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@item DES_ENCRYPT
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This constant, used in the @var{mode} parameter, specifies that
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@var{blocks} is to be encrypted.
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@item DES_DECRYPT
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This constant, used in the @var{mode} parameter, specifies that
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@var{blocks} is to be decrypted.
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@item DES_HW
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This constant, used in the @var{mode} parameter, asks to use a hardware
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device. If no hardware device is available, encryption happens anyway,
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but in software.
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@item DES_SW
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This constant, used in the @var{mode} parameter, specifies that no
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hardware device is to be used.
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@end vtable
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The result of the function will be one of these values:
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@vtable @code
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@item DESERR_NONE
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The encryption succeeded.
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@item DESERR_NOHWDEVICE
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The encryption succeeded, but there was no hardware device available.
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@item DESERR_HWERROR
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The encryption failed because of a hardware problem.
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@item DESERR_BADPARAM
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The encryption failed because of a bad parameter, for instance @var{len}
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is not a multiple of 8 or @var{len} is larger than @code{DES_MAXDATA}.
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@end vtable
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@end deftypefun
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@deftypefun int DES_FAILED (int @var{err})
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This macro returns 1 if @var{err} is a `success' result code from
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@code{ecb_crypt} or @code{cbc_crypt}, and 0 otherwise.
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@end deftypefun
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@deftypefun int cbc_crypt (char *@var{key}, char *@var{blocks}, unsigned @var{len}, unsigned @var{mode}, char *@var{ivec})
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The function @code{cbc_crypt} encrypts or decrypts one or more blocks
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using DES in Cipher Block Chaining mode.
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For encryption in CBC mode, each block is exclusive-ored with @var{ivec}
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before being encrypted, then @var{ivec} is replaced with the result of
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the encryption, then the next block is processed. Decryption is the
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reverse of this process.
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This has the advantage that blocks which are the same before being
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encrypted are very unlikely to be the same after being encrypted, making
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it much harder to detect patterns in the data.
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Usually, @var{ivec} is set to 8 random bytes before encryption starts.
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Then the 8 random bytes are transmitted along with the encrypted data
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(without themselves being encrypted), and passed back in as @var{ivec}
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for decryption. Another possibility is to set @var{ivec} to 8 zeroes
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initially, and have the first the block encrypted consist of 8 random
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bytes.
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Otherwise, all the parameters are similar to those for @code{ecb_crypt}.
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@end deftypefun
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@comment rpc/des_crypt.h
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@comment SUNRPC
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@deftypefun void des_setparity (char *@var{key})
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The function @code{des_setparity} changes the 64-bit @var{key}, stored
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packed in 8-bit bytes, to have odd parity by altering the low bits of
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each byte.
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@end deftypefun
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The @code{ecb_crypt}, @code{cbc_crypt}, and @code{des_setparity}
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functions and their accompanying macros are all defined in the header
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@file{rpc/des_crypt.h}.
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