/* * libyahoo2: libyahoo2.c * * Some code copyright (C) 2002, Philip S Tellis * * Much of this code was taken and adapted from the yahoo module for * gaim released under the GNU GPL. This code is also released under the * GNU GPL. * * This code is derivitive of Gaim * copyright (C) 1998-1999, Mark Spencer * 1998-1999, Adam Fritzler * 1998-2002, Rob Flynn * 2000-2002, Eric Warmenhoven * 2001-2002, Brian Macke * 2001, Anand Biligiri S * 2001, Valdis Kletnieks * 2002, Sean Egan * 2002, Toby Gray * * This library also uses code from other libraries, namely: * Portions from libfaim copyright 1998, 1999 Adam Fritzler * * Portions of Sylpheed copyright 2000-2002 Hiroyuki Yamamoto * * * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02111-1307 USA * */ #if HAVE_CONFIG_H # include #endif #include #include #include #include #include "libyahoo.h" #include "yahoo_fn.h" #include "md5.h" #include "sha1.h" extern char *yahoo_crypt(char *, char *); void yahooBase64(unsigned char *out, const unsigned char *in, int inlen) /* raw bytes in quasi-big-endian order to base 64 string (NUL-terminated) */ { char base64digits[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" "abcdefghijklmnopqrstuvwxyz" "0123456789._"; for (; inlen >= 3; inlen -= 3) { *out++ = base64digits[in[0] >> 2]; *out++ = base64digits[((in[0]<<4) & 0x30) | (in[1]>>4)]; *out++ = base64digits[((in[1]<<2) & 0x3c) | (in[2]>>6)]; *out++ = base64digits[in[2] & 0x3f]; in += 3; } if (inlen > 0) { unsigned char fragment; *out++ = base64digits[in[0] >> 2]; fragment = (in[0] << 4) & 0x30; if (inlen > 1) fragment |= in[1] >> 4; *out++ = base64digits[fragment]; *out++ = (inlen < 2) ? '-' : base64digits[(in[1] << 2) & 0x3c]; *out++ = '-'; } *out = '\0'; } void authresp_0x0b(const char *seed, const char *sn, const char *password, char *resp_6, char *resp_96 ) { md5_byte_t result[16]; md5_state_t ctx; SHA1Context ctx1; SHA1Context ctx2; const char *alphabet1 = "FBZDWAGHrJTLMNOPpRSKUVEXYChImkwQ"; const char *alphabet2 = "F0E1D2C3B4A59687abcdefghijklmnop"; const char *challenge_lookup = "qzec2tb3um1olpar8whx4dfgijknsvy5"; const char *operand_lookup = "+|&%/*^-"; const char *delimit_lookup = ",;"; unsigned char *password_hash = malloc(25); unsigned char *crypt_hash = malloc(25); char *crypt_result = NULL; unsigned char pass_hash_xor1[64]; unsigned char pass_hash_xor2[64]; unsigned char crypt_hash_xor1[64]; unsigned char crypt_hash_xor2[64]; char chal[7]; unsigned char digest1[20]; unsigned char digest2[20]; unsigned char magic_key_char[4]; const unsigned char *magic_ptr; unsigned int magic[64]; unsigned int magic_work = 0; /*unsigned int value = 0;*/ char comparison_src[20]; int x, i, j; int depth = 0, table = 0; int cnt = 0; int magic_cnt = 0; int magic_len; /*int times = 0;*/ memset(pass_hash_xor1, 0, 64); memset(pass_hash_xor2, 0, 64); memset(crypt_hash_xor1, 0, 64); memset(crypt_hash_xor2, 0, 64); memset(digest1, 0, 20); memset(digest2, 0, 20); memset(magic, 0, 64); memset(resp_6, 0, 100); memset(resp_96, 0, 100); memset(magic_key_char, 0, 4); /* * Magic: Phase 1. Generate what seems to be a 30 * byte value (could change if base64 * ends up differently? I don't remember and I'm * tired, so use a 64 byte buffer. */ magic_ptr = (unsigned char *)seed; while (*magic_ptr != (int)NULL) { const char *loc; /* Ignore parentheses. */ if (*magic_ptr == '(' || *magic_ptr == ')') { magic_ptr++; continue; } /* Characters and digits verify against the challenge lookup. */ if (isalpha(*magic_ptr) || isdigit(*magic_ptr)) { loc = strchr(challenge_lookup, *magic_ptr); if (!loc) { /* This isn't good */ continue; } /* Get offset into lookup table and lsh 3. */ magic_work = loc - challenge_lookup; magic_work <<= 3; magic_ptr++; continue; } else { unsigned int local_store; loc = strchr(operand_lookup, *magic_ptr); if (!loc) { /* Also not good. */ continue; } local_store = loc - operand_lookup; /* Oops; how did this happen? */ if (magic_cnt >= 64) break; magic[magic_cnt++] = magic_work | local_store; magic_ptr++; continue; } } magic_len = magic_cnt; magic_cnt = 0; /* Magic: Phase 2. Take generated magic value and * sprinkle fairy dust on the values. */ for (magic_cnt = magic_len-2; magic_cnt >= 0; magic_cnt--) { unsigned char byte1; unsigned char byte2; /* Bad. Abort. */ if (magic_cnt >= magic_len) break; byte1 = magic[magic_cnt]; byte2 = magic[magic_cnt+1]; byte1 *= 0xcd; byte1 ^= byte2; magic[magic_cnt+1] = byte1; } /* Magic: Phase 3. This computes 20 bytes. The first 4 bytes are used as our magic * key (and may be changed later); the next 16 bytes are an MD5 sum of the magic key * plus 3 bytes. The 3 bytes are found by looping, and they represent the offsets * into particular functions we'll later call to potentially alter the magic key. * * %-) */ magic_cnt = 1; x = 0; do { unsigned int bl = 0; unsigned int cl = magic[magic_cnt++]; if (magic_cnt >= magic_len) break; if (cl > 0x7F) { if (cl < 0xe0) bl = cl = (cl & 0x1f) << 6; else { bl = magic[magic_cnt++]; cl = (cl & 0x0f) << 6; bl = ((bl & 0x3f) + cl) << 6; } cl = magic[magic_cnt++]; bl = (cl & 0x3f) + bl; } else bl = cl; comparison_src[x++] = (bl & 0xff00) >> 8; comparison_src[x++] = bl & 0xff; } while (x < 20); /* Dump magic key into a char for SHA1 action. */ for(x = 0; x < 4; x++) magic_key_char[x] = comparison_src[x]; /* Compute values for recursive function table! */ memcpy( chal, magic_key_char, 4 ); x = 1; for( i = 0; i < 0xFFFF && x; i++ ) { for( j = 0; j < 5 && x; j++ ) { chal[4] = i; chal[5] = i >> 8; chal[6] = j; md5_init( &ctx ); md5_append( &ctx, chal, 7 ); md5_finish( &ctx, result ); if( memcmp( comparison_src + 4, result, 16 ) == 0 ) { depth = i; table = j; x = 0; } } } /* Transform magic_key_char using transform table */ x = magic_key_char[3] << 24 | magic_key_char[2] << 16 | magic_key_char[1] << 8 | magic_key_char[0]; x = yahoo_xfrm( table, depth, x ); x = yahoo_xfrm( table, depth, x ); magic_key_char[0] = x & 0xFF; magic_key_char[1] = x >> 8 & 0xFF; magic_key_char[2] = x >> 16 & 0xFF; magic_key_char[3] = x >> 24 & 0xFF; /* Get password and crypt hashes as per usual. */ md5_init(&ctx); md5_append(&ctx, (md5_byte_t *)password, strlen(password)); md5_finish(&ctx, result); yahooBase64(password_hash, result, 16); md5_init(&ctx); crypt_result = yahoo_crypt(password, "$1$_2S43d5f$"); md5_append(&ctx, (md5_byte_t *)crypt_result, strlen(crypt_result)); md5_finish(&ctx, result); yahooBase64(crypt_hash, result, 16); /* Our first authentication response is based off * of the password hash. */ for (x = 0; x < (int)strlen((char *)password_hash); x++) pass_hash_xor1[cnt++] = password_hash[x] ^ 0x36; if (cnt < 64) memset(&(pass_hash_xor1[cnt]), 0x36, 64-cnt); cnt = 0; for (x = 0; x < (int)strlen((char *)password_hash); x++) pass_hash_xor2[cnt++] = password_hash[x] ^ 0x5c; if (cnt < 64) memset(&(pass_hash_xor2[cnt]), 0x5c, 64-cnt); SHA1Init(&ctx1); SHA1Init(&ctx2); /* The first context gets the password hash XORed * with 0x36 plus a magic value * which we previously extrapolated from our * challenge. */ SHA1Update(&ctx1, pass_hash_xor1, 64); if (j >= 3 ) ctx1.totalLength = 0x1ff; SHA1Update(&ctx1, magic_key_char, 4); SHA1Final(&ctx1, digest1); /* The second context gets the password hash XORed * with 0x5c plus the SHA-1 digest * of the first context. */ SHA1Update(&ctx2, pass_hash_xor2, 64); SHA1Update(&ctx2, digest1, 20); SHA1Final(&ctx2, digest2); /* Now that we have digest2, use it to fetch * characters from an alphabet to construct * our first authentication response. */ for (x = 0; x < 20; x += 2) { unsigned int val = 0; unsigned int lookup = 0; char byte[6]; memset(&byte, 0, 6); /* First two bytes of digest stuffed * together. */ val = digest2[x]; val <<= 8; val += digest2[x+1]; lookup = (val >> 0x0b); lookup &= 0x1f; if (lookup >= strlen(alphabet1)) break; sprintf(byte, "%c", alphabet1[lookup]); strcat(resp_6, byte); strcat(resp_6, "="); lookup = (val >> 0x06); lookup &= 0x1f; if (lookup >= strlen(alphabet2)) break; sprintf(byte, "%c", alphabet2[lookup]); strcat(resp_6, byte); lookup = (val >> 0x01); lookup &= 0x1f; if (lookup >= strlen(alphabet2)) break; sprintf(byte, "%c", alphabet2[lookup]); strcat(resp_6, byte); lookup = (val & 0x01); if (lookup >= strlen(delimit_lookup)) break; sprintf(byte, "%c", delimit_lookup[lookup]); strcat(resp_6, byte); } /* Our second authentication response is based off * of the crypto hash. */ cnt = 0; memset(&digest1, 0, 20); memset(&digest2, 0, 20); for (x = 0; x < (int)strlen((char *)crypt_hash); x++) crypt_hash_xor1[cnt++] = crypt_hash[x] ^ 0x36; if (cnt < 64) memset(&(crypt_hash_xor1[cnt]), 0x36, 64-cnt); cnt = 0; for (x = 0; x < (int)strlen((char *)crypt_hash); x++) crypt_hash_xor2[cnt++] = crypt_hash[x] ^ 0x5c; if (cnt < 64) memset(&(crypt_hash_xor2[cnt]), 0x5c, 64-cnt); SHA1Init(&ctx1); SHA1Init(&ctx2); /* The first context gets the password hash XORed * with 0x36 plus a magic value * which we previously extrapolated from our * challenge. */ SHA1Update(&ctx1, crypt_hash_xor1, 64); if (j >= 3 ) ctx1.totalLength = 0x1ff; SHA1Update(&ctx1, magic_key_char, 4); SHA1Final(&ctx1, digest1); /* The second context gets the password hash XORed * with 0x5c plus the SHA-1 digest * of the first context. */ SHA1Update(&ctx2, crypt_hash_xor2, 64); SHA1Update(&ctx2, digest1, 20); SHA1Final(&ctx2, digest2); /* Now that we have digest2, use it to fetch * characters from an alphabet to construct * our first authentication response. */ for (x = 0; x < 20; x += 2) { unsigned int val = 0; unsigned int lookup = 0; char byte[6]; memset(&byte, 0, 6); /* First two bytes of digest stuffed * together. */ val = digest2[x]; val <<= 8; val += digest2[x+1]; lookup = (val >> 0x0b); lookup &= 0x1f; if (lookup >= strlen(alphabet1)) break; sprintf(byte, "%c", alphabet1[lookup]); strcat(resp_96, byte); strcat(resp_96, "="); lookup = (val >> 0x06); lookup &= 0x1f; if (lookup >= strlen(alphabet2)) break; sprintf(byte, "%c", alphabet2[lookup]); strcat(resp_96, byte); lookup = (val >> 0x01); lookup &= 0x1f; if (lookup >= strlen(alphabet2)) break; sprintf(byte, "%c", alphabet2[lookup]); strcat(resp_96, byte); lookup = (val & 0x01); if (lookup >= strlen(delimit_lookup)) break; sprintf(byte, "%c", delimit_lookup[lookup]); strcat(resp_96, byte); } free(password_hash); free(crypt_hash); } char * getcookie(const char *rawcookie) { char * cookie=NULL; char * tmpcookie; char * cookieend; if (strlen(rawcookie) < 2) return NULL; tmpcookie = strdup(rawcookie+2); cookieend = strchr(tmpcookie, ';'); if(cookieend) *cookieend = '\0'; cookie = strdup(tmpcookie); FREE(tmpcookie); /* cookieend=NULL; not sure why this was there since the value is not preserved in the stack -dd */ return cookie; } char * getlcookie(const char *cookie) { char *tmp; char *tmpend; char *login_cookie = NULL; tmpend = strstr(cookie, "n="); if(tmpend) { tmp = strdup(tmpend+2); tmpend = strchr(tmp, '&'); if(tmpend) *tmpend='\0'; login_cookie = strdup(tmp); FREE(tmp); } return login_cookie; }