Mercurial > dropbear
view libtomcrypt/tests/multi_test.c @ 1665:7c17995bcdfb
Improve address logging on early exit messages (#83)
Change 'Early exit' and 'Exit before auth' messages to include the IP
address & port as part of the message.
This allows log scanning utilities such as 'fail2ban' to obtain the
offending IP address as part of the failure event instead of extracting
the PID from the message and then scanning the log again for match
'child connection from' messages
Signed-off-by: Kevin Darbyshire-Bryant <[email protected]>
| author | Kevin Darbyshire-Bryant <6500011+ldir-EDB0@users.noreply.github.com> |
|---|---|
| date | Wed, 18 Mar 2020 15:28:56 +0000 |
| parents | 6dba84798cd5 |
| children |
line wrap: on
line source
/* LibTomCrypt, modular cryptographic library -- Tom St Denis * * LibTomCrypt is a library that provides various cryptographic * algorithms in a highly modular and flexible manner. * * The library is free for all purposes without any express * guarantee it works. */ /* test the multi helpers... */ #include <tomcrypt_test.h> int multi_test(void) { unsigned char key[32] = { 0 }; unsigned char buf[2][MAXBLOCKSIZE]; unsigned long len, len2; /* register algos */ register_hash(&sha256_desc); register_cipher(&aes_desc); /* HASH testing */ len = sizeof(buf[0]); hash_memory(find_hash("sha256"), (unsigned char*)"hello", 5, buf[0], &len); len2 = sizeof(buf[0]); hash_memory_multi(find_hash("sha256"), buf[1], &len2, (unsigned char*)"hello", 5, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); hash_memory_multi(find_hash("sha256"), buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL, 0); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); hash_memory_multi(find_hash("sha256"), buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #ifdef LTC_HMAC len = sizeof(buf[0]); hmac_memory(find_hash("sha256"), key, 16, (unsigned char*)"hello", 5, buf[0], &len); len2 = sizeof(buf[0]); hmac_memory_multi(find_hash("sha256"), key, 16, buf[1], &len2, (unsigned char*)"hello", 5UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); hmac_memory_multi(find_hash("sha256"), key, 16, buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); hmac_memory_multi(find_hash("sha256"), key, 16, buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #endif #ifdef LTC_OMAC len = sizeof(buf[0]); omac_memory(find_cipher("aes"), key, 16, (unsigned char*)"hello", 5, buf[0], &len); len2 = sizeof(buf[0]); omac_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"hello", 5UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); omac_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); omac_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #endif #ifdef LTC_PMAC len = sizeof(buf[0]); pmac_memory(find_cipher("aes"), key, 16, (unsigned char*)"hello", 5, buf[0], &len); len2 = sizeof(buf[0]); pmac_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"hello", 5, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); pmac_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); pmac_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #endif #ifdef LTC_XCBC len = sizeof(buf[0]); xcbc_memory(find_cipher("aes"), key, 16, (unsigned char*)"hello", 5, buf[0], &len); len2 = sizeof(buf[0]); xcbc_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"hello", 5, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); xcbc_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); xcbc_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #endif #ifdef LTC_F9 len = sizeof(buf[0]); f9_memory(find_cipher("aes"), key, 16, (unsigned char*)"hello", 5, buf[0], &len); len2 = sizeof(buf[0]); f9_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"hello", 5, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); f9_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); f9_memory_multi(find_cipher("aes"), key, 16, buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #endif #ifdef LTC_PELICAN /* TODO: there is no pelican_memory_multi(..) */ #endif #ifdef LTC_POLY1305 len = sizeof(buf[0]); poly1305_memory(key, 32, (unsigned char*)"hello", 5, buf[0], &len); len2 = sizeof(buf[0]); poly1305_memory_multi(key, 32, buf[1], &len2, (unsigned char*)"hello", 5, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); poly1305_memory_multi(key, 32, buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = sizeof(buf[0]); poly1305_memory_multi(key, 32, buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #endif #ifdef LTC_BLAKE2SMAC len = 32; blake2smac_memory(key, 16, (unsigned char*)"hello", 5, buf[0], &len); len2 = 32; blake2smac_memory_multi(key, 16, buf[1], &len2, (unsigned char*)"hello", 5, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = 32; blake2smac_memory_multi(key, 16, buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = 32; blake2smac_memory_multi(key, 16, buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #endif #ifdef LTC_BLAKE2BMAC len = 64; blake2bmac_memory(key, 16, (unsigned char*)"hello", 5, buf[0], &len); len2 = 64; blake2bmac_memory_multi(key, 16, buf[1], &len2, (unsigned char*)"hello", 5, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = 64; blake2bmac_memory_multi(key, 16, buf[1], &len2, (unsigned char*)"he", 2UL, "llo", 3UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } len2 = 64; blake2bmac_memory_multi(key, 16, buf[1], &len2, (unsigned char*)"h", 1UL, "e", 1UL, "l", 1UL, "l", 1UL, "o", 1UL, NULL); if (len != len2 || memcmp(buf[0], buf[1], len)) { printf("Failed: %d %lu %lu\n", __LINE__, len, len2); return CRYPT_FAIL_TESTVECTOR; } #endif return CRYPT_OK; } /* ref: $Format:%D$ */ /* git commit: $Format:%H$ */ /* commit time: $Format:%ai$ */