| blob | 67edc97f594271d45b6e75c8d97ac39cd08a2bd9 |
1 /* $PostgreSQL$ */
2 /* $NetBSD$ */
4 /*
5 * Copyright (c) 1989, 1993
6 * The Regents of the University of California. All rights reserved.
7 *
8 * This code is derived from software contributed to Berkeley by
9 * Tom Truscott.
10 *
11 * Redistribution and use in source and binary forms, with or without
12 * modification, are permitted provided that the following conditions
13 * are met:
14 * 1. Redistributions of source code must retain the above copyright
15 * notice, this list of conditions and the following disclaimer.
16 * 2. Redistributions in binary form must reproduce the above copyright
17 * notice, this list of conditions and the following disclaimer in the
18 * documentation and/or other materials provided with the distribution.
19 * 3. Neither the name of the University nor the names of its contributors
20 * may be used to endorse or promote products derived from this software
21 * without specific prior written permission.
22 *
23 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
24 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
25 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
26 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
27 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
28 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
29 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
30 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
31 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
32 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
33 * SUCH DAMAGE.
34 */
36 #if defined(LIBC_SCCS) && !defined(lint)
37 #if 0
39 #else
41 #endif
46 #include <limits.h>
48 #ifndef WIN32
49 #include <unistd.h>
50 #endif
55 /*
56 * UNIX password, and DES, encryption.
57 * By Tom Truscott, trt@rti.rti.org,
58 * from algorithms by Robert W. Baldwin and James Gillogly.
59 *
60 * References:
61 * "Mathematical Cryptology for Computer Scientists and Mathematicians,"
62 * by Wayne Patterson, 1987, ISBN 0-8476-7438-X.
63 *
64 * "Password Security: A Case History," R. Morris and Ken Thompson,
65 * Communications of the ACM, vol. 22, pp. 594-597, Nov. 1979.
66 *
67 * "DES will be Totally Insecure within Ten Years," M.E. Hellman,
68 * IEEE Spectrum, vol. 16, pp. 32-39, July 1979.
69 */
71 /* ===== Configuration ==================== */
73 /*
74 * define "MUST_ALIGN" if your compiler cannot load/store
75 * long integers at arbitrary (e.g. odd) memory locations.
76 * (Either that or never pass unaligned addresses to des_cipher!)
77 */
78 /* #define MUST_ALIGN */
80 #ifdef CHAR_BITS
81 #if CHAR_BITS != 8
82 #error C_block structure assumes 8 bit characters
83 #endif
84 #endif
86 /*
87 * define "B64" to be the declaration for a 64 bit integer.
88 * XXX this feature is currently unused, see "endian" comment below.
89 */
90 #define B64 __int64
92 /*
93 * define "LARGEDATA" to get faster permutations, by using about 72 kilobytes
94 * of lookup tables. This speeds up des_setkey() and des_cipher(), but has
95 * little effect on crypt().
96 */
97 /* #define LARGEDATA */
99 /* compile with "-DSTATIC=void" when profiling */
100 #ifndef STATIC
101 #define STATIC static void
102 #endif
104 /*
105 * Define the "int32_t" type for integral type with a width of at least
106 * 32 bits.
107 */
110 /* ==================================== */
114 /*
115 * Cipher-block representation (Bob Baldwin):
116 *
117 * DES operates on groups of 64 bits, numbered 1..64 (sigh). One
118 * representation is to store one bit per byte in an array of bytes. Bit N of
119 * the NBS spec is stored as the LSB of the Nth byte (index N-1) in the array.
120 * Another representation stores the 64 bits in 8 bytes, with bits 1..8 in the
121 * first byte, 9..16 in the second, and so on. The DES spec apparently has
122 * bit 1 in the MSB of the first byte, but that is particularly noxious so we
123 * bit-reverse each byte so that bit 1 is the LSB of the first byte, bit 8 is
124 * the MSB of the first byte. Specifically, the 64-bit input data and key are
125 * converted to LSB format, and the output 64-bit block is converted back into
126 * MSB format.
127 *
128 * DES operates internally on groups of 32 bits which are expanded to 48 bits
129 * by permutation E and shrunk back to 32 bits by the S boxes. To speed up
130 * the computation, the expansion is applied only once, the expanded
131 * representation is maintained during the encryption, and a compression
132 * permutation is applied only at the end. To speed up the S-box lookups,
133 * the 48 bits are maintained as eight 6 bit groups, one per byte, which
134 * directly feed the eight S-boxes. Within each byte, the 6 bits are the
135 * most significant ones. The low two bits of each byte are zero. (Thus,
136 * bit 1 of the 48 bit E expansion is stored as the "4"-valued bit of the
137 * first byte in the eight byte representation, bit 2 of the 48 bit value is
138 * the "8"-valued bit, and so on.) In fact, a combined "SPE"-box lookup is
139 * used, in which the output is the 64 bit result of an S-box lookup which
140 * has been permuted by P and expanded by E, and is ready for use in the next
141 * iteration. Two 32-bit wide tables, SPE[0] and SPE[1], are used for this
142 * lookup. Since each byte in the 48 bit path is a multiple of four, indexed
143 * lookup of SPE[0] and SPE[1] is simple and fast. The key schedule and
144 * "salt" are also converted to this 8*(6+2) format. The SPE table size is
145 * 8*64*8 = 4K bytes.
146 *
147 * To speed up bit-parallel operations (such as XOR), the 8 byte
148 * representation is "union"ed with 32 bit values "i0" and "i1", and, on
149 * machines which support it, a 64 bit value "b64". This data structure,
150 * "C_block", has two problems. First, alignment restrictions must be
151 * honored. Second, the byte-order (e.g. little-endian or big-endian) of
152 * the architecture becomes visible.
153 *
154 * The byte-order problem is unfortunate, since on the one hand it is good
155 * to have a machine-independent C_block representation (bits 1..8 in the
156 * first byte, etc.), and on the other hand it is good for the LSB of the
157 * first byte to be the LSB of i0. We cannot have both these things, so we
158 * currently use the "little-endian" representation and avoid any multi-byte
159 * operations that depend on byte order. This largely precludes use of the
160 * 64-bit datatype since the relative order of i0 and i1 are unknown. It
161 * also inhibits grouping the SPE table to look up 12 bits at a time. (The
162 * 12 bits can be stored in a 16-bit field with 3 low-order zeroes and 1
163 * high-order zero, providing fast indexing into a 64-bit wide SPE.) On the
164 * other hand, 64-bit datatypes are currently rare, and a 12-bit SPE lookup
165 * requires a 128 kilobyte table, so perhaps this is not a big loss.
166 *
167 * Permutation representation (Jim Gillogly):
168 *
169 * A transformation is defined by its effect on each of the 8 bytes of the
170 * 64-bit input. For each byte we give a 64-bit output that has the bits in
171 * the input distributed appropriately. The transformation is then the OR
172 * of the 8 sets of 64-bits. This uses 8*256*8 = 16K bytes of storage for
173 * each transformation. Unless LARGEDATA is defined, however, a more compact
174 * table is used which looks up 16 4-bit "chunks" rather than 8 8-bit chunks.
175 * The smaller table uses 16*16*8 = 2K bytes for each transformation. This
176 * is slower but tolerable, particularly for password encryption in which
177 * the SPE transformation is iterated many times. The small tables total 9K
178 * bytes, the large tables total 72K bytes.
179 *
180 * The transformations used are:
181 * IE3264: MSB->LSB conversion, initial permutation, and expansion.
182 * This is done by collecting the 32 even-numbered bits and applying
183 * a 32->64 bit transformation, and then collecting the 32 odd-numbered
184 * bits and applying the same transformation. Since there are only
185 * 32 input bits, the IE3264 transformation table is half the size of
186 * the usual table.
187 * CF6464: Compression, final permutation, and LSB->MSB conversion.
188 * This is done by two trivial 48->32 bit compressions to obtain
189 * a 64-bit block (the bit numbering is given in the "CIFP" table)
190 * followed by a 64->64 bit "cleanup" transformation. (It would
191 * be possible to group the bits in the 64-bit block so that 2
192 * identical 32->32 bit transformations could be used instead,
193 * saving a factor of 4 in space and possibly 2 in time, but
194 * byte-ordering and other complications rear their ugly head.
195 * Similar opportunities/problems arise in the key schedule
196 * transforms.)
197 * PC1ROT: MSB->LSB, PC1 permutation, rotate, and PC2 permutation.
198 * This admittedly baroque 64->64 bit transformation is used to
199 * produce the first code (in 8*(6+2) format) of the key schedule.
200 * PC2ROT[0]: Inverse PC2 permutation, rotate, and PC2 permutation.
201 * It would be possible to define 15 more transformations, each
202 * with a different rotation, to generate the entire key schedule.
203 * To save space, however, we instead permute each code into the
204 * next by using a transformation that "undoes" the PC2 permutation,
205 * rotates the code, and then applies PC2. Unfortunately, PC2
206 * transforms 56 bits into 48 bits, dropping 8 bits, so PC2 is not
207 * invertible. We get around that problem by using a modified PC2
208 * which retains the 8 otherwise-lost bits in the unused low-order
209 * bits of each byte. The low-order bits are cleared when the
210 * codes are stored into the key schedule.
211 * PC2ROT[1]: Same as PC2ROT[0], but with two rotations.
212 * This is faster than applying PC2ROT[0] twice,
213 *
214 * The Bell Labs "salt" (Bob Baldwin):
215 *
216 * The salting is a simple permutation applied to the 48-bit result of E.
217 * Specifically, if bit i (1 <= i <= 24) of the salt is set then bits i and
218 * i+24 of the result are swapped. The salt is thus a 24 bit number, with
219 * 16777216 possible values. (The original salt was 12 bits and could not
220 * swap bits 13..24 with 36..48.)
221 *
222 * It is possible, but ugly, to warp the SPE table to account for the salt
223 * permutation. Fortunately, the conditional bit swapping requires only
224 * about four machine instructions and can be done on-the-fly with about an
225 * 8% performance penalty.
226 */
229 {
231 struct
232 {
236 #if defined(B64)
237 B64 b64;
238 #endif
241 /*
242 * Convert twenty-four-bit long in host-order
243 * to six bits (and 2 low-order zeroes) per char little-endian format.
244 */
245 #define TO_SIX_BIT(rslt, src) { \
246 C_block cvt; \
247 cvt.b[0] = src; src >>= 6; \
248 cvt.b[1] = src; src >>= 6; \
249 cvt.b[2] = src; src >>= 6; \
250 cvt.b[3] = src; \
251 rslt = (cvt.b32.i0 & 0x3f3f3f3fL) << 2; \
252 }
254 /*
255 * These macros may someday permit efficient use of 64-bit integers.
256 */
257 #define ZERO(d,d0,d1) d0 = 0, d1 = 0
258 #define LOAD(d,d0,d1,bl) d0 = (bl).b32.i0, d1 = (bl).b32.i1
259 #define LOADREG(d,d0,d1,s,s0,s1) d0 = s0, d1 = s1
260 #define OR(d,d0,d1,bl) d0 |= (bl).b32.i0, d1 |= (bl).b32.i1
261 #define STORE(s,s0,s1,bl) (bl).b32.i0 = s0, (bl).b32.i1 = s1
262 #define DCL_BLOCK(d,d0,d1) int32_t d0, d1
264 #if defined(LARGEDATA)
265 /* Waste memory like crazy. Also, do permutations in line */
266 #define LGCHUNKBITS 3
267 #define CHUNKBITS (1<<LGCHUNKBITS)
268 #define PERM6464(d,d0,d1,cpp,p) \
269 LOAD(d,d0,d1,(p)[(0<<CHUNKBITS)+(cpp)[0]]); \
270 OR (d,d0,d1,(p)[(1<<CHUNKBITS)+(cpp)[1]]); \
271 OR (d,d0,d1,(p)[(2<<CHUNKBITS)+(cpp)[2]]); \
272 OR (d,d0,d1,(p)[(3<<CHUNKBITS)+(cpp)[3]]); \
273 OR (d,d0,d1,(p)[(4<<CHUNKBITS)+(cpp)[4]]); \
274 OR (d,d0,d1,(p)[(5<<CHUNKBITS)+(cpp)[5]]); \
275 OR (d,d0,d1,(p)[(6<<CHUNKBITS)+(cpp)[6]]); \
276 OR (d,d0,d1,(p)[(7<<CHUNKBITS)+(cpp)[7]]);
277 #define PERM3264(d,d0,d1,cpp,p) \
278 LOAD(d,d0,d1,(p)[(0<<CHUNKBITS)+(cpp)[0]]); \
279 OR (d,d0,d1,(p)[(1<<CHUNKBITS)+(cpp)[1]]); \
280 OR (d,d0,d1,(p)[(2<<CHUNKBITS)+(cpp)[2]]); \
281 OR (d,d0,d1,(p)[(3<<CHUNKBITS)+(cpp)[3]]);
282 #else
283 /* "small data" */
284 #define LGCHUNKBITS 2
285 #define CHUNKBITS (1<<LGCHUNKBITS)
286 #define PERM6464(d,d0,d1,cpp,p) \
287 { C_block tblk; permute(cpp,&tblk,p,8); LOAD (d,d0,d1,tblk); }
288 #define PERM3264(d,d0,d1,cpp,p) \
289 { C_block tblk; permute(cpp,&tblk,p,4); LOAD (d,d0,d1,tblk); }
295 #ifndef LARGEDATA
297 #endif
298 #ifdef DEBUG
300 #endif
303 #ifndef LARGEDATA
304 STATIC
310 {
316 do
317 {
327 }
331 /* ===== (mostly) Standard DES Tables ==================== */
342 };
344 /* The final permutation is the inverse of IP - no table is necessary */
355 };
367 };
371 };
373 /* note: each "row" of PC2 is left-padded with bits that make it invertible */
384 };
387 /* S[1] */
392 /* S[2] */
397 /* S[3] */
402 /* S[4] */
407 /* S[5] */
412 /* S[6] */
417 /* S[7] */
422 /* S[8] */
427 };
438 };
450 };
456 /* ===== Tables that are initialized at run time ==================== */
461 /* Initial key schedule permutation */
464 /* Subsequent key schedule rotation permutations */
467 /* Initial permutation/expansion table */
470 /* Table that combines the S, P, and E operations. */
473 /* compressed/interleaved => final permutation table */
477 /* ==================================== */
487 /*
488 * Return a pointer to static data consisting of the "setting"
489 * followed by an encryption produced by the "key" and "setting".
490 */
495 {
501 salt_size;
502 C_block keyblock,
503 rsltblock;
505 #if 0
506 /* Non-DES encryption schemes hook in here. */
508 {
510 {
516 }
517 }
518 #endif
521 {
523 key++;
525 }
531 {
534 /*
535 * Involve the rest of the password 8 characters at a time.
536 */
538 {
543 {
545 key++;
547 }
550 }
554 /* get iteration count */
557 {
562 }
570 }
574 {
579 }
585 /*
586 * Encode the 64 cipher bits as 11 ascii characters.
587 */
618 }
621 /*
622 * The Key Schedule, filled in by des_setkey() or setkey().
623 */
624 #define KS_SIZE 16
629 /*
630 * Set up the key schedule from the key.
631 */
632 static int
635 {
647 {
653 }
655 }
657 /*
658 * Encrypt (or decrypt if num_iter < 0) the 8 chars at "in" with abs(num_iter)
659 * iterations of DES, using the given 24-bit salt and the pre-computed key
660 * schedule, and store the resulting 8 chars at "out" (in == out is permitted).
661 *
662 * NOTE: the performance of this routine is critically dependent on your
663 * compiler and machine architecture.
664 */
665 static int
671 {
672 /* variables that we want in registers, most important first */
673 #if defined(pdp11)
675 #endif
677 L1,
678 R0,
679 R1,
680 k;
683 loop_count;
684 C_block B;
689 #if defined(__vax__) || defined(pdp11)
691 #define SALT (~salt)
692 #else
693 #define SALT salt
694 #endif
696 #if defined(MUST_ALIGN)
706 #else
708 #endif
724 }
725 else
730 }
733 {
735 do
736 {
738 #define SPTAB(t, i) \
739 (*(int32_t *)((unsigned char *)(t) + (i)*(sizeof(int32_t)/4)))
740 #if defined(gould)
741 /* use this if B.b[i] is evaluated just once ... */
742 #define DOXOR(x,y,i) x^=SPTAB(SPE[0][i],B.b[i]); y^=SPTAB(SPE[1][i],B.b[i]);
743 #else
744 #if defined(pdp11)
745 /* use this if your "long" int indexing is slow */
746 #define DOXOR(x,y,i) j=B.b[i]; x^=SPTAB(SPE[0][i],j); y^=SPTAB(SPE[1][i],j);
747 #else
748 /* use this if "k" is allocated to a register ... */
749 #define DOXOR(x,y,i) k=B.b[i]; x^=SPTAB(SPE[0][i],k); y^=SPTAB(SPE[1][i],k);
750 #endif
751 #endif
753 #define CRUNCH(p0, p1, q0, q1) \
754 k = ((q0) ^ (q1)) & SALT; \
755 B.b32.i0 = k ^ (q0) ^ kp->b32.i0; \
756 B.b32.i1 = k ^ (q1) ^ kp->b32.i1; \
757 kp = (C_block *)((char *)kp+ks_inc); \
758 \
759 DOXOR(p0, p1, 0); \
760 DOXOR(p0, p1, 1); \
761 DOXOR(p0, p1, 2); \
762 DOXOR(p0, p1, 3); \
763 DOXOR(p0, p1, 4); \
764 DOXOR(p0, p1, 5); \
765 DOXOR(p0, p1, 6); \
766 DOXOR(p0, p1, 7);
774 /* swap L and R */
781 }
783 /* store the encrypted (or decrypted) result */
788 #if defined(MUST_ALIGN)
798 #else
800 #endif
802 }
805 /*
806 * Initialize various tables. This need only be done once. It could even be
807 * done at compile time, if the compiler were capable of that sort of thing.
808 */
809 STATIC
811 {
813 j;
819 /* static volatile long init_start = 0; not used */
821 /*
822 * table that converts chars "./0-9A-Za-z"to integers 0-63.
823 */
827 /*
828 * PC1ROT - bit reverse, then PC1, then Rotate, then PC2.
829 */
833 {
841 {
842 k--;
844 k++;
845 }
847 }
848 #ifdef DEBUG
850 #endif
853 /*
854 * PC2ROT - PC2 inverse, then Rotate (once or twice), then PC2.
855 */
857 {
863 {
867 }
869 {
876 }
877 #ifdef DEBUG
879 #endif
881 }
883 /*
884 * Bit reverse, then initial permutation, then expansion.
885 */
887 {
889 {
894 k--;
896 {
897 k--;
899 k++;
900 }
902 }
903 }
904 #ifdef DEBUG
906 #endif
909 /*
910 * Compression, then final permutation, then bit reverse.
911 */
913 {
916 {
917 k--;
919 k++;
920 }
922 }
923 #ifdef DEBUG
925 #endif
928 /*
929 * SPE table
930 */
934 {
936 {
960 }
961 }
964 }
966 /*
967 * Initialize "perm" to represent transformation "p", which rearranges
968 * (perhaps with expansion and/or contraction) one packed array of bits
969 * (of size "chars_in" characters) into another array (of size "chars_out"
970 * characters).
971 *
972 * "perm" must be all-zeroes on entry to this routine.
973 */
974 STATIC
979 chars_out;
980 {
982 j,
983 k,
984 l;
997 }
998 }
999 }
1001 /*
1002 * "setkey" routine (for backwards compatibility)
1003 */
1004 #ifdef NOT_USED
1005 int
1008 {
1010 j,
1011 k;
1012 C_block keyblock;
1015 {
1018 {
1021 }
1023 }
1025 }
1027 /*
1028 * "encrypt" routine (for backwards compatibility)
1029 */
1030 static int
1034 {
1036 j,
1037 k;
1038 C_block cblock;
1041 {
1044 {
1047 }
1049 }
1053 {
1056 {
1059 }
1060 }
1062 }
1063 #endif
1065 #ifdef DEBUG
1066 STATIC
1071 {
1073 j;
1077 {
1081 }
1083 }
1085 #endif