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346 lines
11 KiB
C
346 lines
11 KiB
C
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/* One way encryption based on SHA256 sum.
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Copyright (C) 2007 Free Software Foundation, Inc.
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This file is part of the GNU C Library.
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Contributed by Ulrich Drepper <drepper@redhat.com>, 2007.
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The GNU C Library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License as published by the Free Software Foundation; either
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version 2.1 of the License, or (at your option) any later version.
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The GNU C Library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser General Public
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License along with the GNU C Library; if not, write to the Free
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Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
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02111-1307 USA. */
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#include <assert.h>
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#include <errno.h>
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#include <stdbool.h>
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#include <stdlib.h>
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#include <string.h>
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#include <sys/param.h>
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#include "sha256.h"
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/* Define our magic string to mark salt for SHA256 "encryption"
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replacement. */
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static const char sha256_salt_prefix[] = "$5$";
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/* Prefix for optional rounds specification. */
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static const char sha256_rounds_prefix[] = "rounds=";
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/* Maximum salt string length. */
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#define SALT_LEN_MAX 16
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/* Default number of rounds if not explicitly specified. */
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#define ROUNDS_DEFAULT 5000
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/* Minimum number of rounds. */
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#define ROUNDS_MIN 1000
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/* Maximum number of rounds. */
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#define ROUNDS_MAX 999999999
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/* Table with characters for base64 transformation. */
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static const char b64t[64] =
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"./0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz";
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/* Prototypes for local functions. */
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extern char *__sha256_crypt_r (const char *key, const char *salt,
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char *buffer, int buflen);
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extern char *__sha256_crypt (const char *key, const char *salt);
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char *
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__sha256_crypt_r (key, salt, buffer, buflen)
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const char *key;
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const char *salt;
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char *buffer;
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int buflen;
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{
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unsigned char alt_result[32]
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__attribute__ ((__aligned__ (__alignof__ (uint32_t))));
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unsigned char temp_result[32]
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__attribute__ ((__aligned__ (__alignof__ (uint32_t))));
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struct sha256_ctx ctx;
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struct sha256_ctx alt_ctx;
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size_t salt_len;
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size_t key_len;
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size_t cnt;
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char *cp;
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char *copied_key = NULL;
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char *copied_salt = NULL;
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char *p_bytes;
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char *s_bytes;
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/* Default number of rounds. */
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size_t rounds = ROUNDS_DEFAULT;
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bool rounds_custom = false;
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/* Find beginning of salt string. The prefix should normally always
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be present. Just in case it is not. */
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if (strncmp (sha256_salt_prefix, salt, sizeof (sha256_salt_prefix) - 1) == 0)
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/* Skip salt prefix. */
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salt += sizeof (sha256_salt_prefix) - 1;
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if (strncmp (salt, sha256_rounds_prefix, sizeof (sha256_rounds_prefix) - 1)
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== 0)
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{
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const char *num = salt + sizeof (sha256_rounds_prefix) - 1;
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char *endp;
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unsigned long int srounds = strtoul (num, &endp, 10);
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if (*endp == '$')
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{
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salt = endp + 1;
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rounds = MAX (ROUNDS_MIN, MIN (srounds, ROUNDS_MAX));
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rounds_custom = true;
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}
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}
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salt_len = MIN (strcspn (salt, "$"), SALT_LEN_MAX);
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key_len = strlen (key);
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if ((key - (char *) 0) % __alignof__ (uint32_t) != 0)
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{
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char *tmp = (char *) alloca (key_len + __alignof__ (uint32_t));
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key = copied_key =
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memcpy (tmp + __alignof__ (uint32_t)
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- (tmp - (char *) 0) % __alignof__ (uint32_t),
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key, key_len);
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assert ((key - (char *) 0) % __alignof__ (uint32_t) == 0);
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}
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if ((salt - (char *) 0) % __alignof__ (uint32_t) != 0)
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{
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char *tmp = (char *) alloca (salt_len + __alignof__ (uint32_t));
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salt = copied_salt =
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memcpy (tmp + __alignof__ (uint32_t)
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- (tmp - (char *) 0) % __alignof__ (uint32_t),
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salt, salt_len);
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assert ((salt - (char *) 0) % __alignof__ (uint32_t) == 0);
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}
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/* Prepare for the real work. */
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__sha256_init_ctx (&ctx);
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/* Add the key string. */
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__sha256_process_bytes (key, key_len, &ctx);
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/* The last part is the salt string. This must be at most 8
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characters and it ends at the first `$' character (for
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compatibility with existing implementations). */
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__sha256_process_bytes (salt, salt_len, &ctx);
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/* Compute alternate SHA256 sum with input KEY, SALT, and KEY. The
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final result will be added to the first context. */
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__sha256_init_ctx (&alt_ctx);
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/* Add key. */
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__sha256_process_bytes (key, key_len, &alt_ctx);
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/* Add salt. */
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__sha256_process_bytes (salt, salt_len, &alt_ctx);
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/* Add key again. */
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__sha256_process_bytes (key, key_len, &alt_ctx);
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/* Now get result of this (32 bytes) and add it to the other
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context. */
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__sha256_finish_ctx (&alt_ctx, alt_result);
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/* Add for any character in the key one byte of the alternate sum. */
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for (cnt = key_len; cnt > 32; cnt -= 32)
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__sha256_process_bytes (alt_result, 32, &ctx);
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__sha256_process_bytes (alt_result, cnt, &ctx);
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/* Take the binary representation of the length of the key and for every
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1 add the alternate sum, for every 0 the key. */
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for (cnt = key_len; cnt > 0; cnt >>= 1)
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if ((cnt & 1) != 0)
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__sha256_process_bytes (alt_result, 32, &ctx);
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else
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__sha256_process_bytes (key, key_len, &ctx);
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/* Create intermediate result. */
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__sha256_finish_ctx (&ctx, alt_result);
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/* Start computation of P byte sequence. */
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__sha256_init_ctx (&alt_ctx);
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/* For every character in the password add the entire password. */
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for (cnt = 0; cnt < key_len; ++cnt)
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__sha256_process_bytes (key, key_len, &alt_ctx);
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/* Finish the digest. */
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__sha256_finish_ctx (&alt_ctx, temp_result);
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/* Create byte sequence P. */
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cp = p_bytes = alloca (key_len);
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for (cnt = key_len; cnt >= 32; cnt -= 32)
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cp = mempcpy (cp, temp_result, 32);
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memcpy (cp, temp_result, cnt);
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/* Start computation of S byte sequence. */
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__sha256_init_ctx (&alt_ctx);
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/* For every character in the password add the entire password. */
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for (cnt = 0; cnt < 16 + alt_result[0]; ++cnt)
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__sha256_process_bytes (salt, salt_len, &alt_ctx);
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/* Finish the digest. */
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__sha256_finish_ctx (&alt_ctx, temp_result);
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/* Create byte sequence S. */
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cp = s_bytes = alloca (salt_len);
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for (cnt = salt_len; cnt >= 32; cnt -= 32)
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cp = mempcpy (cp, temp_result, 32);
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memcpy (cp, temp_result, cnt);
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/* Repeatedly run the collected hash value through SHA256 to burn
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CPU cycles. */
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for (cnt = 0; cnt < rounds; ++cnt)
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{
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/* New context. */
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__sha256_init_ctx (&ctx);
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/* Add key or last result. */
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if ((cnt & 1) != 0)
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__sha256_process_bytes (p_bytes, key_len, &ctx);
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else
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__sha256_process_bytes (alt_result, 32, &ctx);
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/* Add salt for numbers not divisible by 3. */
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if (cnt % 3 != 0)
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__sha256_process_bytes (s_bytes, salt_len, &ctx);
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/* Add key for numbers not divisible by 7. */
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if (cnt % 7 != 0)
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__sha256_process_bytes (p_bytes, key_len, &ctx);
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/* Add key or last result. */
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if ((cnt & 1) != 0)
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__sha256_process_bytes (alt_result, 32, &ctx);
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else
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__sha256_process_bytes (p_bytes, key_len, &ctx);
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/* Create intermediate result. */
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__sha256_finish_ctx (&ctx, alt_result);
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}
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/* Now we can construct the result string. It consists of three
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parts. */
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cp = __stpncpy (buffer, sha256_salt_prefix, MAX (0, buflen));
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buflen -= sizeof (sha256_salt_prefix) - 1;
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if (rounds_custom)
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{
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int n = snprintf (cp, MAX (0, buflen), "%s%zu$",
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sha256_rounds_prefix, rounds);
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cp += n;
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buflen -= n;
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}
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cp = __stpncpy (cp, salt, MIN ((size_t) MAX (0, buflen), salt_len));
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buflen -= MIN ((size_t) MAX (0, buflen), salt_len);
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if (buflen > 0)
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{
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*cp++ = '$';
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--buflen;
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}
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#define b64_from_24bit(B2, B1, B0, N) \
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do { \
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unsigned int w = ((B2) << 16) | ((B1) << 8) | (B0); \
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int n = (N); \
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while (n-- > 0 && buflen > 0) \
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{ \
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*cp++ = b64t[w & 0x3f]; \
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--buflen; \
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w >>= 6; \
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} \
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} while (0)
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b64_from_24bit (alt_result[0], alt_result[10], alt_result[20], 4);
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b64_from_24bit (alt_result[21], alt_result[1], alt_result[11], 4);
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b64_from_24bit (alt_result[12], alt_result[22], alt_result[2], 4);
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b64_from_24bit (alt_result[3], alt_result[13], alt_result[23], 4);
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b64_from_24bit (alt_result[24], alt_result[4], alt_result[14], 4);
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b64_from_24bit (alt_result[15], alt_result[25], alt_result[5], 4);
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b64_from_24bit (alt_result[6], alt_result[16], alt_result[26], 4);
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b64_from_24bit (alt_result[27], alt_result[7], alt_result[17], 4);
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b64_from_24bit (alt_result[18], alt_result[28], alt_result[8], 4);
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b64_from_24bit (alt_result[9], alt_result[19], alt_result[29], 4);
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b64_from_24bit (0, alt_result[31], alt_result[30], 3);
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if (buflen <= 0)
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{
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__set_errno (ERANGE);
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buffer = NULL;
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}
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else
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*cp = '\0'; /* Terminate the string. */
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/* Clear the buffer for the intermediate result so that people
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attaching to processes or reading core dumps cannot get any
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information. We do it in this way to clear correct_words[]
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inside the SHA256 implementation as well. */
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__sha256_init_ctx (&ctx);
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__sha256_finish_ctx (&ctx, alt_result);
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memset (temp_result, '\0', sizeof (temp_result));
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memset (p_bytes, '\0', key_len);
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memset (s_bytes, '\0', salt_len);
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memset (&ctx, '\0', sizeof (ctx));
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memset (&alt_ctx, '\0', sizeof (alt_ctx));
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if (copied_key != NULL)
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memset (copied_key, '\0', key_len);
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if (copied_salt != NULL)
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memset (copied_salt, '\0', salt_len);
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return buffer;
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}
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#ifndef _LIBC
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# define libc_freeres_ptr(decl) decl
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#endif
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libc_freeres_ptr (static char *buffer);
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/* This entry point is equivalent to the `crypt' function in Unix
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libcs. */
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char *
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__sha256_crypt (const char *key, const char *salt)
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{
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/* We don't want to have an arbitrary limit in the size of the
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password. We can compute an upper bound for the size of the
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result in advance and so we can prepare the buffer we pass to
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`sha256_crypt_r'. */
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static int buflen;
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int needed = (sizeof (sha256_salt_prefix) - 1
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+ sizeof (sha256_rounds_prefix) + 9 + 1
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+ strlen (salt) + 1 + 43 + 1);
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if (buflen < needed)
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{
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char *new_buffer = (char *) realloc (buffer, needed);
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if (new_buffer == NULL)
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return NULL;
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buffer = new_buffer;
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buflen = needed;
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}
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return __sha256_crypt_r (key, salt, buffer, buflen);
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}
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#ifndef _LIBC
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static void
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__attribute__ ((__destructor__))
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free_mem (void)
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{
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free (buffer);
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}
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#endif
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