blob: 75490ee9d7edeb37254fe885f6885213f12c7fa3 [file] [log] [blame]
/*
* Copyright 2004 The WebRTC Project Authors. All rights reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "p2p/base/p2p_transport_channel.h"
#include <iterator>
#include <memory>
#include <set>
#include <utility>
#include "absl/algorithm/container.h"
#include "absl/strings/match.h"
#include "api/candidate.h"
#include "logging/rtc_event_log/ice_logger.h"
#include "p2p/base/basic_ice_controller.h"
#include "p2p/base/candidate_pair_interface.h"
#include "p2p/base/connection.h"
#include "p2p/base/port.h"
#include "rtc_base/checks.h"
#include "rtc_base/crc32.h"
#include "rtc_base/experiments/struct_parameters_parser.h"
#include "rtc_base/logging.h"
#include "rtc_base/net_helper.h"
#include "rtc_base/net_helpers.h"
#include "rtc_base/string_encode.h"
#include "rtc_base/time_utils.h"
#include "system_wrappers/include/field_trial.h"
#include "system_wrappers/include/metrics.h"
namespace {
cricket::PortInterface::CandidateOrigin GetOrigin(
cricket::PortInterface* port,
cricket::PortInterface* origin_port) {
if (!origin_port)
return cricket::PortInterface::ORIGIN_MESSAGE;
else if (port == origin_port)
return cricket::PortInterface::ORIGIN_THIS_PORT;
else
return cricket::PortInterface::ORIGIN_OTHER_PORT;
}
uint32_t GetWeakPingIntervalInFieldTrial() {
uint32_t weak_ping_interval = ::strtoul(
webrtc::field_trial::FindFullName("WebRTC-StunInterPacketDelay").c_str(),
nullptr, 10);
if (weak_ping_interval) {
return static_cast<int>(weak_ping_interval);
}
return cricket::WEAK_PING_INTERVAL;
}
} // unnamed namespace
namespace cricket {
using webrtc::RTCError;
using webrtc::RTCErrorType;
bool IceCredentialsChanged(const std::string& old_ufrag,
const std::string& old_pwd,
const std::string& new_ufrag,
const std::string& new_pwd) {
// The standard (RFC 5245 Section 9.1.1.1) says that ICE restarts MUST change
// both the ufrag and password. However, section 9.2.1.1 says changing the
// ufrag OR password indicates an ICE restart. So, to keep compatibility with
// endpoints that only change one, we'll treat this as an ICE restart.
return (old_ufrag != new_ufrag) || (old_pwd != new_pwd);
}
P2PTransportChannel::P2PTransportChannel(const std::string& transport_name,
int component,
PortAllocator* allocator)
: P2PTransportChannel(transport_name,
component,
allocator,
nullptr,
nullptr) {}
P2PTransportChannel::P2PTransportChannel(
const std::string& transport_name,
int component,
PortAllocator* allocator,
webrtc::AsyncResolverFactory* async_resolver_factory,
webrtc::RtcEventLog* event_log,
IceControllerFactoryInterface* ice_controller_factory)
: transport_name_(transport_name),
component_(component),
allocator_(allocator),
async_resolver_factory_(async_resolver_factory),
network_thread_(rtc::Thread::Current()),
incoming_only_(false),
error_(0),
sort_dirty_(false),
remote_ice_mode_(ICEMODE_FULL),
ice_role_(ICEROLE_UNKNOWN),
tiebreaker_(0),
gathering_state_(kIceGatheringNew),
config_(RECEIVING_TIMEOUT,
BACKUP_CONNECTION_PING_INTERVAL,
GATHER_ONCE /* continual_gathering_policy */,
false /* prioritize_most_likely_candidate_pairs */,
STRONG_AND_STABLE_WRITABLE_CONNECTION_PING_INTERVAL,
true /* presume_writable_when_fully_relayed */,
REGATHER_ON_FAILED_NETWORKS_INTERVAL,
RECEIVING_SWITCHING_DELAY) {
RTC_DCHECK(allocator_ != nullptr);
weak_ping_interval_ = GetWeakPingIntervalInFieldTrial();
// Validate IceConfig even for mostly built-in constant default values in case
// we change them.
RTC_DCHECK(ValidateIceConfig(config_).ok());
webrtc::BasicRegatheringController::Config regathering_config(
config_.regather_all_networks_interval_range,
config_.regather_on_failed_networks_interval_or_default());
regathering_controller_ =
std::make_unique<webrtc::BasicRegatheringController>(
regathering_config, this, network_thread_);
// We populate the change in the candidate filter to the session taken by
// the transport.
allocator_->SignalCandidateFilterChanged.connect(
this, &P2PTransportChannel::OnCandidateFilterChanged);
ice_event_log_.set_event_log(event_log);
IceControllerFactoryArgs args{
[this] { return GetState(); },
[this] { return GetIceRole(); },
[this](const Connection* connection) {
// TODO(webrtc:10647/jonaso): Figure out a way to remove friendship
// between P2PTransportChannel and Connection.
return IsPortPruned(connection->port()) ||
IsRemoteCandidatePruned(connection->remote_candidate());
},
&field_trials_,
};
if (ice_controller_factory != nullptr) {
ice_controller_ = ice_controller_factory->Create(args);
} else {
ice_controller_ = std::make_unique<BasicIceController>(args);
}
}
P2PTransportChannel::~P2PTransportChannel() {
std::vector<Connection*> copy(connections().begin(), connections().end());
for (Connection* con : copy) {
con->Destroy();
}
for (auto& p : resolvers_) {
p.resolver_->Destroy(false);
}
resolvers_.clear();
RTC_DCHECK_RUN_ON(network_thread_);
}
// Add the allocator session to our list so that we know which sessions
// are still active.
void P2PTransportChannel::AddAllocatorSession(
std::unique_ptr<PortAllocatorSession> session) {
RTC_DCHECK_RUN_ON(network_thread_);
session->set_generation(static_cast<uint32_t>(allocator_sessions_.size()));
session->SignalPortReady.connect(this, &P2PTransportChannel::OnPortReady);
session->SignalPortsPruned.connect(this, &P2PTransportChannel::OnPortsPruned);
session->SignalCandidatesReady.connect(
this, &P2PTransportChannel::OnCandidatesReady);
session->SignalCandidateError.connect(this,
&P2PTransportChannel::OnCandidateError);
session->SignalCandidatesRemoved.connect(
this, &P2PTransportChannel::OnCandidatesRemoved);
session->SignalCandidatesAllocationDone.connect(
this, &P2PTransportChannel::OnCandidatesAllocationDone);
if (!allocator_sessions_.empty()) {
allocator_session()->PruneAllPorts();
}
allocator_sessions_.push_back(std::move(session));
regathering_controller_->set_allocator_session(allocator_session());
// We now only want to apply new candidates that we receive to the ports
// created by this new session because these are replacing those of the
// previous sessions.
PruneAllPorts();
}
void P2PTransportChannel::AddConnection(Connection* connection) {
RTC_DCHECK_RUN_ON(network_thread_);
connection->set_remote_ice_mode(remote_ice_mode_);
connection->set_receiving_timeout(config_.receiving_timeout);
connection->set_unwritable_timeout(config_.ice_unwritable_timeout);
connection->set_unwritable_min_checks(config_.ice_unwritable_min_checks);
connection->set_inactive_timeout(config_.ice_inactive_timeout);
connection->SignalReadPacket.connect(this,
&P2PTransportChannel::OnReadPacket);
connection->SignalReadyToSend.connect(this,
&P2PTransportChannel::OnReadyToSend);
connection->SignalStateChange.connect(
this, &P2PTransportChannel::OnConnectionStateChange);
connection->SignalDestroyed.connect(
this, &P2PTransportChannel::OnConnectionDestroyed);
connection->SignalNominated.connect(this, &P2PTransportChannel::OnNominated);
had_connection_ = true;
connection->set_ice_event_log(&ice_event_log_);
connection->SetIceFieldTrials(&field_trials_);
LogCandidatePairConfig(connection,
webrtc::IceCandidatePairConfigType::kAdded);
ice_controller_->AddConnection(connection);
}
bool P2PTransportChannel::MaybeSwitchSelectedConnection(
Connection* new_connection,
IceControllerEvent reason) {
RTC_DCHECK_RUN_ON(network_thread_);
return MaybeSwitchSelectedConnection(
reason, ice_controller_->ShouldSwitchConnection(reason, new_connection));
}
bool P2PTransportChannel::MaybeSwitchSelectedConnection(
IceControllerEvent reason,
IceControllerInterface::SwitchResult result) {
RTC_DCHECK_RUN_ON(network_thread_);
if (result.connection.has_value()) {
RTC_LOG(LS_INFO) << "Switching selected connection due to: "
<< reason.ToString();
SwitchSelectedConnection(const_cast<Connection*>(*result.connection),
reason);
}
if (result.recheck_event.has_value()) {
// If we do not switch to the connection because it missed the receiving
// threshold, the new connection is in a better receiving state than the
// currently selected connection. So we need to re-check whether it needs
// to be switched at a later time.
invoker_.AsyncInvokeDelayed<void>(
RTC_FROM_HERE, thread(),
rtc::Bind(&P2PTransportChannel::SortConnectionsAndUpdateState, this,
*result.recheck_event),
result.recheck_event->recheck_delay_ms);
}
return result.connection.has_value();
}
void P2PTransportChannel::SetIceRole(IceRole ice_role) {
RTC_DCHECK_RUN_ON(network_thread_);
if (ice_role_ != ice_role) {
ice_role_ = ice_role;
for (PortInterface* port : ports_) {
port->SetIceRole(ice_role);
}
// Update role on pruned ports as well, because they may still have
// connections alive that should be using the correct role.
for (PortInterface* port : pruned_ports_) {
port->SetIceRole(ice_role);
}
}
}
IceRole P2PTransportChannel::GetIceRole() const {
RTC_DCHECK_RUN_ON(network_thread_);
return ice_role_;
}
void P2PTransportChannel::SetIceTiebreaker(uint64_t tiebreaker) {
RTC_DCHECK_RUN_ON(network_thread_);
if (!ports_.empty() || !pruned_ports_.empty()) {
RTC_LOG(LS_ERROR)
<< "Attempt to change tiebreaker after Port has been allocated.";
return;
}
tiebreaker_ = tiebreaker;
}
IceTransportState P2PTransportChannel::GetState() const {
RTC_DCHECK_RUN_ON(network_thread_);
return state_;
}
webrtc::IceTransportState P2PTransportChannel::GetIceTransportState() const {
RTC_DCHECK_RUN_ON(network_thread_);
return standardized_state_;
}
const std::string& P2PTransportChannel::transport_name() const {
RTC_DCHECK_RUN_ON(network_thread_);
return transport_name_;
}
int P2PTransportChannel::component() const {
RTC_DCHECK_RUN_ON(network_thread_);
return component_;
}
bool P2PTransportChannel::writable() const {
RTC_DCHECK_RUN_ON(network_thread_);
return writable_;
}
bool P2PTransportChannel::receiving() const {
RTC_DCHECK_RUN_ON(network_thread_);
return receiving_;
}
IceGatheringState P2PTransportChannel::gathering_state() const {
RTC_DCHECK_RUN_ON(network_thread_);
return gathering_state_;
}
absl::optional<int> P2PTransportChannel::GetRttEstimate() {
RTC_DCHECK_RUN_ON(network_thread_);
if (selected_connection_ != nullptr &&
selected_connection_->rtt_samples() > 0) {
return selected_connection_->rtt();
} else {
return absl::nullopt;
}
}
absl::optional<const CandidatePair>
P2PTransportChannel::GetSelectedCandidatePair() const {
RTC_DCHECK_RUN_ON(network_thread_);
if (selected_connection_ == nullptr) {
return absl::nullopt;
}
CandidatePair pair;
pair.local = SanitizeLocalCandidate(selected_connection_->local_candidate());
pair.remote =
SanitizeRemoteCandidate(selected_connection_->remote_candidate());
return pair;
}
// A channel is considered ICE completed once there is at most one active
// connection per network and at least one active connection.
IceTransportState P2PTransportChannel::ComputeState() const {
RTC_DCHECK_RUN_ON(network_thread_);
if (!had_connection_) {
return IceTransportState::STATE_INIT;
}
std::vector<Connection*> active_connections;
for (Connection* connection : connections()) {
if (connection->active()) {
active_connections.push_back(connection);
}
}
if (active_connections.empty()) {
return IceTransportState::STATE_FAILED;
}
std::set<const rtc::Network*> networks;
for (Connection* connection : active_connections) {
const rtc::Network* network = connection->network();
if (networks.find(network) == networks.end()) {
networks.insert(network);
} else {
RTC_LOG(LS_VERBOSE) << ToString()
<< ": Ice not completed yet for this channel as "
<< network->ToString()
<< " has more than 1 connection.";
return IceTransportState::STATE_CONNECTING;
}
}
ice_event_log_.DumpCandidatePairDescriptionToMemoryAsConfigEvents();
return IceTransportState::STATE_COMPLETED;
}
// Compute the current RTCIceTransportState as described in
// https://www.w3.org/TR/webrtc/#dom-rtcicetransportstate
// TODO(bugs.webrtc.org/9218): Start signaling kCompleted once we have
// implemented end-of-candidates signalling.
webrtc::IceTransportState P2PTransportChannel::ComputeIceTransportState()
const {
RTC_DCHECK_RUN_ON(network_thread_);
bool has_connection = false;
for (Connection* connection : connections()) {
if (connection->active()) {
has_connection = true;
break;
}
}
if (had_connection_ && !has_connection) {
return webrtc::IceTransportState::kFailed;
}
if (!writable() && has_been_writable_) {
return webrtc::IceTransportState::kDisconnected;
}
if (!had_connection_ && !has_connection) {
return webrtc::IceTransportState::kNew;
}
if (has_connection && !writable()) {
// A candidate pair has been formed by adding a remote candidate
// and gathering a local candidate.
return webrtc::IceTransportState::kChecking;
}
return webrtc::IceTransportState::kConnected;
}
void P2PTransportChannel::SetIceParameters(const IceParameters& ice_params) {
RTC_DCHECK_RUN_ON(network_thread_);
RTC_LOG(LS_INFO) << "Set ICE ufrag: " << ice_params.ufrag
<< " pwd: " << ice_params.pwd << " on transport "
<< transport_name();
ice_parameters_ = ice_params;
// Note: Candidate gathering will restart when MaybeStartGathering is next
// called.
}
void P2PTransportChannel::SetRemoteIceParameters(
const IceParameters& ice_params) {
RTC_DCHECK_RUN_ON(network_thread_);
RTC_LOG(LS_INFO) << "Received remote ICE parameters: ufrag="
<< ice_params.ufrag << ", renomination "
<< (ice_params.renomination ? "enabled" : "disabled");
IceParameters* current_ice = remote_ice();
if (!current_ice || *current_ice != ice_params) {
// Keep the ICE credentials so that newer connections
// are prioritized over the older ones.
remote_ice_parameters_.push_back(ice_params);
}
// Update the pwd of remote candidate if needed.
for (RemoteCandidate& candidate : remote_candidates_) {
if (candidate.username() == ice_params.ufrag &&
candidate.password().empty()) {
candidate.set_password(ice_params.pwd);
}
}
// We need to update the credentials and generation for any peer reflexive
// candidates.
for (Connection* conn : connections()) {
conn->MaybeSetRemoteIceParametersAndGeneration(
ice_params, static_cast<int>(remote_ice_parameters_.size() - 1));
}
// Updating the remote ICE candidate generation could change the sort order.
RequestSortAndStateUpdate(
IceControllerEvent::REMOTE_CANDIDATE_GENERATION_CHANGE);
}
void P2PTransportChannel::SetRemoteIceMode(IceMode mode) {
RTC_DCHECK_RUN_ON(network_thread_);
remote_ice_mode_ = mode;
}
// TODO(qingsi): We apply the convention that setting a absl::optional parameter
// to null restores its default value in the implementation. However, some
// absl::optional parameters are only processed below if non-null, e.g.,
// regather_on_failed_networks_interval, and thus there is no way to restore the
// defaults. Fix this issue later for consistency.
void P2PTransportChannel::SetIceConfig(const IceConfig& config) {
RTC_DCHECK_RUN_ON(network_thread_);
if (config_.continual_gathering_policy != config.continual_gathering_policy) {
if (!allocator_sessions_.empty()) {
RTC_LOG(LS_ERROR) << "Trying to change continual gathering policy "
"when gathering has already started!";
} else {
config_.continual_gathering_policy = config.continual_gathering_policy;
RTC_LOG(LS_INFO) << "Set continual_gathering_policy to "
<< config_.continual_gathering_policy;
}
}
if (config_.backup_connection_ping_interval !=
config.backup_connection_ping_interval) {
config_.backup_connection_ping_interval =
config.backup_connection_ping_interval;
RTC_LOG(LS_INFO) << "Set backup connection ping interval to "
<< config_.backup_connection_ping_interval_or_default()
<< " milliseconds.";
}
if (config_.receiving_timeout != config.receiving_timeout) {
config_.receiving_timeout = config.receiving_timeout;
for (Connection* connection : connections()) {
connection->set_receiving_timeout(config_.receiving_timeout);
}
RTC_LOG(LS_INFO) << "Set ICE receiving timeout to "
<< config_.receiving_timeout_or_default()
<< " milliseconds";
}
config_.prioritize_most_likely_candidate_pairs =
config.prioritize_most_likely_candidate_pairs;
RTC_LOG(LS_INFO) << "Set ping most likely connection to "
<< config_.prioritize_most_likely_candidate_pairs;
if (config_.stable_writable_connection_ping_interval !=
config.stable_writable_connection_ping_interval) {
config_.stable_writable_connection_ping_interval =
config.stable_writable_connection_ping_interval;
RTC_LOG(LS_INFO)
<< "Set stable_writable_connection_ping_interval to "
<< config_.stable_writable_connection_ping_interval_or_default();
}
if (config_.presume_writable_when_fully_relayed !=
config.presume_writable_when_fully_relayed) {
if (!connections().empty()) {
RTC_LOG(LS_ERROR) << "Trying to change 'presume writable' "
"while connections already exist!";
} else {
config_.presume_writable_when_fully_relayed =
config.presume_writable_when_fully_relayed;
RTC_LOG(LS_INFO) << "Set presume writable when fully relayed to "
<< config_.presume_writable_when_fully_relayed;
}
}
config_.surface_ice_candidates_on_ice_transport_type_changed =
config.surface_ice_candidates_on_ice_transport_type_changed;
if (config_.surface_ice_candidates_on_ice_transport_type_changed &&
config_.continual_gathering_policy != GATHER_CONTINUALLY) {
RTC_LOG(LS_WARNING)
<< "surface_ice_candidates_on_ice_transport_type_changed is "
"ineffective since we do not gather continually.";
}
if (config_.regather_on_failed_networks_interval !=
config.regather_on_failed_networks_interval) {
config_.regather_on_failed_networks_interval =
config.regather_on_failed_networks_interval;
RTC_LOG(LS_INFO)
<< "Set regather_on_failed_networks_interval to "
<< config_.regather_on_failed_networks_interval_or_default();
}
if (config_.regather_all_networks_interval_range !=
config.regather_all_networks_interval_range) {
// Config validation is assumed to have already happened at the API layer.
RTC_DCHECK(config.continual_gathering_policy != GATHER_ONCE);
config_.regather_all_networks_interval_range =
config.regather_all_networks_interval_range;
RTC_LOG(LS_INFO) << "Set regather_all_networks_interval_range to "
<< config.regather_all_networks_interval_range
.value_or(rtc::IntervalRange(-1, 0))
.ToString();
}
if (config_.receiving_switching_delay != config.receiving_switching_delay) {
config_.receiving_switching_delay = config.receiving_switching_delay;
RTC_LOG(LS_INFO) << "Set receiving_switching_delay to "
<< config_.receiving_switching_delay_or_default();
}
if (config_.default_nomination_mode != config.default_nomination_mode) {
config_.default_nomination_mode = config.default_nomination_mode;
RTC_LOG(LS_INFO) << "Set default nomination mode to "
<< static_cast<int>(config_.default_nomination_mode);
}
if (config_.ice_check_interval_strong_connectivity !=
config.ice_check_interval_strong_connectivity) {
config_.ice_check_interval_strong_connectivity =
config.ice_check_interval_strong_connectivity;
RTC_LOG(LS_INFO)
<< "Set strong ping interval to "
<< config_.ice_check_interval_strong_connectivity_or_default();
}
if (config_.ice_check_interval_weak_connectivity !=
config.ice_check_interval_weak_connectivity) {
config_.ice_check_interval_weak_connectivity =
config.ice_check_interval_weak_connectivity;
RTC_LOG(LS_INFO)
<< "Set weak ping interval to "
<< config_.ice_check_interval_weak_connectivity_or_default();
}
if (config_.ice_check_min_interval != config.ice_check_min_interval) {
config_.ice_check_min_interval = config.ice_check_min_interval;
RTC_LOG(LS_INFO) << "Set min ping interval to "
<< config_.ice_check_min_interval_or_default();
}
if (config_.ice_unwritable_timeout != config.ice_unwritable_timeout) {
config_.ice_unwritable_timeout = config.ice_unwritable_timeout;
for (Connection* conn : connections()) {
conn->set_unwritable_timeout(config_.ice_unwritable_timeout);
}
RTC_LOG(LS_INFO) << "Set unwritable timeout to "
<< config_.ice_unwritable_timeout_or_default();
}
if (config_.ice_unwritable_min_checks != config.ice_unwritable_min_checks) {
config_.ice_unwritable_min_checks = config.ice_unwritable_min_checks;
for (Connection* conn : connections()) {
conn->set_unwritable_min_checks(config_.ice_unwritable_min_checks);
}
RTC_LOG(LS_INFO) << "Set unwritable min checks to "
<< config_.ice_unwritable_min_checks_or_default();
}
if (config_.ice_inactive_timeout != config.ice_inactive_timeout) {
config_.ice_inactive_timeout = config.ice_inactive_timeout;
for (Connection* conn : connections()) {
conn->set_inactive_timeout(config_.ice_inactive_timeout);
}
RTC_LOG(LS_INFO) << "Set inactive timeout to "
<< config_.ice_inactive_timeout_or_default();
}
if (config_.network_preference != config.network_preference) {
config_.network_preference = config.network_preference;
RequestSortAndStateUpdate(IceControllerEvent::NETWORK_PREFERENCE_CHANGE);
RTC_LOG(LS_INFO) << "Set network preference to "
<< (config_.network_preference.has_value()
? config_.network_preference.value()
: -1); // network_preference cannot be bound to
// int with value_or.
}
// TODO(qingsi): Resolve the naming conflict of stun_keepalive_delay in
// UDPPort and stun_keepalive_interval.
if (config_.stun_keepalive_interval != config.stun_keepalive_interval) {
config_.stun_keepalive_interval = config.stun_keepalive_interval;
allocator_session()->SetStunKeepaliveIntervalForReadyPorts(
config_.stun_keepalive_interval);
RTC_LOG(LS_INFO) << "Set STUN keepalive interval to "
<< config.stun_keepalive_interval_or_default();
}
if (webrtc::field_trial::IsEnabled("WebRTC-ExtraICEPing")) {
RTC_LOG(LS_INFO) << "Set WebRTC-ExtraICEPing: Enabled";
}
if (webrtc::field_trial::IsEnabled("WebRTC-TurnAddMultiMapping")) {
RTC_LOG(LS_INFO) << "Set WebRTC-TurnAddMultiMapping: Enabled";
}
webrtc::StructParametersParser::Create(
// go/skylift-light
"skip_relay_to_non_relay_connections",
&field_trials_.skip_relay_to_non_relay_connections,
// Limiting pings sent.
"max_outstanding_pings", &field_trials_.max_outstanding_pings,
// Delay initial selection of connection.
"initial_select_dampening", &field_trials_.initial_select_dampening,
// Delay initial selection of connections, that are receiving.
"initial_select_dampening_ping_received",
&field_trials_.initial_select_dampening_ping_received,
// Reply that we support goog ping.
"announce_goog_ping", &field_trials_.announce_goog_ping,
// Use goog ping if remote support it.
"enable_goog_ping", &field_trials_.enable_goog_ping,
// How fast does a RTT sample decay.
"rtt_estimate_halftime_ms", &field_trials_.rtt_estimate_halftime_ms)
->Parse(webrtc::field_trial::FindFullName("WebRTC-IceFieldTrials"));
if (field_trials_.skip_relay_to_non_relay_connections) {
RTC_LOG(LS_INFO) << "Set skip_relay_to_non_relay_connections";
}
if (field_trials_.max_outstanding_pings.has_value()) {
RTC_LOG(LS_INFO) << "Set max_outstanding_pings: "
<< *field_trials_.max_outstanding_pings;
}
if (field_trials_.initial_select_dampening.has_value()) {
RTC_LOG(LS_INFO) << "Set initial_select_dampening: "
<< *field_trials_.initial_select_dampening;
}
if (field_trials_.initial_select_dampening_ping_received.has_value()) {
RTC_LOG(LS_INFO) << "Set initial_select_dampening_ping_received: "
<< *field_trials_.initial_select_dampening_ping_received;
}
webrtc::BasicRegatheringController::Config regathering_config(
config_.regather_all_networks_interval_range,
config_.regather_on_failed_networks_interval_or_default());
regathering_controller_->SetConfig(regathering_config);
ice_controller_->SetIceConfig(config_);
RTC_DCHECK(ValidateIceConfig(config_).ok());
}
const IceConfig& P2PTransportChannel::config() const {
RTC_DCHECK_RUN_ON(network_thread_);
return config_;
}
// TODO(qingsi): Add tests for the config validation starting from
// PeerConnection::SetConfiguration.
// Static
RTCError P2PTransportChannel::ValidateIceConfig(const IceConfig& config) {
if (config.regather_all_networks_interval_range &&
config.continual_gathering_policy == GATHER_ONCE) {
return RTCError(RTCErrorType::INVALID_PARAMETER,
"regather_all_networks_interval_range specified but "
"continual gathering policy is GATHER_ONCE");
}
if (config.ice_check_interval_strong_connectivity_or_default() <
config.ice_check_interval_weak_connectivity.value_or(
GetWeakPingIntervalInFieldTrial())) {
return RTCError(RTCErrorType::INVALID_PARAMETER,
"Ping interval of candidate pairs is shorter when ICE is "
"strongly connected than that when ICE is weakly "
"connected");
}
if (config.receiving_timeout_or_default() <
std::max(config.ice_check_interval_strong_connectivity_or_default(),
config.ice_check_min_interval_or_default())) {
return RTCError(
RTCErrorType::INVALID_PARAMETER,
"Receiving timeout is shorter than the minimal ping interval.");
}
if (config.backup_connection_ping_interval_or_default() <
config.ice_check_interval_strong_connectivity_or_default()) {
return RTCError(RTCErrorType::INVALID_PARAMETER,
"Ping interval of backup candidate pairs is shorter than "
"that of general candidate pairs when ICE is strongly "
"connected");
}
if (config.stable_writable_connection_ping_interval_or_default() <
config.ice_check_interval_strong_connectivity_or_default()) {
return RTCError(RTCErrorType::INVALID_PARAMETER,
"Ping interval of stable and writable candidate pairs is "
"shorter than that of general candidate pairs when ICE is "
"strongly connected");
}
if (config.ice_unwritable_timeout_or_default() >
config.ice_inactive_timeout_or_default()) {
return RTCError(RTCErrorType::INVALID_PARAMETER,
"The timeout period for the writability state to become "
"UNRELIABLE is longer than that to become TIMEOUT.");
}
if (config.regather_all_networks_interval_range &&
config.regather_all_networks_interval_range.value().min() < 0) {
return RTCError(
RTCErrorType::INVALID_RANGE,
"The minimum regathering interval for all networks is negative.");
}
return RTCError::OK();
}
const Connection* P2PTransportChannel::selected_connection() const {
RTC_DCHECK_RUN_ON(network_thread_);
return selected_connection_;
}
int P2PTransportChannel::check_receiving_interval() const {
RTC_DCHECK_RUN_ON(network_thread_);
return std::max(MIN_CHECK_RECEIVING_INTERVAL,
config_.receiving_timeout_or_default() / 10);
}
void P2PTransportChannel::MaybeStartGathering() {
RTC_DCHECK_RUN_ON(network_thread_);
if (ice_parameters_.ufrag.empty() || ice_parameters_.pwd.empty()) {
RTC_LOG(LS_ERROR)
<< "Cannot gather candidates because ICE parameters are empty"
" ufrag: "
<< ice_parameters_.ufrag << " pwd: " << ice_parameters_.pwd;
return;
}
// Start gathering if we never started before, or if an ICE restart occurred.
if (allocator_sessions_.empty() ||
IceCredentialsChanged(allocator_sessions_.back()->ice_ufrag(),
allocator_sessions_.back()->ice_pwd(),
ice_parameters_.ufrag, ice_parameters_.pwd)) {
if (gathering_state_ != kIceGatheringGathering) {
gathering_state_ = kIceGatheringGathering;
SignalGatheringState(this);
}
if (!allocator_sessions_.empty()) {
IceRestartState state;
if (writable()) {
state = IceRestartState::CONNECTED;
} else if (IsGettingPorts()) {
state = IceRestartState::CONNECTING;
} else {
state = IceRestartState::DISCONNECTED;
}
RTC_HISTOGRAM_ENUMERATION("WebRTC.PeerConnection.IceRestartState",
static_cast<int>(state),
static_cast<int>(IceRestartState::MAX_VALUE));
}
// Time for a new allocator.
std::unique_ptr<PortAllocatorSession> pooled_session =
allocator_->TakePooledSession(transport_name(), component(),
ice_parameters_.ufrag,
ice_parameters_.pwd);
if (pooled_session) {
AddAllocatorSession(std::move(pooled_session));
PortAllocatorSession* raw_pooled_session =
allocator_sessions_.back().get();
// Process the pooled session's existing candidates/ports, if they exist.
OnCandidatesReady(raw_pooled_session,
raw_pooled_session->ReadyCandidates());
for (PortInterface* port : allocator_sessions_.back()->ReadyPorts()) {
OnPortReady(raw_pooled_session, port);
}
if (allocator_sessions_.back()->CandidatesAllocationDone()) {
OnCandidatesAllocationDone(raw_pooled_session);
}
} else {
AddAllocatorSession(allocator_->CreateSession(
transport_name(), component(), ice_parameters_.ufrag,
ice_parameters_.pwd));
allocator_sessions_.back()->StartGettingPorts();
}
}
}
// A new port is available, attempt to make connections for it
void P2PTransportChannel::OnPortReady(PortAllocatorSession* session,
PortInterface* port) {
RTC_DCHECK_RUN_ON(network_thread_);
// Set in-effect options on the new port
for (OptionMap::const_iterator it = options_.begin(); it != options_.end();
++it) {
int val = port->SetOption(it->first, it->second);
if (val < 0) {
// Errors are frequent, so use LS_INFO. bugs.webrtc.org/9221
RTC_LOG(LS_INFO) << port->ToString() << ": SetOption(" << it->first
<< ", " << it->second
<< ") failed: " << port->GetError();
}
}
// Remember the ports and candidates, and signal that candidates are ready.
// The session will handle this, and send an initiate/accept/modify message
// if one is pending.
port->SetIceRole(ice_role_);
port->SetIceTiebreaker(tiebreaker_);
ports_.push_back(port);
port->SignalUnknownAddress.connect(this,
&P2PTransportChannel::OnUnknownAddress);
port->SignalDestroyed.connect(this, &P2PTransportChannel::OnPortDestroyed);
port->SignalRoleConflict.connect(this, &P2PTransportChannel::OnRoleConflict);
port->SignalSentPacket.connect(this, &P2PTransportChannel::OnSentPacket);
// Attempt to create a connection from this new port to all of the remote
// candidates that we were given so far.
std::vector<RemoteCandidate>::iterator iter;
for (iter = remote_candidates_.begin(); iter != remote_candidates_.end();
++iter) {
CreateConnection(port, *iter, iter->origin_port());
}
SortConnectionsAndUpdateState(
IceControllerEvent::NEW_CONNECTION_FROM_LOCAL_CANDIDATE);
}
// A new candidate is available, let listeners know
void P2PTransportChannel::OnCandidatesReady(
PortAllocatorSession* session,
const std::vector<Candidate>& candidates) {
RTC_DCHECK_RUN_ON(network_thread_);
for (size_t i = 0; i < candidates.size(); ++i) {
SignalCandidateGathered(this, candidates[i]);
}
}
void P2PTransportChannel::OnCandidateError(
PortAllocatorSession* session,
const IceCandidateErrorEvent& event) {
RTC_DCHECK(network_thread_ == rtc::Thread::Current());
SignalCandidateError(this, event);
}
void P2PTransportChannel::OnCandidatesAllocationDone(
PortAllocatorSession* session) {
RTC_DCHECK_RUN_ON(network_thread_);
if (config_.gather_continually()) {
RTC_LOG(LS_INFO) << "P2PTransportChannel: " << transport_name()
<< ", component " << component()
<< " gathering complete, but using continual "
"gathering so not changing gathering state.";
return;
}
gathering_state_ = kIceGatheringComplete;
RTC_LOG(LS_INFO) << "P2PTransportChannel: " << transport_name()
<< ", component " << component() << " gathering complete";
SignalGatheringState(this);
}
// Handle stun packets
void P2PTransportChannel::OnUnknownAddress(PortInterface* port,
const rtc::SocketAddress& address,
ProtocolType proto,
IceMessage* stun_msg,
const std::string& remote_username,
bool port_muxed) {
RTC_DCHECK_RUN_ON(network_thread_);
// Port has received a valid stun packet from an address that no Connection
// is currently available for. See if we already have a candidate with the
// address. If it isn't we need to create new candidate for it.
//
// TODO(qingsi): There is a caveat of the logic below if we have remote
// candidates with hostnames. We could create a prflx candidate that is
// identical to a host candidate that are currently in the process of name
// resolution. We would not have a duplicate candidate since when adding the
// resolved host candidate, FinishingAddingRemoteCandidate does
// MaybeUpdatePeerReflexiveCandidate, and the prflx candidate would be updated
// to a host candidate. As a result, for a brief moment we would have a prflx
// candidate showing a private IP address, though we do not signal prflx
// candidates to applications and we could obfuscate the IP addresses of prflx
// candidates in P2PTransportChannel::GetStats. The difficulty of preventing
// creating the prflx from the beginning is that we do not have a reliable way
// to claim two candidates are identical without the address information. If
// we always pause the addition of a prflx candidate when there is ongoing
// name resolution and dedup after we have a resolved address, we run into the
// risk of losing/delaying the addition of a non-identical candidate that
// could be the only way to have a connection, if the resolution never
// completes or is significantly delayed.
const Candidate* candidate = nullptr;
for (const Candidate& c : remote_candidates_) {
if (c.username() == remote_username && c.address() == address &&
c.protocol() == ProtoToString(proto)) {
candidate = &c;
break;
}
}
uint32_t remote_generation = 0;
std::string remote_password;
// The STUN binding request may arrive after setRemoteDescription and before
// adding remote candidate, so we need to set the password to the shared
// password and set the generation if the user name matches.
const IceParameters* ice_param =
FindRemoteIceFromUfrag(remote_username, &remote_generation);
// Note: if not found, the remote_generation will still be 0.
if (ice_param != nullptr) {
remote_password = ice_param->pwd;
}
Candidate remote_candidate;
bool remote_candidate_is_new = (candidate == nullptr);
if (!remote_candidate_is_new) {
remote_candidate = *candidate;
} else {
// Create a new candidate with this address.
// The priority of the candidate is set to the PRIORITY attribute
// from the request.
const StunUInt32Attribute* priority_attr =
stun_msg->GetUInt32(STUN_ATTR_PRIORITY);
if (!priority_attr) {
RTC_LOG(LS_WARNING) << "P2PTransportChannel::OnUnknownAddress - "
"No STUN_ATTR_PRIORITY found in the "
"stun request message";
port->SendBindingErrorResponse(stun_msg, address, STUN_ERROR_BAD_REQUEST,
STUN_ERROR_REASON_BAD_REQUEST);
return;
}
int remote_candidate_priority = priority_attr->value();
uint16_t network_id = 0;
uint16_t network_cost = 0;
const StunUInt32Attribute* network_attr =
stun_msg->GetUInt32(STUN_ATTR_NETWORK_INFO);
if (network_attr) {
uint32_t network_info = network_attr->value();
network_id = static_cast<uint16_t>(network_info >> 16);
network_cost = static_cast<uint16_t>(network_info);
}
// RFC 5245
// If the source transport address of the request does not match any
// existing remote candidates, it represents a new peer reflexive remote
// candidate.
remote_candidate = Candidate(
component(), ProtoToString(proto), address, remote_candidate_priority,
remote_username, remote_password, PRFLX_PORT_TYPE, remote_generation,
"", network_id, network_cost);
// From RFC 5245, section-7.2.1.3:
// The foundation of the candidate is set to an arbitrary value, different
// from the foundation for all other remote candidates.
remote_candidate.set_foundation(
rtc::ToString(rtc::ComputeCrc32(remote_candidate.id())));
}
// RFC5245, the agent constructs a pair whose local candidate is equal to
// the transport address on which the STUN request was received, and a
// remote candidate equal to the source transport address where the
// request came from.
// There shouldn't be an existing connection with this remote address.
// When ports are muxed, this channel might get multiple unknown address
// signals. In that case if the connection is already exists, we should
// simply ignore the signal otherwise send server error.
if (port->GetConnection(remote_candidate.address())) {
if (port_muxed) {
RTC_LOG(LS_INFO) << "Connection already exists for peer reflexive "
"candidate: "
<< remote_candidate.ToSensitiveString();
return;
} else {
RTC_NOTREACHED();
port->SendBindingErrorResponse(stun_msg, address, STUN_ERROR_SERVER_ERROR,
STUN_ERROR_REASON_SERVER_ERROR);
return;
}
}
Connection* connection =
port->CreateConnection(remote_candidate, PortInterface::ORIGIN_THIS_PORT);
if (!connection) {
// This could happen in some scenarios. For example, a TurnPort may have
// had a refresh request timeout, so it won't create connections.
port->SendBindingErrorResponse(stun_msg, address, STUN_ERROR_SERVER_ERROR,
STUN_ERROR_REASON_SERVER_ERROR);
return;
}
RTC_LOG(LS_INFO) << "Adding connection from "
<< (remote_candidate_is_new ? "peer reflexive"
: "resurrected")
<< " candidate: " << remote_candidate.ToSensitiveString();
AddConnection(connection);
connection->HandleStunBindingOrGoogPingRequest(stun_msg);
// Update the list of connections since we just added another. We do this
// after sending the response since it could (in principle) delete the
// connection in question.
SortConnectionsAndUpdateState(
IceControllerEvent::NEW_CONNECTION_FROM_UNKNOWN_REMOTE_ADDRESS);
}
void P2PTransportChannel::OnCandidateFilterChanged(uint32_t prev_filter,
uint32_t cur_filter) {
RTC_DCHECK_RUN_ON(network_thread_);
if (prev_filter == cur_filter || allocator_session() == nullptr) {
return;
}
if (config_.surface_ice_candidates_on_ice_transport_type_changed) {
allocator_session()->SetCandidateFilter(cur_filter);
}
}
void P2PTransportChannel::OnRoleConflict(PortInterface* port) {
SignalRoleConflict(this); // STUN ping will be sent when SetRole is called
// from Transport.
}
const IceParameters* P2PTransportChannel::FindRemoteIceFromUfrag(
const std::string& ufrag,
uint32_t* generation) {
RTC_DCHECK_RUN_ON(network_thread_);
const auto& params = remote_ice_parameters_;
auto it = std::find_if(
params.rbegin(), params.rend(),
[ufrag](const IceParameters& param) { return param.ufrag == ufrag; });
if (it == params.rend()) {
// Not found.
return nullptr;
}
*generation = params.rend() - it - 1;
return &(*it);
}
void P2PTransportChannel::OnNominated(Connection* conn) {
RTC_DCHECK_RUN_ON(network_thread_);
RTC_DCHECK(ice_role_ == ICEROLE_CONTROLLED);
if (selected_connection_ == conn) {
return;
}
// TODO(qingsi): RequestSortAndStateUpdate will eventually call
// MaybeSwitchSelectedConnection again. Rewrite this logic.
if (MaybeSwitchSelectedConnection(
conn, IceControllerEvent::NOMINATION_ON_CONTROLLED_SIDE)) {
// Now that we have selected a connection, it is time to prune other
// connections and update the read/write state of the channel.
RequestSortAndStateUpdate(
IceControllerEvent::NOMINATION_ON_CONTROLLED_SIDE);
} else {
RTC_LOG(LS_INFO)
<< "Not switching the selected connection on controlled side yet: "
<< conn->ToString();
}
}
void P2PTransportChannel::ResolveHostnameCandidate(const Candidate& candidate) {
RTC_DCHECK_RUN_ON(network_thread_);
if (!async_resolver_factory_) {
RTC_LOG(LS_WARNING) << "Dropping ICE candidate with hostname address "
"(no AsyncResolverFactory)";
return;
}
rtc::AsyncResolverInterface* resolver = async_resolver_factory_->Create();
resolvers_.emplace_back(candidate, resolver);
resolver->SignalDone.connect(this, &P2PTransportChannel::OnCandidateResolved);
resolver->Start(candidate.address());
RTC_LOG(LS_INFO) << "Asynchronously resolving ICE candidate hostname "
<< candidate.address().HostAsSensitiveURIString();
}
void P2PTransportChannel::AddRemoteCandidate(const Candidate& candidate) {
RTC_DCHECK_RUN_ON(network_thread_);
uint32_t generation = GetRemoteCandidateGeneration(candidate);
// If a remote candidate with a previous generation arrives, drop it.
if (generation < remote_ice_generation()) {
RTC_LOG(LS_WARNING) << "Dropping a remote candidate because its ufrag "
<< candidate.username()
<< " indicates it was for a previous generation.";
return;
}
Candidate new_remote_candidate(candidate);
new_remote_candidate.set_generation(generation);
// ICE candidates don't need to have username and password set, but
// the code below this (specifically, ConnectionRequest::Prepare in
// port.cc) uses the remote candidates's username. So, we set it
// here.
if (remote_ice()) {
if (candidate.username().empty()) {
new_remote_candidate.set_username(remote_ice()->ufrag);
}
if (new_remote_candidate.username() == remote_ice()->ufrag) {
if (candidate.password().empty()) {
new_remote_candidate.set_password(remote_ice()->pwd);
}
} else {
// The candidate belongs to the next generation. Its pwd will be set
// when the new remote ICE credentials arrive.
RTC_LOG(LS_WARNING)
<< "A remote candidate arrives with an unknown ufrag: "
<< candidate.username();
}
}
if (new_remote_candidate.address().IsUnresolvedIP()) {
ResolveHostnameCandidate(new_remote_candidate);
return;
}
FinishAddingRemoteCandidate(new_remote_candidate);
}
P2PTransportChannel::CandidateAndResolver::CandidateAndResolver(
const Candidate& candidate,
rtc::AsyncResolverInterface* resolver)
: candidate_(candidate), resolver_(resolver) {}
P2PTransportChannel::CandidateAndResolver::~CandidateAndResolver() {}
void P2PTransportChannel::OnCandidateResolved(
rtc::AsyncResolverInterface* resolver) {
RTC_DCHECK_RUN_ON(network_thread_);
auto p =
absl::c_find_if(resolvers_, [resolver](const CandidateAndResolver& cr) {
return cr.resolver_ == resolver;
});
if (p == resolvers_.end()) {
RTC_LOG(LS_ERROR) << "Unexpected AsyncResolver signal";
RTC_NOTREACHED();
return;
}
Candidate candidate = p->candidate_;
resolvers_.erase(p);
AddRemoteCandidateWithResolver(candidate, resolver);
invoker_.AsyncInvoke<void>(
RTC_FROM_HERE, thread(),
rtc::Bind(&rtc::AsyncResolverInterface::Destroy, resolver, false));
}
void P2PTransportChannel::AddRemoteCandidateWithResolver(
Candidate candidate,
rtc::AsyncResolverInterface* resolver) {
RTC_DCHECK_RUN_ON(network_thread_);
if (resolver->GetError()) {
RTC_LOG(LS_WARNING) << "Failed to resolve ICE candidate hostname "
<< candidate.address().HostAsSensitiveURIString()
<< " with error " << resolver->GetError();
return;
}
rtc::SocketAddress resolved_address;
// Prefer IPv6 to IPv4 if we have it (see RFC 5245 Section 15.1).
// TODO(zstein): This won't work if we only have IPv4 locally but receive an
// AAAA DNS record.
bool have_address =
resolver->GetResolvedAddress(AF_INET6, &resolved_address) ||
resolver->GetResolvedAddress(AF_INET, &resolved_address);
if (!have_address) {
RTC_LOG(LS_INFO) << "ICE candidate hostname "
<< candidate.address().HostAsSensitiveURIString()
<< " could not be resolved";
return;
}
RTC_LOG(LS_INFO) << "Resolved ICE candidate hostname "
<< candidate.address().HostAsSensitiveURIString() << " to "
<< resolved_address.ipaddr().ToSensitiveString();
candidate.set_address(resolved_address);
FinishAddingRemoteCandidate(candidate);
}
void P2PTransportChannel::FinishAddingRemoteCandidate(
const Candidate& new_remote_candidate) {
RTC_DCHECK_RUN_ON(network_thread_);
// If this candidate matches what was thought to be a peer reflexive
// candidate, we need to update the candidate priority/etc.
for (Connection* conn : connections()) {
conn->MaybeUpdatePeerReflexiveCandidate(new_remote_candidate);
}
// Create connections to this remote candidate.
CreateConnections(new_remote_candidate, NULL);
// Resort the connections list, which may have new elements.
SortConnectionsAndUpdateState(
IceControllerEvent::NEW_CONNECTION_FROM_REMOTE_CANDIDATE);
}
void P2PTransportChannel::RemoveRemoteCandidate(
const Candidate& cand_to_remove) {
RTC_DCHECK_RUN_ON(network_thread_);
auto iter =
std::remove_if(remote_candidates_.begin(), remote_candidates_.end(),
[cand_to_remove](const Candidate& candidate) {
return cand_to_remove.MatchesForRemoval(candidate);
});
if (iter != remote_candidates_.end()) {
RTC_LOG(LS_VERBOSE) << "Removed remote candidate "
<< cand_to_remove.ToSensitiveString();
remote_candidates_.erase(iter, remote_candidates_.end());
}
}
void P2PTransportChannel::RemoveAllRemoteCandidates() {
RTC_DCHECK_RUN_ON(network_thread_);
remote_candidates_.clear();
}
// Creates connections from all of the ports that we care about to the given
// remote candidate. The return value is true if we created a connection from
// the origin port.
bool P2PTransportChannel::CreateConnections(const Candidate& remote_candidate,
PortInterface* origin_port) {
RTC_DCHECK_RUN_ON(network_thread_);
// If we've already seen the new remote candidate (in the current candidate
// generation), then we shouldn't try creating connections for it.
// We either already have a connection for it, or we previously created one
// and then later pruned it. If we don't return, the channel will again
// re-create any connections that were previously pruned, which will then
// immediately be re-pruned, churning the network for no purpose.
// This only applies to candidates received over signaling (i.e. origin_port
// is NULL).
if (!origin_port && IsDuplicateRemoteCandidate(remote_candidate)) {
// return true to indicate success, without creating any new connections.
return true;
}
// Add a new connection for this candidate to every port that allows such a
// connection (i.e., if they have compatible protocols) and that does not
// already have a connection to an equivalent candidate. We must be careful
// to make sure that the origin port is included, even if it was pruned,
// since that may be the only port that can create this connection.
bool created = false;
std::vector<PortInterface*>::reverse_iterator it;
for (it = ports_.rbegin(); it != ports_.rend(); ++it) {
if (CreateConnection(*it, remote_candidate, origin_port)) {
if (*it == origin_port)
created = true;
}
}
if ((origin_port != NULL) && !absl::c_linear_search(ports_, origin_port)) {
if (CreateConnection(origin_port, remote_candidate, origin_port))
created = true;
}
// Remember this remote candidate so that we can add it to future ports.
RememberRemoteCandidate(remote_candidate, origin_port);
return created;
}
// Setup a connection object for the local and remote candidate combination.
// And then listen to connection object for changes.
bool P2PTransportChannel::CreateConnection(PortInterface* port,
const Candidate& remote_candidate,
PortInterface* origin_port) {
RTC_DCHECK_RUN_ON(network_thread_);
if (!port->SupportsProtocol(remote_candidate.protocol())) {
return false;
}
if (field_trials_.skip_relay_to_non_relay_connections) {
if ((port->Type() != remote_candidate.type()) &&
(port->Type() == RELAY_PORT_TYPE ||
remote_candidate.type() == RELAY_PORT_TYPE)) {
RTC_LOG(LS_INFO) << ToString() << ": skip creating connection "
<< port->Type() << " to " << remote_candidate.type();
return false;
}
}
// Look for an existing connection with this remote address. If one is not
// found or it is found but the existing remote candidate has an older
// generation, then we can create a new connection for this address.
Connection* connection = port->GetConnection(remote_candidate.address());
if (connection == nullptr || connection->remote_candidate().generation() <
remote_candidate.generation()) {
// Don't create a connection if this is a candidate we received in a
// message and we are not allowed to make outgoing connections.
PortInterface::CandidateOrigin origin = GetOrigin(port, origin_port);
if (origin == PortInterface::ORIGIN_MESSAGE && incoming_only_) {
return false;
}
Connection* connection = port->CreateConnection(remote_candidate, origin);
if (!connection) {
return false;
}
AddConnection(connection);
RTC_LOG(LS_INFO) << ToString()
<< ": Created connection with origin: " << origin
<< ", total: " << connections().size();
return true;
}
// No new connection was created.
// It is not legal to try to change any of the parameters of an existing
// connection; however, the other side can send a duplicate candidate.
if (!remote_candidate.IsEquivalent(connection->remote_candidate())) {
RTC_LOG(INFO) << "Attempt to change a remote candidate."
" Existing remote candidate: "
<< connection->remote_candidate().ToSensitiveString()
<< "New remote candidate: "
<< remote_candidate.ToSensitiveString();
}
return false;
}
bool P2PTransportChannel::FindConnection(Connection* connection) const {
RTC_DCHECK_RUN_ON(network_thread_);
return absl::c_linear_search(connections(), connection);
}
uint32_t P2PTransportChannel::GetRemoteCandidateGeneration(
const Candidate& candidate) {
RTC_DCHECK_RUN_ON(network_thread_);
// If the candidate has a ufrag, use it to find the generation.
if (!candidate.username().empty()) {
uint32_t generation = 0;
if (!FindRemoteIceFromUfrag(candidate.username(), &generation)) {
// If the ufrag is not found, assume the next/future generation.
generation = static_cast<uint32_t>(remote_ice_parameters_.size());
}
return generation;
}
// If candidate generation is set, use that.
if (candidate.generation() > 0) {
return candidate.generation();
}
// Otherwise, assume the generation from remote ice parameters.
return remote_ice_generation();
}
// Check if remote candidate is already cached.
bool P2PTransportChannel::IsDuplicateRemoteCandidate(
const Candidate& candidate) {
RTC_DCHECK_RUN_ON(network_thread_);
for (size_t i = 0; i < remote_candidates_.size(); ++i) {
if (remote_candidates_[i].IsEquivalent(candidate)) {
return true;
}
}
return false;
}
// Maintain our remote candidate list, adding this new remote one.
void P2PTransportChannel::RememberRemoteCandidate(
const Candidate& remote_candidate,
PortInterface* origin_port) {
RTC_DCHECK_RUN_ON(network_thread_);
// Remove any candidates whose generation is older than this one. The
// presence of a new generation indicates that the old ones are not useful.
size_t i = 0;
while (i < remote_candidates_.size()) {
if (remote_candidates_[i].generation() < remote_candidate.generation()) {
RTC_LOG(INFO) << "Pruning candidate from old generation: "
<< remote_candidates_[i].address().ToSensitiveString();
remote_candidates_.erase(remote_candidates_.begin() + i);
} else {
i += 1;
}
}
// Make sure this candidate is not a duplicate.
if (IsDuplicateRemoteCandidate(remote_candidate)) {
RTC_LOG(INFO) << "Duplicate candidate: "
<< remote_candidate.ToSensitiveString();
return;
}
// Try this candidate for all future ports.
remote_candidates_.push_back(RemoteCandidate(remote_candidate, origin_port));
}
// Set options on ourselves is simply setting options on all of our available
// port objects.
int P2PTransportChannel::SetOption(rtc::Socket::Option opt, int value) {
RTC_DCHECK_RUN_ON(network_thread_);
OptionMap::iterator it = options_.find(opt);
if (it == options_.end()) {
options_.insert(std::make_pair(opt, value));
} else if (it->second == value) {
return 0;
} else {
it->second = value;
}
for (PortInterface* port : ports_) {
int val = port->SetOption(opt, value);
if (val < 0) {
// Because this also occurs deferred, probably no point in reporting an
// error
RTC_LOG(WARNING) << "SetOption(" << opt << ", " << value
<< ") failed: " << port->GetError();
}
}
return 0;
}
bool P2PTransportChannel::GetOption(rtc::Socket::Option opt, int* value) {
RTC_DCHECK_RUN_ON(network_thread_);
const auto& found = options_.find(opt);
if (found == options_.end()) {
return false;
}
*value = found->second;
return true;
}
int P2PTransportChannel::GetError() {
RTC_DCHECK_RUN_ON(network_thread_);
return error_;
}
// Send data to the other side, using our selected connection.
int P2PTransportChannel::SendPacket(const char* data,
size_t len,
const rtc::PacketOptions& options,
int flags) {
RTC_DCHECK_RUN_ON(network_thread_);
if (flags != 0) {
error_ = EINVAL;
return -1;
}
// If we don't think the connection is working yet, return ENOTCONN
// instead of sending a packet that will probably be dropped.
if (!ReadyToSend(selected_connection_)) {
error_ = ENOTCONN;
return -1;
}
last_sent_packet_id_ = options.packet_id;
rtc::PacketOptions modified_options(options);
modified_options.info_signaled_after_sent.packet_type =
rtc::PacketType::kData;
int sent = selected_connection_->Send(data, len, modified_options);
if (sent <= 0) {
RTC_DCHECK(sent < 0);
error_ = selected_connection_->GetError();
}
return sent;
}
bool P2PTransportChannel::GetStats(IceTransportStats* ice_transport_stats) {
RTC_DCHECK_RUN_ON(network_thread_);
// Gather candidate and candidate pair stats.
ice_transport_stats->candidate_stats_list.clear();
ice_transport_stats->connection_infos.clear();
if (!allocator_sessions_.empty()) {
allocator_session()->GetCandidateStatsFromReadyPorts(
&ice_transport_stats->candidate_stats_list);
}
// TODO(qingsi): Remove naming inconsistency for candidate pair/connection.
for (Connection* connection : connections()) {
ConnectionInfo stats = connection->stats();
stats.local_candidate = SanitizeLocalCandidate(stats.local_candidate);
stats.remote_candidate = SanitizeRemoteCandidate(stats.remote_candidate);
stats.best_connection = (selected_connection_ == connection);
ice_transport_stats->connection_infos.push_back(std::move(stats));
connection->set_reported(true);
}
ice_transport_stats->selected_candidate_pair_changes =
selected_candidate_pair_changes_;
return true;
}
absl::optional<rtc::NetworkRoute> P2PTransportChannel::network_route() const {
RTC_DCHECK_RUN_ON(network_thread_);
return network_route_;
}
rtc::DiffServCodePoint P2PTransportChannel::DefaultDscpValue() const {
RTC_DCHECK_RUN_ON(network_thread_);
OptionMap::const_iterator it = options_.find(rtc::Socket::OPT_DSCP);
if (it == options_.end()) {
return rtc::DSCP_NO_CHANGE;
}
return static_cast<rtc::DiffServCodePoint>(it->second);
}
rtc::ArrayView<Connection*> P2PTransportChannel::connections() const {
RTC_DCHECK_RUN_ON(network_thread_);
rtc::ArrayView<const Connection*> res = ice_controller_->connections();
return rtc::ArrayView<Connection*>(const_cast<Connection**>(res.data()),
res.size());
}
// Monitor connection states.
void P2PTransportChannel::UpdateConnectionStates() {
RTC_DCHECK_RUN_ON(network_thread_);
int64_t now = rtc::TimeMillis();
// We need to copy the list of connections since some may delete themselves
// when we call UpdateState.
for (Connection* c : connections()) {
c->UpdateState(now);
}
}
// Prepare for best candidate sorting.
void P2PTransportChannel::RequestSortAndStateUpdate(
IceControllerEvent reason_to_sort) {
RTC_DCHECK_RUN_ON(network_thread_);
if (!sort_dirty_) {
invoker_.AsyncInvoke<void>(
RTC_FROM_HERE, thread(),
rtc::Bind(&P2PTransportChannel::SortConnectionsAndUpdateState, this,
reason_to_sort));
sort_dirty_ = true;
}
}
void P2PTransportChannel::MaybeStartPinging() {
RTC_DCHECK_RUN_ON(network_thread_);
if (started_pinging_) {
return;
}
if (ice_controller_->HasPingableConnection()) {
RTC_LOG(LS_INFO) << ToString()
<< ": Have a pingable connection for the first time; "
"starting to ping.";
invoker_.AsyncInvoke<void>(
RTC_FROM_HERE, thread(),
rtc::Bind(&P2PTransportChannel::CheckAndPing, this));
regathering_controller_->Start();
started_pinging_ = true;
}
}
bool P2PTransportChannel::IsPortPruned(const Port* port) const {
RTC_DCHECK_RUN_ON(network_thread_);
return !absl::c_linear_search(ports_, port);
}
bool P2PTransportChannel::IsRemoteCandidatePruned(const Candidate& cand) const {
RTC_DCHECK_RUN_ON(network_thread_);
return !absl::c_linear_search(remote_candidates_, cand);
}
bool P2PTransportChannel::PresumedWritable(const Connection* conn) const {
RTC_DCHECK_RUN_ON(network_thread_);
return (conn->write_state() == Connection::STATE_WRITE_INIT &&
config_.presume_writable_when_fully_relayed &&
conn->local_candidate().type() == RELAY_PORT_TYPE &&
(conn->remote_candidate().type() == RELAY_PORT_TYPE ||
conn->remote_candidate().type() == PRFLX_PORT_TYPE));
}
// Sort the available connections to find the best one. We also monitor
// the number of available connections and the current state.
void P2PTransportChannel::SortConnectionsAndUpdateState(
IceControllerEvent reason_to_sort) {
RTC_DCHECK_RUN_ON(network_thread_);
// Make sure the connection states are up-to-date since this affects how they
// will be sorted.
UpdateConnectionStates();
// Any changes after this point will require a re-sort.
sort_dirty_ = false;
// If necessary, switch to the new choice. Note that |top_connection| doesn't
// have to be writable to become the selected connection although it will
// have higher priority if it is writable.
MaybeSwitchSelectedConnection(
reason_to_sort, ice_controller_->SortAndSwitchConnection(reason_to_sort));
// The controlled side can prune only if the selected connection has been
// nominated because otherwise it may prune the connection that will be
// selected by the controlling side.
// TODO(honghaiz): This is not enough to prevent a connection from being
// pruned too early because with aggressive nomination, the controlling side
// will nominate every connection until it becomes writable.
if (ice_role_ == ICEROLE_CONTROLLING ||
(selected_connection_ && selected_connection_->nominated())) {
PruneConnections();
}
// Check if all connections are timedout.
bool all_connections_timedout = true;
for (const Connection* conn : connections()) {
if (conn->write_state() != Connection::STATE_WRITE_TIMEOUT) {
all_connections_timedout = false;
break;
}
}
// Now update the writable state of the channel with the information we have
// so far.
if (all_connections_timedout) {
HandleAllTimedOut();
}
// Update the state of this channel.
UpdateState();
// Also possibly start pinging.
// We could start pinging if:
// * The first connection was created.
// * ICE credentials were provided.
// * A TCP connection became connected.
MaybeStartPinging();
}
void P2PTransportChannel::PruneConnections() {
RTC_DCHECK_RUN_ON(network_thread_);
std::vector<const Connection*> connections_to_prune =
ice_controller_->PruneConnections();
for (const Connection* conn : connections_to_prune) {
const_cast<Connection*>(conn)->Prune();
}
}
// Change the selected connection, and let listeners know.
void P2PTransportChannel::SwitchSelectedConnection(Connection* conn,
IceControllerEvent reason) {
RTC_DCHECK_RUN_ON(network_thread_);
// Note: if conn is NULL, the previous |selected_connection_| has been
// destroyed, so don't use it.
Connection* old_selected_connection = selected_connection_;
selected_connection_ = conn;
LogCandidatePairConfig(conn, webrtc::IceCandidatePairConfigType::kSelected);
network_route_.reset();
if (old_selected_connection) {
old_selected_connection->set_selected(false);
}
if (selected_connection_) {
++nomination_;
selected_connection_->set_selected(true);
if (old_selected_connection) {
RTC_LOG(LS_INFO) << ToString() << ": Previous selected connection: "
<< old_selected_connection->ToString();
}
RTC_LOG(LS_INFO) << ToString() << ": New selected connection: "
<< selected_connection_->ToString();
SignalRouteChange(this, selected_connection_->remote_candidate());
// This is a temporary, but safe fix to webrtc issue 5705.
// TODO(honghaiz): Make all ENOTCONN error routed through the transport
// channel so that it knows whether the media channel is allowed to
// send; then it will only signal ready-to-send if the media channel
// has been disallowed to send.
if (selected_connection_->writable() ||
PresumedWritable(selected_connection_)) {
SignalReadyToSend(this);
}
network_route_.emplace(rtc::NetworkRoute());
network_route_->connected = ReadyToSend(selected_connection_);
network_route_->local_network_id =
selected_connection_->local_candidate().network_id();
network_route_->remote_network_id =
selected_connection_->remote_candidate().network_id();
network_route_->last_sent_packet_id = last_sent_packet_id_;
network_route_->packet_overhead =
GetIpOverhead(
selected_connection_->local_candidate().address().family()) +
GetProtocolOverhead(selected_connection_->local_candidate().protocol());
} else {
RTC_LOG(LS_INFO) << ToString() << ": No selected connection";
}
SignalNetworkRouteChanged(network_route_);
// Create event for candidate pair change.
if (selected_connection_) {
CandidatePairChangeEvent pair_change;
pair_change.reason = reason.ToString();
pair_change.selected_candidate_pair = *GetSelectedCandidatePair();
pair_change.last_data_received_ms =
selected_connection_->last_data_received();
SignalCandidatePairChanged(pair_change);
}
++selected_candidate_pair_changes_;
ice_controller_->SetSelectedConnection(selected_connection_);
}
// Warning: UpdateState should eventually be called whenever a connection
// is added, deleted, or the write state of any connection changes so that the
// transport controller will get the up-to-date channel state. However it
// should not be called too often; in the case that multiple connection states
// change, it should be called after all the connection states have changed. For
// example, we call this at the end of SortConnectionsAndUpdateState.
void P2PTransportChannel::UpdateState() {
RTC_DCHECK_RUN_ON(network_thread_);
// If our selected connection is "presumed writable" (TURN-TURN with no
// CreatePermission required), act like we're already writable to the upper
// layers, so they can start media quicker.
bool writable =
selected_connection_ && (selected_connection_->writable() ||
PresumedWritable(selected_connection_));
SetWritable(writable);
bool receiving = false;
for (const Connection* connection : connections()) {
if (connection->receiving()) {
receiving = true;
break;
}
}
SetReceiving(receiving);
IceTransportState state = ComputeState();
webrtc::IceTransportState current_standardized_state =
ComputeIceTransportState();
if (state_ != state) {
RTC_LOG(LS_INFO) << ToString() << ": Transport channel state changed from "
<< static_cast<int>(state_) << " to "
<< static_cast<int>(state);
// Check that the requested transition is allowed. Note that
// P2PTransportChannel does not (yet) implement a direct mapping of the ICE
// states from the standard; the difference is covered by
// TransportController and PeerConnection.
switch (state_) {
case IceTransportState::STATE_INIT:
// TODO(deadbeef): Once we implement end-of-candidates signaling,
// we shouldn't go from INIT to COMPLETED.
RTC_DCHECK(state == IceTransportState::STATE_CONNECTING ||
state == IceTransportState::STATE_COMPLETED ||
state == IceTransportState::STATE_FAILED);
break;
case IceTransportState::STATE_CONNECTING:
RTC_DCHECK(state == IceTransportState::STATE_COMPLETED ||
state == IceTransportState::STATE_FAILED);
break;
case IceTransportState::STATE_COMPLETED:
// TODO(deadbeef): Once we implement end-of-candidates signaling,
// we shouldn't go from COMPLETED to CONNECTING.
// Though we *can* go from COMPlETED to FAILED, if consent expires.
RTC_DCHECK(state == IceTransportState::STATE_CONNECTING ||
state == IceTransportState::STATE_FAILED);
break;
case IceTransportState::STATE_FAILED:
// TODO(deadbeef): Once we implement end-of-candidates signaling,
// we shouldn't go from FAILED to CONNECTING or COMPLETED.
RTC_DCHECK(state == IceTransportState::STATE_CONNECTING ||
state == IceTransportState::STATE_COMPLETED);
break;
default:
RTC_NOTREACHED();
break;
}
state_ = state;
SignalStateChanged(this);
}
if (standardized_state_ != current_standardized_state) {
standardized_state_ = current_standardized_state;
SignalIceTransportStateChanged(this);
}
}
void P2PTransportChannel::MaybeStopPortAllocatorSessions() {
RTC_DCHECK_RUN_ON(network_thread_);
if (!IsGettingPorts()) {
return;
}
for (const auto& session : allocator_sessions_) {
if (session->IsStopped()) {
continue;
}
// If gathering continually, keep the last session running so that
// it can gather candidates if the networks change.
if (config_.gather_continually() && session == allocator_sessions_.back()) {
session->ClearGettingPorts();
} else {
session->StopGettingPorts();
}
}
}
// If all connections timed out, delete them all.
void P2PTransportChannel::HandleAllTimedOut() {
RTC_DCHECK_RUN_ON(network_thread_);
for (Connection* connection : connections()) {
connection->Destroy();
}
}
bool P2PTransportChannel::ReadyToSend(Connection* connection) const {
RTC_DCHECK_RUN_ON(network_thread_);
// Note that we allow sending on an unreliable connection, because it's
// possible that it became unreliable simply due to bad chance.
// So this shouldn't prevent attempting to send media.
return connection != nullptr &&
(connection->writable() ||
connection->write_state() == Connection::STATE_WRITE_UNRELIABLE ||
PresumedWritable(connection));
}
// Handle queued up check-and-ping request
void P2PTransportChannel::CheckAndPing() {
RTC_DCHECK_RUN_ON(network_thread_);
// Make sure the states of the connections are up-to-date (since this affects
// which ones are pingable).
UpdateConnectionStates();
auto result = ice_controller_->SelectConnectionToPing(last_ping_sent_ms_);
Connection* conn = result.first;
int delay = result.second;
if (conn) {
PingConnection(conn);
MarkConnectionPinged(conn);
}
invoker_.AsyncInvokeDelayed<void>(
RTC_FROM_HERE, thread(),
rtc::Bind(&P2PTransportChannel::CheckAndPing, this), delay);
}
// This method is only for unit testing.
Connection* P2PTransportChannel::FindNextPingableConnection() {
RTC_DCHECK_RUN_ON(network_thread_);
return const_cast<Connection*>(ice_controller_->FindNextPingableConnection());
}
// A connection is considered a backup connection if the channel state
// is completed, the connection is not the selected connection and it is active.
void P2PTransportChannel::MarkConnectionPinged(Connection* conn) {
RTC_DCHECK_RUN_ON(network_thread_);
ice_controller_->MarkConnectionPinged(conn);
}
// Apart from sending ping from |conn| this method also updates
// |use_candidate_attr| and |nomination| flags. One of the flags is set to
// nominate |conn| if this channel is in CONTROLLING.
void P2PTransportChannel::PingConnection(Connection* conn) {
RTC_DCHECK_RUN_ON(network_thread_);
bool use_candidate_attr = false;
uint32_t nomination = 0;
if (ice_role_ == ICEROLE_CONTROLLING) {
bool renomination_supported = ice_parameters_.renomination &&
!remote_ice_parameters_.empty() &&
remote_ice_parameters_.back().renomination;
if (renomination_supported) {
nomination = GetNominationAttr(conn);
} else {
use_candidate_attr = GetUseCandidateAttr(conn);
}
}
conn->set_nomination(nomination);
conn->set_use_candidate_attr(use_candidate_attr);
last_ping_sent_ms_ = rtc::TimeMillis();
conn->Ping(last_ping_sent_ms_);
}
uint32_t P2PTransportChannel::GetNominationAttr(Connection* conn) const {
RTC_DCHECK_RUN_ON(network_thread_);
return (conn == selected_connection_) ? nomination_ : 0;
}
// Nominate a connection based on the NominationMode.
bool P2PTransportChannel::GetUseCandidateAttr(Connection* conn) const {
RTC_DCHECK_RUN_ON(network_thread_);
return ice_controller_->GetUseCandidateAttr(
conn, config_.default_nomination_mode, remote_ice_mode_);
}
// When a connection's state changes, we need to figure out who to use as
// the selected connection again. It could have become usable, or become
// unusable.
void P2PTransportChannel::OnConnectionStateChange(Connection* connection) {
RTC_DCHECK_RUN_ON(network_thread_);
// May stop the allocator session when at least one connection becomes
// strongly connected after starting to get ports and the local candidate of
// the connection is at the latest generation. It is not enough to check
// that the connection becomes weakly connected because the connection may be
// changing from (writable, receiving) to (writable, not receiving).
bool strongly_connected = !connection->weak();
bool latest_generation = connection->local_candidate().generation() >=
allocator_session()->generation();
if (strongly_connected && latest_generation) {
MaybeStopPortAllocatorSessions();
}
// We have to unroll the stack before doing this because we may be changing
// the state of connections while sorting.
RequestSortAndStateUpdate(
IceControllerEvent::CONNECT_STATE_CHANGE); // "candidate pair state
// changed");
}
// When a connection is removed, edit it out, and then update our best
// connection.
void P2PTransportChannel::OnConnectionDestroyed(Connection* connection) {
RTC_DCHECK_RUN_ON(network_thread_);
// Note: the previous selected_connection_ may be destroyed by now, so don't
// use it.
// Remove this connection from the list.
ice_controller_->OnConnectionDestroyed(connection);
RTC_LOG(LS_INFO) << ToString() << ": Removed connection " << connection
<< " (" << connections().size() << " remaining)";
// If this is currently the selected connection, then we need to pick a new
// one. The call to SortConnectionsAndUpdateState will pick a new one. It
// looks at the current selected connection in order to avoid switching
// between fairly similar ones. Since this connection is no longer an option,
// we can just set selected to nullptr and re-choose a best assuming that
// there was no selected connection.
if (selected_connection_ == connection) {
RTC_LOG(LS_INFO) << "Selected connection destroyed. Will choose a new one.";
IceControllerEvent reason =
IceControllerEvent::SELECTED_CONNECTION_DESTROYED;
SwitchSelectedConnection(nullptr, reason);
RequestSortAndStateUpdate(reason);
} else {
// If a non-selected connection was destroyed, we don't need to re-sort but
// we do need to update state, because we could be switching to "failed" or
// "completed".
UpdateState();
}
}
// When a port is destroyed, remove it from our list of ports to use for
// connection attempts.
void P2PTransportChannel::OnPortDestroyed(PortInterface* port) {
RTC_DCHECK_RUN_ON(network_thread_);
ports_.erase(std::remove(ports_.begin(), ports_.end(), port), ports_.end());
pruned_ports_.erase(
std::remove(pruned_ports_.begin(), pruned_ports_.end(), port),
pruned_ports_.end());
RTC_LOG(INFO) << "Removed port because it is destroyed: " << ports_.size()
<< " remaining";
}
void P2PTransportChannel::OnPortsPruned(
PortAllocatorSession* session,
const std::vector<PortInterface*>& ports) {
RTC_DCHECK_RUN_ON(network_thread_);
for (PortInterface* port : ports) {
if (PrunePort(port)) {
RTC_LOG(INFO) << "Removed port: " << port->ToString() << " "
<< ports_.size() << " remaining";
}
}
}
void P2PTransportChannel::OnCandidatesRemoved(
PortAllocatorSession* session,
const std::vector<Candidate>& candidates) {
RTC_DCHECK_RUN_ON(network_thread_);
// Do not signal candidate removals if continual gathering is not enabled, or
// if this is not the last session because an ICE restart would have signaled
// the remote side to remove all candidates in previous sessions.
if (!config_.gather_continually() || session != allocator_session()) {
return;
}
std::vector<Candidate> candidates_to_remove;
for (Candidate candidate : candidates) {
candidate.set_transport_name(transport_name());
candidates_to_remove.push_back(candidate);
}
SignalCandidatesRemoved(this, candidates_to_remove);
}
void P2PTransportChannel::PruneAllPorts() {
RTC_DCHECK_RUN_ON(network_thread_);
pruned_ports_.insert(pruned_ports_.end(), ports_.begin(), ports_.end());
ports_.clear();
}
bool P2PTransportChannel::PrunePort(PortInterface* port) {
RTC_DCHECK_RUN_ON(network_thread_);
auto it = absl::c_find(ports_, port);
// Don't need to do anything if the port has been deleted from the port list.
if (it == ports_.end()) {
return false;
}
ports_.erase(it);
pruned_ports_.push_back(port);
return true;
}
// We data is available, let listeners know
void P2PTransportChannel::OnReadPacket(Connection* connection,
const char* data,
size_t len,
int64_t packet_time_us) {
RTC_DCHECK_RUN_ON(network_thread_);
if (connection == selected_connection_) {
// Let the client know of an incoming packet
SignalReadPacket(this, data, len, packet_time_us, 0);
return;
}
// Do not deliver, if packet doesn't belong to the correct transport channel.
if (!FindConnection(connection))
return;
// Let the client know of an incoming packet
SignalReadPacket(this, data, len, packet_time_us, 0);
// May need to switch the sending connection based on the receiving media path
// if this is the controlled side.
if (ice_role_ == ICEROLE_CONTROLLED) {
MaybeSwitchSelectedConnection(connection,
IceControllerEvent::DATA_RECEIVED);
}
}
void P2PTransportChannel::OnSentPacket(const rtc::SentPacket& sent_packet) {
RTC_DCHECK_RUN_ON(network_thread_);
SignalSentPacket(this, sent_packet);
}
void P2PTransportChannel::OnReadyToSend(Connection* connection) {
RTC_DCHECK_RUN_ON(network_thread_);
if (connection == selected_connection_ && writable()) {
SignalReadyToSend(this);
}
}
void P2PTransportChannel::SetWritable(bool writable) {
RTC_DCHECK_RUN_ON(network_thread_);
if (writable_ == writable) {
return;
}
RTC_LOG(LS_VERBOSE) << ToString() << ": Changed writable_ to " << writable;
writable_ = writable;
if (writable_) {
has_been_writable_ = true;
SignalReadyToSend(this);
}
SignalWritableState(this);
}
void P2PTransportChannel::SetReceiving(bool receiving) {
RTC_DCHECK_RUN_ON(network_thread_);
if (receiving_ == receiving) {
return;
}
receiving_ = receiving;
SignalReceivingState(this);
}
Candidate P2PTransportChannel::SanitizeLocalCandidate(
const Candidate& c) const {
RTC_DCHECK_RUN_ON(network_thread_);
// Delegates to the port allocator.
return allocator_->SanitizeCandidate(c);
}
Candidate P2PTransportChannel::SanitizeRemoteCandidate(
const Candidate& c) const {
RTC_DCHECK_RUN_ON(network_thread_);
// If the remote endpoint signaled us an mDNS candidate, we assume it
// is supposed to be sanitized.
bool use_hostname_address = absl::EndsWith(c.address().hostname(), LOCAL_TLD);
// Remove the address for prflx remote candidates. See
// https://w3c.github.io/webrtc-stats/#dom-rtcicecandidatestats.
use_hostname_address |= c.type() == PRFLX_PORT_TYPE;
return c.ToSanitizedCopy(use_hostname_address,
false /* filter_related_address */);
}
void P2PTransportChannel::LogCandidatePairConfig(
Connection* conn,
webrtc::IceCandidatePairConfigType type) {
RTC_DCHECK_RUN_ON(network_thread_);
if (conn == nullptr) {
return;
}
ice_event_log_.LogCandidatePairConfig(type, conn->id(),
conn->ToLogDescription());
}
} // namespace cricket