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transmission/tests/libtransmission/dht-test.cc
Mike Gelfand 57e6b06921
Modernize CMake code (ongoing refactoring) (#4515)
* Use imported CMake target for CURL

* Use imported CMake target for fmtlib

* Use imported CMake target for WideInteger

* Use imported CMake target for FastFloat

* Use imported CMake target for UtfCpp

* Use imported CMake target for Threads

* Use imported CMake target for Iconv

* Use imported CMake target for crypto backend

* Use imported CMake target for GTK

* Use imported CMake target for Qt

* Use imported CMake target for deflate

* Use imported CMake target for libevent

* Use imported CMake target for natpmp

* Use imported CMake target for miniupnpc

* Use imported CMake target for dht

* Use imported CMake target for psl

* Use imported CMake target for libutp

* Use imported CMake target for libb64

* Use include directories from libtransmission target
2023-01-02 16:23:51 +00:00

643 lines
20 KiB
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// This file Copyright (C) 2022 Mnemosyne LLC.
// It may be used under GPLv2 (SPDX: GPL-2.0-only), GPLv3 (SPDX: GPL-3.0-only),
// or any future license endorsed by Mnemosyne LLC.
// License text can be found in the licenses/ folder.
#include <algorithm>
#include <chrono>
#include <fstream>
#include <memory>
#include <utility>
#include <event2/event.h>
#include <libtransmission/transmission.h>
#include <libtransmission/file.h>
#include <libtransmission/timer-ev.h>
#include <libtransmission/session-thread.h> // for tr_evthread_init();
#include "gtest/gtest.h"
#include "test-fixtures.h"
#ifdef _WIN32
#undef gai_strerror
#define gai_strerror gai_strerrorA
#endif
using namespace std::literals;
namespace libtransmission::test
{
bool waitFor(struct event_base* event_base, std::chrono::milliseconds msec)
{
return waitFor(
event_base,
[]() { return false; },
msec);
}
namespace
{
auto constexpr IdLength = size_t{ 20U };
auto constexpr MockTimerInterval = 40ms;
} // namespace
class DhtTest : public SandboxedTest
{
protected:
// Helper for creating a mock dht.dat state file
struct MockStateFile
{
// Fake data to be written to the test state file
std::array<char, IdLength> const id_ = tr_rand_obj<std::array<char, IdLength>>();
std::vector<std::pair<tr_address, tr_port>> ipv4_nodes_ = {
std::make_pair(*tr_address::from_string("10.10.10.1"), tr_port::fromHost(128)),
std::make_pair(*tr_address::from_string("10.10.10.2"), tr_port::fromHost(129)),
std::make_pair(*tr_address::from_string("10.10.10.3"), tr_port::fromHost(130)),
std::make_pair(*tr_address::from_string("10.10.10.4"), tr_port::fromHost(131)),
std::make_pair(*tr_address::from_string("10.10.10.5"), tr_port::fromHost(132))
};
std::vector<std::pair<tr_address, tr_port>> ipv6_nodes_ = {
std::make_pair(*tr_address::from_string("1002:1035:4527:3546:7854:1237:3247:3217"), tr_port::fromHost(6881)),
std::make_pair(*tr_address::from_string("1002:1035:4527:3546:7854:1237:3247:3218"), tr_port::fromHost(6882)),
std::make_pair(*tr_address::from_string("1002:1035:4527:3546:7854:1237:3247:3219"), tr_port::fromHost(6883)),
std::make_pair(*tr_address::from_string("1002:1035:4527:3546:7854:1237:3247:3220"), tr_port::fromHost(6884)),
std::make_pair(*tr_address::from_string("1002:1035:4527:3546:7854:1237:3247:3221"), tr_port::fromHost(6885))
};
[[nodiscard]] auto nodesString() const
{
auto str = std::string{};
for (auto const& [addr, port] : ipv4_nodes_)
{
str += addr.display_name(port);
str += ',';
}
for (auto const& [addr, port] : ipv6_nodes_)
{
str += addr.display_name(port);
str += ',';
}
return str;
}
[[nodiscard]] static auto filename(std::string_view dirname)
{
return std::string{ dirname } + "/dht.dat";
}
void save(std::string_view path) const
{
auto const dat_file = MockStateFile::filename(path);
auto dict = tr_variant{};
tr_variantInitDict(&dict, 3U);
tr_variantDictAddRaw(&dict, TR_KEY_id, std::data(id_), std::size(id_));
auto compact = std::vector<std::byte>{};
for (auto const& [addr, port] : ipv4_nodes_)
{
addr.to_compact_ipv4(std::back_inserter(compact), port);
}
tr_variantDictAddRaw(&dict, TR_KEY_nodes, std::data(compact), std::size(compact));
compact.clear();
for (auto const& [addr, port] : ipv6_nodes_)
{
addr.to_compact_ipv6(std::back_inserter(compact), port);
}
tr_variantDictAddRaw(&dict, TR_KEY_nodes6, std::data(compact), std::size(compact));
tr_variantToFile(&dict, TR_VARIANT_FMT_BENC, dat_file);
tr_variantClear(&dict);
}
};
// A fake libdht for the tests to call
class MockDht final : public tr_dht::API
{
public:
int get_nodes(struct sockaddr_in* /*sin*/, int* /*max*/, struct sockaddr_in6* /*sin6*/, int* /*max6*/) override
{
return 0;
}
int nodes(int /*af*/, int* good, int* dubious, int* cached, int* incoming) override
{
if (good != nullptr)
{
*good = good_;
}
if (dubious != nullptr)
{
*dubious = dubious_;
}
if (cached != nullptr)
{
*cached = cached_;
}
if (incoming != nullptr)
{
*incoming = incoming_;
}
return 0;
}
int periodic(
void const* /*buf*/,
size_t /*buflen*/,
sockaddr const /*from*/*,
int /*fromlen*/,
time_t* /*tosleep*/,
dht_callback_t /*callback*/,
void* /*closure*/) override
{
++n_periodic_calls_;
return 0;
}
int ping_node(struct sockaddr const* sa, int /*salen*/) override
{
auto addrport = tr_address::from_sockaddr(sa);
auto const [addr, port] = *addrport;
pinged_.push_back(Pinged{ addr, port, tr_time() });
return 0;
}
int search(unsigned char const* id, int port, int af, dht_callback_t /*callback*/, void* /*closure*/) override
{
auto info_hash = tr_sha1_digest_t{};
std::copy_n(reinterpret_cast<std::byte const*>(id), std::size(info_hash), std::data(info_hash));
searched_.push_back(Searched{ info_hash, tr_port::fromHost(port), af });
return 0;
}
int init(int dht_socket, int dht_socket6, unsigned const char* id, unsigned const char* /*v*/) override
{
inited_ = true;
dht_socket_ = dht_socket;
dht_socket6_ = dht_socket6;
std::copy_n(id, std::size(id_), std::begin(id_));
return 0;
}
int uninit() override
{
inited_ = false;
return 0;
}
constexpr void setHealthySwarm()
{
good_ = 50;
incoming_ = 10;
}
constexpr void setFirewalledSwarm()
{
good_ = 50;
incoming_ = 0;
}
constexpr void setPoorSwarm()
{
good_ = 10;
incoming_ = 1;
}
struct Searched
{
tr_sha1_digest_t info_hash;
tr_port port;
int af;
};
struct Pinged
{
tr_address address;
tr_port port;
time_t timestamp;
};
int good_ = 0;
int dubious_ = 0;
int cached_ = 0;
int incoming_ = 0;
size_t n_periodic_calls_ = 0;
bool inited_ = false;
std::vector<Pinged> pinged_;
std::vector<Searched> searched_;
std::array<char, IdLength> id_ = {};
tr_socket_t dht_socket_ = TR_BAD_SOCKET;
tr_socket_t dht_socket6_ = TR_BAD_SOCKET;
};
// Creates real timers, but with shortened intervals so that tests can run faster
class MockTimer final : public libtransmission::Timer
{
public:
explicit MockTimer(std::unique_ptr<Timer> real_timer)
: real_timer_{ std::move(real_timer) }
{
}
void stop() override
{
real_timer_->stop();
}
void setCallback(std::function<void()> callback) override
{
real_timer_->setCallback(std::move(callback));
}
void setRepeating(bool repeating = true) override
{
real_timer_->setRepeating(repeating);
}
void setInterval(std::chrono::milliseconds /*interval*/) override
{
real_timer_->setInterval(MockTimerInterval);
}
void start() override
{
real_timer_->start();
}
[[nodiscard]] std::chrono::milliseconds interval() const noexcept override
{
return real_timer_->interval();
}
[[nodiscard]] bool isRepeating() const noexcept override
{
return real_timer_->isRepeating();
}
private:
std::unique_ptr<Timer> const real_timer_;
};
// Creates MockTimers
class MockTimerMaker final : public libtransmission::TimerMaker
{
public:
explicit MockTimerMaker(struct event_base* evb)
: real_timer_maker_{ evb }
{
}
[[nodiscard]] std::unique_ptr<Timer> create() override
{
return std::make_unique<MockTimer>(real_timer_maker_.create());
}
EvTimerMaker real_timer_maker_;
};
class MockMediator final : public tr_dht::Mediator
{
public:
explicit MockMediator(struct event_base* event_base)
: mock_timer_maker_{ event_base }
{
}
[[nodiscard]] std::vector<tr_torrent_id_t> torrentsAllowingDHT() const override
{
return torrents_allowing_dht_;
}
[[nodiscard]] tr_sha1_digest_t torrentInfoHash(tr_torrent_id_t id) const override
{
if (auto const iter = info_hashes_.find(id); iter != std::end(info_hashes_))
{
return iter->second;
}
return {};
}
[[nodiscard]] std::string_view configDir() const override
{
return config_dir_;
}
[[nodiscard]] libtransmission::TimerMaker& timerMaker() override
{
return mock_timer_maker_;
}
[[nodiscard]] tr_dht::API& api() override
{
return mock_dht_;
}
void addPex(tr_sha1_digest_t const& /*info_hash*/, tr_pex const* /*pex*/, size_t /*n_pex*/) override
{
}
std::string config_dir_;
std::vector<tr_torrent_id_t> torrents_allowing_dht_;
std::map<tr_torrent_id_t, tr_sha1_digest_t> info_hashes_;
MockDht mock_dht_;
MockTimerMaker mock_timer_maker_;
};
[[nodiscard]] static std::pair<tr_address, tr_port> getSockaddr(std::string_view name, tr_port port)
{
auto hints = addrinfo{};
hints.ai_socktype = SOCK_DGRAM;
hints.ai_family = AF_UNSPEC;
auto const szname = tr_urlbuf{ name };
auto const port_str = std::to_string(port.host());
addrinfo* info = nullptr;
if (int const rc = getaddrinfo(szname.c_str(), std::data(port_str), &hints, &info); rc != 0)
{
tr_logAddWarn(fmt::format(
_("Couldn't look up '{address}:{port}': {error} ({error_code})"),
fmt::arg("address", name),
fmt::arg("port", port.host()),
fmt::arg("error", gai_strerror(rc)),
fmt::arg("error_code", rc)));
return {};
}
auto opt = tr_address::from_sockaddr(info->ai_addr);
freeaddrinfo(info);
if (opt)
{
return *opt;
}
return {};
}
void SetUp() override
{
SandboxedTest::SetUp();
tr_session_thread::tr_evthread_init();
event_base_ = event_base_new();
}
void TearDown() override
{
event_base_free(event_base_);
event_base_ = nullptr;
SandboxedTest::TearDown();
}
struct event_base* event_base_ = nullptr;
// Arbitrary values. Several tests requires socket/port values
// to be provided but they aren't central to the tests, so they're
// declared here with "Arbitrary" in the name to make that clear.
static auto constexpr ArbitrarySock4 = tr_socket_t{ 404 };
static auto constexpr ArbitrarySock6 = tr_socket_t{ 418 };
static auto constexpr ArbitraryPeerPort = tr_port::fromHost(909);
};
TEST_F(DhtTest, initsWithCorrectSockets)
{
static auto constexpr Sock4 = tr_socket_t{ 1000 };
static auto constexpr Sock6 = tr_socket_t{ 2000 };
// Make the DHT
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, Sock4, Sock6);
// Confirm that dht_init() was called with the right sockets
EXPECT_EQ(Sock4, mediator.mock_dht_.dht_socket_);
EXPECT_EQ(Sock6, mediator.mock_dht_.dht_socket6_);
}
TEST_F(DhtTest, callsUninitOnDestruct)
{
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
EXPECT_FALSE(mediator.mock_dht_.inited_);
{
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, ArbitrarySock4, ArbitrarySock6);
EXPECT_TRUE(mediator.mock_dht_.inited_);
// dht goes out-of-scope here
}
EXPECT_FALSE(mediator.mock_dht_.inited_);
}
TEST_F(DhtTest, loadsStateFromStateFile)
{
auto const state_file = MockStateFile{};
state_file.save(sandboxDir());
// Make the DHT
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, ArbitrarySock4, ArbitrarySock6);
// Wait for all the state nodes to be pinged
auto& pinged = mediator.mock_dht_.pinged_;
auto const n_expected_nodes = std::size(state_file.ipv4_nodes_) + std::size(state_file.ipv6_nodes_);
waitFor(event_base_, [&pinged, n_expected_nodes]() { return std::size(pinged) >= n_expected_nodes; });
auto actual_nodes_str = std::string{};
for (auto const& [addr, port, timestamp] : pinged)
{
actual_nodes_str += addr.display_name(port);
actual_nodes_str += ',';
}
/// Confirm that the state was loaded
// dht_init() should have been called with the state file's id
EXPECT_EQ(state_file.id_, mediator.mock_dht_.id_);
// dht_ping_nodedht_init() should have been called with state file's nodes
EXPECT_EQ(state_file.nodesString(), actual_nodes_str);
}
TEST_F(DhtTest, stopsBootstrappingWhenSwarmHealthIsGoodEnough)
{
auto const state_file = MockStateFile{};
state_file.save(sandboxDir());
// Make the DHT
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, ArbitrarySock4, ArbitrarySock6);
// Wait for N pings to occur...
auto& mock_dht = mediator.mock_dht_;
static auto constexpr TurnGoodAfterNthPing = size_t{ 3 };
waitFor(event_base_, [&mock_dht]() { return std::size(mock_dht.pinged_) == TurnGoodAfterNthPing; });
EXPECT_EQ(TurnGoodAfterNthPing, std::size(mock_dht.pinged_));
// Now fake that libdht says the swarm is healthy.
// This should cause bootstrapping to end.
mock_dht.setHealthySwarm();
// Now test to see if bootstrapping is done.
// There's not public API for `isBootstrapping()`,
// so to test this we just a moment to confirm that no more bootstrap nodes are pinged.
waitFor(event_base_, MockTimerInterval * 10);
// Confirm that the number of nodes pinged is unchanged,
// indicating that boostrapping is done
EXPECT_EQ(TurnGoodAfterNthPing, std::size(mock_dht.pinged_));
}
TEST_F(DhtTest, savesStateIfSwarmIsGood)
{
auto const state_file = MockStateFile{};
auto const dat_file = MockStateFile::filename(sandboxDir());
EXPECT_FALSE(tr_sys_path_exists(dat_file.c_str()));
{
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
mediator.mock_dht_.setHealthySwarm();
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, ArbitrarySock4, ArbitrarySock6);
// as dht goes out of scope,
// it should save its state if the swarm is healthy
EXPECT_FALSE(tr_sys_path_exists(dat_file.c_str()));
}
EXPECT_TRUE(tr_sys_path_exists(dat_file.c_str()));
}
TEST_F(DhtTest, doesNotSaveStateIfSwarmIsBad)
{
auto const state_file = MockStateFile{};
auto const dat_file = MockStateFile::filename(sandboxDir());
EXPECT_FALSE(tr_sys_path_exists(dat_file.c_str()));
{
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
mediator.mock_dht_.setPoorSwarm();
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, ArbitrarySock4, ArbitrarySock6);
// as dht goes out of scope,
// it should save its state if the swarm is healthy
EXPECT_FALSE(tr_sys_path_exists(dat_file.c_str()));
}
EXPECT_FALSE(tr_sys_path_exists(dat_file.c_str()));
}
TEST_F(DhtTest, usesBootstrapFile)
{
// Make the 'dht.bootstrap' file.
// This a file with each line holding `${host} ${port}`
// which tr-dht will try to ping as nodes
static auto constexpr BootstrapNodeName = "example.com"sv;
static auto constexpr BootstrapNodePort = tr_port::fromHost(8080);
if (auto ofs = std::ofstream{ tr_pathbuf{ sandboxDir(), "/dht.bootstrap" } }; ofs)
{
ofs << BootstrapNodeName << ' ' << BootstrapNodePort.host() << std::endl;
ofs.close();
}
// Make the DHT
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, ArbitrarySock4, ArbitrarySock6);
// We didn't create a 'dht.dat' file to load state from,
// so 'dht.bootstrap' should be the first nodes in the bootstrap list.
// Confirm that BootstrapNodeName gets pinged first.
auto const expected = getSockaddr(BootstrapNodeName, BootstrapNodePort);
auto& pinged = mediator.mock_dht_.pinged_;
waitFor(
event_base_,
[&pinged]() { return !std::empty(pinged); },
5s);
ASSERT_EQ(1U, std::size(pinged));
auto const actual = pinged.front();
EXPECT_EQ(expected.first, actual.address);
EXPECT_EQ(expected.second, actual.port);
EXPECT_EQ(expected.first.display_name(expected.second), actual.address.display_name(actual.port));
}
TEST_F(DhtTest, pingsAddedNodes)
{
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, ArbitrarySock4, ArbitrarySock6);
EXPECT_EQ(0U, std::size(mediator.mock_dht_.pinged_));
auto const addr = *tr_address::from_string("10.10.10.1");
auto constexpr Port = tr_port::fromHost(128);
dht->addNode(addr, Port);
ASSERT_EQ(1U, std::size(mediator.mock_dht_.pinged_));
EXPECT_EQ(addr, mediator.mock_dht_.pinged_.front().address);
EXPECT_EQ(Port, mediator.mock_dht_.pinged_.front().port);
}
TEST_F(DhtTest, announcesTorrents)
{
auto constexpr Id = tr_torrent_id_t{ 1 };
auto constexpr PeerPort = tr_port::fromHost(999);
auto const info_hash = tr_rand_obj<tr_sha1_digest_t>();
tr_timeUpdate(time(nullptr));
auto mediator = MockMediator{ event_base_ };
mediator.info_hashes_[Id] = info_hash;
mediator.torrents_allowing_dht_ = { Id };
mediator.config_dir_ = sandboxDir();
// Since we're mocking a swarm that's magically healthy out-of-the-box,
// the DHT object we create can skip bootstrapping and proceed straight
// to announces
auto& mock_dht = mediator.mock_dht_;
mock_dht.setHealthySwarm();
auto dht = tr_dht::create(mediator, PeerPort, ArbitrarySock4, ArbitrarySock6);
waitFor(event_base_, MockTimerInterval * 10);
ASSERT_EQ(2U, std::size(mock_dht.searched_));
EXPECT_EQ(info_hash, mock_dht.searched_[0].info_hash);
EXPECT_EQ(PeerPort, mock_dht.searched_[0].port);
EXPECT_EQ(AF_INET, mock_dht.searched_[0].af);
EXPECT_EQ(info_hash, mock_dht.searched_[1].info_hash);
EXPECT_EQ(PeerPort, mock_dht.searched_[1].port);
EXPECT_EQ(AF_INET6, mock_dht.searched_[1].af);
}
TEST_F(DhtTest, callsPeriodicPeriodically)
{
auto mediator = MockMediator{ event_base_ };
mediator.config_dir_ = sandboxDir();
auto dht = tr_dht::create(mediator, ArbitraryPeerPort, ArbitrarySock4, ArbitrarySock6);
auto& mock_dht = mediator.mock_dht_;
auto const baseline = mock_dht.n_periodic_calls_;
static auto constexpr Periods = 10;
waitFor(event_base_, std::chrono::duration_cast<std::chrono::milliseconds>(MockTimerInterval * Periods));
EXPECT_NEAR(mock_dht.n_periodic_calls_, baseline + Periods, Periods / 2.0);
}
} // namespace libtransmission::test