/* * Copyright (c) 2016 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 "modules/rtp_rtcp/source/flexfec_header_reader_writer.h" #include #include "api/scoped_refptr.h" #include "modules/rtp_rtcp/source/byte_io.h" #include "modules/rtp_rtcp/source/forward_error_correction_internal.h" #include "rtc_base/checks.h" #include "rtc_base/logging.h" namespace webrtc { namespace { // Maximum number of media packets that can be protected in one batch. constexpr size_t kMaxMediaPackets = 48; // Since we are reusing ULPFEC masks. // Maximum number of media packets tracked by FEC decoder. // Maintain a sufficiently larger tracking window than `kMaxMediaPackets` // to account for packet reordering in pacer/ network. constexpr size_t kMaxTrackedMediaPackets = 4 * kMaxMediaPackets; // Maximum number of FEC packets stored inside ForwardErrorCorrection. constexpr size_t kMaxFecPackets = kMaxMediaPackets; // Size (in bytes) of packet masks, given number of K bits set. constexpr size_t kFlexfecPacketMaskSizes[] = {2, 6, 14}; // Size (in bytes) of part of header which is not packet mask specific. constexpr size_t kBaseHeaderSize = 12; // Size (in bytes) of part of header which is stream specific. constexpr size_t kStreamSpecificHeaderSize = 6; // Size (in bytes) of header, given the single stream packet mask size, i.e. // the number of K-bits set. constexpr size_t kHeaderSizes[] = { kBaseHeaderSize + kStreamSpecificHeaderSize + kFlexfecPacketMaskSizes[0], kBaseHeaderSize + kStreamSpecificHeaderSize + kFlexfecPacketMaskSizes[1], kBaseHeaderSize + kStreamSpecificHeaderSize + kFlexfecPacketMaskSizes[2]}; // We currently only support single-stream protection. // TODO(brandtr): Update this when we support multistream protection. constexpr uint8_t kSsrcCount = 1; // There are three reserved bytes that MUST be set to zero in the header. constexpr uint32_t kReservedBits = 0; // TODO(brandtr): Update this when we support multistream protection. constexpr size_t kPacketMaskOffset = kBaseHeaderSize + kStreamSpecificHeaderSize; // Here we count the K-bits as belonging to the packet mask. // This can be used in conjunction with FlexfecHeaderWriter::MinPacketMaskSize, // which calculates a bound on the needed packet mask size including K-bits, // given a packet mask without K-bits. size_t FlexfecHeaderSize(size_t packet_mask_size) { RTC_DCHECK_LE(packet_mask_size, kFlexfecPacketMaskSizes[2]); if (packet_mask_size <= kFlexfecPacketMaskSizes[0]) { return kHeaderSizes[0]; } else if (packet_mask_size <= kFlexfecPacketMaskSizes[1]) { return kHeaderSizes[1]; } return kHeaderSizes[2]; } } // namespace FlexfecHeaderReader::FlexfecHeaderReader() : FecHeaderReader(kMaxTrackedMediaPackets, kMaxFecPackets) {} FlexfecHeaderReader::~FlexfecHeaderReader() = default; // TODO(brandtr): Update this function when we support flexible masks, // retransmissions, and/or several protected SSRCs. bool FlexfecHeaderReader::ReadFecHeader( ForwardErrorCorrection::ReceivedFecPacket* fec_packet) const { if (fec_packet->pkt->data.size() <= kBaseHeaderSize + kStreamSpecificHeaderSize) { RTC_LOG(LS_WARNING) << "Discarding truncated FlexFEC packet."; return false; } uint8_t* const data = fec_packet->pkt->data.MutableData(); bool r_bit = (data[0] & 0x80) != 0; if (r_bit) { RTC_LOG(LS_INFO) << "FlexFEC packet with retransmission bit set. We do not yet " "support this, thus discarding the packet."; return false; } bool f_bit = (data[0] & 0x40) != 0; if (f_bit) { RTC_LOG(LS_INFO) << "FlexFEC packet with inflexible generator matrix. We do " "not yet support this, thus discarding packet."; return false; } uint8_t ssrc_count = ByteReader::ReadBigEndian(&data[8]); if (ssrc_count != 1) { RTC_LOG(LS_INFO) << "FlexFEC packet protecting multiple media SSRCs. We do not " "yet support this, thus discarding packet."; return false; } uint32_t protected_ssrc = ByteReader::ReadBigEndian(&data[12]); uint16_t seq_num_base = ByteReader::ReadBigEndian(&data[16]); // Parse the FlexFEC packet mask and remove the interleaved K-bits. // (See FEC header schematic in flexfec_header_reader_writer.h.) // We store the packed packet mask in-band, which "destroys" the standards // compliance of the header. That is fine though, since the code that // reads from the header (from this point and onwards) is aware of this. // TODO(brandtr): When the FEC packet classes have been refactored, store // the packed packet masks out-of-band, thus leaving the FlexFEC header as is. // // We treat the mask parts as unsigned integers with host order endianness // in order to simplify the bit shifting between bytes. if (fec_packet->pkt->data.size() < kHeaderSizes[0]) { RTC_LOG(LS_WARNING) << "Discarding truncated FlexFEC packet."; return false; } uint8_t* const packet_mask = data + kPacketMaskOffset; bool k_bit0 = (packet_mask[0] & 0x80) != 0; uint16_t mask_part0 = ByteReader::ReadBigEndian(&packet_mask[0]); // Shift away K-bit 0, implicitly clearing the last bit. mask_part0 <<= 1; ByteWriter::WriteBigEndian(&packet_mask[0], mask_part0); size_t packet_mask_size; if (k_bit0) { // The first K-bit is set, and the packet mask is thus only 2 bytes long. // We have now read the entire FEC header, and the rest of the packet // is payload. packet_mask_size = kFlexfecPacketMaskSizes[0]; } else { if (fec_packet->pkt->data.size() < kHeaderSizes[1]) { return false; } bool k_bit1 = (packet_mask[2] & 0x80) != 0; // We have already shifted the first two bytes of the packet mask one step // to the left, thus removing K-bit 0. We will now shift the next four bytes // of the packet mask two steps to the left. (One step for the removed // K-bit 0, and one step for the to be removed K-bit 1). uint8_t bit15 = (packet_mask[2] >> 6) & 0x01; packet_mask[1] |= bit15; uint32_t mask_part1 = ByteReader::ReadBigEndian(&packet_mask[2]); // Shift away K-bit 1 and bit 15, implicitly clearing the last two bits. mask_part1 <<= 2; ByteWriter::WriteBigEndian(&packet_mask[2], mask_part1); if (k_bit1) { // The first K-bit is clear, but the second K-bit is set. The packet // mask is thus 6 bytes long. We have now read the entire FEC header, // and the rest of the packet is payload. packet_mask_size = kFlexfecPacketMaskSizes[1]; } else { if (fec_packet->pkt->data.size() < kHeaderSizes[2]) { RTC_LOG(LS_WARNING) << "Discarding truncated FlexFEC packet."; return false; } bool k_bit2 = (packet_mask[6] & 0x80) != 0; if (k_bit2) { // The first and second K-bits are clear, but the third K-bit is set. // The packet mask is thus 14 bytes long. We have now read the entire // FEC header, and the rest of the packet is payload. packet_mask_size = kFlexfecPacketMaskSizes[2]; } else { RTC_LOG(LS_WARNING) << "Discarding FlexFEC packet with malformed header."; return false; } // At this point, K-bits 0 and 1 have been removed, and the front-most // part of the FlexFEC packet mask has been packed accordingly. We will // now shift the remaning part of the packet mask three steps to the left. // This corresponds to the (in total) three K-bits, which have been // removed. uint8_t tail_bits = (packet_mask[6] >> 5) & 0x03; packet_mask[5] |= tail_bits; uint64_t mask_part2 = ByteReader::ReadBigEndian(&packet_mask[6]); // Shift away K-bit 2, bit 46, and bit 47, implicitly clearing the last // three bits. mask_part2 <<= 3; ByteWriter::WriteBigEndian(&packet_mask[6], mask_part2); } } // Store "ULPFECized" packet mask info. fec_packet->fec_header_size = FlexfecHeaderSize(packet_mask_size); fec_packet->protected_ssrc = protected_ssrc; fec_packet->seq_num_base = seq_num_base; fec_packet->packet_mask_offset = kPacketMaskOffset; fec_packet->packet_mask_size = packet_mask_size; // In FlexFEC, all media packets are protected in their entirety. fec_packet->protection_length = fec_packet->pkt->data.size() - fec_packet->fec_header_size; return true; } FlexfecHeaderWriter::FlexfecHeaderWriter() : FecHeaderWriter(kMaxMediaPackets, kMaxFecPackets, kHeaderSizes[2]) {} FlexfecHeaderWriter::~FlexfecHeaderWriter() = default; size_t FlexfecHeaderWriter::MinPacketMaskSize(const uint8_t* packet_mask, size_t packet_mask_size) const { if (packet_mask_size == kUlpfecPacketMaskSizeLBitClear && (packet_mask[1] & 0x01) == 0) { // Packet mask is 16 bits long, with bit 15 clear. // It can be used as is. return kFlexfecPacketMaskSizes[0]; } else if (packet_mask_size == kUlpfecPacketMaskSizeLBitClear) { // Packet mask is 16 bits long, with bit 15 set. // We must expand the packet mask with zeros in the FlexFEC header. return kFlexfecPacketMaskSizes[1]; } else if (packet_mask_size == kUlpfecPacketMaskSizeLBitSet && (packet_mask[5] & 0x03) == 0) { // Packet mask is 48 bits long, with bits 46 and 47 clear. // It can be used as is. return kFlexfecPacketMaskSizes[1]; } else if (packet_mask_size == kUlpfecPacketMaskSizeLBitSet) { // Packet mask is 48 bits long, with at least one of bits 46 and 47 set. // We must expand it with zeros. return kFlexfecPacketMaskSizes[2]; } RTC_DCHECK_NOTREACHED() << "Incorrect packet mask size: " << packet_mask_size << "."; return kFlexfecPacketMaskSizes[2]; } size_t FlexfecHeaderWriter::FecHeaderSize(size_t packet_mask_size) const { return FlexfecHeaderSize(packet_mask_size); } // This function adapts the precomputed ULPFEC packet masks to the // FlexFEC header standard. Note that the header size is computed by // FecHeaderSize(), so in this function we can be sure that we are // writing in space that is intended for the header. // // TODO(brandtr): Update this function when we support offset-based masks, // retransmissions, and protecting multiple SSRCs. void FlexfecHeaderWriter::FinalizeFecHeader( uint32_t media_ssrc, uint16_t seq_num_base, const uint8_t* packet_mask, size_t packet_mask_size, ForwardErrorCorrection::Packet* fec_packet) const { uint8_t* data = fec_packet->data.MutableData(); data[0] &= 0x7f; // Clear R bit. data[0] &= 0xbf; // Clear F bit. ByteWriter::WriteBigEndian(&data[8], kSsrcCount); ByteWriter::WriteBigEndian(&data[9], kReservedBits); ByteWriter::WriteBigEndian(&data[12], media_ssrc); ByteWriter::WriteBigEndian(&data[16], seq_num_base); // Adapt ULPFEC packet mask to FlexFEC header. // // We treat the mask parts as unsigned integers with host order endianness // in order to simplify the bit shifting between bytes. uint8_t* const written_packet_mask = data + kPacketMaskOffset; if (packet_mask_size == kUlpfecPacketMaskSizeLBitSet) { // The packet mask is 48 bits long. uint16_t tmp_mask_part0 = ByteReader::ReadBigEndian(&packet_mask[0]); uint32_t tmp_mask_part1 = ByteReader::ReadBigEndian(&packet_mask[2]); tmp_mask_part0 >>= 1; // Shift, thus clearing K-bit 0. ByteWriter::WriteBigEndian(&written_packet_mask[0], tmp_mask_part0); tmp_mask_part1 >>= 2; // Shift, thus clearing K-bit 1 and bit 15. ByteWriter::WriteBigEndian(&written_packet_mask[2], tmp_mask_part1); bool bit15 = (packet_mask[1] & 0x01) != 0; if (bit15) written_packet_mask[2] |= 0x40; // Set bit 15. bool bit46 = (packet_mask[5] & 0x02) != 0; bool bit47 = (packet_mask[5] & 0x01) != 0; if (!bit46 && !bit47) { written_packet_mask[2] |= 0x80; // Set K-bit 1. } else { memset(&written_packet_mask[6], 0, 8); // Clear all trailing bits. written_packet_mask[6] |= 0x80; // Set K-bit 2. if (bit46) written_packet_mask[6] |= 0x40; // Set bit 46. if (bit47) written_packet_mask[6] |= 0x20; // Set bit 47. } } else if (packet_mask_size == kUlpfecPacketMaskSizeLBitClear) { // The packet mask is 16 bits long. uint16_t tmp_mask_part0 = ByteReader::ReadBigEndian(&packet_mask[0]); tmp_mask_part0 >>= 1; // Shift, thus clearing K-bit 0. ByteWriter::WriteBigEndian(&written_packet_mask[0], tmp_mask_part0); bool bit15 = (packet_mask[1] & 0x01) != 0; if (!bit15) { written_packet_mask[0] |= 0x80; // Set K-bit 0. } else { memset(&written_packet_mask[2], 0U, 4); // Clear all trailing bits. written_packet_mask[2] |= 0x80; // Set K-bit 1. written_packet_mask[2] |= 0x40; // Set bit 15. } } else { RTC_DCHECK_NOTREACHED() << "Incorrect packet mask size: " << packet_mask_size << "."; } } } // namespace webrtc