34f2a9ea72
Instead of having each test individually initialize and tear down SSL move this to unittest_main.cc so that all tests are properly initialized and new tests "don't have to think about it". R=pthatcher@webrtc.org BUG= Review URL: https://webrtc-codereview.appspot.com/30549004 git-svn-id: http://webrtc.googlecode.com/svn/trunk@7316 4adac7df-926f-26a2-2b94-8c16560cd09d
1720 lines
73 KiB
C++
1720 lines
73 KiB
C++
/*
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* libjingle
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* Copyright 2009 Google Inc.
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions are met:
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*
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* 1. Redistributions of source code must retain the above copyright notice,
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* this list of conditions and the following disclaimer.
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* 2. Redistributions in binary form must reproduce the above copyright notice,
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* this list of conditions and the following disclaimer in the documentation
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* and/or other materials provided with the distribution.
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* 3. The name of the author may not be used to endorse or promote products
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* derived from this software without specific prior written permission.
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*
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* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
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* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
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* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
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* EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
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* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
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* OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
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* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
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* OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
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* ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
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#include "talk/p2p/base/p2ptransportchannel.h"
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#include "talk/p2p/base/testrelayserver.h"
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#include "talk/p2p/base/teststunserver.h"
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#include "talk/p2p/base/testturnserver.h"
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#include "talk/p2p/client/basicportallocator.h"
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#include "webrtc/base/dscp.h"
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#include "webrtc/base/fakenetwork.h"
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#include "webrtc/base/firewallsocketserver.h"
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#include "webrtc/base/gunit.h"
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#include "webrtc/base/helpers.h"
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#include "webrtc/base/logging.h"
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#include "webrtc/base/natserver.h"
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#include "webrtc/base/natsocketfactory.h"
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#include "webrtc/base/physicalsocketserver.h"
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#include "webrtc/base/proxyserver.h"
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#include "webrtc/base/socketaddress.h"
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#include "webrtc/base/ssladapter.h"
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#include "webrtc/base/thread.h"
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#include "webrtc/base/virtualsocketserver.h"
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using cricket::kDefaultPortAllocatorFlags;
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using cricket::kMinimumStepDelay;
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using cricket::kDefaultStepDelay;
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using cricket::PORTALLOCATOR_ENABLE_SHARED_UFRAG;
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using cricket::PORTALLOCATOR_ENABLE_SHARED_SOCKET;
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using cricket::ServerAddresses;
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using rtc::SocketAddress;
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static const int kDefaultTimeout = 1000;
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static const int kOnlyLocalPorts = cricket::PORTALLOCATOR_DISABLE_STUN |
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cricket::PORTALLOCATOR_DISABLE_RELAY |
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cricket::PORTALLOCATOR_DISABLE_TCP;
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// Addresses on the public internet.
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static const SocketAddress kPublicAddrs[2] =
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{ SocketAddress("11.11.11.11", 0), SocketAddress("22.22.22.22", 0) };
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// IPv6 Addresses on the public internet.
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static const SocketAddress kIPv6PublicAddrs[2] = {
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SocketAddress("2400:4030:1:2c00:be30:abcd:efab:cdef", 0),
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SocketAddress("2620:0:1000:1b03:2e41:38ff:fea6:f2a4", 0)
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};
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// For configuring multihomed clients.
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static const SocketAddress kAlternateAddrs[2] =
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{ SocketAddress("11.11.11.101", 0), SocketAddress("22.22.22.202", 0) };
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// Addresses for HTTP proxy servers.
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static const SocketAddress kHttpsProxyAddrs[2] =
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{ SocketAddress("11.11.11.1", 443), SocketAddress("22.22.22.1", 443) };
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// Addresses for SOCKS proxy servers.
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static const SocketAddress kSocksProxyAddrs[2] =
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{ SocketAddress("11.11.11.1", 1080), SocketAddress("22.22.22.1", 1080) };
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// Internal addresses for NAT boxes.
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static const SocketAddress kNatAddrs[2] =
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{ SocketAddress("192.168.1.1", 0), SocketAddress("192.168.2.1", 0) };
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// Private addresses inside the NAT private networks.
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static const SocketAddress kPrivateAddrs[2] =
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{ SocketAddress("192.168.1.11", 0), SocketAddress("192.168.2.22", 0) };
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// For cascaded NATs, the internal addresses of the inner NAT boxes.
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static const SocketAddress kCascadedNatAddrs[2] =
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{ SocketAddress("192.168.10.1", 0), SocketAddress("192.168.20.1", 0) };
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// For cascaded NATs, private addresses inside the inner private networks.
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static const SocketAddress kCascadedPrivateAddrs[2] =
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{ SocketAddress("192.168.10.11", 0), SocketAddress("192.168.20.22", 0) };
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// The address of the public STUN server.
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static const SocketAddress kStunAddr("99.99.99.1", cricket::STUN_SERVER_PORT);
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// The addresses for the public relay server.
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static const SocketAddress kRelayUdpIntAddr("99.99.99.2", 5000);
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static const SocketAddress kRelayUdpExtAddr("99.99.99.3", 5001);
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static const SocketAddress kRelayTcpIntAddr("99.99.99.2", 5002);
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static const SocketAddress kRelayTcpExtAddr("99.99.99.3", 5003);
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static const SocketAddress kRelaySslTcpIntAddr("99.99.99.2", 5004);
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static const SocketAddress kRelaySslTcpExtAddr("99.99.99.3", 5005);
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// The addresses for the public turn server.
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static const SocketAddress kTurnUdpIntAddr("99.99.99.4",
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cricket::STUN_SERVER_PORT);
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static const SocketAddress kTurnUdpExtAddr("99.99.99.5", 0);
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static const cricket::RelayCredentials kRelayCredentials("test", "test");
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// Based on ICE_UFRAG_LENGTH
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static const char* kIceUfrag[4] = {"TESTICEUFRAG0000", "TESTICEUFRAG0001",
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"TESTICEUFRAG0002", "TESTICEUFRAG0003"};
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// Based on ICE_PWD_LENGTH
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static const char* kIcePwd[4] = {"TESTICEPWD00000000000000",
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"TESTICEPWD00000000000001",
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"TESTICEPWD00000000000002",
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"TESTICEPWD00000000000003"};
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static const uint64 kTiebreaker1 = 11111;
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static const uint64 kTiebreaker2 = 22222;
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// This test simulates 2 P2P endpoints that want to establish connectivity
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// with each other over various network topologies and conditions, which can be
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// specified in each individial test.
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// A virtual network (via VirtualSocketServer) along with virtual firewalls and
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// NATs (via Firewall/NATSocketServer) are used to simulate the various network
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// conditions. We can configure the IP addresses of the endpoints,
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// block various types of connectivity, or add arbitrary levels of NAT.
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// We also run a STUN server and a relay server on the virtual network to allow
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// our typical P2P mechanisms to do their thing.
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// For each case, we expect the P2P stack to eventually settle on a specific
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// form of connectivity to the other side. The test checks that the P2P
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// negotiation successfully establishes connectivity within a certain time,
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// and that the result is what we expect.
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// Note that this class is a base class for use by other tests, who will provide
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// specialized test behavior.
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class P2PTransportChannelTestBase : public testing::Test,
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public rtc::MessageHandler,
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public sigslot::has_slots<> {
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public:
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P2PTransportChannelTestBase()
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: main_(rtc::Thread::Current()),
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pss_(new rtc::PhysicalSocketServer),
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vss_(new rtc::VirtualSocketServer(pss_.get())),
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nss_(new rtc::NATSocketServer(vss_.get())),
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ss_(new rtc::FirewallSocketServer(nss_.get())),
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ss_scope_(ss_.get()),
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stun_server_(cricket::TestStunServer::Create(main_, kStunAddr)),
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turn_server_(main_, kTurnUdpIntAddr, kTurnUdpExtAddr),
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relay_server_(main_, kRelayUdpIntAddr, kRelayUdpExtAddr,
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kRelayTcpIntAddr, kRelayTcpExtAddr,
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kRelaySslTcpIntAddr, kRelaySslTcpExtAddr),
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socks_server1_(ss_.get(), kSocksProxyAddrs[0],
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ss_.get(), kSocksProxyAddrs[0]),
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socks_server2_(ss_.get(), kSocksProxyAddrs[1],
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ss_.get(), kSocksProxyAddrs[1]),
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clear_remote_candidates_ufrag_pwd_(false),
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force_relay_(false) {
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ep1_.role_ = cricket::ICEROLE_CONTROLLING;
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ep2_.role_ = cricket::ICEROLE_CONTROLLED;
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ServerAddresses stun_servers;
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stun_servers.insert(kStunAddr);
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ep1_.allocator_.reset(new cricket::BasicPortAllocator(
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&ep1_.network_manager_,
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stun_servers, kRelayUdpIntAddr, kRelayTcpIntAddr, kRelaySslTcpIntAddr));
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ep2_.allocator_.reset(new cricket::BasicPortAllocator(
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&ep2_.network_manager_,
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stun_servers, kRelayUdpIntAddr, kRelayTcpIntAddr, kRelaySslTcpIntAddr));
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}
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protected:
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enum Config {
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OPEN, // Open to the Internet
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NAT_FULL_CONE, // NAT, no filtering
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NAT_ADDR_RESTRICTED, // NAT, must send to an addr to recv
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NAT_PORT_RESTRICTED, // NAT, must send to an addr+port to recv
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NAT_SYMMETRIC, // NAT, endpoint-dependent bindings
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NAT_DOUBLE_CONE, // Double NAT, both cone
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NAT_SYMMETRIC_THEN_CONE, // Double NAT, symmetric outer, cone inner
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BLOCK_UDP, // Firewall, UDP in/out blocked
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BLOCK_UDP_AND_INCOMING_TCP, // Firewall, UDP in/out and TCP in blocked
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BLOCK_ALL_BUT_OUTGOING_HTTP, // Firewall, only TCP out on 80/443
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PROXY_HTTPS, // All traffic through HTTPS proxy
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PROXY_SOCKS, // All traffic through SOCKS proxy
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NUM_CONFIGS
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};
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struct Result {
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Result(const std::string& lt, const std::string& lp,
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const std::string& rt, const std::string& rp,
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const std::string& lt2, const std::string& lp2,
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const std::string& rt2, const std::string& rp2, int wait)
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: local_type(lt), local_proto(lp), remote_type(rt), remote_proto(rp),
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local_type2(lt2), local_proto2(lp2), remote_type2(rt2),
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remote_proto2(rp2), connect_wait(wait) {
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}
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std::string local_type;
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std::string local_proto;
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std::string remote_type;
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std::string remote_proto;
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std::string local_type2;
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std::string local_proto2;
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std::string remote_type2;
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std::string remote_proto2;
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int connect_wait;
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};
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struct ChannelData {
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bool CheckData(const char* data, int len) {
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bool ret = false;
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if (!ch_packets_.empty()) {
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std::string packet = ch_packets_.front();
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ret = (packet == std::string(data, len));
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ch_packets_.pop_front();
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}
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return ret;
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}
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std::string name_; // TODO - Currently not used.
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std::list<std::string> ch_packets_;
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rtc::scoped_ptr<cricket::P2PTransportChannel> ch_;
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};
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struct Endpoint {
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Endpoint() : signaling_delay_(0), role_(cricket::ICEROLE_UNKNOWN),
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tiebreaker_(0), role_conflict_(false),
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protocol_type_(cricket::ICEPROTO_GOOGLE) {}
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bool HasChannel(cricket::TransportChannel* ch) {
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return (ch == cd1_.ch_.get() || ch == cd2_.ch_.get());
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}
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ChannelData* GetChannelData(cricket::TransportChannel* ch) {
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if (!HasChannel(ch)) return NULL;
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if (cd1_.ch_.get() == ch)
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return &cd1_;
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else
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return &cd2_;
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}
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void SetSignalingDelay(int delay) { signaling_delay_ = delay; }
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void SetIceRole(cricket::IceRole role) { role_ = role; }
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cricket::IceRole ice_role() { return role_; }
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void SetIceProtocolType(cricket::IceProtocolType type) {
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protocol_type_ = type;
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}
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cricket::IceProtocolType protocol_type() { return protocol_type_; }
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void SetIceTiebreaker(uint64 tiebreaker) { tiebreaker_ = tiebreaker; }
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uint64 GetIceTiebreaker() { return tiebreaker_; }
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void OnRoleConflict(bool role_conflict) { role_conflict_ = role_conflict; }
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bool role_conflict() { return role_conflict_; }
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void SetAllocationStepDelay(uint32 delay) {
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allocator_->set_step_delay(delay);
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}
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void SetAllowTcpListen(bool allow_tcp_listen) {
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allocator_->set_allow_tcp_listen(allow_tcp_listen);
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}
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rtc::FakeNetworkManager network_manager_;
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rtc::scoped_ptr<cricket::BasicPortAllocator> allocator_;
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ChannelData cd1_;
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ChannelData cd2_;
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int signaling_delay_;
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cricket::IceRole role_;
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uint64 tiebreaker_;
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bool role_conflict_;
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cricket::IceProtocolType protocol_type_;
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};
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struct CandidateData : public rtc::MessageData {
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CandidateData(cricket::TransportChannel* ch, const cricket::Candidate& c)
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: channel(ch), candidate(c) {
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}
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cricket::TransportChannel* channel;
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cricket::Candidate candidate;
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};
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ChannelData* GetChannelData(cricket::TransportChannel* channel) {
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if (ep1_.HasChannel(channel))
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return ep1_.GetChannelData(channel);
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else
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return ep2_.GetChannelData(channel);
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}
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void CreateChannels(int num) {
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std::string ice_ufrag_ep1_cd1_ch = kIceUfrag[0];
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std::string ice_pwd_ep1_cd1_ch = kIcePwd[0];
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std::string ice_ufrag_ep2_cd1_ch = kIceUfrag[1];
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std::string ice_pwd_ep2_cd1_ch = kIcePwd[1];
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ep1_.cd1_.ch_.reset(CreateChannel(
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0, cricket::ICE_CANDIDATE_COMPONENT_DEFAULT,
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ice_ufrag_ep1_cd1_ch, ice_pwd_ep1_cd1_ch,
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ice_ufrag_ep2_cd1_ch, ice_pwd_ep2_cd1_ch));
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ep2_.cd1_.ch_.reset(CreateChannel(
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1, cricket::ICE_CANDIDATE_COMPONENT_DEFAULT,
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ice_ufrag_ep2_cd1_ch, ice_pwd_ep2_cd1_ch,
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ice_ufrag_ep1_cd1_ch, ice_pwd_ep1_cd1_ch));
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if (num == 2) {
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std::string ice_ufrag_ep1_cd2_ch = kIceUfrag[2];
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std::string ice_pwd_ep1_cd2_ch = kIcePwd[2];
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std::string ice_ufrag_ep2_cd2_ch = kIceUfrag[3];
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std::string ice_pwd_ep2_cd2_ch = kIcePwd[3];
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// In BUNDLE each endpoint must share common ICE credentials.
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if (ep1_.allocator_->flags() & cricket::PORTALLOCATOR_ENABLE_BUNDLE) {
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ice_ufrag_ep1_cd2_ch = ice_ufrag_ep1_cd1_ch;
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ice_pwd_ep1_cd2_ch = ice_pwd_ep1_cd1_ch;
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}
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if (ep2_.allocator_->flags() & cricket::PORTALLOCATOR_ENABLE_BUNDLE) {
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ice_ufrag_ep2_cd2_ch = ice_ufrag_ep2_cd1_ch;
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ice_pwd_ep2_cd2_ch = ice_pwd_ep2_cd1_ch;
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}
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ep1_.cd2_.ch_.reset(CreateChannel(
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0, cricket::ICE_CANDIDATE_COMPONENT_DEFAULT,
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ice_ufrag_ep1_cd2_ch, ice_pwd_ep1_cd2_ch,
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ice_ufrag_ep2_cd2_ch, ice_pwd_ep2_cd2_ch));
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ep2_.cd2_.ch_.reset(CreateChannel(
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1, cricket::ICE_CANDIDATE_COMPONENT_DEFAULT,
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ice_ufrag_ep2_cd2_ch, ice_pwd_ep2_cd2_ch,
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ice_ufrag_ep1_cd2_ch, ice_pwd_ep1_cd2_ch));
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}
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}
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cricket::P2PTransportChannel* CreateChannel(
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int endpoint,
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int component,
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const std::string& local_ice_ufrag,
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const std::string& local_ice_pwd,
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const std::string& remote_ice_ufrag,
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const std::string& remote_ice_pwd) {
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cricket::P2PTransportChannel* channel = new cricket::P2PTransportChannel(
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"test content name", component, NULL, GetAllocator(endpoint));
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channel->SignalRequestSignaling.connect(
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this, &P2PTransportChannelTestBase::OnChannelRequestSignaling);
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channel->SignalCandidateReady.connect(this,
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&P2PTransportChannelTestBase::OnCandidate);
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channel->SignalReadPacket.connect(
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this, &P2PTransportChannelTestBase::OnReadPacket);
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channel->SignalRoleConflict.connect(
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this, &P2PTransportChannelTestBase::OnRoleConflict);
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channel->SetIceProtocolType(GetEndpoint(endpoint)->protocol_type());
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channel->SetIceCredentials(local_ice_ufrag, local_ice_pwd);
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if (clear_remote_candidates_ufrag_pwd_) {
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// This only needs to be set if we're clearing them from the
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// candidates. Some unit tests rely on this not being set.
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channel->SetRemoteIceCredentials(remote_ice_ufrag, remote_ice_pwd);
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}
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channel->SetIceRole(GetEndpoint(endpoint)->ice_role());
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channel->SetIceTiebreaker(GetEndpoint(endpoint)->GetIceTiebreaker());
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channel->Connect();
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return channel;
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}
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void DestroyChannels() {
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ep1_.cd1_.ch_.reset();
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ep2_.cd1_.ch_.reset();
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ep1_.cd2_.ch_.reset();
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ep2_.cd2_.ch_.reset();
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}
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cricket::P2PTransportChannel* ep1_ch1() { return ep1_.cd1_.ch_.get(); }
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cricket::P2PTransportChannel* ep1_ch2() { return ep1_.cd2_.ch_.get(); }
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cricket::P2PTransportChannel* ep2_ch1() { return ep2_.cd1_.ch_.get(); }
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cricket::P2PTransportChannel* ep2_ch2() { return ep2_.cd2_.ch_.get(); }
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|
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// Common results.
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static const Result kLocalUdpToLocalUdp;
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static const Result kLocalUdpToStunUdp;
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static const Result kLocalUdpToPrflxUdp;
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static const Result kPrflxUdpToLocalUdp;
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static const Result kStunUdpToLocalUdp;
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static const Result kStunUdpToStunUdp;
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static const Result kPrflxUdpToStunUdp;
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static const Result kLocalUdpToRelayUdp;
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static const Result kPrflxUdpToRelayUdp;
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static const Result kLocalTcpToLocalTcp;
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static const Result kLocalTcpToPrflxTcp;
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static const Result kPrflxTcpToLocalTcp;
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rtc::NATSocketServer* nat() { return nss_.get(); }
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rtc::FirewallSocketServer* fw() { return ss_.get(); }
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Endpoint* GetEndpoint(int endpoint) {
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if (endpoint == 0) {
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return &ep1_;
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} else if (endpoint == 1) {
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return &ep2_;
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} else {
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return NULL;
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}
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}
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cricket::PortAllocator* GetAllocator(int endpoint) {
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return GetEndpoint(endpoint)->allocator_.get();
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}
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void AddAddress(int endpoint, const SocketAddress& addr) {
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GetEndpoint(endpoint)->network_manager_.AddInterface(addr);
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}
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void RemoveAddress(int endpoint, const SocketAddress& addr) {
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GetEndpoint(endpoint)->network_manager_.RemoveInterface(addr);
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|
}
|
|
void SetProxy(int endpoint, rtc::ProxyType type) {
|
|
rtc::ProxyInfo info;
|
|
info.type = type;
|
|
info.address = (type == rtc::PROXY_HTTPS) ?
|
|
kHttpsProxyAddrs[endpoint] : kSocksProxyAddrs[endpoint];
|
|
GetAllocator(endpoint)->set_proxy("unittest/1.0", info);
|
|
}
|
|
void SetAllocatorFlags(int endpoint, int flags) {
|
|
GetAllocator(endpoint)->set_flags(flags);
|
|
}
|
|
void SetSignalingDelay(int endpoint, int delay) {
|
|
GetEndpoint(endpoint)->SetSignalingDelay(delay);
|
|
}
|
|
void SetIceProtocol(int endpoint, cricket::IceProtocolType type) {
|
|
GetEndpoint(endpoint)->SetIceProtocolType(type);
|
|
}
|
|
void SetIceRole(int endpoint, cricket::IceRole role) {
|
|
GetEndpoint(endpoint)->SetIceRole(role);
|
|
}
|
|
void SetIceTiebreaker(int endpoint, uint64 tiebreaker) {
|
|
GetEndpoint(endpoint)->SetIceTiebreaker(tiebreaker);
|
|
}
|
|
bool GetRoleConflict(int endpoint) {
|
|
return GetEndpoint(endpoint)->role_conflict();
|
|
}
|
|
void SetAllocationStepDelay(int endpoint, uint32 delay) {
|
|
return GetEndpoint(endpoint)->SetAllocationStepDelay(delay);
|
|
}
|
|
void SetAllowTcpListen(int endpoint, bool allow_tcp_listen) {
|
|
return GetEndpoint(endpoint)->SetAllowTcpListen(allow_tcp_listen);
|
|
}
|
|
|
|
void Test(const Result& expected) {
|
|
int32 connect_start = rtc::Time(), connect_time;
|
|
|
|
// Create the channels and wait for them to connect.
|
|
CreateChannels(1);
|
|
EXPECT_TRUE_WAIT_MARGIN(ep1_ch1() != NULL &&
|
|
ep2_ch1() != NULL &&
|
|
ep1_ch1()->readable() &&
|
|
ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() &&
|
|
ep2_ch1()->writable(),
|
|
expected.connect_wait,
|
|
1000);
|
|
connect_time = rtc::TimeSince(connect_start);
|
|
if (connect_time < expected.connect_wait) {
|
|
LOG(LS_INFO) << "Connect time: " << connect_time << " ms";
|
|
} else {
|
|
LOG(LS_INFO) << "Connect time: " << "TIMEOUT ("
|
|
<< expected.connect_wait << " ms)";
|
|
}
|
|
|
|
// Allow a few turns of the crank for the best connections to emerge.
|
|
// This may take up to 2 seconds.
|
|
if (ep1_ch1()->best_connection() &&
|
|
ep2_ch1()->best_connection()) {
|
|
int32 converge_start = rtc::Time(), converge_time;
|
|
int converge_wait = 2000;
|
|
EXPECT_TRUE_WAIT_MARGIN(
|
|
LocalCandidate(ep1_ch1())->type() == expected.local_type &&
|
|
LocalCandidate(ep1_ch1())->protocol() == expected.local_proto &&
|
|
RemoteCandidate(ep1_ch1())->type() == expected.remote_type &&
|
|
RemoteCandidate(ep1_ch1())->protocol() == expected.remote_proto,
|
|
converge_wait,
|
|
converge_wait);
|
|
|
|
// Also do EXPECT_EQ on each part so that failures are more verbose.
|
|
EXPECT_EQ(expected.local_type, LocalCandidate(ep1_ch1())->type());
|
|
EXPECT_EQ(expected.local_proto, LocalCandidate(ep1_ch1())->protocol());
|
|
EXPECT_EQ(expected.remote_type, RemoteCandidate(ep1_ch1())->type());
|
|
EXPECT_EQ(expected.remote_proto, RemoteCandidate(ep1_ch1())->protocol());
|
|
|
|
// Verifying remote channel best connection information. This is done
|
|
// only for the RFC 5245 as controlled agent will use USE-CANDIDATE
|
|
// from controlling (ep1) agent. We can easily predict from EP1 result
|
|
// matrix.
|
|
if (ep2_.protocol_type_ == cricket::ICEPROTO_RFC5245) {
|
|
// Checking for best connection candidates information at remote.
|
|
EXPECT_TRUE_WAIT(
|
|
LocalCandidate(ep2_ch1())->type() == expected.local_type2 &&
|
|
LocalCandidate(ep2_ch1())->protocol() == expected.local_proto2 &&
|
|
RemoteCandidate(ep2_ch1())->protocol() == expected.remote_proto2,
|
|
kDefaultTimeout);
|
|
|
|
// For verbose
|
|
EXPECT_EQ(expected.local_type2, LocalCandidate(ep2_ch1())->type());
|
|
EXPECT_EQ(expected.local_proto2, LocalCandidate(ep2_ch1())->protocol());
|
|
EXPECT_EQ(expected.remote_proto2,
|
|
RemoteCandidate(ep2_ch1())->protocol());
|
|
// Removed remote_type comparision aginst best connection remote
|
|
// candidate. This is done to handle remote type discrepancy from
|
|
// local to stun based on the test type.
|
|
// For example in case of Open -> NAT, ep2 channels will have LULU
|
|
// and in other cases like NAT -> NAT it will be LUSU. To avoid these
|
|
// mismatches and we are doing comparision in different way.
|
|
// i.e. when don't match its remote type is either local or stun.
|
|
// TODO(ronghuawu): Refine the test criteria.
|
|
// https://code.google.com/p/webrtc/issues/detail?id=1953
|
|
if (expected.remote_type2 != RemoteCandidate(ep2_ch1())->type()) {
|
|
EXPECT_TRUE(expected.remote_type2 == cricket::LOCAL_PORT_TYPE ||
|
|
expected.remote_type2 == cricket::STUN_PORT_TYPE);
|
|
EXPECT_TRUE(
|
|
RemoteCandidate(ep2_ch1())->type() == cricket::LOCAL_PORT_TYPE ||
|
|
RemoteCandidate(ep2_ch1())->type() == cricket::STUN_PORT_TYPE ||
|
|
RemoteCandidate(ep2_ch1())->type() == cricket::PRFLX_PORT_TYPE);
|
|
}
|
|
}
|
|
|
|
converge_time = rtc::TimeSince(converge_start);
|
|
if (converge_time < converge_wait) {
|
|
LOG(LS_INFO) << "Converge time: " << converge_time << " ms";
|
|
} else {
|
|
LOG(LS_INFO) << "Converge time: " << "TIMEOUT ("
|
|
<< converge_wait << " ms)";
|
|
}
|
|
}
|
|
// Try sending some data to other end.
|
|
TestSendRecv(1);
|
|
|
|
// Destroy the channels, and wait for them to be fully cleaned up.
|
|
DestroyChannels();
|
|
}
|
|
|
|
void TestSendRecv(int channels) {
|
|
for (int i = 0; i < 10; ++i) {
|
|
const char* data = "ABCDEFGHIJKLMNOPQRSTUVWXYZ1234567890";
|
|
int len = static_cast<int>(strlen(data));
|
|
// local_channel1 <==> remote_channel1
|
|
EXPECT_EQ_WAIT(len, SendData(ep1_ch1(), data, len), 1000);
|
|
EXPECT_TRUE_WAIT(CheckDataOnChannel(ep2_ch1(), data, len), 1000);
|
|
EXPECT_EQ_WAIT(len, SendData(ep2_ch1(), data, len), 1000);
|
|
EXPECT_TRUE_WAIT(CheckDataOnChannel(ep1_ch1(), data, len), 1000);
|
|
if (channels == 2 && ep1_ch2() && ep2_ch2()) {
|
|
// local_channel2 <==> remote_channel2
|
|
EXPECT_EQ_WAIT(len, SendData(ep1_ch2(), data, len), 1000);
|
|
EXPECT_TRUE_WAIT(CheckDataOnChannel(ep2_ch2(), data, len), 1000);
|
|
EXPECT_EQ_WAIT(len, SendData(ep2_ch2(), data, len), 1000);
|
|
EXPECT_TRUE_WAIT(CheckDataOnChannel(ep1_ch2(), data, len), 1000);
|
|
}
|
|
}
|
|
}
|
|
|
|
// This test waits for the transport to become readable and writable on both
|
|
// end points. Once they are, the end points set new local ice credentials to
|
|
// restart the ice gathering. Finally it waits for the transport to select a
|
|
// new connection using the newly generated ice candidates.
|
|
// Before calling this function the end points must be configured.
|
|
void TestHandleIceUfragPasswordChanged() {
|
|
ep1_ch1()->SetRemoteIceCredentials(kIceUfrag[1], kIcePwd[1]);
|
|
ep2_ch1()->SetRemoteIceCredentials(kIceUfrag[0], kIcePwd[0]);
|
|
EXPECT_TRUE_WAIT_MARGIN(ep1_ch1()->readable() && ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() && ep2_ch1()->writable(),
|
|
1000, 1000);
|
|
|
|
const cricket::Candidate* old_local_candidate1 = LocalCandidate(ep1_ch1());
|
|
const cricket::Candidate* old_local_candidate2 = LocalCandidate(ep2_ch1());
|
|
const cricket::Candidate* old_remote_candidate1 =
|
|
RemoteCandidate(ep1_ch1());
|
|
const cricket::Candidate* old_remote_candidate2 =
|
|
RemoteCandidate(ep2_ch1());
|
|
|
|
ep1_ch1()->SetIceCredentials(kIceUfrag[2], kIcePwd[2]);
|
|
ep1_ch1()->SetRemoteIceCredentials(kIceUfrag[3], kIcePwd[3]);
|
|
ep2_ch1()->SetIceCredentials(kIceUfrag[3], kIcePwd[3]);
|
|
ep2_ch1()->SetRemoteIceCredentials(kIceUfrag[2], kIcePwd[2]);
|
|
|
|
EXPECT_TRUE_WAIT_MARGIN(LocalCandidate(ep1_ch1())->generation() !=
|
|
old_local_candidate1->generation(),
|
|
1000, 1000);
|
|
EXPECT_TRUE_WAIT_MARGIN(LocalCandidate(ep2_ch1())->generation() !=
|
|
old_local_candidate2->generation(),
|
|
1000, 1000);
|
|
EXPECT_TRUE_WAIT_MARGIN(RemoteCandidate(ep1_ch1())->generation() !=
|
|
old_remote_candidate1->generation(),
|
|
1000, 1000);
|
|
EXPECT_TRUE_WAIT_MARGIN(RemoteCandidate(ep2_ch1())->generation() !=
|
|
old_remote_candidate2->generation(),
|
|
1000, 1000);
|
|
EXPECT_EQ(1u, RemoteCandidate(ep2_ch1())->generation());
|
|
EXPECT_EQ(1u, RemoteCandidate(ep1_ch1())->generation());
|
|
}
|
|
|
|
void TestSignalRoleConflict() {
|
|
SetIceProtocol(0, cricket::ICEPROTO_RFC5245);
|
|
SetIceTiebreaker(0, kTiebreaker1); // Default EP1 is in controlling state.
|
|
|
|
SetIceProtocol(1, cricket::ICEPROTO_RFC5245);
|
|
SetIceRole(1, cricket::ICEROLE_CONTROLLING);
|
|
SetIceTiebreaker(1, kTiebreaker2);
|
|
|
|
// Creating channels with both channels role set to CONTROLLING.
|
|
CreateChannels(1);
|
|
// Since both the channels initiated with controlling state and channel2
|
|
// has higher tiebreaker value, channel1 should receive SignalRoleConflict.
|
|
EXPECT_TRUE_WAIT(GetRoleConflict(0), 1000);
|
|
EXPECT_FALSE(GetRoleConflict(1));
|
|
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() &&
|
|
ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() &&
|
|
ep2_ch1()->writable(),
|
|
1000);
|
|
|
|
EXPECT_TRUE(ep1_ch1()->best_connection() &&
|
|
ep2_ch1()->best_connection());
|
|
|
|
TestSendRecv(1);
|
|
}
|
|
|
|
void TestHybridConnectivity(cricket::IceProtocolType proto) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
|
|
SetAllocationStepDelay(0, kMinimumStepDelay);
|
|
SetAllocationStepDelay(1, kMinimumStepDelay);
|
|
|
|
SetIceRole(0, cricket::ICEROLE_CONTROLLING);
|
|
SetIceProtocol(0, cricket::ICEPROTO_HYBRID);
|
|
SetIceTiebreaker(0, kTiebreaker1);
|
|
SetIceRole(1, cricket::ICEROLE_CONTROLLED);
|
|
SetIceProtocol(1, proto);
|
|
SetIceTiebreaker(1, kTiebreaker2);
|
|
|
|
CreateChannels(1);
|
|
// When channel is in hybrid and it's controlling agent, channel will
|
|
// receive ping request from the remote. Hence connection is readable.
|
|
// Since channel is in hybrid, it will not send any pings, so no writable
|
|
// connection. Since channel2 is in controlled state, it will not have
|
|
// any connections which are readable or writable, as it didn't received
|
|
// pings (or none) with USE-CANDIDATE attribute.
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable(), 1000);
|
|
|
|
// Set real protocol type.
|
|
ep1_ch1()->SetIceProtocolType(proto);
|
|
|
|
// Channel should able to send ping requests and connections become writable
|
|
// in both directions.
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() && ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() && ep2_ch1()->writable(),
|
|
1000);
|
|
EXPECT_TRUE(
|
|
ep1_ch1()->best_connection() && ep2_ch1()->best_connection() &&
|
|
LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) &&
|
|
RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1]));
|
|
|
|
TestSendRecv(1);
|
|
DestroyChannels();
|
|
}
|
|
|
|
void OnChannelRequestSignaling(cricket::TransportChannelImpl* channel) {
|
|
channel->OnSignalingReady();
|
|
}
|
|
// We pass the candidates directly to the other side.
|
|
void OnCandidate(cricket::TransportChannelImpl* ch,
|
|
const cricket::Candidate& c) {
|
|
if (force_relay_ && c.type() != cricket::RELAY_PORT_TYPE)
|
|
return;
|
|
|
|
main_->PostDelayed(GetEndpoint(ch)->signaling_delay_, this, 0,
|
|
new CandidateData(ch, c));
|
|
}
|
|
void OnMessage(rtc::Message* msg) {
|
|
rtc::scoped_ptr<CandidateData> data(
|
|
static_cast<CandidateData*>(msg->pdata));
|
|
cricket::P2PTransportChannel* rch = GetRemoteChannel(data->channel);
|
|
cricket::Candidate c = data->candidate;
|
|
if (clear_remote_candidates_ufrag_pwd_) {
|
|
c.set_username("");
|
|
c.set_password("");
|
|
}
|
|
LOG(LS_INFO) << "Candidate(" << data->channel->component() << "->"
|
|
<< rch->component() << "): " << c.type() << ", " << c.protocol()
|
|
<< ", " << c.address().ToString() << ", " << c.username()
|
|
<< ", " << c.generation();
|
|
rch->OnCandidate(c);
|
|
}
|
|
void OnReadPacket(cricket::TransportChannel* channel, const char* data,
|
|
size_t len, const rtc::PacketTime& packet_time,
|
|
int flags) {
|
|
std::list<std::string>& packets = GetPacketList(channel);
|
|
packets.push_front(std::string(data, len));
|
|
}
|
|
void OnRoleConflict(cricket::TransportChannelImpl* channel) {
|
|
GetEndpoint(channel)->OnRoleConflict(true);
|
|
cricket::IceRole new_role =
|
|
GetEndpoint(channel)->ice_role() == cricket::ICEROLE_CONTROLLING ?
|
|
cricket::ICEROLE_CONTROLLED : cricket::ICEROLE_CONTROLLING;
|
|
channel->SetIceRole(new_role);
|
|
}
|
|
int SendData(cricket::TransportChannel* channel,
|
|
const char* data, size_t len) {
|
|
rtc::PacketOptions options;
|
|
return channel->SendPacket(data, len, options, 0);
|
|
}
|
|
bool CheckDataOnChannel(cricket::TransportChannel* channel,
|
|
const char* data, int len) {
|
|
return GetChannelData(channel)->CheckData(data, len);
|
|
}
|
|
static const cricket::Candidate* LocalCandidate(
|
|
cricket::P2PTransportChannel* ch) {
|
|
return (ch && ch->best_connection()) ?
|
|
&ch->best_connection()->local_candidate() : NULL;
|
|
}
|
|
static const cricket::Candidate* RemoteCandidate(
|
|
cricket::P2PTransportChannel* ch) {
|
|
return (ch && ch->best_connection()) ?
|
|
&ch->best_connection()->remote_candidate() : NULL;
|
|
}
|
|
Endpoint* GetEndpoint(cricket::TransportChannel* ch) {
|
|
if (ep1_.HasChannel(ch)) {
|
|
return &ep1_;
|
|
} else if (ep2_.HasChannel(ch)) {
|
|
return &ep2_;
|
|
} else {
|
|
return NULL;
|
|
}
|
|
}
|
|
cricket::P2PTransportChannel* GetRemoteChannel(
|
|
cricket::TransportChannel* ch) {
|
|
if (ch == ep1_ch1())
|
|
return ep2_ch1();
|
|
else if (ch == ep1_ch2())
|
|
return ep2_ch2();
|
|
else if (ch == ep2_ch1())
|
|
return ep1_ch1();
|
|
else if (ch == ep2_ch2())
|
|
return ep1_ch2();
|
|
else
|
|
return NULL;
|
|
}
|
|
std::list<std::string>& GetPacketList(cricket::TransportChannel* ch) {
|
|
return GetChannelData(ch)->ch_packets_;
|
|
}
|
|
|
|
void set_clear_remote_candidates_ufrag_pwd(bool clear) {
|
|
clear_remote_candidates_ufrag_pwd_ = clear;
|
|
}
|
|
|
|
void set_force_relay(bool relay) {
|
|
force_relay_ = relay;
|
|
}
|
|
|
|
private:
|
|
rtc::Thread* main_;
|
|
rtc::scoped_ptr<rtc::PhysicalSocketServer> pss_;
|
|
rtc::scoped_ptr<rtc::VirtualSocketServer> vss_;
|
|
rtc::scoped_ptr<rtc::NATSocketServer> nss_;
|
|
rtc::scoped_ptr<rtc::FirewallSocketServer> ss_;
|
|
rtc::SocketServerScope ss_scope_;
|
|
rtc::scoped_ptr<cricket::TestStunServer> stun_server_;
|
|
cricket::TestTurnServer turn_server_;
|
|
cricket::TestRelayServer relay_server_;
|
|
rtc::SocksProxyServer socks_server1_;
|
|
rtc::SocksProxyServer socks_server2_;
|
|
Endpoint ep1_;
|
|
Endpoint ep2_;
|
|
bool clear_remote_candidates_ufrag_pwd_;
|
|
bool force_relay_;
|
|
};
|
|
|
|
// The tests have only a few outcomes, which we predefine.
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kLocalUdpToLocalUdp("local", "udp", "local", "udp",
|
|
"local", "udp", "local", "udp", 1000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kLocalUdpToStunUdp("local", "udp", "stun", "udp",
|
|
"local", "udp", "stun", "udp", 1000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kLocalUdpToPrflxUdp("local", "udp", "prflx", "udp",
|
|
"prflx", "udp", "local", "udp", 1000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kPrflxUdpToLocalUdp("prflx", "udp", "local", "udp",
|
|
"local", "udp", "prflx", "udp", 1000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kStunUdpToLocalUdp("stun", "udp", "local", "udp",
|
|
"local", "udp", "stun", "udp", 1000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kStunUdpToStunUdp("stun", "udp", "stun", "udp",
|
|
"stun", "udp", "stun", "udp", 1000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kPrflxUdpToStunUdp("prflx", "udp", "stun", "udp",
|
|
"local", "udp", "prflx", "udp", 1000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kLocalUdpToRelayUdp("local", "udp", "relay", "udp",
|
|
"relay", "udp", "local", "udp", 2000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kPrflxUdpToRelayUdp("prflx", "udp", "relay", "udp",
|
|
"relay", "udp", "prflx", "udp", 2000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kLocalTcpToLocalTcp("local", "tcp", "local", "tcp",
|
|
"local", "tcp", "local", "tcp", 3000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kLocalTcpToPrflxTcp("local", "tcp", "prflx", "tcp",
|
|
"prflx", "tcp", "local", "tcp", 3000);
|
|
const P2PTransportChannelTestBase::Result P2PTransportChannelTestBase::
|
|
kPrflxTcpToLocalTcp("prflx", "tcp", "local", "tcp",
|
|
"local", "tcp", "prflx", "tcp", 3000);
|
|
|
|
// Test the matrix of all the connectivity types we expect to see in the wild.
|
|
// Just test every combination of the configs in the Config enum.
|
|
class P2PTransportChannelTest : public P2PTransportChannelTestBase {
|
|
protected:
|
|
static const Result* kMatrix[NUM_CONFIGS][NUM_CONFIGS];
|
|
static const Result* kMatrixSharedUfrag[NUM_CONFIGS][NUM_CONFIGS];
|
|
static const Result* kMatrixSharedSocketAsGice[NUM_CONFIGS][NUM_CONFIGS];
|
|
static const Result* kMatrixSharedSocketAsIce[NUM_CONFIGS][NUM_CONFIGS];
|
|
void ConfigureEndpoints(Config config1, Config config2,
|
|
int allocator_flags1, int allocator_flags2,
|
|
int delay1, int delay2,
|
|
cricket::IceProtocolType type) {
|
|
// Ideally we want to use TURN server for both GICE and ICE, but in case
|
|
// of GICE, TURN server usage is not producing results reliabally.
|
|
// TODO(mallinath): Remove Relay and use TURN server for all tests.
|
|
ServerAddresses stun_servers;
|
|
stun_servers.insert(kStunAddr);
|
|
GetEndpoint(0)->allocator_.reset(
|
|
new cricket::BasicPortAllocator(&(GetEndpoint(0)->network_manager_),
|
|
stun_servers,
|
|
rtc::SocketAddress(), rtc::SocketAddress(),
|
|
rtc::SocketAddress()));
|
|
GetEndpoint(1)->allocator_.reset(
|
|
new cricket::BasicPortAllocator(&(GetEndpoint(1)->network_manager_),
|
|
stun_servers,
|
|
rtc::SocketAddress(), rtc::SocketAddress(),
|
|
rtc::SocketAddress()));
|
|
|
|
cricket::RelayServerConfig relay_server(cricket::RELAY_GTURN);
|
|
if (type == cricket::ICEPROTO_RFC5245) {
|
|
relay_server.type = cricket::RELAY_TURN;
|
|
relay_server.credentials = kRelayCredentials;
|
|
relay_server.ports.push_back(cricket::ProtocolAddress(
|
|
kTurnUdpIntAddr, cricket::PROTO_UDP, false));
|
|
} else {
|
|
relay_server.ports.push_back(cricket::ProtocolAddress(
|
|
kRelayUdpIntAddr, cricket::PROTO_UDP, false));
|
|
relay_server.ports.push_back(cricket::ProtocolAddress(
|
|
kRelayTcpIntAddr, cricket::PROTO_TCP, false));
|
|
relay_server.ports.push_back(cricket::ProtocolAddress(
|
|
kRelaySslTcpIntAddr, cricket::PROTO_SSLTCP, false));
|
|
}
|
|
GetEndpoint(0)->allocator_->AddRelay(relay_server);
|
|
GetEndpoint(1)->allocator_->AddRelay(relay_server);
|
|
|
|
ConfigureEndpoint(0, config1);
|
|
SetIceProtocol(0, type);
|
|
SetAllocatorFlags(0, allocator_flags1);
|
|
SetAllocationStepDelay(0, delay1);
|
|
ConfigureEndpoint(1, config2);
|
|
SetIceProtocol(1, type);
|
|
SetAllocatorFlags(1, allocator_flags2);
|
|
SetAllocationStepDelay(1, delay2);
|
|
}
|
|
void ConfigureEndpoint(int endpoint, Config config) {
|
|
switch (config) {
|
|
case OPEN:
|
|
AddAddress(endpoint, kPublicAddrs[endpoint]);
|
|
break;
|
|
case NAT_FULL_CONE:
|
|
case NAT_ADDR_RESTRICTED:
|
|
case NAT_PORT_RESTRICTED:
|
|
case NAT_SYMMETRIC:
|
|
AddAddress(endpoint, kPrivateAddrs[endpoint]);
|
|
// Add a single NAT of the desired type
|
|
nat()->AddTranslator(kPublicAddrs[endpoint], kNatAddrs[endpoint],
|
|
static_cast<rtc::NATType>(config - NAT_FULL_CONE))->
|
|
AddClient(kPrivateAddrs[endpoint]);
|
|
break;
|
|
case NAT_DOUBLE_CONE:
|
|
case NAT_SYMMETRIC_THEN_CONE:
|
|
AddAddress(endpoint, kCascadedPrivateAddrs[endpoint]);
|
|
// Add a two cascaded NATs of the desired types
|
|
nat()->AddTranslator(kPublicAddrs[endpoint], kNatAddrs[endpoint],
|
|
(config == NAT_DOUBLE_CONE) ?
|
|
rtc::NAT_OPEN_CONE : rtc::NAT_SYMMETRIC)->
|
|
AddTranslator(kPrivateAddrs[endpoint], kCascadedNatAddrs[endpoint],
|
|
rtc::NAT_OPEN_CONE)->
|
|
AddClient(kCascadedPrivateAddrs[endpoint]);
|
|
break;
|
|
case BLOCK_UDP:
|
|
case BLOCK_UDP_AND_INCOMING_TCP:
|
|
case BLOCK_ALL_BUT_OUTGOING_HTTP:
|
|
case PROXY_HTTPS:
|
|
case PROXY_SOCKS:
|
|
AddAddress(endpoint, kPublicAddrs[endpoint]);
|
|
// Block all UDP
|
|
fw()->AddRule(false, rtc::FP_UDP, rtc::FD_ANY,
|
|
kPublicAddrs[endpoint]);
|
|
if (config == BLOCK_UDP_AND_INCOMING_TCP) {
|
|
// Block TCP inbound to the endpoint
|
|
fw()->AddRule(false, rtc::FP_TCP, SocketAddress(),
|
|
kPublicAddrs[endpoint]);
|
|
} else if (config == BLOCK_ALL_BUT_OUTGOING_HTTP) {
|
|
// Block all TCP to/from the endpoint except 80/443 out
|
|
fw()->AddRule(true, rtc::FP_TCP, kPublicAddrs[endpoint],
|
|
SocketAddress(rtc::IPAddress(INADDR_ANY), 80));
|
|
fw()->AddRule(true, rtc::FP_TCP, kPublicAddrs[endpoint],
|
|
SocketAddress(rtc::IPAddress(INADDR_ANY), 443));
|
|
fw()->AddRule(false, rtc::FP_TCP, rtc::FD_ANY,
|
|
kPublicAddrs[endpoint]);
|
|
} else if (config == PROXY_HTTPS) {
|
|
// Block all TCP to/from the endpoint except to the proxy server
|
|
fw()->AddRule(true, rtc::FP_TCP, kPublicAddrs[endpoint],
|
|
kHttpsProxyAddrs[endpoint]);
|
|
fw()->AddRule(false, rtc::FP_TCP, rtc::FD_ANY,
|
|
kPublicAddrs[endpoint]);
|
|
SetProxy(endpoint, rtc::PROXY_HTTPS);
|
|
} else if (config == PROXY_SOCKS) {
|
|
// Block all TCP to/from the endpoint except to the proxy server
|
|
fw()->AddRule(true, rtc::FP_TCP, kPublicAddrs[endpoint],
|
|
kSocksProxyAddrs[endpoint]);
|
|
fw()->AddRule(false, rtc::FP_TCP, rtc::FD_ANY,
|
|
kPublicAddrs[endpoint]);
|
|
SetProxy(endpoint, rtc::PROXY_SOCKS5);
|
|
}
|
|
break;
|
|
default:
|
|
break;
|
|
}
|
|
}
|
|
};
|
|
|
|
// Shorthands for use in the test matrix.
|
|
#define LULU &kLocalUdpToLocalUdp
|
|
#define LUSU &kLocalUdpToStunUdp
|
|
#define LUPU &kLocalUdpToPrflxUdp
|
|
#define PULU &kPrflxUdpToLocalUdp
|
|
#define SULU &kStunUdpToLocalUdp
|
|
#define SUSU &kStunUdpToStunUdp
|
|
#define PUSU &kPrflxUdpToStunUdp
|
|
#define LURU &kLocalUdpToRelayUdp
|
|
#define PURU &kPrflxUdpToRelayUdp
|
|
#define LTLT &kLocalTcpToLocalTcp
|
|
#define LTPT &kLocalTcpToPrflxTcp
|
|
#define PTLT &kPrflxTcpToLocalTcp
|
|
// TODO: Enable these once TestRelayServer can accept external TCP.
|
|
#define LTRT NULL
|
|
#define LSRS NULL
|
|
|
|
// Test matrix. Originator behavior defined by rows, receiever by columns.
|
|
|
|
// Currently the p2ptransportchannel.cc (specifically the
|
|
// P2PTransportChannel::OnUnknownAddress) operates in 2 modes depend on the
|
|
// remote candidates - ufrag per port or shared ufrag.
|
|
// For example, if the remote candidates have the shared ufrag, for the unknown
|
|
// address reaches the OnUnknownAddress, we will try to find the matched
|
|
// remote candidate based on the address and protocol, if not found, a new
|
|
// remote candidate will be created for this address. But if the remote
|
|
// candidates have different ufrags, we will try to find the matched remote
|
|
// candidate by comparing the ufrag. If not found, an error will be returned.
|
|
// Because currently the shared ufrag feature is under the experiment and will
|
|
// be rolled out gradually. We want to test the different combinations of peers
|
|
// with/without the shared ufrag enabled. And those different combinations have
|
|
// different expectation of the best connection. For example in the OpenToCONE
|
|
// case, an unknown address will be updated to a "host" remote candidate if the
|
|
// remote peer uses different ufrag per port. But in the shared ufrag case,
|
|
// a "stun" (should be peer-reflexive eventually) candidate will be created for
|
|
// that. So the expected best candidate will be LUSU instead of LULU.
|
|
// With all these, we have to keep 2 test matrixes for the tests:
|
|
// kMatrix - for the tests that the remote peer uses different ufrag per port.
|
|
// kMatrixSharedUfrag - for the tests that remote peer uses shared ufrag.
|
|
// The different between the two matrixes are on:
|
|
// OPToCONE, OPTo2CON,
|
|
// COToCONE, COToADDR, COToPORT, COToSYMM, COTo2CON, COToSCON,
|
|
// ADToCONE, ADToADDR, ADTo2CON,
|
|
// POToADDR,
|
|
// SYToADDR,
|
|
// 2CToCONE, 2CToADDR, 2CToPORT, 2CToSYMM, 2CTo2CON, 2CToSCON,
|
|
// SCToADDR,
|
|
|
|
// TODO: Fix NULLs caused by lack of TCP support in NATSocket.
|
|
// TODO: Fix NULLs caused by no HTTP proxy support.
|
|
// TODO: Rearrange rows/columns from best to worst.
|
|
// TODO(ronghuawu): Keep only one test matrix once the shared ufrag is enabled.
|
|
const P2PTransportChannelTest::Result*
|
|
P2PTransportChannelTest::kMatrix[NUM_CONFIGS][NUM_CONFIGS] = {
|
|
// OPEN CONE ADDR PORT SYMM 2CON SCON !UDP !TCP HTTP PRXH PRXS
|
|
/*OP*/ {LULU, LULU, LULU, LULU, LULU, LULU, LULU, LTLT, LTLT, LSRS, NULL, LTLT},
|
|
/*CO*/ {LULU, LULU, LULU, SULU, SULU, LULU, SULU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*AD*/ {LULU, LULU, LULU, SUSU, SUSU, LULU, SUSU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*PO*/ {LULU, LUSU, LUSU, SUSU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*SY*/ {LULU, LUSU, LUSU, LURU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*2C*/ {LULU, LULU, LULU, SULU, SULU, LULU, SULU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*SC*/ {LULU, LUSU, LUSU, LURU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*!U*/ {LTLT, NULL, NULL, NULL, NULL, NULL, NULL, LTLT, LTLT, LSRS, NULL, LTRT},
|
|
/*!T*/ {LTRT, NULL, NULL, NULL, NULL, NULL, NULL, LTLT, LTRT, LSRS, NULL, LTRT},
|
|
/*HT*/ {LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, NULL, LSRS},
|
|
/*PR*/ {NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL},
|
|
/*PR*/ {LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LSRS, NULL, LTRT},
|
|
};
|
|
const P2PTransportChannelTest::Result*
|
|
P2PTransportChannelTest::kMatrixSharedUfrag[NUM_CONFIGS][NUM_CONFIGS] = {
|
|
// OPEN CONE ADDR PORT SYMM 2CON SCON !UDP !TCP HTTP PRXH PRXS
|
|
/*OP*/ {LULU, LUSU, LULU, LULU, LULU, LUSU, LULU, LTLT, LTLT, LSRS, NULL, LTLT},
|
|
/*CO*/ {LULU, LUSU, LUSU, SUSU, SUSU, LUSU, SUSU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*AD*/ {LULU, LUSU, LUSU, SUSU, SUSU, LUSU, SUSU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*PO*/ {LULU, LUSU, LUSU, SUSU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*SY*/ {LULU, LUSU, LUSU, LURU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*2C*/ {LULU, LUSU, LUSU, SUSU, SUSU, LUSU, SUSU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*SC*/ {LULU, LUSU, LUSU, LURU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*!U*/ {LTLT, NULL, NULL, NULL, NULL, NULL, NULL, LTLT, LTLT, LSRS, NULL, LTRT},
|
|
/*!T*/ {LTRT, NULL, NULL, NULL, NULL, NULL, NULL, LTLT, LTRT, LSRS, NULL, LTRT},
|
|
/*HT*/ {LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, NULL, LSRS},
|
|
/*PR*/ {NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL},
|
|
/*PR*/ {LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LSRS, NULL, LTRT},
|
|
};
|
|
const P2PTransportChannelTest::Result*
|
|
P2PTransportChannelTest::kMatrixSharedSocketAsGice
|
|
[NUM_CONFIGS][NUM_CONFIGS] = {
|
|
// OPEN CONE ADDR PORT SYMM 2CON SCON !UDP !TCP HTTP PRXH PRXS
|
|
/*OP*/ {LULU, LUSU, LUSU, LUSU, LUSU, LUSU, LUSU, LTLT, LTLT, LSRS, NULL, LTLT},
|
|
/*CO*/ {LULU, LUSU, LUSU, LUSU, LUSU, LUSU, LUSU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*AD*/ {LULU, LUSU, LUSU, LUSU, LUSU, LUSU, LUSU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*PO*/ {LULU, LUSU, LUSU, LUSU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*SY*/ {LULU, LUSU, LUSU, LURU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*2C*/ {LULU, LUSU, LUSU, LUSU, LUSU, LUSU, LUSU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*SC*/ {LULU, LUSU, LUSU, LURU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*!U*/ {LTLT, NULL, NULL, NULL, NULL, NULL, NULL, LTLT, LTLT, LSRS, NULL, LTRT},
|
|
/*!T*/ {LTRT, NULL, NULL, NULL, NULL, NULL, NULL, LTLT, LTRT, LSRS, NULL, LTRT},
|
|
/*HT*/ {LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, NULL, LSRS},
|
|
/*PR*/ {NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL},
|
|
/*PR*/ {LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LSRS, NULL, LTRT},
|
|
};
|
|
const P2PTransportChannelTest::Result*
|
|
P2PTransportChannelTest::kMatrixSharedSocketAsIce
|
|
[NUM_CONFIGS][NUM_CONFIGS] = {
|
|
// OPEN CONE ADDR PORT SYMM 2CON SCON !UDP !TCP HTTP PRXH PRXS
|
|
/*OP*/ {LULU, LUSU, LUSU, LUSU, LUPU, LUSU, LUPU, PTLT, LTPT, LSRS, NULL, PTLT},
|
|
/*CO*/ {LULU, LUSU, LUSU, LUSU, LUPU, LUSU, LUPU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*AD*/ {LULU, LUSU, LUSU, LUSU, LUPU, LUSU, LUPU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*PO*/ {LULU, LUSU, LUSU, LUSU, LURU, LUSU, LURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*SY*/ {PULU, PUSU, PUSU, PURU, PURU, PUSU, PURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*2C*/ {LULU, LUSU, LUSU, LUSU, LUPU, LUSU, LUPU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*SC*/ {PULU, PUSU, PUSU, PURU, PURU, PUSU, PURU, NULL, NULL, LSRS, NULL, LTRT},
|
|
/*!U*/ {PTLT, NULL, NULL, NULL, NULL, NULL, NULL, PTLT, LTPT, LSRS, NULL, LTRT},
|
|
/*!T*/ {LTRT, NULL, NULL, NULL, NULL, NULL, NULL, PTLT, LTRT, LSRS, NULL, LTRT},
|
|
/*HT*/ {LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, LSRS, NULL, LSRS},
|
|
/*PR*/ {NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL},
|
|
/*PR*/ {LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LTRT, LSRS, NULL, LTRT},
|
|
};
|
|
|
|
// The actual tests that exercise all the various configurations.
|
|
// Test names are of the form P2PTransportChannelTest_TestOPENToNAT_FULL_CONE
|
|
// Same test case is run in both GICE and ICE mode.
|
|
// kDefaultStepDelay - is used for all Gice cases.
|
|
// kMinimumStepDelay - is used when both end points have
|
|
// PORTALLOCATOR_ENABLE_SHARED_UFRAG flag enabled.
|
|
// Technically we should be able to use kMinimumStepDelay irrespective of
|
|
// protocol type. But which might need modifications to current result matrices
|
|
// for tests in this file.
|
|
#define P2P_TEST_DECLARATION(x, y, z) \
|
|
TEST_F(P2PTransportChannelTest, z##Test##x##To##y##AsGiceNoneSharedUfrag) { \
|
|
ConfigureEndpoints(x, y, kDefaultPortAllocatorFlags, \
|
|
kDefaultPortAllocatorFlags, \
|
|
kDefaultStepDelay, kDefaultStepDelay, \
|
|
cricket::ICEPROTO_GOOGLE); \
|
|
if (kMatrix[x][y] != NULL) \
|
|
Test(*kMatrix[x][y]); \
|
|
else \
|
|
LOG(LS_WARNING) << "Not yet implemented"; \
|
|
} \
|
|
TEST_F(P2PTransportChannelTest, z##Test##x##To##y##AsGiceP0SharedUfrag) { \
|
|
ConfigureEndpoints(x, y, PORTALLOCATOR_ENABLE_SHARED_UFRAG, \
|
|
kDefaultPortAllocatorFlags, \
|
|
kDefaultStepDelay, kDefaultStepDelay, \
|
|
cricket::ICEPROTO_GOOGLE); \
|
|
if (kMatrix[x][y] != NULL) \
|
|
Test(*kMatrix[x][y]); \
|
|
else \
|
|
LOG(LS_WARNING) << "Not yet implemented"; \
|
|
} \
|
|
TEST_F(P2PTransportChannelTest, z##Test##x##To##y##AsGiceP1SharedUfrag) { \
|
|
ConfigureEndpoints(x, y, kDefaultPortAllocatorFlags, \
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG, \
|
|
kDefaultStepDelay, kDefaultStepDelay, \
|
|
cricket::ICEPROTO_GOOGLE); \
|
|
if (kMatrixSharedUfrag[x][y] != NULL) \
|
|
Test(*kMatrixSharedUfrag[x][y]); \
|
|
else \
|
|
LOG(LS_WARNING) << "Not yet implemented"; \
|
|
} \
|
|
TEST_F(P2PTransportChannelTest, z##Test##x##To##y##AsGiceBothSharedUfrag) { \
|
|
ConfigureEndpoints(x, y, PORTALLOCATOR_ENABLE_SHARED_UFRAG, \
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG, \
|
|
kDefaultStepDelay, kDefaultStepDelay, \
|
|
cricket::ICEPROTO_GOOGLE); \
|
|
if (kMatrixSharedUfrag[x][y] != NULL) \
|
|
Test(*kMatrixSharedUfrag[x][y]); \
|
|
else \
|
|
LOG(LS_WARNING) << "Not yet implemented"; \
|
|
} \
|
|
TEST_F(P2PTransportChannelTest, \
|
|
z##Test##x##To##y##AsGiceBothSharedUfragWithMinimumStepDelay) { \
|
|
ConfigureEndpoints(x, y, PORTALLOCATOR_ENABLE_SHARED_UFRAG, \
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG, \
|
|
kMinimumStepDelay, kMinimumStepDelay, \
|
|
cricket::ICEPROTO_GOOGLE); \
|
|
if (kMatrixSharedUfrag[x][y] != NULL) \
|
|
Test(*kMatrixSharedUfrag[x][y]); \
|
|
else \
|
|
LOG(LS_WARNING) << "Not yet implemented"; \
|
|
} \
|
|
TEST_F(P2PTransportChannelTest, \
|
|
z##Test##x##To##y##AsGiceBothSharedUfragSocket) { \
|
|
ConfigureEndpoints(x, y, PORTALLOCATOR_ENABLE_SHARED_UFRAG | \
|
|
PORTALLOCATOR_ENABLE_SHARED_SOCKET, \
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG | \
|
|
PORTALLOCATOR_ENABLE_SHARED_SOCKET, \
|
|
kMinimumStepDelay, kMinimumStepDelay, \
|
|
cricket::ICEPROTO_GOOGLE); \
|
|
if (kMatrixSharedSocketAsGice[x][y] != NULL) \
|
|
Test(*kMatrixSharedSocketAsGice[x][y]); \
|
|
else \
|
|
LOG(LS_WARNING) << "Not yet implemented"; \
|
|
} \
|
|
TEST_F(P2PTransportChannelTest, z##Test##x##To##y##AsIce) { \
|
|
ConfigureEndpoints(x, y, PORTALLOCATOR_ENABLE_SHARED_UFRAG | \
|
|
PORTALLOCATOR_ENABLE_SHARED_SOCKET, \
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG | \
|
|
PORTALLOCATOR_ENABLE_SHARED_SOCKET, \
|
|
kMinimumStepDelay, kMinimumStepDelay, \
|
|
cricket::ICEPROTO_RFC5245); \
|
|
if (kMatrixSharedSocketAsIce[x][y] != NULL) \
|
|
Test(*kMatrixSharedSocketAsIce[x][y]); \
|
|
else \
|
|
LOG(LS_WARNING) << "Not yet implemented"; \
|
|
}
|
|
|
|
#define P2P_TEST(x, y) \
|
|
P2P_TEST_DECLARATION(x, y,)
|
|
|
|
#define FLAKY_P2P_TEST(x, y) \
|
|
P2P_TEST_DECLARATION(x, y, DISABLED_)
|
|
|
|
// TODO(holmer): Disabled due to randomly failing on webrtc buildbots.
|
|
// Issue: webrtc/2383
|
|
#define P2P_TEST_SET(x) \
|
|
P2P_TEST(x, OPEN) \
|
|
FLAKY_P2P_TEST(x, NAT_FULL_CONE) \
|
|
FLAKY_P2P_TEST(x, NAT_ADDR_RESTRICTED) \
|
|
FLAKY_P2P_TEST(x, NAT_PORT_RESTRICTED) \
|
|
P2P_TEST(x, NAT_SYMMETRIC) \
|
|
FLAKY_P2P_TEST(x, NAT_DOUBLE_CONE) \
|
|
P2P_TEST(x, NAT_SYMMETRIC_THEN_CONE) \
|
|
P2P_TEST(x, BLOCK_UDP) \
|
|
P2P_TEST(x, BLOCK_UDP_AND_INCOMING_TCP) \
|
|
P2P_TEST(x, BLOCK_ALL_BUT_OUTGOING_HTTP) \
|
|
P2P_TEST(x, PROXY_HTTPS) \
|
|
P2P_TEST(x, PROXY_SOCKS)
|
|
|
|
#define FLAKY_P2P_TEST_SET(x) \
|
|
P2P_TEST(x, OPEN) \
|
|
P2P_TEST(x, NAT_FULL_CONE) \
|
|
P2P_TEST(x, NAT_ADDR_RESTRICTED) \
|
|
P2P_TEST(x, NAT_PORT_RESTRICTED) \
|
|
P2P_TEST(x, NAT_SYMMETRIC) \
|
|
P2P_TEST(x, NAT_DOUBLE_CONE) \
|
|
P2P_TEST(x, NAT_SYMMETRIC_THEN_CONE) \
|
|
P2P_TEST(x, BLOCK_UDP) \
|
|
P2P_TEST(x, BLOCK_UDP_AND_INCOMING_TCP) \
|
|
P2P_TEST(x, BLOCK_ALL_BUT_OUTGOING_HTTP) \
|
|
P2P_TEST(x, PROXY_HTTPS) \
|
|
P2P_TEST(x, PROXY_SOCKS)
|
|
|
|
P2P_TEST_SET(OPEN)
|
|
P2P_TEST_SET(NAT_FULL_CONE)
|
|
P2P_TEST_SET(NAT_ADDR_RESTRICTED)
|
|
P2P_TEST_SET(NAT_PORT_RESTRICTED)
|
|
P2P_TEST_SET(NAT_SYMMETRIC)
|
|
P2P_TEST_SET(NAT_DOUBLE_CONE)
|
|
P2P_TEST_SET(NAT_SYMMETRIC_THEN_CONE)
|
|
P2P_TEST_SET(BLOCK_UDP)
|
|
P2P_TEST_SET(BLOCK_UDP_AND_INCOMING_TCP)
|
|
P2P_TEST_SET(BLOCK_ALL_BUT_OUTGOING_HTTP)
|
|
P2P_TEST_SET(PROXY_HTTPS)
|
|
P2P_TEST_SET(PROXY_SOCKS)
|
|
|
|
// Test that we restart candidate allocation when local ufrag&pwd changed.
|
|
// Standard Ice protocol is used.
|
|
TEST_F(P2PTransportChannelTest, HandleUfragPwdChangeAsIce) {
|
|
ConfigureEndpoints(OPEN, OPEN,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
kMinimumStepDelay, kMinimumStepDelay,
|
|
cricket::ICEPROTO_RFC5245);
|
|
CreateChannels(1);
|
|
TestHandleIceUfragPasswordChanged();
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test that we restart candidate allocation when local ufrag&pwd changed.
|
|
// Standard Ice protocol is used.
|
|
TEST_F(P2PTransportChannelTest, HandleUfragPwdChangeBundleAsIce) {
|
|
ConfigureEndpoints(OPEN, OPEN,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
kMinimumStepDelay, kMinimumStepDelay,
|
|
cricket::ICEPROTO_RFC5245);
|
|
SetAllocatorFlags(0, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
SetAllocatorFlags(1, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
|
|
CreateChannels(2);
|
|
TestHandleIceUfragPasswordChanged();
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test that we restart candidate allocation when local ufrag&pwd changed.
|
|
// Google Ice protocol is used.
|
|
TEST_F(P2PTransportChannelTest, HandleUfragPwdChangeAsGice) {
|
|
ConfigureEndpoints(OPEN, OPEN,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
kDefaultStepDelay, kDefaultStepDelay,
|
|
cricket::ICEPROTO_GOOGLE);
|
|
CreateChannels(1);
|
|
TestHandleIceUfragPasswordChanged();
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test that ICE restart works when bundle is enabled.
|
|
// Google Ice protocol is used.
|
|
TEST_F(P2PTransportChannelTest, HandleUfragPwdChangeBundleAsGice) {
|
|
ConfigureEndpoints(OPEN, OPEN,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
kDefaultStepDelay, kDefaultStepDelay,
|
|
cricket::ICEPROTO_GOOGLE);
|
|
SetAllocatorFlags(0, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
SetAllocatorFlags(1, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
|
|
CreateChannels(2);
|
|
TestHandleIceUfragPasswordChanged();
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test the operation of GetStats.
|
|
TEST_F(P2PTransportChannelTest, GetStats) {
|
|
ConfigureEndpoints(OPEN, OPEN,
|
|
kDefaultPortAllocatorFlags,
|
|
kDefaultPortAllocatorFlags,
|
|
kDefaultStepDelay, kDefaultStepDelay,
|
|
cricket::ICEPROTO_GOOGLE);
|
|
CreateChannels(1);
|
|
EXPECT_TRUE_WAIT_MARGIN(ep1_ch1()->readable() && ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() && ep2_ch1()->writable(),
|
|
1000, 1000);
|
|
TestSendRecv(1);
|
|
cricket::ConnectionInfos infos;
|
|
ASSERT_TRUE(ep1_ch1()->GetStats(&infos));
|
|
ASSERT_EQ(1U, infos.size());
|
|
EXPECT_TRUE(infos[0].new_connection);
|
|
EXPECT_TRUE(infos[0].best_connection);
|
|
EXPECT_TRUE(infos[0].readable);
|
|
EXPECT_TRUE(infos[0].writable);
|
|
EXPECT_FALSE(infos[0].timeout);
|
|
EXPECT_EQ(10 * 36U, infos[0].sent_total_bytes);
|
|
EXPECT_EQ(10 * 36U, infos[0].recv_total_bytes);
|
|
EXPECT_GT(infos[0].rtt, 0U);
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test that we properly handle getting a STUN error due to slow signaling.
|
|
TEST_F(P2PTransportChannelTest, DISABLED_SlowSignaling) {
|
|
ConfigureEndpoints(OPEN, NAT_SYMMETRIC,
|
|
kDefaultPortAllocatorFlags,
|
|
kDefaultPortAllocatorFlags,
|
|
kDefaultStepDelay, kDefaultStepDelay,
|
|
cricket::ICEPROTO_GOOGLE);
|
|
// Make signaling from the callee take 500ms, so that the initial STUN pings
|
|
// from the callee beat the signaling, and so the caller responds with a
|
|
// unknown username error. We should just eat that and carry on; mishandling
|
|
// this will instead cause all the callee's connections to be discarded.
|
|
SetSignalingDelay(1, 1000);
|
|
CreateChannels(1);
|
|
const cricket::Connection* best_connection = NULL;
|
|
// Wait until the callee's connections are created.
|
|
WAIT((best_connection = ep2_ch1()->best_connection()) != NULL, 1000);
|
|
// Wait to see if they get culled; they shouldn't.
|
|
WAIT(ep2_ch1()->best_connection() != best_connection, 1000);
|
|
EXPECT_TRUE(ep2_ch1()->best_connection() == best_connection);
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test that if remote candidates don't have ufrag and pwd, we still work.
|
|
TEST_F(P2PTransportChannelTest, RemoteCandidatesWithoutUfragPwd) {
|
|
set_clear_remote_candidates_ufrag_pwd(true);
|
|
ConfigureEndpoints(OPEN, OPEN,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
kMinimumStepDelay, kMinimumStepDelay,
|
|
cricket::ICEPROTO_GOOGLE);
|
|
CreateChannels(1);
|
|
const cricket::Connection* best_connection = NULL;
|
|
// Wait until the callee's connections are created.
|
|
WAIT((best_connection = ep2_ch1()->best_connection()) != NULL, 1000);
|
|
// Wait to see if they get culled; they shouldn't.
|
|
WAIT(ep2_ch1()->best_connection() != best_connection, 1000);
|
|
EXPECT_TRUE(ep2_ch1()->best_connection() == best_connection);
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test that a host behind NAT cannot be reached when incoming_only
|
|
// is set to true.
|
|
TEST_F(P2PTransportChannelTest, IncomingOnlyBlocked) {
|
|
ConfigureEndpoints(NAT_FULL_CONE, OPEN,
|
|
kDefaultPortAllocatorFlags,
|
|
kDefaultPortAllocatorFlags,
|
|
kDefaultStepDelay, kDefaultStepDelay,
|
|
cricket::ICEPROTO_GOOGLE);
|
|
|
|
SetAllocatorFlags(0, kOnlyLocalPorts);
|
|
CreateChannels(1);
|
|
ep1_ch1()->set_incoming_only(true);
|
|
|
|
// Pump for 1 second and verify that the channels are not connected.
|
|
rtc::Thread::Current()->ProcessMessages(1000);
|
|
|
|
EXPECT_FALSE(ep1_ch1()->readable());
|
|
EXPECT_FALSE(ep1_ch1()->writable());
|
|
EXPECT_FALSE(ep2_ch1()->readable());
|
|
EXPECT_FALSE(ep2_ch1()->writable());
|
|
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test that a peer behind NAT can connect to a peer that has
|
|
// incoming_only flag set.
|
|
TEST_F(P2PTransportChannelTest, IncomingOnlyOpen) {
|
|
ConfigureEndpoints(OPEN, NAT_FULL_CONE,
|
|
kDefaultPortAllocatorFlags,
|
|
kDefaultPortAllocatorFlags,
|
|
kDefaultStepDelay, kDefaultStepDelay,
|
|
cricket::ICEPROTO_GOOGLE);
|
|
|
|
SetAllocatorFlags(0, kOnlyLocalPorts);
|
|
CreateChannels(1);
|
|
ep1_ch1()->set_incoming_only(true);
|
|
|
|
EXPECT_TRUE_WAIT_MARGIN(ep1_ch1() != NULL && ep2_ch1() != NULL &&
|
|
ep1_ch1()->readable() && ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() && ep2_ch1()->writable(),
|
|
1000, 1000);
|
|
|
|
DestroyChannels();
|
|
}
|
|
|
|
TEST_F(P2PTransportChannelTest, TestTcpConnectionsFromActiveToPassive) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
|
|
SetAllocationStepDelay(0, kMinimumStepDelay);
|
|
SetAllocationStepDelay(1, kMinimumStepDelay);
|
|
|
|
int kOnlyLocalTcpPorts = cricket::PORTALLOCATOR_DISABLE_UDP |
|
|
cricket::PORTALLOCATOR_DISABLE_STUN |
|
|
cricket::PORTALLOCATOR_DISABLE_RELAY |
|
|
cricket::PORTALLOCATOR_ENABLE_SHARED_UFRAG;
|
|
// Disable all protocols except TCP.
|
|
SetAllocatorFlags(0, kOnlyLocalTcpPorts);
|
|
SetAllocatorFlags(1, kOnlyLocalTcpPorts);
|
|
|
|
SetAllowTcpListen(0, true); // actpass.
|
|
SetAllowTcpListen(1, false); // active.
|
|
|
|
CreateChannels(1);
|
|
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() && ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() && ep2_ch1()->writable(),
|
|
1000);
|
|
EXPECT_TRUE(
|
|
ep1_ch1()->best_connection() && ep2_ch1()->best_connection() &&
|
|
LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) &&
|
|
RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1]));
|
|
|
|
std::string kTcpProtocol = "tcp";
|
|
EXPECT_EQ(kTcpProtocol, RemoteCandidate(ep1_ch1())->protocol());
|
|
EXPECT_EQ(kTcpProtocol, LocalCandidate(ep1_ch1())->protocol());
|
|
EXPECT_EQ(kTcpProtocol, RemoteCandidate(ep2_ch1())->protocol());
|
|
EXPECT_EQ(kTcpProtocol, LocalCandidate(ep2_ch1())->protocol());
|
|
|
|
TestSendRecv(1);
|
|
DestroyChannels();
|
|
}
|
|
|
|
TEST_F(P2PTransportChannelTest, TestBundleAllocatorToBundleAllocator) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
SetAllocatorFlags(0, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
SetAllocatorFlags(1, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
|
|
CreateChannels(2);
|
|
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() &&
|
|
ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() &&
|
|
ep2_ch1()->writable(),
|
|
1000);
|
|
EXPECT_TRUE(ep1_ch1()->best_connection() &&
|
|
ep2_ch1()->best_connection());
|
|
|
|
EXPECT_FALSE(ep1_ch2()->readable());
|
|
EXPECT_FALSE(ep1_ch2()->writable());
|
|
EXPECT_FALSE(ep2_ch2()->readable());
|
|
EXPECT_FALSE(ep2_ch2()->writable());
|
|
|
|
TestSendRecv(1); // Only 1 channel is writable per Endpoint.
|
|
DestroyChannels();
|
|
}
|
|
|
|
TEST_F(P2PTransportChannelTest, TestBundleAllocatorToNonBundleAllocator) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
// Enable BUNDLE flag at one side.
|
|
SetAllocatorFlags(0, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
|
|
CreateChannels(2);
|
|
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() &&
|
|
ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() &&
|
|
ep2_ch1()->writable(),
|
|
1000);
|
|
EXPECT_TRUE_WAIT(ep1_ch2()->readable() &&
|
|
ep1_ch2()->writable() &&
|
|
ep2_ch2()->readable() &&
|
|
ep2_ch2()->writable(),
|
|
1000);
|
|
|
|
EXPECT_TRUE(ep1_ch1()->best_connection() &&
|
|
ep2_ch1()->best_connection());
|
|
EXPECT_TRUE(ep1_ch2()->best_connection() &&
|
|
ep2_ch2()->best_connection());
|
|
|
|
TestSendRecv(2);
|
|
DestroyChannels();
|
|
}
|
|
|
|
TEST_F(P2PTransportChannelTest, TestIceRoleConflictWithoutBundle) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
TestSignalRoleConflict();
|
|
}
|
|
|
|
TEST_F(P2PTransportChannelTest, TestIceRoleConflictWithBundle) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
SetAllocatorFlags(0, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
SetAllocatorFlags(1, cricket::PORTALLOCATOR_ENABLE_BUNDLE);
|
|
TestSignalRoleConflict();
|
|
}
|
|
|
|
// Tests that the ice configs (protocol, tiebreaker and role) can be passed
|
|
// down to ports.
|
|
TEST_F(P2PTransportChannelTest, TestIceConfigWillPassDownToPort) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
|
|
SetIceRole(0, cricket::ICEROLE_CONTROLLING);
|
|
SetIceProtocol(0, cricket::ICEPROTO_GOOGLE);
|
|
SetIceTiebreaker(0, kTiebreaker1);
|
|
SetIceRole(1, cricket::ICEROLE_CONTROLLING);
|
|
SetIceProtocol(1, cricket::ICEPROTO_RFC5245);
|
|
SetIceTiebreaker(1, kTiebreaker2);
|
|
|
|
CreateChannels(1);
|
|
|
|
EXPECT_EQ_WAIT(2u, ep1_ch1()->ports().size(), 1000);
|
|
|
|
const std::vector<cricket::PortInterface *> ports_before = ep1_ch1()->ports();
|
|
for (size_t i = 0; i < ports_before.size(); ++i) {
|
|
EXPECT_EQ(cricket::ICEROLE_CONTROLLING, ports_before[i]->GetIceRole());
|
|
EXPECT_EQ(cricket::ICEPROTO_GOOGLE, ports_before[i]->IceProtocol());
|
|
EXPECT_EQ(kTiebreaker1, ports_before[i]->IceTiebreaker());
|
|
}
|
|
|
|
ep1_ch1()->SetIceRole(cricket::ICEROLE_CONTROLLED);
|
|
ep1_ch1()->SetIceProtocolType(cricket::ICEPROTO_RFC5245);
|
|
ep1_ch1()->SetIceTiebreaker(kTiebreaker2);
|
|
|
|
const std::vector<cricket::PortInterface *> ports_after = ep1_ch1()->ports();
|
|
for (size_t i = 0; i < ports_after.size(); ++i) {
|
|
EXPECT_EQ(cricket::ICEROLE_CONTROLLED, ports_before[i]->GetIceRole());
|
|
EXPECT_EQ(cricket::ICEPROTO_RFC5245, ports_before[i]->IceProtocol());
|
|
// SetIceTiebreaker after Connect() has been called will fail. So expect the
|
|
// original value.
|
|
EXPECT_EQ(kTiebreaker1, ports_before[i]->IceTiebreaker());
|
|
}
|
|
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() &&
|
|
ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() &&
|
|
ep2_ch1()->writable(),
|
|
1000);
|
|
|
|
EXPECT_TRUE(ep1_ch1()->best_connection() &&
|
|
ep2_ch1()->best_connection());
|
|
|
|
TestSendRecv(1);
|
|
DestroyChannels();
|
|
}
|
|
|
|
// This test verifies channel can handle ice messages when channel is in
|
|
// hybrid mode.
|
|
TEST_F(P2PTransportChannelTest, TestConnectivityBetweenHybridandIce) {
|
|
TestHybridConnectivity(cricket::ICEPROTO_RFC5245);
|
|
}
|
|
|
|
// This test verifies channel can handle Gice messages when channel is in
|
|
// hybrid mode.
|
|
TEST_F(P2PTransportChannelTest, TestConnectivityBetweenHybridandGice) {
|
|
TestHybridConnectivity(cricket::ICEPROTO_GOOGLE);
|
|
}
|
|
|
|
// Verify that we can set DSCP value and retrieve properly from P2PTC.
|
|
TEST_F(P2PTransportChannelTest, TestDefaultDscpValue) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
|
|
CreateChannels(1);
|
|
EXPECT_EQ(rtc::DSCP_NO_CHANGE,
|
|
GetEndpoint(0)->cd1_.ch_->DefaultDscpValue());
|
|
EXPECT_EQ(rtc::DSCP_NO_CHANGE,
|
|
GetEndpoint(1)->cd1_.ch_->DefaultDscpValue());
|
|
GetEndpoint(0)->cd1_.ch_->SetOption(
|
|
rtc::Socket::OPT_DSCP, rtc::DSCP_CS6);
|
|
GetEndpoint(1)->cd1_.ch_->SetOption(
|
|
rtc::Socket::OPT_DSCP, rtc::DSCP_CS6);
|
|
EXPECT_EQ(rtc::DSCP_CS6,
|
|
GetEndpoint(0)->cd1_.ch_->DefaultDscpValue());
|
|
EXPECT_EQ(rtc::DSCP_CS6,
|
|
GetEndpoint(1)->cd1_.ch_->DefaultDscpValue());
|
|
GetEndpoint(0)->cd1_.ch_->SetOption(
|
|
rtc::Socket::OPT_DSCP, rtc::DSCP_AF41);
|
|
GetEndpoint(1)->cd1_.ch_->SetOption(
|
|
rtc::Socket::OPT_DSCP, rtc::DSCP_AF41);
|
|
EXPECT_EQ(rtc::DSCP_AF41,
|
|
GetEndpoint(0)->cd1_.ch_->DefaultDscpValue());
|
|
EXPECT_EQ(rtc::DSCP_AF41,
|
|
GetEndpoint(1)->cd1_.ch_->DefaultDscpValue());
|
|
}
|
|
|
|
// Verify IPv6 connection is preferred over IPv4.
|
|
// Flaky: https://code.google.com/p/webrtc/issues/detail?id=3317
|
|
TEST_F(P2PTransportChannelTest, DISABLED_TestIPv6Connections) {
|
|
AddAddress(0, kIPv6PublicAddrs[0]);
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kIPv6PublicAddrs[1]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
|
|
SetAllocationStepDelay(0, kMinimumStepDelay);
|
|
SetAllocationStepDelay(1, kMinimumStepDelay);
|
|
|
|
// Enable IPv6
|
|
SetAllocatorFlags(0, cricket::PORTALLOCATOR_ENABLE_IPV6);
|
|
SetAllocatorFlags(1, cricket::PORTALLOCATOR_ENABLE_IPV6);
|
|
|
|
CreateChannels(1);
|
|
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() && ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() && ep2_ch1()->writable(),
|
|
1000);
|
|
EXPECT_TRUE(
|
|
ep1_ch1()->best_connection() && ep2_ch1()->best_connection() &&
|
|
LocalCandidate(ep1_ch1())->address().EqualIPs(kIPv6PublicAddrs[0]) &&
|
|
RemoteCandidate(ep1_ch1())->address().EqualIPs(kIPv6PublicAddrs[1]));
|
|
|
|
TestSendRecv(1);
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Testing forceful TURN connections.
|
|
TEST_F(P2PTransportChannelTest, TestForceTurn) {
|
|
ConfigureEndpoints(NAT_PORT_RESTRICTED, NAT_SYMMETRIC,
|
|
kDefaultPortAllocatorFlags |
|
|
cricket::PORTALLOCATOR_ENABLE_SHARED_SOCKET |
|
|
cricket::PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
kDefaultPortAllocatorFlags |
|
|
cricket::PORTALLOCATOR_ENABLE_SHARED_SOCKET |
|
|
cricket::PORTALLOCATOR_ENABLE_SHARED_UFRAG,
|
|
kDefaultStepDelay, kDefaultStepDelay,
|
|
cricket::ICEPROTO_RFC5245);
|
|
set_force_relay(true);
|
|
|
|
SetAllocationStepDelay(0, kMinimumStepDelay);
|
|
SetAllocationStepDelay(1, kMinimumStepDelay);
|
|
|
|
CreateChannels(1);
|
|
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() &&
|
|
ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() &&
|
|
ep2_ch1()->writable(),
|
|
1000);
|
|
|
|
EXPECT_TRUE(ep1_ch1()->best_connection() &&
|
|
ep2_ch1()->best_connection());
|
|
|
|
EXPECT_EQ("relay", RemoteCandidate(ep1_ch1())->type());
|
|
EXPECT_EQ("relay", LocalCandidate(ep1_ch1())->type());
|
|
EXPECT_EQ("relay", RemoteCandidate(ep2_ch1())->type());
|
|
EXPECT_EQ("relay", LocalCandidate(ep2_ch1())->type());
|
|
|
|
TestSendRecv(1);
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test what happens when we have 2 users behind the same NAT. This can lead
|
|
// to interesting behavior because the STUN server will only give out the
|
|
// address of the outermost NAT.
|
|
class P2PTransportChannelSameNatTest : public P2PTransportChannelTestBase {
|
|
protected:
|
|
void ConfigureEndpoints(Config nat_type, Config config1, Config config2) {
|
|
ASSERT(nat_type >= NAT_FULL_CONE && nat_type <= NAT_SYMMETRIC);
|
|
rtc::NATSocketServer::Translator* outer_nat =
|
|
nat()->AddTranslator(kPublicAddrs[0], kNatAddrs[0],
|
|
static_cast<rtc::NATType>(nat_type - NAT_FULL_CONE));
|
|
ConfigureEndpoint(outer_nat, 0, config1);
|
|
ConfigureEndpoint(outer_nat, 1, config2);
|
|
}
|
|
void ConfigureEndpoint(rtc::NATSocketServer::Translator* nat,
|
|
int endpoint, Config config) {
|
|
ASSERT(config <= NAT_SYMMETRIC);
|
|
if (config == OPEN) {
|
|
AddAddress(endpoint, kPrivateAddrs[endpoint]);
|
|
nat->AddClient(kPrivateAddrs[endpoint]);
|
|
} else {
|
|
AddAddress(endpoint, kCascadedPrivateAddrs[endpoint]);
|
|
nat->AddTranslator(kPrivateAddrs[endpoint], kCascadedNatAddrs[endpoint],
|
|
static_cast<rtc::NATType>(config - NAT_FULL_CONE))->AddClient(
|
|
kCascadedPrivateAddrs[endpoint]);
|
|
}
|
|
}
|
|
};
|
|
|
|
TEST_F(P2PTransportChannelSameNatTest, TestConesBehindSameCone) {
|
|
ConfigureEndpoints(NAT_FULL_CONE, NAT_FULL_CONE, NAT_FULL_CONE);
|
|
Test(kLocalUdpToStunUdp);
|
|
}
|
|
|
|
// Test what happens when we have multiple available pathways.
|
|
// In the future we will try different RTTs and configs for the different
|
|
// interfaces, so that we can simulate a user with Ethernet and VPN networks.
|
|
class P2PTransportChannelMultihomedTest : public P2PTransportChannelTestBase {
|
|
};
|
|
|
|
// Test that we can establish connectivity when both peers are multihomed.
|
|
TEST_F(P2PTransportChannelMultihomedTest, DISABLED_TestBasic) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(0, kAlternateAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
AddAddress(1, kAlternateAddrs[1]);
|
|
Test(kLocalUdpToLocalUdp);
|
|
}
|
|
|
|
// Test that we can quickly switch links if an interface goes down.
|
|
TEST_F(P2PTransportChannelMultihomedTest, TestFailover) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
// Adding alternate address will make sure |kPublicAddrs| has the higher
|
|
// priority than others. This is due to FakeNetwork::AddInterface method.
|
|
AddAddress(1, kAlternateAddrs[1]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
|
|
// Use only local ports for simplicity.
|
|
SetAllocatorFlags(0, kOnlyLocalPorts);
|
|
SetAllocatorFlags(1, kOnlyLocalPorts);
|
|
|
|
// Create channels and let them go writable, as usual.
|
|
CreateChannels(1);
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() && ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() && ep2_ch1()->writable(),
|
|
1000);
|
|
EXPECT_TRUE(
|
|
ep1_ch1()->best_connection() && ep2_ch1()->best_connection() &&
|
|
LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) &&
|
|
RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1]));
|
|
|
|
// Blackhole any traffic to or from the public addrs.
|
|
LOG(LS_INFO) << "Failing over...";
|
|
fw()->AddRule(false, rtc::FP_ANY, rtc::FD_ANY,
|
|
kPublicAddrs[1]);
|
|
|
|
// We should detect loss of connectivity within 5 seconds or so.
|
|
EXPECT_TRUE_WAIT(!ep1_ch1()->writable(), 7000);
|
|
|
|
// We should switch over to use the alternate addr immediately
|
|
// when we lose writability.
|
|
EXPECT_TRUE_WAIT(
|
|
ep1_ch1()->best_connection() && ep2_ch1()->best_connection() &&
|
|
LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) &&
|
|
RemoteCandidate(ep1_ch1())->address().EqualIPs(kAlternateAddrs[1]),
|
|
3000);
|
|
|
|
DestroyChannels();
|
|
}
|
|
|
|
// Test that we can switch links in a coordinated fashion.
|
|
TEST_F(P2PTransportChannelMultihomedTest, TestDrain) {
|
|
AddAddress(0, kPublicAddrs[0]);
|
|
AddAddress(1, kPublicAddrs[1]);
|
|
// Use only local ports for simplicity.
|
|
SetAllocatorFlags(0, kOnlyLocalPorts);
|
|
SetAllocatorFlags(1, kOnlyLocalPorts);
|
|
|
|
// Create channels and let them go writable, as usual.
|
|
CreateChannels(1);
|
|
EXPECT_TRUE_WAIT(ep1_ch1()->readable() && ep1_ch1()->writable() &&
|
|
ep2_ch1()->readable() && ep2_ch1()->writable(),
|
|
1000);
|
|
EXPECT_TRUE(
|
|
ep1_ch1()->best_connection() && ep2_ch1()->best_connection() &&
|
|
LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) &&
|
|
RemoteCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[1]));
|
|
|
|
// Remove the public interface, add the alternate interface, and allocate
|
|
// a new generation of candidates for the new interface (via Connect()).
|
|
LOG(LS_INFO) << "Draining...";
|
|
AddAddress(1, kAlternateAddrs[1]);
|
|
RemoveAddress(1, kPublicAddrs[1]);
|
|
ep2_ch1()->Connect();
|
|
|
|
// We should switch over to use the alternate address after
|
|
// an exchange of pings.
|
|
EXPECT_TRUE_WAIT(
|
|
ep1_ch1()->best_connection() && ep2_ch1()->best_connection() &&
|
|
LocalCandidate(ep1_ch1())->address().EqualIPs(kPublicAddrs[0]) &&
|
|
RemoteCandidate(ep1_ch1())->address().EqualIPs(kAlternateAddrs[1]),
|
|
3000);
|
|
|
|
DestroyChannels();
|
|
}
|