/* * Copyright (c) 2016 The ZLMediaKit project authors. All Rights Reserved. * * This file is part of ZLMediaKit(https://github.com/xia-chu/ZLMediaKit). * * Use of this source code is governed by MIT license that can be found in the * LICENSE file in the root of the source tree. All contributing project authors * may be found in the AUTHORS file in the root of the source tree. */ #include "RtcpFCI.h" #include "Util/logger.h" using namespace toolkit; namespace mediakit { void FCI_SLI::check(size_t size){ CHECK(size == kSize); } FCI_SLI::FCI_SLI(uint16_t first, uint16_t number, uint8_t pic_id) { //13 bits first &= 0x1FFF; //13 bits number &= 0x1FFF; //6 bits pic_id &= 0x3F; data = (first << 19) | (number << 6) | pic_id; data = htonl(data); } uint16_t FCI_SLI::getFirst() const { return ntohl(data) >> 19; } uint16_t FCI_SLI::getNumber() const { return (ntohl(data) >> 6) & 0x1FFF; } uint8_t FCI_SLI::getPicID() const { return ntohl(data) & 0x3F; } string FCI_SLI::dumpString() const { return StrPrinter << "First:" << getFirst() << ", Number:" << getNumber() << ", PictureID:" << (int)getPicID(); } /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// void FCI_FIR::check(size_t size){ CHECK(size == kSize); } uint32_t FCI_FIR::getSSRC() const{ return ntohl(ssrc); } uint8_t FCI_FIR::getSeq() const{ return seq_number; } uint32_t FCI_FIR::getReserved() const{ return (reserved[0] << 16) | (reserved[1] << 8) | reserved[2]; } string FCI_FIR::dumpString() const { return StrPrinter << "ssrc:" << getSSRC() << ", seq_number:" << (int)getSeq() << ", reserved:" << getReserved(); } FCI_FIR::FCI_FIR(uint32_t ssrc, uint8_t seq_number, uint32_t reserved) { this->ssrc = htonl(ssrc); this->seq_number = seq_number; this->reserved[0] = (reserved >> 16) & 0xFF; this->reserved[1] = (reserved >> 8) & 0xFF; this->reserved[2] = reserved & 0xFF; } /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// static const char kRembMagic[] = "REMB"; void FCI_REMB::check(size_t size){ CHECK(size >= kSize); CHECK(memcmp(magic, kRembMagic, sizeof(magic)) == 0); auto num_ssrc = bitrate[0]; auto expect_size = kSize + 4 * num_ssrc; CHECK(size == expect_size); } string FCI_REMB::create(const vector &ssrcs, uint32_t bitrate) { CHECK(ssrcs.size() > 0 && ssrcs.size() <= 0xFF); string ret; ret.resize(kSize + ssrcs.size() * 4); FCI_REMB *thiz = (FCI_REMB *) ret.data(); memcpy(thiz->magic, kRembMagic, sizeof(magic)); /* bitrate --> BR Exp/BR Mantissa */ uint8_t b = 0; uint8_t exp = 0; uint32_t mantissa = 0; for (b = 0; b < 32; b++) { if (bitrate <= ((uint32_t) 0x3FFFF << b)) { exp = b; break; } } if (b > 31) { b = 31; } mantissa = bitrate >> b; //Num SSRC (8 bits) thiz->bitrate[0] = ssrcs.size() & 0xFF; //BR Exp (6 bits)/BR Mantissa (18 bits) thiz->bitrate[1] = (uint8_t) ((exp << 2) + ((mantissa >> 16) & 0x03)); //BR Mantissa (18 bits) thiz->bitrate[2] = (uint8_t) (mantissa >> 8); //BR Mantissa (18 bits) thiz->bitrate[3] = (uint8_t) (mantissa); //设置ssrc列表 auto ptr = thiz->ssrc_feedback; for (auto ssrc : ssrcs) { *(ptr++) = htonl(ssrc); } return ret; } uint32_t FCI_REMB::getBitRate() const { uint8_t exp = (bitrate[1] >> 2) & 0x3F; uint32_t mantissa = (bitrate[1] & 0x03) << 16; mantissa += (bitrate[2] << 8); mantissa += (bitrate[3]); return mantissa << exp; } vector FCI_REMB::getSSRC() { vector ret; auto num_ssrc = bitrate[0]; auto ptr = ssrc_feedback; while (num_ssrc--) { ret.emplace_back(ntohl(*ptr++)); } return ret; } string FCI_REMB::dumpString() const { _StrPrinter printer; printer << "bitrate:" << getBitRate() << ", ssrc:"; for (auto &ssrc : ((FCI_REMB *) this)->getSSRC()) { printer << ssrc << " "; } return printer; } /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// FCI_NACK::FCI_NACK(uint16_t pid_h, const vector &type) { uint16_t blp_h = 0; int i = kBitSize; for (auto item : type) { --i; if (item) { blp_h |= (1 << i); } } blp = htons(blp_h); pid = htons(pid_h); } void FCI_NACK::check(size_t size){ CHECK(size == kSize); } uint16_t FCI_NACK::getPid() const { return ntohs(pid); } uint16_t FCI_NACK::getBlp() const { return ntohs(blp); } vector FCI_NACK::getBitArray() const { vector ret; ret.resize(kBitSize); auto blp_h = getBlp(); for (size_t i = 0; i < kBitSize; ++i) { ret[i] = blp_h & (1 << (kBitSize - i - 1)); } return ret; } string FCI_NACK::dumpString() const { _StrPrinter printer; printer << "pid:" << getPid() << ",blp:"; for (auto flag : getBitArray()) { printer << flag << " "; } return std::move(printer); } /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// class RunLengthChunk { public: static size_t constexpr kSize = 2; // 0 1 // 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // |T| S | Run Length | // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ #if __BYTE_ORDER == __BIG_ENDIAN uint16_t type: 1; uint16_t symbol: 2; uint16_t run_length_high: 5; #else // Run Length 高5位 uint16_t run_length_high: 5; //参考SymbolStatus定义 uint16_t symbol: 2; //固定为0 uint16_t type: 1; #endif // Run Length 低8位 uint16_t run_length_low: 8; //获取Run Length uint16_t getRunLength() const; //构造函数 RunLengthChunk(SymbolStatus status, uint16_t run_length); //打印本对象 string dumpString() const; } PACKED; RunLengthChunk::RunLengthChunk(SymbolStatus status, uint16_t run_length) { type = 0; symbol = (uint8_t)status & 0x03; run_length_high = (run_length >> 8) & 0x1F; run_length_low = run_length & 0xFF; } uint16_t RunLengthChunk::getRunLength() const { CHECK(type == 0); return run_length_high << 8 | run_length_low; } string RunLengthChunk::dumpString() const{ _StrPrinter printer; printer << "run length chunk, symbol:" << (int)symbol << ", run length:" << getRunLength(); return std::move(printer); } /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// class StatusVecChunk { public: static size_t constexpr kSize = 2; // 0 1 // 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // |T|S| symbol list | // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ #if __BYTE_ORDER == __BIG_ENDIAN uint16_t type: 1; uint16_t symbol: 1; uint16_t symbol_list_high: 6; #else // symbol_list 高6位 uint16_t symbol_list_high: 6; //symbol_list中元素是1个还是2个bit uint16_t symbol: 1; //固定为1 uint16_t type: 1; #endif // symbol_list 低8位 uint16_t symbol_list_low: 8; //获取symbollist vector getSymbolList() const; //构造函数 StatusVecChunk(const vector &status); //打印本对象 string dumpString() const; } PACKED; StatusVecChunk::StatusVecChunk(const vector &status) { uint16_t value = 0; type = 1; if (status.size() == 14) { symbol = 0; } else if (status.size() == 7) { symbol = 1; } else { //非法 CHECK(0); } int i = 13; for (auto &item : status) { CHECK(item <= SymbolStatus::reserved); if (!symbol) { CHECK(item <= SymbolStatus::small_delta); value |= (int) item << i; --i; } else { value |= (int) item << (i - 1); i -= 2; } } symbol_list_low = value & 0xFF; symbol_list_high = (value >> 8 ) & 0x1F; } vector StatusVecChunk::getSymbolList() const { CHECK(type == 1); vector ret; auto thiz = ntohs(*((uint16_t *) this)); if (symbol == 0) { //s = 0 时,表示symbollist的每一个bit能表示一个数据包的到达状态 for (int i = 13; i >= 0; --i) { SymbolStatus status = (SymbolStatus) ((bool) (thiz & (1 << i))); ret.emplace_back(status); } } else { //s = 1 时,表示symbollist每两个bit表示一个数据包的状态 for (int i = 12; i >= 0; i -= 2) { SymbolStatus status = (SymbolStatus) ((thiz & (3 << i)) >> i); ret.emplace_back(status); } } return ret; } string StatusVecChunk::dumpString() const { _StrPrinter printer; printer << "status vector chunk, symbol:" << (int) symbol << ", symbol list:"; auto vec = getSymbolList(); for (auto &item : vec) { printer << (int) item << " "; } return std::move(printer); } /////////////////////////////////////////////////////// void FCI_TWCC::check(size_t size){ CHECK(size >= kSize); } uint16_t FCI_TWCC::getBaseSeq() const { return ntohs(base_seq); } uint16_t FCI_TWCC::getPacketCount() const { return ntohs(pkt_status_count); } uint32_t FCI_TWCC::getReferenceTime() const { uint32_t ret = 0; ret |= ref_time[0] << 16; ret |= ref_time[1] << 8; ret |= ref_time[2]; return ret; } //3.1.5. Receive Delta // // Deltas are represented as multiples of 250us: // // o If the "Packet received, small delta" symbol has been appended to // the status list, an 8-bit unsigned receive delta will be appended // to recv delta list, representing a delta in the range [0, 63.75] // ms. // // o If the "Packet received, large or negative delta" symbol has been // appended to the status list, a 16-bit signed receive delta will be // appended to recv delta list, representing a delta in the range // [-8192.0, 8191.75] ms. // // o If the delta exceeds even the larger limits, a new feedback // message must be used, where the 24-bit base receive delta can // cover very large gaps. // // The smaller receive delta upper bound of 63.75 ms means that this is // only viable at about 1000/25.5 ~= 16 packets per second and above. // With a packet size of 1200 bytes/packet that amounts to a bitrate of // about 150 kbit/s. // // The 0.25 ms resolution means that up to 4000 packets per second can // be represented. With a 1200 bytes/packet payload, that amounts to // 38.4 Mbit/s payload bandwidth. static int16_t getRecvDelta(SymbolStatus status, uint8_t *&ptr, const uint8_t *end){ int16_t delta = 0; switch (status) { case SymbolStatus::not_received : { //丢包, recv delta为0个字节 delta = 0; break; } case SymbolStatus::small_delta : { CHECK(ptr + 1 <= end); //时间戳增量小于256, recv delta为1个字节 delta = *ptr; ptr += 1; break; } case SymbolStatus::large_delta : { CHECK(ptr + 2 <= end); //时间戳增量256~65535间,recv delta为2个字节 delta = *ptr << 8 | *(ptr + 1); ptr += 2; break; } default: //这个逻辑分支不可达到 CHECK(0); break; } return delta; } map > FCI_TWCC::getPacketChunkList(size_t total_size) const { map > ret; auto ptr = (uint8_t *) this + kSize; auto end = (uint8_t *) this + total_size; CHECK(ptr < end); auto seq = getBaseSeq(); auto rtp_count = getPacketCount(); for (uint8_t i = 0; i < rtp_count;) { CHECK(ptr + RunLengthChunk::kSize <= end); RunLengthChunk *chunk = (RunLengthChunk *) ptr; if (!chunk->type) { //RunLengthChunk for (auto j = 0; j < chunk->getRunLength(); ++j) { ret.emplace(seq++, std::make_pair((SymbolStatus) chunk->symbol, 0)); if (++i >= rtp_count) { break; } } } else { //StatusVecChunk StatusVecChunk *chunk = (StatusVecChunk *) ptr; for (auto &symbol : chunk->getSymbolList()) { ret.emplace(seq++, std::make_pair(symbol, 0)); if (++i >= rtp_count) { break; } } } ptr += 2; } for (auto &pr : ret) { CHECK(ptr <= end); pr.second.second = 250 * getRecvDelta(pr.second.first, ptr, end); } return ret; } string FCI_TWCC::dumpString(size_t total_size) const { _StrPrinter printer; auto map = getPacketChunkList(total_size); printer << "twcc fci, base_seq:" << getBaseSeq() << ", pkt_status_count:" << getPacketCount() << ", ref time:" << getReferenceTime() << ", fb count:" << (int)fb_pkt_count << "\n"; for (auto &pr : map) { printer << "rtp seq:" << pr.first <<", packet status:" << (int)(pr.second.first) << ", delta:" << pr.second.second << "\n"; } return std::move(printer); } }//namespace mediakit #if 1 using namespace mediakit; void testFCI() { { FCI_SLI fci(8191, 0, 63); InfoL << hexdump(&fci, FCI_SLI::kSize) << fci.dumpString(); } { FCI_FIR fci(123456, 139, 456789); InfoL << hexdump(&fci, FCI_FIR::kSize) << fci.dumpString(); } { auto str = FCI_REMB::create({1234, 2345, 5678}, 4 * 1024 * 1024); FCI_REMB *ptr = (FCI_REMB *) str.data(); InfoL << hexdump(str.data(), str.size()) << ptr->dumpString(); } { FCI_NACK nack(1234, vector({1, 0, 0, 0, 1, 0, 1, 0, 1, 0})); InfoL << hexdump(&nack, FCI_NACK::kSize) << nack.dumpString(); } { RunLengthChunk chunk(SymbolStatus::large_delta, 8024); InfoL << hexdump(&chunk, RunLengthChunk::kSize) << chunk.dumpString(); } auto lam = [](const initializer_list &lst) { vector ret; for (auto &num : lst) { ret.emplace_back((SymbolStatus) num); } return ret; }; { StatusVecChunk chunk(lam({0, 1, 0, 1, 0, 1, 0, 0, 0, 1, 1, 1, 0, 1})); InfoL << hexdump(&chunk, StatusVecChunk::kSize) << chunk.dumpString(); } { StatusVecChunk chunk(lam({0, 1, 2, 2, 0, 1, 2})); InfoL << hexdump(&chunk, StatusVecChunk::kSize) << chunk.dumpString(); } } #endif