/* Copyright (c) 2008, Arvid Norberg All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the author nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "libtorrent/session.hpp" #include "libtorrent/session_settings.hpp" #include "libtorrent/hasher.hpp" #include "libtorrent/alert_types.hpp" #include "libtorrent/bencode.hpp" #include "libtorrent/thread.hpp" #include "libtorrent/time.hpp" #include "libtorrent/file.hpp" #include #include #include "test.hpp" #include "setup_transfer.hpp" #include #include using namespace libtorrent; using boost::tuples::ignore; // test the maximum transfer rate void test_rate() { // in case the previous run was terminated error_code ec; remove_all("./tmp1_transfer", ec); remove_all("./tmp2_transfer", ec); remove_all("./tmp1_transfer_moved", ec); remove_all("./tmp2_transfer_moved", ec); session ses1(fingerprint("LT", 0, 1, 0, 0), std::make_pair(48575, 49000), "0.0.0.0", 0); session ses2(fingerprint("LT", 0, 1, 0, 0), std::make_pair(49575, 50000), "0.0.0.0", 0); torrent_handle tor1; torrent_handle tor2; create_directory("./tmp1_transfer", ec); std::ofstream file("./tmp1_transfer/temporary"); boost::intrusive_ptr t = ::create_torrent(&file, 4 * 1024 * 1024, 7); file.close(); boost::tie(tor1, tor2, ignore) = setup_transfer(&ses1, &ses2, 0 , true, false, true, "_transfer", 0, &t); ses1.set_alert_mask(alert::all_categories & ~alert::progress_notification & ~alert::stats_notification); ses2.set_alert_mask(alert::all_categories & ~alert::progress_notification & ~alert::stats_notification); ptime start = time_now(); for (int i = 0; i < 70; ++i) { print_alerts(ses1, "ses1"); print_alerts(ses2, "ses2"); torrent_status st1 = tor1.status(); torrent_status st2 = tor2.status(); std::cerr << "up: \033[33m" << st1.upload_payload_rate / 1000000.f << "MB/s " << " down: \033[32m" << st2.download_payload_rate / 1000000.f << "MB/s " << "\033[0m" << int(st2.progress * 100) << "% " << std::endl; if (tor2.is_seed()) break; test_sleep(100); } TEST_CHECK(tor2.is_seed()); time_duration dt = time_now() - start; std::cerr << "downloaded " << t->total_size() << " bytes " "in " << (total_milliseconds(dt) / 1000.f) << " seconds" << std::endl; std::cerr << "average download rate: " << (t->total_size() / (std::max)(total_milliseconds(dt), 1)) << " kB/s" << std::endl; } void print_alert(std::auto_ptr) { std::cout << "ses1 (alert dispatch function): "/* << a.message() */ << std::endl; } // simulate a full disk struct test_storage : storage_interface { test_storage(file_storage const& fs, std::string const& p, file_pool& fp) : m_lower_layer(default_storage_constructor(fs, 0, p, fp, std::vector())) , m_written(0) , m_limit(16 * 1024 * 2) {} virtual bool initialize(bool allocate_files) { return m_lower_layer->initialize(allocate_files); } virtual bool has_any_file() { return m_lower_layer->has_any_file(); } virtual int readv(file::iovec_t const* bufs, int slot, int offset, int num_bufs) { return m_lower_layer->readv(bufs, slot, offset, num_bufs); } virtual int writev(file::iovec_t const* bufs, int slot, int offset, int num_bufs) { int ret = m_lower_layer->writev(bufs, slot, offset, num_bufs); if (ret > 0) m_written += ret; if (m_written > m_limit) { #if BOOST_VERSION == 103500 set_error("", error_code(boost::system::posix_error::no_space_on_device, get_posix_category())); #elif BOOST_VERSION > 103500 set_error("", error_code(boost::system::errc::no_space_on_device, get_posix_category())); #else set_error("", error_code(ENOSPC, get_posix_category())); #endif return -1; } return ret; } virtual size_type physical_offset(int piece_index, int offset) { return m_lower_layer->physical_offset(piece_index, offset); } virtual int read(char* buf, int slot, int offset, int size) { return m_lower_layer->read(buf, slot, offset, size); } virtual int write(const char* buf, int slot, int offset, int size) { int ret = m_lower_layer->write(buf, slot, offset, size); if (ret > 0) m_written += ret; if (m_written > m_limit) { #if BOOST_VERSION == 103500 set_error("", error_code(boost::system::posix_error::no_space_on_device, get_posix_category())); #elif BOOST_VERSION > 103500 set_error("", error_code(boost::system::errc::no_space_on_device, get_posix_category())); #else set_error("", error_code(ENOSPC, get_posix_category())); #endif return -1; } return ret; } virtual int sparse_end(int start) const { return m_lower_layer->sparse_end(start); } virtual bool move_storage(std::string const& save_path) { return m_lower_layer->move_storage(save_path); } virtual bool verify_resume_data(lazy_entry const& rd, error_code& error) { return m_lower_layer->verify_resume_data(rd, error); } virtual bool write_resume_data(entry& rd) const { return m_lower_layer->write_resume_data(rd); } virtual bool move_slot(int src_slot, int dst_slot) { return m_lower_layer->move_slot(src_slot, dst_slot); } virtual bool swap_slots(int slot1, int slot2) { return m_lower_layer->swap_slots(slot1, slot2); } virtual bool swap_slots3(int slot1, int slot2, int slot3) { return m_lower_layer->swap_slots3(slot1, slot2, slot3); } virtual bool release_files() { return m_lower_layer->release_files(); } virtual bool rename_file(int index, std::string const& new_filename) { return m_lower_layer->rename_file(index, new_filename); } virtual bool delete_files() { return m_lower_layer->delete_files(); } virtual ~test_storage() {} boost::scoped_ptr m_lower_layer; int m_written; int m_limit; }; storage_interface* test_storage_constructor(file_storage const& fs , file_storage const*, std::string const& path, file_pool& fp, std::vector const&) { return new test_storage(fs, path, fp); } int tracker_responses = 0; bool on_alert(alert* a) { if (alert_cast(a)) ++tracker_responses; return false; } void test_transfer(int proxy_type, bool test_disk_full = false, bool test_allowed_fast = false) { char const* test_name[] = {"no", "SOCKS4", "SOCKS5", "SOCKS5 password", "HTTP", "HTTP password"}; fprintf(stderr, "\n\n ==== TESTING %s proxy ====\n\n\n", test_name[proxy_type]); // in case the previous run was terminated error_code ec; remove_all("./tmp1_transfer", ec); remove_all("./tmp2_transfer", ec); remove_all("./tmp1_transfer_moved", ec); remove_all("./tmp2_transfer_moved", ec); session ses1(fingerprint("LT", 0, 1, 0, 0), std::make_pair(48075, 49000), "0.0.0.0", 0); session ses2(fingerprint("LT", 0, 1, 0, 0), std::make_pair(49075, 50000), "0.0.0.0", 0); int proxy_port = (rand() % 30000) + 10000; if (proxy_type) { start_proxy(proxy_port, proxy_type); proxy_settings ps; ps.hostname = "127.0.0.1"; ps.port = proxy_port; ps.username = "testuser"; ps.password = "testpass"; ps.type = (proxy_settings::proxy_type)proxy_type; ses1.set_tracker_proxy(ps); ses2.set_tracker_proxy(ps); } session_settings sett; if (test_allowed_fast) { sett.allowed_fast_set_size = 2000; ses1.set_max_uploads(0); } sett.min_reconnect_time = 1; sett.announce_to_all_trackers = true; sett.announce_to_all_tiers = true; // make sure we announce to both http and udp trackers sett.prefer_udp_trackers = false; ses1.set_settings(sett); ses2.set_settings(sett); #ifndef TORRENT_DISABLE_ENCRYPTION pe_settings pes; pes.out_enc_policy = pe_settings::forced; pes.in_enc_policy = pe_settings::forced; ses1.set_pe_settings(pes); ses2.set_pe_settings(pes); #endif torrent_handle tor1; torrent_handle tor2; create_directory("./tmp1_transfer", ec); std::ofstream file("./tmp1_transfer/temporary"); boost::intrusive_ptr t = ::create_torrent(&file, 16 * 1024, 13, false); file.close(); int udp_tracker_port = start_tracker(); int tracker_port = start_web_server(); char tracker_url[200]; snprintf(tracker_url, sizeof(tracker_url), "http://127.0.0.1:%d/announce", tracker_port); t->add_tracker(tracker_url); snprintf(tracker_url, sizeof(tracker_url), "udp://127.0.0.1:%d/announce", udp_tracker_port); t->add_tracker(tracker_url); add_torrent_params addp(&test_storage_constructor); // test using piece sizes smaller than 16kB boost::tie(tor1, tor2, ignore) = setup_transfer(&ses1, &ses2, 0 , true, false, true, "_transfer", 8 * 1024, &t, false, test_disk_full?&addp:0); // set half of the pieces to priority 0 int num_pieces = tor2.get_torrent_info().num_pieces(); std::vector priorities(num_pieces, 1); std::fill(priorities.begin(), priorities.begin() + (num_pieces / 2), 0); tor2.prioritize_pieces(priorities); std::cerr << "setting priorities: "; std::copy(priorities.begin(), priorities.end(), std::ostream_iterator(std::cerr, ", ")); std::cerr << std::endl; ses1.set_alert_mask(alert::all_categories & ~alert::progress_notification & ~alert::stats_notification); ses2.set_alert_mask(alert::all_categories & ~alert::progress_notification & ~alert::stats_notification); ses1.set_alert_dispatch(&print_alert); ses2.set_download_rate_limit(tor2.get_torrent_info().piece_length() * 5); // also test to move the storage of the downloader and the uploader // to make sure it can handle switching paths bool test_move_storage = false; tracker_responses = 0; for (int i = 0; i < 50; ++i) { print_alerts(ses1, "ses1", true, true, true, on_alert); print_alerts(ses2, "ses2", true, true, true, on_alert); torrent_status st1 = tor1.status(); torrent_status st2 = tor2.status(); std::cerr << "\033[32m" << int(st1.download_payload_rate / 1000.f) << "kB/s " << "\033[33m" << int(st1.upload_payload_rate / 1000.f) << "kB/s " << "\033[0m" << int(st1.progress * 100) << "% " << st1.num_peers << ": " << "\033[32m" << int(st2.download_payload_rate / 1000.f) << "kB/s " << "\033[31m" << int(st2.upload_payload_rate / 1000.f) << "kB/s " << "\033[0m" << int(st2.progress * 100) << "% " << st2.num_peers << " cc: " << st2.connect_candidates << std::endl; if (!test_move_storage && st2.progress > 0.25f) { test_move_storage = true; tor1.move_storage("./tmp1_transfer_moved"); tor2.move_storage("./tmp2_transfer_moved"); std::cerr << "moving storage" << std::endl; } if (test_disk_full && st2.upload_mode) { test_disk_full = false; ((test_storage*)tor2.get_storage_impl())->m_limit = 16 * 1024 * 1024; tor2.set_upload_mode(false); continue; } if (!test_disk_full && tor2.is_finished()) break; TEST_CHECK(st1.state == torrent_status::seeding || st1.state == torrent_status::checking_files); TEST_CHECK(st2.state == torrent_status::downloading || (test_disk_full && !st2.error.empty())); test_sleep(100); } // 1 announce per tracker to start TEST_EQUAL(tracker_responses, 2); TEST_CHECK(!tor2.is_seed()); TEST_CHECK(tor2.is_finished()); if (tor2.is_finished()) std::cerr << "torrent is finished (50% complete)" << std::endl; std::cerr << "force recheck" << std::endl; tor2.force_recheck(); for (int i = 0; i < 50; ++i) { test_sleep(100); print_alerts(ses2, "ses2"); torrent_status st2 = tor2.status(); std::cerr << "\033[0m" << int(st2.progress * 100) << "% " << std::endl; if (st2.state != torrent_status::checking_files) break; } std::vector priorities2 = tor2.piece_priorities(); TEST_CHECK(std::equal(priorities.begin(), priorities.end(), priorities2.begin())); for (int i = 0; i < 5; ++i) { print_alerts(ses2, "ses2"); torrent_status st2 = tor2.status(); std::cerr << "\033[0m" << int(st2.progress * 100) << "% " << std::endl; TEST_CHECK(st2.state == torrent_status::finished); test_sleep(100); } tor2.pause(); alert const* a = ses2.wait_for_alert(seconds(10)); bool got_paused_alert = false; while (a) { std::auto_ptr holder = ses2.pop_alert(); std::cerr << "ses2: " << a->message() << std::endl; if (alert_cast(a)) { got_paused_alert = true; break; } a = ses2.wait_for_alert(seconds(10)); } TEST_CHECK(got_paused_alert); std::vector tr = tor2.trackers(); tr.push_back(announce_entry("http://test.com/announce")); tor2.replace_trackers(tr); tr.clear(); tor2.save_resume_data(); std::vector resume_data; a = ses2.wait_for_alert(seconds(10)); while (a) { std::auto_ptr holder = ses2.pop_alert(); std::cerr << "ses2: " << a->message() << std::endl; if (alert_cast(a)) { bencode(std::back_inserter(resume_data) , *alert_cast(a)->resume_data); break; } a = ses2.wait_for_alert(seconds(10)); } TEST_CHECK(resume_data.size()); std::cerr << "saved resume data" << std::endl; ses2.remove_torrent(tor2); std::cerr << "removed" << std::endl; test_sleep(100); std::cout << "re-adding" << std::endl; add_torrent_params p; p.ti = t; p.save_path = "./tmp2_transfer_moved"; p.resume_data = &resume_data; tor2 = ses2.add_torrent(p, ec); ses2.set_alert_mask(alert::all_categories & ~alert::progress_notification & ~alert::stats_notification); tor2.prioritize_pieces(priorities); std::cout << "resetting priorities" << std::endl; tor2.resume(); tr = tor2.trackers(); TEST_CHECK(std::find_if(tr.begin(), tr.end() , boost::bind(&announce_entry::url, _1) == "http://test.com/announce") != tr.end()); test_sleep(100); for (int i = 0; i < 5; ++i) { print_alerts(ses1, "ses1"); print_alerts(ses2, "ses2"); torrent_status st1 = tor1.status(); torrent_status st2 = tor2.status(); TEST_CHECK(st1.state == torrent_status::seeding); TEST_CHECK(st2.state == torrent_status::finished); test_sleep(100); } TEST_CHECK(!tor2.is_seed()); std::fill(priorities.begin(), priorities.end(), 1); tor2.prioritize_pieces(priorities); std::cout << "setting priorities to 1" << std::endl; for (int i = 0; i < 130; ++i) { print_alerts(ses1, "ses1"); print_alerts(ses2, "ses2"); torrent_status st1 = tor1.status(); torrent_status st2 = tor2.status(); std::cerr << "\033[32m" << int(st1.download_payload_rate / 1000.f) << "kB/s " << "\033[33m" << int(st1.upload_payload_rate / 1000.f) << "kB/s " << "\033[0m" << int(st1.progress * 100) << "% " << st1.num_peers << ": " << "\033[32m" << int(st2.download_payload_rate / 1000.f) << "kB/s " << "\033[31m" << int(st2.upload_payload_rate / 1000.f) << "kB/s " << "\033[0m" << int(st2.progress * 100) << "% " << st2.num_peers << " cc: " << st2.connect_candidates << std::endl; if (tor2.is_finished()) break; TEST_CHECK(st1.state == torrent_status::seeding); TEST_CHECK(st2.state == torrent_status::downloading); test_sleep(100); } TEST_CHECK(tor2.is_seed()); stop_tracker(); stop_web_server(); if (proxy_type) stop_proxy(proxy_port); } int test_main() { using namespace libtorrent; #ifdef NDEBUG // test rate only makes sense in release mode test_rate(); #endif // test with all kinds of proxies for (int i = 0; i < 6; ++i) test_transfer(i); // test with a (simulated) full disk test_transfer(0, true); // test allowed fast test_transfer(0, false, true); error_code ec; remove_all("./tmp1_transfer", ec); remove_all("./tmp2_transfer", ec); remove_all("./tmp1_transfer_moved", ec); remove_all("./tmp2_transfer_moved", ec); return 0; }