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https://github.com/topjohnwu/ndk-busybox.git
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49ecee098d
Good news that TLS_RSA_WITH_AES_256_CBC_SHA256 still works with new code ;) This change adds inevitable extension to have different sized hashes and AES key sizes. In libbb, md5_end() and shaX_end() are extended to return result size instead of void - this helps *a lot* in tls (the cost is ~5 bytes per _end() function). Signed-off-by: Denys Vlasenko <vda.linux@googlemail.com>
287 lines
9.2 KiB
C
287 lines
9.2 KiB
C
/* SHA256 and SHA512-based Unix crypt implementation.
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* Released into the Public Domain by Ulrich Drepper <drepper@redhat.com>.
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*/
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/* Prefix for optional rounds specification. */
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static const char str_rounds[] ALIGN1 = "rounds=%u$";
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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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static char *
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NOINLINE
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sha_crypt(/*const*/ char *key_data, /*const*/ char *salt_data)
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{
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#undef sha_end
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void (*sha_begin)(void *ctx) FAST_FUNC;
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void (*sha_hash)(void *ctx, const void *buffer, size_t len) FAST_FUNC;
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unsigned (*sha_end)(void *ctx, void *resbuf) FAST_FUNC;
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int _32or64;
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char *result, *resptr;
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/* btw, sha256 needs [32] and uint32_t only */
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struct {
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unsigned char alt_result[64];
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unsigned char temp_result[64];
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union {
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sha256_ctx_t x;
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sha512_ctx_t y;
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} ctx;
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union {
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sha256_ctx_t x;
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sha512_ctx_t y;
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} alt_ctx;
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} L __attribute__((__aligned__(__alignof__(uint64_t))));
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#define alt_result (L.alt_result )
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#define temp_result (L.temp_result)
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#define ctx (L.ctx )
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#define alt_ctx (L.alt_ctx )
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unsigned salt_len;
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unsigned key_len;
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unsigned cnt;
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unsigned rounds;
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char *cp;
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/* Analyze salt, construct already known part of result */
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cnt = strlen(salt_data) + 1 + 43 + 1;
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_32or64 = 32;
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if (salt_data[1] == '6') { /* sha512 */
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_32or64 *= 2; /*64*/
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cnt += 43;
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}
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result = resptr = xzalloc(cnt); /* will provide NUL terminator */
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*resptr++ = '$';
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*resptr++ = salt_data[1];
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*resptr++ = '$';
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rounds = ROUNDS_DEFAULT;
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salt_data += 3;
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if (strncmp(salt_data, str_rounds, 7) == 0) {
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/* 7 == strlen("rounds=") */
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char *endp;
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cnt = bb_strtou(salt_data + 7, &endp, 10);
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if (*endp == '$') {
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salt_data = endp + 1;
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rounds = cnt;
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if (rounds < ROUNDS_MIN)
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rounds = ROUNDS_MIN;
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if (rounds > ROUNDS_MAX)
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rounds = ROUNDS_MAX;
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/* add "rounds=NNNNN$" to result */
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resptr += sprintf(resptr, str_rounds, rounds);
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}
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}
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salt_len = strchrnul(salt_data, '$') - salt_data;
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if (salt_len > SALT_LEN_MAX)
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salt_len = SALT_LEN_MAX;
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/* xstrdup assures suitable alignment; also we will use it
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as a scratch space later. */
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salt_data = xstrndup(salt_data, salt_len);
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/* add "salt$" to result */
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strcpy(resptr, salt_data);
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resptr += salt_len;
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*resptr++ = '$';
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/* key data doesn't need much processing */
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key_len = strlen(key_data);
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key_data = xstrdup(key_data);
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/* Which flavor of SHAnnn ops to use? */
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sha_begin = (void*)sha256_begin;
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sha_hash = (void*)sha256_hash;
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sha_end = (void*)sha256_end;
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if (_32or64 != 32) {
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sha_begin = (void*)sha512_begin;
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sha_hash = (void*)sha512_hash;
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sha_end = (void*)sha512_end;
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}
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/* Add KEY, SALT. */
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sha_begin(&ctx);
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sha_hash(&ctx, key_data, key_len);
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sha_hash(&ctx, salt_data, salt_len);
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/* Compute alternate SHA sum with input KEY, SALT, and KEY.
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The final result will be added to the first context. */
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sha_begin(&alt_ctx);
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sha_hash(&alt_ctx, key_data, key_len);
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sha_hash(&alt_ctx, salt_data, salt_len);
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sha_hash(&alt_ctx, key_data, key_len);
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sha_end(&alt_ctx, alt_result);
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/* Add result of this to the other context. */
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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 > _32or64; cnt -= _32or64)
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sha_hash(&ctx, alt_result, _32or64);
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sha_hash(&ctx, alt_result, cnt);
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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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sha_hash(&ctx, alt_result, _32or64);
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else
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sha_hash(&ctx, key_data, key_len);
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/* Create intermediate result. */
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sha_end(&ctx, alt_result);
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/* Start computation of P byte sequence. */
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/* For every character in the password add the entire password. */
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sha_begin(&alt_ctx);
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for (cnt = 0; cnt < key_len; ++cnt)
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sha_hash(&alt_ctx, key_data, key_len);
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sha_end(&alt_ctx, temp_result);
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/* NB: past this point, raw key_data is not used anymore */
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/* Create byte sequence P. */
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#define p_bytes key_data /* reuse the buffer as it is of the key_len size */
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cp = p_bytes; /* was: ... = alloca(key_len); */
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for (cnt = key_len; cnt >= _32or64; cnt -= _32or64) {
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cp = memcpy(cp, temp_result, _32or64);
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cp += _32or64;
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}
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memcpy(cp, temp_result, cnt);
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/* Start computation of S byte sequence. */
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/* For every character in the password add the entire password. */
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sha_begin(&alt_ctx);
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for (cnt = 0; cnt < 16 + alt_result[0]; ++cnt)
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sha_hash(&alt_ctx, salt_data, salt_len);
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sha_end(&alt_ctx, temp_result);
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/* NB: past this point, raw salt_data is not used anymore */
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/* Create byte sequence S. */
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#define s_bytes salt_data /* reuse the buffer as it is of the salt_len size */
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cp = s_bytes; /* was: ... = alloca(salt_len); */
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for (cnt = salt_len; cnt >= _32or64; cnt -= _32or64) {
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cp = memcpy(cp, temp_result, _32or64);
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cp += _32or64;
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}
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memcpy(cp, temp_result, cnt);
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/* Repeatedly run the collected hash value through SHA to burn
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CPU cycles. */
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for (cnt = 0; cnt < rounds; ++cnt) {
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sha_begin(&ctx);
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/* Add key or last result. */
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if ((cnt & 1) != 0)
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sha_hash(&ctx, p_bytes, key_len);
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else
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sha_hash(&ctx, alt_result, _32or64);
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/* Add salt for numbers not divisible by 3. */
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if (cnt % 3 != 0)
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sha_hash(&ctx, s_bytes, salt_len);
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/* Add key for numbers not divisible by 7. */
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if (cnt % 7 != 0)
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sha_hash(&ctx, p_bytes, key_len);
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/* Add key or last result. */
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if ((cnt & 1) != 0)
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sha_hash(&ctx, alt_result, _32or64);
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else
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sha_hash(&ctx, p_bytes, key_len);
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sha_end(&ctx, alt_result);
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}
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/* Append encrypted password to result buffer */
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//TODO: replace with something like
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// bb_uuencode(cp, src, length, bb_uuenc_tbl_XXXbase64);
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#define b64_from_24bit(B2, B1, B0, N) \
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do { \
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unsigned w = ((B2) << 16) | ((B1) << 8) | (B0); \
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resptr = to64(resptr, w, N); \
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} while (0)
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if (_32or64 == 32) { /* sha256 */
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unsigned i = 0;
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while (1) {
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unsigned j = i + 10;
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unsigned k = i + 20;
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if (j >= 30) j -= 30;
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if (k >= 30) k -= 30;
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b64_from_24bit(alt_result[i], alt_result[j], alt_result[k], 4);
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if (k == 29)
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break;
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i = k + 1;
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}
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b64_from_24bit(0, alt_result[31], alt_result[30], 3);
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/* was:
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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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*/
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} else {
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unsigned i = 0;
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while (1) {
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unsigned j = i + 21;
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unsigned k = i + 42;
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if (j >= 63) j -= 63;
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if (k >= 63) k -= 63;
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b64_from_24bit(alt_result[i], alt_result[j], alt_result[k], 4);
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if (j == 20)
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break;
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i = j + 1;
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}
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b64_from_24bit(0, 0, alt_result[63], 2);
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/* was:
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b64_from_24bit(alt_result[0], alt_result[21], alt_result[42], 4);
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b64_from_24bit(alt_result[22], alt_result[43], alt_result[1], 4);
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b64_from_24bit(alt_result[44], alt_result[2], alt_result[23], 4);
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b64_from_24bit(alt_result[3], alt_result[24], alt_result[45], 4);
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b64_from_24bit(alt_result[25], alt_result[46], alt_result[4], 4);
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b64_from_24bit(alt_result[47], alt_result[5], alt_result[26], 4);
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b64_from_24bit(alt_result[6], alt_result[27], alt_result[48], 4);
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b64_from_24bit(alt_result[28], alt_result[49], alt_result[7], 4);
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b64_from_24bit(alt_result[50], alt_result[8], alt_result[29], 4);
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b64_from_24bit(alt_result[9], alt_result[30], alt_result[51], 4);
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b64_from_24bit(alt_result[31], alt_result[52], alt_result[10], 4);
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b64_from_24bit(alt_result[53], alt_result[11], alt_result[32], 4);
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b64_from_24bit(alt_result[12], alt_result[33], alt_result[54], 4);
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b64_from_24bit(alt_result[34], alt_result[55], alt_result[13], 4);
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b64_from_24bit(alt_result[56], alt_result[14], alt_result[35], 4);
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b64_from_24bit(alt_result[15], alt_result[36], alt_result[57], 4);
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b64_from_24bit(alt_result[37], alt_result[58], alt_result[16], 4);
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b64_from_24bit(alt_result[59], alt_result[17], alt_result[38], 4);
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b64_from_24bit(alt_result[18], alt_result[39], alt_result[60], 4);
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b64_from_24bit(alt_result[40], alt_result[61], alt_result[19], 4);
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b64_from_24bit(alt_result[62], alt_result[20], alt_result[41], 4);
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b64_from_24bit(0, 0, alt_result[63], 2);
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*/
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}
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/* *resptr = '\0'; - xzalloc did it */
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#undef b64_from_24bit
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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. */
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memset(&L, 0, sizeof(L)); /* [alt]_ctx and XXX_result buffers */
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memset(key_data, 0, key_len); /* also p_bytes */
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memset(salt_data, 0, salt_len); /* also s_bytes */
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free(key_data);
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free(salt_data);
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#undef p_bytes
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#undef s_bytes
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return result;
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#undef alt_result
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#undef temp_result
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#undef ctx
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#undef alt_ctx
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}
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