Xref: ivgate comp.org.eff.talk:12829 sci.crypt:993 Newsgroups: comp.org.eff.talk,sci.crypt,alt.security.pgp Path: ivgate!uunet!spool.mu.edu!bloom-beacon.mit.edu!world!decwrl!csus.edu!netcom.com!grady From: grady@netcom.com (Grady Ward) Subject: PASSPHRASE FAQ Message-ID: Followup-To: sci.crypt,alt.security.pgp Organization: Moby lexicons X-Newsreader: TIN [version 1.1 PL8] References: <13598.2CAB3707@puddle.fidonet.org> Date: Sun, 3 Oct 1993 04:16:32 GMT Lines: 991 PASSPHRASE FAQ V. 1.0 2 October 1993 '"PGP," warns Dorothy Denning, a Georgetown University professor who has worked closely with the National Security Agency, "could potentially become a widespread problem.' -- (E. Dexheimer) Comments to: Grady Ward, grady@netcom.com Contributors: John Kelsey, c445585@mizzou1.missouri.edu (Appendix A.) RSA Data Security (Appendix C. The MD5 Algorithm) Jim Gillogly (Appendix D. The Secure Hash Algorithm) FAQ: How do I choose a good password or phrase? ANS: Shocking nonsense makes the most sense With the intrinsic strength of some of the modern encryption, authentication, and message digest algorithms such as RSA, MD5, SHS and IDEA the user password or phrase is becoming more and more the focus of vulnerability. For example, Deputy Ponder with the Los Angeles County Sheriff's Department admitted in early 1993 that both they and the FBI despaired of breaking the PGP 1.0 system except through a successful dictionary attack (trying many possible passwords or phrases from lists of probable choices and their variations) rather than "breaking" the underlying cryptographic algorithm mathematically. The fundamental reason why attacking or trying to guess the user's password or phrase will increasingly be the focus of cryptanalysis is that the user's choice of password may represent a much simpler cryptographic key than optimal for the encryption algorithm being used. This weakness of the user's password choice provides the potential cryptanalytic wedge. For example, suppose a user chooses the password 'david.' On the surface the entropy of this key (or the number of different equiprobable key states) appears to be five characters chosen from a set of twenty-six with replacements: 26^5 or 1.188 x 10^7. But since the user is apparently biased toward common given names, which a majority appear in lists numbering only 6,000-7,000 entries, the true entropy is undoubtedly much closer to 6.5 x 10^3, or about four orders of magnitude smaller than the raw length might suggest. (In fact this password probably possesses a much smaller entropy than even this for the very common name "david" would be one of the first names to be checked by an optimized dictionary attack program.) In other words the "entropy" of a keyspace is not a fixed physical quantity: the cryptanalyst can exploit whole cultural biases and contexts, not just byte frequencies, digraphs, or even whole-word correlations to reduce the key space he or she is trying to explore. To thwart this avenue of attack we would like to discover a method of selecting passwords or phrases that have at least as many bits of entropy (or "hard-to-guessness") as the entropy of the cryptographic key of the underlying algorithm being used. To compare, DES (Data Encryption Standard) is believed to have about 54-55 bits (~4 x 10 ^16) of entropy while the IDEA algorithm is believed to have about 128 bits (~3.5 x 10^38) of entropy. The closer the entropy of the user's password or phrase is to the intrinsic entropy of the cryptographic key of the underlying algorithm being used, the more likely an attacker would need to search a substantially larger portion of the algorithm's key space in order to rediscover the key. Unfortunately many documents suggest choosing passwords or phrases that are distinctly inferior to the latest method. For example, one white paper widely archived on the internet suggests selecting an original password by constructing an acronym from a popular song lyric or from a line of script from, for example, the SF movie "Star Wars". Both of these ideas turn out to be weak because both the entire script to Stars Wars and entire sets of song lyrics to thousands of popular songs are available on-line to everyone and, in some cases, are already embedded into "crack" dictionary attack programs (See ftp.uwp.edu). However, the conflict between choosing an easy-to-remember key and choosing a key with a high level of entropy is not a hopeless task if we exploit mnemonic devices that have been used for a long time outside the field of cryptography. With the goal of making up a passphrase not included in any existing corpus yet very easy to remember, an effective technique is one known as "shocking nonsense." "Shocking nonsense" means to make up a short phrase or sentence that is both nonsensical and shocking in the culture of the user, that is, it contains grossly obscene, racist, impossible or other extreme juxtaposition of ideas. This technique is permissable because the passphrase, by its nature, is never revealed to anyone with sensibilities to be offended. Shocking nonsense is unlikely to be duplicated anywhere because it does not describe a matter-of-fact that could be accidentally rediscovered by anyone else and the emotional evocation makes it difficult for the creator to forget. A mild example of such shocking nonsense might be: "mollusks peck my galloping genitals ." The reader can undoubtedly make up many far more shocking or entertaining examples for himself or herself. Even relatively short phrases offer acceptable entropy because the far larger "alphabet" pool of word symbols that may be chosen than the 26 characters that form the Roman alphabet. Even choosing from a vocabulary of a few thousand words a five word phrase might have on the order of 58 to 60 bits of entropy -- more than what is needed for the DES algorithm, for example. When you are permitted to use passphrases of arbitrary length (in PGP for example) it is not necessary to further perturb your 'shocking nonsense' passphrase to include numbers or special symbols because the pool of word choices is already very high. Not needing those special symbols or numbers (that are not intrinsically meaningful) makes the shocking nonsense passphrase that much easier to remember. If you are forced to use, say, a Unix password utility that permits only passwords of restricted length, one good strategy is to process a your secret passphrase using MD5 or SHA, then UUENCODE the result and select your shorter key from the output. See Appendix C and D for actual MD5 and SHA source implmentations. Appendix A. For software developers For software developers designing "front-ends" or user interfaces to conventional short-password applications, very good results will come from permitting the user arbitrary length passphrases that are then "crunched" or processed using a strong digest algorithm such as the 160-bit SHS (Secure Hash Standard) or the 128-bit MD5 (Message Digest rev.5).[See following Appendices] The interface program then chooses the appropriate number of bits from the digest and supplies them to the engine enforcing a short password. This 'key crunching' technique will assure the developer that even the short password key space will have a far greater opportunity of being fully exploited by the user. John Kelsey writes: "I think it's a really good idea to use a randomly-generated salt to generate a key from a password, and that this salt should be as large as possible. Basically, this is to keep an attacker from spending lots of computer power *once* to generate a dictionary of likely keys. If users use good techniques to choose passwords, this won't matter much, but if they don't, this may save them from having their encrypted files or transmissions routinely read. The simplest scheme I can see for this is simply to prepend a 128-bit salt (generated as strongly as possible) to each encrypted file. Generate the key from the password by pre- filling a buffer with the 128-bit salt, then XORing in the keyed- in password, or by appending the key to the keyed-in password. Then, run SHA or MD5 or whatever to get the key. A secondary point: Adding a random salt ensures that people who use the same password/passphrase for lots of files/transmissions don't get the same key every time. Since most successful attacks against modern encryption schemes use *lots* of ciphertext from the same key, this might add some practical security, at relatively low cost." --John Kelsey, c445585@mizzou1.missouri.edu Appendix B. A tool to experimentally investigate entropy A practical Unix tool for investigating the entropy of typical user keys can be found in Wu and Manber's 'agrep' (approximate grep) similarity pattern matching tool available in C source from cs.arizona.edu [192.12.69.5]. This tool can determine the "edit distance," that is, the number of insertions, substitutions, or deletions that would be required of an arbitrary pattern in order for it to match any of a large corpus of words or phrases, say the usr/dict word list, or over the set of Star Trek trivia archives. The user can then adjust the pattern to give an arbitrary high threshold difference between it and common words and phrases in the corpus to make crack programs that systematically vary known strings less likely to succeed. It is often surprising to discover that a substring pattern like "hxirtes" is only of edit distance two from as many as forty separate words ranging from "bushfires" to "whitest." Certainly no password or phrase ought to be chosen as a working password or phrase that is within two or fewer edit distance from a known string or substring in any on-line collection. Appendix C. An implementation in C of the Message Digest Rev.5 Algorithm /* md5.h -- header file for implementation of MD5 RSA Data Security, Inc. MD5 Message-Digest Algorithm Created: 2/17/90 RLR Revised: 12/27/90 SRD,AJ,BSK,JT Reference C version Revised (for MD5): RLR 4/27/91 -- G modified to have y&~z instead of y&z -- FF, GG, HH modified to add in last register done -- Access pattern: round 2 works mod 5, round 3 works mod 3 -- distinct additive constant for each step -- round 4 added, working mod 7 */ /* Copyright (C) 1990, RSA Data Security, Inc. All rights reserved. License to copy and use this software is granted provided that it is identified as the "RSA Data Security, Inc. MD5 Message-Digest Algorithm" in all material mentioning or referencing this software or this function. License is also granted to make and use derivative works provided that such works are identified as "derived from the RSA Data Security, Inc. MD5 Message-Digest Algorithm" in all material mentioning or referencing the derived work. RSA Data Security, Inc. makes no representations concerning either the merchantability of this software or the suitability of this software for any particular purpose. It is provided "as is" without express or implied warranty of any kind. These notices must be retained in any copies of any part of this documentation and/or software. */ typedef unsigned int UINT4; /* Data structure for MD5 (Message-Digest) computation */ typedef struct { UINT4 i[2]; /* number of _bits_ handled mod 2^64 */ UINT4 buf[4]; /* scratch buffer */ unsigned char in[64]; /* input buffer */ unsigned char digest[16]; /* actual digest after MD5Final call */ } MD5_CTX; void MD5Init(MD5_CTX *); void MD5Update(MD5_CTX *,unsigned char *,unsigned int); void MD5Final(MD5_CTX *); void Transform(UINT4 *,UINT4 *); #include #include #include "md5.h" void findhash( FILE *fp ) { MD5_CTX ctx; char buffer[ BUFSIZ ]; size_t count; int i,j; MD5Init( &ctx ); while ( (count=fread(buffer,1,sizeof(buffer),fp)) > 0 ) MD5Update( &ctx, buffer, count ); MD5Final( &ctx ); j = 0; for ( i=0; idigest[0...15] */ static unsigned char PADDING[64] = { 0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; /* F, G, H and I are basic MD5 functions */ #define F(x, y, z) (((x) & (y)) | ((~x) & (z))) #define G(x, y, z) (((x) & (z)) | ((y) & (~z))) #define H(x, y, z) ((x) ^ (y) ^ (z)) #define I(x, y, z) ((y) ^ ((x) | (~z))) /* ROTATE_LEFT rotates x left n bits */ #define ROTATE_LEFT(x, n) (((x) << (n)) | ((x) >> (32-(n)))) /* FF, GG, HH, and II transformations for rounds 1, 2, 3, and 4 */ /* Rotation is separate from addition to prevent recomputation */ #define FF(a, b, c, d, x, s, ac) \ {(a) += F ((b), (c), (d)) + (x) + (UINT4)(ac); \ (a) = ROTATE_LEFT ((a), (s)); \ (a) += (b); \ } #define GG(a, b, c, d, x, s, ac) \ {(a) += G ((b), (c), (d)) + (x) + (UINT4)(ac); \ (a) = ROTATE_LEFT ((a), (s)); \ (a) += (b); \ } #define HH(a, b, c, d, x, s, ac) \ {(a) += H ((b), (c), (d)) + (x) + (UINT4)(ac); \ (a) = ROTATE_LEFT ((a), (s)); \ (a) += (b); \ } #define II(a, b, c, d, x, s, ac) \ {(a) += I ((b), (c), (d)) + (x) + (UINT4)(ac); \ (a) = ROTATE_LEFT ((a), (s)); \ (a) += (b); \ } /* The routine MD5Init initializes the message-digest context mdContext. All fields are set to zero. */ void MD5Init ( MD5_CTX *mdContext) { mdContext->i[0] = mdContext->i[1] = (UINT4)0; /* Load magic initialization constants. */ mdContext->buf[0] = (UINT4)0x67452301L; mdContext->buf[1] = (UINT4)0xefcdab89L; mdContext->buf[2] = (UINT4)0x98badcfeL; mdContext->buf[3] = (UINT4)0x10325476L; } /* The routine MD5Update updates the message-digest context to account for the presence of each of the characters inBuf[0..inLen-1] in the message whose digest is being computed. */ void MD5Update (register MD5_CTX *mdContext, unsigned char *inBuf, unsigned int inLen) { register int i, ii; int mdi; UINT4 in[16]; /* compute number of bytes mod 64 */ mdi = (int)((mdContext->i[0] >> 3) & 0x3F); /* update number of bits */ if ((mdContext->i[0] + ((UINT4)inLen << 3)) < mdContext->i[0]) mdContext->i[1]++; mdContext->i[0] += ((UINT4)inLen << 3); mdContext->i[1] += ((UINT4)inLen >> 29); while (inLen--) { /* add new character to buffer, increment mdi */ mdContext->in[mdi++] = *inBuf++; /* transform if necessary */ if (mdi == 0x40) { for (i = 0, ii = 0; i < 16; i++, ii += 4) in[i] = (((UINT4)mdContext->in[ii+3]) << 24) | (((UINT4)mdContext->in[ii+2]) << 16) | (((UINT4)mdContext->in[ii+1]) << 8) | ((UINT4)mdContext->in[ii]); Transform (mdContext->buf, in); mdi = 0; } } } /* The routine MD5Final terminates the message-digest computation and ends with the desired message digest in mdContext->digest[0...15]. */ void MD5Final (MD5_CTX *mdContext) { UINT4 in[16]; int mdi; unsigned int i, ii; unsigned int padLen; /* save number of bits */ in[14] = mdContext->i[0]; in[15] = mdContext->i[1]; /* compute number of bytes mod 64 */ mdi = (int)((mdContext->i[0] >> 3) & 0x3F); /* pad out to 56 mod 64 */ padLen = (mdi < 56) ? (56 - mdi) : (120 - mdi); MD5Update (mdContext, PADDING, padLen); /* append length in bits and transform */ for (i = 0, ii = 0; i < 14; i++, ii += 4) in[i] = (((UINT4)mdContext->in[ii+3]) << 24) | (((UINT4)mdContext->in[ii+2]) << 16) | (((UINT4)mdContext->in[ii+1]) << 8) | ((UINT4)mdContext->in[ii]); Transform (mdContext->buf, in); /* store buffer in digest */ for (i = 0, ii = 0; i < 4; i++, ii += 4) { mdContext->digest[ii] = (unsigned char)(mdContext->buf[i] & 0xFF); mdContext->digest[ii+1] = (unsigned char)((mdContext->buf[i] >> 8) & 0xFF); mdContext->digest[ii+2] = (unsigned char)((mdContext->buf[i] >> 16) & 0xFF); mdContext->digest[ii+3] = (unsigned char)((mdContext->buf[i] >> 24) & 0xFF); } } /* Basic MD5 step. Transforms buf based on in. Note that if the Mysterious Constants are arranged backwards in little-endian order and decrypted with the DES they produce OCCULT MESSAGES! */ void Transform(register UINT4 *buf,register UINT4 *in) { register UINT4 a = buf[0], b = buf[1], c = buf[2], d = buf[3]; /* Round 1 */ #define S11 7 #define S12 12 #define S13 17 #define S14 22 FF ( a, b, c, d, in[ 0], S11, 0xD76AA478L); /* 1 */ FF ( d, a, b, c, in[ 1], S12, 0xE8C7B756L); /* 2 */ FF ( c, d, a, b, in[ 2], S13, 0x242070DBL); /* 3 */ FF ( b, c, d, a, in[ 3], S14, 0xC1BDCEEEL); /* 4 */ FF ( a, b, c, d, in[ 4], S11, 0xF57C0FAFL); /* 5 */ FF ( d, a, b, c, in[ 5], S12, 0x4787C62AL); /* 6 */ FF ( c, d, a, b, in[ 6], S13, 0xA8304613L); /* 7 */ FF ( b, c, d, a, in[ 7], S14, 0xFD469501L); /* 8 */ FF ( a, b, c, d, in[ 8], S11, 0x698098D8L); /* 9 */ FF ( d, a, b, c, in[ 9], S12, 0x8B44F7AFL); /* 10 */ FF ( c, d, a, b, in[10], S13, 0xFFFF5BB1L); /* 11 */ FF ( b, c, d, a, in[11], S14, 0x895CD7BEL); /* 12 */ FF ( a, b, c, d, in[12], S11, 0x6B901122L); /* 13 */ FF ( d, a, b, c, in[13], S12, 0xFD987193L); /* 14 */ FF ( c, d, a, b, in[14], S13, 0xA679438EL); /* 15 */ FF ( b, c, d, a, in[15], S14, 0x49B40821L); /* 16 */ /* Round 2 */ #define S21 5 #define S22 9 #define S23 14 #define S24 20 GG ( a, b, c, d, in[ 1], S21, 0xF61E2562L); /* 17 */ GG ( d, a, b, c, in[ 6], S22, 0xC040B340L); /* 18 */ GG ( c, d, a, b, in[11], S23, 0x265E5A51L); /* 19 */ GG ( b, c, d, a, in[ 0], S24, 0xE9B6C7AAL); /* 20 */ GG ( a, b, c, d, in[ 5], S21, 0xD62F105DL); /* 21 */ GG ( d, a, b, c, in[10], S22, 0x02441453L); /* 22 */ GG ( c, d, a, b, in[15], S23, 0xD8A1E681L); /* 23 */ GG ( b, c, d, a, in[ 4], S24, 0xE7D3FBC8L); /* 24 */ GG ( a, b, c, d, in[ 9], S21, 0x21E1CDE6L); /* 25 */ GG ( d, a, b, c, in[14], S22, 0xC33707D6L); /* 26 */ GG ( c, d, a, b, in[ 3], S23, 0xF4D50D87L); /* 27 */ GG ( b, c, d, a, in[ 8], S24, 0x455A14EDL); /* 28 */ GG ( a, b, c, d, in[13], S21, 0xA9E3E905L); /* 29 */ GG ( d, a, b, c, in[ 2], S22, 0xFCEFA3F8L); /* 30 */ GG ( c, d, a, b, in[ 7], S23, 0x676F02D9L); /* 31 */ GG ( b, c, d, a, in[12], S24, 0x8D2A4C8AL); /* 32 */ /* Round 3 */ #define S31 4 #define S32 11 #define S33 16 #define S34 23 HH ( a, b, c, d, in[ 5], S31, 0xFFFA3942L); /* 33 */ HH ( d, a, b, c, in[ 8], S32, 0x8771F681L); /* 34 */ HH ( c, d, a, b, in[11], S33, 0x6D9D6122L); /* 35 */ HH ( b, c, d, a, in[14], S34, 0xFDE5380CL); /* 36 */ HH ( a, b, c, d, in[ 1], S31, 0xA4BEEA44L); /* 37 */ HH ( d, a, b, c, in[ 4], S32, 0x4BDECFA9L); /* 38 */ HH ( c, d, a, b, in[ 7], S33, 0xF6BB4B60L); /* 39 */ HH ( b, c, d, a, in[10], S34, 0xBEBFBC70L); /* 40 */ HH ( a, b, c, d, in[13], S31, 0x289B7EC6L); /* 41 */ HH ( d, a, b, c, in[ 0], S32, 0xEAA127FAL); /* 42 */ HH ( c, d, a, b, in[ 3], S33, 0xD4EF3085L); /* 43 */ HH ( b, c, d, a, in[ 6], S34, 0x04881D05L); /* 44 */ HH ( a, b, c, d, in[ 9], S31, 0xD9D4D039L); /* 45 */ HH ( d, a, b, c, in[12], S32, 0xE6DB99E5L); /* 46 */ HH ( c, d, a, b, in[15], S33, 0x1FA27CF8L); /* 47 */ HH ( b, c, d, a, in[ 2], S34, 0xC4AC5665L); /* 48 */ /* Round 4 */ #define S41 6 #define S42 10 #define S43 15 #define S44 21 II ( a, b, c, d, in[ 0], S41, 0xF4292244L); /* 49 */ II ( d, a, b, c, in[ 7], S42, 0x432AFF97L); /* 50 */ II ( c, d, a, b, in[14], S43, 0xAB9423A7L); /* 51 */ II ( b, c, d, a, in[ 5], S44, 0xFC93A039L); /* 52 */ II ( a, b, c, d, in[12], S41, 0x655B59C3L); /* 53 */ II ( d, a, b, c, in[ 3], S42, 0x8F0CCC92L); /* 54 */ II ( c, d, a, b, in[10], S43, 0xFFEFF47DL); /* 55 */ II ( b, c, d, a, in[ 1], S44, 0x85845DD1L); /* 56 */ II ( a, b, c, d, in[ 8], S41, 0x6FA87E4FL); /* 57 */ II ( d, a, b, c, in[15], S42, 0xFE2CE6E0L); /* 58 */ II ( c, d, a, b, in[ 6], S43, 0xA3014314L); /* 59 */ II ( b, c, d, a, in[13], S44, 0x4E0811A1L); /* 60 */ II ( a, b, c, d, in[ 4], S41, 0xF7537E82L); /* 61 */ II ( d, a, b, c, in[11], S42, 0xBD3AF235L); /* 62 */ II ( c, d, a, b, in[ 2], S43, 0x2AD7D2BBL); /* 63 */ II ( b, c, d, a, in[ 9], S44, 0xEB86D391L); /* 64 */ buf[0] += a; buf[1] += b; buf[2] += c; buf[3] += d; } /* MD5 test vectors: d41d8cd98f00b204e9800998ecf8427e "" 0cc175b9c0f1b6a831c399e269772661 "a" 900150983cd24fb0d6963f7d28e17f72 "abc" f96b697d7cb7938d525a2f31aaf161d0 "message digest" c3fcd3d76192e4007dfb496cca67e13b "abcdefghijklmnopqrstuvwxyz" d174ab98d277d9f5a5611c2c9f419d9f "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijk\ lmnopqrstuvwxyz0123456789" 57edf4a22be3c955ac49da2e2107b67a "1234567890123456789012345678901234567\ 8901234567890123456789012345678901234567890" 900150983cd24fb0d6963f7d28e17f72 foo */ Appendix D. The Secure Hash Algorithm /* Implementation of NIST's Secure Hash Algorithm (FIPS 180) * Lightly bummed for execution efficiency. * * Jim Gillogly 3 May 1993 * * Compile: cc -O -o sha sha.c * * To remove the test wrapper and use just the nist_hash() routine, * compile with -DONT_WRAP * * Usage: sha [-vt] [filename ...] * * -v switch: output the filename as well * -t switch: suppress spaces between 32-bit blocks * * If no input files are specified, process standard input. * * Output: 40-hex-digit digest of each file specified (160 bits) * * Synopsis of the function calls: * * sha_file(char *filename, unsigned long *buffer) * Filename is a file to be opened and processed. * buffer is a user-supplied array of 5 or more longs. * The 5-word buffer is filled with 160 bits of non- terminated hash. * Returns 0 if successful, non-zero if bad file. * * void sha_stream(FILE *stream, unsigned long *buffer) * Input is from already-opened stream, not file. * * void sha_memory(char *mem, long length, unsigned long *buffer) * Input is a memory block "length" bytes long. * * Caveat: * Not tested for case that requires the high word of the length, * which would be files larger than 1/2 gig or so. * * Limitation: * sha_memory (the memory block function) will deal with blocks no longer * than 4 gigabytes; for longer samples, the stream version will * probably be most convenient (e.g. perl moby_data.pl | sha). * * Bugs: * The standard is defined for bit strings; I assume bytes. * * test vector: "abcdbcdecdefdefgefghfghighijhijkijkljklmklmnlmnomnopnopq" * should compute: * 0xd2516ee1L * 0xacfa5bafL * 0x33dfc1c4L * 0x71e43844L * 0x9ef134c8L * * test vector: "abc" * should compute: * 0x0164b8a9L * 0x14cd2a5eL * 0x74c4f7ffL * 0x082c4d97L * 0xf1edf880L * * Copyright 1993, Dr. James J. Gillogly * This code may be freely used in any application. */ #include #include #define TRUE 1 #define FALSE 0 #define SUCCESS 0 #define FAILURE -1 int sha_file(); /* External entries */ void sha_stream(), sha_memory(); static void nist_guts(); #ifndef ONT_WRAP /* Using just the hash routine itself */ #define HASH_SIZE 5 /* Produces 160-bit digest of the message */ main(argc, argv) int argc; char **argv; { unsigned long hbuf[HASH_SIZE]; char *s; int file_args = FALSE; /* If no files, take it from stdin */ int verbose = FALSE; int terse = FALSE; #ifdef MEMTEST sha_memory("abc", 3l, hbuf); /* NIST test value from appendix A */ if (verbose) printf("Memory:"); if (terse) printf("%08x%08x%08x%08x%08x\n", hbuf[0], hbuf[1], hbuf[2], hbuf[3], hbuf[4]); else printf("%08x %08x %08x %08x %08x\n", hbuf[0], hbuf[1], hbuf[2], hbuf[3], hbuf[4]); #endif for (++argv; --argc; ++argv) /* March down the arg list */ { verbose = TRUE; if (**argv == '-') /* Process one or more flags */ for (s = &(*argv)[1]; *s; s++) /* Obfuscated C contest entry */ switch(*s) { case 'v': case 'V': verbose = TRUE; break; case 't': case 'T': terse = TRUE; break; default: fprintf(stderr, "Unrecognized flag: %c\n", *s); return FALSE; } else /* Process a file */ { if (verbose) printf("%s:\t\t", *argv); file_args = TRUE; /* Whether or not we could read it */ if (sha_file(*argv, hbuf) == FAILURE) printf("Can't open file %s.\n", *argv); else if (terse) printf("%08x%08x%08x%08x%08x\n", hbuf[0], hbuf[1], hbuf[2], hbuf[3], hbuf[4]); else printf("%08x %08x %08x %08x %08x\n", hbuf[0], hbuf[1], hbuf[2], hbuf[3], hbuf[4]); } } if (! file_args) /* No file specified */ { if (verbose) printf("%s:\t\t", *argv); sha_stream(stdin, hbuf); if (terse) printf("%08x%08x%08x%08x%08x\n", hbuf[0], hbuf[1], hbuf[2], hbuf[3], hbuf[4]); else printf("%08x %08x %08x %08x %08x\n", hbuf[0], hbuf[1], hbuf[2], hbuf[3], hbuf[4]); } return TRUE; } #endif ONT_WRAP union longbyte { unsigned long W[80]; /* Process 16 32-bit words at a time */ char B[320]; /* But read them as bytes for counting */ }; sha_file(filename, buffer) /* Hash a file */ char *filename; unsigned long *buffer; { FILE *infile; if ((infile = fopen(filename, "rb")) == NULL) { int i; for (i = 0; i < 5; i++) buffer[i] = 0xdeadbeef; return FAILURE; } (void) sha_stream(infile, buffer); fclose(infile); return SUCCESS; } void sha_memory(mem, length, buffer) /* Hash a memory block */ char *mem; unsigned long length; unsigned long *buffer; { nist_guts(FALSE, (FILE *) NULL, mem, length, buffer); } void sha_stream(stream, buffer) FILE *stream; unsigned long *buffer; { nist_guts(TRUE, stream, (char *) NULL, 0l, buffer); } #define f0(x,y,z) (z ^ (x & (y ^ z))) /* Magic functions */ #define f1(x,y,z) (x ^ y ^ z) #define f2(x,y,z) ((x & y) | (z & (x | y))) #define f3(x,y,z) (x ^ y ^ z) #define K0 0x5a827999 /* Magic constants */ #define K1 0x6ed9eba1 #define K2 0x8f1bbcdc #define K3 0xca62c1d6 #define S(n, X) ((X << n) | (X >> (32 - n))) /* Barrel roll */ #define r0(f, K) \ temp = S(5, A) + f(B, C, D) + E + *p0++ + K; \ E = D; \ D = C; \ C = S(30, B); \ B = A; \ A = temp #define r1(f, K) \ temp = S(5, A) + f(B, C, D) + E + \ (*p0++ = *p1++ ^ *p2++ ^ *p3++ ^ *p4++) + K; \ E = D; \ D = C; \ C = S(30, B); \ B = A; \ A = temp static void nist_guts(file_flag, stream, mem, length, buf) int file_flag; /* Input from memory, or from stream? */ FILE *stream; char *mem; unsigned long length; unsigned long *buf; { int i, nread, nbits; union longbyte d; unsigned long hi_length, lo_length; int padded; char *s; register unsigned long *p0, *p1, *p2, *p3, *p4; unsigned long A, B, C, D, E, temp; unsigned long h0, h1, h2, h3, h4; h0 = 0x67452301; /* Accumulators */ h1 = 0xefcdab89; h2 = 0x98badcfe; h3 = 0x10325476; h4 = 0xc3d2e1f0; padded = FALSE; s = mem; for (hi_length = lo_length = 0; ;) /* Process 16 longs at a time */ { if (file_flag) { nread = fread(d.B, 1, 64, stream); /* Read as 64 bytes */ } else { if (length < 64) nread = length; else nread = 64; length -= nread; memcpy(d.B, s, nread); s += nread; } if (nread < 64) /* Partial block? */ { nbits = nread << 3; /* Length: bits */ if ((lo_length += nbits) < nbits) hi_length++; /* 64-bit integer */ if (nread < 64 && ! padded) /* Append a single bit */ { d.B[nread++] = 0x80; /* Using up next byte */ padded = TRUE; /* Single bit once */ } for (i = nread; i < 64; i++) /* Pad with nulls */ d.B[i] = 0; if (nread <= 56) /* Room for length in this block */ { d.W[14] = hi_length; d.W[15] = lo_length; } } else /* Full block -- get efficient */ { if ((lo_length += 512) < 512) hi_length++; /* 64-bit integer */ } p0 = d.W; A = h0; B = h1; C = h2; D = h3; E = h4; r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); r0(f0,K0); p1 = &d.W[13]; p2 = &d.W[8]; p3 = &d.W[2]; p4 = &d.W[0]; r1(f0,K0); r1(f0,K0); r1(f0,K0); r1(f0,K0); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f1,K1); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f2,K2); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); r1(f3,K3); h0 += A; h1 += B; h2 += C; h3 += D; h4 += E; if (nread <= 56) break; /* If it's greater, length in next block */ } buf[0] = h0; buf[1] = h1; buf[2] = h2; buf[3] = h3; buf[4] = h4; } Appendix E. Select References [selection and of passwords in differing threat environments] Department of Defense Password Management Guideline CSC-STD-002-85 published by the Computer Security Center of the Department of Defense Fort George G. Meade, MD 20755 [discovering weak passwords] The COPS Security Checker System by D. Farmer, E. Spafford Purdue University Technical Report CSD-TR-993 West Lafayette, IN 47907 [an example of automated key cracking] With Microscope and Tweezers: An Analysis of the Internet Virus of 1988 by M. Eichin, J. Rochlis, Massachusetts Institute of Technology Cambridge, MA 02139 [password vulnerabilities in distributed systems] Computer Emergency Response - An International Problem by R. Pethia, K. van Wyk CERT/Software Engineering Institute Carnegie Mellon University, Pittsburgh, PA 15213 [key metrics and the MD5 message digest algorithm] Answers to Frequently Asked Questions About Today's Cryptography Second edition, by Paul Fahn RSA Laboratories, Redwood City, CA 94065 (available through anonymous FTP from rsa.com) [implementation details of the MD5 message digest algorithm] RFC-1321 ('request for comments') The MD5 algorithm by R. Rivest MIT Center for Computer Science (available on the internet from gatekeeper.dec.com) [implementation details of the NIST Secure Hash Standard] The Secure Hash Standard (SHS) Specification, Jan 1992 DRAFT Federal Information Processing Standards Publication YY Director, Computer Systems Laboratory National Institute of Standards and Technology Gaithersburg, MD 20899 (The SHS was approved as a Federal Standard in May, 1993) [other possible approaches to password generation] Automated Password Generator, NIST publication ???? Director, Computer Systems Laboratory National Institute of Standards and Technology Gaithersburg, MD 20899 (a pronounceable password algorithm using DES) -- Grady Ward grady@netcom.com 3449 Martha Ct. compiler of Moby lexicons Arcata, CA 95521-4884 e-mail or finger grady@netcom.com (707) 826-7715 (voice/24hr FAX) for more information