/* * Copyright (c) 2017 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 "call/rtp_demuxer.h" #include "call/rtp_packet_sink_interface.h" #include "modules/rtp_rtcp/source/rtp_header_extensions.h" #include "modules/rtp_rtcp/source/rtp_packet_received.h" #include "rtc_base/checks.h" #include "rtc_base/logging.h" #include "rtc_base/strings/string_builder.h" namespace webrtc { namespace { template size_t RemoveFromMultimapByValue(Container* multimap, const Value& value) { size_t count = 0; for (auto it = multimap->begin(); it != multimap->end();) { if (it->second == value) { it = multimap->erase(it); ++count; } else { ++it; } } return count; } template size_t RemoveFromMapByValue(Map* map, const Value& value) { size_t count = 0; for (auto it = map->begin(); it != map->end();) { if (it->second == value) { it = map->erase(it); ++count; } else { ++it; } } return count; } } // namespace RtpDemuxerCriteria::RtpDemuxerCriteria() = default; RtpDemuxerCriteria::~RtpDemuxerCriteria() = default; std::string RtpDemuxerCriteria::ToString() const { rtc::StringBuilder sb; sb << "{mid: " << (mid.empty() ? "" : mid) << ", rsid: " << (rsid.empty() ? "" : rsid) << ", ssrcs: ["; for (auto ssrc : ssrcs) { sb << ssrc << ", "; } sb << "], payload_types = ["; for (auto pt : payload_types) { sb << pt << ", "; } sb << "]}"; return sb.Release(); } // static std::string RtpDemuxer::DescribePacket(const RtpPacketReceived& packet) { rtc::StringBuilder sb; sb << "PT=" << packet.PayloadType() << " SSRC=" << packet.Ssrc(); std::string mid; if (packet.GetExtension(&mid)) { sb << " MID=" << mid; } std::string rsid; if (packet.GetExtension(&rsid)) { sb << " RSID=" << rsid; } std::string rrsid; if (packet.GetExtension(&rrsid)) { sb << " RRSID=" << rrsid; } return sb.Release(); } RtpDemuxer::RtpDemuxer() = default; RtpDemuxer::~RtpDemuxer() { RTC_DCHECK(sink_by_mid_.empty()); RTC_DCHECK(sink_by_ssrc_.empty()); RTC_DCHECK(sinks_by_pt_.empty()); RTC_DCHECK(sink_by_mid_and_rsid_.empty()); RTC_DCHECK(sink_by_rsid_.empty()); } bool RtpDemuxer::AddSink(const RtpDemuxerCriteria& criteria, RtpPacketSinkInterface* sink) { RTC_DCHECK(!criteria.payload_types.empty() || !criteria.ssrcs.empty() || !criteria.mid.empty() || !criteria.rsid.empty()); RTC_DCHECK(criteria.mid.empty() || IsLegalMidName(criteria.mid)); RTC_DCHECK(criteria.rsid.empty() || IsLegalRsidName(criteria.rsid)); RTC_DCHECK(sink); // We return false instead of DCHECKing for logical conflicts with the new // criteria because new sinks are created according to user-specified SDP and // we do not want to crash due to a data validation error. if (CriteriaWouldConflict(criteria)) { RTC_LOG(LS_ERROR) << "Unable to add sink = " << sink << " due conflicting criteria " << criteria.ToString(); return false; } if (!criteria.mid.empty()) { if (criteria.rsid.empty()) { sink_by_mid_.emplace(criteria.mid, sink); } else { sink_by_mid_and_rsid_.emplace(std::make_pair(criteria.mid, criteria.rsid), sink); } } else { if (!criteria.rsid.empty()) { sink_by_rsid_.emplace(criteria.rsid, sink); } } for (uint32_t ssrc : criteria.ssrcs) { sink_by_ssrc_.emplace(ssrc, sink); } for (uint8_t payload_type : criteria.payload_types) { sinks_by_pt_.emplace(payload_type, sink); } RefreshKnownMids(); RTC_LOG(LS_INFO) << "Added sink = " << sink << " for criteria " << criteria.ToString(); return true; } bool RtpDemuxer::CriteriaWouldConflict( const RtpDemuxerCriteria& criteria) const { if (!criteria.mid.empty()) { if (criteria.rsid.empty()) { // If the MID is in the known_mids_ set, then there is already a sink // added for this MID directly, or there is a sink already added with a // MID, RSID pair for our MID and some RSID. // Adding this criteria would cause one of these rules to be shadowed, so // reject this new criteria. if (known_mids_.find(criteria.mid) != known_mids_.end()) { RTC_LOG(LS_INFO) << criteria.ToString() << " would conflict with known mid"; return true; } } else { // If the exact rule already exists, then reject this duplicate. const auto sink_by_mid_and_rsid = sink_by_mid_and_rsid_.find( std::make_pair(criteria.mid, criteria.rsid)); if (sink_by_mid_and_rsid != sink_by_mid_and_rsid_.end()) { RTC_LOG(LS_INFO) << criteria.ToString() << " would conflict with existing sink = " << sink_by_mid_and_rsid->second << " by mid+rsid binding"; return true; } // If there is already a sink registered for the bare MID, then this // criteria will never receive any packets because they will just be // directed to that MID sink, so reject this new criteria. const auto sink_by_mid = sink_by_mid_.find(criteria.mid); if (sink_by_mid != sink_by_mid_.end()) { RTC_LOG(LS_INFO) << criteria.ToString() << " would conflict with existing sink = " << sink_by_mid->second << " by mid binding"; return true; } } } for (uint32_t ssrc : criteria.ssrcs) { const auto sink_by_ssrc = sink_by_ssrc_.find(ssrc); if (sink_by_ssrc != sink_by_ssrc_.end()) { RTC_LOG(LS_INFO) << criteria.ToString() << " would conflict with existing sink = " << sink_by_ssrc->second << " binding by SSRC=" << ssrc; return true; } } // TODO(steveanton): May also sanity check payload types. return false; } void RtpDemuxer::RefreshKnownMids() { known_mids_.clear(); for (auto const& item : sink_by_mid_) { const std::string& mid = item.first; known_mids_.insert(mid); } for (auto const& item : sink_by_mid_and_rsid_) { const std::string& mid = item.first.first; known_mids_.insert(mid); } } bool RtpDemuxer::AddSink(uint32_t ssrc, RtpPacketSinkInterface* sink) { RtpDemuxerCriteria criteria; criteria.ssrcs.insert(ssrc); return AddSink(criteria, sink); } void RtpDemuxer::AddSink(const std::string& rsid, RtpPacketSinkInterface* sink) { RtpDemuxerCriteria criteria; criteria.rsid = rsid; AddSink(criteria, sink); } bool RtpDemuxer::RemoveSink(const RtpPacketSinkInterface* sink) { RTC_DCHECK(sink); size_t num_removed = RemoveFromMapByValue(&sink_by_mid_, sink) + RemoveFromMapByValue(&sink_by_ssrc_, sink) + RemoveFromMultimapByValue(&sinks_by_pt_, sink) + RemoveFromMapByValue(&sink_by_mid_and_rsid_, sink) + RemoveFromMapByValue(&sink_by_rsid_, sink); RefreshKnownMids(); bool removed = num_removed > 0; if (removed) { RTC_LOG(LS_INFO) << "Removed sink = " << sink << " bindings"; } return removed; } bool RtpDemuxer::OnRtpPacket(const RtpPacketReceived& packet) { RtpPacketSinkInterface* sink = ResolveSink(packet); if (sink != nullptr) { sink->OnRtpPacket(packet); return true; } return false; } RtpPacketSinkInterface* RtpDemuxer::ResolveSink( const RtpPacketReceived& packet) { // See the BUNDLE spec for high level reference to this algorithm: // https://tools.ietf.org/html/draft-ietf-mmusic-sdp-bundle-negotiation-38#section-10.2 // RSID and RRID are routed to the same sinks. If an RSID is specified on a // repair packet, it should be ignored and the RRID should be used. std::string packet_mid, packet_rsid; bool has_mid = use_mid_ && packet.GetExtension(&packet_mid); bool has_rsid = packet.GetExtension(&packet_rsid); if (!has_rsid) { has_rsid = packet.GetExtension(&packet_rsid); } uint32_t ssrc = packet.Ssrc(); // The BUNDLE spec says to drop any packets with unknown MIDs, even if the // SSRC is known/latched. if (has_mid && known_mids_.find(packet_mid) == known_mids_.end()) { return nullptr; } // Cache information we learn about SSRCs and IDs. We need to do this even if // there isn't a rule/sink yet because we might add an MID/RSID rule after // learning an MID/RSID<->SSRC association. std::string* mid = nullptr; if (has_mid) { mid_by_ssrc_[ssrc] = packet_mid; mid = &packet_mid; } else { // If the packet does not include a MID header extension, check if there is // a latched MID for the SSRC. const auto it = mid_by_ssrc_.find(ssrc); if (it != mid_by_ssrc_.end()) { mid = &it->second; } } std::string* rsid = nullptr; if (has_rsid) { rsid_by_ssrc_[ssrc] = packet_rsid; rsid = &packet_rsid; } else { // If the packet does not include an RRID/RSID header extension, check if // there is a latched RSID for the SSRC. const auto it = rsid_by_ssrc_.find(ssrc); if (it != rsid_by_ssrc_.end()) { rsid = &it->second; } } // If MID and/or RSID is specified, prioritize that for demuxing the packet. // The motivation behind the BUNDLE algorithm is that we trust these are used // deliberately by senders and are more likely to be correct than SSRC/payload // type which are included with every packet. // TODO(steveanton): According to the BUNDLE spec, new SSRC mappings are only // accepted if the packet's extended sequence number is // greater than that of the last SSRC mapping update. // https://tools.ietf.org/html/rfc7941#section-4.2.6 if (mid != nullptr) { RtpPacketSinkInterface* sink_by_mid = ResolveSinkByMid(*mid, ssrc); if (sink_by_mid != nullptr) { return sink_by_mid; } // RSID is scoped to a given MID if both are included. if (rsid != nullptr) { RtpPacketSinkInterface* sink_by_mid_rsid = ResolveSinkByMidRsid(*mid, *rsid, ssrc); if (sink_by_mid_rsid != nullptr) { return sink_by_mid_rsid; } } // At this point, there is at least one sink added for this MID and an RSID // but either the packet does not have an RSID or it is for a different // RSID. This falls outside the BUNDLE spec so drop the packet. return nullptr; } // RSID can be used without MID as long as they are unique. if (rsid != nullptr) { RtpPacketSinkInterface* sink_by_rsid = ResolveSinkByRsid(*rsid, ssrc); if (sink_by_rsid != nullptr) { return sink_by_rsid; } } // We trust signaled SSRC more than payload type which is likely to conflict // between streams. const auto ssrc_sink_it = sink_by_ssrc_.find(ssrc); if (ssrc_sink_it != sink_by_ssrc_.end()) { return ssrc_sink_it->second; } // Legacy senders will only signal payload type, support that as last resort. return ResolveSinkByPayloadType(packet.PayloadType(), ssrc); } RtpPacketSinkInterface* RtpDemuxer::ResolveSinkByMid(const std::string& mid, uint32_t ssrc) { const auto it = sink_by_mid_.find(mid); if (it != sink_by_mid_.end()) { RtpPacketSinkInterface* sink = it->second; AddSsrcSinkBinding(ssrc, sink); return sink; } return nullptr; } RtpPacketSinkInterface* RtpDemuxer::ResolveSinkByMidRsid( const std::string& mid, const std::string& rsid, uint32_t ssrc) { const auto it = sink_by_mid_and_rsid_.find(std::make_pair(mid, rsid)); if (it != sink_by_mid_and_rsid_.end()) { RtpPacketSinkInterface* sink = it->second; AddSsrcSinkBinding(ssrc, sink); return sink; } return nullptr; } RtpPacketSinkInterface* RtpDemuxer::ResolveSinkByRsid(const std::string& rsid, uint32_t ssrc) { const auto it = sink_by_rsid_.find(rsid); if (it != sink_by_rsid_.end()) { RtpPacketSinkInterface* sink = it->second; AddSsrcSinkBinding(ssrc, sink); return sink; } return nullptr; } RtpPacketSinkInterface* RtpDemuxer::ResolveSinkByPayloadType( uint8_t payload_type, uint32_t ssrc) { const auto range = sinks_by_pt_.equal_range(payload_type); if (range.first != range.second) { auto it = range.first; const auto end = range.second; if (std::next(it) == end) { RtpPacketSinkInterface* sink = it->second; AddSsrcSinkBinding(ssrc, sink); return sink; } } return nullptr; } void RtpDemuxer::AddSsrcSinkBinding(uint32_t ssrc, RtpPacketSinkInterface* sink) { if (sink_by_ssrc_.size() >= kMaxSsrcBindings) { RTC_LOG(LS_WARNING) << "New SSRC=" << ssrc << " sink binding ignored; limit of" << kMaxSsrcBindings << " bindings has been reached."; return; } auto result = sink_by_ssrc_.emplace(ssrc, sink); auto it = result.first; bool inserted = result.second; if (inserted) { RTC_LOG(LS_INFO) << "Added sink = " << sink << " binding with SSRC=" << ssrc; } else if (it->second != sink) { RTC_LOG(LS_INFO) << "Updated sink = " << sink << " binding with SSRC=" << ssrc; it->second = sink; } } } // namespace webrtc