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net_peer_eviction_tests.cpp
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net_peer_eviction_tests.cpp
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// Copyright (c) 2021-2022 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 <netaddress.h>
#include <net.h>
#include <test/util/net.h>
#include <test/util/setup_common.h>
#include <boost/test/unit_test.hpp>
#include <algorithm>
#include <functional>
#include <optional>
#include <unordered_set>
#include <vector>
BOOST_FIXTURE_TEST_SUITE(net_peer_eviction_tests, BasicTestingSetup)
// Create `num_peers` random nodes, apply setup function `candidate_setup_fn`,
// call ProtectEvictionCandidatesByRatio() to apply protection logic, and then
// return true if all of `protected_peer_ids` and none of `unprotected_peer_ids`
// are protected from eviction, i.e. removed from the eviction candidates.
bool IsProtected(int num_peers,
std::function<void(NodeEvictionCandidate&)> candidate_setup_fn,
const std::unordered_set<NodeId>& protected_peer_ids,
const std::unordered_set<NodeId>& unprotected_peer_ids,
FastRandomContext& random_context)
{
std::vector<NodeEvictionCandidate> candidates{GetRandomNodeEvictionCandidates(num_peers, random_context)};
for (NodeEvictionCandidate& candidate : candidates) {
candidate_setup_fn(candidate);
}
Shuffle(candidates.begin(), candidates.end(), random_context);
const size_t size{candidates.size()};
const size_t expected{size - size / 2}; // Expect half the candidates will be protected.
ProtectEvictionCandidatesByRatio(candidates);
BOOST_CHECK_EQUAL(candidates.size(), expected);
size_t unprotected_count{0};
for (const NodeEvictionCandidate& candidate : candidates) {
if (protected_peer_ids.count(candidate.id)) {
// this peer should have been removed from the eviction candidates
BOOST_TEST_MESSAGE(strprintf("expected candidate to be protected: %d", candidate.id));
return false;
}
if (unprotected_peer_ids.count(candidate.id)) {
// this peer remains in the eviction candidates, as expected
++unprotected_count;
}
}
const bool is_protected{unprotected_count == unprotected_peer_ids.size()};
if (!is_protected) {
BOOST_TEST_MESSAGE(strprintf("unprotected: expected %d, actual %d",
unprotected_peer_ids.size(), unprotected_count));
}
return is_protected;
}
BOOST_AUTO_TEST_CASE(peer_protection_test)
{
FastRandomContext random_context{true};
int num_peers{12};
// Expect half of the peers with greatest uptime (the lowest m_connected)
// to be protected from eviction.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = false;
c.m_network = NET_IPV4;
},
/*protected_peer_ids=*/{0, 1, 2, 3, 4, 5},
/*unprotected_peer_ids=*/{6, 7, 8, 9, 10, 11},
random_context));
// Verify in the opposite direction.
BOOST_CHECK(IsProtected(
num_peers, [num_peers](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{num_peers - c.id};
c.m_is_local = false;
c.m_network = NET_IPV6;
},
/*protected_peer_ids=*/{6, 7, 8, 9, 10, 11},
/*unprotected_peer_ids=*/{0, 1, 2, 3, 4, 5},
random_context));
// Test protection of onion, localhost, and I2P peers...
// Expect 1/4 onion peers to be protected from eviction,
// if no localhost, I2P, or CJDNS peers.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_is_local = false;
c.m_network = (c.id == 3 || c.id == 8 || c.id == 9) ? NET_ONION : NET_IPV4;
},
/*protected_peer_ids=*/{3, 8, 9},
/*unprotected_peer_ids=*/{},
random_context));
// Expect 1/4 onion peers and 1/4 of the other peers to be protected,
// sorted by longest uptime (lowest m_connected), if no localhost, I2P or CJDNS peers.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = false;
c.m_network = (c.id == 3 || c.id > 7) ? NET_ONION : NET_IPV6;
},
/*protected_peer_ids=*/{0, 1, 2, 3, 8, 9},
/*unprotected_peer_ids=*/{4, 5, 6, 7, 10, 11},
random_context));
// Expect 1/4 localhost peers to be protected from eviction,
// if no onion, I2P, or CJDNS peers.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_is_local = (c.id == 1 || c.id == 9 || c.id == 11);
c.m_network = NET_IPV4;
},
/*protected_peer_ids=*/{1, 9, 11},
/*unprotected_peer_ids=*/{},
random_context));
// Expect 1/4 localhost peers and 1/4 of the other peers to be protected,
// sorted by longest uptime (lowest m_connected), if no onion, I2P, or CJDNS peers.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id > 6);
c.m_network = NET_IPV6;
},
/*protected_peer_ids=*/{0, 1, 2, 7, 8, 9},
/*unprotected_peer_ids=*/{3, 4, 5, 6, 10, 11},
random_context));
// Expect 1/4 I2P peers to be protected from eviction,
// if no onion, localhost, or CJDNS peers.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_is_local = false;
c.m_network = (c.id == 2 || c.id == 7 || c.id == 10) ? NET_I2P : NET_IPV4;
},
/*protected_peer_ids=*/{2, 7, 10},
/*unprotected_peer_ids=*/{},
random_context));
// Expect 1/4 I2P peers and 1/4 of the other peers to be protected, sorted
// by longest uptime (lowest m_connected), if no onion, localhost, or CJDNS peers.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = false;
c.m_network = (c.id == 4 || c.id > 8) ? NET_I2P : NET_IPV6;
},
/*protected_peer_ids=*/{0, 1, 2, 4, 9, 10},
/*unprotected_peer_ids=*/{3, 5, 6, 7, 8, 11},
random_context));
// Expect 1/4 CJDNS peers to be protected from eviction,
// if no onion, localhost, or I2P peers.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_is_local = false;
c.m_network = (c.id == 2 || c.id == 7 || c.id == 10) ? NET_CJDNS : NET_IPV4;
},
/*protected_peer_ids=*/{2, 7, 10},
/*unprotected_peer_ids=*/{},
random_context));
// Expect 1/4 CJDNS peers and 1/4 of the other peers to be protected, sorted
// by longest uptime (lowest m_connected), if no onion, localhost, or I2P peers.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = false;
c.m_network = (c.id == 4 || c.id > 8) ? NET_CJDNS : NET_IPV6;
},
/*protected_peer_ids=*/{0, 1, 2, 4, 9, 10},
/*unprotected_peer_ids=*/{3, 5, 6, 7, 8, 11},
random_context));
// Tests with 2 networks...
// Combined test: expect having 1 localhost and 1 onion peer out of 4 to
// protect 1 localhost, 0 onion and 1 other peer, sorted by longest uptime;
// stable sort breaks tie with array order of localhost first.
BOOST_CHECK(IsProtected(
4, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 4);
c.m_network = (c.id == 3) ? NET_ONION : NET_IPV4;
},
/*protected_peer_ids=*/{0, 4},
/*unprotected_peer_ids=*/{1, 2},
random_context));
// Combined test: expect having 1 localhost and 1 onion peer out of 7 to
// protect 1 localhost, 0 onion, and 2 other peers (3 total), sorted by
// uptime; stable sort breaks tie with array order of localhost first.
BOOST_CHECK(IsProtected(
7, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 6);
c.m_network = (c.id == 5) ? NET_ONION : NET_IPV4;
},
/*protected_peer_ids=*/{0, 1, 6},
/*unprotected_peer_ids=*/{2, 3, 4, 5},
random_context));
// Combined test: expect having 1 localhost and 1 onion peer out of 8 to
// protect protect 1 localhost, 1 onion and 2 other peers (4 total), sorted
// by uptime; stable sort breaks tie with array order of localhost first.
BOOST_CHECK(IsProtected(
8, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 6);
c.m_network = (c.id == 5) ? NET_ONION : NET_IPV4;
},
/*protected_peer_ids=*/{0, 1, 5, 6},
/*unprotected_peer_ids=*/{2, 3, 4, 7},
random_context));
// Combined test: expect having 3 localhost and 3 onion peers out of 12 to
// protect 2 localhost and 1 onion, plus 3 other peers, sorted by longest
// uptime; stable sort breaks ties with the array order of localhost first.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 6 || c.id == 9 || c.id == 11);
c.m_network = (c.id == 7 || c.id == 8 || c.id == 10) ? NET_ONION : NET_IPV6;
},
/*protected_peer_ids=*/{0, 1, 2, 6, 7, 9},
/*unprotected_peer_ids=*/{3, 4, 5, 8, 10, 11},
random_context));
// Combined test: expect having 4 localhost and 1 onion peer out of 12 to
// protect 2 localhost and 1 onion, plus 3 other peers, sorted by longest uptime.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id > 4 && c.id < 9);
c.m_network = (c.id == 10) ? NET_ONION : NET_IPV4;
},
/*protected_peer_ids=*/{0, 1, 2, 5, 6, 10},
/*unprotected_peer_ids=*/{3, 4, 7, 8, 9, 11},
random_context));
// Combined test: expect having 4 localhost and 2 onion peers out of 16 to
// protect 2 localhost and 2 onions, plus 4 other peers, sorted by longest uptime.
BOOST_CHECK(IsProtected(
16, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 6 || c.id == 9 || c.id == 11 || c.id == 12);
c.m_network = (c.id == 8 || c.id == 10) ? NET_ONION : NET_IPV6;
},
/*protected_peer_ids=*/{0, 1, 2, 3, 6, 8, 9, 10},
/*unprotected_peer_ids=*/{4, 5, 7, 11, 12, 13, 14, 15},
random_context));
// Combined test: expect having 5 localhost and 1 onion peer out of 16 to
// protect 3 localhost (recovering the unused onion slot), 1 onion, and 4
// others, sorted by longest uptime.
BOOST_CHECK(IsProtected(
16, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id > 10);
c.m_network = (c.id == 10) ? NET_ONION : NET_IPV4;
},
/*protected_peer_ids=*/{0, 1, 2, 3, 10, 11, 12, 13},
/*unprotected_peer_ids=*/{4, 5, 6, 7, 8, 9, 14, 15},
random_context));
// Combined test: expect having 1 localhost and 4 onion peers out of 16 to
// protect 1 localhost and 3 onions (recovering the unused localhost slot),
// plus 4 others, sorted by longest uptime.
BOOST_CHECK(IsProtected(
16, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 15);
c.m_network = (c.id > 6 && c.id < 11) ? NET_ONION : NET_IPV6;
},
/*protected_peer_ids=*/{0, 1, 2, 3, 7, 8, 9, 15},
/*unprotected_peer_ids=*/{5, 6, 10, 11, 12, 13, 14},
random_context));
// Combined test: expect having 2 onion and 4 I2P out of 12 peers to protect
// 2 onion (prioritized for having fewer candidates) and 1 I2P, plus 3
// others, sorted by longest uptime.
BOOST_CHECK(IsProtected(
num_peers, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = false;
if (c.id == 8 || c.id == 10) {
c.m_network = NET_ONION;
} else if (c.id == 6 || c.id == 9 || c.id == 11 || c.id == 12) {
c.m_network = NET_I2P;
} else {
c.m_network = NET_IPV4;
}
},
/*protected_peer_ids=*/{0, 1, 2, 6, 8, 10},
/*unprotected_peer_ids=*/{3, 4, 5, 7, 9, 11},
random_context));
// Tests with 3 networks...
// Combined test: expect having 1 localhost, 1 I2P and 1 onion peer out of 4
// to protect 1 I2P, 0 localhost, 0 onion and 1 other peer (2 total), sorted
// by longest uptime; stable sort breaks tie with array order of I2P first.
BOOST_CHECK(IsProtected(
4, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 2);
if (c.id == 3) {
c.m_network = NET_I2P;
} else if (c.id == 1) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV6;
}
},
/*protected_peer_ids=*/{0, 3},
/*unprotected_peer_ids=*/{1, 2},
random_context));
// Combined test: expect having 1 localhost, 1 I2P and 1 onion peer out of 7
// to protect 1 I2P, 0 localhost, 0 onion and 2 other peers (3 total) sorted
// by longest uptime; stable sort breaks tie with array order of I2P first.
BOOST_CHECK(IsProtected(
7, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 4);
if (c.id == 6) {
c.m_network = NET_I2P;
} else if (c.id == 5) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV6;
}
},
/*protected_peer_ids=*/{0, 1, 6},
/*unprotected_peer_ids=*/{2, 3, 4, 5},
random_context));
// Combined test: expect having 1 localhost, 1 I2P and 1 onion peer out of 8
// to protect 1 I2P, 1 localhost, 0 onion and 2 other peers (4 total) sorted
// by uptime; stable sort breaks tie with array order of I2P then localhost.
BOOST_CHECK(IsProtected(
8, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 6);
if (c.id == 5) {
c.m_network = NET_I2P;
} else if (c.id == 4) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV6;
}
},
/*protected_peer_ids=*/{0, 1, 5, 6},
/*unprotected_peer_ids=*/{2, 3, 4, 7},
random_context));
// Combined test: expect having 4 localhost, 2 I2P, and 2 onion peers out of
// 16 to protect 1 localhost, 2 I2P, and 1 onion (4/16 total), plus 4 others
// for 8 total, sorted by longest uptime.
BOOST_CHECK(IsProtected(
16, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 6 || c.id > 11);
if (c.id == 7 || c.id == 11) {
c.m_network = NET_I2P;
} else if (c.id == 9 || c.id == 10) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV4;
}
},
/*protected_peer_ids=*/{0, 1, 2, 3, 6, 7, 9, 11},
/*unprotected_peer_ids=*/{4, 5, 8, 10, 12, 13, 14, 15},
random_context));
// Combined test: expect having 1 localhost, 8 I2P and 1 onion peer out of
// 24 to protect 1, 4, and 1 (6 total), plus 6 others for 12/24 total,
// sorted by longest uptime.
BOOST_CHECK(IsProtected(
24, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 12);
if (c.id > 14 && c.id < 23) { // 4 protected instead of usual 2
c.m_network = NET_I2P;
} else if (c.id == 23) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV6;
}
},
/*protected_peer_ids=*/{0, 1, 2, 3, 4, 5, 12, 15, 16, 17, 18, 23},
/*unprotected_peer_ids=*/{6, 7, 8, 9, 10, 11, 13, 14, 19, 20, 21, 22},
random_context));
// Combined test: expect having 1 localhost, 3 I2P and 6 onion peers out of
// 24 to protect 1, 3, and 2 (6 total, I2P has fewer candidates and so gets the
// unused localhost slot), plus 6 others for 12/24 total, sorted by longest uptime.
BOOST_CHECK(IsProtected(
24, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 15);
if (c.id == 12 || c.id == 14 || c.id == 17) {
c.m_network = NET_I2P;
} else if (c.id > 17) { // 4 protected instead of usual 2
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV4;
}
},
/*protected_peer_ids=*/{0, 1, 2, 3, 4, 5, 12, 14, 15, 17, 18, 19},
/*unprotected_peer_ids=*/{6, 7, 8, 9, 10, 11, 13, 16, 20, 21, 22, 23},
random_context));
// Combined test: expect having 1 localhost, 7 I2P and 4 onion peers out of
// 24 to protect 1 localhost, 2 I2P, and 3 onions (6 total), plus 6 others
// for 12/24 total, sorted by longest uptime.
BOOST_CHECK(IsProtected(
24, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 13);
if (c.id > 16) {
c.m_network = NET_I2P;
} else if (c.id == 12 || c.id == 14 || c.id == 15 || c.id == 16) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV6;
}
},
/*protected_peer_ids=*/{0, 1, 2, 3, 4, 5, 12, 13, 14, 15, 17, 18},
/*unprotected_peer_ids=*/{6, 7, 8, 9, 10, 11, 16, 19, 20, 21, 22, 23},
random_context));
// Combined test: expect having 8 localhost, 4 CJDNS, and 3 onion peers out
// of 24 to protect 2 of each (6 total), plus 6 others for 12/24 total,
// sorted by longest uptime.
BOOST_CHECK(IsProtected(
24, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id > 15);
if (c.id > 10 && c.id < 15) {
c.m_network = NET_CJDNS;
} else if (c.id > 6 && c.id < 10) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV4;
}
},
/*protected_peer_ids=*/{0, 1, 2, 3, 4, 5, 7, 8, 11, 12, 16, 17},
/*unprotected_peer_ids=*/{6, 9, 10, 13, 14, 15, 18, 19, 20, 21, 22, 23},
random_context));
// Tests with 4 networks...
// Combined test: expect having 1 CJDNS, 1 I2P, 1 localhost and 1 onion peer
// out of 5 to protect 1 CJDNS, 0 I2P, 0 localhost, 0 onion and 1 other peer
// (2 total), sorted by longest uptime; stable sort breaks tie with array
// order of CJDNS first.
BOOST_CHECK(IsProtected(
5, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 3);
if (c.id == 4) {
c.m_network = NET_CJDNS;
} else if (c.id == 1) {
c.m_network = NET_I2P;
} else if (c.id == 2) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV6;
}
},
/*protected_peer_ids=*/{0, 4},
/*unprotected_peer_ids=*/{1, 2, 3},
random_context));
// Combined test: expect having 1 CJDNS, 1 I2P, 1 localhost and 1 onion peer
// out of 7 to protect 1 CJDNS, 0, I2P, 0 localhost, 0 onion and 2 other
// peers (3 total) sorted by longest uptime; stable sort breaks tie with
// array order of CJDNS first.
BOOST_CHECK(IsProtected(
7, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 4);
if (c.id == 6) {
c.m_network = NET_CJDNS;
} else if (c.id == 5) {
c.m_network = NET_I2P;
} else if (c.id == 3) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV4;
}
},
/*protected_peer_ids=*/{0, 1, 6},
/*unprotected_peer_ids=*/{2, 3, 4, 5},
random_context));
// Combined test: expect having 1 CJDNS, 1 I2P, 1 localhost and 1 onion peer
// out of 8 to protect 1 CJDNS, 1 I2P, 0 localhost, 0 onion and 2 other
// peers (4 total) sorted by longest uptime; stable sort breaks tie with
// array order of CJDNS first.
BOOST_CHECK(IsProtected(
8, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 3);
if (c.id == 5) {
c.m_network = NET_CJDNS;
} else if (c.id == 6) {
c.m_network = NET_I2P;
} else if (c.id == 3) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV6;
}
},
/*protected_peer_ids=*/{0, 1, 5, 6},
/*unprotected_peer_ids=*/{2, 3, 4, 7},
random_context));
// Combined test: expect having 2 CJDNS, 2 I2P, 4 localhost, and 2 onion
// peers out of 16 to protect 1 CJDNS, 1 I2P, 1 localhost, 1 onion (4/16
// total), plus 4 others for 8 total, sorted by longest uptime.
BOOST_CHECK(IsProtected(
16, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id > 5);
if (c.id == 11 || c.id == 15) {
c.m_network = NET_CJDNS;
} else if (c.id == 10 || c.id == 14) {
c.m_network = NET_I2P;
} else if (c.id == 8 || c.id == 9) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV4;
}
},
/*protected_peer_ids=*/{0, 1, 2, 3, 6, 8, 10, 11},
/*unprotected_peer_ids=*/{4, 5, 7, 9, 12, 13, 14, 15},
random_context));
// Combined test: expect having 6 CJDNS, 1 I2P, 1 localhost, and 4 onion
// peers out of 24 to protect 2 CJDNS, 1 I2P, 1 localhost, and 2 onions (6
// total), plus 6 others for 12/24 total, sorted by longest uptime.
BOOST_CHECK(IsProtected(
24, [](NodeEvictionCandidate& c) {
c.m_connected = std::chrono::seconds{c.id};
c.m_is_local = (c.id == 13);
if (c.id > 17) {
c.m_network = NET_CJDNS;
} else if (c.id == 17) {
c.m_network = NET_I2P;
} else if (c.id == 12 || c.id == 14 || c.id == 15 || c.id == 16) {
c.m_network = NET_ONION;
} else {
c.m_network = NET_IPV6;
}
},
/*protected_peer_ids=*/{0, 1, 2, 3, 4, 5, 12, 13, 14, 17, 18, 19},
/*unprotected_peer_ids=*/{6, 7, 8, 9, 10, 11, 15, 16, 20, 21, 22, 23},
random_context));
}
// Returns true if any of the node ids in node_ids are selected for eviction.
bool IsEvicted(std::vector<NodeEvictionCandidate> candidates, const std::unordered_set<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 node_ids.count(*evicted_node_id);
}
// 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::unordered_set<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);
}
BOOST_AUTO_TEST_CASE(peer_eviction_test)
{
FastRandomContext random_context{true};
for (int number_of_nodes = 0; number_of_nodes < 200; ++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.m_last_tx_time = std::chrono::seconds{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.m_last_block_time = std::chrono::seconds{number_of_nodes - candidate.id};
if (candidate.id <= 7) {
candidate.m_relay_txs = 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.m_last_block_time = std::chrono::seconds{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.m_last_block_time = std::chrono::seconds{number_of_nodes - candidate.id};
if (candidate.id <= 7) {
candidate.m_relay_txs = 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.m_last_tx_time = std::chrono::seconds{number_of_nodes - candidate.id}; // 4 protected
candidate.m_last_block_time = std::chrono::seconds{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:
// * "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()