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This is a major rewrite of the description of 'crypt', 'getentropy', and 'getrandom'. A few highlights of the content changes: - Throughout the manual, public headers, and user-visible messages, I replaced the term "password" with "passphrase", the term "password database" with "user database", and the term "encrypt(ion)" with "(one-way) hashing" whenever it was applied to passphrases. I didn't bother making this change in internal code or tests. The use of the term "password" in ruserpass.c survives, because that refers to a keyword in netrc files, but it is adjusted to make this clearer. There is a note in crypt.texi explaining that they were traditionally called passwords but single words are not good enough anymore, and a note in users.texi explaining that actual passphrase hashes are found in a "shadow" database nowadays. - There is a new short introduction to the "Cryptographic Functions" section, explaining how we do not intend to be a general-purpose cryptography library, and cautioning that there _are_, or have been, legal restrictions on the use of cryptography in many countries, without getting into any kind of detail that we can't promise to keep up to date. - I added more detail about what a "one-way function" is, and why they are used to obscure passphrases for storage. I removed the paragraph saying that systems not connected to a network need no user authentication, because that's a pretty rare situation nowadays. (It still says "sometimes it is necessary" to authenticate the user, though.) - I added documentation for all of the hash functions that glibc actually supports, but not for the additional hash functions supported by libxcrypt. If we're going to keep this manual section around after the transition is more advanced, it would probably make sense to add them then. - There is much more detailed discussion of how to generate a salt, and the failure behavior for crypt is documented. (Returning an invalid hash on failure is what libxcrypt does; Solar Designer's notes say that this was done "for compatibility with old programs that assume crypt can never fail".) - As far as I can tell, the header 'crypt.h' is entirely a GNU invention, and never existed on any other Unix lineage. The function 'crypt', however, was in Issue 1 of the SVID and is now in the XSI component of POSIX. I tried to make all of the @standards annotations consistent with this, but I'm not sure I got them perfectly right. - The genpass.c example has been improved to use getentropy instead of the current time to generate the salt, and to use a SHA-256 hash instead of MD5. It uses more random bytes than is strictly necessary because I didn't want to complicate the code with proper base64 encoding. - The testpass.c example has three hardwired hashes now, to demonstrate that different one-way functions produce different hashes for the same input. It also demonstrates how DES hashing only pays attention to the first eight characters of the input. - There is new text explaining in more detail how a CSPRNG differs from a regular random number generator, and how getentropy/getrandom are not exactly a CSPRNG. I tried not to make specific falsifiable claims here. I also tried to make the blocking/cancellation/error behavior of both getentropy and getrandom clearer.
342 lines
14 KiB
Plaintext
342 lines
14 KiB
Plaintext
@node Cryptographic Functions, Debugging Support, System Configuration, Top
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@chapter Cryptographic Functions
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@c %MENU% Passphrase storage and strongly unpredictable bytes.
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@Theglibc{} includes only a few special-purpose cryptographic
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functions: one-way hash functions for passphrase storage, and access
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to a cryptographic randomness source, if one is provided by the
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operating system. Programs that need general-purpose cryptography
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should use a dedicated cryptography library, such as
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@uref{https://www.gnu.org/software/libgcrypt/,,libgcrypt}.
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Many countries place legal restrictions on the import, export,
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possession, or use of cryptographic software. We deplore these
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restrictions, but we must still warn you that @theglibc{} may be
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subject to them, even if you do not use the functions in this chapter
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yourself. The restrictions vary from place to place and are changed
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often, so we cannot give any more specific advice than this warning.
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@menu
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* Passphrase Storage:: One-way hashing for passphrases.
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* Unpredictable Bytes:: Randomness for cryptographic purposes.
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@end menu
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@node Passphrase Storage
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@section Passphrase Storage
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@cindex passphrase hashing
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@cindex one-way hashing
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@cindex hashing, passphrase
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Sometimes 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{passphrase}; then, the
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system can ask someone claiming to be a user what the user's passphrase
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is, and if the person gives the correct passphrase then the system can
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grant the appropriate privileges. (Traditionally, these were called
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``passwords,'' but nowadays a single word is too easy to guess.)
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Programs that handle passphrases must take special care not to reveal
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them to anyone, no matter what. It is not enough to keep them in a
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file that is only accessible with special privileges. The file might
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be ``leaked'' via a bug or misconfiguration, and system administrators
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shouldn't learn everyone's passphrase even if they have to edit that
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file for some reason. To avoid this, passphrases should also be
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converted into @dfn{one-way hashes}, using a @dfn{one-way function},
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before they are stored.
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A one-way function is easy to compute, but there is no known way to
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compute its inverse. This means the system can easily check
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passphrases, by hashing them and comparing the result with the stored
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hash. But an attacker who discovers someone's passphrase hash can
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only discover the passphrase it corresponds to by guessing and
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checking. The one-way functions are designed to make this process
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impractically slow, for all but the most obvious guesses. (Do not use
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a word from the dictionary as your passphrase.)
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@Theglibc{} provides an interface to four one-way functions, based on
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the SHA-2-512, SHA-2-256, MD5, and DES cryptographic primitives. New
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passphrases should be hashed with either of the SHA-based functions.
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The others are too weak for newly set passphrases, but we continue to
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support them for verifying old passphrases. The DES-based hash is
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especially weak, because it ignores all but the first eight characters
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of its input.
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@deftypefun {char *} crypt (const char *@var{phrase}, const char *@var{salt})
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@standards{X/Open, unistd.h}
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@standards{GNU, crypt.h}
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@safety{@prelim{}@mtunsafe{@mtasurace{:crypt}}@asunsafe{@asucorrupt{} @asulock{} @ascuheap{} @ascudlopen{}}@acunsafe{@aculock{} @acsmem{}}}
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@c Besides the obvious problem of returning a pointer into static
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@c storage, the DES initializer takes an internal lock with the usual
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@c set of problems for AS- and AC-Safety.
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@c The NSS implementations may leak file descriptors if cancelled.
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@c The MD5, SHA256 and SHA512 implementations will malloc on long keys,
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@c and NSS relies on dlopening, which brings about another can of worms.
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The function @code{crypt} converts a passphrase string, @var{phrase},
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into a one-way hash suitable for storage in the user database. The
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string that it returns will consist entirely of printable ASCII
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characters. It will not contain whitespace, nor any of the characters
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@samp{:}, @samp{;}, @samp{*}, @samp{!}, or @samp{\}.
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The @var{salt} parameter controls which one-way function is used, and
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it also ensures that the output of the one-way function is different
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for every user, even if they have the same passphrase. This makes it
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harder to guess passphrases from a large user database. Without salt,
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the attacker could make a guess, run @code{crypt} on it once, and
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compare the result with all the hashes. Salt forces the attacker to
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make separate calls to @code{crypt} for each user.
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To verify a passphrase, pass the previously hashed passphrase as the
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@var{salt}. To hash a new passphrase for storage, set @var{salt} to a
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string consisting of a prefix plus a sequence of randomly chosen
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characters, according to this table:
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@multitable @columnfractions .2 .1 .3
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@headitem One-way function @tab Prefix @tab Random sequence
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@item SHA-2-512
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@tab @samp{$6$}
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@tab 16 characters
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@item SHA-2-256
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@tab @samp{$5$}
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@tab 16 characters
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@item MD5
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@tab @samp{$1$}
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@tab 8 characters
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@item DES
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@tab @samp{}
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@tab 2 characters
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@end multitable
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In all cases, the random characters should be chosen from the alphabet
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@code{./0-9A-Za-z}.
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With all of the hash functions @emph{except} DES, @var{phrase} can be
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arbitrarily long, and all eight bits of each byte are significant.
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With DES, only the first eight characters of @var{phrase} affect the
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output, and the eighth bit of each byte is also ignored.
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@code{crypt} can fail. Some implementations return @code{NULL} on
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failure, and others return an @emph{invalid} hashed passphrase, which
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will begin with a @samp{*} and will not be the same as @var{salt}. In
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either case, @code{errno} will be set to indicate the problem. Some
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of the possible error codes are:
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@table @code
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@item EINVAL
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@var{salt} is invalid; neither a previously hashed passphrase, nor a
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well-formed new salt for any of the supported hash functions.
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@item EPERM
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The system configuration forbids use of the hash function selected by
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@var{salt}.
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@item ENOMEM
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Failed to allocate internal scratch storage.
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@item ENOSYS
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@itemx EOPNOTSUPP
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Hashing passphrases is not supported at all, or the hash function
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selected by @var{salt} is not supported. @Theglibc{} does not use
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these error codes, but they may be encountered on other operating
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systems.
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@end table
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@code{crypt} uses static storage for both internal scratchwork and the
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string it returns. It is not safe to call @code{crypt} from multiple
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threads simultaneously, and the string it returns will be overwritten
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by any subsequent call to @code{crypt}.
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@code{crypt} is specified in the X/Open Portability Guide and is
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present on nearly all historical Unix systems. However, the XPG does
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not specify any one-way functions.
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@code{crypt} is declared in @file{unistd.h}. @Theglibc{} also
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declares this function in @file{crypt.h}.
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@end deftypefun
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@deftypefun {char *} crypt_r (const char *@var{phrase}, const char *@var{salt}, struct crypt_data *@var{data})
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@standards{GNU, crypt.h}
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@safety{@prelim{}@mtsafe{}@asunsafe{@asucorrupt{} @asulock{} @ascuheap{} @ascudlopen{}}@acunsafe{@aculock{} @acsmem{}}}
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@tindex struct crypt_data
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@c Compared with crypt, this function fixes the @mtasurace:crypt
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@c problem, but nothing else.
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The function @code{crypt_r} is a thread-safe version of @code{crypt}.
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Instead of static storage, it uses the memory pointed to by its
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@var{data} argument for both scratchwork and the string it returns.
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It can safely be used from multiple threads, as long as different
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@var{data} objects are used in each thread. The string it returns
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will still be overwritten by another call with the same @var{data}.
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@var{data} must point to a @code{struct crypt_data} object allocated
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by the caller. All of the fields of @code{struct crypt_data} are
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private, but before one of these objects is used for the first time,
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it must be initialized to all zeroes, using @code{memset} or similar.
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After that, it can be reused for many calls to @code{crypt_r} without
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erasing it again. @code{struct crypt_data} is very large, so it is
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best to allocate it with @code{malloc} rather than as a local
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variable. @xref{Memory Allocation}.
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@code{crypt_r} is a GNU extension. It is declared in @file{crypt.h},
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as is @code{struct crypt_data}.
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@end deftypefun
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The following program shows how to use @code{crypt} the first time a
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passphrase is entered. It uses @code{getentropy} to make the salt as
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unpredictable as possible; @pxref{Unpredictable Bytes}.
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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 demonstrates how to verify a passphrase. It checks a
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hash hardcoded into the program, because looking up real users' hashed
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passphrases may require special privileges (@pxref{User Database}).
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It also shows that different one-way functions produce different
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hashes for the same passphrase.
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@smallexample
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@include testpass.c.texi
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@end smallexample
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@node Unpredictable Bytes
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@section Generating Unpredictable Bytes
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@cindex randomness source
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@cindex random numbers, cryptographic
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@cindex pseudo-random numbers, cryptographic
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@cindex cryptographic random number generator
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@cindex deterministic random bit generator
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@cindex CRNG
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@cindex CSPRNG
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@cindex DRBG
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Cryptographic applications often need some random data that will be as
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difficult as possible for a hostile eavesdropper to guess. For
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instance, encryption keys should be chosen at random, and the ``salt''
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strings used by @code{crypt} (@pxref{Passphrase Storage}) should also
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be chosen at random.
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Some pseudo-random number generators do not provide unpredictable-enough
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output for cryptographic applications; @pxref{Pseudo-Random Numbers}.
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Such applications need to use a @dfn{cryptographic random number
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generator} (CRNG), also sometimes called a @dfn{cryptographically strong
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pseudo-random number generator} (CSPRNG) or @dfn{deterministic random
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bit generator} (DRBG).
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Currently, @theglibc{} does not provide a cryptographic random number
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generator, but it does provide functions that read random data from a
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@dfn{randomness source} supplied by the operating system. The
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randomness source is a CRNG at heart, but it also continually
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``re-seeds'' itself from physical sources of randomness, such as
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electronic noise and clock jitter. This means applications do not need
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to do anything to ensure that the random numbers it produces are
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different on each run.
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The catch, however, is that these functions will only produce
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relatively short random strings in any one call. Often this is not a
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problem, but applications that need more than a few kilobytes of
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cryptographically strong random data should call these functions once
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and use their output to seed a CRNG.
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Most applications should use @code{getentropy}. The @code{getrandom}
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function is intended for low-level applications which need additional
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control over blocking behavior.
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@deftypefun int getentropy (void *@var{buffer}, size_t @var{length})
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@standards{GNU, sys/random.h}
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@safety{@mtsafe{}@assafe{}@acsafe{}}
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This function writes exactly @var{length} bytes of random data to the
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array starting at @var{buffer}. @var{length} can be no more than 256.
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On success, it returns zero. On failure, it returns @math{-1}, and
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@code{errno} is set to indicate the problem. Some of the possible
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errors are listed below.
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@table @code
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@item ENOSYS
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The operating system does not implement a randomness source, or does
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not support this way of accessing it. (For instance, the system call
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used by this function was added to the Linux kernel in version 3.17.)
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@item EFAULT
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The combination of @var{buffer} and @var{length} arguments specifies
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an invalid memory range.
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@item EIO
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@var{length} is larger than 256, or the kernel entropy pool has
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suffered a catastrophic failure.
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@end table
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A call to @code{getentropy} can only block when the system has just
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booted and the randomness source has not yet been initialized.
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However, if it does block, it cannot be interrupted by signals or
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thread cancellation. Programs intended to run in very early stages of
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the boot process may need to use @code{getrandom} in non-blocking mode
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instead, and be prepared to cope with random data not being available
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at all.
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The @code{getentropy} function is declared in the header file
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@file{sys/random.h}. It is derived from OpenBSD.
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@end deftypefun
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@deftypefun ssize_t getrandom (void *@var{buffer}, size_t @var{length}, unsigned int @var{flags})
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@standards{GNU, sys/random.h}
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@safety{@mtsafe{}@assafe{}@acsafe{}}
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This function writes up to @var{length} bytes of random data to the
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array starting at @var{buffer}. The @var{flags} argument should be
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either zero, or the bitwise OR of some of the following flags:
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@table @code
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@item GRND_RANDOM
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Use the @file{/dev/random} (blocking) source instead of the
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@file{/dev/urandom} (non-blocking) source to obtain randomness.
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If this flag is specified, the call may block, potentially for quite
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some time, even after the randomness source has been initialized. If it
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is not specified, the call can only block when the system has just
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booted and the randomness source has not yet been initialized.
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@item GRND_NONBLOCK
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Instead of blocking, return to the caller immediately if no data is
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available.
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@end table
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Unlike @code{getentropy}, the @code{getrandom} function is a
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cancellation point, and if it blocks, it can be interrupted by
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signals.
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On success, @code{getrandom} returns the number of bytes which have
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been written to the buffer, which may be less than @var{length}. On
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error, it returns @math{-1}, and @code{errno} is set to indicate the
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problem. Some of the possible errors are:
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@table @code
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@item ENOSYS
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The operating system does not implement a randomness source, or does
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not support this way of accessing it. (For instance, the system call
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used by this function was added to the Linux kernel in version 3.17.)
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@item EAGAIN
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No random data was available and @code{GRND_NONBLOCK} was specified in
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@var{flags}.
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@item EFAULT
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The combination of @var{buffer} and @var{length} arguments specifies
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an invalid memory range.
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@item EINTR
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The system call was interrupted. During the system boot process, before
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the kernel randomness pool is initialized, this can happen even if
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@var{flags} is zero.
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@item EINVAL
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The @var{flags} argument contains an invalid combination of flags.
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@end table
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The @code{getrandom} function is declared in the header file
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@file{sys/random.h}. It is a GNU extension.
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@end deftypefun
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