// Copyright (c) 2012-2022 The Bitcoin Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace std::literals; using node::NodeContext; using util::ToString; static NetGroupManager EMPTY_NETGROUPMAN{std::vector()}; static const bool DETERMINISTIC{true}; static int32_t GetCheckRatio(const NodeContext& node_ctx) { return std::clamp(node_ctx.args->GetIntArg("-checkaddrman", 100), 0, 1000000); } static CNetAddr ResolveIP(const std::string& ip) { const std::optional addr{LookupHost(ip, false)}; BOOST_CHECK_MESSAGE(addr.has_value(), strprintf("failed to resolve: %s", ip)); return addr.value_or(CNetAddr{}); } static CService ResolveService(const std::string& ip, uint16_t port = 0) { const std::optional serv{Lookup(ip, port, false)}; BOOST_CHECK_MESSAGE(serv.has_value(), strprintf("failed to resolve: %s:%i", ip, port)); return serv.value_or(CService{}); } static std::vector FromBytes(std::span source) { int vector_size(source.size() * 8); std::vector result(vector_size); for (int byte_i = 0; byte_i < vector_size / 8; ++byte_i) { uint8_t cur_byte{std::to_integer(source[byte_i])}; for (int bit_i = 0; bit_i < 8; ++bit_i) { result[byte_i * 8 + bit_i] = (cur_byte >> bit_i) & 1; } } return result; } BOOST_FIXTURE_TEST_SUITE(addrman_tests, BasicTestingSetup) BOOST_AUTO_TEST_CASE(addrman_simple) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); CNetAddr source = ResolveIP("252.2.2.2"); // Test: Does Addrman respond correctly when empty. BOOST_CHECK_EQUAL(addrman->Size(), 0U); auto addr_null = addrman->Select().first; BOOST_CHECK_EQUAL(addr_null.ToStringAddrPort(), "[::]:0"); // Test: Does Addrman::Add work as expected. CService addr1 = ResolveService("250.1.1.1", 8333); BOOST_CHECK(addrman->Add({CAddress(addr1, NODE_NONE)}, source)); BOOST_CHECK_EQUAL(addrman->Size(), 1U); auto addr_ret1 = addrman->Select().first; BOOST_CHECK_EQUAL(addr_ret1.ToStringAddrPort(), "250.1.1.1:8333"); // Test: Does IP address deduplication work correctly. // Expected dup IP should not be added. CService addr1_dup = ResolveService("250.1.1.1", 8333); BOOST_CHECK(!addrman->Add({CAddress(addr1_dup, NODE_NONE)}, source)); BOOST_CHECK_EQUAL(addrman->Size(), 1U); // Test: New table has one addr and we add a diff addr we should // have at least one addr. // Note that addrman's size cannot be tested reliably after insertion, as // hash collisions may occur. But we can always be sure of at least one // success. CService addr2 = ResolveService("250.1.1.2", 8333); BOOST_CHECK(addrman->Add({CAddress(addr2, NODE_NONE)}, source)); BOOST_CHECK(addrman->Size() >= 1); // Test: reset addrman and test AddrMan::Add multiple addresses works as expected addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); std::vector vAddr; vAddr.emplace_back(ResolveService("250.1.1.3", 8333), NODE_NONE); vAddr.emplace_back(ResolveService("250.1.1.4", 8333), NODE_NONE); BOOST_CHECK(addrman->Add(vAddr, source)); BOOST_CHECK(addrman->Size() >= 1); } BOOST_AUTO_TEST_CASE(addrman_ports) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); CNetAddr source = ResolveIP("252.2.2.2"); BOOST_CHECK_EQUAL(addrman->Size(), 0U); // Test 7; Addr with same IP but diff port does not replace existing addr. CService addr1 = ResolveService("250.1.1.1", 8333); BOOST_CHECK(addrman->Add({CAddress(addr1, NODE_NONE)}, source)); BOOST_CHECK_EQUAL(addrman->Size(), 1U); CService addr1_port = ResolveService("250.1.1.1", 8334); BOOST_CHECK(addrman->Add({CAddress(addr1_port, NODE_NONE)}, source)); BOOST_CHECK_EQUAL(addrman->Size(), 2U); auto addr_ret2 = addrman->Select().first; BOOST_CHECK(addr_ret2.ToStringAddrPort() == "250.1.1.1:8333" || addr_ret2.ToStringAddrPort() == "250.1.1.1:8334"); // Test: Add same IP but diff port to tried table; this converts the entry with // the specified port to tried, but not the other. addrman->Good(CAddress(addr1_port, NODE_NONE)); BOOST_CHECK_EQUAL(addrman->Size(), 2U); bool new_only = true; auto addr_ret3 = addrman->Select(new_only).first; BOOST_CHECK_EQUAL(addr_ret3.ToStringAddrPort(), "250.1.1.1:8333"); } BOOST_AUTO_TEST_CASE(addrman_select) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); BOOST_CHECK(!addrman->Select(false).first.IsValid()); BOOST_CHECK(!addrman->Select(true).first.IsValid()); CNetAddr source = ResolveIP("252.2.2.2"); // Add 1 address to the new table CService addr1 = ResolveService("250.1.1.1", 8333); BOOST_CHECK(addrman->Add({CAddress(addr1, NODE_NONE)}, source)); BOOST_CHECK_EQUAL(addrman->Size(), 1U); BOOST_CHECK(addrman->Select(/*new_only=*/true).first == addr1); BOOST_CHECK(addrman->Select(/*new_only=*/false).first == addr1); // Move address to the tried table BOOST_CHECK(addrman->Good(CAddress(addr1, NODE_NONE))); BOOST_CHECK_EQUAL(addrman->Size(), 1U); BOOST_CHECK(!addrman->Select(/*new_only=*/true).first.IsValid()); BOOST_CHECK(addrman->Select().first == addr1); BOOST_CHECK_EQUAL(addrman->Size(), 1U); // Add one address to the new table CService addr2 = ResolveService("250.3.1.1", 8333); BOOST_CHECK(addrman->Add({CAddress(addr2, NODE_NONE)}, addr2)); BOOST_CHECK(addrman->Select(/*new_only=*/true).first == addr2); // Add two more addresses to the new table CService addr3 = ResolveService("250.3.2.2", 9999); CService addr4 = ResolveService("250.3.3.3", 9999); BOOST_CHECK(addrman->Add({CAddress(addr3, NODE_NONE)}, addr2)); BOOST_CHECK(addrman->Add({CAddress(addr4, NODE_NONE)}, ResolveService("250.4.1.1", 8333))); // Add three addresses to tried table. CService addr5 = ResolveService("250.4.4.4", 8333); CService addr6 = ResolveService("250.4.5.5", 7777); CService addr7 = ResolveService("250.4.6.6", 8333); BOOST_CHECK(addrman->Add({CAddress(addr5, NODE_NONE)}, addr3)); BOOST_CHECK(addrman->Good(CAddress(addr5, NODE_NONE))); BOOST_CHECK(addrman->Add({CAddress(addr6, NODE_NONE)}, addr3)); BOOST_CHECK(addrman->Good(CAddress(addr6, NODE_NONE))); BOOST_CHECK(addrman->Add({CAddress(addr7, NODE_NONE)}, ResolveService("250.1.1.3", 8333))); BOOST_CHECK(addrman->Good(CAddress(addr7, NODE_NONE))); // 6 addrs + 1 addr from last test = 7. BOOST_CHECK_EQUAL(addrman->Size(), 7U); // Select pulls from new and tried regardless of port number. std::set ports; for (int i = 0; i < 20; ++i) { ports.insert(addrman->Select().first.GetPort()); } BOOST_CHECK_EQUAL(ports.size(), 3U); } BOOST_AUTO_TEST_CASE(addrman_select_by_network) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); BOOST_CHECK(!addrman->Select(/*new_only=*/true, {NET_IPV4}).first.IsValid()); BOOST_CHECK(!addrman->Select(/*new_only=*/false, {NET_IPV4}).first.IsValid()); // add ipv4 address to the new table CNetAddr source = ResolveIP("252.2.2.2"); CService addr1 = ResolveService("250.1.1.1", 8333); BOOST_CHECK(addrman->Add({CAddress(addr1, NODE_NONE)}, source)); BOOST_CHECK(addrman->Select(/*new_only=*/true, {NET_IPV4}).first == addr1); BOOST_CHECK(addrman->Select(/*new_only=*/false, {NET_IPV4}).first == addr1); BOOST_CHECK(!addrman->Select(/*new_only=*/false, {NET_IPV6}).first.IsValid()); BOOST_CHECK(!addrman->Select(/*new_only=*/false, {NET_ONION}).first.IsValid()); BOOST_CHECK(!addrman->Select(/*new_only=*/false, {NET_I2P}).first.IsValid()); BOOST_CHECK(!addrman->Select(/*new_only=*/false, {NET_CJDNS}).first.IsValid()); BOOST_CHECK(!addrman->Select(/*new_only=*/true, {NET_CJDNS}).first.IsValid()); BOOST_CHECK(addrman->Select(/*new_only=*/false).first == addr1); // add I2P address to the new table CAddress i2p_addr; i2p_addr.SetSpecial("udhdrtrcetjm5sxzskjyr5ztpeszydbh4dpl3pl4utgqqw2v4jna.b32.i2p"); BOOST_CHECK(addrman->Add({i2p_addr}, source)); BOOST_CHECK(addrman->Select(/*new_only=*/true, {NET_I2P}).first == i2p_addr); BOOST_CHECK(addrman->Select(/*new_only=*/false, {NET_I2P}).first == i2p_addr); BOOST_CHECK(addrman->Select(/*new_only=*/false, {NET_IPV4}).first == addr1); std::unordered_set nets_with_entries = {NET_IPV4, NET_I2P}; BOOST_CHECK(addrman->Select(/*new_only=*/false, nets_with_entries).first.IsValid()); BOOST_CHECK(!addrman->Select(/*new_only=*/false, {NET_IPV6}).first.IsValid()); BOOST_CHECK(!addrman->Select(/*new_only=*/false, {NET_ONION}).first.IsValid()); BOOST_CHECK(!addrman->Select(/*new_only=*/false, {NET_CJDNS}).first.IsValid()); std::unordered_set nets_without_entries = {NET_IPV6, NET_ONION, NET_CJDNS}; BOOST_CHECK(!addrman->Select(/*new_only=*/false, nets_without_entries).first.IsValid()); // bump I2P address to tried table BOOST_CHECK(addrman->Good(i2p_addr)); BOOST_CHECK(!addrman->Select(/*new_only=*/true, {NET_I2P}).first.IsValid()); BOOST_CHECK(addrman->Select(/*new_only=*/false, {NET_I2P}).first == i2p_addr); // add another I2P address to the new table CAddress i2p_addr2; i2p_addr2.SetSpecial("c4gfnttsuwqomiygupdqqqyy5y5emnk5c73hrfvatri67prd7vyq.b32.i2p"); BOOST_CHECK(addrman->Add({i2p_addr2}, source)); BOOST_CHECK(addrman->Select(/*new_only=*/true, {NET_I2P}).first == i2p_addr2); // ensure that both new and tried table are selected from bool new_selected{false}; bool tried_selected{false}; int counter = 256; while (--counter > 0 && (!new_selected || !tried_selected)) { const CAddress selected{addrman->Select(/*new_only=*/false, {NET_I2P}).first}; BOOST_REQUIRE(selected == i2p_addr || selected == i2p_addr2); if (selected == i2p_addr) { tried_selected = true; } else { new_selected = true; } } BOOST_CHECK(new_selected); BOOST_CHECK(tried_selected); } BOOST_AUTO_TEST_CASE(addrman_select_special) { // use a non-deterministic addrman to ensure a passing test isn't due to setup auto addrman = std::make_unique(EMPTY_NETGROUPMAN, /*deterministic=*/false, GetCheckRatio(m_node)); CNetAddr source = ResolveIP("252.2.2.2"); // add I2P address to the tried table CAddress i2p_addr; i2p_addr.SetSpecial("udhdrtrcetjm5sxzskjyr5ztpeszydbh4dpl3pl4utgqqw2v4jna.b32.i2p"); BOOST_CHECK(addrman->Add({i2p_addr}, source)); BOOST_CHECK(addrman->Good(i2p_addr)); // add ipv4 address to the new table CService addr1 = ResolveService("250.1.1.3", 8333); BOOST_CHECK(addrman->Add({CAddress(addr1, NODE_NONE)}, source)); // since the only ipv4 address is on the new table, ensure that the new // table gets selected even if new_only is false. if the table was being // selected at random, this test will sporadically fail BOOST_CHECK(addrman->Select(/*new_only=*/false, {NET_IPV4}).first == addr1); } BOOST_AUTO_TEST_CASE(addrman_new_collisions) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); CNetAddr source = ResolveIP("252.2.2.2"); uint32_t num_addrs{0}; BOOST_CHECK_EQUAL(addrman->Size(), num_addrs); while (num_addrs < 22) { // Magic number! 250.1.1.1 - 250.1.1.22 do not collide with deterministic key = 1 CService addr = ResolveService("250.1.1." + ToString(++num_addrs)); BOOST_CHECK(addrman->Add({CAddress(addr, NODE_NONE)}, source)); // Test: No collision in new table yet. BOOST_CHECK_EQUAL(addrman->Size(), num_addrs); } // Test: new table collision! CService addr1 = ResolveService("250.1.1." + ToString(++num_addrs)); uint32_t collisions{1}; BOOST_CHECK(addrman->Add({CAddress(addr1, NODE_NONE)}, source)); BOOST_CHECK_EQUAL(addrman->Size(), num_addrs - collisions); CService addr2 = ResolveService("250.1.1." + ToString(++num_addrs)); BOOST_CHECK(addrman->Add({CAddress(addr2, NODE_NONE)}, source)); BOOST_CHECK_EQUAL(addrman->Size(), num_addrs - collisions); } BOOST_AUTO_TEST_CASE(addrman_new_multiplicity) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); CAddress addr{CAddress(ResolveService("253.3.3.3", 8333), NODE_NONE)}; const auto start_time{Now()}; addr.nTime = start_time; // test that multiplicity stays at 1 if nTime doesn't increase for (unsigned int i = 1; i < 20; ++i) { std::string addr_ip{ToString(i % 256) + "." + ToString(i >> 8 % 256) + ".1.1"}; CNetAddr source{ResolveIP(addr_ip)}; addrman->Add({addr}, source); } AddressPosition addr_pos = addrman->FindAddressEntry(addr).value(); BOOST_CHECK_EQUAL(addr_pos.multiplicity, 1U); BOOST_CHECK_EQUAL(addrman->Size(), 1U); // if nTime increases, an addr can occur in up to 8 buckets // The acceptance probability decreases exponentially with existing multiplicity - // choose number of iterations such that it gets to 8 with deterministic addrman. for (unsigned int i = 1; i < 400; ++i) { std::string addr_ip{ToString(i % 256) + "." + ToString(i >> 8 % 256) + ".1.1"}; CNetAddr source{ResolveIP(addr_ip)}; addr.nTime = start_time + std::chrono::seconds{i}; addrman->Add({addr}, source); } AddressPosition addr_pos_multi = addrman->FindAddressEntry(addr).value(); BOOST_CHECK_EQUAL(addr_pos_multi.multiplicity, 8U); // multiplicity doesn't affect size BOOST_CHECK_EQUAL(addrman->Size(), 1U); } BOOST_AUTO_TEST_CASE(addrman_tried_collisions) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); CNetAddr source = ResolveIP("252.2.2.2"); uint32_t num_addrs{0}; BOOST_CHECK_EQUAL(addrman->Size(), num_addrs); while (num_addrs < 35) { // Magic number! 250.1.1.1 - 250.1.1.35 do not collide in tried with deterministic key = 1 CService addr = ResolveService("250.1.1." + ToString(++num_addrs)); BOOST_CHECK(addrman->Add({CAddress(addr, NODE_NONE)}, source)); // Test: Add to tried without collision BOOST_CHECK(addrman->Good(CAddress(addr, NODE_NONE))); } // Test: Unable to add to tried table due to collision! CService addr1 = ResolveService("250.1.1." + ToString(++num_addrs)); BOOST_CHECK(addrman->Add({CAddress(addr1, NODE_NONE)}, source)); BOOST_CHECK(!addrman->Good(CAddress(addr1, NODE_NONE))); // Test: Add the next address to tried without collision CService addr2 = ResolveService("250.1.1." + ToString(++num_addrs)); BOOST_CHECK(addrman->Add({CAddress(addr2, NODE_NONE)}, source)); BOOST_CHECK(addrman->Good(CAddress(addr2, NODE_NONE))); } BOOST_AUTO_TEST_CASE(addrman_getaddr) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); // Test: Sanity check, GetAddr should never return anything if addrman // is empty. BOOST_CHECK_EQUAL(addrman->Size(), 0U); std::vector vAddr1 = addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt); BOOST_CHECK_EQUAL(vAddr1.size(), 0U); CAddress addr1 = CAddress(ResolveService("250.250.2.1", 8333), NODE_NONE); addr1.nTime = Now(); // Set time so isTerrible = false CAddress addr2 = CAddress(ResolveService("250.251.2.2", 9999), NODE_NONE); addr2.nTime = Now(); CAddress addr3 = CAddress(ResolveService("251.252.2.3", 8333), NODE_NONE); addr3.nTime = Now(); CAddress addr4 = CAddress(ResolveService("252.253.3.4", 8333), NODE_NONE); addr4.nTime = Now(); CAddress addr5 = CAddress(ResolveService("252.254.4.5", 8333), NODE_NONE); addr5.nTime = Now(); CNetAddr source1 = ResolveIP("250.1.2.1"); CNetAddr source2 = ResolveIP("250.2.3.3"); // Test: Ensure GetAddr works with new addresses. BOOST_CHECK(addrman->Add({addr1, addr3, addr5}, source1)); BOOST_CHECK(addrman->Add({addr2, addr4}, source2)); BOOST_CHECK_EQUAL(addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt).size(), 5U); // Net processing asks for 23% of addresses. 23% of 5 is 1 rounded down. BOOST_CHECK_EQUAL(addrman->GetAddr(/*max_addresses=*/2500, /*max_pct=*/23, /*network=*/std::nullopt).size(), 1U); // Test: Ensure GetAddr works with new and tried addresses. BOOST_CHECK(addrman->Good(CAddress(addr1, NODE_NONE))); BOOST_CHECK(addrman->Good(CAddress(addr2, NODE_NONE))); BOOST_CHECK_EQUAL(addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt).size(), 5U); BOOST_CHECK_EQUAL(addrman->GetAddr(/*max_addresses=*/2500, /*max_pct=*/23, /*network=*/std::nullopt).size(), 1U); // Test: Ensure GetAddr still returns 23% when addrman has many addrs. for (unsigned int i = 1; i < (8 * 256); i++) { int octet1 = i % 256; int octet2 = i >> 8 % 256; std::string strAddr = ToString(octet1) + "." + ToString(octet2) + ".1.23"; CAddress addr = CAddress(ResolveService(strAddr), NODE_NONE); // Ensure that for all addrs in addrman, isTerrible == false. addr.nTime = Now(); addrman->Add({addr}, ResolveIP(strAddr)); if (i % 8 == 0) addrman->Good(addr); } std::vector vAddr = addrman->GetAddr(/*max_addresses=*/2500, /*max_pct=*/23, /*network=*/std::nullopt); size_t percent23 = (addrman->Size() * 23) / 100; BOOST_CHECK_EQUAL(vAddr.size(), percent23); BOOST_CHECK_EQUAL(vAddr.size(), 461U); // (addrman.Size() < number of addresses added) due to address collisions. BOOST_CHECK_EQUAL(addrman->Size(), 2006U); } BOOST_AUTO_TEST_CASE(getaddr_unfiltered) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); // Set time on this addr so isTerrible = false CAddress addr1 = CAddress(ResolveService("250.250.2.1", 8333), NODE_NONE); addr1.nTime = Now(); // Not setting time so this addr should be isTerrible = true CAddress addr2 = CAddress(ResolveService("250.251.2.2", 9999), NODE_NONE); CNetAddr source = ResolveIP("250.1.2.1"); BOOST_CHECK(addrman->Add({addr1, addr2}, source)); // Filtered GetAddr should only return addr1 BOOST_CHECK_EQUAL(addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt).size(), 1U); // Unfiltered GetAddr should return addr1 and addr2 BOOST_CHECK_EQUAL(addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt, /*filtered=*/false).size(), 2U); } BOOST_AUTO_TEST_CASE(caddrinfo_get_tried_bucket_legacy) { CAddress addr1 = CAddress(ResolveService("250.1.1.1", 8333), NODE_NONE); CAddress addr2 = CAddress(ResolveService("250.1.1.1", 9999), NODE_NONE); CNetAddr source1 = ResolveIP("250.1.1.1"); AddrInfo info1 = AddrInfo(addr1, source1); uint256 nKey1 = (HashWriter{} << 1).GetHash(); uint256 nKey2 = (HashWriter{} << 2).GetHash(); BOOST_CHECK_EQUAL(info1.GetTriedBucket(nKey1, EMPTY_NETGROUPMAN), 40); // Test: Make sure key actually randomizes bucket placement. A fail on // this test could be a security issue. BOOST_CHECK(info1.GetTriedBucket(nKey1, EMPTY_NETGROUPMAN) != info1.GetTriedBucket(nKey2, EMPTY_NETGROUPMAN)); // Test: Two addresses with same IP but different ports can map to // different buckets because they have different keys. AddrInfo info2 = AddrInfo(addr2, source1); BOOST_CHECK(info1.GetKey() != info2.GetKey()); BOOST_CHECK(info1.GetTriedBucket(nKey1, EMPTY_NETGROUPMAN) != info2.GetTriedBucket(nKey1, EMPTY_NETGROUPMAN)); std::set buckets; for (int i = 0; i < 255; i++) { AddrInfo infoi = AddrInfo( CAddress(ResolveService("250.1.1." + ToString(i)), NODE_NONE), ResolveIP("250.1.1." + ToString(i))); int bucket = infoi.GetTriedBucket(nKey1, EMPTY_NETGROUPMAN); buckets.insert(bucket); } // Test: IP addresses in the same /16 prefix should // never get more than 8 buckets with legacy grouping BOOST_CHECK_EQUAL(buckets.size(), 8U); buckets.clear(); for (int j = 0; j < 255; j++) { AddrInfo infoj = AddrInfo( CAddress(ResolveService("250." + ToString(j) + ".1.1"), NODE_NONE), ResolveIP("250." + ToString(j) + ".1.1")); int bucket = infoj.GetTriedBucket(nKey1, EMPTY_NETGROUPMAN); buckets.insert(bucket); } // Test: IP addresses in the different /16 prefix should map to more than // 8 buckets with legacy grouping BOOST_CHECK_EQUAL(buckets.size(), 160U); } BOOST_AUTO_TEST_CASE(caddrinfo_get_new_bucket_legacy) { CAddress addr1 = CAddress(ResolveService("250.1.2.1", 8333), NODE_NONE); CAddress addr2 = CAddress(ResolveService("250.1.2.1", 9999), NODE_NONE); CNetAddr source1 = ResolveIP("250.1.2.1"); AddrInfo info1 = AddrInfo(addr1, source1); uint256 nKey1 = (HashWriter{} << 1).GetHash(); uint256 nKey2 = (HashWriter{} << 2).GetHash(); // Test: Make sure the buckets are what we expect BOOST_CHECK_EQUAL(info1.GetNewBucket(nKey1, EMPTY_NETGROUPMAN), 786); BOOST_CHECK_EQUAL(info1.GetNewBucket(nKey1, source1, EMPTY_NETGROUPMAN), 786); // Test: Make sure key actually randomizes bucket placement. A fail on // this test could be a security issue. BOOST_CHECK(info1.GetNewBucket(nKey1, EMPTY_NETGROUPMAN) != info1.GetNewBucket(nKey2, EMPTY_NETGROUPMAN)); // Test: Ports should not affect bucket placement in the addr AddrInfo info2 = AddrInfo(addr2, source1); BOOST_CHECK(info1.GetKey() != info2.GetKey()); BOOST_CHECK_EQUAL(info1.GetNewBucket(nKey1, EMPTY_NETGROUPMAN), info2.GetNewBucket(nKey1, EMPTY_NETGROUPMAN)); std::set buckets; for (int i = 0; i < 255; i++) { AddrInfo infoi = AddrInfo( CAddress(ResolveService("250.1.1." + ToString(i)), NODE_NONE), ResolveIP("250.1.1." + ToString(i))); int bucket = infoi.GetNewBucket(nKey1, EMPTY_NETGROUPMAN); buckets.insert(bucket); } // Test: IP addresses in the same group (\16 prefix for IPv4) should // always map to the same bucket. BOOST_CHECK_EQUAL(buckets.size(), 1U); buckets.clear(); for (int j = 0; j < 4 * 255; j++) { AddrInfo infoj = AddrInfo(CAddress( ResolveService( ToString(250 + (j / 255)) + "." + ToString(j % 256) + ".1.1"), NODE_NONE), ResolveIP("251.4.1.1")); int bucket = infoj.GetNewBucket(nKey1, EMPTY_NETGROUPMAN); buckets.insert(bucket); } // Test: IP addresses in the same source groups should map to NO MORE // than 64 buckets. BOOST_CHECK(buckets.size() <= 64); buckets.clear(); for (int p = 0; p < 255; p++) { AddrInfo infoj = AddrInfo( CAddress(ResolveService("250.1.1.1"), NODE_NONE), ResolveIP("250." + ToString(p) + ".1.1")); int bucket = infoj.GetNewBucket(nKey1, EMPTY_NETGROUPMAN); buckets.insert(bucket); } // Test: IP addresses in the different source groups should map to MORE // than 64 buckets. BOOST_CHECK(buckets.size() > 64); } // The following three test cases use asmap.raw // We use an artificial minimal mock mapping // 250.0.0.0/8 AS1000 // 101.1.0.0/16 AS1 // 101.2.0.0/16 AS2 // 101.3.0.0/16 AS3 // 101.4.0.0/16 AS4 // 101.5.0.0/16 AS5 // 101.6.0.0/16 AS6 // 101.7.0.0/16 AS7 // 101.8.0.0/16 AS8 BOOST_AUTO_TEST_CASE(caddrinfo_get_tried_bucket) { std::vector asmap = FromBytes(test::data::asmap); NetGroupManager ngm_asmap{asmap}; CAddress addr1 = CAddress(ResolveService("250.1.1.1", 8333), NODE_NONE); CAddress addr2 = CAddress(ResolveService("250.1.1.1", 9999), NODE_NONE); CNetAddr source1 = ResolveIP("250.1.1.1"); AddrInfo info1 = AddrInfo(addr1, source1); uint256 nKey1 = (HashWriter{} << 1).GetHash(); uint256 nKey2 = (HashWriter{} << 2).GetHash(); BOOST_CHECK_EQUAL(info1.GetTriedBucket(nKey1, ngm_asmap), 236); // Test: Make sure key actually randomizes bucket placement. A fail on // this test could be a security issue. BOOST_CHECK(info1.GetTriedBucket(nKey1, ngm_asmap) != info1.GetTriedBucket(nKey2, ngm_asmap)); // Test: Two addresses with same IP but different ports can map to // different buckets because they have different keys. AddrInfo info2 = AddrInfo(addr2, source1); BOOST_CHECK(info1.GetKey() != info2.GetKey()); BOOST_CHECK(info1.GetTriedBucket(nKey1, ngm_asmap) != info2.GetTriedBucket(nKey1, ngm_asmap)); std::set buckets; for (int j = 0; j < 255; j++) { AddrInfo infoj = AddrInfo( CAddress(ResolveService("101." + ToString(j) + ".1.1"), NODE_NONE), ResolveIP("101." + ToString(j) + ".1.1")); int bucket = infoj.GetTriedBucket(nKey1, ngm_asmap); buckets.insert(bucket); } // Test: IP addresses in the different /16 prefix MAY map to more than // 8 buckets. BOOST_CHECK(buckets.size() > 8); buckets.clear(); for (int j = 0; j < 255; j++) { AddrInfo infoj = AddrInfo( CAddress(ResolveService("250." + ToString(j) + ".1.1"), NODE_NONE), ResolveIP("250." + ToString(j) + ".1.1")); int bucket = infoj.GetTriedBucket(nKey1, ngm_asmap); buckets.insert(bucket); } // Test: IP addresses in the different /16 prefix MAY NOT map to more than // 8 buckets. BOOST_CHECK(buckets.size() == 8); } BOOST_AUTO_TEST_CASE(caddrinfo_get_new_bucket) { std::vector asmap = FromBytes(test::data::asmap); NetGroupManager ngm_asmap{asmap}; CAddress addr1 = CAddress(ResolveService("250.1.2.1", 8333), NODE_NONE); CAddress addr2 = CAddress(ResolveService("250.1.2.1", 9999), NODE_NONE); CNetAddr source1 = ResolveIP("250.1.2.1"); AddrInfo info1 = AddrInfo(addr1, source1); uint256 nKey1 = (HashWriter{} << 1).GetHash(); uint256 nKey2 = (HashWriter{} << 2).GetHash(); // Test: Make sure the buckets are what we expect BOOST_CHECK_EQUAL(info1.GetNewBucket(nKey1, ngm_asmap), 795); BOOST_CHECK_EQUAL(info1.GetNewBucket(nKey1, source1, ngm_asmap), 795); // Test: Make sure key actually randomizes bucket placement. A fail on // this test could be a security issue. BOOST_CHECK(info1.GetNewBucket(nKey1, ngm_asmap) != info1.GetNewBucket(nKey2, ngm_asmap)); // Test: Ports should not affect bucket placement in the addr AddrInfo info2 = AddrInfo(addr2, source1); BOOST_CHECK(info1.GetKey() != info2.GetKey()); BOOST_CHECK_EQUAL(info1.GetNewBucket(nKey1, ngm_asmap), info2.GetNewBucket(nKey1, ngm_asmap)); std::set buckets; for (int i = 0; i < 255; i++) { AddrInfo infoi = AddrInfo( CAddress(ResolveService("250.1.1." + ToString(i)), NODE_NONE), ResolveIP("250.1.1." + ToString(i))); int bucket = infoi.GetNewBucket(nKey1, ngm_asmap); buckets.insert(bucket); } // Test: IP addresses in the same /16 prefix // usually map to the same bucket. BOOST_CHECK_EQUAL(buckets.size(), 1U); buckets.clear(); for (int j = 0; j < 4 * 255; j++) { AddrInfo infoj = AddrInfo(CAddress( ResolveService( ToString(250 + (j / 255)) + "." + ToString(j % 256) + ".1.1"), NODE_NONE), ResolveIP("251.4.1.1")); int bucket = infoj.GetNewBucket(nKey1, ngm_asmap); buckets.insert(bucket); } // Test: IP addresses in the same source /16 prefix should not map to more // than 64 buckets. BOOST_CHECK(buckets.size() <= 64); buckets.clear(); for (int p = 0; p < 255; p++) { AddrInfo infoj = AddrInfo( CAddress(ResolveService("250.1.1.1"), NODE_NONE), ResolveIP("101." + ToString(p) + ".1.1")); int bucket = infoj.GetNewBucket(nKey1, ngm_asmap); buckets.insert(bucket); } // Test: IP addresses in the different source /16 prefixes usually map to MORE // than 1 bucket. BOOST_CHECK(buckets.size() > 1); buckets.clear(); for (int p = 0; p < 255; p++) { AddrInfo infoj = AddrInfo( CAddress(ResolveService("250.1.1.1"), NODE_NONE), ResolveIP("250." + ToString(p) + ".1.1")); int bucket = infoj.GetNewBucket(nKey1, ngm_asmap); buckets.insert(bucket); } // Test: IP addresses in the different source /16 prefixes sometimes map to NO MORE // than 1 bucket. BOOST_CHECK(buckets.size() == 1); } BOOST_AUTO_TEST_CASE(addrman_serialization) { std::vector asmap1 = FromBytes(test::data::asmap); NetGroupManager netgroupman{asmap1}; const auto ratio = GetCheckRatio(m_node); auto addrman_asmap1 = std::make_unique(netgroupman, DETERMINISTIC, ratio); auto addrman_asmap1_dup = std::make_unique(netgroupman, DETERMINISTIC, ratio); auto addrman_noasmap = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, ratio); DataStream stream{}; CAddress addr = CAddress(ResolveService("250.1.1.1"), NODE_NONE); CNetAddr default_source; addrman_asmap1->Add({addr}, default_source); stream << *addrman_asmap1; // serizalizing/deserializing addrman with the same asmap stream >> *addrman_asmap1_dup; AddressPosition addr_pos1 = addrman_asmap1->FindAddressEntry(addr).value(); AddressPosition addr_pos2 = addrman_asmap1_dup->FindAddressEntry(addr).value(); BOOST_CHECK(addr_pos1.multiplicity != 0); BOOST_CHECK(addr_pos2.multiplicity != 0); BOOST_CHECK(addr_pos1 == addr_pos2); // deserializing asmaped peers.dat to non-asmaped addrman stream << *addrman_asmap1; stream >> *addrman_noasmap; AddressPosition addr_pos3 = addrman_noasmap->FindAddressEntry(addr).value(); BOOST_CHECK(addr_pos3.multiplicity != 0); BOOST_CHECK(addr_pos1.bucket != addr_pos3.bucket); BOOST_CHECK(addr_pos1.position != addr_pos3.position); // deserializing non-asmaped peers.dat to asmaped addrman addrman_asmap1 = std::make_unique(netgroupman, DETERMINISTIC, ratio); addrman_noasmap = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, ratio); addrman_noasmap->Add({addr}, default_source); stream << *addrman_noasmap; stream >> *addrman_asmap1; AddressPosition addr_pos4 = addrman_asmap1->FindAddressEntry(addr).value(); BOOST_CHECK(addr_pos4.multiplicity != 0); BOOST_CHECK(addr_pos4.bucket != addr_pos3.bucket); BOOST_CHECK(addr_pos4 == addr_pos2); // used to map to different buckets, now maps to the same bucket. addrman_asmap1 = std::make_unique(netgroupman, DETERMINISTIC, ratio); addrman_noasmap = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, ratio); CAddress addr1 = CAddress(ResolveService("250.1.1.1"), NODE_NONE); CAddress addr2 = CAddress(ResolveService("250.2.1.1"), NODE_NONE); addrman_noasmap->Add({addr, addr2}, default_source); AddressPosition addr_pos5 = addrman_noasmap->FindAddressEntry(addr1).value(); AddressPosition addr_pos6 = addrman_noasmap->FindAddressEntry(addr2).value(); BOOST_CHECK(addr_pos5.bucket != addr_pos6.bucket); stream << *addrman_noasmap; stream >> *addrman_asmap1; AddressPosition addr_pos7 = addrman_asmap1->FindAddressEntry(addr1).value(); AddressPosition addr_pos8 = addrman_asmap1->FindAddressEntry(addr2).value(); BOOST_CHECK(addr_pos7.bucket == addr_pos8.bucket); BOOST_CHECK(addr_pos7.position != addr_pos8.position); } BOOST_AUTO_TEST_CASE(remove_invalid) { // Confirm that invalid addresses are ignored in unserialization. auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); DataStream stream{}; const CAddress new1{ResolveService("5.5.5.5"), NODE_NONE}; const CAddress new2{ResolveService("6.6.6.6"), NODE_NONE}; const CAddress tried1{ResolveService("7.7.7.7"), NODE_NONE}; const CAddress tried2{ResolveService("8.8.8.8"), NODE_NONE}; addrman->Add({new1, tried1, new2, tried2}, CNetAddr{}); addrman->Good(tried1); addrman->Good(tried2); BOOST_REQUIRE_EQUAL(addrman->Size(), 4); stream << *addrman; const std::string str{stream.str()}; size_t pos; const char new2_raw[]{6, 6, 6, 6}; const uint8_t new2_raw_replacement[]{0, 0, 0, 0}; // 0.0.0.0 is !IsValid() pos = str.find(new2_raw, 0, sizeof(new2_raw)); BOOST_REQUIRE(pos != std::string::npos); BOOST_REQUIRE(pos + sizeof(new2_raw_replacement) <= stream.size()); memcpy(stream.data() + pos, new2_raw_replacement, sizeof(new2_raw_replacement)); const char tried2_raw[]{8, 8, 8, 8}; const uint8_t tried2_raw_replacement[]{255, 255, 255, 255}; // 255.255.255.255 is !IsValid() pos = str.find(tried2_raw, 0, sizeof(tried2_raw)); BOOST_REQUIRE(pos != std::string::npos); BOOST_REQUIRE(pos + sizeof(tried2_raw_replacement) <= stream.size()); memcpy(stream.data() + pos, tried2_raw_replacement, sizeof(tried2_raw_replacement)); addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); stream >> *addrman; BOOST_CHECK_EQUAL(addrman->Size(), 2); } BOOST_AUTO_TEST_CASE(addrman_selecttriedcollision) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); BOOST_CHECK(addrman->Size() == 0); // Empty addrman should return blank addrman info. BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); // Add twenty two addresses. CNetAddr source = ResolveIP("252.2.2.2"); for (unsigned int i = 1; i < 23; i++) { CService addr = ResolveService("250.1.1." + ToString(i)); BOOST_CHECK(addrman->Add({CAddress(addr, NODE_NONE)}, source)); // No collisions in tried. BOOST_CHECK(addrman->Good(addr)); BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); } // Ensure Good handles duplicates well. // If an address is a duplicate, Good will return false but will not count it as a collision. for (unsigned int i = 1; i < 23; i++) { CService addr = ResolveService("250.1.1." + ToString(i)); // Unable to add duplicate address to tried table. BOOST_CHECK(!addrman->Good(addr)); // Verify duplicate address not marked as a collision. BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); } } BOOST_AUTO_TEST_CASE(addrman_noevict) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); // Add 35 addresses. CNetAddr source = ResolveIP("252.2.2.2"); for (unsigned int i = 1; i < 36; i++) { CService addr = ResolveService("250.1.1." + ToString(i)); BOOST_CHECK(addrman->Add({CAddress(addr, NODE_NONE)}, source)); // No collision yet. BOOST_CHECK(addrman->Good(addr)); } // Collision in tried table between 36 and 19. CService addr36 = ResolveService("250.1.1.36"); BOOST_CHECK(addrman->Add({CAddress(addr36, NODE_NONE)}, source)); BOOST_CHECK(!addrman->Good(addr36)); BOOST_CHECK_EQUAL(addrman->SelectTriedCollision().first.ToStringAddrPort(), "250.1.1.19:0"); // 36 should be discarded and 19 not evicted. // This means we keep 19 in the tried table and // 36 stays in the new table. addrman->ResolveCollisions(); BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); // Lets create two collisions. for (unsigned int i = 37; i < 59; i++) { CService addr = ResolveService("250.1.1." + ToString(i)); BOOST_CHECK(addrman->Add({CAddress(addr, NODE_NONE)}, source)); BOOST_CHECK(addrman->Good(addr)); } // Cause a collision in the tried table. CService addr59 = ResolveService("250.1.1.59"); BOOST_CHECK(addrman->Add({CAddress(addr59, NODE_NONE)}, source)); BOOST_CHECK(!addrman->Good(addr59)); BOOST_CHECK_EQUAL(addrman->SelectTriedCollision().first.ToStringAddrPort(), "250.1.1.10:0"); // Cause a second collision in the new table. BOOST_CHECK(!addrman->Add({CAddress(addr36, NODE_NONE)}, source)); // 36 still cannot be moved from new to tried due to colliding with 19 BOOST_CHECK(!addrman->Good(addr36)); BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() != "[::]:0"); // Resolve all collisions. addrman->ResolveCollisions(); BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); } BOOST_AUTO_TEST_CASE(addrman_evictionworks) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); BOOST_CHECK(addrman->Size() == 0); // Empty addrman should return blank addrman info. BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); // Add 35 addresses CNetAddr source = ResolveIP("252.2.2.2"); for (unsigned int i = 1; i < 36; i++) { CService addr = ResolveService("250.1.1." + ToString(i)); BOOST_CHECK(addrman->Add({CAddress(addr, NODE_NONE)}, source)); // No collision yet. BOOST_CHECK(addrman->Good(addr)); } // Collision between 36 and 19. CService addr = ResolveService("250.1.1.36"); BOOST_CHECK(addrman->Add({CAddress(addr, NODE_NONE)}, source)); BOOST_CHECK(!addrman->Good(addr)); auto info = addrman->SelectTriedCollision().first; BOOST_CHECK_EQUAL(info.ToStringAddrPort(), "250.1.1.19:0"); // Ensure test of address fails, so that it is evicted. // Update entry in tried by setting last good connection in the deep past. BOOST_CHECK(!addrman->Good(info, NodeSeconds{1s})); addrman->Attempt(info, /*fCountFailure=*/false, Now() - 61s); // Should swap 36 for 19. addrman->ResolveCollisions(); BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); AddressPosition addr_pos{addrman->FindAddressEntry(CAddress(addr, NODE_NONE)).value()}; BOOST_CHECK(addr_pos.tried); // If 36 was swapped for 19, then adding 36 to tried should fail because we // are attempting to add a duplicate. // We check this by verifying Good() returns false and also verifying that // we have no collisions. BOOST_CHECK(!addrman->Good(addr)); BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); // 19 should fail as a collision (not a duplicate) if we now attempt to move // it to the tried table. CService addr19 = ResolveService("250.1.1.19"); BOOST_CHECK(!addrman->Good(addr19)); BOOST_CHECK_EQUAL(addrman->SelectTriedCollision().first.ToStringAddrPort(), "250.1.1.36:0"); // Eviction is also successful if too much time has passed since last try SetMockTime(GetTime() + 4 * 60 *60); addrman->ResolveCollisions(); BOOST_CHECK(addrman->SelectTriedCollision().first.ToStringAddrPort() == "[::]:0"); //Now 19 is in tried again, and 36 back to new AddressPosition addr_pos19{addrman->FindAddressEntry(CAddress(addr19, NODE_NONE)).value()}; BOOST_CHECK(addr_pos19.tried); AddressPosition addr_pos36{addrman->FindAddressEntry(CAddress(addr, NODE_NONE)).value()}; BOOST_CHECK(!addr_pos36.tried); } static auto AddrmanToStream(const AddrMan& addrman) { DataStream ssPeersIn{}; ssPeersIn << Params().MessageStart(); ssPeersIn << addrman; return ssPeersIn; } BOOST_AUTO_TEST_CASE(load_addrman) { AddrMan addrman{EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)}; std::optional addr1, addr2, addr3, addr4; addr1 = Lookup("250.7.1.1", 8333, false); BOOST_CHECK(addr1.has_value()); addr2 = Lookup("250.7.2.2", 9999, false); BOOST_CHECK(addr2.has_value()); addr3 = Lookup("250.7.3.3", 9999, false); BOOST_CHECK(addr3.has_value()); addr3 = Lookup("250.7.3.3"s, 9999, false); BOOST_CHECK(addr3.has_value()); addr4 = Lookup("250.7.3.3\0example.com"s, 9999, false); BOOST_CHECK(!addr4.has_value()); // Add three addresses to new table. const std::optional source{Lookup("252.5.1.1", 8333, false)}; BOOST_CHECK(source.has_value()); std::vector addresses{CAddress(addr1.value(), NODE_NONE), CAddress(addr2.value(), NODE_NONE), CAddress(addr3.value(), NODE_NONE)}; BOOST_CHECK(addrman.Add(addresses, source.value())); BOOST_CHECK(addrman.Size() == 3); // Test that the de-serialization does not throw an exception. auto ssPeers1{AddrmanToStream(addrman)}; bool exceptionThrown = false; AddrMan addrman1{EMPTY_NETGROUPMAN, !DETERMINISTIC, GetCheckRatio(m_node)}; BOOST_CHECK(addrman1.Size() == 0); try { unsigned char pchMsgTmp[4]; ssPeers1 >> pchMsgTmp; ssPeers1 >> addrman1; } catch (const std::exception&) { exceptionThrown = true; } BOOST_CHECK(addrman1.Size() == 3); BOOST_CHECK(exceptionThrown == false); // Test that ReadFromStream creates an addrman with the correct number of addrs. DataStream ssPeers2 = AddrmanToStream(addrman); AddrMan addrman2{EMPTY_NETGROUPMAN, !DETERMINISTIC, GetCheckRatio(m_node)}; BOOST_CHECK(addrman2.Size() == 0); ReadFromStream(addrman2, ssPeers2); BOOST_CHECK(addrman2.Size() == 3); } // Produce a corrupt peers.dat that claims 20 addrs when it only has one addr. static auto MakeCorruptPeersDat() { DataStream s{}; s << ::Params().MessageStart(); unsigned char nVersion = 1; s << nVersion; s << ((unsigned char)32); s << uint256::ONE; s << 10; // nNew s << 10; // nTried int nUBuckets = ADDRMAN_NEW_BUCKET_COUNT ^ (1 << 30); s << nUBuckets; const std::optional serv{Lookup("252.1.1.1", 7777, false)}; BOOST_REQUIRE(serv.has_value()); CAddress addr = CAddress(serv.value(), NODE_NONE); std::optional resolved{LookupHost("252.2.2.2", false)}; BOOST_REQUIRE(resolved.has_value()); AddrInfo info = AddrInfo(addr, resolved.value()); s << CAddress::V1_DISK(info); return s; } BOOST_AUTO_TEST_CASE(load_addrman_corrupted) { // Test that the de-serialization of corrupted peers.dat throws an exception. auto ssPeers1{MakeCorruptPeersDat()}; bool exceptionThrown = false; AddrMan addrman1{EMPTY_NETGROUPMAN, !DETERMINISTIC, GetCheckRatio(m_node)}; BOOST_CHECK(addrman1.Size() == 0); try { unsigned char pchMsgTmp[4]; ssPeers1 >> pchMsgTmp; ssPeers1 >> addrman1; } catch (const std::exception&) { exceptionThrown = true; } BOOST_CHECK(exceptionThrown); // Test that ReadFromStream fails if peers.dat is corrupt auto ssPeers2{MakeCorruptPeersDat()}; AddrMan addrman2{EMPTY_NETGROUPMAN, !DETERMINISTIC, GetCheckRatio(m_node)}; BOOST_CHECK(addrman2.Size() == 0); BOOST_CHECK_THROW(ReadFromStream(addrman2, ssPeers2), std::ios_base::failure); } BOOST_AUTO_TEST_CASE(addrman_update_address) { // Tests updating nTime via Connected() and nServices via SetServices() and Add() auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); CNetAddr source{ResolveIP("252.2.2.2")}; CAddress addr{CAddress(ResolveService("250.1.1.1", 8333), NODE_NONE)}; const auto start_time{Now() - 10000s}; addr.nTime = start_time; BOOST_CHECK(addrman->Add({addr}, source)); BOOST_CHECK_EQUAL(addrman->Size(), 1U); // Updating an addrman entry with a different port doesn't change it CAddress addr_diff_port{CAddress(ResolveService("250.1.1.1", 8334), NODE_NONE)}; addr_diff_port.nTime = start_time; addrman->Connected(addr_diff_port); addrman->SetServices(addr_diff_port, NODE_NETWORK_LIMITED); std::vector vAddr1{addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt)}; BOOST_CHECK_EQUAL(vAddr1.size(), 1U); BOOST_CHECK(vAddr1.at(0).nTime == start_time); BOOST_CHECK_EQUAL(vAddr1.at(0).nServices, NODE_NONE); // Updating an addrman entry with the correct port is successful addrman->Connected(addr); addrman->SetServices(addr, NODE_NETWORK_LIMITED); std::vector vAddr2 = addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt); BOOST_CHECK_EQUAL(vAddr2.size(), 1U); BOOST_CHECK(vAddr2.at(0).nTime >= start_time + 10000s); BOOST_CHECK_EQUAL(vAddr2.at(0).nServices, NODE_NETWORK_LIMITED); // Updating an existing addr through Add() (used in gossip relay) can add additional services but can't remove existing ones. CAddress addr_v2{CAddress(ResolveService("250.1.1.1", 8333), NODE_P2P_V2)}; addr_v2.nTime = start_time; BOOST_CHECK(!addrman->Add({addr_v2}, source)); std::vector vAddr3{addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt)}; BOOST_CHECK_EQUAL(vAddr3.size(), 1U); BOOST_CHECK_EQUAL(vAddr3.at(0).nServices, NODE_P2P_V2 | NODE_NETWORK_LIMITED); // SetServices() (used when we connected to them) overwrites existing service flags addrman->SetServices(addr, NODE_NETWORK); std::vector vAddr4{addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt)}; BOOST_CHECK_EQUAL(vAddr4.size(), 1U); BOOST_CHECK_EQUAL(vAddr4.at(0).nServices, NODE_NETWORK); // Promoting to Tried does not affect the service flags BOOST_CHECK(addrman->Good(addr)); // addr has NODE_NONE std::vector vAddr5{addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt)}; BOOST_CHECK_EQUAL(vAddr5.size(), 1U); BOOST_CHECK_EQUAL(vAddr5.at(0).nServices, NODE_NETWORK); // Adding service flags even works when the addr is in Tried BOOST_CHECK(!addrman->Add({addr_v2}, source)); std::vector vAddr6{addrman->GetAddr(/*max_addresses=*/0, /*max_pct=*/0, /*network=*/std::nullopt)}; BOOST_CHECK_EQUAL(vAddr6.size(), 1U); BOOST_CHECK_EQUAL(vAddr6.at(0).nServices, NODE_NETWORK | NODE_P2P_V2); } BOOST_AUTO_TEST_CASE(addrman_size) { auto addrman = std::make_unique(EMPTY_NETGROUPMAN, DETERMINISTIC, GetCheckRatio(m_node)); const CNetAddr source = ResolveIP("252.2.2.2"); // empty addrman BOOST_CHECK_EQUAL(addrman->Size(/*net=*/std::nullopt, /*in_new=*/std::nullopt), 0U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/NET_IPV4, /*in_new=*/std::nullopt), 0U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/std::nullopt, /*in_new=*/true), 0U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/NET_IPV4, /*in_new=*/false), 0U); // add two ipv4 addresses, one to tried and new const CAddress addr1{ResolveService("250.1.1.1", 8333), NODE_NONE}; BOOST_CHECK(addrman->Add({addr1}, source)); BOOST_CHECK(addrman->Good(addr1)); const CAddress addr2{ResolveService("250.1.1.2", 8333), NODE_NONE}; BOOST_CHECK(addrman->Add({addr2}, source)); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/std::nullopt, /*in_new=*/std::nullopt), 2U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/NET_IPV4, /*in_new=*/std::nullopt), 2U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/std::nullopt, /*in_new=*/true), 1U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/std::nullopt, /*in_new=*/false), 1U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/NET_IPV4, /*in_new=*/true), 1U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/NET_IPV4, /*in_new=*/false), 1U); // add one i2p address to new CService i2p_addr; i2p_addr.SetSpecial("UDHDrtrcetjm5sxzskjyr5ztpeszydbh4dpl3pl4utgqqw2v4jna.b32.I2P"); const CAddress addr3{i2p_addr, NODE_NONE}; BOOST_CHECK(addrman->Add({addr3}, source)); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/std::nullopt, /*in_new=*/std::nullopt), 3U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/NET_IPV4, /*in_new=*/std::nullopt), 2U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/NET_I2P, /*in_new=*/std::nullopt), 1U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/NET_I2P, /*in_new=*/true), 1U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/std::nullopt, /*in_new=*/true), 2U); BOOST_CHECK_EQUAL(addrman->Size(/*net=*/std::nullopt, /*in_new=*/false), 1U); } BOOST_AUTO_TEST_SUITE_END()