/* * Copyright 2011 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 "webrtc/examples/peerconnection/server/peer_channel.h" #include #include #include #include #include "webrtc/examples/peerconnection/server/data_socket.h" #include "webrtc/examples/peerconnection/server/utils.h" #include "webrtc/base/stringutils.h" #include "webrtc/base/urlencode.h" using rtc::sprintfn; // Set to the peer id of the originator when messages are being // exchanged between peers, but set to the id of the receiving peer // itself when notifications are sent from the server about the state // of other peers. // // WORKAROUND: Since support for CORS varies greatly from one browser to the // next, we don't use a custom name for our peer-id header (originally it was // "X-Peer-Id: "). Instead, we use a "simple header", "Pragma" which should // always be exposed to CORS requests. There is a special CORS header devoted // to exposing proprietary headers (Access-Control-Expose-Headers), however // at this point it is not working correctly in some popular browsers. static const char kPeerIdHeader[] = "Pragma: "; static const char* kRequestPaths[] = { "/wait", "/sign_out", "/message", }; enum RequestPathIndex { kWait, kSignOut, kMessage, }; const size_t kMaxNameLength = 512; // // ChannelMember // int ChannelMember::s_member_id_ = 0; ChannelMember::ChannelMember(DataSocket* socket) : waiting_socket_(NULL), id_(++s_member_id_), connected_(true), timestamp_(time(NULL)) { assert(socket); assert(socket->method() == DataSocket::GET); assert(socket->PathEquals("/sign_in")); name_ = rtc::UrlDecodeString(socket->request_arguments()); if (name_.empty()) name_ = "peer_" + int2str(id_); else if (name_.length() > kMaxNameLength) name_.resize(kMaxNameLength); std::replace(name_.begin(), name_.end(), ',', '_'); } ChannelMember::~ChannelMember() { } bool ChannelMember::is_wait_request(DataSocket* ds) const { return ds && ds->PathEquals(kRequestPaths[kWait]); } bool ChannelMember::TimedOut() { return waiting_socket_ == NULL && (time(NULL) - timestamp_) > 30; } std::string ChannelMember::GetPeerIdHeader() const { std::string ret(kPeerIdHeader + int2str(id_) + "\r\n"); return ret; } bool ChannelMember::NotifyOfOtherMember(const ChannelMember& other) { assert(&other != this); QueueResponse("200 OK", "text/plain", GetPeerIdHeader(), other.GetEntry()); return true; } // Returns a string in the form "name,id,connected\n". std::string ChannelMember::GetEntry() const { assert(name_.length() <= kMaxNameLength); // name, 11-digit int, 1-digit bool, newline, null char entry[kMaxNameLength + 15]; sprintfn(entry, sizeof(entry), "%s,%d,%d\n", name_.substr(0, kMaxNameLength).c_str(), id_, connected_); return entry; } void ChannelMember::ForwardRequestToPeer(DataSocket* ds, ChannelMember* peer) { assert(peer); assert(ds); std::string extra_headers(GetPeerIdHeader()); if (peer == this) { ds->Send("200 OK", true, ds->content_type(), extra_headers, ds->data()); } else { printf("Client %s sending to %s\n", name_.c_str(), peer->name().c_str()); peer->QueueResponse("200 OK", ds->content_type(), extra_headers, ds->data()); ds->Send("200 OK", true, "text/plain", "", ""); } } void ChannelMember::OnClosing(DataSocket* ds) { if (ds == waiting_socket_) { waiting_socket_ = NULL; timestamp_ = time(NULL); } } void ChannelMember::QueueResponse(const std::string& status, const std::string& content_type, const std::string& extra_headers, const std::string& data) { if (waiting_socket_) { assert(queue_.size() == 0); assert(waiting_socket_->method() == DataSocket::GET); bool ok = waiting_socket_->Send(status, true, content_type, extra_headers, data); if (!ok) { printf("Failed to deliver data to waiting socket\n"); } waiting_socket_ = NULL; timestamp_ = time(NULL); } else { QueuedResponse qr; qr.status = status; qr.content_type = content_type; qr.extra_headers = extra_headers; qr.data = data; queue_.push(qr); } } void ChannelMember::SetWaitingSocket(DataSocket* ds) { assert(ds->method() == DataSocket::GET); if (ds && !queue_.empty()) { assert(waiting_socket_ == NULL); const QueuedResponse& response = queue_.front(); ds->Send(response.status, true, response.content_type, response.extra_headers, response.data); queue_.pop(); } else { waiting_socket_ = ds; } } // // PeerChannel // // static bool PeerChannel::IsPeerConnection(const DataSocket* ds) { assert(ds); return (ds->method() == DataSocket::POST && ds->content_length() > 0) || (ds->method() == DataSocket::GET && ds->PathEquals("/sign_in")); } ChannelMember* PeerChannel::Lookup(DataSocket* ds) const { assert(ds); if (ds->method() != DataSocket::GET && ds->method() != DataSocket::POST) return NULL; size_t i = 0; for (; i < ARRAYSIZE(kRequestPaths); ++i) { if (ds->PathEquals(kRequestPaths[i])) break; } if (i == ARRAYSIZE(kRequestPaths)) return NULL; std::string args(ds->request_arguments()); static const char kPeerId[] = "peer_id="; size_t found = args.find(kPeerId); if (found == std::string::npos) return NULL; int id = atoi(&args[found + ARRAYSIZE(kPeerId) - 1]); Members::const_iterator iter = members_.begin(); for (; iter != members_.end(); ++iter) { if (id == (*iter)->id()) { if (i == kWait) (*iter)->SetWaitingSocket(ds); if (i == kSignOut) (*iter)->set_disconnected(); return *iter; } } return NULL; } ChannelMember* PeerChannel::IsTargetedRequest(const DataSocket* ds) const { assert(ds); // Regardless of GET or POST, we look for the peer_id parameter // only in the request_path. const std::string& path = ds->request_path(); size_t args = path.find('?'); if (args == std::string::npos) return NULL; size_t found; const char kTargetPeerIdParam[] = "to="; do { found = path.find(kTargetPeerIdParam, args); if (found == std::string::npos) return NULL; if (found == (args + 1) || path[found - 1] == '&') { found += ARRAYSIZE(kTargetPeerIdParam) - 1; break; } args = found + ARRAYSIZE(kTargetPeerIdParam) - 1; } while (true); int id = atoi(&path[found]); Members::const_iterator i = members_.begin(); for (; i != members_.end(); ++i) { if ((*i)->id() == id) { return *i; } } return NULL; } bool PeerChannel::AddMember(DataSocket* ds) { assert(IsPeerConnection(ds)); ChannelMember* new_guy = new ChannelMember(ds); Members failures; BroadcastChangedState(*new_guy, &failures); HandleDeliveryFailures(&failures); members_.push_back(new_guy); printf("New member added (total=%s): %s\n", size_t2str(members_.size()).c_str(), new_guy->name().c_str()); // Let the newly connected peer know about other members of the channel. std::string content_type; std::string response = BuildResponseForNewMember(*new_guy, &content_type); ds->Send("200 Added", true, content_type, new_guy->GetPeerIdHeader(), response); return true; } void PeerChannel::CloseAll() { Members::const_iterator i = members_.begin(); for (; i != members_.end(); ++i) { (*i)->QueueResponse("200 OK", "text/plain", "", "Server shutting down"); } DeleteAll(); } void PeerChannel::OnClosing(DataSocket* ds) { for (Members::iterator i = members_.begin(); i != members_.end(); ++i) { ChannelMember* m = (*i); m->OnClosing(ds); if (!m->connected()) { i = members_.erase(i); Members failures; BroadcastChangedState(*m, &failures); HandleDeliveryFailures(&failures); delete m; if (i == members_.end()) break; } } printf("Total connected: %s\n", size_t2str(members_.size()).c_str()); } void PeerChannel::CheckForTimeout() { for (Members::iterator i = members_.begin(); i != members_.end(); ++i) { ChannelMember* m = (*i); if (m->TimedOut()) { printf("Timeout: %s\n", m->name().c_str()); m->set_disconnected(); i = members_.erase(i); Members failures; BroadcastChangedState(*m, &failures); HandleDeliveryFailures(&failures); delete m; if (i == members_.end()) break; } } } void PeerChannel::DeleteAll() { for (Members::iterator i = members_.begin(); i != members_.end(); ++i) delete (*i); members_.clear(); } void PeerChannel::BroadcastChangedState(const ChannelMember& member, Members* delivery_failures) { // This function should be called prior to DataSocket::Close(). assert(delivery_failures); if (!member.connected()) { printf("Member disconnected: %s\n", member.name().c_str()); } Members::iterator i = members_.begin(); for (; i != members_.end(); ++i) { if (&member != (*i)) { if (!(*i)->NotifyOfOtherMember(member)) { (*i)->set_disconnected(); delivery_failures->push_back(*i); i = members_.erase(i); if (i == members_.end()) break; } } } } void PeerChannel::HandleDeliveryFailures(Members* failures) { assert(failures); while (!failures->empty()) { Members::iterator i = failures->begin(); ChannelMember* member = *i; assert(!member->connected()); failures->erase(i); BroadcastChangedState(*member, failures); delete member; } } // Builds a simple list of "name,id\n" entries for each member. std::string PeerChannel::BuildResponseForNewMember(const ChannelMember& member, std::string* content_type) { assert(content_type); *content_type = "text/plain"; // The peer itself will always be the first entry. std::string response(member.GetEntry()); for (Members::iterator i = members_.begin(); i != members_.end(); ++i) { if (member.id() != (*i)->id()) { assert((*i)->connected()); response += (*i)->GetEntry(); } } return response; }