TEST_F(WPA2DecryptTest, DecryptCCMPQosUsingBeacon) { Crypto::WPA2Decrypter decrypter; decrypter.add_ap_data("password1", "Testing"); for(size_t i = 0; i < 6; ++i) { RadioTap radio(ccmp_qos_packets[i], ccmp_qos_packets_size[i]); if (i > 4) { ASSERT_TRUE(decrypter.decrypt(radio)); EXPECT_TRUE(radio.find_pdu<ARP>() != 0); } else { ASSERT_FALSE(decrypter.decrypt(radio)); } } }
TEST_F(WPA2DecryptTest, DecryptCCMPUsingBeacon) { Crypto::WPA2Decrypter decrypter; decrypter.add_ap_data("Induction", "Coherer"); for(size_t i = 0; i < 7; ++i) { RadioTap radio(ccmp_packets[i], ccmp_packets_size[i]); if(i > 4) { ASSERT_TRUE(decrypter.decrypt(radio)); if(i == 5) check_ccmp_packet5(radio); else check_ccmp_packet6(radio); } else ASSERT_FALSE(decrypter.decrypt(radio)); } }
TEST_F(WPA2DecryptTest, DecryptTKIPWithoutUsingBeacon) { Crypto::WPA2Decrypter decrypter; decrypter.add_ap_data("libtinstest", "NODO", "00:1b:11:d2:1b:eb"); for(size_t i = 1; i < 7; ++i) { RadioTap radio(tkip_packets[i], tkip_packets_size[i]); if(i > 4) { ASSERT_TRUE(decrypter.decrypt(radio)); if(i == 5) check_tkip_packet5(radio); else check_tkip_packet6(radio); } else ASSERT_FALSE(decrypter.decrypt(radio)); } }
TEST_F(WPA2DecryptTest, DecryptTKIPUsingKey) { Crypto::WPA2Decrypter::addr_pair addresses; Crypto::WPA2::SessionKeys session_keys; { Crypto::WPA2Decrypter decrypter; decrypter.add_ap_data("libtinstest", "NODO", "00:1b:11:d2:1b:eb"); for(size_t i = 1; i < 5; ++i) { RadioTap radio(tkip_packets[i], tkip_packets_size[i]); ASSERT_FALSE(decrypter.decrypt(radio)); } const Crypto::WPA2Decrypter::keys_map& keys = decrypter.get_keys(); ASSERT_EQ(1ULL, keys.size()); addresses = keys.begin()->first; session_keys = keys.begin()->second; } Crypto::WPA2Decrypter decrypter; decrypter.add_decryption_keys(addresses, session_keys); for(size_t i = 5; i < 7; ++i) { RadioTap radio(tkip_packets[i], tkip_packets_size[i]); ASSERT_TRUE(decrypter.decrypt(radio)); if(i == 5) check_tkip_packet5(radio); else check_tkip_packet6(radio); } EXPECT_FALSE(session_keys.uses_ccmp()); }
TEST_F(WPA2DecryptTest, DecryptCCMPUsingKey) { Crypto::WPA2Decrypter::addr_pair addresses; Crypto::WPA2::SessionKeys session_keys; { Crypto::WPA2Decrypter decrypter; decrypter.add_ap_data("Induction", "Coherer", "00:0c:41:82:b2:55"); for(size_t i = 1; i < 5; ++i) { RadioTap radio(ccmp_packets[i], ccmp_packets_size[i]); ASSERT_FALSE(decrypter.decrypt(radio)); } const Crypto::WPA2Decrypter::keys_map& keys = decrypter.get_keys(); ASSERT_EQ(1ULL, keys.size()); addresses = keys.begin()->first; session_keys = keys.begin()->second; } Crypto::WPA2Decrypter decrypter; decrypter.add_decryption_keys(addresses, session_keys); for(size_t i = 5; i < 7; ++i) { RadioTap radio(ccmp_packets[i], ccmp_packets_size[i]); ASSERT_TRUE(decrypter.decrypt(radio)); if(i == 5) check_ccmp_packet5(radio); else check_ccmp_packet6(radio); } EXPECT_TRUE(session_keys.uses_ccmp()); }
TEST_F(WPA2DecryptTest, AccessPointFoundCallback) { using namespace std::placeholders; Crypto::WPA2Decrypter decrypter; decrypter.add_ap_data("libtinstest", "NODO"); decrypter.add_ap_data("Induction", "Coherer"); decrypter.ap_found_callback(std::bind(&WPA2DecryptTest::ap_found, this, _1, _2)); for(size_t i = 0; i < 7; ++i) { RadioTap radio(ccmp_packets[i], ccmp_packets_size[i]); decrypter.decrypt(radio); } for(size_t i = 0; i < 7; ++i) { RadioTap radio(tkip_packets[i], tkip_packets_size[i]); decrypter.decrypt(radio); } ASSERT_EQ(2U, access_points_.size()); ap_data data = access_points_[0]; EXPECT_EQ("Coherer", data.ssid); EXPECT_EQ(address_type("00:0c:41:82:b2:55"), data.bssid); data = access_points_[1]; EXPECT_EQ("NODO", data.ssid); EXPECT_EQ(address_type("00:1b:11:d2:1b:eb"), data.bssid); }
TEST_F(WPA2DecryptTest, HandshakeCapturedCallback) { using namespace std::placeholders; Crypto::WPA2Decrypter decrypter; decrypter.add_ap_data("libtinstest", "NODO", "00:1b:11:d2:1b:eb"); decrypter.add_ap_data("Induction", "Coherer", "00:0c:41:82:b2:55"); decrypter.handshake_captured_callback(std::bind(&WPA2DecryptTest::handshake_captured, this, _1, _2, _3)); for(size_t i = 1; i < 7; ++i) { RadioTap radio(ccmp_packets[i], ccmp_packets_size[i]); decrypter.decrypt(radio); } for(size_t i = 1; i < 7; ++i) { RadioTap radio(tkip_packets[i], tkip_packets_size[i]); decrypter.decrypt(radio); } ASSERT_EQ(2U, handshakes_.size()); handshake hs = handshakes_[0]; EXPECT_EQ(hs.ssid, "Coherer"); EXPECT_EQ(address_type("00:0d:93:82:36:3a"), hs.client_hw); EXPECT_EQ(address_type("00:0c:41:82:b2:55"), hs.bssid); hs = handshakes_[1]; EXPECT_EQ(hs.ssid, "NODO"); EXPECT_EQ(address_type("94:0c:6d:8f:93:88"), hs.client_hw); EXPECT_EQ(address_type("00:1b:11:d2:1b:eb"), hs.bssid); }