// Copyright 2019 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "cast/streaming/rtcp_common.h" #include #include #include "cast/streaming/packet_util.h" #include "util/saturate_cast.h" namespace openscreen { namespace cast { RtcpCommonHeader::RtcpCommonHeader() = default; RtcpCommonHeader::~RtcpCommonHeader() = default; void RtcpCommonHeader::AppendFields(absl::Span* buffer) const { OSP_CHECK_GE(buffer->size(), kRtcpCommonHeaderSize); uint8_t byte0 = kRtcpRequiredVersionAndPaddingBits << kRtcpReportCountFieldNumBits; switch (packet_type) { case RtcpPacketType::kSenderReport: case RtcpPacketType::kReceiverReport: OSP_DCHECK_LE(with.report_count, FieldBitmask(kRtcpReportCountFieldNumBits)); byte0 |= with.report_count; break; case RtcpPacketType::kSourceDescription: OSP_UNIMPLEMENTED(); break; case RtcpPacketType::kApplicationDefined: case RtcpPacketType::kPayloadSpecific: switch (with.subtype) { case RtcpSubtype::kPictureLossIndicator: case RtcpSubtype::kFeedback: byte0 |= static_cast(with.subtype); break; case RtcpSubtype::kReceiverLog: OSP_UNIMPLEMENTED(); break; default: OSP_NOTREACHED(); } break; case RtcpPacketType::kExtendedReports: break; case RtcpPacketType::kNull: OSP_NOTREACHED(); } AppendField(byte0, buffer); AppendField(static_cast(packet_type), buffer); // The size of the packet must be evenly divisible by the 32-bit word size. OSP_DCHECK_EQ(0, payload_size % sizeof(uint32_t)); AppendField(payload_size / sizeof(uint32_t), buffer); } // static absl::optional RtcpCommonHeader::Parse( absl::Span buffer) { if (buffer.size() < kRtcpCommonHeaderSize) { return absl::nullopt; } const uint8_t byte0 = ConsumeField(&buffer); if ((byte0 >> kRtcpReportCountFieldNumBits) != kRtcpRequiredVersionAndPaddingBits) { return absl::nullopt; } const uint8_t report_count_or_subtype = byte0 & FieldBitmask(kRtcpReportCountFieldNumBits); const uint8_t byte1 = ConsumeField(&buffer); if (!IsRtcpPacketType(byte1)) { return absl::nullopt; } // Optionally set |header.with.report_count| or |header.with.subtype|, // depending on the packet type. RtcpCommonHeader header; header.packet_type = static_cast(byte1); switch (header.packet_type) { case RtcpPacketType::kSenderReport: case RtcpPacketType::kReceiverReport: header.with.report_count = report_count_or_subtype; break; case RtcpPacketType::kApplicationDefined: case RtcpPacketType::kPayloadSpecific: switch (static_cast(report_count_or_subtype)) { case RtcpSubtype::kPictureLossIndicator: case RtcpSubtype::kReceiverLog: case RtcpSubtype::kFeedback: header.with.subtype = static_cast(report_count_or_subtype); break; default: // Unknown subtype. header.with.subtype = RtcpSubtype::kNull; break; } break; default: // Neither |header.with.report_count| nor |header.with.subtype| are used. break; } header.payload_size = static_cast(ConsumeField(&buffer)) * sizeof(uint32_t); return header; } RtcpReportBlock::RtcpReportBlock() = default; RtcpReportBlock::~RtcpReportBlock() = default; void RtcpReportBlock::AppendFields(absl::Span* buffer) const { OSP_CHECK_GE(buffer->size(), kRtcpReportBlockSize); AppendField(ssrc, buffer); OSP_DCHECK_GE(packet_fraction_lost_numerator, std::numeric_limits::min()); OSP_DCHECK_LE(packet_fraction_lost_numerator, std::numeric_limits::max()); OSP_DCHECK_GE(cumulative_packets_lost, 0); OSP_DCHECK_LE(cumulative_packets_lost, FieldBitmask(kRtcpCumulativePacketsFieldNumBits)); AppendField( (static_cast(packet_fraction_lost_numerator) << kRtcpCumulativePacketsFieldNumBits) | (static_cast(cumulative_packets_lost) & FieldBitmask(kRtcpCumulativePacketsFieldNumBits)), buffer); AppendField(extended_high_sequence_number, buffer); const int64_t jitter_ticks = jitter / RtpTimeDelta::FromTicks(1); OSP_DCHECK_GE(jitter_ticks, 0); OSP_DCHECK_LE(jitter_ticks, int64_t{std::numeric_limits::max()}); AppendField(jitter_ticks, buffer); AppendField(last_status_report_id, buffer); const int64_t delay_ticks = delay_since_last_report.count(); OSP_DCHECK_GE(delay_ticks, 0); OSP_DCHECK_LE(delay_ticks, int64_t{std::numeric_limits::max()}); AppendField(delay_ticks, buffer); } void RtcpReportBlock::SetPacketFractionLostNumerator( int64_t num_apparently_sent, int64_t num_received) { if (num_apparently_sent <= 0) { packet_fraction_lost_numerator = 0; return; } // The following computes the fraction of packets lost as "one minus // |num_received| divided by |num_apparently_sent|" and scales by 256 (the // kPacketFractionLostDenominator). It's valid for |num_received| to be // greater than |num_apparently_sent| in some cases (e.g., if duplicate // packets were received from the network). const int64_t numerator = ((num_apparently_sent - num_received) * kPacketFractionLostDenominator) / num_apparently_sent; // Since the value must be in the range [0,255], just do a saturate_cast // to the uint8_t type to clamp. packet_fraction_lost_numerator = saturate_cast(numerator); } void RtcpReportBlock::SetCumulativePacketsLost(int64_t num_apparently_sent, int64_t num_received) { const int64_t num_lost = num_apparently_sent - num_received; // Clamp to valid range supported by the wire format (and RTP spec). // // Note that |num_lost| can be negative if duplicate packets were received. // The RFC spec (https://tools.ietf.org/html/rfc3550#section-6.4.1) states // this should result in a clamped, "zero loss" value. cumulative_packets_lost = static_cast( std::min(std::max(num_lost, 0), FieldBitmask(kRtcpCumulativePacketsFieldNumBits))); } void RtcpReportBlock::SetDelaySinceLastReport( Clock::duration local_clock_delay) { // Clamp to valid range supported by the wire format (and RTP spec). The // bounds checking is done in terms of Clock::duration, since doing the checks // after the duration_cast may allow overflow to occur in the duration_cast // math (well, only for unusually large inputs). constexpr Delay kMaxValidReportedDelay{std::numeric_limits::max()}; constexpr auto kMaxValidLocalClockDelay = Clock::to_duration(kMaxValidReportedDelay); if (local_clock_delay > kMaxValidLocalClockDelay) { delay_since_last_report = kMaxValidReportedDelay; return; } if (local_clock_delay <= Clock::duration::zero()) { delay_since_last_report = Delay::zero(); return; } // If this point is reached, then the |local_clock_delay| is representable as // a Delay within the valid range. delay_since_last_report = std::chrono::duration_cast(local_clock_delay); } // static absl::optional RtcpReportBlock::ParseOne( absl::Span buffer, int report_count, Ssrc ssrc) { if (static_cast(buffer.size()) < (kRtcpReportBlockSize * report_count)) { return absl::nullopt; } absl::optional result; for (int block = 0; block < report_count; ++block) { if (ConsumeField(&buffer) != ssrc) { // Skip-over report block meant for some other recipient. buffer.remove_prefix(kRtcpReportBlockSize - sizeof(uint32_t)); continue; } RtcpReportBlock& report_block = result.emplace(); report_block.ssrc = ssrc; const auto second_word = ConsumeField(&buffer); report_block.packet_fraction_lost_numerator = second_word >> kRtcpCumulativePacketsFieldNumBits; report_block.cumulative_packets_lost = second_word & FieldBitmask(kRtcpCumulativePacketsFieldNumBits); report_block.extended_high_sequence_number = ConsumeField(&buffer); report_block.jitter = RtpTimeDelta::FromTicks(ConsumeField(&buffer)); report_block.last_status_report_id = ConsumeField(&buffer); report_block.delay_since_last_report = RtcpReportBlock::Delay(ConsumeField(&buffer)); } return result; } RtcpSenderReport::RtcpSenderReport() = default; RtcpSenderReport::~RtcpSenderReport() = default; } // namespace cast } // namespace openscreen