ref: 19d6a98038953b27f539e1fd2187b7cfec9b108d
dir: /sys/src/libsec/port/md4.c/
#include "os.h" #include <libsec.h> /* * This MD4 is implemented from the description in Stinson's Cryptography, * theory and practice. -- presotto */ /* * Rotate ammounts used in the algorithm */ enum { S11= 3, S12= 7, S13= 11, S14= 19, S21= 3, S22= 5, S23= 9, S24= 13, S31= 3, S32= 9, S33= 11, S34= 15, }; typedef struct MD4Table MD4Table; struct MD4Table { uchar x; /* index into data block */ uchar rot; /* amount to rotate left by */ }; static MD4Table tab[] = { /* round 1 */ /*[0]*/ { 0, S11}, { 1, S12}, { 2, S13}, { 3, S14}, { 4, S11}, { 5, S12}, { 6, S13}, { 7, S14}, { 8, S11}, { 9, S12}, { 10, S13}, { 11, S14}, { 12, S11}, { 13, S12}, { 14, S13}, { 15, S14}, /* round 2 */ /*[16]*/{ 0, S21}, { 4, S22}, { 8, S23}, { 12, S24}, { 1, S21}, { 5, S22}, { 9, S23}, { 13, S24}, { 2, S21}, { 6, S22}, { 10, S23}, { 14, S24}, { 3, S21}, { 7, S22}, { 11, S23}, { 15, S24}, /* round 3 */ /*[32]*/{ 0, S31}, { 8, S32}, { 4, S33}, { 12, S34}, { 2, S31}, { 10, S32}, { 6, S33}, { 14, S34}, { 1, S31}, { 9, S32}, { 5, S33}, { 13, S34}, { 3, S31}, { 11, S32}, { 7, S33}, { 15, S34}, }; static void encode(uchar*, u32int*, ulong); static void decode(u32int*, uchar*, ulong); static void md4block(uchar *p, ulong len, MD4state *s) { int i; u32int a, b, c, d, tmp; MD4Table *t; uchar *end; u32int x[16]; for(end = p+len; p < end; p += 64){ a = s->state[0]; b = s->state[1]; c = s->state[2]; d = s->state[3]; decode(x, p, 64); for(i = 0; i < 48; i++){ t = tab + i; switch(i>>4){ case 0: a += (b & c) | (~b & d); break; case 1: a += ((b & c) | (b & d) | (c & d)) + 0x5A827999; break; case 2: a += (b ^ c ^ d) + 0x6ED9EBA1; break; } a += x[t->x]; a = (a << t->rot) | (a >> (32 - t->rot)); /* rotate variables */ tmp = d; d = c; c = b; b = a; a = tmp; } s->state[0] += a; s->state[1] += b; s->state[2] += c; s->state[3] += d; s->len += 64; } } MD4state* md4(uchar *p, ulong len, uchar *digest, MD4state *s) { u32int x[16]; uchar buf[128]; int i; uchar *e; if(s == nil){ s = malloc(sizeof(*s)); if(s == nil) return nil; memset(s, 0, sizeof(*s)); s->malloced = 1; } if(s->seeded == 0){ /* seed the state, these constants would look nicer big-endian */ s->state[0] = 0x67452301; s->state[1] = 0xefcdab89; s->state[2] = 0x98badcfe; s->state[3] = 0x10325476; s->seeded = 1; } /* fill out the partial 64 byte block from previous calls */ if(s->blen){ i = 64 - s->blen; if(len < i) i = len; memmove(s->buf + s->blen, p, i); len -= i; s->blen += i; p += i; if(s->blen == 64){ md4block(s->buf, s->blen, s); s->blen = 0; } } /* do 64 byte blocks */ i = len & ~0x3f; if(i){ md4block(p, i, s); len -= i; p += i; } /* save the left overs if not last call */ if(digest == 0){ if(len){ memmove(s->buf, p, len); s->blen += len; } return s; } /* * this is the last time through, pad what's left with 0x80, * 0's, and the input count to create a multiple of 64 bytes */ if(s->blen){ p = s->buf; len = s->blen; } else { memmove(buf, p, len); p = buf; } s->len += len; e = p + len; if(len < 56) i = 56 - len; else i = 120 - len; memset(e, 0, i); *e = 0x80; len += i; /* append the count */ x[0] = s->len<<3; x[1] = s->len>>29; encode(p+len, x, 8); /* digest the last part */ md4block(p, len+8, s); /* return result and free state */ encode(digest, s->state, MD4dlen); if(s->malloced == 1) free(s); return nil; } /* * encodes input (u32int) into output (uchar). Assumes len is * a multiple of 4. */ static void encode(uchar *output, u32int *input, ulong len) { u32int x; uchar *e; for(e = output + len; output < e;) { x = *input++; *output++ = x; *output++ = x >> 8; *output++ = x >> 16; *output++ = x >> 24; } } /* * decodes input (uchar) into output (u32int). Assumes len is * a multiple of 4. */ static void decode(u32int *output, uchar *input, ulong len) { uchar *e; for(e = input+len; input < e; input += 4) *output++ = input[0] | (input[1] << 8) | (input[2] << 16) | (input[3] << 24); }