/* * 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 "pc/webrtc_sdp.h" #include #include #include #include #include #include #include #include #include #include #include #include #include "absl/algorithm/container.h" #include "api/candidate.h" #include "api/crypto_params.h" #include "api/jsep_ice_candidate.h" #include "api/jsep_session_description.h" #include "api/media_types.h" // for RtpExtension #include "absl/types/optional.h" #include "api/rtc_error.h" #include "api/rtp_parameters.h" #include "api/rtp_transceiver_direction.h" #include "media/base/codec.h" #include "media/base/media_constants.h" #include "media/base/rid_description.h" #include "media/base/rtp_utils.h" #include "media/base/stream_params.h" #include "media/sctp/sctp_transport_internal.h" #include "p2p/base/candidate_pair_interface.h" #include "p2p/base/ice_transport_internal.h" #include "p2p/base/p2p_constants.h" #include "p2p/base/port.h" #include "p2p/base/port_interface.h" #include "p2p/base/transport_description.h" #include "p2p/base/transport_info.h" #include "pc/media_protocol_names.h" #include "pc/media_session.h" #include "pc/sdp_serializer.h" #include "pc/session_description.h" #include "pc/simulcast_description.h" #include "rtc_base/arraysize.h" #include "rtc_base/checks.h" #include "rtc_base/helpers.h" #include "rtc_base/ip_address.h" #include "rtc_base/logging.h" #include "rtc_base/net_helper.h" #include "rtc_base/network_constants.h" #include "rtc_base/socket_address.h" #include "rtc_base/ssl_fingerprint.h" #include "rtc_base/string_encode.h" #include "rtc_base/string_utils.h" #include "rtc_base/strings/string_builder.h" using cricket::AudioContentDescription; using cricket::Candidate; using cricket::Candidates; using cricket::ContentInfo; using cricket::CryptoParams; using cricket::ICE_CANDIDATE_COMPONENT_RTCP; using cricket::ICE_CANDIDATE_COMPONENT_RTP; using cricket::kApplicationSpecificBandwidth; using cricket::kCodecParamMaxPTime; using cricket::kCodecParamMinPTime; using cricket::kCodecParamPTime; using cricket::kTransportSpecificBandwidth; using cricket::MediaContentDescription; using cricket::MediaProtocolType; using cricket::MediaType; using cricket::RidDescription; using cricket::RtpHeaderExtensions; using cricket::SctpDataContentDescription; using cricket::SimulcastDescription; using cricket::SimulcastLayer; using cricket::SimulcastLayerList; using cricket::SsrcGroup; using cricket::StreamParams; using cricket::StreamParamsVec; using cricket::TransportDescription; using cricket::TransportInfo; using cricket::UnsupportedContentDescription; using cricket::VideoContentDescription; using rtc::SocketAddress; // TODO(deadbeef): Switch to using anonymous namespace rather than declaring // everything "static". namespace webrtc { // Line type // RFC 4566 // An SDP session description consists of a number of lines of text of // the form: // = // where MUST be exactly one case-significant character. // Check if passed character is a "token-char" from RFC 4566. // https://datatracker.ietf.org/doc/html/rfc4566#section-9 // token-char = %x21 / %x23-27 / %x2A-2B / %x2D-2E / %x30-39 // / %x41-5A / %x5E-7E bool IsTokenChar(char ch) { return ch == 0x21 || (ch >= 0x23 && ch <= 0x27) || ch == 0x2a || ch == 0x2b || ch == 0x2d || ch == 0x2e || (ch >= 0x30 && ch <= 0x39) || (ch >= 0x41 && ch <= 0x5a) || (ch >= 0x5e && ch <= 0x7e); } static const int kLinePrefixLength = 2; // Length of = static const char kLineTypeVersion = 'v'; static const char kLineTypeOrigin = 'o'; static const char kLineTypeSessionName = 's'; static const char kLineTypeSessionInfo = 'i'; static const char kLineTypeSessionUri = 'u'; static const char kLineTypeSessionEmail = 'e'; static const char kLineTypeSessionPhone = 'p'; static const char kLineTypeSessionBandwidth = 'b'; static const char kLineTypeTiming = 't'; static const char kLineTypeRepeatTimes = 'r'; static const char kLineTypeTimeZone = 'z'; static const char kLineTypeEncryptionKey = 'k'; static const char kLineTypeMedia = 'm'; static const char kLineTypeConnection = 'c'; static const char kLineTypeAttributes = 'a'; // Attributes static const char kAttributeGroup[] = "group"; static const char kAttributeMid[] = "mid"; static const char kAttributeMsid[] = "msid"; static const char kAttributeBundleOnly[] = "bundle-only"; static const char kAttributeRtcpMux[] = "rtcp-mux"; static const char kAttributeRtcpReducedSize[] = "rtcp-rsize"; static const char kAttributeSsrc[] = "ssrc"; static const char kSsrcAttributeCname[] = "cname"; static const char kAttributeExtmapAllowMixed[] = "extmap-allow-mixed"; static const char kAttributeExtmap[] = "extmap"; // draft-alvestrand-mmusic-msid-01 // a=msid-semantic: WMS // This is a legacy field supported only for Plan B semantics. static const char kAttributeMsidSemantics[] = "msid-semantic"; static const char kMediaStreamSemantic[] = "WMS"; static const char kSsrcAttributeMsid[] = "msid"; static const char kDefaultMsid[] = "default"; static const char kNoStreamMsid[] = "-"; static const char kSsrcAttributeMslabel[] = "mslabel"; static const char kSSrcAttributeLabel[] = "label"; static const char kAttributeSsrcGroup[] = "ssrc-group"; static const char kAttributeCrypto[] = "crypto"; static const char kAttributeCandidate[] = "candidate"; static const char kAttributeCandidateTyp[] = "typ"; static const char kAttributeCandidateRaddr[] = "raddr"; static const char kAttributeCandidateRport[] = "rport"; static const char kAttributeCandidateUfrag[] = "ufrag"; static const char kAttributeCandidatePwd[] = "pwd"; static const char kAttributeCandidateGeneration[] = "generation"; static const char kAttributeCandidateNetworkId[] = "network-id"; static const char kAttributeCandidateNetworkCost[] = "network-cost"; static const char kAttributeFingerprint[] = "fingerprint"; static const char kAttributeSetup[] = "setup"; static const char kAttributeFmtp[] = "fmtp"; static const char kAttributeRtpmap[] = "rtpmap"; static const char kAttributeSctpmap[] = "sctpmap"; static const char kAttributeRtcp[] = "rtcp"; static const char kAttributeIceUfrag[] = "ice-ufrag"; static const char kAttributeIcePwd[] = "ice-pwd"; static const char kAttributeIceLite[] = "ice-lite"; static const char kAttributeIceOption[] = "ice-options"; static const char kAttributeSendOnly[] = "sendonly"; static const char kAttributeRecvOnly[] = "recvonly"; static const char kAttributeRtcpFb[] = "rtcp-fb"; static const char kAttributeSendRecv[] = "sendrecv"; static const char kAttributeInactive[] = "inactive"; // draft-ietf-mmusic-sctp-sdp-26 // a=sctp-port, a=max-message-size static const char kAttributeSctpPort[] = "sctp-port"; static const char kAttributeMaxMessageSize[] = "max-message-size"; static const int kDefaultSctpMaxMessageSize = 65536; // draft-ietf-mmusic-sdp-simulcast-13 // a=simulcast static const char kAttributeSimulcast[] = "simulcast"; // draft-ietf-mmusic-rid-15 // a=rid static const char kAttributeRid[] = "rid"; static const char kAttributePacketization[] = "packetization"; // Experimental flags static const char kAttributeXGoogleFlag[] = "x-google-flag"; static const char kValueConference[] = "conference"; static const char kAttributeRtcpRemoteEstimate[] = "remote-net-estimate"; // Candidate static const char kCandidateHost[] = "host"; static const char kCandidateSrflx[] = "srflx"; static const char kCandidatePrflx[] = "prflx"; static const char kCandidateRelay[] = "relay"; static const char kTcpCandidateType[] = "tcptype"; // rtc::StringBuilder doesn't have a << overload for chars, while rtc::split and // rtc::tokenize_first both take a char delimiter. To handle both cases these // constants come in pairs of a chars and length-one strings. static const char kSdpDelimiterEqual[] = "="; static const char kSdpDelimiterEqualChar = '='; static const char kSdpDelimiterSpace[] = " "; static const char kSdpDelimiterSpaceChar = ' '; static const char kSdpDelimiterColon[] = ":"; static const char kSdpDelimiterColonChar = ':'; static const char kSdpDelimiterSemicolon[] = ";"; static const char kSdpDelimiterSemicolonChar = ';'; static const char kSdpDelimiterSlashChar = '/'; static const char kNewLine[] = "\n"; static const char kNewLineChar = '\n'; static const char kReturnChar = '\r'; static const char kLineBreak[] = "\r\n"; // TODO(deadbeef): Generate the Session and Time description // instead of hardcoding. static const char kSessionVersion[] = "v=0"; // RFC 4566 static const char kSessionOriginUsername[] = "-"; static const char kSessionOriginSessionId[] = "0"; static const char kSessionOriginSessionVersion[] = "0"; static const char kSessionOriginNettype[] = "IN"; static const char kSessionOriginAddrtype[] = "IP4"; static const char kSessionOriginAddress[] = "127.0.0.1"; static const char kSessionName[] = "s=-"; static const char kTimeDescription[] = "t=0 0"; static const char kAttrGroup[] = "a=group:BUNDLE"; static const char kConnectionNettype[] = "IN"; static const char kConnectionIpv4Addrtype[] = "IP4"; static const char kConnectionIpv6Addrtype[] = "IP6"; static const char kMediaTypeVideo[] = "video"; static const char kMediaTypeAudio[] = "audio"; static const char kMediaTypeData[] = "application"; static const char kMediaPortRejected[] = "0"; // draft-ietf-mmusic-trickle-ice-01 // When no candidates have been gathered, set the connection // address to IP6 ::. // TODO(perkj): FF can not parse IP6 ::. See http://crbug/430333 // Use IPV4 per default. static const char kDummyAddress[] = "0.0.0.0"; static const char kDummyPort[] = "9"; static const char kDefaultSctpmapProtocol[] = "webrtc-datachannel"; // RTP payload type is in the 0-127 range. Use -1 to indicate "all" payload // types. const int kWildcardPayloadType = -1; // Maximum number of channels allowed. static const size_t kMaxNumberOfChannels = 24; struct SsrcInfo { uint32_t ssrc_id; std::string cname; std::string stream_id; std::string track_id; // For backward compatibility. // TODO(ronghuawu): Remove below 2 fields once all the clients support msid. std::string label; std::string mslabel; }; typedef std::vector SsrcInfoVec; typedef std::vector SsrcGroupVec; template static void AddFmtpLine(const T& codec, std::string* message); static void BuildMediaDescription(const ContentInfo* content_info, const TransportInfo* transport_info, const cricket::MediaType media_type, const std::vector& candidates, int msid_signaling, std::string* message); static void BuildRtpContentAttributes(const MediaContentDescription* media_desc, const cricket::MediaType media_type, int msid_signaling, std::string* message); static void BuildRtpMap(const MediaContentDescription* media_desc, const cricket::MediaType media_type, std::string* message); static void BuildCandidate(const std::vector& candidates, bool include_ufrag, std::string* message); static void BuildIceOptions(const std::vector& transport_options, std::string* message); static bool ParseSessionDescription(const std::string& message, size_t* pos, std::string* session_id, std::string* session_version, TransportDescription* session_td, RtpHeaderExtensions* session_extmaps, rtc::SocketAddress* connection_addr, cricket::SessionDescription* desc, SdpParseError* error); static bool ParseMediaDescription( const std::string& message, const TransportDescription& session_td, const RtpHeaderExtensions& session_extmaps, size_t* pos, const rtc::SocketAddress& session_connection_addr, cricket::SessionDescription* desc, std::vector>* candidates, SdpParseError* error); static bool ParseContent( const std::string& message, const cricket::MediaType media_type, int mline_index, const std::string& protocol, const std::vector& payload_types, size_t* pos, std::string* content_name, bool* bundle_only, int* msid_signaling, MediaContentDescription* media_desc, TransportDescription* transport, std::vector>* candidates, SdpParseError* error); static bool ParseGroupAttribute(const std::string& line, cricket::SessionDescription* desc, SdpParseError* error); static bool ParseSsrcAttribute(const std::string& line, SsrcInfoVec* ssrc_infos, int* msid_signaling, SdpParseError* error); static bool ParseSsrcGroupAttribute(const std::string& line, SsrcGroupVec* ssrc_groups, SdpParseError* error); static bool ParseCryptoAttribute(const std::string& line, MediaContentDescription* media_desc, SdpParseError* error); static bool ParseRtpmapAttribute(const std::string& line, const cricket::MediaType media_type, const std::vector& payload_types, MediaContentDescription* media_desc, SdpParseError* error); static bool ParseFmtpAttributes(const std::string& line, const cricket::MediaType media_type, MediaContentDescription* media_desc, SdpParseError* error); static bool ParseFmtpParam(const std::string& line, std::string* parameter, std::string* value, SdpParseError* error); static bool ParsePacketizationAttribute(const std::string& line, const cricket::MediaType media_type, MediaContentDescription* media_desc, SdpParseError* error); static bool ParseRtcpFbAttribute(const std::string& line, const cricket::MediaType media_type, MediaContentDescription* media_desc, SdpParseError* error); static bool ParseIceOptions(const std::string& line, std::vector* transport_options, SdpParseError* error); static bool ParseExtmap(const std::string& line, RtpExtension* extmap, SdpParseError* error); static bool ParseFingerprintAttribute( const std::string& line, std::unique_ptr* fingerprint, SdpParseError* error); static bool ParseDtlsSetup(const std::string& line, cricket::ConnectionRole* role, SdpParseError* error); static bool ParseMsidAttribute(const std::string& line, std::vector* stream_ids, std::string* track_id, SdpParseError* error); static void RemoveInvalidRidDescriptions(const std::vector& payload_types, std::vector* rids); static SimulcastLayerList RemoveRidsFromSimulcastLayerList( const std::set& to_remove, const SimulcastLayerList& layers); static void RemoveInvalidRidsFromSimulcast( const std::vector& rids, SimulcastDescription* simulcast); // Helper functions // Below ParseFailed*** functions output the line that caused the parsing // failure and the detailed reason (`description`) of the failure to `error`. // The functions always return false so that they can be used directly in the // following way when error happens: // "return ParseFailed***(...);" // The line starting at `line_start` of `message` is the failing line. // The reason for the failure should be provided in the `description`. // An example of a description could be "unknown character". static bool ParseFailed(absl::string_view message, size_t line_start, std::string description, SdpParseError* error) { // Get the first line of `message` from `line_start`. absl::string_view first_line; size_t line_end = message.find(kNewLine, line_start); if (line_end != std::string::npos) { if (line_end > 0 && (message.at(line_end - 1) == kReturnChar)) { --line_end; } first_line = message.substr(line_start, (line_end - line_start)); } else { first_line = message.substr(line_start); } RTC_LOG(LS_ERROR) << "Failed to parse: \"" << first_line << "\". Reason: " << description; if (error) { // TODO(bugs.webrtc.org/13220): In C++17, we can use plain assignment, with // a string_view on the right hand side. error->line.assign(first_line.data(), first_line.size()); error->description = std::move(description); } return false; } // `line` is the failing line. The reason for the failure should be // provided in the `description`. static bool ParseFailed(absl::string_view line, std::string description, SdpParseError* error) { return ParseFailed(line, 0, std::move(description), error); } // Parses failure where the failing SDP line isn't know or there are multiple // failing lines. static bool ParseFailed(std::string description, SdpParseError* error) { return ParseFailed("", std::move(description), error); } // `line` is the failing line. The failure is due to the fact that `line` // doesn't have `expected_fields` fields. static bool ParseFailedExpectFieldNum(absl::string_view line, int expected_fields, SdpParseError* error) { rtc::StringBuilder description; description << "Expects " << expected_fields << " fields."; return ParseFailed(line, description.Release(), error); } // `line` is the failing line. The failure is due to the fact that `line` has // less than `expected_min_fields` fields. static bool ParseFailedExpectMinFieldNum(absl::string_view line, int expected_min_fields, SdpParseError* error) { rtc::StringBuilder description; description << "Expects at least " << expected_min_fields << " fields."; return ParseFailed(line, description.Release(), error); } // `line` is the failing line. The failure is due to the fact that it failed to // get the value of `attribute`. static bool ParseFailedGetValue(absl::string_view line, const std::string& attribute, SdpParseError* error) { rtc::StringBuilder description; description << "Failed to get the value of attribute: " << attribute; return ParseFailed(line, description.Release(), error); } // The line starting at `line_start` of `message` is the failing line. The // failure is due to the line type (e.g. the "m" part of the "m-line") // not matching what is expected. The expected line type should be // provided as `line_type`. static bool ParseFailedExpectLine(absl::string_view message, size_t line_start, const char line_type, absl::string_view line_value, SdpParseError* error) { rtc::StringBuilder description; description << "Expect line: " << std::string(1, line_type) << "=" << line_value; return ParseFailed(message, line_start, description.Release(), error); } static bool AddLine(const std::string& line, std::string* message) { if (!message) return false; message->append(line); message->append(kLineBreak); return true; } static bool GetLine(const std::string& message, size_t* pos, std::string* line) { size_t line_begin = *pos; size_t line_end = message.find(kNewLine, line_begin); if (line_end == std::string::npos) { return false; } // Update the new start position *pos = line_end + 1; if (line_end > 0 && (message.at(line_end - 1) == kReturnChar)) { --line_end; } *line = message.substr(line_begin, (line_end - line_begin)); const char* cline = line->c_str(); // RFC 4566 // An SDP session description consists of a number of lines of text of // the form: // = // where MUST be exactly one case-significant character and // is structured text whose format depends on . // Whitespace MUST NOT be used on either side of the "=" sign. // // However, an exception to the whitespace rule is made for "s=", since // RFC4566 also says: // // If a session has no meaningful name, the value "s= " SHOULD be used // (i.e., a single space as the session name). if (line->length() < 3 || !islower(cline[0]) || cline[1] != kSdpDelimiterEqualChar || (cline[0] != kLineTypeSessionName && cline[2] == kSdpDelimiterSpaceChar)) { *pos = line_begin; return false; } return true; } // Init `os` to "`type`=`value`". static void InitLine(const char type, const std::string& value, rtc::StringBuilder* os) { os->Clear(); *os << std::string(1, type) << kSdpDelimiterEqual << value; } // Init `os` to "a=`attribute`". static void InitAttrLine(const std::string& attribute, rtc::StringBuilder* os) { InitLine(kLineTypeAttributes, attribute, os); } // Writes a SDP attribute line based on `attribute` and `value` to `message`. static void AddAttributeLine(const std::string& attribute, int value, std::string* message) { rtc::StringBuilder os; InitAttrLine(attribute, &os); os << kSdpDelimiterColon << value; AddLine(os.str(), message); } static bool IsLineType(const std::string& message, const char type, size_t line_start) { if (message.size() < line_start + kLinePrefixLength) { return false; } const char* cmessage = message.c_str(); return (cmessage[line_start] == type && cmessage[line_start + 1] == kSdpDelimiterEqualChar); } static bool IsLineType(const std::string& line, const char type) { return IsLineType(line, type, 0); } static bool GetLineWithType(const std::string& message, size_t* pos, std::string* line, const char type) { if (!IsLineType(message, type, *pos)) { return false; } if (!GetLine(message, pos, line)) return false; return true; } static bool HasAttribute(const std::string& line, const std::string& attribute) { if (line.compare(kLinePrefixLength, attribute.size(), attribute) == 0) { // Make sure that the match is not only a partial match. If length of // strings doesn't match, the next character of the line must be ':' or ' '. // This function is also used for media descriptions (e.g., "m=audio 9..."), // hence the need to also allow space in the end. RTC_CHECK_LE(kLinePrefixLength + attribute.size(), line.size()); if ((kLinePrefixLength + attribute.size()) == line.size() || line[kLinePrefixLength + attribute.size()] == kSdpDelimiterColonChar || line[kLinePrefixLength + attribute.size()] == kSdpDelimiterSpaceChar) { return true; } } return false; } static bool AddSsrcLine(uint32_t ssrc_id, const std::string& attribute, const std::string& value, std::string* message) { // RFC 5576 // a=ssrc: : rtc::StringBuilder os; InitAttrLine(kAttributeSsrc, &os); os << kSdpDelimiterColon << ssrc_id << kSdpDelimiterSpace << attribute << kSdpDelimiterColon << value; return AddLine(os.str(), message); } // Get value only from :. static bool GetValue(const std::string& message, const std::string& attribute, std::string* value, SdpParseError* error) { std::string leftpart; if (!rtc::tokenize_first(message, kSdpDelimiterColonChar, &leftpart, value)) { return ParseFailedGetValue(message, attribute, error); } // The left part should end with the expected attribute. if (leftpart.length() < attribute.length() || leftpart.compare(leftpart.length() - attribute.length(), attribute.length(), attribute) != 0) { return ParseFailedGetValue(message, attribute, error); } return true; } // Get a single [token] from : static bool GetSingleTokenValue(const std::string& message, const std::string& attribute, std::string* value, SdpParseError* error) { if (!GetValue(message, attribute, value, error)) { return false; } if (!absl::c_all_of(absl::string_view(*value), IsTokenChar)) { rtc::StringBuilder description; description << "Illegal character found in the value of " << attribute; return ParseFailed(message, description.Release(), error); } return true; } static bool CaseInsensitiveFind(std::string str1, std::string str2) { absl::c_transform(str1, str1.begin(), ::tolower); absl::c_transform(str2, str2.begin(), ::tolower); return str1.find(str2) != std::string::npos; } template static bool GetValueFromString(const std::string& line, const std::string& s, T* t, SdpParseError* error) { if (!rtc::FromString(s, t)) { rtc::StringBuilder description; description << "Invalid value: " << s << "."; return ParseFailed(line, description.Release(), error); } return true; } static bool GetPayloadTypeFromString(const std::string& line, const std::string& s, int* payload_type, SdpParseError* error) { return GetValueFromString(line, s, payload_type, error) && cricket::IsValidRtpPayloadType(*payload_type); } // Creates a StreamParams track in the case when no SSRC lines are signaled. // This is a track that does not contain SSRCs and only contains // stream_ids/track_id if it's signaled with a=msid lines. void CreateTrackWithNoSsrcs(const std::vector& msid_stream_ids, const std::string& msid_track_id, const std::vector& rids, StreamParamsVec* tracks) { StreamParams track; if (msid_track_id.empty() && rids.empty()) { // We only create an unsignaled track if a=msid lines were signaled. RTC_LOG(LS_INFO) << "MSID not signaled, skipping creation of StreamParams"; return; } track.set_stream_ids(msid_stream_ids); track.id = msid_track_id; track.set_rids(rids); tracks->push_back(track); } // Creates the StreamParams tracks, for the case when SSRC lines are signaled. // `msid_stream_ids` and `msid_track_id` represent the stream/track ID from the // "a=msid" attribute, if it exists. They are empty if the attribute does not // exist. We prioritize getting stream_ids/track_ids signaled in a=msid lines. void CreateTracksFromSsrcInfos(const SsrcInfoVec& ssrc_infos, const std::vector& msid_stream_ids, const std::string& msid_track_id, StreamParamsVec* tracks, int msid_signaling) { RTC_DCHECK(tracks != NULL); for (const SsrcInfo& ssrc_info : ssrc_infos) { // According to https://tools.ietf.org/html/rfc5576#section-6.1, the CNAME // attribute is mandatory, but we relax that restriction. if (ssrc_info.cname.empty()) { RTC_LOG(LS_WARNING) << "CNAME attribute missing for SSRC " << ssrc_info.ssrc_id; } std::vector stream_ids; std::string track_id; if (msid_signaling & cricket::kMsidSignalingMediaSection) { // This is the case with Unified Plan SDP msid signaling. stream_ids = msid_stream_ids; track_id = msid_track_id; } else if (msid_signaling & cricket::kMsidSignalingSsrcAttribute) { // This is the case with Plan B SDP msid signaling. stream_ids.push_back(ssrc_info.stream_id); track_id = ssrc_info.track_id; } else if (!ssrc_info.mslabel.empty()) { // Since there's no a=msid or a=ssrc msid signaling, this is a sdp from // an older version of client that doesn't support msid. // In that case, we use the mslabel and label to construct the track. stream_ids.push_back(ssrc_info.mslabel); track_id = ssrc_info.label; } else { // Since no media streams isn't supported with older SDP signaling, we // use a default a stream id. stream_ids.push_back(kDefaultMsid); } // If a track ID wasn't populated from the SSRC attributes OR the // msid attribute, use default/random values. if (track_id.empty()) { // TODO(ronghuawu): What should we do if the track id doesn't appear? // Create random string (which will be used as track label later)? track_id = rtc::CreateRandomString(8); } auto track_it = absl::c_find_if( *tracks, [track_id](const StreamParams& track) { return track.id == track_id; }); if (track_it == tracks->end()) { // If we don't find an existing track, create a new one. tracks->push_back(StreamParams()); track_it = tracks->end() - 1; } StreamParams& track = *track_it; track.add_ssrc(ssrc_info.ssrc_id); track.cname = ssrc_info.cname; track.set_stream_ids(stream_ids); track.id = track_id; } } void GetMediaStreamIds(const ContentInfo* content, std::set* labels) { for (const StreamParams& stream_params : content->media_description()->streams()) { for (const std::string& stream_id : stream_params.stream_ids()) { labels->insert(stream_id); } } } // RFC 5245 // It is RECOMMENDED that default candidates be chosen based on the // likelihood of those candidates to work with the peer that is being // contacted. It is RECOMMENDED that relayed > reflexive > host. static const int kPreferenceUnknown = 0; static const int kPreferenceHost = 1; static const int kPreferenceReflexive = 2; static const int kPreferenceRelayed = 3; static int GetCandidatePreferenceFromType(const std::string& type) { int preference = kPreferenceUnknown; if (type == cricket::LOCAL_PORT_TYPE) { preference = kPreferenceHost; } else if (type == cricket::STUN_PORT_TYPE) { preference = kPreferenceReflexive; } else if (type == cricket::RELAY_PORT_TYPE) { preference = kPreferenceRelayed; } else { RTC_DCHECK_NOTREACHED(); } return preference; } // Get ip and port of the default destination from the `candidates` with the // given value of `component_id`. The default candidate should be the one most // likely to work, typically IPv4 relay. // RFC 5245 // The value of `component_id` currently supported are 1 (RTP) and 2 (RTCP). // TODO(deadbeef): Decide the default destination in webrtcsession and // pass it down via SessionDescription. static void GetDefaultDestination(const std::vector& candidates, int component_id, std::string* port, std::string* ip, std::string* addr_type) { *addr_type = kConnectionIpv4Addrtype; *port = kDummyPort; *ip = kDummyAddress; int current_preference = kPreferenceUnknown; int current_family = AF_UNSPEC; for (const Candidate& candidate : candidates) { if (candidate.component() != component_id) { continue; } // Default destination should be UDP only. if (candidate.protocol() != cricket::UDP_PROTOCOL_NAME) { continue; } const int preference = GetCandidatePreferenceFromType(candidate.type()); const int family = candidate.address().ipaddr().family(); // See if this candidate is more preferable then the current one if it's the // same family. Or if the current family is IPv4 already so we could safely // ignore all IPv6 ones. WebRTC bug 4269. // http://code.google.com/p/webrtc/issues/detail?id=4269 if ((preference <= current_preference && current_family == family) || (current_family == AF_INET && family == AF_INET6)) { continue; } if (family == AF_INET) { addr_type->assign(kConnectionIpv4Addrtype); } else if (family == AF_INET6) { addr_type->assign(kConnectionIpv6Addrtype); } current_preference = preference; current_family = family; *port = candidate.address().PortAsString(); *ip = candidate.address().ipaddr().ToString(); } } // Gets "a=rtcp" line if found default RTCP candidate from `candidates`. static std::string GetRtcpLine(const std::vector& candidates) { std::string rtcp_line, rtcp_port, rtcp_ip, addr_type; GetDefaultDestination(candidates, ICE_CANDIDATE_COMPONENT_RTCP, &rtcp_port, &rtcp_ip, &addr_type); // Found default RTCP candidate. // RFC 5245 // If the agent is utilizing RTCP, it MUST encode the RTCP candidate // using the a=rtcp attribute as defined in RFC 3605. // RFC 3605 // rtcp-attribute = "a=rtcp:" port [nettype space addrtype space // connection-address] CRLF rtc::StringBuilder os; InitAttrLine(kAttributeRtcp, &os); os << kSdpDelimiterColon << rtcp_port << " " << kConnectionNettype << " " << addr_type << " " << rtcp_ip; rtcp_line = os.str(); return rtcp_line; } // Get candidates according to the mline index from SessionDescriptionInterface. static void GetCandidatesByMindex(const SessionDescriptionInterface& desci, int mline_index, std::vector* candidates) { if (!candidates) { return; } const IceCandidateCollection* cc = desci.candidates(mline_index); for (size_t i = 0; i < cc->count(); ++i) { const IceCandidateInterface* candidate = cc->at(i); candidates->push_back(candidate->candidate()); } } static bool IsValidPort(int port) { return port >= 0 && port <= 65535; } std::string SdpSerialize(const JsepSessionDescription& jdesc) { const cricket::SessionDescription* desc = jdesc.description(); if (!desc) { return ""; } std::string message; // Session Description. AddLine(kSessionVersion, &message); // Session Origin // RFC 4566 // o= // rtc::StringBuilder os; InitLine(kLineTypeOrigin, kSessionOriginUsername, &os); const std::string& session_id = jdesc.session_id().empty() ? kSessionOriginSessionId : jdesc.session_id(); const std::string& session_version = jdesc.session_version().empty() ? kSessionOriginSessionVersion : jdesc.session_version(); os << " " << session_id << " " << session_version << " " << kSessionOriginNettype << " " << kSessionOriginAddrtype << " " << kSessionOriginAddress; AddLine(os.str(), &message); AddLine(kSessionName, &message); // Time Description. AddLine(kTimeDescription, &message); // BUNDLE Groups std::vector groups = desc->GetGroupsByName(cricket::GROUP_TYPE_BUNDLE); for (const cricket::ContentGroup* group : groups) { std::string group_line = kAttrGroup; RTC_DCHECK(group != NULL); for (const std::string& content_name : group->content_names()) { group_line.append(" "); group_line.append(content_name); } AddLine(group_line, &message); } // Mixed one- and two-byte header extension. if (desc->extmap_allow_mixed()) { InitAttrLine(kAttributeExtmapAllowMixed, &os); AddLine(os.str(), &message); } // MediaStream semantics InitAttrLine(kAttributeMsidSemantics, &os); os << kSdpDelimiterColon << " " << kMediaStreamSemantic; std::set media_stream_ids; const ContentInfo* audio_content = GetFirstAudioContent(desc); if (audio_content) GetMediaStreamIds(audio_content, &media_stream_ids); const ContentInfo* video_content = GetFirstVideoContent(desc); if (video_content) GetMediaStreamIds(video_content, &media_stream_ids); for (const std::string& id : media_stream_ids) { os << " " << id; } AddLine(os.str(), &message); // a=ice-lite // // TODO(deadbeef): It's weird that we need to iterate TransportInfos for // this, when it's a session-level attribute. It really should be moved to a // session-level structure like SessionDescription. for (const cricket::TransportInfo& transport : desc->transport_infos()) { if (transport.description.ice_mode == cricket::ICEMODE_LITE) { InitAttrLine(kAttributeIceLite, &os); AddLine(os.str(), &message); break; } } // Preserve the order of the media contents. int mline_index = -1; for (const ContentInfo& content : desc->contents()) { std::vector candidates; GetCandidatesByMindex(jdesc, ++mline_index, &candidates); BuildMediaDescription(&content, desc->GetTransportInfoByName(content.name), content.media_description()->type(), candidates, desc->msid_signaling(), &message); } return message; } // Serializes the passed in IceCandidateInterface to a SDP string. // candidate - The candidate to be serialized. std::string SdpSerializeCandidate(const IceCandidateInterface& candidate) { return SdpSerializeCandidate(candidate.candidate()); } // Serializes a cricket Candidate. std::string SdpSerializeCandidate(const cricket::Candidate& candidate) { std::string message; std::vector candidates(1, candidate); BuildCandidate(candidates, true, &message); // From WebRTC draft section 4.8.1.1 candidate-attribute will be // just candidate: not a=candidate:CRLF RTC_DCHECK(message.find("a=") == 0); message.erase(0, 2); RTC_DCHECK(message.find(kLineBreak) == message.size() - 2); message.resize(message.size() - 2); return message; } bool SdpDeserialize(const std::string& message, JsepSessionDescription* jdesc, SdpParseError* error) { std::string session_id; std::string session_version; TransportDescription session_td("", ""); RtpHeaderExtensions session_extmaps; rtc::SocketAddress session_connection_addr; auto desc = std::make_unique(); size_t current_pos = 0; // Session Description if (!ParseSessionDescription(message, ¤t_pos, &session_id, &session_version, &session_td, &session_extmaps, &session_connection_addr, desc.get(), error)) { return false; } // Media Description std::vector> candidates; if (!ParseMediaDescription(message, session_td, session_extmaps, ¤t_pos, session_connection_addr, desc.get(), &candidates, error)) { return false; } jdesc->Initialize(std::move(desc), session_id, session_version); for (const auto& candidate : candidates) { jdesc->AddCandidate(candidate.get()); } return true; } bool SdpDeserializeCandidate(const std::string& message, JsepIceCandidate* jcandidate, SdpParseError* error) { RTC_DCHECK(jcandidate != NULL); Candidate candidate; if (!ParseCandidate(message, &candidate, error, true)) { return false; } jcandidate->SetCandidate(candidate); return true; } bool SdpDeserializeCandidate(const std::string& transport_name, const std::string& message, cricket::Candidate* candidate, SdpParseError* error) { RTC_DCHECK(candidate != nullptr); if (!ParseCandidate(message, candidate, error, true)) { return false; } candidate->set_transport_name(transport_name); return true; } bool ParseCandidate(const std::string& message, Candidate* candidate, SdpParseError* error, bool is_raw) { RTC_DCHECK(candidate != NULL); // Get the first line from `message`. std::string first_line = message; size_t pos = 0; GetLine(message, &pos, &first_line); // Makes sure `message` contains only one line. if (message.size() > first_line.size()) { std::string left, right; if (rtc::tokenize_first(message, kNewLineChar, &left, &right) && !right.empty()) { return ParseFailed(message, 0, "Expect one line only", error); } } // From WebRTC draft section 4.8.1.1 candidate-attribute should be // candidate: when trickled, but we still support // a=candidate:CRLF for backward compatibility and for parsing a line // from the SDP. if (IsLineType(first_line, kLineTypeAttributes)) { first_line = first_line.substr(kLinePrefixLength); } std::string attribute_candidate; std::string candidate_value; // `first_line` must be in the form of "candidate:". if (!rtc::tokenize_first(first_line, kSdpDelimiterColonChar, &attribute_candidate, &candidate_value) || attribute_candidate != kAttributeCandidate) { if (is_raw) { rtc::StringBuilder description; description << "Expect line: " << kAttributeCandidate << ":" ""; return ParseFailed(first_line, 0, description.Release(), error); } else { return ParseFailedExpectLine(first_line, 0, kLineTypeAttributes, kAttributeCandidate, error); } } std::vector fields; rtc::split(candidate_value, kSdpDelimiterSpaceChar, &fields); // RFC 5245 // a=candidate: // typ // [raddr ] [rport ] // *(SP extension-att-name SP extension-att-value) const size_t expected_min_fields = 8; if (fields.size() < expected_min_fields || (fields[6] != kAttributeCandidateTyp)) { return ParseFailedExpectMinFieldNum(first_line, expected_min_fields, error); } const std::string& foundation = fields[0]; int component_id = 0; if (!GetValueFromString(first_line, fields[1], &component_id, error)) { return false; } const std::string& transport = fields[2]; uint32_t priority = 0; if (!GetValueFromString(first_line, fields[3], &priority, error)) { return false; } const std::string& connection_address = fields[4]; int port = 0; if (!GetValueFromString(first_line, fields[5], &port, error)) { return false; } if (!IsValidPort(port)) { return ParseFailed(first_line, "Invalid port number.", error); } SocketAddress address(connection_address, port); cricket::ProtocolType protocol; if (!StringToProto(transport.c_str(), &protocol)) { return ParseFailed(first_line, "Unsupported transport type.", error); } bool tcp_protocol = false; switch (protocol) { // Supported protocols. case cricket::PROTO_UDP: break; case cricket::PROTO_TCP: case cricket::PROTO_SSLTCP: tcp_protocol = true; break; default: return ParseFailed(first_line, "Unsupported transport type.", error); } std::string candidate_type; const std::string& type = fields[7]; if (type == kCandidateHost) { candidate_type = cricket::LOCAL_PORT_TYPE; } else if (type == kCandidateSrflx) { candidate_type = cricket::STUN_PORT_TYPE; } else if (type == kCandidateRelay) { candidate_type = cricket::RELAY_PORT_TYPE; } else if (type == kCandidatePrflx) { candidate_type = cricket::PRFLX_PORT_TYPE; } else { return ParseFailed(first_line, "Unsupported candidate type.", error); } size_t current_position = expected_min_fields; SocketAddress related_address; // The 2 optional fields for related address // [raddr ] [rport ] if (fields.size() >= (current_position + 2) && fields[current_position] == kAttributeCandidateRaddr) { related_address.SetIP(fields[++current_position]); ++current_position; } if (fields.size() >= (current_position + 2) && fields[current_position] == kAttributeCandidateRport) { int port = 0; if (!GetValueFromString(first_line, fields[++current_position], &port, error)) { return false; } if (!IsValidPort(port)) { return ParseFailed(first_line, "Invalid port number.", error); } related_address.SetPort(port); ++current_position; } // If this is a TCP candidate, it has additional extension as defined in // RFC 6544. std::string tcptype; if (fields.size() >= (current_position + 2) && fields[current_position] == kTcpCandidateType) { tcptype = fields[++current_position]; ++current_position; if (tcptype != cricket::TCPTYPE_ACTIVE_STR && tcptype != cricket::TCPTYPE_PASSIVE_STR && tcptype != cricket::TCPTYPE_SIMOPEN_STR) { return ParseFailed(first_line, "Invalid TCP candidate type.", error); } if (!tcp_protocol) { return ParseFailed(first_line, "Invalid non-TCP candidate", error); } } else if (tcp_protocol) { // We allow the tcptype to be missing, for backwards compatibility, // treating it as a passive candidate. // TODO(bugs.webrtc.org/11466): Treat a missing tcptype as an error? tcptype = cricket::TCPTYPE_PASSIVE_STR; } // Extension // Though non-standard, we support the ICE ufrag and pwd being signaled on // the candidate to avoid issues with confusing which generation a candidate // belongs to when trickling multiple generations at the same time. std::string username; std::string password; uint32_t generation = 0; uint16_t network_id = 0; uint16_t network_cost = 0; for (size_t i = current_position; i + 1 < fields.size(); ++i) { // RFC 5245 // *(SP extension-att-name SP extension-att-value) if (fields[i] == kAttributeCandidateGeneration) { if (!GetValueFromString(first_line, fields[++i], &generation, error)) { return false; } } else if (fields[i] == kAttributeCandidateUfrag) { username = fields[++i]; } else if (fields[i] == kAttributeCandidatePwd) { password = fields[++i]; } else if (fields[i] == kAttributeCandidateNetworkId) { if (!GetValueFromString(first_line, fields[++i], &network_id, error)) { return false; } } else if (fields[i] == kAttributeCandidateNetworkCost) { if (!GetValueFromString(first_line, fields[++i], &network_cost, error)) { return false; } network_cost = std::min(network_cost, rtc::kNetworkCostMax); } else { // Skip the unknown extension. ++i; } } *candidate = Candidate(component_id, cricket::ProtoToString(protocol), address, priority, username, password, candidate_type, generation, foundation, network_id, network_cost); candidate->set_related_address(related_address); candidate->set_tcptype(tcptype); return true; } bool ParseIceOptions(const std::string& line, std::vector* transport_options, SdpParseError* error) { std::string ice_options; if (!GetValue(line, kAttributeIceOption, &ice_options, error)) { return false; } std::vector fields; rtc::split(ice_options, kSdpDelimiterSpaceChar, &fields); for (size_t i = 0; i < fields.size(); ++i) { transport_options->push_back(fields[i]); } return true; } bool ParseSctpPort(const std::string& line, int* sctp_port, SdpParseError* error) { // draft-ietf-mmusic-sctp-sdp-26 // a=sctp-port std::vector fields; const size_t expected_min_fields = 2; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterColonChar, &fields); if (fields.size() < expected_min_fields) { fields.resize(0); rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); } if (fields.size() < expected_min_fields) { return ParseFailedExpectMinFieldNum(line, expected_min_fields, error); } if (!rtc::FromString(fields[1], sctp_port)) { return ParseFailed(line, "Invalid sctp port value.", error); } return true; } bool ParseSctpMaxMessageSize(const std::string& line, int* max_message_size, SdpParseError* error) { // draft-ietf-mmusic-sctp-sdp-26 // a=max-message-size:199999 std::vector fields; const size_t expected_min_fields = 2; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterColonChar, &fields); if (fields.size() < expected_min_fields) { return ParseFailedExpectMinFieldNum(line, expected_min_fields, error); } if (!rtc::FromString(fields[1], max_message_size)) { return ParseFailed(line, "Invalid SCTP max message size.", error); } return true; } bool ParseExtmap(const std::string& line, RtpExtension* extmap, SdpParseError* error) { // RFC 5285 // a=extmap:["/"] std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); const size_t expected_min_fields = 2; if (fields.size() < expected_min_fields) { return ParseFailedExpectMinFieldNum(line, expected_min_fields, error); } std::string uri = fields[1]; std::string value_direction; if (!GetValue(fields[0], kAttributeExtmap, &value_direction, error)) { return false; } std::vector sub_fields; rtc::split(value_direction, kSdpDelimiterSlashChar, &sub_fields); int value = 0; if (!GetValueFromString(line, sub_fields[0], &value, error)) { return false; } bool encrypted = false; if (uri == RtpExtension::kEncryptHeaderExtensionsUri) { // RFC 6904 // a=extmap:] urn:ietf:params:rtp-hdrext:encrypt // const size_t expected_min_fields_encrypted = expected_min_fields + 1; if (fields.size() < expected_min_fields_encrypted) { return ParseFailedExpectMinFieldNum(line, expected_min_fields_encrypted, error); } encrypted = true; uri = fields[2]; if (uri == RtpExtension::kEncryptHeaderExtensionsUri) { return ParseFailed(line, "Recursive encrypted header.", error); } } *extmap = RtpExtension(uri, value, encrypted); return true; } static void BuildSctpContentAttributes( std::string* message, const cricket::SctpDataContentDescription* data_desc) { rtc::StringBuilder os; if (data_desc->use_sctpmap()) { // draft-ietf-mmusic-sctp-sdp-04 // a=sctpmap:sctpmap-number protocol [streams] rtc::StringBuilder os; InitAttrLine(kAttributeSctpmap, &os); os << kSdpDelimiterColon << data_desc->port() << kSdpDelimiterSpace << kDefaultSctpmapProtocol << kSdpDelimiterSpace << cricket::kMaxSctpStreams; AddLine(os.str(), message); } else { // draft-ietf-mmusic-sctp-sdp-23 // a=sctp-port: InitAttrLine(kAttributeSctpPort, &os); os << kSdpDelimiterColon << data_desc->port(); AddLine(os.str(), message); if (data_desc->max_message_size() != kDefaultSctpMaxMessageSize) { InitAttrLine(kAttributeMaxMessageSize, &os); os << kSdpDelimiterColon << data_desc->max_message_size(); AddLine(os.str(), message); } } } void BuildMediaDescription(const ContentInfo* content_info, const TransportInfo* transport_info, const cricket::MediaType media_type, const std::vector& candidates, int msid_signaling, std::string* message) { RTC_DCHECK(message != NULL); if (content_info == NULL || message == NULL) { return; } rtc::StringBuilder os; const MediaContentDescription* media_desc = content_info->media_description(); RTC_DCHECK(media_desc); // RFC 4566 // m= // fmt is a list of payload type numbers that MAY be used in the session. std::string type; std::string fmt; if (media_type == cricket::MEDIA_TYPE_VIDEO) { type = kMediaTypeVideo; const VideoContentDescription* video_desc = media_desc->as_video(); for (const cricket::VideoCodec& codec : video_desc->codecs()) { fmt.append(" "); fmt.append(rtc::ToString(codec.id)); } } else if (media_type == cricket::MEDIA_TYPE_AUDIO) { type = kMediaTypeAudio; const AudioContentDescription* audio_desc = media_desc->as_audio(); for (const cricket::AudioCodec& codec : audio_desc->codecs()) { fmt.append(" "); fmt.append(rtc::ToString(codec.id)); } } else if (media_type == cricket::MEDIA_TYPE_DATA) { type = kMediaTypeData; const cricket::SctpDataContentDescription* sctp_data_desc = media_desc->as_sctp(); if (sctp_data_desc) { fmt.append(" "); if (sctp_data_desc->use_sctpmap()) { fmt.append(rtc::ToString(sctp_data_desc->port())); } else { fmt.append(kDefaultSctpmapProtocol); } } else { RTC_DCHECK_NOTREACHED() << "Data description without SCTP"; } } else if (media_type == cricket::MEDIA_TYPE_UNSUPPORTED) { const UnsupportedContentDescription* unsupported_desc = media_desc->as_unsupported(); type = unsupported_desc->media_type(); } else { RTC_DCHECK_NOTREACHED(); } // The fmt must never be empty. If no codecs are found, set the fmt attribute // to 0. if (fmt.empty()) { fmt = " 0"; } // The port number in the m line will be updated later when associated with // the candidates. // // A port value of 0 indicates that the m= section is rejected. // RFC 3264 // To reject an offered stream, the port number in the corresponding stream in // the answer MUST be set to zero. // // However, the BUNDLE draft adds a new meaning to port zero, when used along // with a=bundle-only. std::string port = kDummyPort; if (content_info->rejected || content_info->bundle_only) { port = kMediaPortRejected; } else if (!media_desc->connection_address().IsNil()) { port = rtc::ToString(media_desc->connection_address().port()); } rtc::SSLFingerprint* fp = (transport_info) ? transport_info->description.identity_fingerprint.get() : NULL; // Add the m and c lines. InitLine(kLineTypeMedia, type, &os); os << " " << port << " " << media_desc->protocol() << fmt; AddLine(os.str(), message); InitLine(kLineTypeConnection, kConnectionNettype, &os); if (media_desc->connection_address().IsNil()) { os << " " << kConnectionIpv4Addrtype << " " << kDummyAddress; } else if (media_desc->connection_address().family() == AF_INET) { os << " " << kConnectionIpv4Addrtype << " " << media_desc->connection_address().ipaddr().ToString(); } else if (media_desc->connection_address().family() == AF_INET6) { os << " " << kConnectionIpv6Addrtype << " " << media_desc->connection_address().ipaddr().ToString(); } else { os << " " << kConnectionIpv4Addrtype << " " << kDummyAddress; } AddLine(os.str(), message); // RFC 4566 // b=AS: or // b=TIAS: int bandwidth = media_desc->bandwidth(); std::string bandwidth_type = media_desc->bandwidth_type(); if (bandwidth_type == kApplicationSpecificBandwidth && bandwidth >= 1000) { InitLine(kLineTypeSessionBandwidth, bandwidth_type, &os); bandwidth /= 1000; os << kSdpDelimiterColon << bandwidth; AddLine(os.str(), message); } else if (bandwidth_type == kTransportSpecificBandwidth && bandwidth > 0) { InitLine(kLineTypeSessionBandwidth, bandwidth_type, &os); os << kSdpDelimiterColon << bandwidth; AddLine(os.str(), message); } // Add the a=bundle-only line. if (content_info->bundle_only) { InitAttrLine(kAttributeBundleOnly, &os); AddLine(os.str(), message); } // Add the a=rtcp line. if (cricket::IsRtpProtocol(media_desc->protocol())) { std::string rtcp_line = GetRtcpLine(candidates); if (!rtcp_line.empty()) { AddLine(rtcp_line, message); } } // Build the a=candidate lines. We don't include ufrag and pwd in the // candidates in the SDP to avoid redundancy. BuildCandidate(candidates, false, message); // Use the transport_info to build the media level ice-ufrag and ice-pwd. if (transport_info) { // RFC 5245 // ice-pwd-att = "ice-pwd" ":" password // ice-ufrag-att = "ice-ufrag" ":" ufrag // ice-ufrag if (!transport_info->description.ice_ufrag.empty()) { InitAttrLine(kAttributeIceUfrag, &os); os << kSdpDelimiterColon << transport_info->description.ice_ufrag; AddLine(os.str(), message); } // ice-pwd if (!transport_info->description.ice_pwd.empty()) { InitAttrLine(kAttributeIcePwd, &os); os << kSdpDelimiterColon << transport_info->description.ice_pwd; AddLine(os.str(), message); } // draft-petithuguenin-mmusic-ice-attributes-level-03 BuildIceOptions(transport_info->description.transport_options, message); // RFC 4572 // fingerprint-attribute = // "fingerprint" ":" hash-func SP fingerprint if (fp) { // Insert the fingerprint attribute. InitAttrLine(kAttributeFingerprint, &os); os << kSdpDelimiterColon << fp->algorithm << kSdpDelimiterSpace << fp->GetRfc4572Fingerprint(); AddLine(os.str(), message); // Inserting setup attribute. if (transport_info->description.connection_role != cricket::CONNECTIONROLE_NONE) { // Making sure we are not using "passive" mode. cricket::ConnectionRole role = transport_info->description.connection_role; std::string dtls_role_str; const bool success = cricket::ConnectionRoleToString(role, &dtls_role_str); RTC_DCHECK(success); InitAttrLine(kAttributeSetup, &os); os << kSdpDelimiterColon << dtls_role_str; AddLine(os.str(), message); } } } // RFC 3388 // mid-attribute = "a=mid:" identification-tag // identification-tag = token // Use the content name as the mid identification-tag. InitAttrLine(kAttributeMid, &os); os << kSdpDelimiterColon << content_info->name; AddLine(os.str(), message); if (cricket::IsDtlsSctp(media_desc->protocol())) { const cricket::SctpDataContentDescription* data_desc = media_desc->as_sctp(); BuildSctpContentAttributes(message, data_desc); } else if (cricket::IsRtpProtocol(media_desc->protocol())) { BuildRtpContentAttributes(media_desc, media_type, msid_signaling, message); } } void BuildRtpContentAttributes(const MediaContentDescription* media_desc, const cricket::MediaType media_type, int msid_signaling, std::string* message) { SdpSerializer serializer; rtc::StringBuilder os; // RFC 8285 // a=extmap-allow-mixed // The attribute MUST be either on session level or media level. We support // responding on both levels, however, we don't respond on media level if it's // set on session level. if (media_desc->extmap_allow_mixed_enum() == MediaContentDescription::kMedia) { InitAttrLine(kAttributeExtmapAllowMixed, &os); AddLine(os.str(), message); } // RFC 8285 // a=extmap:["/"] // The definitions MUST be either all session level or all media level. This // implementation uses all media level. for (size_t i = 0; i < media_desc->rtp_header_extensions().size(); ++i) { const RtpExtension& extension = media_desc->rtp_header_extensions()[i]; InitAttrLine(kAttributeExtmap, &os); os << kSdpDelimiterColon << extension.id; if (extension.encrypt) { os << kSdpDelimiterSpace << RtpExtension::kEncryptHeaderExtensionsUri; } os << kSdpDelimiterSpace << extension.uri; AddLine(os.str(), message); } // RFC 3264 // a=sendrecv || a=sendonly || a=sendrecv || a=inactive switch (media_desc->direction()) { // Special case that for sdp purposes should be treated same as inactive. case RtpTransceiverDirection::kStopped: case RtpTransceiverDirection::kInactive: InitAttrLine(kAttributeInactive, &os); break; case RtpTransceiverDirection::kSendOnly: InitAttrLine(kAttributeSendOnly, &os); break; case RtpTransceiverDirection::kRecvOnly: InitAttrLine(kAttributeRecvOnly, &os); break; case RtpTransceiverDirection::kSendRecv: InitAttrLine(kAttributeSendRecv, &os); break; default: RTC_DCHECK_NOTREACHED(); InitAttrLine(kAttributeSendRecv, &os); break; } AddLine(os.str(), message); // Specified in https://datatracker.ietf.org/doc/draft-ietf-mmusic-msid/16/ // a=msid: // The msid-id is a 1*64 token char representing the media stream id, and the // msid-appdata is a 1*64 token char representing the track id. There is a // line for every media stream, with a special msid-id value of "-" // representing no streams. The value of "msid-appdata" MUST be identical for // all lines. if (msid_signaling & cricket::kMsidSignalingMediaSection) { const StreamParamsVec& streams = media_desc->streams(); if (streams.size() == 1u) { const StreamParams& track = streams[0]; std::vector stream_ids = track.stream_ids(); if (stream_ids.empty()) { stream_ids.push_back(kNoStreamMsid); } for (const std::string& stream_id : stream_ids) { InitAttrLine(kAttributeMsid, &os); os << kSdpDelimiterColon << stream_id << kSdpDelimiterSpace << track.id; AddLine(os.str(), message); } } else if (streams.size() > 1u) { RTC_LOG(LS_WARNING) << "Trying to serialize Unified Plan SDP with more than " "one track in a media section. Omitting 'a=msid'."; } } // RFC 5761 // a=rtcp-mux if (media_desc->rtcp_mux()) { InitAttrLine(kAttributeRtcpMux, &os); AddLine(os.str(), message); } // RFC 5506 // a=rtcp-rsize if (media_desc->rtcp_reduced_size()) { InitAttrLine(kAttributeRtcpReducedSize, &os); AddLine(os.str(), message); } if (media_desc->conference_mode()) { InitAttrLine(kAttributeXGoogleFlag, &os); os << kSdpDelimiterColon << kValueConference; AddLine(os.str(), message); } if (media_desc->remote_estimate()) { InitAttrLine(kAttributeRtcpRemoteEstimate, &os); AddLine(os.str(), message); } // RFC 4568 // a=crypto: [] for (const CryptoParams& crypto_params : media_desc->cryptos()) { InitAttrLine(kAttributeCrypto, &os); os << kSdpDelimiterColon << crypto_params.tag << " " << crypto_params.cipher_suite << " " << crypto_params.key_params; if (!crypto_params.session_params.empty()) { os << " " << crypto_params.session_params; } AddLine(os.str(), message); } // RFC 4566 // a=rtpmap: / // [/] BuildRtpMap(media_desc, media_type, message); for (const StreamParams& track : media_desc->streams()) { // Build the ssrc-group lines. for (const SsrcGroup& ssrc_group : track.ssrc_groups) { // RFC 5576 // a=ssrc-group: ... if (ssrc_group.ssrcs.empty()) { continue; } InitAttrLine(kAttributeSsrcGroup, &os); os << kSdpDelimiterColon << ssrc_group.semantics; for (uint32_t ssrc : ssrc_group.ssrcs) { os << kSdpDelimiterSpace << rtc::ToString(ssrc); } AddLine(os.str(), message); } // Build the ssrc lines for each ssrc. for (uint32_t ssrc : track.ssrcs) { // RFC 5576 // a=ssrc: cname: AddSsrcLine(ssrc, kSsrcAttributeCname, track.cname, message); if (msid_signaling & cricket::kMsidSignalingSsrcAttribute) { // draft-alvestrand-mmusic-msid-00 // a=ssrc: msid:identifier [appdata] // The appdata consists of the "id" attribute of a MediaStreamTrack, // which corresponds to the "id" attribute of StreamParams. // Since a=ssrc msid signaling is used in Plan B SDP semantics, and // multiple stream ids are not supported for Plan B, we are only adding // a line for the first media stream id here. const std::string& track_stream_id = track.first_stream_id(); // We use a special msid-id value of "-" to represent no streams, // for Unified Plan compatibility. Plan B will always have a // track_stream_id. const std::string& stream_id = track_stream_id.empty() ? kNoStreamMsid : track_stream_id; InitAttrLine(kAttributeSsrc, &os); os << kSdpDelimiterColon << ssrc << kSdpDelimiterSpace << kSsrcAttributeMsid << kSdpDelimiterColon << stream_id << kSdpDelimiterSpace << track.id; AddLine(os.str(), message); // TODO(ronghuawu): Remove below code which is for backward // compatibility. // draft-alvestrand-rtcweb-mid-01 // a=ssrc: mslabel: // The label isn't yet defined. // a=ssrc: label: AddSsrcLine(ssrc, kSsrcAttributeMslabel, stream_id, message); AddSsrcLine(ssrc, kSSrcAttributeLabel, track.id, message); } } // Build the rid lines for each layer of the track for (const RidDescription& rid_description : track.rids()) { InitAttrLine(kAttributeRid, &os); os << kSdpDelimiterColon << serializer.SerializeRidDescription(rid_description); AddLine(os.str(), message); } } for (const RidDescription& rid_description : media_desc->receive_rids()) { InitAttrLine(kAttributeRid, &os); os << kSdpDelimiterColon << serializer.SerializeRidDescription(rid_description); AddLine(os.str(), message); } // Simulcast (a=simulcast) // https://tools.ietf.org/html/draft-ietf-mmusic-sdp-simulcast-13#section-5.1 if (media_desc->HasSimulcast()) { const auto& simulcast = media_desc->simulcast_description(); InitAttrLine(kAttributeSimulcast, &os); os << kSdpDelimiterColon << serializer.SerializeSimulcastDescription(simulcast); AddLine(os.str(), message); } } void WriteFmtpHeader(int payload_type, rtc::StringBuilder* os) { // fmtp header: a=fmtp:`payload_type` // Add a=fmtp InitAttrLine(kAttributeFmtp, os); // Add :`payload_type` *os << kSdpDelimiterColon << payload_type; } void WritePacketizationHeader(int payload_type, rtc::StringBuilder* os) { // packetization header: a=packetization:`payload_type` // Add a=packetization InitAttrLine(kAttributePacketization, os); // Add :`payload_type` *os << kSdpDelimiterColon << payload_type; } void WriteRtcpFbHeader(int payload_type, rtc::StringBuilder* os) { // rtcp-fb header: a=rtcp-fb:`payload_type` // /> // Add a=rtcp-fb InitAttrLine(kAttributeRtcpFb, os); // Add : *os << kSdpDelimiterColon; if (payload_type == kWildcardPayloadType) { *os << "*"; } else { *os << payload_type; } } void WriteFmtpParameter(const std::string& parameter_name, const std::string& parameter_value, rtc::StringBuilder* os) { if (parameter_name == "") { // RFC 2198 and RFC 4733 don't use key-value pairs. *os << parameter_value; } else { // fmtp parameters: `parameter_name`=`parameter_value` *os << parameter_name << kSdpDelimiterEqual << parameter_value; } } bool IsFmtpParam(const std::string& name) { // RFC 4855, section 3 specifies the mapping of media format parameters to SDP // parameters. Only ptime, maxptime, channels and rate are placed outside of // the fmtp line. In WebRTC, channels and rate are already handled separately // and thus not included in the CodecParameterMap. return name != kCodecParamPTime && name != kCodecParamMaxPTime; } bool WriteFmtpParameters(const cricket::CodecParameterMap& parameters, rtc::StringBuilder* os) { bool empty = true; const char* delimiter = ""; // No delimiter before first parameter. for (const auto& entry : parameters) { const std::string& key = entry.first; const std::string& value = entry.second; if (IsFmtpParam(key)) { *os << delimiter; // A semicolon before each subsequent parameter. delimiter = kSdpDelimiterSemicolon; WriteFmtpParameter(key, value, os); empty = false; } } return !empty; } template void AddFmtpLine(const T& codec, std::string* message) { rtc::StringBuilder os; WriteFmtpHeader(codec.id, &os); os << kSdpDelimiterSpace; // Create FMTP line and check that it's nonempty. if (WriteFmtpParameters(codec.params, &os)) { AddLine(os.str(), message); } return; } template void AddPacketizationLine(const T& codec, std::string* message) { if (!codec.packetization) { return; } rtc::StringBuilder os; WritePacketizationHeader(codec.id, &os); os << " " << *codec.packetization; AddLine(os.str(), message); } template void AddRtcpFbLines(const T& codec, std::string* message) { for (const cricket::FeedbackParam& param : codec.feedback_params.params()) { rtc::StringBuilder os; WriteRtcpFbHeader(codec.id, &os); os << " " << param.id(); if (!param.param().empty()) { os << " " << param.param(); } AddLine(os.str(), message); } } bool GetMinValue(const std::vector& values, int* value) { if (values.empty()) { return false; } auto it = absl::c_min_element(values); *value = *it; return true; } bool GetParameter(const std::string& name, const cricket::CodecParameterMap& params, int* value) { std::map::const_iterator found = params.find(name); if (found == params.end()) { return false; } if (!rtc::FromString(found->second, value)) { return false; } return true; } void BuildRtpMap(const MediaContentDescription* media_desc, const cricket::MediaType media_type, std::string* message) { RTC_DCHECK(message != NULL); RTC_DCHECK(media_desc != NULL); rtc::StringBuilder os; if (media_type == cricket::MEDIA_TYPE_VIDEO) { for (const cricket::VideoCodec& codec : media_desc->as_video()->codecs()) { // RFC 4566 // a=rtpmap: / // [/] if (codec.id != kWildcardPayloadType) { InitAttrLine(kAttributeRtpmap, &os); os << kSdpDelimiterColon << codec.id << " " << codec.name << "/" << cricket::kVideoCodecClockrate; AddLine(os.str(), message); } AddPacketizationLine(codec, message); AddRtcpFbLines(codec, message); AddFmtpLine(codec, message); } } else if (media_type == cricket::MEDIA_TYPE_AUDIO) { std::vector ptimes; std::vector maxptimes; int max_minptime = 0; for (const cricket::AudioCodec& codec : media_desc->as_audio()->codecs()) { RTC_DCHECK(!codec.name.empty()); // RFC 4566 // a=rtpmap: / // [/] InitAttrLine(kAttributeRtpmap, &os); os << kSdpDelimiterColon << codec.id << " "; os << codec.name << "/" << codec.clockrate; if (codec.channels != 1) { os << "/" << codec.channels; } AddLine(os.str(), message); AddRtcpFbLines(codec, message); AddFmtpLine(codec, message); int minptime = 0; if (GetParameter(kCodecParamMinPTime, codec.params, &minptime)) { max_minptime = std::max(minptime, max_minptime); } int ptime; if (GetParameter(kCodecParamPTime, codec.params, &ptime)) { ptimes.push_back(ptime); } int maxptime; if (GetParameter(kCodecParamMaxPTime, codec.params, &maxptime)) { maxptimes.push_back(maxptime); } } // Populate the maxptime attribute with the smallest maxptime of all codecs // under the same m-line. int min_maxptime = INT_MAX; if (GetMinValue(maxptimes, &min_maxptime)) { AddAttributeLine(kCodecParamMaxPTime, min_maxptime, message); } RTC_DCHECK(min_maxptime > max_minptime); // Populate the ptime attribute with the smallest ptime or the largest // minptime, whichever is the largest, for all codecs under the same m-line. int ptime = INT_MAX; if (GetMinValue(ptimes, &ptime)) { ptime = std::min(ptime, min_maxptime); ptime = std::max(ptime, max_minptime); AddAttributeLine(kCodecParamPTime, ptime, message); } } } void BuildCandidate(const std::vector& candidates, bool include_ufrag, std::string* message) { rtc::StringBuilder os; for (const Candidate& candidate : candidates) { // RFC 5245 // a=candidate: // typ // [raddr ] [rport ] // *(SP extension-att-name SP extension-att-value) std::string type; // Map the cricket candidate type to "host" / "srflx" / "prflx" / "relay" if (candidate.type() == cricket::LOCAL_PORT_TYPE) { type = kCandidateHost; } else if (candidate.type() == cricket::STUN_PORT_TYPE) { type = kCandidateSrflx; } else if (candidate.type() == cricket::RELAY_PORT_TYPE) { type = kCandidateRelay; } else if (candidate.type() == cricket::PRFLX_PORT_TYPE) { type = kCandidatePrflx; // Peer reflexive candidate may be signaled for being removed. } else { RTC_DCHECK_NOTREACHED(); // Never write out candidates if we don't know the type. continue; } InitAttrLine(kAttributeCandidate, &os); os << kSdpDelimiterColon << candidate.foundation() << " " << candidate.component() << " " << candidate.protocol() << " " << candidate.priority() << " " << (candidate.address().ipaddr().IsNil() ? candidate.address().hostname() : candidate.address().ipaddr().ToString()) << " " << candidate.address().PortAsString() << " " << kAttributeCandidateTyp << " " << type << " "; // Related address if (!candidate.related_address().IsNil()) { os << kAttributeCandidateRaddr << " " << candidate.related_address().ipaddr().ToString() << " " << kAttributeCandidateRport << " " << candidate.related_address().PortAsString() << " "; } // Note that we allow the tcptype to be missing, for backwards // compatibility; the implementation treats this as a passive candidate. // TODO(bugs.webrtc.org/11466): Treat a missing tcptype as an error? if (candidate.protocol() == cricket::TCP_PROTOCOL_NAME && !candidate.tcptype().empty()) { os << kTcpCandidateType << " " << candidate.tcptype() << " "; } // Extensions os << kAttributeCandidateGeneration << " " << candidate.generation(); if (include_ufrag && !candidate.username().empty()) { os << " " << kAttributeCandidateUfrag << " " << candidate.username(); } if (candidate.network_id() > 0) { os << " " << kAttributeCandidateNetworkId << " " << candidate.network_id(); } if (candidate.network_cost() > 0) { os << " " << kAttributeCandidateNetworkCost << " " << candidate.network_cost(); } AddLine(os.str(), message); } } void BuildIceOptions(const std::vector& transport_options, std::string* message) { if (!transport_options.empty()) { rtc::StringBuilder os; InitAttrLine(kAttributeIceOption, &os); os << kSdpDelimiterColon << transport_options[0]; for (size_t i = 1; i < transport_options.size(); ++i) { os << kSdpDelimiterSpace << transport_options[i]; } AddLine(os.str(), message); } } bool ParseConnectionData(const std::string& line, rtc::SocketAddress* addr, SdpParseError* error) { // Parse the line from left to right. std::string token; std::string rightpart; // RFC 4566 // c= // Skip the "c=" if (!rtc::tokenize_first(line, kSdpDelimiterEqualChar, &token, &rightpart)) { return ParseFailed(line, "Failed to parse the network type.", error); } // Extract and verify the if (!rtc::tokenize_first(rightpart, kSdpDelimiterSpaceChar, &token, &rightpart) || token != kConnectionNettype) { return ParseFailed(line, "Failed to parse the connection data. The network type " "is not currently supported.", error); } // Extract the "" and "". if (!rtc::tokenize_first(rightpart, kSdpDelimiterSpaceChar, &token, &rightpart)) { return ParseFailed(line, "Failed to parse the address type.", error); } // The rightpart part should be the IP address without the slash which is used // for multicast. if (rightpart.find('/') != std::string::npos) { return ParseFailed(line, "Failed to parse the connection data. Multicast is not " "currently supported.", error); } addr->SetIP(rightpart); // Verify that the addrtype matches the type of the parsed address. if ((addr->family() == AF_INET && token != "IP4") || (addr->family() == AF_INET6 && token != "IP6")) { addr->Clear(); return ParseFailed( line, "Failed to parse the connection data. The address type is mismatching.", error); } return true; } bool ParseSessionDescription(const std::string& message, size_t* pos, std::string* session_id, std::string* session_version, TransportDescription* session_td, RtpHeaderExtensions* session_extmaps, rtc::SocketAddress* connection_addr, cricket::SessionDescription* desc, SdpParseError* error) { std::string line; desc->set_msid_supported(false); desc->set_extmap_allow_mixed(false); // RFC 4566 // v= (protocol version) if (!GetLineWithType(message, pos, &line, kLineTypeVersion)) { return ParseFailedExpectLine(message, *pos, kLineTypeVersion, std::string(), error); } // RFC 4566 // o= // if (!GetLineWithType(message, pos, &line, kLineTypeOrigin)) { return ParseFailedExpectLine(message, *pos, kLineTypeOrigin, std::string(), error); } std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); const size_t expected_fields = 6; if (fields.size() != expected_fields) { return ParseFailedExpectFieldNum(line, expected_fields, error); } *session_id = fields[1]; *session_version = fields[2]; // RFC 4566 // s= (session name) if (!GetLineWithType(message, pos, &line, kLineTypeSessionName)) { return ParseFailedExpectLine(message, *pos, kLineTypeSessionName, std::string(), error); } // absl::optional lines // Those are the optional lines, so shouldn't return false if not present. // RFC 4566 // i=* (session information) GetLineWithType(message, pos, &line, kLineTypeSessionInfo); // RFC 4566 // u=* (URI of description) GetLineWithType(message, pos, &line, kLineTypeSessionUri); // RFC 4566 // e=* (email address) GetLineWithType(message, pos, &line, kLineTypeSessionEmail); // RFC 4566 // p=* (phone number) GetLineWithType(message, pos, &line, kLineTypeSessionPhone); // RFC 4566 // c=* (connection information -- not required if included in // all media) if (GetLineWithType(message, pos, &line, kLineTypeConnection)) { if (!ParseConnectionData(line, connection_addr, error)) { return false; } } // RFC 4566 // b=* (zero or more bandwidth information lines) while (GetLineWithType(message, pos, &line, kLineTypeSessionBandwidth)) { // By pass zero or more b lines. } // RFC 4566 // One or more time descriptions ("t=" and "r=" lines; see below) // t= (time the session is active) // r=* (zero or more repeat times) // Ensure there's at least one time description if (!GetLineWithType(message, pos, &line, kLineTypeTiming)) { return ParseFailedExpectLine(message, *pos, kLineTypeTiming, std::string(), error); } while (GetLineWithType(message, pos, &line, kLineTypeRepeatTimes)) { // By pass zero or more r lines. } // Go through the rest of the time descriptions while (GetLineWithType(message, pos, &line, kLineTypeTiming)) { while (GetLineWithType(message, pos, &line, kLineTypeRepeatTimes)) { // By pass zero or more r lines. } } // RFC 4566 // z=* (time zone adjustments) GetLineWithType(message, pos, &line, kLineTypeTimeZone); // RFC 4566 // k=* (encryption key) GetLineWithType(message, pos, &line, kLineTypeEncryptionKey); // RFC 4566 // a=* (zero or more session attribute lines) while (GetLineWithType(message, pos, &line, kLineTypeAttributes)) { if (HasAttribute(line, kAttributeGroup)) { if (!ParseGroupAttribute(line, desc, error)) { return false; } } else if (HasAttribute(line, kAttributeIceUfrag)) { if (!GetValue(line, kAttributeIceUfrag, &(session_td->ice_ufrag), error)) { return false; } } else if (HasAttribute(line, kAttributeIcePwd)) { if (!GetValue(line, kAttributeIcePwd, &(session_td->ice_pwd), error)) { return false; } } else if (HasAttribute(line, kAttributeIceLite)) { session_td->ice_mode = cricket::ICEMODE_LITE; } else if (HasAttribute(line, kAttributeIceOption)) { if (!ParseIceOptions(line, &(session_td->transport_options), error)) { return false; } } else if (HasAttribute(line, kAttributeFingerprint)) { if (session_td->identity_fingerprint.get()) { return ParseFailed( line, "Can't have multiple fingerprint attributes at the same level.", error); } std::unique_ptr fingerprint; if (!ParseFingerprintAttribute(line, &fingerprint, error)) { return false; } session_td->identity_fingerprint = std::move(fingerprint); } else if (HasAttribute(line, kAttributeSetup)) { if (!ParseDtlsSetup(line, &(session_td->connection_role), error)) { return false; } } else if (HasAttribute(line, kAttributeMsidSemantics)) { std::string semantics; if (!GetValue(line, kAttributeMsidSemantics, &semantics, error)) { return false; } desc->set_msid_supported( CaseInsensitiveFind(semantics, kMediaStreamSemantic)); } else if (HasAttribute(line, kAttributeExtmapAllowMixed)) { desc->set_extmap_allow_mixed(true); } else if (HasAttribute(line, kAttributeExtmap)) { RtpExtension extmap; if (!ParseExtmap(line, &extmap, error)) { return false; } session_extmaps->push_back(extmap); } } return true; } bool ParseGroupAttribute(const std::string& line, cricket::SessionDescription* desc, SdpParseError* error) { RTC_DCHECK(desc != NULL); // RFC 5888 and draft-holmberg-mmusic-sdp-bundle-negotiation-00 // a=group:BUNDLE video voice std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); std::string semantics; if (!GetValue(fields[0], kAttributeGroup, &semantics, error)) { return false; } cricket::ContentGroup group(semantics); for (size_t i = 1; i < fields.size(); ++i) { group.AddContentName(fields[i]); } desc->AddGroup(group); return true; } static bool ParseFingerprintAttribute( const std::string& line, std::unique_ptr* fingerprint, SdpParseError* error) { std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); const size_t expected_fields = 2; if (fields.size() != expected_fields) { return ParseFailedExpectFieldNum(line, expected_fields, error); } // The first field here is "fingerprint:. std::string algorithm; if (!GetValue(fields[0], kAttributeFingerprint, &algorithm, error)) { return false; } // Downcase the algorithm. Note that we don't need to downcase the // fingerprint because hex_decode can handle upper-case. absl::c_transform(algorithm, algorithm.begin(), ::tolower); // The second field is the digest value. De-hexify it. *fingerprint = rtc::SSLFingerprint::CreateUniqueFromRfc4572(algorithm, fields[1]); if (!*fingerprint) { return ParseFailed(line, "Failed to create fingerprint from the digest.", error); } return true; } static bool ParseDtlsSetup(const std::string& line, cricket::ConnectionRole* role, SdpParseError* error) { // setup-attr = "a=setup:" role // role = "active" / "passive" / "actpass" / "holdconn" std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterColonChar, &fields); const size_t expected_fields = 2; if (fields.size() != expected_fields) { return ParseFailedExpectFieldNum(line, expected_fields, error); } std::string role_str = fields[1]; if (!cricket::StringToConnectionRole(role_str, role)) { return ParseFailed(line, "Invalid attribute value.", error); } return true; } static bool ParseMsidAttribute(const std::string& line, std::vector* stream_ids, std::string* track_id, SdpParseError* error) { // https://datatracker.ietf.org/doc/draft-ietf-mmusic-msid/16/ // a=msid: // msid-value = msid-id [ SP msid-appdata ] // msid-id = 1*64token-char ; see RFC 4566 // msid-appdata = 1*64token-char ; see RFC 4566 std::string field1; std::string new_stream_id; std::string new_track_id; if (!rtc::tokenize_first(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &field1, &new_track_id)) { const size_t expected_fields = 2; return ParseFailedExpectFieldNum(line, expected_fields, error); } if (new_track_id.empty()) { return ParseFailed(line, "Missing track ID in msid attribute.", error); } // All track ids should be the same within an m section in a Unified Plan SDP. if (!track_id->empty() && new_track_id.compare(*track_id) != 0) { return ParseFailed( line, "Two different track IDs in msid attribute in one m= section", error); } *track_id = new_track_id; // msid: if (!GetValue(field1, kAttributeMsid, &new_stream_id, error)) { return false; } if (new_stream_id.empty()) { return ParseFailed(line, "Missing stream ID in msid attribute.", error); } // The special value "-" indicates "no MediaStream". if (new_stream_id.compare(kNoStreamMsid) != 0) { stream_ids->push_back(new_stream_id); } return true; } static void RemoveInvalidRidDescriptions(const std::vector& payload_types, std::vector* rids) { RTC_DCHECK(rids); std::set to_remove; std::set unique_rids; // Check the rids to see which ones should be removed. for (RidDescription& rid : *rids) { // In the case of a duplicate, the entire "a=rid" line, and all "a=rid" // lines with rid-ids that duplicate this line, are discarded and MUST NOT // be included in the SDP Answer. auto pair = unique_rids.insert(rid.rid); // Insert will "fail" if element already exists. if (!pair.second) { to_remove.insert(rid.rid); continue; } // If the "a=rid" line contains a "pt=", the list of payload types // is verified against the list of valid payload types for the media // section (that is, those listed on the "m=" line). Any PT missing // from the "m=" line is discarded from the set of values in the // "pt=". If no values are left in the "pt=" parameter after this // processing, then the "a=rid" line is discarded. if (rid.payload_types.empty()) { // If formats were not specified, rid should not be removed. continue; } // Note: Spec does not mention how to handle duplicate formats. // Media section does not handle duplicates either. std::set removed_formats; for (int payload_type : rid.payload_types) { if (!absl::c_linear_search(payload_types, payload_type)) { removed_formats.insert(payload_type); } } rid.payload_types.erase( std::remove_if(rid.payload_types.begin(), rid.payload_types.end(), [&removed_formats](int format) { return removed_formats.count(format) > 0; }), rid.payload_types.end()); // If all formats were removed then remove the rid alogether. if (rid.payload_types.empty()) { to_remove.insert(rid.rid); } } // Remove every rid description that appears in the to_remove list. if (!to_remove.empty()) { rids->erase(std::remove_if(rids->begin(), rids->end(), [&to_remove](const RidDescription& rid) { return to_remove.count(rid.rid) > 0; }), rids->end()); } } // Create a new list (because SimulcastLayerList is immutable) without any // layers that have a rid in the to_remove list. // If a group of alternatives is empty after removing layers, the group should // be removed altogether. static SimulcastLayerList RemoveRidsFromSimulcastLayerList( const std::set& to_remove, const SimulcastLayerList& layers) { SimulcastLayerList result; for (const std::vector& vector : layers) { std::vector new_layers; for (const SimulcastLayer& layer : vector) { if (to_remove.find(layer.rid) == to_remove.end()) { new_layers.push_back(layer); } } // If all layers were removed, do not add an entry. if (!new_layers.empty()) { result.AddLayerWithAlternatives(new_layers); } } return result; } // Will remove Simulcast Layers if: // 1. They appear in both send and receive directions. // 2. They do not appear in the list of `valid_rids`. static void RemoveInvalidRidsFromSimulcast( const std::vector& valid_rids, SimulcastDescription* simulcast) { RTC_DCHECK(simulcast); std::set to_remove; std::vector all_send_layers = simulcast->send_layers().GetAllLayers(); std::vector all_receive_layers = simulcast->receive_layers().GetAllLayers(); // If a rid appears in both send and receive directions, remove it from both. // This algorithm runs in O(n^2) time, but for small n (as is the case with // simulcast layers) it should still perform well. for (const SimulcastLayer& send_layer : all_send_layers) { if (absl::c_any_of(all_receive_layers, [&send_layer](const SimulcastLayer& layer) { return layer.rid == send_layer.rid; })) { to_remove.insert(send_layer.rid); } } // Add any rid that is not in the valid list to the remove set. for (const SimulcastLayer& send_layer : all_send_layers) { if (absl::c_none_of(valid_rids, [&send_layer](const RidDescription& rid) { return send_layer.rid == rid.rid && rid.direction == cricket::RidDirection::kSend; })) { to_remove.insert(send_layer.rid); } } // Add any rid that is not in the valid list to the remove set. for (const SimulcastLayer& receive_layer : all_receive_layers) { if (absl::c_none_of( valid_rids, [&receive_layer](const RidDescription& rid) { return receive_layer.rid == rid.rid && rid.direction == cricket::RidDirection::kReceive; })) { to_remove.insert(receive_layer.rid); } } simulcast->send_layers() = RemoveRidsFromSimulcastLayerList(to_remove, simulcast->send_layers()); simulcast->receive_layers() = RemoveRidsFromSimulcastLayerList(to_remove, simulcast->receive_layers()); } // RFC 3551 // PT encoding media type clock rate channels // name (Hz) // 0 PCMU A 8,000 1 // 1 reserved A // 2 reserved A // 3 GSM A 8,000 1 // 4 G723 A 8,000 1 // 5 DVI4 A 8,000 1 // 6 DVI4 A 16,000 1 // 7 LPC A 8,000 1 // 8 PCMA A 8,000 1 // 9 G722 A 8,000 1 // 10 L16 A 44,100 2 // 11 L16 A 44,100 1 // 12 QCELP A 8,000 1 // 13 CN A 8,000 1 // 14 MPA A 90,000 (see text) // 15 G728 A 8,000 1 // 16 DVI4 A 11,025 1 // 17 DVI4 A 22,050 1 // 18 G729 A 8,000 1 struct StaticPayloadAudioCodec { const char* name; int clockrate; size_t channels; }; static const StaticPayloadAudioCodec kStaticPayloadAudioCodecs[] = { {"PCMU", 8000, 1}, {"reserved", 0, 0}, {"reserved", 0, 0}, {"GSM", 8000, 1}, {"G723", 8000, 1}, {"DVI4", 8000, 1}, {"DVI4", 16000, 1}, {"LPC", 8000, 1}, {"PCMA", 8000, 1}, {"G722", 8000, 1}, {"L16", 44100, 2}, {"L16", 44100, 1}, {"QCELP", 8000, 1}, {"CN", 8000, 1}, {"MPA", 90000, 1}, {"G728", 8000, 1}, {"DVI4", 11025, 1}, {"DVI4", 22050, 1}, {"G729", 8000, 1}, }; void MaybeCreateStaticPayloadAudioCodecs(const std::vector& fmts, AudioContentDescription* media_desc) { if (!media_desc) { return; } RTC_DCHECK(media_desc->codecs().empty()); for (int payload_type : fmts) { if (!media_desc->HasCodec(payload_type) && payload_type >= 0 && static_cast(payload_type) < arraysize(kStaticPayloadAudioCodecs)) { std::string encoding_name = kStaticPayloadAudioCodecs[payload_type].name; int clock_rate = kStaticPayloadAudioCodecs[payload_type].clockrate; size_t channels = kStaticPayloadAudioCodecs[payload_type].channels; media_desc->AddCodec(cricket::AudioCodec(payload_type, encoding_name, clock_rate, 0, channels)); } } } template static std::unique_ptr ParseContentDescription( const std::string& message, const cricket::MediaType media_type, int mline_index, const std::string& protocol, const std::vector& payload_types, size_t* pos, std::string* content_name, bool* bundle_only, int* msid_signaling, TransportDescription* transport, std::vector>* candidates, webrtc::SdpParseError* error) { auto media_desc = std::make_unique(); media_desc->set_extmap_allow_mixed_enum(MediaContentDescription::kNo); if (!ParseContent(message, media_type, mline_index, protocol, payload_types, pos, content_name, bundle_only, msid_signaling, media_desc.get(), transport, candidates, error)) { return nullptr; } // Sort the codecs according to the m-line fmt list. std::unordered_map payload_type_preferences; // "size + 1" so that the lowest preference payload type has a preference of // 1, which is greater than the default (0) for payload types not in the fmt // list. int preference = static_cast(payload_types.size() + 1); for (int pt : payload_types) { payload_type_preferences[pt] = preference--; } std::vector codecs = media_desc->codecs(); absl::c_sort( codecs, [&payload_type_preferences](const typename C::CodecType& a, const typename C::CodecType& b) { return payload_type_preferences[a.id] > payload_type_preferences[b.id]; }); media_desc->set_codecs(codecs); return media_desc; } bool ParseMediaDescription( const std::string& message, const TransportDescription& session_td, const RtpHeaderExtensions& session_extmaps, size_t* pos, const rtc::SocketAddress& session_connection_addr, cricket::SessionDescription* desc, std::vector>* candidates, SdpParseError* error) { RTC_DCHECK(desc != NULL); std::string line; int mline_index = -1; int msid_signaling = 0; // Zero or more media descriptions // RFC 4566 // m= while (GetLineWithType(message, pos, &line, kLineTypeMedia)) { ++mline_index; std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); const size_t expected_min_fields = 4; if (fields.size() < expected_min_fields) { return ParseFailedExpectMinFieldNum(line, expected_min_fields, error); } bool port_rejected = false; // RFC 3264 // To reject an offered stream, the port number in the corresponding stream // in the answer MUST be set to zero. if (fields[1] == kMediaPortRejected) { port_rejected = true; } int port = 0; if (!rtc::FromString(fields[1], &port) || !IsValidPort(port)) { return ParseFailed(line, "The port number is invalid", error); } const std::string& protocol = fields[2]; // std::vector payload_types; if (cricket::IsRtpProtocol(protocol)) { for (size_t j = 3; j < fields.size(); ++j) { int pl = 0; if (!GetPayloadTypeFromString(line, fields[j], &pl, error)) { return false; } payload_types.push_back(pl); } } // Make a temporary TransportDescription based on `session_td`. // Some of this gets overwritten by ParseContent. TransportDescription transport( session_td.transport_options, session_td.ice_ufrag, session_td.ice_pwd, session_td.ice_mode, session_td.connection_role, session_td.identity_fingerprint.get()); std::unique_ptr content; std::string content_name; bool bundle_only = false; int section_msid_signaling = 0; const std::string& media_type = fields[0]; if ((media_type == kMediaTypeVideo || media_type == kMediaTypeAudio) && !cricket::IsRtpProtocol(protocol)) { return ParseFailed(line, "Unsupported protocol for media type", error); } if (media_type == kMediaTypeVideo) { content = ParseContentDescription( message, cricket::MEDIA_TYPE_VIDEO, mline_index, protocol, payload_types, pos, &content_name, &bundle_only, §ion_msid_signaling, &transport, candidates, error); } else if (media_type == kMediaTypeAudio) { content = ParseContentDescription( message, cricket::MEDIA_TYPE_AUDIO, mline_index, protocol, payload_types, pos, &content_name, &bundle_only, §ion_msid_signaling, &transport, candidates, error); } else if (media_type == kMediaTypeData) { if (cricket::IsDtlsSctp(protocol)) { // The draft-03 format is: // m=application DTLS/SCTP ... // use_sctpmap should be false. // The draft-26 format is: // m=application UDP/DTLS/SCTP webrtc-datachannel // use_sctpmap should be false. auto data_desc = std::make_unique(); // Default max message size is 64K // according to draft-ietf-mmusic-sctp-sdp-26 data_desc->set_max_message_size(kDefaultSctpMaxMessageSize); int p; if (rtc::FromString(fields[3], &p)) { data_desc->set_port(p); } else if (fields[3] == kDefaultSctpmapProtocol) { data_desc->set_use_sctpmap(false); } if (!ParseContent(message, cricket::MEDIA_TYPE_DATA, mline_index, protocol, payload_types, pos, &content_name, &bundle_only, §ion_msid_signaling, data_desc.get(), &transport, candidates, error)) { return false; } data_desc->set_protocol(protocol); content = std::move(data_desc); } else { return ParseFailed(line, "Unsupported protocol for media type", error); } } else { RTC_LOG(LS_WARNING) << "Unsupported media type: " << line; auto unsupported_desc = std::make_unique(media_type); if (!ParseContent(message, cricket::MEDIA_TYPE_UNSUPPORTED, mline_index, protocol, payload_types, pos, &content_name, &bundle_only, §ion_msid_signaling, unsupported_desc.get(), &transport, candidates, error)) { return false; } unsupported_desc->set_protocol(protocol); content = std::move(unsupported_desc); } if (!content.get()) { // ParseContentDescription returns NULL if failed. return false; } msid_signaling |= section_msid_signaling; bool content_rejected = false; // A port of 0 is not interpreted as a rejected m= section when it's // used along with a=bundle-only. if (bundle_only) { if (!port_rejected) { // Usage of bundle-only with a nonzero port is unspecified. So just // ignore bundle-only if we see this. bundle_only = false; RTC_LOG(LS_WARNING) << "a=bundle-only attribute observed with a nonzero " "port; this usage is unspecified so the attribute is being " "ignored."; } } else { // If not using bundle-only, interpret port 0 in the normal way; the m= // section is being rejected. content_rejected = port_rejected; } if (content->as_unsupported()) { content_rejected = true; } else if (cricket::IsRtpProtocol(protocol) && !content->as_sctp()) { content->set_protocol(protocol); // Set the extmap. if (!session_extmaps.empty() && !content->rtp_header_extensions().empty()) { return ParseFailed("", "The a=extmap MUST be either all session level or " "all media level.", error); } for (size_t i = 0; i < session_extmaps.size(); ++i) { content->AddRtpHeaderExtension(session_extmaps[i]); } } else if (content->as_sctp()) { // Do nothing, it's OK } else { RTC_LOG(LS_WARNING) << "Parse failed with unknown protocol " << protocol; return false; } // Use the session level connection address if the media level addresses are // not specified. rtc::SocketAddress address; address = content->connection_address().IsNil() ? session_connection_addr : content->connection_address(); address.SetPort(port); content->set_connection_address(address); desc->AddContent(content_name, cricket::IsDtlsSctp(protocol) ? MediaProtocolType::kSctp : MediaProtocolType::kRtp, content_rejected, bundle_only, std::move(content)); // Create TransportInfo with the media level "ice-pwd" and "ice-ufrag". desc->AddTransportInfo(TransportInfo(content_name, transport)); } desc->set_msid_signaling(msid_signaling); size_t end_of_message = message.size(); if (mline_index == -1 && *pos != end_of_message) { ParseFailed(message, *pos, "Expects m line.", error); return false; } return true; } bool VerifyCodec(const cricket::Codec& codec) { // Codec has not been populated correctly unless the name has been set. This // can happen if an SDP has an fmtp or rtcp-fb with a payload type but doesn't // have a corresponding "rtpmap" line. return !codec.name.empty(); } bool VerifyAudioCodecs(const AudioContentDescription* audio_desc) { return absl::c_all_of(audio_desc->codecs(), &VerifyCodec); } bool VerifyVideoCodecs(const VideoContentDescription* video_desc) { return absl::c_all_of(video_desc->codecs(), &VerifyCodec); } void AddParameters(const cricket::CodecParameterMap& parameters, cricket::Codec* codec) { for (const auto& entry : parameters) { const std::string& key = entry.first; const std::string& value = entry.second; codec->SetParam(key, value); } } void AddFeedbackParameter(const cricket::FeedbackParam& feedback_param, cricket::Codec* codec) { codec->AddFeedbackParam(feedback_param); } void AddFeedbackParameters(const cricket::FeedbackParams& feedback_params, cricket::Codec* codec) { for (const cricket::FeedbackParam& param : feedback_params.params()) { codec->AddFeedbackParam(param); } } // Gets the current codec setting associated with `payload_type`. If there // is no Codec associated with that payload type it returns an empty codec // with that payload type. template T GetCodecWithPayloadType(const std::vector& codecs, int payload_type) { const T* codec = FindCodecById(codecs, payload_type); if (codec) return *codec; // Return empty codec with `payload_type`. T ret_val; ret_val.id = payload_type; return ret_val; } // Updates or creates a new codec entry in the audio description. template void AddOrReplaceCodec(MediaContentDescription* content_desc, const U& codec) { T* desc = static_cast(content_desc); std::vector codecs = desc->codecs(); bool found = false; for (U& existing_codec : codecs) { if (codec.id == existing_codec.id) { // Overwrite existing codec with the new codec. existing_codec = codec; found = true; break; } } if (!found) { desc->AddCodec(codec); return; } desc->set_codecs(codecs); } // Adds or updates existing codec corresponding to `payload_type` according // to `parameters`. template void UpdateCodec(MediaContentDescription* content_desc, int payload_type, const cricket::CodecParameterMap& parameters) { // Codec might already have been populated (from rtpmap). U new_codec = GetCodecWithPayloadType(static_cast(content_desc)->codecs(), payload_type); AddParameters(parameters, &new_codec); AddOrReplaceCodec(content_desc, new_codec); } // Adds or updates existing codec corresponding to `payload_type` according // to `feedback_param`. template void UpdateCodec(MediaContentDescription* content_desc, int payload_type, const cricket::FeedbackParam& feedback_param) { // Codec might already have been populated (from rtpmap). U new_codec = GetCodecWithPayloadType(static_cast(content_desc)->codecs(), payload_type); AddFeedbackParameter(feedback_param, &new_codec); AddOrReplaceCodec(content_desc, new_codec); } // Adds or updates existing video codec corresponding to `payload_type` // according to `packetization`. void UpdateVideoCodecPacketization(VideoContentDescription* video_desc, int payload_type, const std::string& packetization) { if (packetization != cricket::kPacketizationParamRaw) { // Ignore unsupported packetization attribute. return; } // Codec might already have been populated (from rtpmap). cricket::VideoCodec codec = GetCodecWithPayloadType(video_desc->codecs(), payload_type); codec.packetization = packetization; AddOrReplaceCodec(video_desc, codec); } template bool PopWildcardCodec(std::vector* codecs, T* wildcard_codec) { for (auto iter = codecs->begin(); iter != codecs->end(); ++iter) { if (iter->id == kWildcardPayloadType) { *wildcard_codec = *iter; codecs->erase(iter); return true; } } return false; } template void UpdateFromWildcardCodecs(cricket::MediaContentDescriptionImpl* desc) { auto codecs = desc->codecs(); T wildcard_codec; if (!PopWildcardCodec(&codecs, &wildcard_codec)) { return; } for (auto& codec : codecs) { AddFeedbackParameters(wildcard_codec.feedback_params, &codec); } desc->set_codecs(codecs); } void AddAudioAttribute(const std::string& name, const std::string& value, AudioContentDescription* audio_desc) { if (value.empty()) { return; } std::vector codecs = audio_desc->codecs(); for (cricket::AudioCodec& codec : codecs) { codec.params[name] = value; } audio_desc->set_codecs(codecs); } bool ParseContent(const std::string& message, const cricket::MediaType media_type, int mline_index, const std::string& protocol, const std::vector& payload_types, size_t* pos, std::string* content_name, bool* bundle_only, int* msid_signaling, MediaContentDescription* media_desc, TransportDescription* transport, std::vector>* candidates, SdpParseError* error) { RTC_DCHECK(media_desc != NULL); RTC_DCHECK(content_name != NULL); RTC_DCHECK(transport != NULL); if (media_type == cricket::MEDIA_TYPE_AUDIO) { MaybeCreateStaticPayloadAudioCodecs(payload_types, media_desc->as_audio()); } // The media level "ice-ufrag" and "ice-pwd". // The candidates before update the media level "ice-pwd" and "ice-ufrag". Candidates candidates_orig; std::string line; std::string mline_id; // Tracks created out of the ssrc attributes. StreamParamsVec tracks; SsrcInfoVec ssrc_infos; SsrcGroupVec ssrc_groups; std::string maxptime_as_string; std::string ptime_as_string; std::vector stream_ids; std::string track_id; SdpSerializer deserializer; std::vector rids; SimulcastDescription simulcast; // Loop until the next m line while (!IsLineType(message, kLineTypeMedia, *pos)) { if (!GetLine(message, pos, &line)) { if (*pos >= message.size()) { break; // Done parsing } else { return ParseFailed(message, *pos, "Invalid SDP line.", error); } } // RFC 4566 // b=* (zero or more bandwidth information lines) if (IsLineType(line, kLineTypeSessionBandwidth)) { std::string bandwidth; std::string bandwidth_type; if (!rtc::tokenize_first(line.substr(kLinePrefixLength), kSdpDelimiterColonChar, &bandwidth_type, &bandwidth)) { return ParseFailed( line, "b= syntax error, does not match b=:.", error); } if (!(bandwidth_type == kApplicationSpecificBandwidth || bandwidth_type == kTransportSpecificBandwidth)) { // Ignore unknown bandwidth types. continue; } int b = 0; if (!GetValueFromString(line, bandwidth, &b, error)) { return false; } // TODO(deadbeef): Historically, applications may be setting a value // of -1 to mean "unset any previously set bandwidth limit", even // though ommitting the "b=AS" entirely will do just that. Once we've // transitioned applications to doing the right thing, it would be // better to treat this as a hard error instead of just ignoring it. if (bandwidth_type == kApplicationSpecificBandwidth && b == -1) { RTC_LOG(LS_WARNING) << "Ignoring \"b=AS:-1\"; will be treated as \"no " "bandwidth limit\"."; continue; } if (b < 0) { return ParseFailed( line, "b=" + bandwidth_type + " value can't be negative.", error); } // Convert values. Prevent integer overflow. if (bandwidth_type == kApplicationSpecificBandwidth) { b = std::min(b, INT_MAX / 1000) * 1000; } else { b = std::min(b, INT_MAX); } media_desc->set_bandwidth(b); media_desc->set_bandwidth_type(bandwidth_type); continue; } // Parse the media level connection data. if (IsLineType(line, kLineTypeConnection)) { rtc::SocketAddress addr; if (!ParseConnectionData(line, &addr, error)) { return false; } media_desc->set_connection_address(addr); continue; } if (!IsLineType(line, kLineTypeAttributes)) { // TODO(deadbeef): Handle other lines if needed. RTC_LOG(LS_VERBOSE) << "Ignored line: " << line; continue; } // Handle attributes common to SCTP and RTP. if (HasAttribute(line, kAttributeMid)) { // RFC 3388 // mid-attribute = "a=mid:" identification-tag // identification-tag = token // Use the mid identification-tag as the content name. if (!GetSingleTokenValue(line, kAttributeMid, &mline_id, error)) { return false; } *content_name = mline_id; } else if (HasAttribute(line, kAttributeBundleOnly)) { *bundle_only = true; } else if (HasAttribute(line, kAttributeCandidate)) { Candidate candidate; if (!ParseCandidate(line, &candidate, error, false)) { return false; } // ParseCandidate will parse non-standard ufrag and password attributes, // since it's used for candidate trickling, but we only want to process // the "a=ice-ufrag"/"a=ice-pwd" values in a session description, so // strip them off at this point. candidate.set_username(std::string()); candidate.set_password(std::string()); candidates_orig.push_back(candidate); } else if (HasAttribute(line, kAttributeIceUfrag)) { if (!GetValue(line, kAttributeIceUfrag, &transport->ice_ufrag, error)) { return false; } } else if (HasAttribute(line, kAttributeIcePwd)) { if (!GetValue(line, kAttributeIcePwd, &transport->ice_pwd, error)) { return false; } } else if (HasAttribute(line, kAttributeIceOption)) { if (!ParseIceOptions(line, &transport->transport_options, error)) { return false; } } else if (HasAttribute(line, kAttributeFmtp)) { if (!ParseFmtpAttributes(line, media_type, media_desc, error)) { return false; } } else if (HasAttribute(line, kAttributeFingerprint)) { std::unique_ptr fingerprint; if (!ParseFingerprintAttribute(line, &fingerprint, error)) { return false; } transport->identity_fingerprint = std::move(fingerprint); } else if (HasAttribute(line, kAttributeSetup)) { if (!ParseDtlsSetup(line, &(transport->connection_role), error)) { return false; } } else if (cricket::IsDtlsSctp(protocol) && media_type == cricket::MEDIA_TYPE_DATA) { // // SCTP specific attributes // if (HasAttribute(line, kAttributeSctpPort)) { if (media_desc->as_sctp()->use_sctpmap()) { return ParseFailed( line, "sctp-port attribute can't be used with sctpmap.", error); } int sctp_port; if (!ParseSctpPort(line, &sctp_port, error)) { return false; } media_desc->as_sctp()->set_port(sctp_port); } else if (HasAttribute(line, kAttributeMaxMessageSize)) { int max_message_size; if (!ParseSctpMaxMessageSize(line, &max_message_size, error)) { return false; } media_desc->as_sctp()->set_max_message_size(max_message_size); } else if (HasAttribute(line, kAttributeSctpmap)) { // Ignore a=sctpmap: from early versions of draft-ietf-mmusic-sctp-sdp continue; } } else if (cricket::IsRtpProtocol(protocol)) { // // RTP specific attributes // if (HasAttribute(line, kAttributeRtcpMux)) { media_desc->set_rtcp_mux(true); } else if (HasAttribute(line, kAttributeRtcpReducedSize)) { media_desc->set_rtcp_reduced_size(true); } else if (HasAttribute(line, kAttributeRtcpRemoteEstimate)) { media_desc->set_remote_estimate(true); } else if (HasAttribute(line, kAttributeSsrcGroup)) { if (!ParseSsrcGroupAttribute(line, &ssrc_groups, error)) { return false; } } else if (HasAttribute(line, kAttributeSsrc)) { if (!ParseSsrcAttribute(line, &ssrc_infos, msid_signaling, error)) { return false; } } else if (HasAttribute(line, kAttributeCrypto)) { if (!ParseCryptoAttribute(line, media_desc, error)) { return false; } } else if (HasAttribute(line, kAttributeRtpmap)) { if (!ParseRtpmapAttribute(line, media_type, payload_types, media_desc, error)) { return false; } } else if (HasAttribute(line, kCodecParamMaxPTime)) { if (!GetValue(line, kCodecParamMaxPTime, &maxptime_as_string, error)) { return false; } } else if (HasAttribute(line, kAttributePacketization)) { if (!ParsePacketizationAttribute(line, media_type, media_desc, error)) { return false; } } else if (HasAttribute(line, kAttributeRtcpFb)) { if (!ParseRtcpFbAttribute(line, media_type, media_desc, error)) { return false; } } else if (HasAttribute(line, kCodecParamPTime)) { if (!GetValue(line, kCodecParamPTime, &ptime_as_string, error)) { return false; } } else if (HasAttribute(line, kAttributeSendOnly)) { media_desc->set_direction(RtpTransceiverDirection::kSendOnly); } else if (HasAttribute(line, kAttributeRecvOnly)) { media_desc->set_direction(RtpTransceiverDirection::kRecvOnly); } else if (HasAttribute(line, kAttributeInactive)) { media_desc->set_direction(RtpTransceiverDirection::kInactive); } else if (HasAttribute(line, kAttributeSendRecv)) { media_desc->set_direction(RtpTransceiverDirection::kSendRecv); } else if (HasAttribute(line, kAttributeExtmapAllowMixed)) { media_desc->set_extmap_allow_mixed_enum( MediaContentDescription::kMedia); } else if (HasAttribute(line, kAttributeExtmap)) { RtpExtension extmap; if (!ParseExtmap(line, &extmap, error)) { return false; } media_desc->AddRtpHeaderExtension(extmap); } else if (HasAttribute(line, kAttributeXGoogleFlag)) { // Experimental attribute. Conference mode activates more aggressive // AEC and NS settings. // TODO(deadbeef): expose API to set these directly. std::string flag_value; if (!GetValue(line, kAttributeXGoogleFlag, &flag_value, error)) { return false; } if (flag_value.compare(kValueConference) == 0) media_desc->set_conference_mode(true); } else if (HasAttribute(line, kAttributeMsid)) { if (!ParseMsidAttribute(line, &stream_ids, &track_id, error)) { return false; } *msid_signaling |= cricket::kMsidSignalingMediaSection; } else if (HasAttribute(line, kAttributeRid)) { const size_t kRidPrefixLength = kLinePrefixLength + arraysize(kAttributeRid); if (line.size() <= kRidPrefixLength) { RTC_LOG(LS_INFO) << "Ignoring empty RID attribute: " << line; continue; } RTCErrorOr error_or_rid_description = deserializer.DeserializeRidDescription( line.substr(kRidPrefixLength)); // Malformed a=rid lines are discarded. if (!error_or_rid_description.ok()) { RTC_LOG(LS_INFO) << "Ignoring malformed RID line: '" << line << "'. Error: " << error_or_rid_description.error().message(); continue; } rids.push_back(error_or_rid_description.MoveValue()); } else if (HasAttribute(line, kAttributeSimulcast)) { const size_t kSimulcastPrefixLength = kLinePrefixLength + arraysize(kAttributeSimulcast); if (line.size() <= kSimulcastPrefixLength) { return ParseFailed(line, "Simulcast attribute is empty.", error); } if (!simulcast.empty()) { return ParseFailed(line, "Multiple Simulcast attributes specified.", error); } RTCErrorOr error_or_simulcast = deserializer.DeserializeSimulcastDescription( line.substr(kSimulcastPrefixLength)); if (!error_or_simulcast.ok()) { return ParseFailed(line, std::string("Malformed simulcast line: ") + error_or_simulcast.error().message(), error); } simulcast = error_or_simulcast.value(); } else if (HasAttribute(line, kAttributeRtcp)) { // Ignore and do not log a=rtcp line. // JSEP section 5.8.2 (media section parsing) says to ignore it. continue; } else { // Unrecognized attribute in RTP protocol. RTC_LOG(LS_VERBOSE) << "Ignored line: " << line; continue; } } else { // Only parse lines that we are interested of. RTC_LOG(LS_VERBOSE) << "Ignored line: " << line; continue; } } // Remove duplicate or inconsistent rids. RemoveInvalidRidDescriptions(payload_types, &rids); // If simulcast is specifed, split the rids into send and receive. // Rids that do not appear in simulcast attribute will be removed. // If it is not specified, we assume that all rids are for send layers. std::vector send_rids; std::vector receive_rids; if (!simulcast.empty()) { // Verify that the rids in simulcast match rids in sdp. RemoveInvalidRidsFromSimulcast(rids, &simulcast); // Use simulcast description to figure out Send / Receive RIDs. std::map rid_map; for (const RidDescription& rid : rids) { rid_map[rid.rid] = rid; } for (const auto& layer : simulcast.send_layers().GetAllLayers()) { auto iter = rid_map.find(layer.rid); RTC_DCHECK(iter != rid_map.end()); send_rids.push_back(iter->second); } for (const auto& layer : simulcast.receive_layers().GetAllLayers()) { auto iter = rid_map.find(layer.rid); RTC_DCHECK(iter != rid_map.end()); receive_rids.push_back(iter->second); } media_desc->set_simulcast_description(simulcast); } else { send_rids = rids; } media_desc->set_receive_rids(receive_rids); // Create tracks from the `ssrc_infos`. // If the stream_id/track_id for all SSRCS are identical, one StreamParams // will be created in CreateTracksFromSsrcInfos, containing all the SSRCs from // the m= section. if (!ssrc_infos.empty()) { CreateTracksFromSsrcInfos(ssrc_infos, stream_ids, track_id, &tracks, *msid_signaling); } else if (media_type != cricket::MEDIA_TYPE_DATA && (*msid_signaling & cricket::kMsidSignalingMediaSection)) { // If the stream_ids/track_id was signaled but SSRCs were unsignaled we // still create a track. This isn't done for data media types because // StreamParams aren't used for SCTP streams, and RTP data channels don't // support unsignaled SSRCs. CreateTrackWithNoSsrcs(stream_ids, track_id, send_rids, &tracks); } // Add the ssrc group to the track. for (const SsrcGroup& ssrc_group : ssrc_groups) { if (ssrc_group.ssrcs.empty()) { continue; } uint32_t ssrc = ssrc_group.ssrcs.front(); for (StreamParams& track : tracks) { if (track.has_ssrc(ssrc)) { track.ssrc_groups.push_back(ssrc_group); } } } // Add the new tracks to the `media_desc`. for (StreamParams& track : tracks) { media_desc->AddStream(track); } if (media_type == cricket::MEDIA_TYPE_AUDIO) { AudioContentDescription* audio_desc = media_desc->as_audio(); UpdateFromWildcardCodecs(audio_desc); // Verify audio codec ensures that no audio codec has been populated with // only fmtp. if (!VerifyAudioCodecs(audio_desc)) { return ParseFailed("Failed to parse audio codecs correctly.", error); } AddAudioAttribute(kCodecParamMaxPTime, maxptime_as_string, audio_desc); AddAudioAttribute(kCodecParamPTime, ptime_as_string, audio_desc); } if (media_type == cricket::MEDIA_TYPE_VIDEO) { VideoContentDescription* video_desc = media_desc->as_video(); UpdateFromWildcardCodecs(video_desc); // Verify video codec ensures that no video codec has been populated with // only rtcp-fb. if (!VerifyVideoCodecs(video_desc)) { return ParseFailed("Failed to parse video codecs correctly.", error); } } // RFC 5245 // Update the candidates with the media level "ice-pwd" and "ice-ufrag". for (Candidate& candidate : candidates_orig) { RTC_DCHECK(candidate.username().empty() || candidate.username() == transport->ice_ufrag); candidate.set_username(transport->ice_ufrag); RTC_DCHECK(candidate.password().empty()); candidate.set_password(transport->ice_pwd); candidates->push_back( std::make_unique(mline_id, mline_index, candidate)); } return true; } bool ParseSsrcAttribute(const std::string& line, SsrcInfoVec* ssrc_infos, int* msid_signaling, SdpParseError* error) { RTC_DCHECK(ssrc_infos != NULL); // RFC 5576 // a=ssrc: // a=ssrc: : std::string field1, field2; if (!rtc::tokenize_first(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &field1, &field2)) { const size_t expected_fields = 2; return ParseFailedExpectFieldNum(line, expected_fields, error); } // ssrc: std::string ssrc_id_s; if (!GetValue(field1, kAttributeSsrc, &ssrc_id_s, error)) { return false; } uint32_t ssrc_id = 0; if (!GetValueFromString(line, ssrc_id_s, &ssrc_id, error)) { return false; } std::string attribute; std::string value; if (!rtc::tokenize_first(field2, kSdpDelimiterColonChar, &attribute, &value)) { rtc::StringBuilder description; description << "Failed to get the ssrc attribute value from " << field2 << ". Expected format :."; return ParseFailed(line, description.Release(), error); } // Check if there's already an item for this `ssrc_id`. Create a new one if // there isn't. auto ssrc_info_it = absl::c_find_if(*ssrc_infos, [ssrc_id](const SsrcInfo& ssrc_info) { return ssrc_info.ssrc_id == ssrc_id; }); if (ssrc_info_it == ssrc_infos->end()) { SsrcInfo info; info.ssrc_id = ssrc_id; ssrc_infos->push_back(info); ssrc_info_it = ssrc_infos->end() - 1; } SsrcInfo& ssrc_info = *ssrc_info_it; // Store the info to the `ssrc_info`. if (attribute == kSsrcAttributeCname) { // RFC 5576 // cname: ssrc_info.cname = value; } else if (attribute == kSsrcAttributeMsid) { // draft-alvestrand-mmusic-msid-00 // msid:identifier [appdata] std::vector fields; rtc::split(value, kSdpDelimiterSpaceChar, &fields); if (fields.size() < 1 || fields.size() > 2) { return ParseFailed( line, "Expected format \"msid:[ ]\".", error); } ssrc_info.stream_id = fields[0]; if (fields.size() == 2) { ssrc_info.track_id = fields[1]; } *msid_signaling |= cricket::kMsidSignalingSsrcAttribute; } else if (attribute == kSsrcAttributeMslabel) { // draft-alvestrand-rtcweb-mid-01 // mslabel: ssrc_info.mslabel = value; } else if (attribute == kSSrcAttributeLabel) { // The label isn't defined. // label: ssrc_info.label = value; } return true; } bool ParseSsrcGroupAttribute(const std::string& line, SsrcGroupVec* ssrc_groups, SdpParseError* error) { RTC_DCHECK(ssrc_groups != NULL); // RFC 5576 // a=ssrc-group: ... std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); const size_t expected_min_fields = 2; if (fields.size() < expected_min_fields) { return ParseFailedExpectMinFieldNum(line, expected_min_fields, error); } std::string semantics; if (!GetValue(fields[0], kAttributeSsrcGroup, &semantics, error)) { return false; } std::vector ssrcs; for (size_t i = 1; i < fields.size(); ++i) { uint32_t ssrc = 0; if (!GetValueFromString(line, fields[i], &ssrc, error)) { return false; } ssrcs.push_back(ssrc); } ssrc_groups->push_back(SsrcGroup(semantics, ssrcs)); return true; } bool ParseCryptoAttribute(const std::string& line, MediaContentDescription* media_desc, SdpParseError* error) { std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); // RFC 4568 // a=crypto: [] const size_t expected_min_fields = 3; if (fields.size() < expected_min_fields) { return ParseFailedExpectMinFieldNum(line, expected_min_fields, error); } std::string tag_value; if (!GetValue(fields[0], kAttributeCrypto, &tag_value, error)) { return false; } int tag = 0; if (!GetValueFromString(line, tag_value, &tag, error)) { return false; } const std::string& crypto_suite = fields[1]; const std::string& key_params = fields[2]; std::string session_params; if (fields.size() > 3) { session_params = fields[3]; } media_desc->AddCrypto( CryptoParams(tag, crypto_suite, key_params, session_params)); return true; } // Updates or creates a new codec entry in the audio description with according // to `name`, `clockrate`, `bitrate`, and `channels`. void UpdateCodec(int payload_type, const std::string& name, int clockrate, int bitrate, size_t channels, AudioContentDescription* audio_desc) { // Codec may already be populated with (only) optional parameters // (from an fmtp). cricket::AudioCodec codec = GetCodecWithPayloadType(audio_desc->codecs(), payload_type); codec.name = name; codec.clockrate = clockrate; codec.bitrate = bitrate; codec.channels = channels; AddOrReplaceCodec(audio_desc, codec); } // Updates or creates a new codec entry in the video description according to // `name`, `width`, `height`, and `framerate`. void UpdateCodec(int payload_type, const std::string& name, VideoContentDescription* video_desc) { // Codec may already be populated with (only) optional parameters // (from an fmtp). cricket::VideoCodec codec = GetCodecWithPayloadType(video_desc->codecs(), payload_type); codec.name = name; AddOrReplaceCodec(video_desc, codec); } bool ParseRtpmapAttribute(const std::string& line, const cricket::MediaType media_type, const std::vector& payload_types, MediaContentDescription* media_desc, SdpParseError* error) { std::vector fields; rtc::split(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &fields); // RFC 4566 // a=rtpmap: /[/] const size_t expected_min_fields = 2; if (fields.size() < expected_min_fields) { return ParseFailedExpectMinFieldNum(line, expected_min_fields, error); } std::string payload_type_value; if (!GetValue(fields[0], kAttributeRtpmap, &payload_type_value, error)) { return false; } int payload_type = 0; if (!GetPayloadTypeFromString(line, payload_type_value, &payload_type, error)) { return false; } if (!absl::c_linear_search(payload_types, payload_type)) { RTC_LOG(LS_WARNING) << "Ignore rtpmap line that did not appear in the " " of the m-line: " << line; return true; } const std::string& encoder = fields[1]; std::vector codec_params; rtc::split(encoder, '/', &codec_params); // /[/] // 2 mandatory fields if (codec_params.size() < 2 || codec_params.size() > 3) { return ParseFailed(line, "Expected format \"/" "[/]\".", error); } const std::string& encoding_name = codec_params[0]; int clock_rate = 0; if (!GetValueFromString(line, codec_params[1], &clock_rate, error)) { return false; } if (media_type == cricket::MEDIA_TYPE_VIDEO) { VideoContentDescription* video_desc = media_desc->as_video(); UpdateCodec(payload_type, encoding_name, video_desc); } else if (media_type == cricket::MEDIA_TYPE_AUDIO) { // RFC 4566 // For audio streams, indicates the number // of audio channels. This parameter is OPTIONAL and may be // omitted if the number of channels is one, provided that no // additional parameters are needed. size_t channels = 1; if (codec_params.size() == 3) { if (!GetValueFromString(line, codec_params[2], &channels, error)) { return false; } } if (channels > kMaxNumberOfChannels) { return ParseFailed(line, "At most 24 channels are supported.", error); } AudioContentDescription* audio_desc = media_desc->as_audio(); UpdateCodec(payload_type, encoding_name, clock_rate, 0, channels, audio_desc); } return true; } bool ParseFmtpParam(const std::string& line, std::string* parameter, std::string* value, SdpParseError* error) { if (!rtc::tokenize_first(line, kSdpDelimiterEqualChar, parameter, value)) { // Support for non-key-value lines like RFC 2198 or RFC 4733. *parameter = ""; *value = line; return true; } // a=fmtp: =; =; ... return true; } bool ParseFmtpAttributes(const std::string& line, const cricket::MediaType media_type, MediaContentDescription* media_desc, SdpParseError* error) { if (media_type != cricket::MEDIA_TYPE_AUDIO && media_type != cricket::MEDIA_TYPE_VIDEO) { return true; } std::string line_payload; std::string line_params; // https://tools.ietf.org/html/rfc4566#section-6 // a=fmtp: // At least two fields, whereas the second one is any of the optional // parameters. if (!rtc::tokenize_first(line.substr(kLinePrefixLength), kSdpDelimiterSpaceChar, &line_payload, &line_params)) { ParseFailedExpectMinFieldNum(line, 2, error); return false; } // Parse out the payload information. std::string payload_type_str; if (!GetValue(line_payload, kAttributeFmtp, &payload_type_str, error)) { return false; } int payload_type = 0; if (!GetPayloadTypeFromString(line_payload, payload_type_str, &payload_type, error)) { return false; } // Parse out format specific parameters. std::vector fields; rtc::split(line_params, kSdpDelimiterSemicolonChar, &fields); cricket::CodecParameterMap codec_params; for (auto& iter : fields) { std::string name; std::string value; if (!ParseFmtpParam(rtc::string_trim(iter), &name, &value, error)) { return false; } if (codec_params.find(name) != codec_params.end()) { RTC_LOG(LS_INFO) << "Overwriting duplicate fmtp parameter with key \"" << name << "\"."; } codec_params[name] = value; } if (media_type == cricket::MEDIA_TYPE_AUDIO) { UpdateCodec( media_desc, payload_type, codec_params); } else if (media_type == cricket::MEDIA_TYPE_VIDEO) { UpdateCodec( media_desc, payload_type, codec_params); } return true; } bool ParsePacketizationAttribute(const std::string& line, const cricket::MediaType media_type, MediaContentDescription* media_desc, SdpParseError* error) { if (media_type != cricket::MEDIA_TYPE_VIDEO) { return true; } std::vector packetization_fields; rtc::split(line.c_str(), kSdpDelimiterSpaceChar, &packetization_fields); if (packetization_fields.size() < 2) { return ParseFailedGetValue(line, kAttributePacketization, error); } std::string payload_type_string; if (!GetValue(packetization_fields[0], kAttributePacketization, &payload_type_string, error)) { return false; } int payload_type; if (!GetPayloadTypeFromString(line, payload_type_string, &payload_type, error)) { return false; } std::string packetization = packetization_fields[1]; UpdateVideoCodecPacketization(media_desc->as_video(), payload_type, packetization); return true; } bool ParseRtcpFbAttribute(const std::string& line, const cricket::MediaType media_type, MediaContentDescription* media_desc, SdpParseError* error) { if (media_type != cricket::MEDIA_TYPE_AUDIO && media_type != cricket::MEDIA_TYPE_VIDEO) { return true; } std::vector rtcp_fb_fields; rtc::split(line.c_str(), kSdpDelimiterSpaceChar, &rtcp_fb_fields); if (rtcp_fb_fields.size() < 2) { return ParseFailedGetValue(line, kAttributeRtcpFb, error); } std::string payload_type_string; if (!GetValue(rtcp_fb_fields[0], kAttributeRtcpFb, &payload_type_string, error)) { return false; } int payload_type = kWildcardPayloadType; if (payload_type_string != "*") { if (!GetPayloadTypeFromString(line, payload_type_string, &payload_type, error)) { return false; } } std::string id = rtcp_fb_fields[1]; std::string param = ""; for (std::vector::iterator iter = rtcp_fb_fields.begin() + 2; iter != rtcp_fb_fields.end(); ++iter) { param.append(*iter); } const cricket::FeedbackParam feedback_param(id, param); if (media_type == cricket::MEDIA_TYPE_AUDIO) { UpdateCodec( media_desc, payload_type, feedback_param); } else if (media_type == cricket::MEDIA_TYPE_VIDEO) { UpdateCodec( media_desc, payload_type, feedback_param); } return true; } } // namespace webrtc