/* * Copyright 1999-2020 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the Apache License 2.0 (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ /* test vectors from p1ovect1.txt */ /* * RSA low level APIs are deprecated for public use, but still ok for * internal use. */ #include "internal/deprecated.h" #include #include #include "internal/nelem.h" #include #include #include #include #include "testutil.h" #include #define SetKey \ RSA_set0_key(key, \ BN_bin2bn(n, sizeof(n)-1, NULL), \ BN_bin2bn(e, sizeof(e)-1, NULL), \ BN_bin2bn(d, sizeof(d)-1, NULL)); \ RSA_set0_factors(key, \ BN_bin2bn(p, sizeof(p)-1, NULL), \ BN_bin2bn(q, sizeof(q)-1, NULL)); \ RSA_set0_crt_params(key, \ BN_bin2bn(dmp1, sizeof(dmp1)-1, NULL), \ BN_bin2bn(dmq1, sizeof(dmq1)-1, NULL), \ BN_bin2bn(iqmp, sizeof(iqmp)-1, NULL)); \ if (c != NULL) \ memcpy(c, ctext_ex, sizeof(ctext_ex) - 1); \ return sizeof(ctext_ex) - 1; static int key1(RSA *key, unsigned char *c) { static unsigned char n[] = "\x00\xAA\x36\xAB\xCE\x88\xAC\xFD\xFF\x55\x52\x3C\x7F\xC4\x52\x3F" "\x90\xEF\xA0\x0D\xF3\x77\x4A\x25\x9F\x2E\x62\xB4\xC5\xD9\x9C\xB5" "\xAD\xB3\x00\xA0\x28\x5E\x53\x01\x93\x0E\x0C\x70\xFB\x68\x76\x93" "\x9C\xE6\x16\xCE\x62\x4A\x11\xE0\x08\x6D\x34\x1E\xBC\xAC\xA0\xA1" "\xF5"; static unsigned char e[] = "\x11"; static unsigned char d[] = "\x0A\x03\x37\x48\x62\x64\x87\x69\x5F\x5F\x30\xBC\x38\xB9\x8B\x44" "\xC2\xCD\x2D\xFF\x43\x40\x98\xCD\x20\xD8\xA1\x38\xD0\x90\xBF\x64" "\x79\x7C\x3F\xA7\xA2\xCD\xCB\x3C\xD1\xE0\xBD\xBA\x26\x54\xB4\xF9" "\xDF\x8E\x8A\xE5\x9D\x73\x3D\x9F\x33\xB3\x01\x62\x4A\xFD\x1D\x51"; static unsigned char p[] = "\x00\xD8\x40\xB4\x16\x66\xB4\x2E\x92\xEA\x0D\xA3\xB4\x32\x04\xB5" "\xCF\xCE\x33\x52\x52\x4D\x04\x16\xA5\xA4\x41\xE7\x00\xAF\x46\x12" "\x0D"; static unsigned char q[] = "\x00\xC9\x7F\xB1\xF0\x27\xF4\x53\xF6\x34\x12\x33\xEA\xAA\xD1\xD9" "\x35\x3F\x6C\x42\xD0\x88\x66\xB1\xD0\x5A\x0F\x20\x35\x02\x8B\x9D" "\x89"; static unsigned char dmp1[] = "\x59\x0B\x95\x72\xA2\xC2\xA9\xC4\x06\x05\x9D\xC2\xAB\x2F\x1D\xAF" "\xEB\x7E\x8B\x4F\x10\xA7\x54\x9E\x8E\xED\xF5\xB4\xFC\xE0\x9E\x05"; static unsigned char dmq1[] = "\x00\x8E\x3C\x05\x21\xFE\x15\xE0\xEA\x06\xA3\x6F\xF0\xF1\x0C\x99" "\x52\xC3\x5B\x7A\x75\x14\xFD\x32\x38\xB8\x0A\xAD\x52\x98\x62\x8D" "\x51"; static unsigned char iqmp[] = "\x36\x3F\xF7\x18\x9D\xA8\xE9\x0B\x1D\x34\x1F\x71\xD0\x9B\x76\xA8" "\xA9\x43\xE1\x1D\x10\xB2\x4D\x24\x9F\x2D\xEA\xFE\xF8\x0C\x18\x26"; static unsigned char ctext_ex[] = "\x1b\x8f\x05\xf9\xca\x1a\x79\x52\x6e\x53\xf3\xcc\x51\x4f\xdb\x89" "\x2b\xfb\x91\x93\x23\x1e\x78\xb9\x92\xe6\x8d\x50\xa4\x80\xcb\x52" "\x33\x89\x5c\x74\x95\x8d\x5d\x02\xab\x8c\x0f\xd0\x40\xeb\x58\x44" "\xb0\x05\xc3\x9e\xd8\x27\x4a\x9d\xbf\xa8\x06\x71\x40\x94\x39\xd2"; SetKey; } static int key2(RSA *key, unsigned char *c) { static unsigned char n[] = "\x00\xA3\x07\x9A\x90\xDF\x0D\xFD\x72\xAC\x09\x0C\xCC\x2A\x78\xB8" "\x74\x13\x13\x3E\x40\x75\x9C\x98\xFA\xF8\x20\x4F\x35\x8A\x0B\x26" "\x3C\x67\x70\xE7\x83\xA9\x3B\x69\x71\xB7\x37\x79\xD2\x71\x7B\xE8" "\x34\x77\xCF"; static unsigned char e[] = "\x3"; static unsigned char d[] = "\x6C\xAF\xBC\x60\x94\xB3\xFE\x4C\x72\xB0\xB3\x32\xC6\xFB\x25\xA2" "\xB7\x62\x29\x80\x4E\x68\x65\xFC\xA4\x5A\x74\xDF\x0F\x8F\xB8\x41" "\x3B\x52\xC0\xD0\xE5\x3D\x9B\x59\x0F\xF1\x9B\xE7\x9F\x49\xDD\x21" "\xE5\xEB"; static unsigned char p[] = "\x00\xCF\x20\x35\x02\x8B\x9D\x86\x98\x40\xB4\x16\x66\xB4\x2E\x92" "\xEA\x0D\xA3\xB4\x32\x04\xB5\xCF\xCE\x91"; static unsigned char q[] = "\x00\xC9\x7F\xB1\xF0\x27\xF4\x53\xF6\x34\x12\x33\xEA\xAA\xD1\xD9" "\x35\x3F\x6C\x42\xD0\x88\x66\xB1\xD0\x5F"; static unsigned char dmp1[] = "\x00\x8A\x15\x78\xAC\x5D\x13\xAF\x10\x2B\x22\xB9\x99\xCD\x74\x61" "\xF1\x5E\x6D\x22\xCC\x03\x23\xDF\xDF\x0B"; static unsigned char dmq1[] = "\x00\x86\x55\x21\x4A\xC5\x4D\x8D\x4E\xCD\x61\x77\xF1\xC7\x36\x90" "\xCE\x2A\x48\x2C\x8B\x05\x99\xCB\xE0\x3F"; static unsigned char iqmp[] = "\x00\x83\xEF\xEF\xB8\xA9\xA4\x0D\x1D\xB6\xED\x98\xAD\x84\xED\x13" "\x35\xDC\xC1\x08\xF3\x22\xD0\x57\xCF\x8D"; static unsigned char ctext_ex[] = "\x14\xbd\xdd\x28\xc9\x83\x35\x19\x23\x80\xe8\xe5\x49\xb1\x58\x2a" "\x8b\x40\xb4\x48\x6d\x03\xa6\xa5\x31\x1f\x1f\xd5\xf0\xa1\x80\xe4" "\x17\x53\x03\x29\xa9\x34\x90\x74\xb1\x52\x13\x54\x29\x08\x24\x52" "\x62\x51"; SetKey; } static int key3(RSA *key, unsigned char *c) { static unsigned char n[] = "\x00\xBB\xF8\x2F\x09\x06\x82\xCE\x9C\x23\x38\xAC\x2B\x9D\xA8\x71" "\xF7\x36\x8D\x07\xEE\xD4\x10\x43\xA4\x40\xD6\xB6\xF0\x74\x54\xF5" "\x1F\xB8\xDF\xBA\xAF\x03\x5C\x02\xAB\x61\xEA\x48\xCE\xEB\x6F\xCD" "\x48\x76\xED\x52\x0D\x60\xE1\xEC\x46\x19\x71\x9D\x8A\x5B\x8B\x80" "\x7F\xAF\xB8\xE0\xA3\xDF\xC7\x37\x72\x3E\xE6\xB4\xB7\xD9\x3A\x25" "\x84\xEE\x6A\x64\x9D\x06\x09\x53\x74\x88\x34\xB2\x45\x45\x98\x39" "\x4E\xE0\xAA\xB1\x2D\x7B\x61\xA5\x1F\x52\x7A\x9A\x41\xF6\xC1\x68" "\x7F\xE2\x53\x72\x98\xCA\x2A\x8F\x59\x46\xF8\xE5\xFD\x09\x1D\xBD" "\xCB"; static unsigned char e[] = "\x11"; static unsigned char d[] = "\x00\xA5\xDA\xFC\x53\x41\xFA\xF2\x89\xC4\xB9\x88\xDB\x30\xC1\xCD" "\xF8\x3F\x31\x25\x1E\x06\x68\xB4\x27\x84\x81\x38\x01\x57\x96\x41" "\xB2\x94\x10\xB3\xC7\x99\x8D\x6B\xC4\x65\x74\x5E\x5C\x39\x26\x69" "\xD6\x87\x0D\xA2\xC0\x82\xA9\x39\xE3\x7F\xDC\xB8\x2E\xC9\x3E\xDA" "\xC9\x7F\xF3\xAD\x59\x50\xAC\xCF\xBC\x11\x1C\x76\xF1\xA9\x52\x94" "\x44\xE5\x6A\xAF\x68\xC5\x6C\x09\x2C\xD3\x8D\xC3\xBE\xF5\xD2\x0A" "\x93\x99\x26\xED\x4F\x74\xA1\x3E\xDD\xFB\xE1\xA1\xCE\xCC\x48\x94" "\xAF\x94\x28\xC2\xB7\xB8\x88\x3F\xE4\x46\x3A\x4B\xC8\x5B\x1C\xB3" "\xC1"; static unsigned char p[] = "\x00\xEE\xCF\xAE\x81\xB1\xB9\xB3\xC9\x08\x81\x0B\x10\xA1\xB5\x60" "\x01\x99\xEB\x9F\x44\xAE\xF4\xFD\xA4\x93\xB8\x1A\x9E\x3D\x84\xF6" "\x32\x12\x4E\xF0\x23\x6E\x5D\x1E\x3B\x7E\x28\xFA\xE7\xAA\x04\x0A" "\x2D\x5B\x25\x21\x76\x45\x9D\x1F\x39\x75\x41\xBA\x2A\x58\xFB\x65" "\x99"; static unsigned char q[] = "\x00\xC9\x7F\xB1\xF0\x27\xF4\x53\xF6\x34\x12\x33\xEA\xAA\xD1\xD9" "\x35\x3F\x6C\x42\xD0\x88\x66\xB1\xD0\x5A\x0F\x20\x35\x02\x8B\x9D" "\x86\x98\x40\xB4\x16\x66\xB4\x2E\x92\xEA\x0D\xA3\xB4\x32\x04\xB5" "\xCF\xCE\x33\x52\x52\x4D\x04\x16\xA5\xA4\x41\xE7\x00\xAF\x46\x15" "\x03"; static unsigned char dmp1[] = "\x54\x49\x4C\xA6\x3E\xBA\x03\x37\xE4\xE2\x40\x23\xFC\xD6\x9A\x5A" "\xEB\x07\xDD\xDC\x01\x83\xA4\xD0\xAC\x9B\x54\xB0\x51\xF2\xB1\x3E" "\xD9\x49\x09\x75\xEA\xB7\x74\x14\xFF\x59\xC1\xF7\x69\x2E\x9A\x2E" "\x20\x2B\x38\xFC\x91\x0A\x47\x41\x74\xAD\xC9\x3C\x1F\x67\xC9\x81"; static unsigned char dmq1[] = "\x47\x1E\x02\x90\xFF\x0A\xF0\x75\x03\x51\xB7\xF8\x78\x86\x4C\xA9" "\x61\xAD\xBD\x3A\x8A\x7E\x99\x1C\x5C\x05\x56\xA9\x4C\x31\x46\xA7" "\xF9\x80\x3F\x8F\x6F\x8A\xE3\x42\xE9\x31\xFD\x8A\xE4\x7A\x22\x0D" "\x1B\x99\xA4\x95\x84\x98\x07\xFE\x39\xF9\x24\x5A\x98\x36\xDA\x3D"; static unsigned char iqmp[] = "\x00\xB0\x6C\x4F\xDA\xBB\x63\x01\x19\x8D\x26\x5B\xDB\xAE\x94\x23" "\xB3\x80\xF2\x71\xF7\x34\x53\x88\x50\x93\x07\x7F\xCD\x39\xE2\x11" "\x9F\xC9\x86\x32\x15\x4F\x58\x83\xB1\x67\xA9\x67\xBF\x40\x2B\x4E" "\x9E\x2E\x0F\x96\x56\xE6\x98\xEA\x36\x66\xED\xFB\x25\x79\x80\x39" "\xF7"; static unsigned char ctext_ex[] = "\xb8\x24\x6b\x56\xa6\xed\x58\x81\xae\xb5\x85\xd9\xa2\x5b\x2a\xd7" "\x90\xc4\x17\xe0\x80\x68\x1b\xf1\xac\x2b\xc3\xde\xb6\x9d\x8b\xce" "\xf0\xc4\x36\x6f\xec\x40\x0a\xf0\x52\xa7\x2e\x9b\x0e\xff\xb5\xb3" "\xf2\xf1\x92\xdb\xea\xca\x03\xc1\x27\x40\x05\x71\x13\xbf\x1f\x06" "\x69\xac\x22\xe9\xf3\xa7\x85\x2e\x3c\x15\xd9\x13\xca\xb0\xb8\x86" "\x3a\x95\xc9\x92\x94\xce\x86\x74\x21\x49\x54\x61\x03\x46\xf4\xd4" "\x74\xb2\x6f\x7c\x48\xb4\x2e\xe6\x8e\x1f\x57\x2a\x1f\xc4\x02\x6a" "\xc4\x56\xb4\xf5\x9f\x7b\x62\x1e\xa1\xb9\xd8\x8f\x64\x20\x2f\xb1"; SetKey; } static int rsa_setkey(RSA** key, unsigned char *ctext, int idx) { int clen = 0; *key = RSA_new(); if (*key != NULL) switch (idx) { case 0: clen = key1(*key, ctext); break; case 1: clen = key2(*key, ctext); break; case 2: clen = key3(*key, ctext); break; } return clen; } static int test_rsa_simple(int idx, int en_pad_type, int de_pad_type, int success, unsigned char *ctext_ex, int *clen, RSA **retkey) { int ret = 0; RSA *key; unsigned char ptext[256]; unsigned char ctext[256]; static unsigned char ptext_ex[] = "\x54\x85\x9b\x34\x2c\x49\xea\x2a"; int plen; int clentmp = 0; int num; plen = sizeof(ptext_ex) - 1; clentmp = rsa_setkey(&key, ctext_ex, idx); if (clen != NULL) *clen = clentmp; num = RSA_public_encrypt(plen, ptext_ex, ctext, key, en_pad_type); if (!TEST_int_eq(num, clentmp)) goto err; num = RSA_private_decrypt(num, ctext, ptext, key, de_pad_type); if (success) { if (!TEST_int_gt(num, 0) || !TEST_mem_eq(ptext, num, ptext_ex, plen)) goto err; } else { if (!TEST_int_lt(num, 0)) goto err; } ret = 1; if (retkey != NULL) { *retkey = key; key = NULL; } err: RSA_free(key); return ret; } static int test_rsa_pkcs1(int idx) { return test_rsa_simple(idx, RSA_PKCS1_PADDING, RSA_PKCS1_PADDING, 1, NULL, NULL, NULL); } static int test_rsa_sslv23(int idx) { int ret; /* Simulate an SSLv2 only client talking to a TLS capable server */ ret = test_rsa_simple(idx, RSA_PKCS1_PADDING, RSA_SSLV23_PADDING, 1, NULL, NULL, NULL); /* Simulate a TLS capable client talking to an SSLv2 only server */ ret &= test_rsa_simple(idx, RSA_SSLV23_PADDING, RSA_PKCS1_PADDING, 1, NULL, NULL, NULL); /* * Simulate a TLS capable client talking to a TLS capable server. Should * fail due to detecting a rollback attack. */ ret &= test_rsa_simple(idx, RSA_SSLV23_PADDING, RSA_SSLV23_PADDING, 0, NULL, NULL, NULL); return ret; } static int test_rsa_oaep(int idx) { int ret = 0; RSA *key = NULL; unsigned char ptext[256]; unsigned char ctext[256]; static unsigned char ptext_ex[] = "\x54\x85\x9b\x34\x2c\x49\xea\x2a"; unsigned char ctext_ex[256]; int plen; int clen = 0; int num; int n; if (!test_rsa_simple(idx, RSA_PKCS1_OAEP_PADDING, RSA_PKCS1_OAEP_PADDING, 1, ctext_ex, &clen, &key)) goto err; plen = sizeof(ptext_ex) - 1; /* Different ciphertexts. Try decrypting ctext_ex */ num = RSA_private_decrypt(clen, ctext_ex, ptext, key, RSA_PKCS1_OAEP_PADDING); if (num <= 0 || !TEST_mem_eq(ptext, num, ptext_ex, plen)) goto err; /* Try decrypting corrupted ciphertexts. */ for (n = 0; n < clen; ++n) { ctext[n] ^= 1; num = RSA_private_decrypt(clen, ctext, ptext, key, RSA_PKCS1_OAEP_PADDING); if (!TEST_int_le(num, 0)) goto err; ctext[n] ^= 1; } /* Test truncated ciphertexts, as well as negative length. */ for (n = -1; n < clen; ++n) { num = RSA_private_decrypt(n, ctext, ptext, key, RSA_PKCS1_OAEP_PADDING); if (!TEST_int_le(num, 0)) goto err; } ret = 1; err: RSA_free(key); return ret; } static const struct { int bits; unsigned int r; } rsa_security_bits_cases[] = { /* NIST SP 800-56B rev 2 (draft) Appendix D Table 5 */ { 2048, 112 }, { 3072, 128 }, { 4096, 152 }, { 6144, 176 }, { 8192, 200 }, /* Older values */ { 256, 40 }, { 512, 56 }, { 1024, 80 }, /* Slightly different value to the 256 that NIST lists in their tables */ { 15360, 264 }, /* Some other values */ { 8888, 208 }, { 2468, 120 }, { 13456, 248 } }; static int test_rsa_security_bit(int n) { static const unsigned char vals[8] = { 0x80, 0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40 }; RSA *key = RSA_new(); const int bits = rsa_security_bits_cases[n].bits; const int result = rsa_security_bits_cases[n].r; const int bytes = (bits + 7) / 8; int r = 0; unsigned char num[2000]; if (!TEST_ptr(key) || !TEST_int_le(bytes, (int)sizeof(num))) goto err; /* * It is necessary to set the RSA key in order to ask for the strength. * A BN of an appropriate size is created, in general it won't have the * properties necessary for RSA to function. This is okay here since * the RSA key is never used. */ memset(num, vals[bits % 8], bytes); /* * The 'e' parameter is set to the same value as 'n'. This saves having * an extra BN to hold a sensible value for 'e'. This is safe since the * RSA key is not used. The 'd' parameter can be NULL safely. */ if (TEST_true(RSA_set0_key(key, BN_bin2bn(num, bytes, NULL), BN_bin2bn(num, bytes, NULL), NULL)) && TEST_uint_eq(RSA_security_bits(key), result)) r = 1; err: RSA_free(key); return r; } int setup_tests(void) { ADD_ALL_TESTS(test_rsa_pkcs1, 3); ADD_ALL_TESTS(test_rsa_sslv23, 3); ADD_ALL_TESTS(test_rsa_oaep, 3); ADD_ALL_TESTS(test_rsa_security_bit, OSSL_NELEM(rsa_security_bits_cases)); return 1; }