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|
// Copyright (c) 2012-2020 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 <addrdb.h>
#include <addrman.h>
#include <chainparams.h>
#include <clientversion.h>
#include <cstdint>
#include <net.h>
#include <netaddress.h>
#include <netbase.h>
#include <serialize.h>
#include <span.h>
#include <streams.h>
#include <test/util/setup_common.h>
#include <util/strencodings.h>
#include <util/string.h>
#include <util/system.h>
#include <version.h>
#include <boost/test/unit_test.hpp>
#include <algorithm>
#include <ios>
#include <memory>
#include <optional>
#include <string>
using namespace std::literals;
class CAddrManSerializationMock : public CAddrMan
{
public:
virtual void Serialize(CDataStream& s) const = 0;
//! Ensure that bucket placement is always the same for testing purposes.
void MakeDeterministic()
{
nKey.SetNull();
insecure_rand = FastRandomContext(true);
}
};
class CAddrManUncorrupted : public CAddrManSerializationMock
{
public:
void Serialize(CDataStream& s) const override
{
CAddrMan::Serialize(s);
}
};
class CAddrManCorrupted : public CAddrManSerializationMock
{
public:
void Serialize(CDataStream& s) const override
{
// Produces corrupt output that claims addrman has 20 addrs when it only has one addr.
unsigned char nVersion = 1;
s << nVersion;
s << ((unsigned char)32);
s << nKey;
s << 10; // nNew
s << 10; // nTried
int nUBuckets = ADDRMAN_NEW_BUCKET_COUNT ^ (1 << 30);
s << nUBuckets;
CService serv;
BOOST_CHECK(Lookup("252.1.1.1", serv, 7777, false));
CAddress addr = CAddress(serv, NODE_NONE);
CNetAddr resolved;
BOOST_CHECK(LookupHost("252.2.2.2", resolved, false));
CAddrInfo info = CAddrInfo(addr, resolved);
s << info;
}
};
static CDataStream AddrmanToStream(const CAddrManSerializationMock& _addrman)
{
CDataStream ssPeersIn(SER_DISK, CLIENT_VERSION);
ssPeersIn << Params().MessageStart();
ssPeersIn << _addrman;
std::string str = ssPeersIn.str();
std::vector<unsigned char> vchData(str.begin(), str.end());
return CDataStream(vchData, SER_DISK, CLIENT_VERSION);
}
BOOST_FIXTURE_TEST_SUITE(net_tests, BasicTestingSetup)
BOOST_AUTO_TEST_CASE(cnode_listen_port)
{
// test default
uint16_t port{GetListenPort()};
BOOST_CHECK(port == Params().GetDefaultPort());
// test set port
uint16_t altPort = 12345;
BOOST_CHECK(gArgs.SoftSetArg("-port", ToString(altPort)));
port = GetListenPort();
BOOST_CHECK(port == altPort);
}
BOOST_AUTO_TEST_CASE(caddrdb_read)
{
CAddrManUncorrupted addrmanUncorrupted;
addrmanUncorrupted.MakeDeterministic();
CService addr1, addr2, addr3;
BOOST_CHECK(Lookup("250.7.1.1", addr1, 8333, false));
BOOST_CHECK(Lookup("250.7.2.2", addr2, 9999, false));
BOOST_CHECK(Lookup("250.7.3.3", addr3, 9999, false));
BOOST_CHECK(Lookup("250.7.3.3"s, addr3, 9999, false));
BOOST_CHECK(!Lookup("250.7.3.3\0example.com"s, addr3, 9999, false));
// Add three addresses to new table.
CService source;
BOOST_CHECK(Lookup("252.5.1.1", source, 8333, false));
BOOST_CHECK(addrmanUncorrupted.Add(CAddress(addr1, NODE_NONE), source));
BOOST_CHECK(addrmanUncorrupted.Add(CAddress(addr2, NODE_NONE), source));
BOOST_CHECK(addrmanUncorrupted.Add(CAddress(addr3, NODE_NONE), source));
// Test that the de-serialization does not throw an exception.
CDataStream ssPeers1 = AddrmanToStream(addrmanUncorrupted);
bool exceptionThrown = false;
CAddrMan addrman1;
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 CAddrDB::Read creates an addrman with the correct number of addrs.
CDataStream ssPeers2 = AddrmanToStream(addrmanUncorrupted);
CAddrMan addrman2;
BOOST_CHECK(addrman2.size() == 0);
BOOST_CHECK(CAddrDB::Read(addrman2, ssPeers2));
BOOST_CHECK(addrman2.size() == 3);
}
BOOST_AUTO_TEST_CASE(caddrdb_read_corrupted)
{
CAddrManCorrupted addrmanCorrupted;
addrmanCorrupted.MakeDeterministic();
// Test that the de-serialization of corrupted addrman throws an exception.
CDataStream ssPeers1 = AddrmanToStream(addrmanCorrupted);
bool exceptionThrown = false;
CAddrMan addrman1;
BOOST_CHECK(addrman1.size() == 0);
try {
unsigned char pchMsgTmp[4];
ssPeers1 >> pchMsgTmp;
ssPeers1 >> addrman1;
} catch (const std::exception&) {
exceptionThrown = true;
}
// Even through de-serialization failed addrman is not left in a clean state.
BOOST_CHECK(addrman1.size() == 1);
BOOST_CHECK(exceptionThrown);
// Test that CAddrDB::Read leaves addrman in a clean state if de-serialization fails.
CDataStream ssPeers2 = AddrmanToStream(addrmanCorrupted);
CAddrMan addrman2;
BOOST_CHECK(addrman2.size() == 0);
BOOST_CHECK(!CAddrDB::Read(addrman2, ssPeers2));
BOOST_CHECK(addrman2.size() == 0);
}
BOOST_AUTO_TEST_CASE(cnode_simple_test)
{
SOCKET hSocket = INVALID_SOCKET;
NodeId id = 0;
in_addr ipv4Addr;
ipv4Addr.s_addr = 0xa0b0c001;
CAddress addr = CAddress(CService(ipv4Addr, 7777), NODE_NETWORK);
std::string pszDest;
std::unique_ptr<CNode> pnode1 = std::make_unique<CNode>(
id++, NODE_NETWORK, hSocket, addr,
/* nKeyedNetGroupIn = */ 0,
/* nLocalHostNonceIn = */ 0,
CAddress(), pszDest, ConnectionType::OUTBOUND_FULL_RELAY,
/* inbound_onion = */ false);
BOOST_CHECK(pnode1->IsFullOutboundConn() == true);
BOOST_CHECK(pnode1->IsManualConn() == false);
BOOST_CHECK(pnode1->IsBlockOnlyConn() == false);
BOOST_CHECK(pnode1->IsFeelerConn() == false);
BOOST_CHECK(pnode1->IsAddrFetchConn() == false);
BOOST_CHECK(pnode1->IsInboundConn() == false);
BOOST_CHECK(pnode1->m_inbound_onion == false);
BOOST_CHECK_EQUAL(pnode1->ConnectedThroughNetwork(), Network::NET_IPV4);
std::unique_ptr<CNode> pnode2 = std::make_unique<CNode>(
id++, NODE_NETWORK, hSocket, addr,
/* nKeyedNetGroupIn = */ 1,
/* nLocalHostNonceIn = */ 1,
CAddress(), pszDest, ConnectionType::INBOUND,
/* inbound_onion = */ false);
BOOST_CHECK(pnode2->IsFullOutboundConn() == false);
BOOST_CHECK(pnode2->IsManualConn() == false);
BOOST_CHECK(pnode2->IsBlockOnlyConn() == false);
BOOST_CHECK(pnode2->IsFeelerConn() == false);
BOOST_CHECK(pnode2->IsAddrFetchConn() == false);
BOOST_CHECK(pnode2->IsInboundConn() == true);
BOOST_CHECK(pnode2->m_inbound_onion == false);
BOOST_CHECK_EQUAL(pnode2->ConnectedThroughNetwork(), Network::NET_IPV4);
std::unique_ptr<CNode> pnode3 = std::make_unique<CNode>(
id++, NODE_NETWORK, hSocket, addr,
/* nKeyedNetGroupIn = */ 0,
/* nLocalHostNonceIn = */ 0,
CAddress(), pszDest, ConnectionType::OUTBOUND_FULL_RELAY,
/* inbound_onion = */ false);
BOOST_CHECK(pnode3->IsFullOutboundConn() == true);
BOOST_CHECK(pnode3->IsManualConn() == false);
BOOST_CHECK(pnode3->IsBlockOnlyConn() == false);
BOOST_CHECK(pnode3->IsFeelerConn() == false);
BOOST_CHECK(pnode3->IsAddrFetchConn() == false);
BOOST_CHECK(pnode3->IsInboundConn() == false);
BOOST_CHECK(pnode3->m_inbound_onion == false);
BOOST_CHECK_EQUAL(pnode3->ConnectedThroughNetwork(), Network::NET_IPV4);
std::unique_ptr<CNode> pnode4 = std::make_unique<CNode>(
id++, NODE_NETWORK, hSocket, addr,
/* nKeyedNetGroupIn = */ 1,
/* nLocalHostNonceIn = */ 1,
CAddress(), pszDest, ConnectionType::INBOUND,
/* inbound_onion = */ true);
BOOST_CHECK(pnode4->IsFullOutboundConn() == false);
BOOST_CHECK(pnode4->IsManualConn() == false);
BOOST_CHECK(pnode4->IsBlockOnlyConn() == false);
BOOST_CHECK(pnode4->IsFeelerConn() == false);
BOOST_CHECK(pnode4->IsAddrFetchConn() == false);
BOOST_CHECK(pnode4->IsInboundConn() == true);
BOOST_CHECK(pnode4->m_inbound_onion == true);
BOOST_CHECK_EQUAL(pnode4->ConnectedThroughNetwork(), Network::NET_ONION);
}
BOOST_AUTO_TEST_CASE(cnetaddr_basic)
{
CNetAddr addr;
// IPv4, INADDR_ANY
BOOST_REQUIRE(LookupHost("0.0.0.0", addr, false));
BOOST_REQUIRE(!addr.IsValid());
BOOST_REQUIRE(addr.IsIPv4());
BOOST_CHECK(addr.IsBindAny());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "0.0.0.0");
// IPv4, INADDR_NONE
BOOST_REQUIRE(LookupHost("255.255.255.255", addr, false));
BOOST_REQUIRE(!addr.IsValid());
BOOST_REQUIRE(addr.IsIPv4());
BOOST_CHECK(!addr.IsBindAny());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "255.255.255.255");
// IPv4, casual
BOOST_REQUIRE(LookupHost("12.34.56.78", addr, false));
BOOST_REQUIRE(addr.IsValid());
BOOST_REQUIRE(addr.IsIPv4());
BOOST_CHECK(!addr.IsBindAny());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "12.34.56.78");
// IPv6, in6addr_any
BOOST_REQUIRE(LookupHost("::", addr, false));
BOOST_REQUIRE(!addr.IsValid());
BOOST_REQUIRE(addr.IsIPv6());
BOOST_CHECK(addr.IsBindAny());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "::");
// IPv6, casual
BOOST_REQUIRE(LookupHost("1122:3344:5566:7788:9900:aabb:ccdd:eeff", addr, false));
BOOST_REQUIRE(addr.IsValid());
BOOST_REQUIRE(addr.IsIPv6());
BOOST_CHECK(!addr.IsBindAny());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "1122:3344:5566:7788:9900:aabb:ccdd:eeff");
// IPv6, scoped/link-local. See https://tools.ietf.org/html/rfc4007
// We support non-negative decimal integers (uint32_t) as zone id indices.
// Test with a fairly-high value, e.g. 32, to avoid locally reserved ids.
const std::string link_local{"fe80::1"};
const std::string scoped_addr{link_local + "%32"};
BOOST_REQUIRE(LookupHost(scoped_addr, addr, false));
BOOST_REQUIRE(addr.IsValid());
BOOST_REQUIRE(addr.IsIPv6());
BOOST_CHECK(!addr.IsBindAny());
const std::string addr_str{addr.ToString()};
BOOST_CHECK(addr_str == scoped_addr || addr_str == "fe80:0:0:0:0:0:0:1");
// The fallback case "fe80:0:0:0:0:0:0:1" is needed for macOS 10.14/10.15 and (probably) later.
// Test that the delimiter "%" and default zone id of 0 can be omitted for the default scope.
BOOST_REQUIRE(LookupHost(link_local + "%0", addr, false));
BOOST_REQUIRE(addr.IsValid());
BOOST_REQUIRE(addr.IsIPv6());
BOOST_CHECK(!addr.IsBindAny());
BOOST_CHECK_EQUAL(addr.ToString(), link_local);
// TORv2
BOOST_REQUIRE(addr.SetSpecial("6hzph5hv6337r6p2.onion"));
BOOST_REQUIRE(addr.IsValid());
BOOST_REQUIRE(addr.IsTor());
BOOST_CHECK(!addr.IsI2P());
BOOST_CHECK(!addr.IsBindAny());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "6hzph5hv6337r6p2.onion");
// TORv3
const char* torv3_addr = "pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscryd.onion";
BOOST_REQUIRE(addr.SetSpecial(torv3_addr));
BOOST_REQUIRE(addr.IsValid());
BOOST_REQUIRE(addr.IsTor());
BOOST_CHECK(!addr.IsI2P());
BOOST_CHECK(!addr.IsBindAny());
BOOST_CHECK(!addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), torv3_addr);
// TORv3, broken, with wrong checksum
BOOST_CHECK(!addr.SetSpecial("pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscsad.onion"));
// TORv3, broken, with wrong version
BOOST_CHECK(!addr.SetSpecial("pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscrye.onion"));
// TORv3, malicious
BOOST_CHECK(!addr.SetSpecial(std::string{
"pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscryd\0wtf.onion", 66}));
// TOR, bogus length
BOOST_CHECK(!addr.SetSpecial(std::string{"mfrggzak.onion"}));
// TOR, invalid base32
BOOST_CHECK(!addr.SetSpecial(std::string{"mf*g zak.onion"}));
// I2P
const char* i2p_addr = "UDHDrtrcetjm5sxzskjyr5ztpeszydbh4dpl3pl4utgqqw2v4jna.b32.I2P";
BOOST_REQUIRE(addr.SetSpecial(i2p_addr));
BOOST_REQUIRE(addr.IsValid());
BOOST_REQUIRE(addr.IsI2P());
BOOST_CHECK(!addr.IsTor());
BOOST_CHECK(!addr.IsBindAny());
BOOST_CHECK(!addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), ToLower(i2p_addr));
// I2P, correct length, but decodes to less than the expected number of bytes.
BOOST_CHECK(!addr.SetSpecial("udhdrtrcetjm5sxzskjyr5ztpeszydbh4dpl3pl4utgqqw2v4jn=.b32.i2p"));
// I2P, extra unnecessary padding
BOOST_CHECK(!addr.SetSpecial("udhdrtrcetjm5sxzskjyr5ztpeszydbh4dpl3pl4utgqqw2v4jna=.b32.i2p"));
// I2P, malicious
BOOST_CHECK(!addr.SetSpecial("udhdrtrcetjm5sxzskjyr5ztpeszydbh4dpl3pl4utgqqw2v\0wtf.b32.i2p"s));
// I2P, valid but unsupported (56 Base32 characters)
// See "Encrypted LS with Base 32 Addresses" in
// https://geti2p.net/spec/encryptedleaseset.txt
BOOST_CHECK(
!addr.SetSpecial("pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscsad.b32.i2p"));
// I2P, invalid base32
BOOST_CHECK(!addr.SetSpecial(std::string{"tp*szydbh4dp.b32.i2p"}));
// Internal
addr.SetInternal("esffpp");
BOOST_REQUIRE(!addr.IsValid()); // "internal" is considered invalid
BOOST_REQUIRE(addr.IsInternal());
BOOST_CHECK(!addr.IsBindAny());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "esffpvrt3wpeaygy.internal");
// Totally bogus
BOOST_CHECK(!addr.SetSpecial("totally bogus"));
}
BOOST_AUTO_TEST_CASE(cnetaddr_tostring_canonical_ipv6)
{
// Test that CNetAddr::ToString formats IPv6 addresses with zero compression as described in
// RFC 5952 ("A Recommendation for IPv6 Address Text Representation").
const std::map<std::string, std::string> canonical_representations_ipv6{
{"0000:0000:0000:0000:0000:0000:0000:0000", "::"},
{"000:0000:000:00:0:00:000:0000", "::"},
{"000:000:000:000:000:000:000:000", "::"},
{"00:00:00:00:00:00:00:00", "::"},
{"0:0:0:0:0:0:0:0", "::"},
{"0:0:0:0:0:0:0:1", "::1"},
{"2001:0:0:1:0:0:0:1", "2001:0:0:1::1"},
{"2001:0db8:0:0:1:0:0:1", "2001:db8::1:0:0:1"},
{"2001:0db8:85a3:0000:0000:8a2e:0370:7334", "2001:db8:85a3::8a2e:370:7334"},
{"2001:0db8::0001", "2001:db8::1"},
{"2001:0db8::0001:0000", "2001:db8::1:0"},
{"2001:0db8::1:0:0:1", "2001:db8::1:0:0:1"},
{"2001:db8:0000:0:1::1", "2001:db8::1:0:0:1"},
{"2001:db8:0000:1:1:1:1:1", "2001:db8:0:1:1:1:1:1"},
{"2001:db8:0:0:0:0:2:1", "2001:db8::2:1"},
{"2001:db8:0:0:0::1", "2001:db8::1"},
{"2001:db8:0:0:1:0:0:1", "2001:db8::1:0:0:1"},
{"2001:db8:0:0:1::1", "2001:db8::1:0:0:1"},
{"2001:DB8:0:0:1::1", "2001:db8::1:0:0:1"},
{"2001:db8:0:0::1", "2001:db8::1"},
{"2001:db8:0:0:aaaa::1", "2001:db8::aaaa:0:0:1"},
{"2001:db8:0:1:1:1:1:1", "2001:db8:0:1:1:1:1:1"},
{"2001:db8:0::1", "2001:db8::1"},
{"2001:db8:85a3:0:0:8a2e:370:7334", "2001:db8:85a3::8a2e:370:7334"},
{"2001:db8::0:1", "2001:db8::1"},
{"2001:db8::0:1:0:0:1", "2001:db8::1:0:0:1"},
{"2001:DB8::1", "2001:db8::1"},
{"2001:db8::1", "2001:db8::1"},
{"2001:db8::1:0:0:1", "2001:db8::1:0:0:1"},
{"2001:db8::1:1:1:1:1", "2001:db8:0:1:1:1:1:1"},
{"2001:db8::aaaa:0:0:1", "2001:db8::aaaa:0:0:1"},
{"2001:db8:aaaa:bbbb:cccc:dddd:0:1", "2001:db8:aaaa:bbbb:cccc:dddd:0:1"},
{"2001:db8:aaaa:bbbb:cccc:dddd::1", "2001:db8:aaaa:bbbb:cccc:dddd:0:1"},
{"2001:db8:aaaa:bbbb:cccc:dddd:eeee:0001", "2001:db8:aaaa:bbbb:cccc:dddd:eeee:1"},
{"2001:db8:aaaa:bbbb:cccc:dddd:eeee:001", "2001:db8:aaaa:bbbb:cccc:dddd:eeee:1"},
{"2001:db8:aaaa:bbbb:cccc:dddd:eeee:01", "2001:db8:aaaa:bbbb:cccc:dddd:eeee:1"},
{"2001:db8:aaaa:bbbb:cccc:dddd:eeee:1", "2001:db8:aaaa:bbbb:cccc:dddd:eeee:1"},
{"2001:db8:aaaa:bbbb:cccc:dddd:eeee:aaaa", "2001:db8:aaaa:bbbb:cccc:dddd:eeee:aaaa"},
{"2001:db8:aaaa:bbbb:cccc:dddd:eeee:AAAA", "2001:db8:aaaa:bbbb:cccc:dddd:eeee:aaaa"},
{"2001:db8:aaaa:bbbb:cccc:dddd:eeee:AaAa", "2001:db8:aaaa:bbbb:cccc:dddd:eeee:aaaa"},
};
for (const auto& [input_address, expected_canonical_representation_output] : canonical_representations_ipv6) {
CNetAddr net_addr;
BOOST_REQUIRE(LookupHost(input_address, net_addr, false));
BOOST_REQUIRE(net_addr.IsIPv6());
BOOST_CHECK_EQUAL(net_addr.ToString(), expected_canonical_representation_output);
}
}
BOOST_AUTO_TEST_CASE(cnetaddr_serialize_v1)
{
CNetAddr addr;
CDataStream s(SER_NETWORK, PROTOCOL_VERSION);
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "00000000000000000000000000000000");
s.clear();
BOOST_REQUIRE(LookupHost("1.2.3.4", addr, false));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "00000000000000000000ffff01020304");
s.clear();
BOOST_REQUIRE(LookupHost("1a1b:2a2b:3a3b:4a4b:5a5b:6a6b:7a7b:8a8b", addr, false));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "1a1b2a2b3a3b4a4b5a5b6a6b7a7b8a8b");
s.clear();
BOOST_REQUIRE(addr.SetSpecial("6hzph5hv6337r6p2.onion"));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "fd87d87eeb43f1f2f3f4f5f6f7f8f9fa");
s.clear();
BOOST_REQUIRE(addr.SetSpecial("pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscryd.onion"));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "00000000000000000000000000000000");
s.clear();
addr.SetInternal("a");
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "fd6b88c08724ca978112ca1bbdcafac2");
s.clear();
}
BOOST_AUTO_TEST_CASE(cnetaddr_serialize_v2)
{
CNetAddr addr;
CDataStream s(SER_NETWORK, PROTOCOL_VERSION);
// Add ADDRV2_FORMAT to the version so that the CNetAddr
// serialize method produces an address in v2 format.
s.SetVersion(s.GetVersion() | ADDRV2_FORMAT);
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "021000000000000000000000000000000000");
s.clear();
BOOST_REQUIRE(LookupHost("1.2.3.4", addr, false));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "010401020304");
s.clear();
BOOST_REQUIRE(LookupHost("1a1b:2a2b:3a3b:4a4b:5a5b:6a6b:7a7b:8a8b", addr, false));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "02101a1b2a2b3a3b4a4b5a5b6a6b7a7b8a8b");
s.clear();
BOOST_REQUIRE(addr.SetSpecial("6hzph5hv6337r6p2.onion"));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "030af1f2f3f4f5f6f7f8f9fa");
s.clear();
BOOST_REQUIRE(addr.SetSpecial("kpgvmscirrdqpekbqjsvw5teanhatztpp2gl6eee4zkowvwfxwenqaid.onion"));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "042053cd5648488c4707914182655b7664034e09e66f7e8cbf1084e654eb56c5bd88");
s.clear();
BOOST_REQUIRE(addr.SetInternal("a"));
s << addr;
BOOST_CHECK_EQUAL(HexStr(s), "0210fd6b88c08724ca978112ca1bbdcafac2");
s.clear();
}
BOOST_AUTO_TEST_CASE(cnetaddr_unserialize_v2)
{
CNetAddr addr;
CDataStream s(SER_NETWORK, PROTOCOL_VERSION);
// Add ADDRV2_FORMAT to the version so that the CNetAddr
// unserialize method expects an address in v2 format.
s.SetVersion(s.GetVersion() | ADDRV2_FORMAT);
// Valid IPv4.
s << MakeSpan(ParseHex("01" // network type (IPv4)
"04" // address length
"01020304")); // address
s >> addr;
BOOST_CHECK(addr.IsValid());
BOOST_CHECK(addr.IsIPv4());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "1.2.3.4");
BOOST_REQUIRE(s.empty());
// Invalid IPv4, valid length but address itself is shorter.
s << MakeSpan(ParseHex("01" // network type (IPv4)
"04" // address length
"0102")); // address
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure, HasReason("end of data"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Invalid IPv4, with bogus length.
s << MakeSpan(ParseHex("01" // network type (IPv4)
"05" // address length
"01020304")); // address
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure,
HasReason("BIP155 IPv4 address with length 5 (should be 4)"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Invalid IPv4, with extreme length.
s << MakeSpan(ParseHex("01" // network type (IPv4)
"fd0102" // address length (513 as CompactSize)
"01020304")); // address
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure,
HasReason("Address too long: 513 > 512"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Valid IPv6.
s << MakeSpan(ParseHex("02" // network type (IPv6)
"10" // address length
"0102030405060708090a0b0c0d0e0f10")); // address
s >> addr;
BOOST_CHECK(addr.IsValid());
BOOST_CHECK(addr.IsIPv6());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "102:304:506:708:90a:b0c:d0e:f10");
BOOST_REQUIRE(s.empty());
// Valid IPv6, contains embedded "internal".
s << MakeSpan(ParseHex(
"02" // network type (IPv6)
"10" // address length
"fd6b88c08724ca978112ca1bbdcafac2")); // address: 0xfd + sha256("bitcoin")[0:5] +
// sha256(name)[0:10]
s >> addr;
BOOST_CHECK(addr.IsInternal());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "zklycewkdo64v6wc.internal");
BOOST_REQUIRE(s.empty());
// Invalid IPv6, with bogus length.
s << MakeSpan(ParseHex("02" // network type (IPv6)
"04" // address length
"00")); // address
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure,
HasReason("BIP155 IPv6 address with length 4 (should be 16)"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Invalid IPv6, contains embedded IPv4.
s << MakeSpan(ParseHex("02" // network type (IPv6)
"10" // address length
"00000000000000000000ffff01020304")); // address
s >> addr;
BOOST_CHECK(!addr.IsValid());
BOOST_REQUIRE(s.empty());
// Invalid IPv6, contains embedded TORv2.
s << MakeSpan(ParseHex("02" // network type (IPv6)
"10" // address length
"fd87d87eeb430102030405060708090a")); // address
s >> addr;
BOOST_CHECK(!addr.IsValid());
BOOST_REQUIRE(s.empty());
// Valid TORv2.
s << MakeSpan(ParseHex("03" // network type (TORv2)
"0a" // address length
"f1f2f3f4f5f6f7f8f9fa")); // address
s >> addr;
BOOST_CHECK(addr.IsValid());
BOOST_CHECK(addr.IsTor());
BOOST_CHECK(addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "6hzph5hv6337r6p2.onion");
BOOST_REQUIRE(s.empty());
// Invalid TORv2, with bogus length.
s << MakeSpan(ParseHex("03" // network type (TORv2)
"07" // address length
"00")); // address
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure,
HasReason("BIP155 TORv2 address with length 7 (should be 10)"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Valid TORv3.
s << MakeSpan(ParseHex("04" // network type (TORv3)
"20" // address length
"79bcc625184b05194975c28b66b66b04" // address
"69f7f6556fb1ac3189a79b40dda32f1f"
));
s >> addr;
BOOST_CHECK(addr.IsValid());
BOOST_CHECK(addr.IsTor());
BOOST_CHECK(!addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(),
"pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscryd.onion");
BOOST_REQUIRE(s.empty());
// Invalid TORv3, with bogus length.
s << MakeSpan(ParseHex("04" // network type (TORv3)
"00" // address length
"00" // address
));
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure,
HasReason("BIP155 TORv3 address with length 0 (should be 32)"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Valid I2P.
s << MakeSpan(ParseHex("05" // network type (I2P)
"20" // address length
"a2894dabaec08c0051a481a6dac88b64" // address
"f98232ae42d4b6fd2fa81952dfe36a87"));
s >> addr;
BOOST_CHECK(addr.IsValid());
BOOST_CHECK(addr.IsI2P());
BOOST_CHECK(!addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(),
"ukeu3k5oycgaauneqgtnvselmt4yemvoilkln7jpvamvfx7dnkdq.b32.i2p");
BOOST_REQUIRE(s.empty());
// Invalid I2P, with bogus length.
s << MakeSpan(ParseHex("05" // network type (I2P)
"03" // address length
"00" // address
));
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure,
HasReason("BIP155 I2P address with length 3 (should be 32)"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Valid CJDNS.
s << MakeSpan(ParseHex("06" // network type (CJDNS)
"10" // address length
"fc000001000200030004000500060007" // address
));
s >> addr;
BOOST_CHECK(addr.IsValid());
BOOST_CHECK(addr.IsCJDNS());
BOOST_CHECK(!addr.IsAddrV1Compatible());
BOOST_CHECK_EQUAL(addr.ToString(), "fc00:1:2:3:4:5:6:7");
BOOST_REQUIRE(s.empty());
// Invalid CJDNS, wrong prefix.
s << MakeSpan(ParseHex("06" // network type (CJDNS)
"10" // address length
"aa000001000200030004000500060007" // address
));
s >> addr;
BOOST_CHECK(addr.IsCJDNS());
BOOST_CHECK(!addr.IsValid());
BOOST_REQUIRE(s.empty());
// Invalid CJDNS, with bogus length.
s << MakeSpan(ParseHex("06" // network type (CJDNS)
"01" // address length
"00" // address
));
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure,
HasReason("BIP155 CJDNS address with length 1 (should be 16)"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Unknown, with extreme length.
s << MakeSpan(ParseHex("aa" // network type (unknown)
"fe00000002" // address length (CompactSize's MAX_SIZE)
"01020304050607" // address
));
BOOST_CHECK_EXCEPTION(s >> addr, std::ios_base::failure,
HasReason("Address too long: 33554432 > 512"));
BOOST_REQUIRE(!s.empty()); // The stream is not consumed on invalid input.
s.clear();
// Unknown, with reasonable length.
s << MakeSpan(ParseHex("aa" // network type (unknown)
"04" // address length
"01020304" // address
));
s >> addr;
BOOST_CHECK(!addr.IsValid());
BOOST_REQUIRE(s.empty());
// Unknown, with zero length.
s << MakeSpan(ParseHex("aa" // network type (unknown)
"00" // address length
"" // address
));
s >> addr;
BOOST_CHECK(!addr.IsValid());
BOOST_REQUIRE(s.empty());
}
// prior to PR #14728, this test triggers an undefined behavior
BOOST_AUTO_TEST_CASE(ipv4_peer_with_ipv6_addrMe_test)
{
// set up local addresses; all that's necessary to reproduce the bug is
// that a normal IPv4 address is among the entries, but if this address is
// !IsRoutable the undefined behavior is easier to trigger deterministically
{
LOCK(cs_mapLocalHost);
in_addr ipv4AddrLocal;
ipv4AddrLocal.s_addr = 0x0100007f;
CNetAddr addr = CNetAddr(ipv4AddrLocal);
LocalServiceInfo lsi;
lsi.nScore = 23;
lsi.nPort = 42;
mapLocalHost[addr] = lsi;
}
// create a peer with an IPv4 address
in_addr ipv4AddrPeer;
ipv4AddrPeer.s_addr = 0xa0b0c001;
CAddress addr = CAddress(CService(ipv4AddrPeer, 7777), NODE_NETWORK);
std::unique_ptr<CNode> pnode = std::make_unique<CNode>(0, NODE_NETWORK, INVALID_SOCKET, addr, /* nKeyedNetGroupIn */ 0, /* nLocalHostNonceIn */ 0, CAddress{}, /* pszDest */ std::string{}, ConnectionType::OUTBOUND_FULL_RELAY, /* inbound_onion */ false);
pnode->fSuccessfullyConnected.store(true);
// the peer claims to be reaching us via IPv6
in6_addr ipv6AddrLocal;
memset(ipv6AddrLocal.s6_addr, 0, 16);
ipv6AddrLocal.s6_addr[0] = 0xcc;
CAddress addrLocal = CAddress(CService(ipv6AddrLocal, 7777), NODE_NETWORK);
pnode->SetAddrLocal(addrLocal);
// before patch, this causes undefined behavior detectable with clang's -fsanitize=memory
GetLocalAddrForPeer(&*pnode);
// suppress no-checks-run warning; if this test fails, it's by triggering a sanitizer
BOOST_CHECK(1);
}
BOOST_AUTO_TEST_CASE(LimitedAndReachable_Network)
{
BOOST_CHECK_EQUAL(IsReachable(NET_IPV4), true);
BOOST_CHECK_EQUAL(IsReachable(NET_IPV6), true);
BOOST_CHECK_EQUAL(IsReachable(NET_ONION), true);
SetReachable(NET_IPV4, false);
SetReachable(NET_IPV6, false);
SetReachable(NET_ONION, false);
BOOST_CHECK_EQUAL(IsReachable(NET_IPV4), false);
BOOST_CHECK_EQUAL(IsReachable(NET_IPV6), false);
BOOST_CHECK_EQUAL(IsReachable(NET_ONION), false);
SetReachable(NET_IPV4, true);
SetReachable(NET_IPV6, true);
SetReachable(NET_ONION, true);
BOOST_CHECK_EQUAL(IsReachable(NET_IPV4), true);
BOOST_CHECK_EQUAL(IsReachable(NET_IPV6), true);
BOOST_CHECK_EQUAL(IsReachable(NET_ONION), true);
}
BOOST_AUTO_TEST_CASE(LimitedAndReachable_NetworkCaseUnroutableAndInternal)
{
BOOST_CHECK_EQUAL(IsReachable(NET_UNROUTABLE), true);
BOOST_CHECK_EQUAL(IsReachable(NET_INTERNAL), true);
SetReachable(NET_UNROUTABLE, false);
SetReachable(NET_INTERNAL, false);
BOOST_CHECK_EQUAL(IsReachable(NET_UNROUTABLE), true); // Ignored for both networks
BOOST_CHECK_EQUAL(IsReachable(NET_INTERNAL), true);
}
CNetAddr UtilBuildAddress(unsigned char p1, unsigned char p2, unsigned char p3, unsigned char p4)
{
unsigned char ip[] = {p1, p2, p3, p4};
struct sockaddr_in sa;
memset(&sa, 0, sizeof(sockaddr_in)); // initialize the memory block
memcpy(&(sa.sin_addr), &ip, sizeof(ip));
return CNetAddr(sa.sin_addr);
}
BOOST_AUTO_TEST_CASE(LimitedAndReachable_CNetAddr)
{
CNetAddr addr = UtilBuildAddress(0x001, 0x001, 0x001, 0x001); // 1.1.1.1
SetReachable(NET_IPV4, true);
BOOST_CHECK_EQUAL(IsReachable(addr), true);
SetReachable(NET_IPV4, false);
BOOST_CHECK_EQUAL(IsReachable(addr), false);
SetReachable(NET_IPV4, true); // have to reset this, because this is stateful.
}
BOOST_AUTO_TEST_CASE(LocalAddress_BasicLifecycle)
{
CService addr = CService(UtilBuildAddress(0x002, 0x001, 0x001, 0x001), 1000); // 2.1.1.1:1000
SetReachable(NET_IPV4, true);
BOOST_CHECK_EQUAL(IsLocal(addr), false);
BOOST_CHECK_EQUAL(AddLocal(addr, 1000), true);
BOOST_CHECK_EQUAL(IsLocal(addr), true);
RemoveLocal(addr);
BOOST_CHECK_EQUAL(IsLocal(addr), false);
}
std::vector<NodeEvictionCandidate> GetRandomNodeEvictionCandidates(const int n_candidates, FastRandomContext& random_context)
{
std::vector<NodeEvictionCandidate> candidates;
for (int id = 0; id < n_candidates; ++id) {
candidates.push_back({
/* id */ id,
/* nTimeConnected */ static_cast<int64_t>(random_context.randrange(100)),
/* m_min_ping_time */ std::chrono::microseconds{random_context.randrange(100)},
/* nLastBlockTime */ static_cast<int64_t>(random_context.randrange(100)),
/* nLastTXTime */ static_cast<int64_t>(random_context.randrange(100)),
/* fRelevantServices */ random_context.randbool(),
/* fRelayTxes */ random_context.randbool(),
/* fBloomFilter */ random_context.randbool(),
/* nKeyedNetGroup */ random_context.randrange(100),
/* prefer_evict */ random_context.randbool(),
/* m_is_local */ random_context.randbool(),
});
}
return candidates;
}
// Returns true if any of the node ids in node_ids are selected for eviction.
bool IsEvicted(std::vector<NodeEvictionCandidate> candidates, const std::vector<NodeId>& node_ids, FastRandomContext& random_context)
{
Shuffle(candidates.begin(), candidates.end(), random_context);
const std::optional<NodeId> evicted_node_id = SelectNodeToEvict(std::move(candidates));
if (!evicted_node_id) {
return false;
}
return std::find(node_ids.begin(), node_ids.end(), *evicted_node_id) != node_ids.end();
}
// Create number_of_nodes random nodes, apply setup function candidate_setup_fn,
// apply eviction logic and then return true if any of the node ids in node_ids
// are selected for eviction.
bool IsEvicted(const int number_of_nodes, std::function<void(NodeEvictionCandidate&)> candidate_setup_fn, const std::vector<NodeId>& node_ids, FastRandomContext& random_context)
{
std::vector<NodeEvictionCandidate> candidates = GetRandomNodeEvictionCandidates(number_of_nodes, random_context);
for (NodeEvictionCandidate& candidate : candidates) {
candidate_setup_fn(candidate);
}
return IsEvicted(candidates, node_ids, random_context);
}
namespace {
constexpr int NODE_EVICTION_TEST_ROUNDS{10};
constexpr int NODE_EVICTION_TEST_UP_TO_N_NODES{200};
} // namespace
BOOST_AUTO_TEST_CASE(node_eviction_test)
{
FastRandomContext random_context{true};
for (int i = 0; i < NODE_EVICTION_TEST_ROUNDS; ++i) {
for (int number_of_nodes = 0; number_of_nodes < NODE_EVICTION_TEST_UP_TO_N_NODES; ++number_of_nodes) {
// Four nodes with the highest keyed netgroup values should be
// protected from eviction.
BOOST_CHECK(!IsEvicted(
number_of_nodes, [number_of_nodes](NodeEvictionCandidate& candidate) {
candidate.nKeyedNetGroup = number_of_nodes - candidate.id;
},
{0, 1, 2, 3}, random_context));
// Eight nodes with the lowest minimum ping time should be protected
// from eviction.
BOOST_CHECK(!IsEvicted(
number_of_nodes, [](NodeEvictionCandidate& candidate) {
candidate.m_min_ping_time = std::chrono::microseconds{candidate.id};
},
{0, 1, 2, 3, 4, 5, 6, 7}, random_context));
// Four nodes that most recently sent us novel transactions accepted
// into our mempool should be protected from eviction.
BOOST_CHECK(!IsEvicted(
number_of_nodes, [number_of_nodes](NodeEvictionCandidate& candidate) {
candidate.nLastTXTime = number_of_nodes - candidate.id;
},
{0, 1, 2, 3}, random_context));
// Up to eight non-tx-relay peers that most recently sent us novel
// blocks should be protected from eviction.
BOOST_CHECK(!IsEvicted(
number_of_nodes, [number_of_nodes](NodeEvictionCandidate& candidate) {
candidate.nLastBlockTime = number_of_nodes - candidate.id;
if (candidate.id <= 7) {
candidate.fRelayTxes = false;
candidate.fRelevantServices = true;
}
},
{0, 1, 2, 3, 4, 5, 6, 7}, random_context));
// Four peers that most recently sent us novel blocks should be
// protected from eviction.
BOOST_CHECK(!IsEvicted(
number_of_nodes, [number_of_nodes](NodeEvictionCandidate& candidate) {
candidate.nLastBlockTime = number_of_nodes - candidate.id;
},
{0, 1, 2, 3}, random_context));
// Combination of the previous two tests.
BOOST_CHECK(!IsEvicted(
number_of_nodes, [number_of_nodes](NodeEvictionCandidate& candidate) {
candidate.nLastBlockTime = number_of_nodes - candidate.id;
if (candidate.id <= 7) {
candidate.fRelayTxes = false;
candidate.fRelevantServices = true;
}
},
{0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11}, random_context));
// Combination of all tests above.
BOOST_CHECK(!IsEvicted(
number_of_nodes, [number_of_nodes](NodeEvictionCandidate& candidate) {
candidate.nKeyedNetGroup = number_of_nodes - candidate.id; // 4 protected
candidate.m_min_ping_time = std::chrono::microseconds{candidate.id}; // 8 protected
candidate.nLastTXTime = number_of_nodes - candidate.id; // 4 protected
candidate.nLastBlockTime = number_of_nodes - candidate.id; // 4 protected
},
{0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19}, random_context));
// An eviction is expected given >= 29 random eviction candidates. The eviction logic protects at most
// four peers by net group, eight by lowest ping time, four by last time of novel tx, up to eight non-tx-relay
// peers by last novel block time, and four more peers by last novel block time.
if (number_of_nodes >= 29) {
BOOST_CHECK(SelectNodeToEvict(GetRandomNodeEvictionCandidates(number_of_nodes, random_context)));
}
// No eviction is expected given <= 20 random eviction candidates. The eviction logic protects at least
// four peers by net group, eight by lowest ping time, four by last time of novel tx and four peers by last
// novel block time.
if (number_of_nodes <= 20) {
BOOST_CHECK(!SelectNodeToEvict(GetRandomNodeEvictionCandidates(number_of_nodes, random_context)));
}
// Cases left to test:
// * "Protect the half of the remaining nodes which have been connected the longest. [...]"
// * "Pick out up to 1/4 peers that are localhost, sorted by longest uptime. [...]"
// * "If any remaining peers are preferred for eviction consider only them. [...]"
// * "Identify the network group with the most connections and youngest member. [...]"
}
}
}
BOOST_AUTO_TEST_SUITE_END()
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