blob: 742c15dbf84d2b1964f8f531c1b437f692b478cd [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/port.h"
#include <math.h>
#include <algorithm>
#include <memory>
#include <utility>
#include <vector>
#include "absl/algorithm/container.h"
#include "absl/strings/match.h"
#include "p2p/base/connection.h"
#include "p2p/base/port_allocator.h"
#include "rtc_base/checks.h"
#include "rtc_base/crc32.h"
#include "rtc_base/helpers.h"
#include "rtc_base/logging.h"
#include "rtc_base/mdns_responder_interface.h"
#include "rtc_base/message_digest.h"
#include "rtc_base/network.h"
#include "rtc_base/numerics/safe_minmax.h"
#include "rtc_base/string_encode.h"
#include "rtc_base/string_utils.h"
#include "rtc_base/third_party/base64/base64.h"
#include "system_wrappers/include/field_trial.h"
namespace {
rtc::PacketInfoProtocolType ConvertProtocolTypeToPacketInfoProtocolType(
cricket::ProtocolType type) {
switch (type) {
case cricket::ProtocolType::PROTO_UDP:
return rtc::PacketInfoProtocolType::kUdp;
case cricket::ProtocolType::PROTO_TCP:
return rtc::PacketInfoProtocolType::kTcp;
case cricket::ProtocolType::PROTO_SSLTCP:
return rtc::PacketInfoProtocolType::kSsltcp;
case cricket::ProtocolType::PROTO_TLS:
return rtc::PacketInfoProtocolType::kTls;
default:
return rtc::PacketInfoProtocolType::kUnknown;
}
}
// The delay before we begin checking if this port is useless. We set
// it to a little higher than a total STUN timeout.
const int kPortTimeoutDelay = cricket::STUN_TOTAL_TIMEOUT + 5000;
} // namespace
namespace cricket {
using webrtc::RTCError;
using webrtc::RTCErrorType;
// TODO(ronghuawu): Use "local", "srflx", "prflx" and "relay". But this requires
// the signaling part be updated correspondingly as well.
const char LOCAL_PORT_TYPE[] = "local";
const char STUN_PORT_TYPE[] = "stun";
const char PRFLX_PORT_TYPE[] = "prflx";
const char RELAY_PORT_TYPE[] = "relay";
static const char* const PROTO_NAMES[] = {UDP_PROTOCOL_NAME, TCP_PROTOCOL_NAME,
SSLTCP_PROTOCOL_NAME,
TLS_PROTOCOL_NAME};
const char* ProtoToString(ProtocolType proto) {
return PROTO_NAMES[proto];
}
bool StringToProto(const char* value, ProtocolType* proto) {
for (size_t i = 0; i <= PROTO_LAST; ++i) {
if (absl::EqualsIgnoreCase(PROTO_NAMES[i], value)) {
*proto = static_cast<ProtocolType>(i);
return true;
}
}
return false;
}
// RFC 6544, TCP candidate encoding rules.
const int DISCARD_PORT = 9;
const char TCPTYPE_ACTIVE_STR[] = "active";
const char TCPTYPE_PASSIVE_STR[] = "passive";
const char TCPTYPE_SIMOPEN_STR[] = "so";
std::string Port::ComputeFoundation(const std::string& type,
const std::string& protocol,
const std::string& relay_protocol,
const rtc::SocketAddress& base_address) {
rtc::StringBuilder sb;
sb << type << base_address.ipaddr().ToString() << protocol << relay_protocol;
return rtc::ToString(rtc::ComputeCrc32(sb.Release()));
}
CandidateStats::CandidateStats() = default;
CandidateStats::CandidateStats(const CandidateStats&) = default;
CandidateStats::CandidateStats(Candidate candidate) {
this->candidate = candidate;
}
CandidateStats::~CandidateStats() = default;
Port::Port(rtc::Thread* thread,
const std::string& type,
rtc::PacketSocketFactory* factory,
rtc::Network* network,
const std::string& username_fragment,
const std::string& password)
: thread_(thread),
factory_(factory),
type_(type),
send_retransmit_count_attribute_(false),
network_(network),
min_port_(0),
max_port_(0),
component_(ICE_CANDIDATE_COMPONENT_DEFAULT),
generation_(0),
ice_username_fragment_(username_fragment),
password_(password),
timeout_delay_(kPortTimeoutDelay),
enable_port_packets_(false),
ice_role_(ICEROLE_UNKNOWN),
tiebreaker_(0),
shared_socket_(true),
weak_factory_(this) {
Construct();
}
Port::Port(rtc::Thread* thread,
const std::string& type,
rtc::PacketSocketFactory* factory,
rtc::Network* network,
uint16_t min_port,
uint16_t max_port,
const std::string& username_fragment,
const std::string& password)
: thread_(thread),
factory_(factory),
type_(type),
send_retransmit_count_attribute_(false),
network_(network),
min_port_(min_port),
max_port_(max_port),
component_(ICE_CANDIDATE_COMPONENT_DEFAULT),
generation_(0),
ice_username_fragment_(username_fragment),
password_(password),
timeout_delay_(kPortTimeoutDelay),
enable_port_packets_(false),
ice_role_(ICEROLE_UNKNOWN),
tiebreaker_(0),
shared_socket_(false),
weak_factory_(this) {
RTC_DCHECK(factory_ != NULL);
Construct();
}
void Port::Construct() {
// TODO(pthatcher): Remove this old behavior once we're sure no one
// relies on it. If the username_fragment and password are empty,
// we should just create one.
if (ice_username_fragment_.empty()) {
RTC_DCHECK(password_.empty());
ice_username_fragment_ = rtc::CreateRandomString(ICE_UFRAG_LENGTH);
password_ = rtc::CreateRandomString(ICE_PWD_LENGTH);
}
network_->SignalTypeChanged.connect(this, &Port::OnNetworkTypeChanged);
network_cost_ = network_->GetCost();
thread_->PostDelayed(RTC_FROM_HERE, timeout_delay_, this,
MSG_DESTROY_IF_DEAD);
RTC_LOG(LS_INFO) << ToString() << ": Port created with network cost "
<< network_cost_;
}
Port::~Port() {
// Delete all of the remaining connections. We copy the list up front
// because each deletion will cause it to be modified.
std::vector<Connection*> list;
AddressMap::iterator iter = connections_.begin();
while (iter != connections_.end()) {
list.push_back(iter->second);
++iter;
}
for (uint32_t i = 0; i < list.size(); i++)
delete list[i];
}
const std::string& Port::Type() const {
return type_;
}
rtc::Network* Port::Network() const {
return network_;
}
IceRole Port::GetIceRole() const {
return ice_role_;
}
void Port::SetIceRole(IceRole role) {
ice_role_ = role;
}
void Port::SetIceTiebreaker(uint64_t tiebreaker) {
tiebreaker_ = tiebreaker;
}
uint64_t Port::IceTiebreaker() const {
return tiebreaker_;
}
bool Port::SharedSocket() const {
return shared_socket_;
}
void Port::SetIceParameters(int component,
const std::string& username_fragment,
const std::string& password) {
component_ = component;
ice_username_fragment_ = username_fragment;
password_ = password;
for (Candidate& c : candidates_) {
c.set_component(component);
c.set_username(username_fragment);
c.set_password(password);
}
}
const std::vector<Candidate>& Port::Candidates() const {
return candidates_;
}
Connection* Port::GetConnection(const rtc::SocketAddress& remote_addr) {
AddressMap::const_iterator iter = connections_.find(remote_addr);
if (iter != connections_.end())
return iter->second;
else
return NULL;
}
void Port::AddAddress(const rtc::SocketAddress& address,
const rtc::SocketAddress& base_address,
const rtc::SocketAddress& related_address,
const std::string& protocol,
const std::string& relay_protocol,
const std::string& tcptype,
const std::string& type,
uint32_t type_preference,
uint32_t relay_preference,
bool is_final) {
AddAddress(address, base_address, related_address, protocol, relay_protocol,
tcptype, type, type_preference, relay_preference, "", is_final);
}
void Port::AddAddress(const rtc::SocketAddress& address,
const rtc::SocketAddress& base_address,
const rtc::SocketAddress& related_address,
const std::string& protocol,
const std::string& relay_protocol,
const std::string& tcptype,
const std::string& type,
uint32_t type_preference,
uint32_t relay_preference,
const std::string& url,
bool is_final) {
if (protocol == TCP_PROTOCOL_NAME && type == LOCAL_PORT_TYPE) {
RTC_DCHECK(!tcptype.empty());
}
std::string foundation =
ComputeFoundation(type, protocol, relay_protocol, base_address);
Candidate c(component_, protocol, address, 0U, username_fragment(), password_,
type, generation_, foundation, network_->id(), network_cost_);
c.set_priority(
c.GetPriority(type_preference, network_->preference(), relay_preference));
c.set_relay_protocol(relay_protocol);
c.set_tcptype(tcptype);
c.set_network_name(network_->name());
c.set_network_type(network_->type());
c.set_url(url);
c.set_related_address(related_address);
bool pending = MaybeObfuscateAddress(&c, type, is_final);
if (!pending) {
FinishAddingAddress(c, is_final);
}
}
bool Port::MaybeObfuscateAddress(Candidate* c,
const std::string& type,
bool is_final) {
// TODO(bugs.webrtc.org/9723): Use a config to control the feature of IP
// handling with mDNS.
if (network_->GetMdnsResponder() == nullptr) {
return false;
}
if (type != LOCAL_PORT_TYPE) {
return false;
}
auto copy = *c;
auto weak_ptr = weak_factory_.GetWeakPtr();
auto callback = [weak_ptr, copy, is_final](const rtc::IPAddress& addr,
const std::string& name) mutable {
RTC_DCHECK(copy.address().ipaddr() == addr);
rtc::SocketAddress hostname_address(name, copy.address().port());
// In Port and Connection, we need the IP address information to
// correctly handle the update of candidate type to prflx. The removal
// of IP address when signaling this candidate will take place in
// BasicPortAllocatorSession::OnCandidateReady, via SanitizeCandidate.
hostname_address.SetResolvedIP(addr);
copy.set_address(hostname_address);
copy.set_related_address(rtc::SocketAddress());
if (weak_ptr != nullptr) {
weak_ptr->set_mdns_name_registration_status(
MdnsNameRegistrationStatus::kCompleted);
weak_ptr->FinishAddingAddress(copy, is_final);
}
};
set_mdns_name_registration_status(MdnsNameRegistrationStatus::kInProgress);
network_->GetMdnsResponder()->CreateNameForAddress(copy.address().ipaddr(),
callback);
return true;
}
void Port::FinishAddingAddress(const Candidate& c, bool is_final) {
candidates_.push_back(c);
SignalCandidateReady(this, c);
PostAddAddress(is_final);
}
void Port::PostAddAddress(bool is_final) {
if (is_final) {
SignalPortComplete(this);
}
}
void Port::AddOrReplaceConnection(Connection* conn) {
auto ret = connections_.insert(
std::make_pair(conn->remote_candidate().address(), conn));
// If there is a different connection on the same remote address, replace
// it with the new one and destroy the old one.
if (ret.second == false && ret.first->second != conn) {
RTC_LOG(LS_WARNING)
<< ToString()
<< ": A new connection was created on an existing remote address. "
"New remote candidate: "
<< conn->remote_candidate().ToSensitiveString();
ret.first->second->SignalDestroyed.disconnect(this);
ret.first->second->Destroy();
ret.first->second = conn;
}
conn->SignalDestroyed.connect(this, &Port::OnConnectionDestroyed);
SignalConnectionCreated(this, conn);
}
void Port::OnReadPacket(const char* data,
size_t size,
const rtc::SocketAddress& addr,
ProtocolType proto) {
// If the user has enabled port packets, just hand this over.
if (enable_port_packets_) {
SignalReadPacket(this, data, size, addr);
return;
}
// If this is an authenticated STUN request, then signal unknown address and
// send back a proper binding response.
std::unique_ptr<IceMessage> msg;
std::string remote_username;
if (!GetStunMessage(data, size, addr, &msg, &remote_username)) {
RTC_LOG(LS_ERROR) << ToString()
<< ": Received non-STUN packet from unknown address: "
<< addr.ToSensitiveString();
} else if (!msg) {
// STUN message handled already
} else if (msg->type() == STUN_BINDING_REQUEST) {
RTC_LOG(LS_INFO) << "Received STUN ping id="
<< rtc::hex_encode(msg->transaction_id())
<< " from unknown address " << addr.ToSensitiveString();
// We need to signal an unknown address before we handle any role conflict
// below. Otherwise there would be no candidate pair and TURN entry created
// to send the error response in case of a role conflict.
SignalUnknownAddress(this, addr, proto, msg.get(), remote_username, false);
// Check for role conflicts.
if (!MaybeIceRoleConflict(addr, msg.get(), remote_username)) {
RTC_LOG(LS_INFO) << "Received conflicting role from the peer.";
return;
}
} else {
// NOTE(tschmelcher): STUN_BINDING_RESPONSE is benign. It occurs if we
// pruned a connection for this port while it had STUN requests in flight,
// because we then get back responses for them, which this code correctly
// does not handle.
if (msg->type() != STUN_BINDING_RESPONSE) {
RTC_LOG(LS_ERROR) << ToString()
<< ": Received unexpected STUN message type: "
<< msg->type() << " from unknown address: "
<< addr.ToSensitiveString();
}
}
}
void Port::OnReadyToSend() {
AddressMap::iterator iter = connections_.begin();
for (; iter != connections_.end(); ++iter) {
iter->second->OnReadyToSend();
}
}
size_t Port::AddPrflxCandidate(const Candidate& local) {
candidates_.push_back(local);
return (candidates_.size() - 1);
}
bool Port::GetStunMessage(const char* data,
size_t size,
const rtc::SocketAddress& addr,
std::unique_ptr<IceMessage>* out_msg,
std::string* out_username) {
// NOTE: This could clearly be optimized to avoid allocating any memory.
// However, at the data rates we'll be looking at on the client side,
// this probably isn't worth worrying about.
RTC_DCHECK(out_msg != NULL);
RTC_DCHECK(out_username != NULL);
out_username->clear();
// Don't bother parsing the packet if we can tell it's not STUN.
// In ICE mode, all STUN packets will have a valid fingerprint.
if (!StunMessage::ValidateFingerprint(data, size)) {
return false;
}
// Parse the request message. If the packet is not a complete and correct
// STUN message, then ignore it.
std::unique_ptr<IceMessage> stun_msg(new IceMessage());
rtc::ByteBufferReader buf(data, size);
if (!stun_msg->Read(&buf) || (buf.Length() > 0)) {
return false;
}
if (stun_msg->type() == STUN_BINDING_REQUEST) {
// Check for the presence of USERNAME and MESSAGE-INTEGRITY (if ICE) first.
// If not present, fail with a 400 Bad Request.
if (!stun_msg->GetByteString(STUN_ATTR_USERNAME) ||
!stun_msg->GetByteString(STUN_ATTR_MESSAGE_INTEGRITY)) {
RTC_LOG(LS_ERROR) << ToString()
<< ": Received STUN request without username/M-I from: "
<< addr.ToSensitiveString();
SendBindingErrorResponse(stun_msg.get(), addr, STUN_ERROR_BAD_REQUEST,
STUN_ERROR_REASON_BAD_REQUEST);
return true;
}
// If the username is bad or unknown, fail with a 401 Unauthorized.
std::string local_ufrag;
std::string remote_ufrag;
if (!ParseStunUsername(stun_msg.get(), &local_ufrag, &remote_ufrag) ||
local_ufrag != username_fragment()) {
RTC_LOG(LS_ERROR) << ToString()
<< ": Received STUN request with bad local username "
<< local_ufrag << " from " << addr.ToSensitiveString();
SendBindingErrorResponse(stun_msg.get(), addr, STUN_ERROR_UNAUTHORIZED,
STUN_ERROR_REASON_UNAUTHORIZED);
return true;
}
// If ICE, and the MESSAGE-INTEGRITY is bad, fail with a 401 Unauthorized
if (!stun_msg->ValidateMessageIntegrity(data, size, password_)) {
RTC_LOG(LS_ERROR) << ToString()
<< ": Received STUN request with bad M-I from "
<< addr.ToSensitiveString()
<< ", password_=" << password_;
SendBindingErrorResponse(stun_msg.get(), addr, STUN_ERROR_UNAUTHORIZED,
STUN_ERROR_REASON_UNAUTHORIZED);
return true;
}
out_username->assign(remote_ufrag);
} else if ((stun_msg->type() == STUN_BINDING_RESPONSE) ||
(stun_msg->type() == STUN_BINDING_ERROR_RESPONSE)) {
if (stun_msg->type() == STUN_BINDING_ERROR_RESPONSE) {
if (const StunErrorCodeAttribute* error_code = stun_msg->GetErrorCode()) {
RTC_LOG(LS_ERROR) << ToString()
<< ": Received STUN binding error: class="
<< error_code->eclass()
<< " number=" << error_code->number() << " reason='"
<< error_code->reason() << "' from "
<< addr.ToSensitiveString();
// Return message to allow error-specific processing
} else {
RTC_LOG(LS_ERROR)
<< ToString()
<< ": Received STUN binding error without a error code from "
<< addr.ToSensitiveString();
return true;
}
}
// NOTE: Username should not be used in verifying response messages.
out_username->clear();
} else if (stun_msg->type() == STUN_BINDING_INDICATION) {
RTC_LOG(LS_VERBOSE) << ToString()
<< ": Received STUN binding indication: from "
<< addr.ToSensitiveString();
out_username->clear();
// No stun attributes will be verified, if it's stun indication message.
// Returning from end of the this method.
} else {
RTC_LOG(LS_ERROR) << ToString()
<< ": Received STUN packet with invalid type ("
<< stun_msg->type() << ") from "
<< addr.ToSensitiveString();
return true;
}
// Return the STUN message found.
*out_msg = std::move(stun_msg);
return true;
}
bool Port::IsCompatibleAddress(const rtc::SocketAddress& addr) {
// Get a representative IP for the Network this port is configured to use.
rtc::IPAddress ip = network_->GetBestIP();
// We use single-stack sockets, so families must match.
if (addr.family() != ip.family()) {
return false;
}
// Link-local IPv6 ports can only connect to other link-local IPv6 ports.
if (ip.family() == AF_INET6 &&
(IPIsLinkLocal(ip) != IPIsLinkLocal(addr.ipaddr()))) {
return false;
}
return true;
}
rtc::DiffServCodePoint Port::StunDscpValue() const {
// By default, inherit from whatever the MediaChannel sends.
return rtc::DSCP_NO_CHANGE;
}
bool Port::ParseStunUsername(const StunMessage* stun_msg,
std::string* local_ufrag,
std::string* remote_ufrag) const {
// The packet must include a username that either begins or ends with our
// fragment. It should begin with our fragment if it is a request and it
// should end with our fragment if it is a response.
local_ufrag->clear();
remote_ufrag->clear();
const StunByteStringAttribute* username_attr =
stun_msg->GetByteString(STUN_ATTR_USERNAME);
if (username_attr == NULL)
return false;
// RFRAG:LFRAG
const std::string username = username_attr->GetString();
size_t colon_pos = username.find(':');
if (colon_pos == std::string::npos) {
return false;
}
*local_ufrag = username.substr(0, colon_pos);
*remote_ufrag = username.substr(colon_pos + 1, username.size());
return true;
}
bool Port::MaybeIceRoleConflict(const rtc::SocketAddress& addr,
IceMessage* stun_msg,
const std::string& remote_ufrag) {
// Validate ICE_CONTROLLING or ICE_CONTROLLED attributes.
bool ret = true;
IceRole remote_ice_role = ICEROLE_UNKNOWN;
uint64_t remote_tiebreaker = 0;
const StunUInt64Attribute* stun_attr =
stun_msg->GetUInt64(STUN_ATTR_ICE_CONTROLLING);
if (stun_attr) {
remote_ice_role = ICEROLE_CONTROLLING;
remote_tiebreaker = stun_attr->value();
}
// If |remote_ufrag| is same as port local username fragment and
// tie breaker value received in the ping message matches port
// tiebreaker value this must be a loopback call.
// We will treat this as valid scenario.
if (remote_ice_role == ICEROLE_CONTROLLING &&
username_fragment() == remote_ufrag &&
remote_tiebreaker == IceTiebreaker()) {
return true;
}
stun_attr = stun_msg->GetUInt64(STUN_ATTR_ICE_CONTROLLED);
if (stun_attr) {
remote_ice_role = ICEROLE_CONTROLLED;
remote_tiebreaker = stun_attr->value();
}
switch (ice_role_) {
case ICEROLE_CONTROLLING:
if (ICEROLE_CONTROLLING == remote_ice_role) {
if (remote_tiebreaker >= tiebreaker_) {
SignalRoleConflict(this);
} else {
// Send Role Conflict (487) error response.
SendBindingErrorResponse(stun_msg, addr, STUN_ERROR_ROLE_CONFLICT,
STUN_ERROR_REASON_ROLE_CONFLICT);
ret = false;
}
}
break;
case ICEROLE_CONTROLLED:
if (ICEROLE_CONTROLLED == remote_ice_role) {
if (remote_tiebreaker < tiebreaker_) {
SignalRoleConflict(this);
} else {
// Send Role Conflict (487) error response.
SendBindingErrorResponse(stun_msg, addr, STUN_ERROR_ROLE_CONFLICT,
STUN_ERROR_REASON_ROLE_CONFLICT);
ret = false;
}
}
break;
default:
RTC_NOTREACHED();
}
return ret;
}
void Port::CreateStunUsername(const std::string& remote_username,
std::string* stun_username_attr_str) const {
stun_username_attr_str->clear();
*stun_username_attr_str = remote_username;
stun_username_attr_str->append(":");
stun_username_attr_str->append(username_fragment());
}
bool Port::HandleIncomingPacket(rtc::AsyncPacketSocket* socket,
const char* data,
size_t size,
const rtc::SocketAddress& remote_addr,
int64_t packet_time_us) {
RTC_NOTREACHED();
return false;
}
bool Port::CanHandleIncomingPacketsFrom(const rtc::SocketAddress&) const {
return false;
}
void Port::SendBindingResponse(StunMessage* request,
const rtc::SocketAddress& addr) {
RTC_DCHECK(request->type() == STUN_BINDING_REQUEST);
// Retrieve the username from the request.
const StunByteStringAttribute* username_attr =
request->GetByteString(STUN_ATTR_USERNAME);
RTC_DCHECK(username_attr != NULL);
if (username_attr == NULL) {
// No valid username, skip the response.
return;
}
// Fill in the response message.
StunMessage response;
response.SetType(STUN_BINDING_RESPONSE);
response.SetTransactionID(request->transaction_id());
const StunUInt32Attribute* retransmit_attr =
request->GetUInt32(STUN_ATTR_RETRANSMIT_COUNT);
if (retransmit_attr) {
// Inherit the incoming retransmit value in the response so the other side
// can see our view of lost pings.
response.AddAttribute(std::make_unique<StunUInt32Attribute>(
STUN_ATTR_RETRANSMIT_COUNT, retransmit_attr->value()));
if (retransmit_attr->value() > CONNECTION_WRITE_CONNECT_FAILURES) {
RTC_LOG(LS_INFO)
<< ToString()
<< ": Received a remote ping with high retransmit count: "
<< retransmit_attr->value();
}
}
response.AddAttribute(std::make_unique<StunXorAddressAttribute>(
STUN_ATTR_XOR_MAPPED_ADDRESS, addr));
response.AddMessageIntegrity(password_);
response.AddFingerprint();
// Send the response message.
rtc::ByteBufferWriter buf;
response.Write(&buf);
rtc::PacketOptions options(StunDscpValue());
options.info_signaled_after_sent.packet_type =
rtc::PacketType::kIceConnectivityCheckResponse;
auto err = SendTo(buf.Data(), buf.Length(), addr, options, false);
if (err < 0) {
RTC_LOG(LS_ERROR) << ToString()
<< ": Failed to send STUN ping response, to="
<< addr.ToSensitiveString() << ", err=" << err
<< ", id=" << rtc::hex_encode(response.transaction_id());
} else {
// Log at LS_INFO if we send a stun ping response on an unwritable
// connection.
Connection* conn = GetConnection(addr);
rtc::LoggingSeverity sev =
(conn && !conn->writable()) ? rtc::LS_INFO : rtc::LS_VERBOSE;
RTC_LOG_V(sev) << ToString() << ": Sent STUN ping response, to="
<< addr.ToSensitiveString()
<< ", id=" << rtc::hex_encode(response.transaction_id());
conn->stats_.sent_ping_responses++;
conn->LogCandidatePairEvent(
webrtc::IceCandidatePairEventType::kCheckResponseSent,
request->reduced_transaction_id());
}
}
void Port::SendBindingErrorResponse(StunMessage* request,
const rtc::SocketAddress& addr,
int error_code,
const std::string& reason) {
RTC_DCHECK(request->type() == STUN_BINDING_REQUEST);
// Fill in the response message.
StunMessage response;
response.SetType(STUN_BINDING_ERROR_RESPONSE);
response.SetTransactionID(request->transaction_id());
// When doing GICE, we need to write out the error code incorrectly to
// maintain backwards compatiblility.
auto error_attr = StunAttribute::CreateErrorCode();
error_attr->SetCode(error_code);
error_attr->SetReason(reason);
response.AddAttribute(std::move(error_attr));
// Per Section 10.1.2, certain error cases don't get a MESSAGE-INTEGRITY,
// because we don't have enough information to determine the shared secret.
if (error_code != STUN_ERROR_BAD_REQUEST &&
error_code != STUN_ERROR_UNAUTHORIZED)
response.AddMessageIntegrity(password_);
response.AddFingerprint();
// Send the response message.
rtc::ByteBufferWriter buf;
response.Write(&buf);
rtc::PacketOptions options(StunDscpValue());
options.info_signaled_after_sent.packet_type =
rtc::PacketType::kIceConnectivityCheckResponse;
SendTo(buf.Data(), buf.Length(), addr, options, false);
RTC_LOG(LS_INFO) << ToString()
<< ": Sending STUN binding error: reason=" << reason
<< " to " << addr.ToSensitiveString();
}
void Port::KeepAliveUntilPruned() {
// If it is pruned, we won't bring it up again.
if (state_ == State::INIT) {
state_ = State::KEEP_ALIVE_UNTIL_PRUNED;
}
}
void Port::Prune() {
state_ = State::PRUNED;
thread_->Post(RTC_FROM_HERE, this, MSG_DESTROY_IF_DEAD);
}
void Port::OnMessage(rtc::Message* pmsg) {
RTC_DCHECK(pmsg->message_id == MSG_DESTROY_IF_DEAD);
bool dead =
(state_ == State::INIT || state_ == State::PRUNED) &&
connections_.empty() &&
rtc::TimeMillis() - last_time_all_connections_removed_ >= timeout_delay_;
if (dead) {
Destroy();
}
}
void Port::OnNetworkTypeChanged(const rtc::Network* network) {
RTC_DCHECK(network == network_);
UpdateNetworkCost();
}
std::string Port::ToString() const {
rtc::StringBuilder ss;
ss << "Port[" << rtc::ToHex(reinterpret_cast<uintptr_t>(this)) << ":"
<< content_name_ << ":" << component_ << ":" << generation_ << ":" << type_
<< ":" << network_->ToString() << "]";
return ss.Release();
}
// TODO(honghaiz): Make the network cost configurable from user setting.
void Port::UpdateNetworkCost() {
uint16_t new_cost = network_->GetCost();
if (network_cost_ == new_cost) {
return;
}
RTC_LOG(LS_INFO) << "Network cost changed from " << network_cost_ << " to "
<< new_cost
<< ". Number of candidates created: " << candidates_.size()
<< ". Number of connections created: "
<< connections_.size();
network_cost_ = new_cost;
for (cricket::Candidate& candidate : candidates_) {
candidate.set_network_cost(network_cost_);
}
// Network cost change will affect the connection selection criteria.
// Signal the connection state change on each connection to force a
// re-sort in P2PTransportChannel.
for (const auto& kv : connections_) {
Connection* conn = kv.second;
conn->SignalStateChange(conn);
}
}
void Port::EnablePortPackets() {
enable_port_packets_ = true;
}
void Port::OnConnectionDestroyed(Connection* conn) {
AddressMap::iterator iter =
connections_.find(conn->remote_candidate().address());
RTC_DCHECK(iter != connections_.end());
connections_.erase(iter);
HandleConnectionDestroyed(conn);
// Ports time out after all connections fail if it is not marked as
// "keep alive until pruned."
// Note: If a new connection is added after this message is posted, but it
// fails and is removed before kPortTimeoutDelay, then this message will
// not cause the Port to be destroyed.
if (connections_.empty()) {
last_time_all_connections_removed_ = rtc::TimeMillis();
thread_->PostDelayed(RTC_FROM_HERE, timeout_delay_, this,
MSG_DESTROY_IF_DEAD);
}
}
void Port::Destroy() {
RTC_DCHECK(connections_.empty());
RTC_LOG(LS_INFO) << ToString() << ": Port deleted";
SignalDestroyed(this);
delete this;
}
const std::string Port::username_fragment() const {
return ice_username_fragment_;
}
void Port::CopyPortInformationToPacketInfo(rtc::PacketInfo* info) const {
info->protocol = ConvertProtocolTypeToPacketInfoProtocolType(GetProtocol());
info->network_id = Network()->id();
}
} // namespace cricket