Provided by: libcrypt-dev_4.4.36-4build1_amd64 bug

NAME

     crypt — storage format for hashed passphrases and available hashing methods

DESCRIPTION

     The hashing methods implemented by crypt(3) are designed only to process user passphrases
     for storage and authentication; they are not suitable for use as general-purpose
     cryptographic hashes.

     Passphrase hashing is not a replacement for strong passphrases.  It is always possible for
     an attacker with access to the hashed passphrases to guess and check possible cleartext
     passphrases.  However, with a strong hashing method, guessing will be too slow for the
     attacker to discover a strong passphrase.

     All of the hashing methods use a “salt” to perturb the hash function, so that the same
     passphrase may produce many possible hashes.  Newer methods accept longer salt strings.  The
     salt should be chosen at random for each user.  Salt defeats a number of attacks:

     1.   It is not possible to hash a passphrase once and then test it against each account's
          stored hash; the hash calculation must be repeated for each account.

     2.   It is not possible to tell whether two accounts use the same passphrase without
          successfully guessing one of the phrases.

     3.   Tables of precalculated hashes of commonly used passphrases must have an entry for each
          possible salt, which makes them impractically large.

     All of the hashing methods are also deliberately engineered to be slow; they use many
     iterations of an underlying cryptographic primitive to increase the cost of each guess.  The
     newer hashing methods allow the number of iterations to be adjusted, using the “CPU time
     cost” parameter to crypt_gensalt(3).  This makes it possible to keep the hash slow as
     hardware improves.

FORMAT OF HASHED PASSPHRASES

     All of the hashing methods supported by crypt(3) produce a hashed passphrase which consists
     of four components: prefix, options, salt, and hash.  The prefix controls which hashing
     method is to be used, and is the appropriate string to pass to crypt_gensalt(3) to select
     that method.  The contents of options, salt, and hash are up to the method.  Depending on
     the method, the prefix and options components may be empty.

     The setting argument to crypt(3) must begin with the first three components of a valid
     hashed passphrase, but anything after that is ignored.  This makes authentication simple:
     hash the input passphrase using the stored passphrase as the setting, and then compare the
     result to the stored passphrase.

     Hashed passphrases are always entirely printable ASCII, and do not contain any whitespace or
     the characters ‘:’, ‘;’, ‘*’, ‘!’, or ‘\’.  (These characters are used as delimiters and
     special markers in the passwd(5) and shadow(5) files.)

     The syntax of each component of a hashed passphrase is up to the hashing method.  ‘$’
     characters usually delimit components, and the salt and hash are usually encoded as numerals
     in base 64.  The details of this base-64 encoding vary among hashing methods.  The common
     “base64” encoding specified by RFC 4648 is usually not used.

AVAILABLE HASHING METHODS

     This is a list of all the hashing methods supported by crypt(3), in decreasing order of
     strength.  Many of the older methods are now considered too weak to use for new passphrases.
     The hashed passphrase format is expressed with extended regular expressions (see regex(7))
     and does not show the division into prefix, options, salt, and hash.

   yescrypt
     yescrypt is a scalable passphrase hashing scheme designed by Solar Designer, which is based
     on Colin Percival's scrypt.  Recommended for new hashes.

     Prefix
         "$y$"

     Hashed passphrase format
         \$y\$[./A-Za-z0-9]+\$[./A-Za-z0-9]{,86}\$[./A-Za-z0-9]{43}

     Maximum passphrase length
         unlimited

     Hash size
         256 bits

     Salt size
         up to 512 (128+ recommended) bits

     CPU time cost parameter
         1 to 11 (logarithmic)

   gost-yescrypt
     gost-yescrypt uses the output from the yescrypt hashing method in place of a hmac message.
     Thus, the yescrypt crypto properties are superseded by the GOST R 34.11-2012 (Streebog) hash
     function with a 256 bit digest.  This hashing method is useful in applications that need
     modern passphrase hashing methods, but require to rely on the cryptographic properties of
     GOST algorithms.  The GOST R 34.11-2012 (Streebog) hash function has been published by the
     IETF as RFC 6986.  Recommended for new hashes.

     Prefix
         "$gy$"

     Hashed passphrase format
         \$gy\$[./A-Za-z0-9]+\$[./A-Za-z0-9]{,86}\$[./A-Za-z0-9]{43}

     Maximum passphrase length
         unlimited

     Hash size
         256 bits

     Salt size
         up to 512 (128+ recommended) bits

     CPU time cost parameter
         1 to 11 (logarithmic)

   scrypt
     scrypt is a password-based key derivation function created by Colin Percival, originally for
     the Tarsnap online backup service.  The algorithm was specifically designed to make it
     costly to perform large-scale custom hardware attacks by requiring large amounts of memory.
     In 2016, the scrypt algorithm was published by IETF as RFC 7914.

     Prefix
         "$7$"

     Hashed passphrase format
         \$7\$[./A-Za-z0-9]{11,97}\$[./A-Za-z0-9]{43}

     Maximum passphrase length
         unlimited

     Hash size
         256 bits

     Salt size
         up to 512 (128+ recommended) bits

     CPU time cost parameter
         6 to 11 (logarithmic)

   bcrypt
     A hash based on the Blowfish block cipher, modified to have an extra-expensive key schedule.
     Originally developed by Niels Provos and David Mazieres for OpenBSD and also supported on
     recent versions of FreeBSD and NetBSD, on Solaris 10 and newer, and on several GNU/*/Linux
     distributions.

     Prefix
         "$2b$"

     Hashed passphrase format
         \$2[abxy]\$[0-9]{2}\$[./A-Za-z0-9]{53}

     Maximum passphrase length
         72 characters

     Hash size
         184 bits

     Salt size
         128 bits

     CPU time cost parameter
         4 to 31 (logarithmic)

     The alternative prefix "$2y$" is equivalent to "$2b$".  It exists for historical reasons
     only.  The alternative prefixes "$2a$" and "$2x$" provide bug-compatibility with
     crypt_blowfish 1.0.4 and earlier, which incorrectly processed characters with the 8th bit
     set.

   sha512crypt
     A hash based on SHA-2 with 512-bit output, originally developed by Ulrich Drepper for GNU
     libc.  Supported on Linux but not common elsewhere.  Acceptable for new hashes.  The default
     CPU time cost parameter is 5000, which is too low for modern hardware.

     Prefix
         "$6$"

     Hashed passphrase format
         \$6\$(rounds=[1-9][0-9]+\$)?[^$:\n]{1,16}\$[./0-9A-Za-z]{86}

     Maximum passphrase length
         unlimited

     Hash size
         512 bits

     Salt size
         6 to 96 bits

     CPU time cost parameter
         1000 to 999,999,999

   sha256crypt
     A hash based on SHA-2 with 256-bit output, originally developed by Ulrich Drepper for GNU
     libc.  Supported on Linux but not common elsewhere.  Acceptable for new hashes.  The default
     CPU time cost parameter is 5000, which is too low for modern hardware.

     Prefix
         "$5$"

     Hashed passphrase format
         \$5\$(rounds=[1-9][0-9]+\$)?[^$:\n]{1,16}\$[./0-9A-Za-z]{43}

     Maximum passphrase length
         unlimited

     Hash size
         256 bits

     Salt size
         6 to 96 bits

     CPU time cost parameter
         1000 to 999,999,999

   sha1crypt
     A hash based on HMAC-SHA1.  Originally developed by Simon Gerraty for NetBSD.  Not as weak
     as the DES-based hashes below, but SHA1 is so cheap on modern hardware that it should not be
     used for new hashes.

     Prefix
         "$sha1"

     Hashed passphrase format
         \$sha1\$[1-9][0-9]+\$[./0-9A-Za-z]{1,64}\$[./0-9A-Za-z]{8,64}[./0-9A-Za-z]{32}

     Maximum passphrase length
         unlimited

     Hash size
         160 bits

     Salt size
         6 to 384 bits

     CPU time cost parameter
         4 to 4,294,967,295

   SunMD5
     A hash based on the MD5 algorithm, with additional cleverness to make precomputation
     difficult, originally developed by Alec David Muffet for Solaris.  Not adopted elsewhere, to
     our knowledge.  Not as weak as the DES-based hashes below, but MD5 is so cheap on modern
     hardware that it should not be used for new hashes.

     Prefix
         "$md5"

     Hashed passphrase format
         \$md5(,rounds=[1-9][0-9]+)?\$[./0-9A-Za-z]{8}\${1,2}[./0-9A-Za-z]{22}

     Maximum passphrase length
         unlimited

     Hash size
         128 bits

     Salt size
         48 bits

     CPU time cost parameter
         4096 to 4,294,963,199

   md5crypt
     A hash based on the MD5 algorithm, originally developed by Poul-Henning Kamp for FreeBSD.
     Supported on most free Unixes and newer versions of Solaris.  Not as weak as the DES-based
     hashes below, but MD5 is so cheap on modern hardware that it should not be used for new
     hashes.  CPU time cost is not adjustable.

     Prefix
         "$1$"

     Hashed passphrase format
         \$1\$[^$:\n]{1,8}\$[./0-9A-Za-z]{22}

     Maximum passphrase length
         unlimited

     Hash size
         128 bits

     Salt size
         6 to 48 bits

     CPU time cost parameter
         1000

   bsdicrypt (BSDI extended DES)
     A weak extension of traditional DES, which eliminates the length limit, increases the salt
     size, and makes the time cost tunable.  It originates with BSDI and is also available on at
     least NetBSD, OpenBSD, and FreeBSD due to the use of David Burren's FreeSec library.  It is
     better than bigcrypt and traditional DES, but still should not be used for new hashes.

     Prefix
         "_"

     Hashed passphrase format
         _[./0-9A-Za-z]{19}

     Maximum passphrase length
         unlimited (ignores 8th bit)

     Hash size
         64 bits

     Effective key size
         56 bits

     Salt size
         24 bits

     CPU time cost parameter
         1 to 16,777,215 (must be odd)

   bigcrypt
     A weak extension of traditional DES, available on some System V-derived Unixes.  All it does
     is raise the length limit from 8 to 128 characters, and it does this in a crude way that
     allows attackers to guess chunks of a long passphrase in parallel.  It should not be used
     for new hashes.

     Prefix
         "" (empty string)

     Hashed passphrase format
         [./0-9A-Za-z]{13,178}

     Maximum passphrase length
         128 characters (ignores 8th bit)

     Hash size
         up to 1024 bits

     Effective key size
         up to 896 bits

     Salt size
         12 bits

     CPU time cost parameter
         25

   descrypt (Traditional DES)
     The original hashing method from Unix V7, based on the DES block cipher.  Because DES is
     cheap on modern hardware, because there are only 4096 possible salts and 2**56 possible
     hashes, and because it truncates passphrases to 8 characters, it is feasible to discover any
     passphrase hashed with this method.  It should only be used if you absolutely have to
     generate hashes that will work on an old operating system that supports nothing else.

     Prefix
         "" (empty string)

     Hashed passphrase format
         [./0-9A-Za-z]{13}

     Maximum passphrase length
         8 characters (ignores 8th bit)

     Hash size
         64 bits

     Effective key size
         56 bits

     Salt size
         12 bits

     CPU time cost parameter
         25

   NT
     The hashing method used for network authentication in some versions of the SMB/CIFS
     protocol.  Available, for cross-compatibility's sake, on FreeBSD.  Based on MD4.  Has no
     salt or tunable cost parameter.  Like traditional DES, it is so weak that any passphrase
     hashed with this method is guessable.  It should only be used if you absolutely have to
     generate hashes that will work on an old operating system that supports nothing else.

     Prefix
         "$3$"

     Hashed passphrase format
         \$3\$\$[0-9a-f]{32}

     Maximum passphrase length
         unlimited

     Hash size
         256 bits

     Salt size
         0 bits

     CPU time cost parameter
         1

SEE ALSO

     crypt(3), crypt_gensalt(3), getpwent(3), passwd(5), shadow(5), pam(8)

     Niels Provos and David Mazieres, “A Future-Adaptable Password Scheme”, Proceedings of the
     1999 USENIX Annual Technical Conference, https://www.usenix.org/events/usenix99/provos.html,
     June 1999.

     Robert Morris and Ken Thompson, “Password Security: A Case History”, Communications of the
     ACM, 11, 22, http://wolfram.schneider.org/bsd/7thEdManVol2/password/password.pdf, 1979.