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author | Zack Weinberg <zackw@panix.com> | 2018-06-29 16:53:37 +0200 |
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committer | Florian Weimer <fweimer@redhat.com> | 2018-06-29 16:53:37 +0200 |
commit | 841785bad14dfad81a0af94900310141c59f26a4 (patch) | |
tree | 9fba8a7c16596dcb9652576f9322c810eb0cf682 /manual | |
parent | 6ab902e4decd89c1a9206497d14ddba7680bfc37 (diff) | |
download | glibc-841785bad14dfad81a0af94900310141c59f26a4.tar.gz glibc-841785bad14dfad81a0af94900310141c59f26a4.tar.xz glibc-841785bad14dfad81a0af94900310141c59f26a4.zip |
manual: Revise crypt.texi.
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.
Diffstat (limited to 'manual')
-rw-r--r-- | manual/contrib.texi | 2 | ||||
-rw-r--r-- | manual/crypt.texi | 392 | ||||
-rw-r--r-- | manual/examples/genpass.c | 44 | ||||
-rw-r--r-- | manual/examples/mygetpass.c | 4 | ||||
-rw-r--r-- | manual/examples/testpass.c | 52 | ||||
-rw-r--r-- | manual/intro.texi | 1 | ||||
-rw-r--r-- | manual/memory.texi | 2 | ||||
-rw-r--r-- | manual/nss.texi | 12 | ||||
-rw-r--r-- | manual/socket.texi | 4 | ||||
-rw-r--r-- | manual/terminal.texi | 14 | ||||
-rw-r--r-- | manual/users.texi | 21 |
11 files changed, 351 insertions, 197 deletions
diff --git a/manual/contrib.texi b/manual/contrib.texi index dd28e9293b..6191f46f31 100644 --- a/manual/contrib.texi +++ b/manual/contrib.texi @@ -129,7 +129,7 @@ Martin Galvan for contributing gdb pretty printer support to glibc and adding an initial set of pretty printers for structures in the POSIX Threads library. @item -Michael Glad for the DES encryption function @code{crypt} and related +Michael Glad for the passphrase-hashing function @code{crypt} and related functions. @item diff --git a/manual/crypt.texi b/manual/crypt.texi index 0f04ee9899..c41b911c8f 100644 --- a/manual/crypt.texi +++ b/manual/crypt.texi @@ -1,121 +1,200 @@ @node Cryptographic Functions, Debugging Support, System Configuration, Top @chapter Cryptographic Functions -@c %MENU% Password storage and strongly unpredictable bytes +@c %MENU% Passphrase storage and strongly unpredictable bytes. + +@Theglibc{} includes only a few special-purpose cryptographic +functions: one-way hash functions for passphrase storage, and access +to a cryptographic randomness source, if one is provided by the +operating system. Programs that need general-purpose cryptography +should use a dedicated cryptography library, such as +@uref{https://www.gnu.org/software/libgcrypt/,,libgcrypt}. + +Many countries place legal restrictions on the import, export, +possession, or use of cryptographic software. We deplore these +restrictions, but we must still warn you that @theglibc{} may be +subject to them, even if you do not use the functions in this chapter +yourself. The restrictions vary from place to place and are changed +often, so we cannot give any more specific advice than this warning. @menu -* crypt:: A one-way function for passwords. -* Unpredictable Bytes:: Randomness for cryptography purposes. +* Passphrase Storage:: One-way hashing for passphrases. +* Unpredictable Bytes:: Randomness for cryptographic purposes. @end menu -@node crypt -@section Encrypting Passwords +@node Passphrase Storage +@section Passphrase Storage +@cindex passphrase hashing +@cindex one-way hashing +@cindex hashing, passphrase -On many systems, it is unnecessary to have any kind of user -authentication; for instance, a workstation which is not connected to a -network probably does not need any user authentication, because to use -the machine an intruder must have physical access. - -Sometimes, however, it is necessary to be sure that a user is authorized +Sometimes it is necessary to be sure that a user is authorized to use some service a machine provides---for instance, to log in as a particular user id (@pxref{Users and Groups}). One traditional way of -doing this is for each user to choose a secret @dfn{password}; then, the -system can ask someone claiming to be a user what the user's password -is, and if the person gives the correct password then the system can -grant the appropriate privileges. - -If all the passwords are just stored in a file somewhere, then this file -has to be very carefully protected. To avoid this, passwords are run -through a @dfn{one-way function}, a function which makes it difficult to -work out what its input was by looking at its output, before storing in -the file. - -@Theglibc{} provides a one-way function that is compatible with -the behavior of the @code{crypt} function introduced in FreeBSD 2.0. -It supports two one-way algorithms: one based on the MD5 -message-digest algorithm that is compatible with modern BSD systems, -and the other based on the Data Encryption Standard (DES) that is -compatible with Unix systems. - -@deftypefun {char *} crypt (const char *@var{key}, const char *@var{salt}) -@standards{BSD, crypt.h} -@standards{SVID, crypt.h} +doing this is for each user to choose a secret @dfn{passphrase}; then, the +system can ask someone claiming to be a user what the user's passphrase +is, and if the person gives the correct passphrase then the system can +grant the appropriate privileges. (Traditionally, these were called +``passwords,'' but nowadays a single word is too easy to guess.) + +Programs that handle passphrases must take special care not to reveal +them to anyone, no matter what. It is not enough to keep them in a +file that is only accessible with special privileges. The file might +be ``leaked'' via a bug or misconfiguration, and system administrators +shouldn't learn everyone's passphrase even if they have to edit that +file for some reason. To avoid this, passphrases should also be +converted into @dfn{one-way hashes}, using a @dfn{one-way function}, +before they are stored. + +A one-way function is easy to compute, but there is no known way to +compute its inverse. This means the system can easily check +passphrases, by hashing them and comparing the result with the stored +hash. But an attacker who discovers someone's passphrase hash can +only discover the passphrase it corresponds to by guessing and +checking. The one-way functions are designed to make this process +impractically slow, for all but the most obvious guesses. (Do not use +a word from the dictionary as your passphrase.) + +@Theglibc{} provides an interface to four one-way functions, based on +the SHA-2-512, SHA-2-256, MD5, and DES cryptographic primitives. New +passphrases should be hashed with either of the SHA-based functions. +The others are too weak for newly set passphrases, but we continue to +support them for verifying old passphrases. The DES-based hash is +especially weak, because it ignores all but the first eight characters +of its input. + +@deftypefun {char *} crypt (const char *@var{phrase}, const char *@var{salt}) +@standards{X/Open, unistd.h} +@standards{GNU, crypt.h} @safety{@prelim{}@mtunsafe{@mtasurace{:crypt}}@asunsafe{@asucorrupt{} @asulock{} @ascuheap{} @ascudlopen{}}@acunsafe{@aculock{} @acsmem{}}} @c Besides the obvious problem of returning a pointer into static @c storage, the DES initializer takes an internal lock with the usual -@c set of problems for AS- and AC-Safety. The FIPS mode checker and the -@c NSS implementations of may leak file descriptors if canceled. The +@c set of problems for AS- and AC-Safety. +@c The NSS implementations may leak file descriptors if cancelled. @c The MD5, SHA256 and SHA512 implementations will malloc on long keys, @c and NSS relies on dlopening, which brings about another can of worms. -The @code{crypt} function takes a password, @var{key}, as a string, and -a @var{salt} character array which is described below, and returns a -printable ASCII string which starts with another salt. It is believed -that, given the output of the function, the best way to find a @var{key} -that will produce that output is to guess values of @var{key} until the -original value of @var{key} is found. - -The @var{salt} parameter does two things. Firstly, it selects which -algorithm is used, the MD5-based one or the DES-based one. Secondly, it -makes life harder for someone trying to guess passwords against a file -containing many passwords; without a @var{salt}, an intruder can make a -guess, run @code{crypt} on it once, and compare the result with all the -passwords. With a @var{salt}, the intruder must run @code{crypt} once -for each different salt. - -For the MD5-based algorithm, the @var{salt} should consist of the string -@code{$1$}, followed by up to 8 characters, terminated by either -another @code{$} or the end of the string. The result of @code{crypt} -will be the @var{salt}, followed by a @code{$} if the salt didn't end -with one, followed by 22 characters from the alphabet -@code{./0-9A-Za-z}, up to 34 characters total. Every character in the -@var{key} is significant. - -For the DES-based algorithm, the @var{salt} should consist of two -characters from the alphabet @code{./0-9A-Za-z}, and the result of -@code{crypt} will be those two characters followed by 11 more from the -same alphabet, 13 in total. Only the first 8 characters in the -@var{key} are significant. - -The MD5-based algorithm has no limit on the useful length of the -password used, and is slightly more secure. It is therefore preferred -over the DES-based algorithm. - -When the user enters their password for the first time, the @var{salt} -should be set to a new string which is reasonably random. To verify a -password against the result of a previous call to @code{crypt}, pass -the result of the previous call as the @var{salt}. +The function @code{crypt} converts a passphrase string, @var{phrase}, +into a one-way hash suitable for storage in the user database. The +string that it returns will consist entirely of printable ASCII +characters. It will not contain whitespace, nor any of the characters +@samp{:}, @samp{;}, @samp{*}, @samp{!}, or @samp{\}. + +The @var{salt} parameter controls which one-way function is used, and +it also ensures that the output of the one-way function is different +for every user, even if they have the same passphrase. This makes it +harder to guess passphrases from a large user database. Without salt, +the attacker could make a guess, run @code{crypt} on it once, and +compare the result with all the hashes. Salt forces the attacker to +make separate calls to @code{crypt} for each user. + +To verify a passphrase, pass the previously hashed passphrase as the +@var{salt}. To hash a new passphrase for storage, set @var{salt} to a +string consisting of a prefix plus a sequence of randomly chosen +characters, according to this table: + +@multitable @columnfractions .2 .1 .3 +@headitem One-way function @tab Prefix @tab Random sequence +@item SHA-2-512 +@tab @samp{$6$} +@tab 16 characters +@item SHA-2-256 +@tab @samp{$5$} +@tab 16 characters +@item MD5 +@tab @samp{$1$} +@tab 8 characters +@item DES +@tab @samp{} +@tab 2 characters +@end multitable + +In all cases, the random characters should be chosen from the alphabet +@code{./0-9A-Za-z}. + +With all of the hash functions @emph{except} DES, @var{phrase} can be +arbitrarily long, and all eight bits of each byte are significant. +With DES, only the first eight characters of @var{phrase} affect the +output, and the eighth bit of each byte is also ignored. + +@code{crypt} can fail. Some implementations return @code{NULL} on +failure, and others return an @emph{invalid} hashed passphrase, which +will begin with a @samp{*} and will not be the same as @var{salt}. In +either case, @code{errno} will be set to indicate the problem. Some +of the possible error codes are: + +@table @code +@item EINVAL +@var{salt} is invalid; neither a previously hashed passphrase, nor a +well-formed new salt for any of the supported hash functions. + +@item EPERM +The system configuration forbids use of the hash function selected by +@var{salt}. + +@item ENOMEM +Failed to allocate internal scratch storage. + +@item ENOSYS +@itemx EOPNOTSUPP +Hashing passphrases is not supported at all, or the hash function +selected by @var{salt} is not supported. @Theglibc{} does not use +these error codes, but they may be encountered on other operating +systems. +@end table + +@code{crypt} uses static storage for both internal scratchwork and the +string it returns. It is not safe to call @code{crypt} from multiple +threads simultaneously, and the string it returns will be overwritten +by any subsequent call to @code{crypt}. + +@code{crypt} is specified in the X/Open Portability Guide and is +present on nearly all historical Unix systems. However, the XPG does +not specify any one-way functions. + +@code{crypt} is declared in @file{unistd.h}. @Theglibc{} also +declares this function in @file{crypt.h}. @end deftypefun -@deftypefun {char *} crypt_r (const char *@var{key}, const char *@var{salt}, {struct crypt_data *} @var{data}) +@deftypefun {char *} crypt_r (const char *@var{phrase}, const char *@var{salt}, struct crypt_data *@var{data}) @standards{GNU, crypt.h} @safety{@prelim{}@mtsafe{}@asunsafe{@asucorrupt{} @asulock{} @ascuheap{} @ascudlopen{}}@acunsafe{@aculock{} @acsmem{}}} +@tindex struct crypt_data @c Compared with crypt, this function fixes the @mtasurace:crypt @c problem, but nothing else. -The @code{crypt_r} function does the same thing as @code{crypt}, but -takes an extra parameter which includes space for its result (among -other things), so it can be reentrant. @code{data@w{->}initialized} must be -cleared to zero before the first time @code{crypt_r} is called. - -The @code{crypt_r} function is a GNU extension. +The function @code{crypt_r} is a thread-safe version of @code{crypt}. +Instead of static storage, it uses the memory pointed to by its +@var{data} argument for both scratchwork and the string it returns. +It can safely be used from multiple threads, as long as different +@var{data} objects are used in each thread. The string it returns +will still be overwritten by another call with the same @var{data}. + +@var{data} must point to a @code{struct crypt_data} object allocated +by the caller. All of the fields of @code{struct crypt_data} are +private, but before one of these objects is used for the first time, +it must be initialized to all zeroes, using @code{memset} or similar. +After that, it can be reused for many calls to @code{crypt_r} without +erasing it again. @code{struct crypt_data} is very large, so it is +best to allocate it with @code{malloc} rather than as a local +variable. @xref{Memory Allocation}. + +@code{crypt_r} is a GNU extension. It is declared in @file{crypt.h}, +as is @code{struct crypt_data}. @end deftypefun -The @code{crypt} and @code{crypt_r} functions are prototyped in the -header @file{crypt.h}. - -The following short program is an example of how to use @code{crypt} the -first time a password is entered. Note that the @var{salt} generation -is just barely acceptable; in particular, it is not unique between -machines, and in many applications it would not be acceptable to let an -attacker know what time the user's password was last set. +The following program shows how to use @code{crypt} the first time a +passphrase is entered. It uses @code{getentropy} to make the salt as +unpredictable as possible; @pxref{Unpredictable Bytes}. @smallexample @include genpass.c.texi @end smallexample -The next program shows how to verify a password. It prompts the user -for a password and prints ``Access granted.'' if the user types -@code{GNU libc manual}. +The next program demonstrates how to verify a passphrase. It checks a +hash hardcoded into the program, because looking up real users' hashed +passphrases may require special privileges (@pxref{User Database}). +It also shows that different one-way functions produce different +hashes for the same passphrase. @smallexample @include testpass.c.texi @@ -123,93 +202,121 @@ for a password and prints ``Access granted.'' if the user types @node Unpredictable Bytes @section Generating Unpredictable Bytes - -Some cryptographic applications (such as session key generation) need -unpredictable bytes. - -In general, application code should use a deterministic random bit -generator, which could call the @code{getentropy} function described -below internally to obtain randomness to seed the generator. The -@code{getrandom} function is intended for low-level applications which -need additional control over the blocking behavior. +@cindex randomness source +@cindex random numbers, cryptographic +@cindex pseudo-random numbers, cryptographic +@cindex cryptographic random number generator +@cindex deterministic random bit generator +@cindex CRNG +@cindex CSPRNG +@cindex DRBG + +Cryptographic applications often need some random data that will be as +difficult as possible for a hostile eavesdropper to guess. For +instance, encryption keys should be chosen at random, and the ``salt'' +strings used by @code{crypt} (@pxref{Passphrase Storage}) should also +be chosen at random. + +Some pseudo-random number generators do not provide unpredictable-enough +output for cryptographic applications; @pxref{Pseudo-Random Numbers}. +Such applications need to use a @dfn{cryptographic random number +generator} (CRNG), also sometimes called a @dfn{cryptographically strong +pseudo-random number generator} (CSPRNG) or @dfn{deterministic random +bit generator} (DRBG). + +Currently, @theglibc{} does not provide a cryptographic random number +generator, but it does provide functions that read random data from a +@dfn{randomness source} supplied by the operating system. The +randomness source is a CRNG at heart, but it also continually +``re-seeds'' itself from physical sources of randomness, such as +electronic noise and clock jitter. This means applications do not need +to do anything to ensure that the random numbers it produces are +different on each run. + +The catch, however, is that these functions will only produce +relatively short random strings in any one call. Often this is not a +problem, but applications that need more than a few kilobytes of +cryptographically strong random data should call these functions once +and use their output to seed a CRNG. + +Most applications should use @code{getentropy}. The @code{getrandom} +function is intended for low-level applications which need additional +control over blocking behavior. @deftypefun int getentropy (void *@var{buffer}, size_t @var{length}) @standards{GNU, sys/random.h} @safety{@mtsafe{}@assafe{}@acsafe{}} -This function writes @var{length} bytes of random data to the array -starting at @var{buffer}, which must be at most 256 bytes long. The -function returns zero on success. On failure, it returns @code{-1} and -@code{errno} is updated accordingly. - -The @code{getentropy} function is declared in the header file -@file{sys/random.h}. It is derived from OpenBSD. - -The @code{getentropy} function is not a cancellation point. A call to -@code{getentropy} can block if the system has just booted and the kernel -entropy pool has not yet been initialized. In this case, the function -will keep blocking even if a signal arrives, and return only after the -entropy pool has been initialized. - -The @code{getentropy} function can fail with several errors, some of -which are listed below. +This function writes exactly @var{length} bytes of random data to the +array starting at @var{buffer}. @var{length} can be no more than 256. +On success, it returns zero. On failure, it returns @math{-1}, and +@code{errno} is set to indicate the problem. Some of the possible +errors are listed below. @table @code @item ENOSYS -The kernel does not implement the required system call. +The operating system does not implement a randomness source, or does +not support this way of accessing it. (For instance, the system call +used by this function was added to the Linux kernel in version 3.17.) @item EFAULT The combination of @var{buffer} and @var{length} arguments specifies an invalid memory range. @item EIO -More than 256 bytes of randomness have been requested, or the buffer -could not be overwritten with random data for an unspecified reason. - +@var{length} is larger than 256, or the kernel entropy pool has +suffered a catastrophic failure. @end table +A call to @code{getentropy} can only block when the system has just +booted and the randomness source has not yet been initialized. +However, if it does block, it cannot be interrupted by signals or +thread cancellation. Programs intended to run in very early stages of +the boot process may need to use @code{getrandom} in non-blocking mode +instead, and be prepared to cope with random data not being available +at all. + +The @code{getentropy} function is declared in the header file +@file{sys/random.h}. It is derived from OpenBSD. @end deftypefun @deftypefun ssize_t getrandom (void *@var{buffer}, size_t @var{length}, unsigned int @var{flags}) @standards{GNU, sys/random.h} @safety{@mtsafe{}@assafe{}@acsafe{}} -This function writes @var{length} bytes of random data to the array -starting at @var{buffer}. On success, this function returns the number -of bytes which have been written to the buffer (which can be less than -@var{length}). On error, @code{-1} is returned, and @code{errno} is -updated accordingly. - -The @code{getrandom} function is declared in the header file -@file{sys/random.h}. It is a GNU extension. - -The following flags are defined for the @var{flags} argument: +This function writes up to @var{length} bytes of random data to the +array starting at @var{buffer}. The @var{flags} argument should be +either zero, or the bitwise OR of some of the following flags: @table @code @item GRND_RANDOM -Use the @file{/dev/random} (blocking) pool instead of the -@file{/dev/urandom} (non-blocking) pool to obtain randomness. If the -@code{GRND_RANDOM} flag is specified, the @code{getrandom} function can -block even after the randomness source has been initialized. +Use the @file{/dev/random} (blocking) source instead of the +@file{/dev/urandom} (non-blocking) source to obtain randomness. + +If this flag is specified, the call may block, potentially for quite +some time, even after the randomness source has been initialized. If it +is not specified, the call can only block when the system has just +booted and the randomness source has not yet been initialized. @item GRND_NONBLOCK Instead of blocking, return to the caller immediately if no data is available. @end table -The @code{getrandom} function is a cancellation point. +Unlike @code{getentropy}, the @code{getrandom} function is a +cancellation point, and if it blocks, it can be interrupted by +signals. -Obtaining randomness from the @file{/dev/urandom} pool (i.e., a call -without the @code{GRND_RANDOM} flag) can block if the system has just -booted and the pool has not yet been initialized. - -The @code{getrandom} function can fail with several errors, some of -which are listed below. In addition, the function may not fill the -buffer completely and return a value less than @var{length}. +On success, @code{getrandom} returns the number of bytes which have +been written to the buffer, which may be less than @var{length}. On +error, it returns @math{-1}, and @code{errno} is set to indicate the +problem. Some of the possible errors are: @table @code @item ENOSYS -The kernel does not implement the @code{getrandom} system call. +The operating system does not implement a randomness source, or does +not support this way of accessing it. (For instance, the system call +used by this function was added to the Linux kernel in version 3.17.) @item EAGAIN No random data was available and @code{GRND_NONBLOCK} was specified in @@ -228,4 +335,7 @@ the kernel randomness pool is initialized, this can happen even if The @var{flags} argument contains an invalid combination of flags. @end table +The @code{getrandom} function is declared in the header file +@file{sys/random.h}. It is a GNU extension. + @end deftypefun diff --git a/manual/examples/genpass.c b/manual/examples/genpass.c index 5edb2e9b8a..23d20789fc 100644 --- a/manual/examples/genpass.c +++ b/manual/examples/genpass.c @@ -16,34 +16,44 @@ */ #include <stdio.h> -#include <time.h> #include <unistd.h> #include <crypt.h> int main(void) { - unsigned long seed[2]; - char salt[] = "$1$........"; - const char *const seedchars = + unsigned char ubytes[16]; + char salt[20]; + const char *const saltchars = "./0123456789ABCDEFGHIJKLMNOPQRST" "UVWXYZabcdefghijklmnopqrstuvwxyz"; - char *password; + char *hash; int i; - /* Generate a (not very) random seed. - You should do it better than this... */ - seed[0] = time(NULL); - seed[1] = getpid() ^ (seed[0] >> 14 & 0x30000); - - /* Turn it into printable characters from `seedchars'. */ - for (i = 0; i < 8; i++) - salt[3+i] = seedchars[(seed[i/5] >> (i%5)*6) & 0x3f]; - - /* Read in the user's password and encrypt it. */ - password = crypt(getpass("Password:"), salt); + /* Retrieve 16 unpredictable bytes from the operating system. */ + if (getentropy (ubytes, sizeof ubytes)) + { + perror ("getentropy"); + return 1; + } + + /* Use them to fill in the salt string. */ + salt[0] = '$'; + salt[1] = '5'; /* SHA-256 */ + salt[2] = '$'; + for (i = 0; i < 16; i++) + salt[3+i] = saltchars[ubytes[i] & 0x3f]; + salt[3+i] = '\0'; + + /* Read in the user's passphrase and hash it. */ + hash = crypt (getpass ("Enter new passphrase: "), salt); + if (!hash || hash[0] == '*') + { + perror ("crypt"); + return 1; + } /* Print the results. */ - puts(password); + puts (hash); return 0; } diff --git a/manual/examples/mygetpass.c b/manual/examples/mygetpass.c index dfc0c59a7f..3f465ac8ea 100644 --- a/manual/examples/mygetpass.c +++ b/manual/examples/mygetpass.c @@ -1,4 +1,4 @@ -/* Reading Passwords +/* Reading passphrases manually. Copyright (C) 1991-2018 Free Software Foundation, Inc. This program is free software; you can redistribute it and/or @@ -32,7 +32,7 @@ my_getpass (char **lineptr, size_t *n, FILE *stream) if (tcsetattr (fileno (stream), TCSAFLUSH, &new) != 0) return -1; - /* Read the password. */ + /* Read the passphrase */ nread = getline (lineptr, n, stream); /* Restore terminal. */ diff --git a/manual/examples/testpass.c b/manual/examples/testpass.c index 19f1ae7de0..f8883fea17 100644 --- a/manual/examples/testpass.c +++ b/manual/examples/testpass.c @@ -1,4 +1,4 @@ -/* Verify a password. +/* Verify a passphrase. Copyright (C) 1991-2018 Free Software Foundation, Inc. This program is free software; you can redistribute it and/or @@ -20,24 +20,48 @@ #include <unistd.h> #include <crypt.h> +/* @samp{GNU's Not Unix} hashed using SHA-256, MD5, and DES. */ +static const char hash_sha[] = + "$5$DQ2z5NHf1jNJnChB$kV3ZTR0aUaosujPhLzR84Llo3BsspNSe4/tsp7VoEn6"; +static const char hash_md5[] = "$1$A3TxDv41$rtXVTUXl2LkeSV0UU5xxs1"; +static const char hash_des[] = "FgkTuF98w5DaI"; + int main(void) { - /* Hashed form of "GNU libc manual". */ - const char *const pass = "$1$/iSaq7rB$EoUw5jJPPvAPECNaaWzMK/"; + char *phrase; + int status = 0; + + /* Prompt for a passphrase. */ + phrase = getpass ("Enter passphrase: "); + + /* Compare against the stored hashes. Any input that begins with + @samp{GNU's No} will match the DES hash, but the other two will + only match @samp{GNU's Not Unix}. */ - char *result; - int ok; + if (strcmp (crypt (phrase, hash_sha), hash_sha)) + { + puts ("SHA: not ok"); + status = 1; + } + else + puts ("SHA: ok"); -/*@group*/ - /* Read in the user's password and encrypt it, - passing the expected password in as the salt. */ - result = crypt(getpass("Password:"), pass); -/*@end group*/ + if (strcmp (crypt (phrase, hash_md5), hash_md5)) + { + puts ("MD5: not ok"); + status = 1; + } + else + puts ("MD5: ok"); - /* Test the result. */ - ok = strcmp (result, pass) == 0; + if (strcmp (crypt (phrase, hash_des), hash_des)) + { + puts ("DES: not ok"); + status = 1; + } + else + puts ("DES: ok"); - puts(ok ? "Access granted." : "Access denied."); - return ok ? 0 : 1; + return status; } diff --git a/manual/intro.texi b/manual/intro.texi index cc9c99f543..779fec8f3d 100644 --- a/manual/intro.texi +++ b/manual/intro.texi @@ -1321,7 +1321,6 @@ this manual. @c Message Translation (8) @c Resource Usage And Limitations (22) @c Inter-Process Communication (27) -@c DES Encryption and Password Handling (33) @c Debugging support (34) @c POSIX Threads (35) @c Internal Probes (36) diff --git a/manual/memory.texi b/manual/memory.texi index 2fac64939f..a1435aad1a 100644 --- a/manual/memory.texi +++ b/manual/memory.texi @@ -3452,7 +3452,7 @@ system performance. In this case, locking pages can help. @item Privacy. If you keep secrets in virtual memory and that virtual memory gets paged out, that increases the chance that the secrets will get out. -If a password gets written out to disk swap space, for example, it might +If a passphrase gets written out to disk swap space, for example, it might still be there long after virtual and real memory have been wiped clean. @end itemize diff --git a/manual/nss.texi b/manual/nss.texi index d534c260d3..18361b6f42 100644 --- a/manual/nss.texi +++ b/manual/nss.texi @@ -84,15 +84,15 @@ Network names and numbers, @pxref{Networks Database}. @item protocols Network protocols, @pxref{Protocols Database}. @item passwd -User passwords, @pxref{User Database}. +User identities, @pxref{User Database}. @item rpc -Remote procedure call names and numbers, +Remote procedure call names and numbers. @comment @pxref{RPC Database}. @item services Network services, @pxref{Services Database}. @item shadow -Shadow user passwords, -@comment @pxref{Shadow Password Database}. +User passphrase hashes and related information. +@comment @pxref{Shadow Passphrase Database}. @end table @noindent @@ -526,7 +526,7 @@ with the main application.) The @code{get@var{XXX}by@var{YYY}} functions are the most important functions in the NSS modules. But there are others which implement the other ways to access system databases (say for the -password database, there are @code{setpwent}, @code{getpwent}, and +user database, there are @code{setpwent}, @code{getpwent}, and @code{endpwent}). These will be described in more detail later. Here we give a general way to determine the signature of the module function: @@ -650,7 +650,7 @@ general rules must be followed by all functions. In fact there are four kinds of different functions which may appear in the interface. All derive from the traditional ones for system databases. @var{db} in the following table is normally an abbreviation for the -database (e.g., it is @code{pw} for the password database). +database (e.g., it is @code{pw} for the user database). @table @code @item enum nss_status _nss_@var{database}_set@var{db}ent (void) diff --git a/manual/socket.texi b/manual/socket.texi index 79eb4208be..a6c44b77c3 100644 --- a/manual/socket.texi +++ b/manual/socket.texi @@ -257,7 +257,7 @@ system assigns an address automatically if you have not specified one. Occasionally a client needs to specify an address because the server discriminates based on address; for example, the rsh and rlogin -protocols look at the client's socket address and only bypass password +protocols look at the client's socket address and only bypass passphrase checking if it is less than @code{IPPORT_RESERVED} (@pxref{Ports}). The details of socket addresses vary depending on what namespace you are @@ -3277,7 +3277,7 @@ or request that comes in. If @var{style} uses connections, then @var{user} is the user name that the server should run as. @code{inetd} runs as root, so it can set the user ID of its children arbitrarily. It's best to avoid using @samp{root} for @var{user} if you can; but some -servers, such as Telnet and FTP, read a username and password +servers, such as Telnet and FTP, read a username and passphrase themselves. These servers need to be root initially so they can log in as commanded by the data coming over the network. diff --git a/manual/terminal.texi b/manual/terminal.texi index 0b275fc002..d830baacd7 100644 --- a/manual/terminal.texi +++ b/manual/terminal.texi @@ -24,7 +24,7 @@ descriptor is and how to open a file descriptor for a terminal device. * Line Control:: Sending break sequences, clearing terminal buffers @dots{} * Noncanon Example:: How to read single characters without echo. -* getpass:: Prompting the user for a password. +* getpass:: Prompting the user for a passphrase. * Pseudo-Terminals:: How to open a pseudo-terminal. @end menu @@ -1873,9 +1873,9 @@ handlers for job control signals that reset terminal modes. The above example does so. @node getpass -@section Reading Passwords +@section Reading Passphrases -When reading in a password, it is desirable to avoid displaying it on +When reading in a passphrase, it is desirable to avoid displaying it on the screen, to help keep it secret. The following function handles this in a convenient way. @@ -1884,7 +1884,7 @@ in a convenient way. @safety{@prelim{}@mtunsafe{@mtasuterm{}}@asunsafe{@ascuheap{} @asulock{} @asucorrupt{}}@acunsafe{@acuterm{} @aculock{} @acucorrupt{}}} @c This function will attempt to create a stream for terminal I/O, but @c will fallback to stdio/stderr. It attempts to change the terminal -@c mode in a thread-unsafe way, write out the prompt, read the password, +@c mode in a thread-unsafe way, write out the prompt, read the passphrase, @c then restore the terminal mode. It has a cleanup to close the stream @c in case of (synchronous) cancellation, but not to restore the @c terminal mode. @@ -1892,14 +1892,14 @@ in a convenient way. @code{getpass} outputs @var{prompt}, then reads a string in from the terminal without echoing it. It tries to connect to the real terminal, @file{/dev/tty}, if possible, to encourage users not to put plaintext -passwords in files; otherwise, it uses @code{stdin} and @code{stderr}. +passphrases in files; otherwise, it uses @code{stdin} and @code{stderr}. @code{getpass} also disables the INTR, QUIT, and SUSP characters on the terminal using the @code{ISIG} terminal attribute (@pxref{Local Modes}). The terminal is flushed before and after @code{getpass}, so that -characters of a mistyped password are not accidentally visible. +characters of a mistyped passphrase are not accidentally visible. In other C libraries, @code{getpass} may only return the first -@code{PASS_MAX} bytes of a password. @Theglibc{} has no limit, so +@code{PASS_MAX} bytes of a passphrase. @Theglibc{} has no limit, so @code{PASS_MAX} is undefined. The prototype for this function is in @file{unistd.h}. @code{PASS_MAX} diff --git a/manual/users.texi b/manual/users.texi index 8690b65633..4ed79ba26f 100644 --- a/manual/users.texi +++ b/manual/users.texi @@ -1730,6 +1730,16 @@ users. The database itself is kept in the file @file{/etc/passwd} on most systems, but on some systems a special network server gives access to it. +Historically, this database included one-way hashes of user +passphrases (@pxref{Passphrase Storage}) as well as public information +about each user (such as their user ID and full name). Many of the +functions and data structures associated with this database, and the +filename @file{/etc/passwd} itself, reflect this history. However, +the information in this database is available to all users, and it is +no longer considered safe to make passphrase hashes available to all +users, so they have been moved to a ``shadow'' database that can only +be accessed with special privileges. + @menu * User Data Structure:: What each user record contains. * Lookup User:: How to look for a particular user. @@ -1753,8 +1763,10 @@ entries in the system user data base. It has at least the following members: @item char *pw_name The user's login name. -@item char *pw_passwd. -The encrypted password string. +@item char *pw_passwd +Historically, this field would hold the one-way hash of the user's +passphrase. Nowadays, it will almost always be the single character +@samp{x}, indicating that the hash is in the shadow database. @item uid_t pw_uid The user ID number. @@ -2105,7 +2117,7 @@ rewritten on subsequent calls to @code{fgetpwent}. You must copy the contents of the structure if you wish to save the information. The stream must correspond to a file in the same format as the standard -password database file. +user database file. @end deftypefun @deftypefun int fgetpwent_r (FILE *@var{stream}, struct passwd *@var{result_buf}, char *@var{buffer}, size_t @var{buflen}, struct passwd **@var{result}) @@ -2126,7 +2138,7 @@ first @var{buflen} bytes of the additional buffer pointed to by strings which are pointed to by the elements of the result structure. The stream must correspond to a file in the same format as the standard -password database file. +user database file. If the function returns zero @var{result} points to the structure with the wanted data (normally this is in @var{result_buf}). If errors @@ -2234,7 +2246,6 @@ avoid using it, because it makes sense only on the assumption that the on a system which merges the traditional Unix data base with other extended information about users, adding an entry using this function would inevitably leave out much of the important information. -@c Then how are programmers to modify the password file? -zw The group and user ID fields are left empty if the group or user name starts with a - or +. |