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format code use clang-format

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This commit is contained in:
xiongguangjie 2022-07-14 22:49:31 +08:00
parent 602b475a3c
commit cffc0743d7
7 changed files with 1071 additions and 1042 deletions
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514
src/Rtcp/Rtcp.cpp
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@ -8,55 +8,67 @@
* may be found in the AUTHORS file in the root of the source tree. * may be found in the AUTHORS file in the root of the source tree.
*/ */
#include <stddef.h>
#include <assert.h>
#include "Rtcp.h" #include "Rtcp.h"
#include "Util/logger.h"
#include "RtcpFCI.h" #include "RtcpFCI.h"
#include "Util/logger.h"
#include <assert.h>
#include <stddef.h>
using namespace std; using namespace std;
using namespace toolkit; using namespace toolkit;
namespace mediakit { namespace mediakit {
const char *rtcpTypeToStr(RtcpType type){ const char *rtcpTypeToStr(RtcpType type) {
switch (type){ switch (type) {
#define SWITCH_CASE(key, value) case RtcpType::key : return #value "(" #key ")"; #define SWITCH_CASE(key, value) \
case RtcpType::key: \
return #value "(" #key ")";
RTCP_PT_MAP(SWITCH_CASE) RTCP_PT_MAP(SWITCH_CASE)
#undef SWITCH_CASE #undef SWITCH_CASE
default: return "unknown rtcp pt"; default:
return "unknown rtcp pt";
} }
} }
const char *sdesTypeToStr(SdesType type){ const char *sdesTypeToStr(SdesType type) {
switch (type){ switch (type) {
#define SWITCH_CASE(key, value) case SdesType::key : return #value "(" #key ")"; #define SWITCH_CASE(key, value) \
case SdesType::key: \
return #value "(" #key ")";
SDES_TYPE_MAP(SWITCH_CASE) SDES_TYPE_MAP(SWITCH_CASE)
#undef SWITCH_CASE #undef SWITCH_CASE
default: return "unknown source description type"; default:
return "unknown source description type";
} }
} }
const char *psfbTypeToStr(PSFBType type) { const char *psfbTypeToStr(PSFBType type) {
switch (type){ switch (type) {
#define SWITCH_CASE(key, value) case PSFBType::key : return #value "(" #key ")"; #define SWITCH_CASE(key, value) \
case PSFBType::key: \
return #value "(" #key ")";
PSFB_TYPE_MAP(SWITCH_CASE) PSFB_TYPE_MAP(SWITCH_CASE)
#undef SWITCH_CASE #undef SWITCH_CASE
default: return "unknown payload-specific fb message fmt type"; default:
return "unknown payload-specific fb message fmt type";
} }
} }
const char *rtpfbTypeToStr(RTPFBType type) { const char *rtpfbTypeToStr(RTPFBType type) {
switch (type){ switch (type) {
#define SWITCH_CASE(key, value) case RTPFBType::key : return #value "(" #key ")"; #define SWITCH_CASE(key, value) \
case RTPFBType::key: \
return #value "(" #key ")";
RTPFB_TYPE_MAP(SWITCH_CASE) RTPFB_TYPE_MAP(SWITCH_CASE)
#undef SWITCH_CASE #undef SWITCH_CASE
default: return "unknown transport layer feedback messages fmt type"; default:
return "unknown transport layer feedback messages fmt type";
} }
} }
static size_t alignSize(size_t bytes) { static size_t alignSize(size_t bytes) {
return (size_t) ((bytes + 3) >> 2) << 2; return (size_t)((bytes + 3) >> 2) << 2;
} }
static void setupHeader(RtcpHeader *rtcp, RtcpType type, size_t report_count, size_t total_bytes) { static void setupHeader(RtcpHeader *rtcp, RtcpType type, size_t report_count, size_t total_bytes) {
@ -65,16 +77,16 @@ static void setupHeader(RtcpHeader *rtcp, RtcpType type, size_t report_count, si
if (report_count > 0x1F) { if (report_count > 0x1F) {
throw std::invalid_argument(StrPrinter << "rtcp report_count最大赋值为31,当前为:" << report_count); throw std::invalid_argument(StrPrinter << "rtcp report_count最大赋值为31,当前为:" << report_count);
} }
//items总个数 // items总个数
rtcp->report_count = report_count; rtcp->report_count = report_count;
rtcp->pt = (uint8_t) type; rtcp->pt = (uint8_t)type;
rtcp->setSize(total_bytes); rtcp->setSize(total_bytes);
} }
static void setupPadding(RtcpHeader *rtcp, size_t padding_size) { static void setupPadding(RtcpHeader *rtcp, size_t padding_size) {
if (padding_size) { if (padding_size) {
rtcp->padding = 1; rtcp->padding = 1;
((uint8_t *) rtcp)[rtcp->getSize() - 1] = padding_size & 0xFF; ((uint8_t *)rtcp)[rtcp->getSize() - 1] = padding_size & 0xFF;
} else { } else {
rtcp->padding = 0; rtcp->padding = 0;
} }
@ -91,123 +103,125 @@ string RtcpHeader::dumpHeader() const {
printer << "padding:" << padding << "\r\n"; printer << "padding:" << padding << "\r\n";
} }
switch ((RtcpType) pt) { switch ((RtcpType)pt) {
case RtcpType::RTCP_RTPFB : { case RtcpType::RTCP_RTPFB: {
printer << "report_count:" << rtpfbTypeToStr((RTPFBType) report_count) << "\r\n"; printer << "report_count:" << rtpfbTypeToStr((RTPFBType)report_count) << "\r\n";
break; break;
} }
case RtcpType::RTCP_PSFB : { case RtcpType::RTCP_PSFB: {
printer << "report_count:" << psfbTypeToStr((PSFBType) report_count) << "\r\n"; printer << "report_count:" << psfbTypeToStr((PSFBType)report_count) << "\r\n";
break; break;
} }
default : { default: {
printer << "report_count:" << report_count << "\r\n"; printer << "report_count:" << report_count << "\r\n";
break; break;
} }
} }
printer << "pt:" << rtcpTypeToStr((RtcpType) pt) << "\r\n"; printer << "pt:" << rtcpTypeToStr((RtcpType)pt) << "\r\n";
printer << "size:" << getSize() << "\r\n"; printer << "size:" << getSize() << "\r\n";
printer << "--------\r\n"; printer << "--------\r\n";
return std::move(printer); return std::move(printer);
} }
string RtcpHeader::dumpString() const { string RtcpHeader::dumpString() const {
switch ((RtcpType) pt) { switch ((RtcpType)pt) {
case RtcpType::RTCP_SR: { case RtcpType::RTCP_SR: {
RtcpSR *rtcp = (RtcpSR *) this; RtcpSR *rtcp = (RtcpSR *)this;
return rtcp->dumpString(); return rtcp->dumpString();
} }
case RtcpType::RTCP_RR: { case RtcpType::RTCP_RR: {
RtcpRR *rtcp = (RtcpRR *) this; RtcpRR *rtcp = (RtcpRR *)this;
return rtcp->dumpString(); return rtcp->dumpString();
} }
case RtcpType::RTCP_SDES: { case RtcpType::RTCP_SDES: {
RtcpSdes *rtcp = (RtcpSdes *) this; RtcpSdes *rtcp = (RtcpSdes *)this;
return rtcp->dumpString(); return rtcp->dumpString();
} }
case RtcpType::RTCP_RTPFB: case RtcpType::RTCP_RTPFB:
case RtcpType::RTCP_PSFB: { case RtcpType::RTCP_PSFB: {
RtcpFB *rtcp = (RtcpFB *) this; RtcpFB *rtcp = (RtcpFB *)this;
return rtcp->dumpString(); return rtcp->dumpString();
} }
case RtcpType::RTCP_BYE: { case RtcpType::RTCP_BYE: {
RtcpBye *rtcp = (RtcpBye *) this; RtcpBye *rtcp = (RtcpBye *)this;
return rtcp->dumpString(); return rtcp->dumpString();
} }
default: return StrPrinter << dumpHeader() << hexdump((char *)this + sizeof(*this), getSize() - sizeof(*this)); default:
return StrPrinter << dumpHeader() << hexdump((char *)this + sizeof(*this), getSize() - sizeof(*this));
} }
} }
size_t RtcpHeader::getSize() const { size_t RtcpHeader::getSize() const {
//加上rtcp头长度 // 加上rtcp头长度
return (1 + ntohs(length)) << 2; return (1 + ntohs(length)) << 2;
} }
size_t RtcpHeader::getPaddingSize() const{ size_t RtcpHeader::getPaddingSize() const {
if (!padding) { if (!padding) {
return 0; return 0;
} }
return ((uint8_t *) this)[getSize() - 1]; return ((uint8_t *)this)[getSize() - 1];
} }
void RtcpHeader::setSize(size_t size) { void RtcpHeader::setSize(size_t size) {
//不包含rtcp头的长度 // 不包含rtcp头的长度
length = htons((uint16_t) ((size >> 2) - 1)); length = htons((uint16_t)((size >> 2) - 1));
} }
void RtcpHeader::net2Host(size_t len) { void RtcpHeader::net2Host(size_t len) {
switch ((RtcpType) pt) { switch ((RtcpType)pt) {
case RtcpType::RTCP_SR: { case RtcpType::RTCP_SR: {
RtcpSR *sr = (RtcpSR *) this; RtcpSR *sr = (RtcpSR *)this;
sr->net2Host(len); sr->net2Host(len);
break; break;
} }
case RtcpType::RTCP_RR: { case RtcpType::RTCP_RR: {
RtcpRR *rr = (RtcpRR *) this; RtcpRR *rr = (RtcpRR *)this;
rr->net2Host(len); rr->net2Host(len);
break; break;
} }
case RtcpType::RTCP_SDES: { case RtcpType::RTCP_SDES: {
RtcpSdes *sdes = (RtcpSdes *) this; RtcpSdes *sdes = (RtcpSdes *)this;
sdes->net2Host(len); sdes->net2Host(len);
break; break;
} }
case RtcpType::RTCP_RTPFB: case RtcpType::RTCP_RTPFB:
case RtcpType::RTCP_PSFB: { case RtcpType::RTCP_PSFB: {
RtcpFB *fb = (RtcpFB *) this; RtcpFB *fb = (RtcpFB *)this;
fb->net2Host(len); fb->net2Host(len);
break; break;
} }
case RtcpType::RTCP_BYE: { case RtcpType::RTCP_BYE: {
RtcpBye *bye = (RtcpBye *) this; RtcpBye *bye = (RtcpBye *)this;
bye->net2Host(len); bye->net2Host(len);
break; break;
}
case RtcpType::RTCP_XR: {
RtcpXRRRTR *xr = (RtcpXRRRTR *)this;
if (xr->bt == 4) {
xr->net2Host(len);
// TraceL<<xr->dumpString();
} else if (xr->bt == 5) {
RtcpXRDLRR *dlrr = (RtcpXRDLRR *)this;
dlrr->net2Host(len);
TraceL << dlrr->dumpString();
} else {
throw std::runtime_error(StrPrinter << "rtcp xr bt " << xr->bt << " not support");
} }
case RtcpType::RTCP_XR:{ break;
RtcpXRRRTR* xr = (RtcpXRRRTR*)this; }
if(xr->bt == 4){ default:
xr->net2Host(len); throw std::runtime_error(StrPrinter << "未处理的rtcp包:" << rtcpTypeToStr((RtcpType)this->pt));
//TraceL<<xr->dumpString();
}else if(xr->bt == 5){
RtcpXRDLRR* dlrr = (RtcpXRDLRR*)this;
dlrr->net2Host(len);
TraceL<<dlrr->dumpString();
}else{
throw std::runtime_error(StrPrinter << "rtcp xr bt " << xr->bt<<" not support");
}
break;
}
default: throw std::runtime_error(StrPrinter << "未处理的rtcp包:" << rtcpTypeToStr((RtcpType) this->pt));
} }
} }
@ -215,10 +229,10 @@ vector<RtcpHeader *> RtcpHeader::loadFromBytes(char *data, size_t len) {
vector<RtcpHeader *> ret; vector<RtcpHeader *> ret;
ssize_t remain = len; ssize_t remain = len;
char *ptr = data; char *ptr = data;
while (remain > (ssize_t) sizeof(RtcpHeader)) { while (remain > (ssize_t)sizeof(RtcpHeader)) {
RtcpHeader *rtcp = (RtcpHeader *) ptr; RtcpHeader *rtcp = (RtcpHeader *)ptr;
auto rtcp_len = rtcp->getSize(); auto rtcp_len = rtcp->getSize();
if (remain < (ssize_t) rtcp_len) { if (remain < (ssize_t)rtcp_len) {
WarnL << "非法的rtcp包,声明的长度超过实际数据长度"; WarnL << "非法的rtcp包,声明的长度超过实际数据长度";
break; break;
} }
@ -226,7 +240,7 @@ vector<RtcpHeader *> RtcpHeader::loadFromBytes(char *data, size_t len) {
rtcp->net2Host(rtcp_len); rtcp->net2Host(rtcp_len);
ret.emplace_back(rtcp); ret.emplace_back(rtcp);
} catch (std::exception &ex) { } catch (std::exception &ex) {
//不能处理的rtcp包或者无法解析的rtcp包忽略掉 // 不能处理的rtcp包或者无法解析的rtcp包忽略掉
WarnL << ex.what() << ",长度为:" << rtcp_len; WarnL << ex.what() << ",长度为:" << rtcp_len;
} }
ptr += rtcp_len; ptr += rtcp_len;
@ -237,19 +251,13 @@ vector<RtcpHeader *> RtcpHeader::loadFromBytes(char *data, size_t len) {
class BufferRtcp : public Buffer { class BufferRtcp : public Buffer {
public: public:
BufferRtcp(std::shared_ptr<RtcpHeader> rtcp) { BufferRtcp(std::shared_ptr<RtcpHeader> rtcp) { _rtcp = std::move(rtcp); }
_rtcp = std::move(rtcp);
}
~BufferRtcp() override {} ~BufferRtcp() override {}
char *data() const override { char *data() const override { return (char *)_rtcp.get(); }
return (char *) _rtcp.get();
}
size_t size() const override { size_t size() const override { return _rtcp->getSize(); }
return _rtcp->getSize();
}
private: private:
std::shared_ptr<RtcpHeader> _rtcp; std::shared_ptr<RtcpHeader> _rtcp;
@ -264,36 +272,34 @@ Buffer::Ptr RtcpHeader::toBuffer(std::shared_ptr<RtcpHeader> rtcp) {
std::shared_ptr<RtcpSR> RtcpSR::create(size_t item_count) { std::shared_ptr<RtcpSR> RtcpSR::create(size_t item_count) {
auto real_size = sizeof(RtcpSR) - sizeof(ReportItem) + item_count * sizeof(ReportItem); auto real_size = sizeof(RtcpSR) - sizeof(ReportItem) + item_count * sizeof(ReportItem);
auto bytes = alignSize(real_size); auto bytes = alignSize(real_size);
auto ptr = (RtcpSR *) new char[bytes]; auto ptr = (RtcpSR *)new char[bytes];
setupHeader(ptr, RtcpType::RTCP_SR, item_count, bytes); setupHeader(ptr, RtcpType::RTCP_SR, item_count, bytes);
setupPadding(ptr, bytes - real_size); setupPadding(ptr, bytes - real_size);
return std::shared_ptr<RtcpSR>(ptr, [](RtcpSR *ptr) { return std::shared_ptr<RtcpSR>(ptr, [](RtcpSR *ptr) { delete[] (char *)ptr; });
delete[] (char *) ptr;
});
} }
string RtcpSR::getNtpStamp() const { string RtcpSR::getNtpStamp() const {
struct timeval tv; struct timeval tv;
tv.tv_sec = ntpmsw - 0x83AA7E80; tv.tv_sec = ntpmsw - 0x83AA7E80;
tv.tv_usec = (decltype(tv.tv_usec)) (ntplsw / ((double) (((uint64_t) 1) << 32) * 1.0e-6)); tv.tv_usec = (decltype(tv.tv_usec))(ntplsw / ((double)(((uint64_t)1) << 32) * 1.0e-6));
return LogChannel::printTime(tv); return LogChannel::printTime(tv);
} }
uint64_t RtcpSR::getNtpUnixStampMS() const { uint64_t RtcpSR::getNtpUnixStampMS() const {
if (ntpmsw < 0x83AA7E80) { if (ntpmsw < 0x83AA7E80) {
//ntp时间戳起始时间为1900年但是utc时间戳起始时间为1970年两者相差0x83AA7E80秒 // ntp时间戳起始时间为1900年但是utc时间戳起始时间为1970年两者相差0x83AA7E80秒
//ntp时间戳不得早于1970年否则无法转换为utc时间戳 // ntp时间戳不得早于1970年否则无法转换为utc时间戳
return 0; return 0;
} }
struct timeval tv; struct timeval tv;
tv.tv_sec = ntpmsw - 0x83AA7E80; tv.tv_sec = ntpmsw - 0x83AA7E80;
tv.tv_usec = (decltype(tv.tv_usec)) (ntplsw / ((double) (((uint64_t) 1) << 32) * 1.0e-6)); tv.tv_usec = (decltype(tv.tv_usec))(ntplsw / ((double)(((uint64_t)1) << 32) * 1.0e-6));
return 1000 * tv.tv_sec + tv.tv_usec / 1000; return 1000 * tv.tv_sec + tv.tv_usec / 1000;
} }
void RtcpSR::setNtpStamp(struct timeval tv) { void RtcpSR::setNtpStamp(struct timeval tv) {
ntpmsw = htonl(tv.tv_sec + 0x83AA7E80); /* 0x83AA7E80 is the number of seconds from 1900 to 1970 */ ntpmsw = htonl(tv.tv_sec + 0x83AA7E80); /* 0x83AA7E80 is the number of seconds from 1900 to 1970 */
ntplsw = htonl((uint32_t) ((double) tv.tv_usec * (double) (((uint64_t) 1) << 32) * 1.0e-6)); ntplsw = htonl((uint32_t)((double)tv.tv_usec * (double)(((uint64_t)1) << 32) * 1.0e-6));
} }
void RtcpSR::setNtpStamp(uint64_t unix_stamp_ms) { void RtcpSR::setNtpStamp(uint64_t unix_stamp_ms) {
@ -313,7 +319,7 @@ string RtcpSR::dumpString() const {
printer << "rtpts:" << rtpts << "\r\n"; printer << "rtpts:" << rtpts << "\r\n";
printer << "packet_count:" << packet_count << "\r\n"; printer << "packet_count:" << packet_count << "\r\n";
printer << "octet_count:" << octet_count << "\r\n"; printer << "octet_count:" << octet_count << "\r\n";
auto items = ((RtcpSR *) this)->getItemList(); auto items = ((RtcpSR *)this)->getItemList();
auto i = 0; auto i = 0;
for (auto &item : items) { for (auto &item : items) {
printer << "---- item:" << i++ << " ----\r\n"; printer << "---- item:" << i++ << " ----\r\n";
@ -322,17 +328,19 @@ string RtcpSR::dumpString() const {
return std::move(printer); return std::move(printer);
} }
#define CHECK_MIN_SIZE(size, kMinSize) \ #define CHECK_MIN_SIZE(size, kMinSize) \
if (size < kMinSize) { \ if (size < kMinSize) { \
throw std::out_of_range(StrPrinter << rtcpTypeToStr((RtcpType)pt) << " 长度不足:" << size << " < " << kMinSize); \ throw std::out_of_range( \
} StrPrinter << rtcpTypeToStr((RtcpType)pt) << " 长度不足:" << size << " < " << kMinSize); \
}
#define CHECK_REPORT_COUNT(item_count) \ #define CHECK_REPORT_COUNT(item_count) \
/*修正个数防止getItemList时内存越界*/ \ /*修正个数防止getItemList时内存越界*/ \
if (report_count != item_count) { \ if (report_count != item_count) { \
WarnL << rtcpTypeToStr((RtcpType)pt) << " report_count 字段不正确,已修正为:" << (int)report_count << " -> " << item_count; \ WarnL << rtcpTypeToStr((RtcpType)pt) << " report_count 字段不正确,已修正为:" << (int)report_count << " -> " \
report_count = item_count; \ << item_count; \
} report_count = item_count; \
}
void RtcpSR::net2Host(size_t size) { void RtcpSR::net2Host(size_t size) {
static const size_t kMinSize = sizeof(RtcpSR) - sizeof(items); static const size_t kMinSize = sizeof(RtcpSR) - sizeof(items);
@ -347,7 +355,7 @@ void RtcpSR::net2Host(size_t size) {
ReportItem *ptr = &items; ReportItem *ptr = &items;
int item_count = 0; int item_count = 0;
for (int i = 0; i < (int) report_count && (char *) (ptr) + sizeof(ReportItem) <= (char *) (this) + size; ++i) { for (int i = 0; i < (int)report_count && (char *)(ptr) + sizeof(ReportItem) <= (char *)(this) + size; ++i) {
ptr->net2Host(); ptr->net2Host();
++ptr; ++ptr;
++item_count; ++item_count;
@ -358,7 +366,7 @@ void RtcpSR::net2Host(size_t size) {
vector<ReportItem *> RtcpSR::getItemList() { vector<ReportItem *> RtcpSR::getItemList() {
vector<ReportItem *> ret; vector<ReportItem *> ret;
ReportItem *ptr = &items; ReportItem *ptr = &items;
for (int i = 0; i < (int) report_count; ++i) { for (int i = 0; i < (int)report_count; ++i) {
ret.emplace_back(ptr); ret.emplace_back(ptr);
++ptr; ++ptr;
} }
@ -395,19 +403,17 @@ void ReportItem::net2Host() {
std::shared_ptr<RtcpRR> RtcpRR::create(size_t item_count) { std::shared_ptr<RtcpRR> RtcpRR::create(size_t item_count) {
auto real_size = sizeof(RtcpRR) - sizeof(ReportItem) + item_count * sizeof(ReportItem); auto real_size = sizeof(RtcpRR) - sizeof(ReportItem) + item_count * sizeof(ReportItem);
auto bytes = alignSize(real_size); auto bytes = alignSize(real_size);
auto ptr = (RtcpRR *) new char[bytes]; auto ptr = (RtcpRR *)new char[bytes];
setupHeader(ptr, RtcpType::RTCP_RR, item_count, bytes); setupHeader(ptr, RtcpType::RTCP_RR, item_count, bytes);
setupPadding(ptr, bytes - real_size); setupPadding(ptr, bytes - real_size);
return std::shared_ptr<RtcpRR>(ptr, [](RtcpRR *ptr) { return std::shared_ptr<RtcpRR>(ptr, [](RtcpRR *ptr) { delete[] (char *)ptr; });
delete[] (char *) ptr;
});
} }
string RtcpRR::dumpString() const { string RtcpRR::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << RtcpHeader::dumpHeader(); printer << RtcpHeader::dumpHeader();
printer << "ssrc:" << ssrc << "\r\n"; printer << "ssrc:" << ssrc << "\r\n";
auto items = ((RtcpRR *) this)->getItemList(); auto items = ((RtcpRR *)this)->getItemList();
auto i = 0; auto i = 0;
for (auto &item : items) { for (auto &item : items) {
printer << "---- item:" << i++ << " ----\r\n"; printer << "---- item:" << i++ << " ----\r\n";
@ -423,7 +429,7 @@ void RtcpRR::net2Host(size_t size) {
ReportItem *ptr = &items; ReportItem *ptr = &items;
int item_count = 0; int item_count = 0;
for (int i = 0; i < (int) report_count && (char *) (ptr) + sizeof(ReportItem) <= (char *) (this) + size; ++i) { for (int i = 0; i < (int)report_count && (char *)(ptr) + sizeof(ReportItem) <= (char *)(this) + size; ++i) {
ptr->net2Host(); ptr->net2Host();
++ptr; ++ptr;
++item_count; ++item_count;
@ -434,7 +440,7 @@ void RtcpRR::net2Host(size_t size) {
vector<ReportItem *> RtcpRR::getItemList() { vector<ReportItem *> RtcpRR::getItemList() {
vector<ReportItem *> ret; vector<ReportItem *> ret;
ReportItem *ptr = &items; ReportItem *ptr = &items;
for (int i = 0; i < (int) report_count; ++i) { for (int i = 0; i < (int)report_count; ++i) {
ret.emplace_back(ptr); ret.emplace_back(ptr);
++ptr; ++ptr;
} }
@ -458,8 +464,8 @@ size_t SdesChunk::minSize() {
string SdesChunk::dumpString() const { string SdesChunk::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << "ssrc:" << ssrc << "\r\n"; printer << "ssrc:" << ssrc << "\r\n";
printer << "type:" << sdesTypeToStr((SdesType) type) << "\r\n"; printer << "type:" << sdesTypeToStr((SdesType)type) << "\r\n";
printer << "txt_len:" << (int) txt_len << "\r\n"; printer << "txt_len:" << (int)txt_len << "\r\n";
printer << "text:" << (txt_len ? string(text, txt_len) : "") << "\r\n"; printer << "text:" << (txt_len ? string(text, txt_len) : "") << "\r\n";
return std::move(printer); return std::move(printer);
} }
@ -469,32 +475,30 @@ string SdesChunk::dumpString() const {
std::shared_ptr<RtcpSdes> RtcpSdes::create(const std::vector<string> &item_text) { std::shared_ptr<RtcpSdes> RtcpSdes::create(const std::vector<string> &item_text) {
size_t item_total_size = 0; size_t item_total_size = 0;
for (auto &text : item_text) { for (auto &text : item_text) {
//统计所有SdesChunk对象占用的空间 // 统计所有SdesChunk对象占用的空间
item_total_size += alignSize(SdesChunk::minSize() + (0xFF & text.size())); item_total_size += alignSize(SdesChunk::minSize() + (0xFF & text.size()));
} }
auto real_size = sizeof(RtcpSdes) - sizeof(SdesChunk) + item_total_size; auto real_size = sizeof(RtcpSdes) - sizeof(SdesChunk) + item_total_size;
auto bytes = alignSize(real_size); auto bytes = alignSize(real_size);
auto ptr = (RtcpSdes *) new char[bytes]; auto ptr = (RtcpSdes *)new char[bytes];
memset(ptr, 0x00, bytes); memset(ptr, 0x00, bytes);
auto item_ptr = &ptr->chunks; auto item_ptr = &ptr->chunks;
for (auto &text : item_text) { for (auto &text : item_text) {
item_ptr->txt_len = (0xFF & text.size()); item_ptr->txt_len = (0xFF & text.size());
//确保赋值\0为RTCP_SDES_END // 确保赋值\0为RTCP_SDES_END
memcpy(item_ptr->text, text.data(), item_ptr->txt_len + 1); memcpy(item_ptr->text, text.data(), item_ptr->txt_len + 1);
item_ptr = (SdesChunk *) ((char *) item_ptr + item_ptr->totalBytes()); item_ptr = (SdesChunk *)((char *)item_ptr + item_ptr->totalBytes());
} }
setupHeader(ptr, RtcpType::RTCP_SDES, item_text.size(), bytes); setupHeader(ptr, RtcpType::RTCP_SDES, item_text.size(), bytes);
setupPadding(ptr, bytes - real_size); setupPadding(ptr, bytes - real_size);
return std::shared_ptr<RtcpSdes>(ptr, [](RtcpSdes *ptr) { return std::shared_ptr<RtcpSdes>(ptr, [](RtcpSdes *ptr) { delete[] (char *)ptr; });
delete[] (char *) ptr;
});
} }
string RtcpSdes::dumpString() const { string RtcpSdes::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << RtcpHeader::dumpHeader(); printer << RtcpHeader::dumpHeader();
auto items = ((RtcpSdes *) this)->getChunkList(); auto items = ((RtcpSdes *)this)->getChunkList();
auto i = 0; auto i = 0;
for (auto &item : items) { for (auto &item : items) {
printer << "---- item:" << i++ << " ----\r\n"; printer << "---- item:" << i++ << " ----\r\n";
@ -508,9 +512,9 @@ void RtcpSdes::net2Host(size_t size) {
CHECK_MIN_SIZE(size, kMinSize); CHECK_MIN_SIZE(size, kMinSize);
SdesChunk *ptr = &chunks; SdesChunk *ptr = &chunks;
int item_count = 0; int item_count = 0;
for (int i = 0; i < (int) report_count && (char *) (ptr) + SdesChunk::minSize() <= (char *) (this) + size; ++i) { for (int i = 0; i < (int)report_count && (char *)(ptr) + SdesChunk::minSize() <= (char *)(this) + size; ++i) {
ptr->net2Host(); ptr->net2Host();
ptr = (SdesChunk *) ((char *) ptr + ptr->totalBytes()); ptr = (SdesChunk *)((char *)ptr + ptr->totalBytes());
++item_count; ++item_count;
} }
CHECK_REPORT_COUNT(item_count); CHECK_REPORT_COUNT(item_count);
@ -519,9 +523,9 @@ void RtcpSdes::net2Host(size_t size) {
vector<SdesChunk *> RtcpSdes::getChunkList() { vector<SdesChunk *> RtcpSdes::getChunkList() {
vector<SdesChunk *> ret; vector<SdesChunk *> ret;
SdesChunk *ptr = &chunks; SdesChunk *ptr = &chunks;
for (int i = 0; i < (int) report_count; ++i) { for (int i = 0; i < (int)report_count; ++i) {
ret.emplace_back(ptr); ret.emplace_back(ptr);
ptr = (SdesChunk *) ((char *) ptr + ptr->totalBytes()); ptr = (SdesChunk *)((char *)ptr + ptr->totalBytes());
} }
return ret; return ret;
} }
@ -534,31 +538,29 @@ std::shared_ptr<RtcpFB> RtcpFB::create_l(RtcpType type, int fmt, const void *fci
} }
auto real_size = sizeof(RtcpFB) + fci_len; auto real_size = sizeof(RtcpFB) + fci_len;
auto bytes = alignSize(real_size); auto bytes = alignSize(real_size);
auto ptr = (RtcpFB *) new char[bytes]; auto ptr = (RtcpFB *)new char[bytes];
if (fci && fci_len) { if (fci && fci_len) {
memcpy((char *) ptr + sizeof(RtcpFB), fci, fci_len); memcpy((char *)ptr + sizeof(RtcpFB), fci, fci_len);
} }
setupHeader(ptr, type, fmt, bytes); setupHeader(ptr, type, fmt, bytes);
setupPadding(ptr, bytes - real_size); setupPadding(ptr, bytes - real_size);
return std::shared_ptr<RtcpFB>((RtcpFB *) ptr, [](RtcpFB *ptr) { return std::shared_ptr<RtcpFB>((RtcpFB *)ptr, [](RtcpFB *ptr) { delete[] (char *)ptr; });
delete[] (char *) ptr;
});
} }
std::shared_ptr<RtcpFB> RtcpFB::create(PSFBType fmt, const void *fci, size_t fci_len) { std::shared_ptr<RtcpFB> RtcpFB::create(PSFBType fmt, const void *fci, size_t fci_len) {
return RtcpFB::create_l(RtcpType::RTCP_PSFB, (int) fmt, fci, fci_len); return RtcpFB::create_l(RtcpType::RTCP_PSFB, (int)fmt, fci, fci_len);
} }
std::shared_ptr<RtcpFB> RtcpFB::create(RTPFBType fmt, const void *fci, size_t fci_len) { std::shared_ptr<RtcpFB> RtcpFB::create(RTPFBType fmt, const void *fci, size_t fci_len) {
return RtcpFB::create_l(RtcpType::RTCP_RTPFB, (int) fmt, fci, fci_len); return RtcpFB::create_l(RtcpType::RTCP_RTPFB, (int)fmt, fci, fci_len);
} }
const void *RtcpFB::getFciPtr() const { const void *RtcpFB::getFciPtr() const {
return (uint8_t *) &ssrc_media + sizeof(ssrc_media); return (uint8_t *)&ssrc_media + sizeof(ssrc_media);
} }
size_t RtcpFB::getFciSize() const { size_t RtcpFB::getFciSize() const {
auto fci_len = (ssize_t) getSize() - getPaddingSize() - sizeof(RtcpFB); auto fci_len = (ssize_t)getSize() - getPaddingSize() - sizeof(RtcpFB);
CHECK(fci_len >= 0); CHECK(fci_len >= 0);
return fci_len; return fci_len;
} }
@ -568,58 +570,60 @@ string RtcpFB::dumpString() const {
printer << RtcpHeader::dumpHeader(); printer << RtcpHeader::dumpHeader();
printer << "ssrc:" << ssrc << "\r\n"; printer << "ssrc:" << ssrc << "\r\n";
printer << "ssrc_media:" << ssrc_media << "\r\n"; printer << "ssrc_media:" << ssrc_media << "\r\n";
switch ((RtcpType) pt) { switch ((RtcpType)pt) {
case RtcpType::RTCP_PSFB : { case RtcpType::RTCP_PSFB: {
switch ((PSFBType) report_count) { switch ((PSFBType)report_count) {
case PSFBType::RTCP_PSFB_SLI : { case PSFBType::RTCP_PSFB_SLI: {
auto &fci = getFci<FCI_SLI>(); auto &fci = getFci<FCI_SLI>();
printer << "fci:" << psfbTypeToStr((PSFBType) report_count) << " " << fci.dumpString(); printer << "fci:" << psfbTypeToStr((PSFBType)report_count) << " " << fci.dumpString();
break;
}
case PSFBType::RTCP_PSFB_PLI : {
getFciSize();
printer << "fci:" << psfbTypeToStr((PSFBType) report_count);
break;
}
case PSFBType::RTCP_PSFB_FIR : {
auto &fci = getFci<FCI_FIR>();
printer << "fci:" << psfbTypeToStr((PSFBType) report_count) << " " << fci.dumpString();
break;
}
case PSFBType::RTCP_PSFB_REMB : {
auto &fci = getFci<FCI_REMB>();
printer << "fci:" << psfbTypeToStr((PSFBType) report_count) << " " << fci.dumpString();
break;
}
default:{
printer << "fci:" << psfbTypeToStr((PSFBType) report_count) << " " << hexdump(getFciPtr(), getFciSize());
break;
}
}
break; break;
} }
case RtcpType::RTCP_RTPFB : { case PSFBType::RTCP_PSFB_PLI: {
switch ((RTPFBType) report_count) { getFciSize();
case RTPFBType::RTCP_RTPFB_NACK : { printer << "fci:" << psfbTypeToStr((PSFBType)report_count);
auto &fci = getFci<FCI_NACK>();
printer << "fci:" << rtpfbTypeToStr((RTPFBType) report_count) << " " << fci.dumpString();
break;
}
case RTPFBType::RTCP_RTPFB_TWCC : {
auto &fci = getFci<FCI_TWCC>();
printer << "fci:" << rtpfbTypeToStr((RTPFBType) report_count) << " " << fci.dumpString(getFciSize());
break;
}
default: {
printer << "fci:" << rtpfbTypeToStr((RTPFBType) report_count) << " " << hexdump(getFciPtr(), getFciSize());
break;
}
}
break; break;
} }
default: /*不可达*/ assert(0); break;
case PSFBType::RTCP_PSFB_FIR: {
auto &fci = getFci<FCI_FIR>();
printer << "fci:" << psfbTypeToStr((PSFBType)report_count) << " " << fci.dumpString();
break;
}
case PSFBType::RTCP_PSFB_REMB: {
auto &fci = getFci<FCI_REMB>();
printer << "fci:" << psfbTypeToStr((PSFBType)report_count) << " " << fci.dumpString();
break;
}
default: {
printer << "fci:" << psfbTypeToStr((PSFBType)report_count) << " " << hexdump(getFciPtr(), getFciSize());
break;
}
}
break;
}
case RtcpType::RTCP_RTPFB: {
switch ((RTPFBType)report_count) {
case RTPFBType::RTCP_RTPFB_NACK: {
auto &fci = getFci<FCI_NACK>();
printer << "fci:" << rtpfbTypeToStr((RTPFBType)report_count) << " " << fci.dumpString();
break;
}
case RTPFBType::RTCP_RTPFB_TWCC: {
auto &fci = getFci<FCI_TWCC>();
printer << "fci:" << rtpfbTypeToStr((RTPFBType)report_count) << " " << fci.dumpString(getFciSize());
break;
}
default: {
printer << "fci:" << rtpfbTypeToStr((RTPFBType)report_count) << " " << hexdump(getFciPtr(), getFciSize());
break;
}
}
break;
}
default: /*不可达*/
assert(0);
break;
} }
return std::move(printer); return std::move(printer);
} }
@ -637,24 +641,22 @@ std::shared_ptr<RtcpBye> RtcpBye::create(const std::vector<uint32_t> &ssrcs, con
assert(reason.size() <= 0xFF); assert(reason.size() <= 0xFF);
auto real_size = sizeof(RtcpHeader) + sizeof(uint32_t) * ssrcs.size() + 1 + reason.size(); auto real_size = sizeof(RtcpHeader) + sizeof(uint32_t) * ssrcs.size() + 1 + reason.size();
auto bytes = alignSize(real_size); auto bytes = alignSize(real_size);
auto ptr = (RtcpBye *) new char[bytes]; auto ptr = (RtcpBye *)new char[bytes];
setupHeader(ptr, RtcpType::RTCP_BYE, ssrcs.size(), bytes); setupHeader(ptr, RtcpType::RTCP_BYE, ssrcs.size(), bytes);
setupPadding(ptr, bytes - real_size); setupPadding(ptr, bytes - real_size);
int i = 0; int i = 0;
for (auto ssrc : ssrcs) { for (auto ssrc : ssrcs) {
((RtcpBye *) ptr)->ssrc[i++] = htonl(ssrc); ((RtcpBye *)ptr)->ssrc[i++] = htonl(ssrc);
} }
if (!reason.empty()) { if (!reason.empty()) {
uint8_t *reason_len_ptr = (uint8_t *) ptr + sizeof(RtcpHeader) + sizeof(uint32_t) * ssrcs.size(); uint8_t *reason_len_ptr = (uint8_t *)ptr + sizeof(RtcpHeader) + sizeof(uint32_t) * ssrcs.size();
*reason_len_ptr = reason.size() & 0xFF; *reason_len_ptr = reason.size() & 0xFF;
memcpy(reason_len_ptr + 1, reason.data(), *reason_len_ptr); memcpy(reason_len_ptr + 1, reason.data(), *reason_len_ptr);
} }
return std::shared_ptr<RtcpBye>(ptr, [](RtcpBye *ptr) { return std::shared_ptr<RtcpBye>(ptr, [](RtcpBye *ptr) { delete[] (char *)ptr; });
delete[] (char *) ptr;
});
} }
vector<uint32_t *> RtcpBye::getSSRC() { vector<uint32_t *> RtcpBye::getSSRC() {
@ -667,16 +669,16 @@ vector<uint32_t *> RtcpBye::getSSRC() {
string RtcpBye::getReason() const { string RtcpBye::getReason() const {
auto *reason_len_ptr = &reason_len + sizeof(ssrc) * (report_count - 1); auto *reason_len_ptr = &reason_len + sizeof(ssrc) * (report_count - 1);
if (reason_len_ptr + 1 >= (uint8_t *) this + getSize()) { if (reason_len_ptr + 1 >= (uint8_t *)this + getSize()) {
return ""; return "";
} }
return string((char *) reason_len_ptr + 1, *reason_len_ptr); return string((char *)reason_len_ptr + 1, *reason_len_ptr);
} }
string RtcpBye::dumpString() const { string RtcpBye::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << RtcpHeader::dumpHeader(); printer << RtcpHeader::dumpHeader();
for (auto ssrc : ((RtcpBye *) this)->getSSRC()) { for (auto ssrc : ((RtcpBye *)this)->getSSRC()) {
printer << "ssrc:" << *ssrc << "\r\n"; printer << "ssrc:" << *ssrc << "\r\n";
} }
printer << "reason:" << getReason(); printer << "reason:" << getReason();
@ -692,15 +694,15 @@ void RtcpBye::net2Host(size_t size) {
ssrc[i] = ntohl(ssrc[i]); ssrc[i] = ntohl(ssrc[i]);
offset += sizeof(ssrc); offset += sizeof(ssrc);
} }
//修正ssrc个数 // 修正ssrc个数
CHECK_REPORT_COUNT(i); CHECK_REPORT_COUNT(i);
if (offset < size) { if (offset < size) {
uint8_t *reason_len_ptr = &reason_len + sizeof(ssrc) * (report_count - 1); uint8_t *reason_len_ptr = &reason_len + sizeof(ssrc) * (report_count - 1);
if (reason_len_ptr + 1 + *reason_len_ptr > (uint8_t *) this + size) { if (reason_len_ptr + 1 + *reason_len_ptr > (uint8_t *)this + size) {
WarnL << "invalid rtcp bye reason length"; WarnL << "invalid rtcp bye reason length";
//修正reason_len长度 // 修正reason_len长度
*reason_len_ptr = ((uint8_t *) this + size - reason_len_ptr - 1) & 0xFF; *reason_len_ptr = ((uint8_t *)this + size - reason_len_ptr - 1) & 0xFF;
} }
} }
} }
@ -708,19 +710,21 @@ void RtcpBye::net2Host(size_t size) {
string RtcpXRRRTR::dumpString() const { string RtcpXRRRTR::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << RtcpHeader::dumpHeader(); printer << RtcpHeader::dumpHeader();
printer << "ssrc :" <<ssrc<<"\r\n"; printer << "ssrc :" << ssrc << "\r\n";
printer << "bt :" <<(int)bt<<"\r\n"; printer << "bt :" << (int)bt << "\r\n";
printer << "block_length : "<<block_length<<"\r\n"; printer << "block_length : " << block_length << "\r\n";
printer << "ntp msw : "<<ntpmsw<<"\r\n"; printer << "ntp msw : " << ntpmsw << "\r\n";
printer << "ntp lsw : "<<ntplsw<<"\r\n"; printer << "ntp lsw : " << ntplsw << "\r\n";
return std::move(printer); return std::move(printer);
} }
void RtcpXRRRTR::net2Host(size_t size) { void RtcpXRRRTR::net2Host(size_t size) {
static const size_t kMinSize = sizeof(RtcpHeader); static const size_t kMinSize = sizeof(RtcpHeader);
CHECK_MIN_SIZE(size, kMinSize); CHECK_MIN_SIZE(size, kMinSize);
if(size != sizeof(RtcpXRRRTR)){ if (size != sizeof(RtcpXRRRTR)) {
throw std::invalid_argument(StrPrinter << "rtcp xr Receiver Reference Time Report Block must is " << sizeof(RtcpXRRRTR)<<" actual size "<<size); throw std::invalid_argument(
StrPrinter << "rtcp xr Receiver Reference Time Report Block must is " << sizeof(RtcpXRRRTR)
<< " actual size " << size);
} }
ssrc = ntohl(ssrc); ssrc = ntohl(ssrc);
block_length = ntohs(block_length); block_length = ntohs(block_length);
@ -728,13 +732,12 @@ void RtcpXRRRTR::net2Host(size_t size) {
ntplsw = ntohl(ntplsw); ntplsw = ntohl(ntplsw);
} }
string RtcpXRDLRRReportItem::dumpString() const { string RtcpXRDLRRReportItem::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << "ssrc :" <<ssrc<<"\r\n"; printer << "ssrc :" << ssrc << "\r\n";
printer << "last RR (lrr) :" <<lrr<<"\r\n"; printer << "last RR (lrr) :" << lrr << "\r\n";
printer << "delay since last RR (dlrr): "<<dlrr<<"\r\n"; printer << "delay since last RR (dlrr): " << dlrr << "\r\n";
return std::move(printer); return std::move(printer);
} }
@ -745,24 +748,23 @@ void RtcpXRDLRRReportItem::net2Host() {
dlrr = ntohl(dlrr); dlrr = ntohl(dlrr);
} }
std::vector<RtcpXRDLRRReportItem*> RtcpXRDLRR::getItemList(){ std::vector<RtcpXRDLRRReportItem *> RtcpXRDLRR::getItemList() {
auto count = block_length/3; auto count = block_length / 3;
RtcpXRDLRRReportItem *ptr = &items; RtcpXRDLRRReportItem *ptr = &items;
vector<RtcpXRDLRRReportItem *> ret; vector<RtcpXRDLRRReportItem *> ret;
for (int i = 0; i < (int) count; ++i) { for (int i = 0; i < (int)count; ++i) {
ret.emplace_back(ptr); ret.emplace_back(ptr);
++ptr; ++ptr;
} }
return ret; return ret;
} }
string RtcpXRDLRR::dumpString() const { string RtcpXRDLRR::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << RtcpHeader::dumpHeader(); printer << RtcpHeader::dumpHeader();
printer << "ssrc :" <<ssrc<<"\r\n"; printer << "ssrc :" << ssrc << "\r\n";
printer << "bt :" <<(int)bt<<"\r\n"; printer << "bt :" << (int)bt << "\r\n";
printer << "block_length : "<<block_length<<"\r\n"; printer << "block_length : " << block_length << "\r\n";
auto items_list = ((RtcpXRDLRR *) this)->getItemList(); auto items_list = ((RtcpXRDLRR *)this)->getItemList();
auto i = 0; auto i = 0;
for (auto &item : items_list) { for (auto &item : items_list) {
printer << "---- item:" << i++ << " ----\r\n"; printer << "---- item:" << i++ << " ----\r\n";
@ -778,23 +780,21 @@ void RtcpXRDLRR::net2Host(size_t size) {
ssrc = ntohl(ssrc); ssrc = ntohl(ssrc);
block_length = ntohs(block_length); block_length = ntohs(block_length);
auto count = block_length/3; auto count = block_length / 3;
for (int i = 0; i < (int) count; ++i) { for (int i = 0; i < (int)count; ++i) {
RtcpXRDLRRReportItem *ptr = &items; RtcpXRDLRRReportItem *ptr = &items;
ptr->net2Host(); ptr->net2Host();
ptr++; ptr++;
} }
} }
std::shared_ptr<RtcpXRDLRR> RtcpXRDLRR::create(size_t item_count){ std::shared_ptr<RtcpXRDLRR> RtcpXRDLRR::create(size_t item_count) {
auto real_size = sizeof(RtcpXRDLRR) - sizeof(RtcpXRDLRRReportItem) + item_count * sizeof(RtcpXRDLRRReportItem); auto real_size = sizeof(RtcpXRDLRR) - sizeof(RtcpXRDLRRReportItem) + item_count * sizeof(RtcpXRDLRRReportItem);
auto bytes = alignSize(real_size); auto bytes = alignSize(real_size);
auto ptr = (RtcpXRDLRR *) new char[bytes]; auto ptr = (RtcpXRDLRR *)new char[bytes];
setupHeader(ptr, RtcpType::RTCP_XR, 0, bytes); setupHeader(ptr, RtcpType::RTCP_XR, 0, bytes);
setupPadding(ptr, bytes - real_size); setupPadding(ptr, bytes - real_size);
return std::shared_ptr<RtcpXRDLRR>(ptr, [](RtcpXRDLRR *ptr) { return std::shared_ptr<RtcpXRDLRR>(ptr, [](RtcpXRDLRR *ptr) { delete[] (char *)ptr; });
delete[] (char *) ptr;
});
} }
#if 0 #if 0
@ -811,4 +811,4 @@ static toolkit::onceToken token([](){
}); });
#endif #endif
}//namespace mediakit } // namespace mediakit

341
src/Rtcp/Rtcp.h
View File

@ -11,11 +11,11 @@
#ifndef ZLMEDIAKIT_RTCP_H #ifndef ZLMEDIAKIT_RTCP_H
#define ZLMEDIAKIT_RTCP_H #define ZLMEDIAKIT_RTCP_H
#include "Common/macros.h"
#include "Network/Buffer.h"
#include "Util/util.h"
#include <stdint.h> #include <stdint.h>
#include <vector> #include <vector>
#include "Util/util.h"
#include "Network/Buffer.h"
#include "Common/macros.h"
namespace mediakit { namespace mediakit {
@ -23,115 +23,115 @@ namespace mediakit {
#pragma pack(push, 1) #pragma pack(push, 1)
#endif // defined(_WIN32) #endif // defined(_WIN32)
//http://www.networksorcery.com/enp/protocol/rtcp.htm // http://www.networksorcery.com/enp/protocol/rtcp.htm
#define RTCP_PT_MAP(XX) \ #define RTCP_PT_MAP(XX) \
XX(RTCP_FIR, 192) \ XX(RTCP_FIR, 192) \
XX(RTCP_NACK, 193) \ XX(RTCP_NACK, 193) \
XX(RTCP_SMPTETC, 194) \ XX(RTCP_SMPTETC, 194) \
XX(RTCP_IJ, 195) \ XX(RTCP_IJ, 195) \
XX(RTCP_SR, 200) \ XX(RTCP_SR, 200) \
XX(RTCP_RR, 201) \ XX(RTCP_RR, 201) \
XX(RTCP_SDES, 202) \ XX(RTCP_SDES, 202) \
XX(RTCP_BYE, 203) \ XX(RTCP_BYE, 203) \
XX(RTCP_APP, 204) \ XX(RTCP_APP, 204) \
XX(RTCP_RTPFB, 205) \ XX(RTCP_RTPFB, 205) \
XX(RTCP_PSFB, 206) \ XX(RTCP_PSFB, 206) \
XX(RTCP_XR, 207) \ XX(RTCP_XR, 207) \
XX(RTCP_AVB, 208) \ XX(RTCP_AVB, 208) \
XX(RTCP_RSI, 209) \ XX(RTCP_RSI, 209) \
XX(RTCP_TOKEN, 210) XX(RTCP_TOKEN, 210)
//https://tools.ietf.org/html/rfc3550#section-6.5 // https://tools.ietf.org/html/rfc3550#section-6.5
#define SDES_TYPE_MAP(XX) \ #define SDES_TYPE_MAP(XX) \
XX(RTCP_SDES_END, 0) \ XX(RTCP_SDES_END, 0) \
XX(RTCP_SDES_CNAME, 1) \ XX(RTCP_SDES_CNAME, 1) \
XX(RTCP_SDES_NAME, 2) \ XX(RTCP_SDES_NAME, 2) \
XX(RTCP_SDES_EMAIL, 3) \ XX(RTCP_SDES_EMAIL, 3) \
XX(RTCP_SDES_PHONE, 4) \ XX(RTCP_SDES_PHONE, 4) \
XX(RTCP_SDES_LOC, 5) \ XX(RTCP_SDES_LOC, 5) \
XX(RTCP_SDES_TOOL, 6) \ XX(RTCP_SDES_TOOL, 6) \
XX(RTCP_SDES_NOTE, 7) \ XX(RTCP_SDES_NOTE, 7) \
XX(RTCP_SDES_PRIVATE, 8) XX(RTCP_SDES_PRIVATE, 8)
//https://datatracker.ietf.org/doc/rfc4585/?include_text=1 // https://datatracker.ietf.org/doc/rfc4585/?include_text=1
//6.3. Payload-Specific Feedback Messages // 6.3. Payload-Specific Feedback Messages
// //
// Payload-Specific FB messages are identified by the value PT=PSFB as // Payload-Specific FB messages are identified by the value PT=PSFB as
// RTCP message type. // RTCP message type.
// //
// Three payload-specific FB messages are defined so far plus an // Three payload-specific FB messages are defined so far plus an
// application layer FB message. They are identified by means of the // application layer FB message. They are identified by means of the
// FMT parameter as follows: // FMT parameter as follows:
// //
// 0: unassigned // 0: unassigned
// 1: Picture Loss Indication (PLI) // 1: Picture Loss Indication (PLI)
// 2: Slice Loss Indication (SLI) // 2: Slice Loss Indication (SLI)
// 3: Reference Picture Selection Indication (RPSI) // 3: Reference Picture Selection Indication (RPSI)
// 4: FIR https://tools.ietf.org/html/rfc5104#section-4.3.1.1 // 4: FIR https://tools.ietf.org/html/rfc5104#section-4.3.1.1
// 5: TSTR https://tools.ietf.org/html/rfc5104#section-4.3.2.1 // 5: TSTR https://tools.ietf.org/html/rfc5104#section-4.3.2.1
// 6: TSTN https://tools.ietf.org/html/rfc5104#section-4.3.2.1 // 6: TSTN https://tools.ietf.org/html/rfc5104#section-4.3.2.1
// 7: VBCM https://tools.ietf.org/html/rfc5104#section-4.3.4.1 // 7: VBCM https://tools.ietf.org/html/rfc5104#section-4.3.4.1
// 8-14: unassigned // 8-14: unassigned
// 15: REMB / Application layer FB (AFB) message, https://tools.ietf.org/html/draft-alvestrand-rmcat-remb-03 // 15: REMB / Application layer FB (AFB) message, https://tools.ietf.org/html/draft-alvestrand-rmcat-remb-03
// 16-30: unassigned // 16-30: unassigned
// 31: reserved for future expansion of the sequence number space // 31: reserved for future expansion of the sequence number space
#define PSFB_TYPE_MAP(XX) \ #define PSFB_TYPE_MAP(XX) \
XX(RTCP_PSFB_PLI, 1) \ XX(RTCP_PSFB_PLI, 1) \
XX(RTCP_PSFB_SLI, 2) \ XX(RTCP_PSFB_SLI, 2) \
XX(RTCP_PSFB_RPSI, 3) \ XX(RTCP_PSFB_RPSI, 3) \
XX(RTCP_PSFB_FIR, 4) \ XX(RTCP_PSFB_FIR, 4) \
XX(RTCP_PSFB_TSTR, 5)\ XX(RTCP_PSFB_TSTR, 5) \
XX(RTCP_PSFB_TSTN, 6)\ XX(RTCP_PSFB_TSTN, 6) \
XX(RTCP_PSFB_VBCM, 7) \ XX(RTCP_PSFB_VBCM, 7) \
XX(RTCP_PSFB_REMB, 15) XX(RTCP_PSFB_REMB, 15)
//https://tools.ietf.org/html/rfc4585#section-6.2 // https://tools.ietf.org/html/rfc4585#section-6.2
//6.2. Transport Layer Feedback Messages // 6.2. Transport Layer Feedback Messages
// //
// Transport layer FB messages are identified by the value RTPFB as RTCP // Transport layer FB messages are identified by the value RTPFB as RTCP
// message type. // message type.
// //
// A single general purpose transport layer FB message is defined in // A single general purpose transport layer FB message is defined in
// this document: Generic NACK. It is identified by means of the FMT // this document: Generic NACK. It is identified by means of the FMT
// parameter as follows: // parameter as follows:
// //
// 0: unassigned // 0: unassigned
// 1: Generic NACK // 1: Generic NACK
// 2: reserved https://tools.ietf.org/html/rfc5104#section-4.2 // 2: reserved https://tools.ietf.org/html/rfc5104#section-4.2
// 3: TMMBR https://tools.ietf.org/html/rfc5104#section-4.2.1.1 // 3: TMMBR https://tools.ietf.org/html/rfc5104#section-4.2.1.1
// 4: TMMBN https://tools.ietf.org/html/rfc5104#section-4.2.2.1 // 4: TMMBN https://tools.ietf.org/html/rfc5104#section-4.2.2.1
// 5-14: unassigned // 5-14: unassigned
// 15 transport-cc https://tools.ietf.org/html/draft-holmer-rmcat-transport-wide-cc-extensions-01 // 15 transport-cc https://tools.ietf.org/html/draft-holmer-rmcat-transport-wide-cc-extensions-01
// 16-30: unassigned // 16-30: unassigned
// 31: reserved for future expansion of the identifier number space // 31: reserved for future expansion of the identifier number space
#define RTPFB_TYPE_MAP(XX) \ #define RTPFB_TYPE_MAP(XX) \
XX(RTCP_RTPFB_NACK, 1) \ XX(RTCP_RTPFB_NACK, 1) \
XX(RTCP_RTPFB_TMMBR, 3) \ XX(RTCP_RTPFB_TMMBR, 3) \
XX(RTCP_RTPFB_TMMBN, 4) \ XX(RTCP_RTPFB_TMMBN, 4) \
XX(RTCP_RTPFB_TWCC, 15) XX(RTCP_RTPFB_TWCC, 15)
//rtcp类型枚举 // rtcp类型枚举
enum class RtcpType : uint8_t { enum class RtcpType : uint8_t {
#define XX(key, value) key = value, #define XX(key, value) key = value,
RTCP_PT_MAP(XX) RTCP_PT_MAP(XX)
#undef XX #undef XX
}; };
//sdes类型枚举 // sdes类型枚举
enum class SdesType : uint8_t { enum class SdesType : uint8_t {
#define XX(key, value) key = value, #define XX(key, value) key = value,
SDES_TYPE_MAP(XX) SDES_TYPE_MAP(XX)
#undef XX #undef XX
}; };
//psfb类型枚举 // psfb类型枚举
enum class PSFBType : uint8_t { enum class PSFBType : uint8_t {
#define XX(key, value) key = value, #define XX(key, value) key = value,
PSFB_TYPE_MAP(XX) PSFB_TYPE_MAP(XX)
#undef XX #undef XX
}; };
//rtpfb类型枚举 // rtpfb类型枚举
enum class RTPFBType : uint8_t { enum class RTPFBType : uint8_t {
#define XX(key, value) key = value, #define XX(key, value) key = value,
RTPFB_TYPE_MAP(XX) RTPFB_TYPE_MAP(XX)
@ -161,26 +161,26 @@ const char *rtpfbTypeToStr(RTPFBType type);
class RtcpHeader { class RtcpHeader {
public: public:
#if __BYTE_ORDER == __BIG_ENDIAN #if __BYTE_ORDER == __BIG_ENDIAN
//版本号固定为2 // 版本号固定为2
uint32_t version: 2; uint32_t version : 2;
//padding固定为0 // padding固定为0
uint32_t padding: 1; uint32_t padding : 1;
//reception report count // reception report count
uint32_t report_count: 5; uint32_t report_count : 5;
#else #else
//reception report count // reception report count
uint32_t report_count: 5; uint32_t report_count : 5;
//padding末尾是否有追加填充 // padding末尾是否有追加填充
uint32_t padding: 1; uint32_t padding : 1;
//版本号固定为2 // 版本号固定为2
uint32_t version: 2; uint32_t version : 2;
#endif #endif
//rtcp类型,RtcpType // rtcp类型,RtcpType
uint32_t pt: 8; uint32_t pt : 8;
private: private:
//长度 // 长度
uint32_t length: 16; uint32_t length : 16;
public: public:
/** /**
@ -222,7 +222,6 @@ public:
void setSize(size_t size); void setSize(size_t size);
protected: protected:
/** /**
* *
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
@ -240,26 +239,26 @@ private:
///////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////
//ReportBlock // ReportBlock
class ReportItem { class ReportItem {
public: public:
friend class RtcpSR; friend class RtcpSR;
friend class RtcpRR; friend class RtcpRR;
uint32_t ssrc; uint32_t ssrc;
//Fraction lost // Fraction lost
uint32_t fraction: 8; uint32_t fraction : 8;
//Cumulative number of packets lost // Cumulative number of packets lost
uint32_t cumulative: 24; uint32_t cumulative : 24;
//Sequence number cycles count // Sequence number cycles count
uint16_t seq_cycles; uint16_t seq_cycles;
//Highest sequence number received // Highest sequence number received
uint16_t seq_max; uint16_t seq_max;
//Interarrival jitter // Interarrival jitter
uint32_t jitter; uint32_t jitter;
//Last SR timestamp, NTP timestamp,(ntpmsw & 0xFFFF) << 16 | (ntplsw >> 16) & 0xFFFF) // Last SR timestamp, NTP timestamp,(ntpmsw & 0xFFFF) << 16 | (ntplsw >> 16) & 0xFFFF)
uint32_t last_sr_stamp; uint32_t last_sr_stamp;
//Delay since last SR timestamp,expressed in units of 1/65536 seconds // Delay since last SR timestamp,expressed in units of 1/65536 seconds
uint32_t delay_since_last_sr; uint32_t delay_since_last_sr;
private: private:
@ -273,7 +272,7 @@ private:
* *
*/ */
void net2Host(); void net2Host();
}PACKED; } PACKED;
/* /*
* 6.4.1 SR: Sender Report RTCP Packet * 6.4.1 SR: Sender Report RTCP Packet
@ -329,7 +328,7 @@ public:
uint32_t packet_count; uint32_t packet_count;
// sender octet count // sender octet count
uint32_t octet_count; uint32_t octet_count;
//可能有很多个 // 可能有很多个
ReportItem items; ReportItem items;
public: public:
@ -358,13 +357,13 @@ public:
* ReportItem对象指针列表 * ReportItem对象指针列表
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::vector<ReportItem*> getItemList(); std::vector<ReportItem *> getItemList();
private: private:
/** /**
* *
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::string dumpString() const; std::string dumpString() const;
/** /**
@ -406,13 +405,13 @@ block +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*/ */
//Receiver Report // Receiver Report
class RtcpRR : public RtcpHeader { class RtcpRR : public RtcpHeader {
public: public:
friend class RtcpHeader; friend class RtcpHeader;
uint32_t ssrc; uint32_t ssrc;
//可能有很多个 // 可能有很多个
ReportItem items; ReportItem items;
public: public:
@ -420,14 +419,14 @@ public:
* RR包RtcpHeader部分 * RR包RtcpHeader部分
* @param item_count ReportItem对象个数 * @param item_count ReportItem对象个数
* @return RR包 * @return RR包
*/ */
static std::shared_ptr<RtcpRR> create(size_t item_count); static std::shared_ptr<RtcpRR> create(size_t item_count);
/** /**
* ReportItem对象指针列表 * ReportItem对象指针列表
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::vector<ReportItem*> getItemList(); std::vector<ReportItem *> getItemList();
private: private:
/** /**
@ -475,20 +474,20 @@ SDES items 定义
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*/ */
//Source description Chunk // Source description Chunk
class SdesChunk { class SdesChunk {
public: public:
friend class RtcpSdes; friend class RtcpSdes;
uint32_t ssrc; uint32_t ssrc;
//SdesType // SdesType
uint8_t type; uint8_t type;
//text长度股可以为0 // text长度股可以为0
uint8_t txt_len; uint8_t txt_len;
//不定长 // 不定长
char text[1]; char text[1];
//最后以RTCP_SDES_END结尾 // 最后以RTCP_SDES_END结尾
//只字段为占位字段,不代表真实位置 // 只字段为占位字段,不代表真实位置
uint8_t end; uint8_t end;
public: public:
@ -511,16 +510,16 @@ private:
/** /**
* *
*/ */
void net2Host(); void net2Host();
} PACKED; } PACKED;
//Source description // Source description
class RtcpSdes : public RtcpHeader { class RtcpSdes : public RtcpHeader {
public: public:
friend class RtcpHeader; friend class RtcpHeader;
//可能有很多个 // 可能有很多个
SdesChunk chunks; SdesChunk chunks;
public: public:
@ -535,13 +534,13 @@ public:
* SdesChunk对象指针列表 * SdesChunk对象指针列表
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::vector<SdesChunk*> getChunkList(); std::vector<SdesChunk *> getChunkList();
private: private:
/** /**
* *
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::string dumpString() const; std::string dumpString() const;
/** /**
@ -591,11 +590,11 @@ public:
* @tparam Type * @tparam Type
* @return * @return
*/ */
template<typename Type> template <typename Type>
const Type& getFci() const{ const Type &getFci() const {
auto fci_data = getFciPtr(); auto fci_data = getFciPtr();
auto fci_len = getFciSize(); auto fci_len = getFciSize();
Type *fci = (Type *) fci_data; Type *fci = (Type *)fci_data;
fci->check(fci_len); fci->check(fci_len);
return *fci; return *fci;
} }
@ -612,9 +611,9 @@ public:
private: private:
/** /**
* *
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::string dumpString() const; std::string dumpString() const;
/** /**
@ -627,7 +626,7 @@ private:
static std::shared_ptr<RtcpFB> create_l(RtcpType type, int fmt, const void *fci, size_t fci_len); static std::shared_ptr<RtcpFB> create_l(RtcpType type, int fmt, const void *fci, size_t fci_len);
} PACKED; } PACKED;
//BYE // BYE
/* /*
0 1 2 3 0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
@ -675,9 +674,9 @@ public:
private: private:
/** /**
* *
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::string dumpString() const; std::string dumpString() const;
/** /**
@ -712,8 +711,7 @@ private:
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*/ */
class RtcpXRRRTR : public RtcpHeader class RtcpXRRRTR : public RtcpHeader {
{
public: public:
friend class RtcpHeader; friend class RtcpHeader;
uint32_t ssrc; uint32_t ssrc;
@ -722,15 +720,16 @@ public:
uint8_t reserved; uint8_t reserved;
// 2 // 2
uint16_t block_length; uint16_t block_length;
// ntp timestamp MSW(in second) // ntp timestamp MSW(in second)
uint32_t ntpmsw; uint32_t ntpmsw;
// ntp timestamp LSW(in picosecond) // ntp timestamp LSW(in picosecond)
uint32_t ntplsw; uint32_t ntplsw;
private: private:
/** /**
* *
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::string dumpString() const; std::string dumpString() const;
/** /**
@ -739,7 +738,7 @@ private:
*/ */
void net2Host(size_t size); void net2Host(size_t size);
}PACKED; } PACKED;
/* /*
@ -759,18 +758,18 @@ private:
: ... : 2 : ... : 2
+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+ +=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+
*/ */
class RtcpXRDLRRReportItem class RtcpXRDLRRReportItem {
{
public: public:
friend class RtcpXRDLRR; friend class RtcpXRDLRR;
uint32_t ssrc; uint32_t ssrc;
uint32_t lrr; uint32_t lrr;
uint32_t dlrr; uint32_t dlrr;
private: private:
/** /**
* *
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::string dumpString() const; std::string dumpString() const;
/** /**
@ -778,12 +777,9 @@ private:
* @param size * @param size
*/ */
void net2Host(); void net2Host();
}PACKED; } PACKED;
class RtcpXRDLRR : public RtcpHeader {
class RtcpXRDLRR : public RtcpHeader
{
public: public:
friend class RtcpHeader; friend class RtcpHeader;
uint32_t ssrc; uint32_t ssrc;
@ -799,17 +795,17 @@ public:
*/ */
static std::shared_ptr<RtcpXRDLRR> create(size_t item_count); static std::shared_ptr<RtcpXRDLRR> create(size_t item_count);
/** /**
* RtcpXRDLRRReportItem对象指针列表 * RtcpXRDLRRReportItem对象指针列表
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::vector<RtcpXRDLRRReportItem*> getItemList(); std::vector<RtcpXRDLRRReportItem *> getItemList();
private: private:
/** /**
* *
* 使net2Host转换成主机字节序后才可使用此函数 * 使net2Host转换成主机字节序后才可使用此函数
*/ */
std::string dumpString() const; std::string dumpString() const;
/** /**
@ -818,12 +814,11 @@ private:
*/ */
void net2Host(size_t size); void net2Host(size_t size);
}PACKED; } PACKED;
#if defined(_WIN32) #if defined(_WIN32)
#pragma pack(pop) #pragma pack(pop)
#endif // defined(_WIN32) #endif // defined(_WIN32)
} //namespace mediakit } // namespace mediakit
#endif //ZLMEDIAKIT_RTCP_H #endif // ZLMEDIAKIT_RTCP_H

150
src/Rtcp/RtcpContext.cpp
View File

@ -14,7 +14,8 @@ using namespace toolkit;
namespace mediakit { namespace mediakit {
void RtcpContext::onRtp(uint16_t /*seq*/, uint32_t stamp, uint64_t ntp_stamp_ms, uint32_t /*sample_rate*/, size_t bytes) { void RtcpContext::onRtp(
uint16_t /*seq*/, uint32_t stamp, uint64_t ntp_stamp_ms, uint32_t /*sample_rate*/, size_t bytes) {
++_packets; ++_packets;
_bytes += bytes; _bytes += bytes;
_last_rtp_stamp = stamp; _last_rtp_stamp = stamp;
@ -52,43 +53,45 @@ Buffer::Ptr RtcpContext::createRtcpXRDLRR(uint32_t rtcp_ssrc, uint32_t rtp_ssrc)
//////////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////////////
void RtcpContextForSend::onRtcp(RtcpHeader *rtcp) { void RtcpContextForSend::onRtcp(RtcpHeader *rtcp) {
switch ((RtcpType) rtcp->pt) { switch ((RtcpType)rtcp->pt) {
case RtcpType::RTCP_RR: { case RtcpType::RTCP_RR: {
auto rtcp_rr = (RtcpRR *) rtcp; auto rtcp_rr = (RtcpRR *)rtcp;
for (auto item : rtcp_rr->getItemList()) { for (auto item : rtcp_rr->getItemList()) {
if (!item->last_sr_stamp) { if (!item->last_sr_stamp) {
continue; continue;
}
auto it = _sender_report_ntp.find(item->last_sr_stamp);
if (it == _sender_report_ntp.end()) {
continue;
}
//发送sr到收到rr之间的时间戳增量
auto ms_inc = getCurrentMillisecond() - it->second;
//rtp接收端收到sr包后回复rr包的延时已转换为毫秒
auto delay_ms = (uint64_t) item->delay_since_last_sr * 1000 / 65536;
auto rtt = (int) (ms_inc - delay_ms);
if (rtt >= 0) {
//rtt不可能小于0
_rtt[item->ssrc] = rtt;
//InfoL << "ssrc:" << item->ssrc << ",rtt:" << rtt;
}
} }
break; auto it = _sender_report_ntp.find(item->last_sr_stamp);
} if (it == _sender_report_ntp.end()) {
case RtcpType::RTCP_XR:{ continue;
auto rtcp_xr = (RtcpXRRRTR*)rtcp; }
if(rtcp_xr->bt == 4){ // 发送sr到收到rr之间的时间戳增量
_xr_xrrtr_recv_last_rr[rtcp_xr->ssrc] = ((rtcp_xr->ntpmsw & 0xFFFF) << 16) | ((rtcp_xr->ntplsw >> 16) & 0xFFFF); auto ms_inc = getCurrentMillisecond() - it->second;
_xr_rrtr_recv_sys_stamp[rtcp_xr->ssrc] = getCurrentMillisecond(); // rtp接收端收到sr包后回复rr包的延时已转换为毫秒
}else if(rtcp_xr->bt == 5){ auto delay_ms = (uint64_t)item->delay_since_last_sr * 1000 / 65536;
TraceL<<"for sender not recive dlrr"; auto rtt = (int)(ms_inc - delay_ms);
}else{ if (rtt >= 0) {
TraceL<<"not support xr bt "<<rtcp_xr->bt; // rtt不可能小于0
_rtt[item->ssrc] = rtt;
// InfoL << "ssrc:" << item->ssrc << ",rtt:" << rtt;
} }
break;
} }
default: break; break;
}
case RtcpType::RTCP_XR: {
auto rtcp_xr = (RtcpXRRRTR *)rtcp;
if (rtcp_xr->bt == 4) {
_xr_xrrtr_recv_last_rr[rtcp_xr->ssrc]
= ((rtcp_xr->ntpmsw & 0xFFFF) << 16) | ((rtcp_xr->ntplsw >> 16) & 0xFFFF);
_xr_rrtr_recv_sys_stamp[rtcp_xr->ssrc] = getCurrentMillisecond();
} else if (rtcp_xr->bt == 5) {
TraceL << "for sender not recive dlrr";
} else {
TraceL << "not support xr bt " << rtcp_xr->bt;
}
break;
}
default:
break;
} }
} }
@ -105,21 +108,21 @@ Buffer::Ptr RtcpContextForSend::createRtcpSR(uint32_t rtcp_ssrc) {
rtcp->setNtpStamp(_last_ntp_stamp_ms); rtcp->setNtpStamp(_last_ntp_stamp_ms);
rtcp->rtpts = htonl(_last_rtp_stamp); rtcp->rtpts = htonl(_last_rtp_stamp);
rtcp->ssrc = htonl(rtcp_ssrc); rtcp->ssrc = htonl(rtcp_ssrc);
rtcp->packet_count = htonl((uint32_t) _packets); rtcp->packet_count = htonl((uint32_t)_packets);
rtcp->octet_count = htonl((uint32_t) _bytes); rtcp->octet_count = htonl((uint32_t)_bytes);
//记录上次发送的sender report信息用于后续统计rtt // 记录上次发送的sender report信息用于后续统计rtt
auto last_sr_lsr = ((ntohl(rtcp->ntpmsw) & 0xFFFF) << 16) | ((ntohl(rtcp->ntplsw) >> 16) & 0xFFFF); auto last_sr_lsr = ((ntohl(rtcp->ntpmsw) & 0xFFFF) << 16) | ((ntohl(rtcp->ntplsw) >> 16) & 0xFFFF);
_sender_report_ntp[last_sr_lsr] = getCurrentMillisecond(); _sender_report_ntp[last_sr_lsr] = getCurrentMillisecond();
if (_sender_report_ntp.size() >= 5) { if (_sender_report_ntp.size() >= 5) {
//删除最早的sr rtcp // 删除最早的sr rtcp
_sender_report_ntp.erase(_sender_report_ntp.begin()); _sender_report_ntp.erase(_sender_report_ntp.begin());
} }
return RtcpHeader::toBuffer(std::move(rtcp)); return RtcpHeader::toBuffer(std::move(rtcp));
} }
toolkit::Buffer::Ptr RtcpContextForSend::createRtcpXRDLRR(uint32_t rtcp_ssrc, uint32_t rtp_ssrc){ toolkit::Buffer::Ptr RtcpContextForSend::createRtcpXRDLRR(uint32_t rtcp_ssrc, uint32_t rtp_ssrc) {
auto rtcp = RtcpXRDLRR::create(1); auto rtcp = RtcpXRDLRR::create(1);
rtcp->bt = 5; rtcp->bt = 5;
rtcp->reserved = 0; rtcp->reserved = 0;
@ -127,14 +130,14 @@ toolkit::Buffer::Ptr RtcpContextForSend::createRtcpXRDLRR(uint32_t rtcp_ssrc, ui
rtcp->ssrc = htonl(rtcp_ssrc); rtcp->ssrc = htonl(rtcp_ssrc);
rtcp->items.ssrc = htonl(rtp_ssrc); rtcp->items.ssrc = htonl(rtp_ssrc);
if(_xr_xrrtr_recv_last_rr.find(rtp_ssrc) == _xr_xrrtr_recv_last_rr.end()){ if (_xr_xrrtr_recv_last_rr.find(rtp_ssrc) == _xr_xrrtr_recv_last_rr.end()) {
rtcp->items.lrr = 0; rtcp->items.lrr = 0;
WarnL; WarnL;
}else{ } else {
rtcp->items.lrr = htonl(_xr_xrrtr_recv_last_rr[rtp_ssrc]); rtcp->items.lrr = htonl(_xr_xrrtr_recv_last_rr[rtp_ssrc]);
} }
if(_xr_rrtr_recv_sys_stamp.find(rtp_ssrc) == _xr_rrtr_recv_sys_stamp.end()){ if (_xr_rrtr_recv_sys_stamp.find(rtp_ssrc) == _xr_rrtr_recv_sys_stamp.end()) {
rtcp->items.dlrr = 0; rtcp->items.dlrr = 0;
WarnL; WarnL;
} else { } else {
@ -149,39 +152,41 @@ toolkit::Buffer::Ptr RtcpContextForSend::createRtcpXRDLRR(uint32_t rtcp_ssrc, ui
//////////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////////////
void RtcpContextForRecv::onRtp(uint16_t seq, uint32_t stamp, uint64_t ntp_stamp_ms, uint32_t sample_rate, size_t bytes) { void RtcpContextForRecv::onRtp(
uint16_t seq, uint32_t stamp, uint64_t ntp_stamp_ms, uint32_t sample_rate, size_t bytes) {
{ {
//接收者才做复杂的统计运算 // 接收者才做复杂的统计运算
auto sys_stamp = getCurrentMillisecond(); auto sys_stamp = getCurrentMillisecond();
if (_last_rtp_sys_stamp) { if (_last_rtp_sys_stamp) {
//计算时间戳抖动值 // 计算时间戳抖动值
double diff = double((int64_t(sys_stamp) - int64_t(_last_rtp_sys_stamp)) * (sample_rate / double(1000.0)) double diff = double(
- (int64_t(stamp) - int64_t(_last_rtp_stamp))); (int64_t(sys_stamp) - int64_t(_last_rtp_sys_stamp)) * (sample_rate / double(1000.0))
- (int64_t(stamp) - int64_t(_last_rtp_stamp)));
if (diff < 0) { if (diff < 0) {
diff = -diff; diff = -diff;
} }
//抖动单位为采样次数 // 抖动单位为采样次数
_jitter += (diff - _jitter) / 16.0; _jitter += (diff - _jitter) / 16.0;
} else { } else {
_jitter = 0; _jitter = 0;
} }
if (_last_rtp_seq > 0xFF00 && seq < 0xFF && (!_seq_cycles || _packets - _last_cycle_packets > 0x1FFF)) { if (_last_rtp_seq > 0xFF00 && seq < 0xFF && (!_seq_cycles || _packets - _last_cycle_packets > 0x1FFF)) {
//上次seq大于0xFF00且本次seq小于0xFF // 上次seq大于0xFF00且本次seq小于0xFF
//且未发生回环或者距离上次回环间隔超过0x1FFF个包则认为回环 // 且未发生回环或者距离上次回环间隔超过0x1FFF个包则认为回环
++_seq_cycles; ++_seq_cycles;
_last_cycle_packets = _packets; _last_cycle_packets = _packets;
_seq_max = seq; _seq_max = seq;
} else if (seq > _seq_max) { } else if (seq > _seq_max) {
//本次回环前最大seq // 本次回环前最大seq
_seq_max = seq; _seq_max = seq;
} }
if (!_seq_base) { if (!_seq_base) {
//记录第一个rtp的seq // 记录第一个rtp的seq
_seq_base = seq; _seq_base = seq;
} else if (!_seq_cycles && seq < _seq_base) { } else if (!_seq_cycles && seq < _seq_base) {
//未发生回环那么取最新的seq为基准seq // 未发生回环那么取最新的seq为基准seq
_seq_base = seq; _seq_base = seq;
} }
@ -192,21 +197,22 @@ void RtcpContextForRecv::onRtp(uint16_t seq, uint32_t stamp, uint64_t ntp_stamp_
} }
void RtcpContextForRecv::onRtcp(RtcpHeader *rtcp) { void RtcpContextForRecv::onRtcp(RtcpHeader *rtcp) {
switch ((RtcpType) rtcp->pt) { switch ((RtcpType)rtcp->pt) {
case RtcpType::RTCP_SR: { case RtcpType::RTCP_SR: {
auto rtcp_sr = (RtcpSR *) rtcp; auto rtcp_sr = (RtcpSR *)rtcp;
/** /**
last SR timestamp (LSR): 32 bits last SR timestamp (LSR): 32 bits
The middle 32 bits out of 64 in the NTP timestamp (as explained in The middle 32 bits out of 64 in the NTP timestamp (as explained in
Section 4) received as part of the most recent RTCP sender report Section 4) received as part of the most recent RTCP sender report
(SR) packet from source SSRC_n. If no SR has been received yet, (SR) packet from source SSRC_n. If no SR has been received yet,
the field is set to zero. the field is set to zero.
*/ */
_last_sr_lsr = ((rtcp_sr->ntpmsw & 0xFFFF) << 16) | ((rtcp_sr->ntplsw >> 16) & 0xFFFF); _last_sr_lsr = ((rtcp_sr->ntpmsw & 0xFFFF) << 16) | ((rtcp_sr->ntplsw >> 16) & 0xFFFF);
_last_sr_ntp_sys = getCurrentMillisecond(); _last_sr_ntp_sys = getCurrentMillisecond();
break; break;
} }
default: break; default:
break;
} }
} }
@ -236,7 +242,7 @@ Buffer::Ptr RtcpContextForRecv::createRtcpRR(uint32_t rtcp_ssrc, uint32_t rtp_ss
auto rtcp = RtcpRR::create(1); auto rtcp = RtcpRR::create(1);
rtcp->ssrc = htonl(rtcp_ssrc); rtcp->ssrc = htonl(rtcp_ssrc);
ReportItem *item = (ReportItem *) &rtcp->items; ReportItem *item = (ReportItem *)&rtcp->items;
item->ssrc = htonl(rtp_ssrc); item->ssrc = htonl(rtp_ssrc);
uint8_t fraction = 0; uint8_t fraction = 0;
@ -255,9 +261,9 @@ Buffer::Ptr RtcpContextForRecv::createRtcpRR(uint32_t rtcp_ssrc, uint32_t rtp_ss
// now - Last SR time,单位毫秒 // now - Last SR time,单位毫秒
auto delay = getCurrentMillisecond() - _last_sr_ntp_sys; auto delay = getCurrentMillisecond() - _last_sr_ntp_sys;
// in units of 1/65536 seconds // in units of 1/65536 seconds
auto dlsr = (uint32_t) (delay / 1000.0f * 65536); auto dlsr = (uint32_t)(delay / 1000.0f * 65536);
item->delay_since_last_sr = htonl(_last_sr_lsr ? dlsr : 0); item->delay_since_last_sr = htonl(_last_sr_lsr ? dlsr : 0);
return RtcpHeader::toBuffer(rtcp); return RtcpHeader::toBuffer(rtcp);
} }
}//namespace mediakit } // namespace mediakit

45
src/Rtcp/RtcpContext.h
View File

@ -11,9 +11,9 @@
#ifndef ZLMEDIAKIT_RTCPCONTEXT_H #ifndef ZLMEDIAKIT_RTCPCONTEXT_H
#define ZLMEDIAKIT_RTCPCONTEXT_H #define ZLMEDIAKIT_RTCPCONTEXT_H
#include <stdint.h>
#include <stddef.h>
#include "Rtcp.h" #include "Rtcp.h"
#include <stddef.h>
#include <stdint.h>
namespace mediakit { namespace mediakit {
@ -55,7 +55,6 @@ public:
*/ */
virtual toolkit::Buffer::Ptr createRtcpSR(uint32_t rtcp_ssrc); virtual toolkit::Buffer::Ptr createRtcpSR(uint32_t rtcp_ssrc);
/** /**
* @brief xr的dlrr包rtt * @brief xr的dlrr包rtt
* *
@ -82,11 +81,11 @@ public:
virtual size_t geLostInterval(); virtual size_t geLostInterval();
protected: protected:
//收到或发送的rtp的字节数 // 收到或发送的rtp的字节数
size_t _bytes = 0; size_t _bytes = 0;
//收到或发送的rtp的个数 // 收到或发送的rtp的个数
size_t _packets = 0; size_t _packets = 0;
//上次的rtp时间戳,毫秒 // 上次的rtp时间戳,毫秒
uint32_t _last_rtp_stamp = 0; uint32_t _last_rtp_stamp = 0;
uint64_t _last_ntp_stamp_ms = 0; uint64_t _last_ntp_stamp_ms = 0;
}; };
@ -107,11 +106,11 @@ public:
uint32_t getRtt(uint32_t ssrc) const; uint32_t getRtt(uint32_t ssrc) const;
private: private:
std::map<uint32_t/*ssrc*/, uint32_t/*rtt*/> _rtt; std::map<uint32_t /*ssrc*/, uint32_t /*rtt*/> _rtt;
std::map<uint32_t/*last_sr_lsr*/, uint64_t/*ntp stamp*/> _sender_report_ntp; std::map<uint32_t /*last_sr_lsr*/, uint64_t /*ntp stamp*/> _sender_report_ntp;
std::map<uint32_t/*ssrc*/,uint64_t/*xr rrtr sys stamp*/> _xr_rrtr_recv_sys_stamp; std::map<uint32_t /*ssrc*/, uint64_t /*xr rrtr sys stamp*/> _xr_rrtr_recv_sys_stamp;
std::map<uint32_t/*ssrc*/,uint32_t/*last rr */> _xr_xrrtr_recv_last_rr; std::map<uint32_t /*ssrc*/, uint32_t /*last rr */> _xr_xrrtr_recv_last_rr;
}; };
class RtcpContextForRecv : public RtcpContext { class RtcpContextForRecv : public RtcpContext {
@ -125,29 +124,29 @@ public:
void onRtcp(RtcpHeader *rtcp) override; void onRtcp(RtcpHeader *rtcp) override;
private: private:
//时间戳抖动值 // 时间戳抖动值
double _jitter = 0; double _jitter = 0;
//第一个seq的值 // 第一个seq的值
uint16_t _seq_base = 0; uint16_t _seq_base = 0;
//rtp最大seq // rtp最大seq
uint16_t _seq_max = 0; uint16_t _seq_max = 0;
//rtp回环次数 // rtp回环次数
uint16_t _seq_cycles = 0; uint16_t _seq_cycles = 0;
//上次回环发生时记录的rtp包数 // 上次回环发生时记录的rtp包数
size_t _last_cycle_packets = 0; size_t _last_cycle_packets = 0;
//上次的seq // 上次的seq
uint16_t _last_rtp_seq = 0; uint16_t _last_rtp_seq = 0;
//上次的rtp的系统时间戳(毫秒)用于统计抖动 // 上次的rtp的系统时间戳(毫秒)用于统计抖动
uint64_t _last_rtp_sys_stamp = 0; uint64_t _last_rtp_sys_stamp = 0;
//上次统计的丢包总数 // 上次统计的丢包总数
size_t _last_lost = 0; size_t _last_lost = 0;
//上次统计应收rtp包总数 // 上次统计应收rtp包总数
size_t _last_expected = 0; size_t _last_expected = 0;
//上次收到sr包时计算出的Last SR timestamp // 上次收到sr包时计算出的Last SR timestamp
uint32_t _last_sr_lsr = 0; uint32_t _last_sr_lsr = 0;
//上次收到sr时的系统时间戳,单位毫秒 // 上次收到sr时的系统时间戳,单位毫秒
uint64_t _last_sr_ntp_sys = 0; uint64_t _last_sr_ntp_sys = 0;
}; };
}//namespace mediakit } // namespace mediakit
#endif //ZLMEDIAKIT_RTCPCONTEXT_H #endif // ZLMEDIAKIT_RTCPCONTEXT_H

274
src/Rtcp/RtcpFCI.cpp
View File

@ -16,16 +16,16 @@ using namespace toolkit;
namespace mediakit { namespace mediakit {
void FCI_SLI::check(size_t size){ void FCI_SLI::check(size_t size) {
CHECK(size >= kSize); CHECK(size >= kSize);
} }
FCI_SLI::FCI_SLI(uint16_t first, uint16_t number, uint8_t pic_id) { FCI_SLI::FCI_SLI(uint16_t first, uint16_t number, uint8_t pic_id) {
//13 bits // 13 bits
first &= 0x1FFF; first &= 0x1FFF;
//13 bits // 13 bits
number &= 0x1FFF; number &= 0x1FFF;
//6 bits // 6 bits
pic_id &= 0x3F; pic_id &= 0x3F;
data = (first << 19) | (number << 6) | pic_id; data = (first << 19) | (number << 6) | pic_id;
data = htonl(data); data = htonl(data);
@ -49,19 +49,19 @@ string FCI_SLI::dumpString() const {
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
void FCI_FIR::check(size_t size){ void FCI_FIR::check(size_t size) {
CHECK(size >= kSize); CHECK(size >= kSize);
} }
uint32_t FCI_FIR::getSSRC() const{ uint32_t FCI_FIR::getSSRC() const {
return ntohl(ssrc); return ntohl(ssrc);
} }
uint8_t FCI_FIR::getSeq() const{ uint8_t FCI_FIR::getSeq() const {
return seq_number; return seq_number;
} }
uint32_t FCI_FIR::getReserved() const{ uint32_t FCI_FIR::getReserved() const {
return (reserved[0] << 16) | (reserved[1] << 8) | reserved[2]; return (reserved[0] << 16) | (reserved[1] << 8) | reserved[2];
} }
@ -81,7 +81,7 @@ FCI_FIR::FCI_FIR(uint32_t ssrc, uint8_t seq_number, uint32_t reserved) {
static const char kRembMagic[] = "REMB"; static const char kRembMagic[] = "REMB";
void FCI_REMB::check(size_t size){ void FCI_REMB::check(size_t size) {
CHECK(size >= kSize); CHECK(size >= kSize);
CHECK(memcmp(magic, kRembMagic, sizeof(magic)) == 0); CHECK(memcmp(magic, kRembMagic, sizeof(magic)) == 0);
auto num_ssrc = bitrate[0]; auto num_ssrc = bitrate[0];
@ -93,7 +93,7 @@ string FCI_REMB::create(const vector<uint32_t> &ssrcs, uint32_t bitrate) {
CHECK(ssrcs.size() > 0 && ssrcs.size() <= 0xFF); CHECK(ssrcs.size() > 0 && ssrcs.size() <= 0xFF);
string ret; string ret;
ret.resize(kSize + ssrcs.size() * 4); ret.resize(kSize + ssrcs.size() * 4);
FCI_REMB *thiz = (FCI_REMB *) ret.data(); FCI_REMB *thiz = (FCI_REMB *)ret.data();
memcpy(thiz->magic, kRembMagic, sizeof(magic)); memcpy(thiz->magic, kRembMagic, sizeof(magic));
/* bitrate --> BR Exp/BR Mantissa */ /* bitrate --> BR Exp/BR Mantissa */
@ -101,7 +101,7 @@ string FCI_REMB::create(const vector<uint32_t> &ssrcs, uint32_t bitrate) {
uint8_t exp = 0; uint8_t exp = 0;
uint32_t mantissa = 0; uint32_t mantissa = 0;
for (b = 0; b < 32; b++) { for (b = 0; b < 32; b++) {
if (bitrate <= ((uint32_t) 0x3FFFF << b)) { if (bitrate <= ((uint32_t)0x3FFFF << b)) {
exp = b; exp = b;
break; break;
} }
@ -110,16 +110,16 @@ string FCI_REMB::create(const vector<uint32_t> &ssrcs, uint32_t bitrate) {
b = 31; b = 31;
} }
mantissa = bitrate >> b; mantissa = bitrate >> b;
//Num SSRC (8 bits) // Num SSRC (8 bits)
thiz->bitrate[0] = ssrcs.size() & 0xFF; thiz->bitrate[0] = ssrcs.size() & 0xFF;
//BR Exp (6 bits)/BR Mantissa (18 bits) // BR Exp (6 bits)/BR Mantissa (18 bits)
thiz->bitrate[1] = (uint8_t) ((exp << 2) + ((mantissa >> 16) & 0x03)); thiz->bitrate[1] = (uint8_t)((exp << 2) + ((mantissa >> 16) & 0x03));
//BR Mantissa (18 bits) // BR Mantissa (18 bits)
thiz->bitrate[2] = (uint8_t) (mantissa >> 8); thiz->bitrate[2] = (uint8_t)(mantissa >> 8);
//BR Mantissa (18 bits) // BR Mantissa (18 bits)
thiz->bitrate[3] = (uint8_t) (mantissa); thiz->bitrate[3] = (uint8_t)(mantissa);
//设置ssrc列表 // 设置ssrc列表
int i = 0; int i = 0;
for (auto ssrc : ssrcs) { for (auto ssrc : ssrcs) {
thiz->ssrc_feedback[i++] = htonl(ssrc); thiz->ssrc_feedback[i++] = htonl(ssrc);
@ -149,7 +149,7 @@ vector<uint32_t> FCI_REMB::getSSRC() {
string FCI_REMB::dumpString() const { string FCI_REMB::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << "bitrate:" << getBitRate() << ", ssrc:"; printer << "bitrate:" << getBitRate() << ", ssrc:";
for (auto &ssrc : ((FCI_REMB *) this)->getSSRC()) { for (auto &ssrc : ((FCI_REMB *)this)->getSSRC()) {
printer << ssrc << " "; printer << ssrc << " ";
} }
return std::move(printer); return std::move(printer);
@ -171,7 +171,7 @@ FCI_NACK::FCI_NACK(uint16_t pid_h, const vector<bool> &type) {
pid = htons(pid_h); pid = htons(pid_h);
} }
void FCI_NACK::check(size_t size){ void FCI_NACK::check(size_t size) {
CHECK(size >= kSize); CHECK(size >= kSize);
} }
@ -186,7 +186,7 @@ uint16_t FCI_NACK::getBlp() const {
vector<bool> FCI_NACK::getBitArray() const { vector<bool> FCI_NACK::getBitArray() const {
vector<bool> ret; vector<bool> ret;
ret.resize(kBitSize + 1); ret.resize(kBitSize + 1);
//nack第一个包丢包 // nack第一个包丢包
ret[0] = true; ret[0] = true;
auto blp_h = getBlp(); auto blp_h = getBlp();
@ -220,25 +220,25 @@ public:
// |T| S | Run Length | // |T| S | Run Length |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
#if __BYTE_ORDER == __BIG_ENDIAN #if __BYTE_ORDER == __BIG_ENDIAN
uint16_t type: 1; uint16_t type : 1;
uint16_t symbol: 2; uint16_t symbol : 2;
uint16_t run_length_high: 5; uint16_t run_length_high : 5;
#else #else
// Run Length 高5位 // Run Length 高5位
uint16_t run_length_high: 5; uint16_t run_length_high : 5;
//参考SymbolStatus定义 // 参考SymbolStatus定义
uint16_t symbol: 2; uint16_t symbol : 2;
//固定为0 // 固定为0
uint16_t type: 1; uint16_t type : 1;
#endif #endif
// Run Length 低8位 // Run Length 低8位
uint16_t run_length_low: 8; uint16_t run_length_low : 8;
//获取Run Length // 获取Run Length
uint16_t getRunLength() const; uint16_t getRunLength() const;
//构造函数 // 构造函数
RunLengthChunk(SymbolStatus status, uint16_t run_length); RunLengthChunk(SymbolStatus status, uint16_t run_length);
//打印本对象 // 打印本对象
string dumpString() const; string dumpString() const;
} PACKED; } PACKED;
@ -254,7 +254,7 @@ uint16_t RunLengthChunk::getRunLength() const {
return run_length_high << 8 | run_length_low; return run_length_high << 8 | run_length_low;
} }
string RunLengthChunk::dumpString() const{ string RunLengthChunk::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << "run length chunk, symbol:" << (int)symbol << ", run length:" << getRunLength(); printer << "run length chunk, symbol:" << (int)symbol << ", run length:" << getRunLength();
return std::move(printer); return std::move(printer);
@ -271,30 +271,30 @@ public:
// |T|S| symbol list | // |T|S| symbol list |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
#if __BYTE_ORDER == __BIG_ENDIAN #if __BYTE_ORDER == __BIG_ENDIAN
uint16_t type: 1; uint16_t type : 1;
uint16_t symbol: 1; uint16_t symbol : 1;
uint16_t symbol_list_high: 6; uint16_t symbol_list_high : 6;
#else #else
// symbol_list 高6位 // symbol_list 高6位
uint16_t symbol_list_high: 6; uint16_t symbol_list_high : 6;
//symbol_list中元素是1个还是2个bit // symbol_list中元素是1个还是2个bit
uint16_t symbol: 1; uint16_t symbol : 1;
//固定为1 // 固定为1
uint16_t type: 1; uint16_t type : 1;
#endif #endif
// symbol_list 低8位 // symbol_list 低8位
uint16_t symbol_list_low: 8; uint16_t symbol_list_low : 8;
//获取symbollist // 获取symbollist
vector<SymbolStatus> getSymbolList() const; vector<SymbolStatus> getSymbolList() const;
//构造函数 // 构造函数
StatusVecChunk(bool symbol_bit, const vector<SymbolStatus> &status); StatusVecChunk(bool symbol_bit, const vector<SymbolStatus> &status);
//打印本对象 // 打印本对象
string dumpString() const; string dumpString() const;
} PACKED; } PACKED;
StatusVecChunk::StatusVecChunk(bool symbol_bit, const vector<SymbolStatus> &status) { StatusVecChunk::StatusVecChunk(bool symbol_bit, const vector<SymbolStatus> &status) {
CHECK( status.size() << symbol_bit <= 14); CHECK(status.size() << symbol_bit <= 14);
uint16_t value = 0; uint16_t value = 0;
type = 1; type = 1;
symbol = symbol_bit; symbol = symbol_bit;
@ -303,31 +303,31 @@ StatusVecChunk::StatusVecChunk(bool symbol_bit, const vector<SymbolStatus> &stat
CHECK(item <= SymbolStatus::reserved); CHECK(item <= SymbolStatus::reserved);
if (!symbol) { if (!symbol) {
CHECK(item <= SymbolStatus::small_delta); CHECK(item <= SymbolStatus::small_delta);
value |= (int) item << i; value |= (int)item << i;
--i; --i;
} else { } else {
value |= (int) item << (i - 1); value |= (int)item << (i - 1);
i -= 2; i -= 2;
} }
} }
symbol_list_low = value & 0xFF; symbol_list_low = value & 0xFF;
symbol_list_high = (value >> 8 ) & 0x3F; symbol_list_high = (value >> 8) & 0x3F;
} }
vector<SymbolStatus> StatusVecChunk::getSymbolList() const { vector<SymbolStatus> StatusVecChunk::getSymbolList() const {
CHECK(type == 1); CHECK(type == 1);
vector<SymbolStatus> ret; vector<SymbolStatus> ret;
auto thiz = ntohs(*((uint16_t *) this)); auto thiz = ntohs(*((uint16_t *)this));
if (symbol == 0) { 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 // 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) { for (int i = 13; i >= 0; --i) {
SymbolStatus status = (SymbolStatus) ((bool) (thiz & (1 << i))); SymbolStatus status = (SymbolStatus)((bool)(thiz & (1 << i)));
ret.emplace_back(status); ret.emplace_back(status);
} }
} else { } else {
//s = 1 时表示symbollist每两个bit表示一个数据包的状态 // 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) { for (int i = 12; i >= 0; i -= 2) {
SymbolStatus status = (SymbolStatus) ((thiz & (3 << i)) >> i); SymbolStatus status = (SymbolStatus)((thiz & (3 << i)) >> i);
ret.emplace_back(status); ret.emplace_back(status);
} }
} }
@ -336,17 +336,17 @@ vector<SymbolStatus> StatusVecChunk::getSymbolList() const {
string StatusVecChunk::dumpString() const { string StatusVecChunk::dumpString() const {
_StrPrinter printer; _StrPrinter printer;
printer << "status vector chunk, symbol:" << (int) symbol << ", symbol list:"; printer << "status vector chunk, symbol:" << (int)symbol << ", symbol list:";
auto vec = getSymbolList(); auto vec = getSymbolList();
for (auto &item : vec) { for (auto &item : vec) {
printer << (int) item << " "; printer << (int)item << " ";
} }
return std::move(printer); return std::move(printer);
} }
/////////////////////////////////////////////////////// ///////////////////////////////////////////////////////
void FCI_TWCC::check(size_t size){ void FCI_TWCC::check(size_t size) {
CHECK(size >= kSize); CHECK(size >= kSize);
} }
@ -365,87 +365,87 @@ uint32_t FCI_TWCC::getReferenceTime() const {
ret |= ref_time[2]; ret |= ref_time[2];
return ret; return ret;
} }
//3.1.5. Receive Delta // 3.1.5. Receive Delta
// //
// Deltas are represented as multiples of 250us: // Deltas are represented as multiples of 250us:
// //
// o If the "Packet received, small delta" symbol has been appended to // o If the "Packet received, small delta" symbol has been appended to
// the status list, an 8-bit unsigned receive delta will be appended // 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] // to recv delta list, representing a delta in the range [0, 63.75]
// ms. // ms.
// //
// o If the "Packet received, large or negative delta" symbol has been // 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 the status list, a 16-bit signed receive delta will be
// appended to recv delta list, representing a delta in the range // appended to recv delta list, representing a delta in the range
// [-8192.0, 8191.75] ms. // [-8192.0, 8191.75] ms.
// //
// o If the delta exceeds even the larger limits, a new feedback // o If the delta exceeds even the larger limits, a new feedback
// message must be used, where the 24-bit base receive delta can // message must be used, where the 24-bit base receive delta can
// cover very large gaps. // cover very large gaps.
// //
// The smaller receive delta upper bound of 63.75 ms means that this is // 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. // 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 // With a packet size of 1200 bytes/packet that amounts to a bitrate of
// about 150 kbit/s. // about 150 kbit/s.
// //
// The 0.25 ms resolution means that up to 4000 packets per second can // 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 // be represented. With a 1200 bytes/packet payload, that amounts to
// 38.4 Mbit/s payload bandwidth. // 38.4 Mbit/s payload bandwidth.
static int16_t getRecvDelta(SymbolStatus status, uint8_t *&ptr, const uint8_t *end){ static int16_t getRecvDelta(SymbolStatus status, uint8_t *&ptr, const uint8_t *end) {
int16_t delta = 0; int16_t delta = 0;
switch (status) { switch (status) {
case SymbolStatus::not_received : { case SymbolStatus::not_received: {
//丢包, recv delta为0个字节 // 丢包, recv delta为0个字节
break; break;
} }
case SymbolStatus::small_delta : { case SymbolStatus::small_delta: {
CHECK(ptr + 1 <= end); CHECK(ptr + 1 <= end);
//时间戳增量小于256 recv delta为1个字节 // 时间戳增量小于256 recv delta为1个字节
delta = *ptr; delta = *ptr;
ptr += 1; ptr += 1;
break; break;
} }
case SymbolStatus::large_delta : { case SymbolStatus::large_delta: {
CHECK(ptr + 2 <= end); CHECK(ptr + 2 <= end);
//时间戳增量256~65535间recv delta为2个字节 // 时间戳增量256~65535间recv delta为2个字节
delta = *ptr << 8 | *(ptr + 1); delta = *ptr << 8 | *(ptr + 1);
ptr += 2; ptr += 2;
break; break;
} }
case SymbolStatus::reserved : { case SymbolStatus::reserved: {
//没有时间戳 // 没有时间戳
break; break;
} }
default: default:
//这个逻辑分支不可达到 // 这个逻辑分支不可达到
CHECK(0); CHECK(0);
break; break;
} }
return delta; return delta;
} }
FCI_TWCC::TwccPacketStatus FCI_TWCC::getPacketChunkList(size_t total_size) const { FCI_TWCC::TwccPacketStatus FCI_TWCC::getPacketChunkList(size_t total_size) const {
TwccPacketStatus ret; TwccPacketStatus ret;
auto ptr = (uint8_t *) this + kSize; auto ptr = (uint8_t *)this + kSize;
auto end = (uint8_t *) this + total_size; auto end = (uint8_t *)this + total_size;
CHECK(ptr < end); CHECK(ptr < end);
auto seq = getBaseSeq(); auto seq = getBaseSeq();
auto rtp_count = getPacketCount(); auto rtp_count = getPacketCount();
for (uint8_t i = 0; i < rtp_count;) { for (uint8_t i = 0; i < rtp_count;) {
CHECK(ptr + RunLengthChunk::kSize <= end); CHECK(ptr + RunLengthChunk::kSize <= end);
RunLengthChunk *chunk = (RunLengthChunk *) ptr; RunLengthChunk *chunk = (RunLengthChunk *)ptr;
if (!chunk->type) { if (!chunk->type) {
//RunLengthChunk // RunLengthChunk
for (auto j = 0; j < chunk->getRunLength(); ++j) { for (auto j = 0; j < chunk->getRunLength(); ++j) {
ret.emplace(seq++, std::make_pair((SymbolStatus) chunk->symbol, 0)); ret.emplace(seq++, std::make_pair((SymbolStatus)chunk->symbol, 0));
if (++i >= rtp_count) { if (++i >= rtp_count) {
break; break;
} }
} }
} else { } else {
//StatusVecChunk // StatusVecChunk
StatusVecChunk *chunk = (StatusVecChunk *) ptr; StatusVecChunk *chunk = (StatusVecChunk *)ptr;
for (auto &symbol : chunk->getSymbolList()) { for (auto &symbol : chunk->getSymbolList()) {
ret.emplace(seq++, std::make_pair(symbol, 0)); ret.emplace(seq++, std::make_pair(symbol, 0));
if (++i >= rtp_count) { if (++i >= rtp_count) {
@ -465,23 +465,29 @@ FCI_TWCC::TwccPacketStatus FCI_TWCC::getPacketChunkList(size_t total_size) const
string FCI_TWCC::dumpString(size_t total_size) const { string FCI_TWCC::dumpString(size_t total_size) const {
_StrPrinter printer; _StrPrinter printer;
auto map = getPacketChunkList(total_size); 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"; printer << "twcc fci, base_seq:" << getBaseSeq() << ", pkt_status_count:" << getPacketCount()
<< ", ref time:" << getReferenceTime() << ", fb count:" << (int)fb_pkt_count << "\n";
for (auto &pr : map) { for (auto &pr : map) {
printer << "rtp seq:" << pr.first <<", packet status:" << (int)(pr.second.first) << ", delta:" << pr.second.second << "\n"; printer << "rtp seq:" << pr.first << ", packet status:" << (int)(pr.second.first)
<< ", delta:" << pr.second.second << "\n";
} }
return std::move(printer); return std::move(printer);
} }
static void appendDeltaString(string &delta_str, FCI_TWCC::TwccPacketStatus &status, int count){ static void appendDeltaString(string &delta_str, FCI_TWCC::TwccPacketStatus &status, int count) {
for (auto it = status.begin(); it != status.end() && count--;) { for (auto it = status.begin(); it != status.end() && count--;) {
switch (it->second.first) { switch (it->second.first) {
//large delta模式先写高字节再写低字节 // large delta模式先写高字节再写低字节
case SymbolStatus::large_delta: delta_str.push_back((it->second.second >> 8) & 0xFF); case SymbolStatus::large_delta:
//small delta模式只写低字节 delta_str.push_back((it->second.second >> 8) & 0xFF);
case SymbolStatus::small_delta: delta_str.push_back(it->second.second & 0xFF); break; // small delta模式只写低字节
default: break; case SymbolStatus::small_delta:
delta_str.push_back(it->second.second & 0xFF);
break;
default:
break;
} }
//移除已经处理过的数据 // 移除已经处理过的数据
it = status.erase(it); it = status.erase(it);
} }
} }
@ -489,7 +495,7 @@ static void appendDeltaString(string &delta_str, FCI_TWCC::TwccPacketStatus &sta
string FCI_TWCC::create(uint32_t ref_time, uint8_t fb_pkt_count, TwccPacketStatus &status) { string FCI_TWCC::create(uint32_t ref_time, uint8_t fb_pkt_count, TwccPacketStatus &status) {
string fci; string fci;
fci.resize(FCI_TWCC::kSize); fci.resize(FCI_TWCC::kSize);
FCI_TWCC *ptr = (FCI_TWCC *) (fci.data()); FCI_TWCC *ptr = (FCI_TWCC *)(fci.data());
ptr->base_seq = htons(status.begin()->first); ptr->base_seq = htons(status.begin()->first);
ptr->pkt_status_count = htons(status.size()); ptr->pkt_status_count = htons(status.size());
ptr->fb_pkt_count = fb_pkt_count; ptr->fb_pkt_count = fb_pkt_count;
@ -500,21 +506,21 @@ string FCI_TWCC::create(uint32_t ref_time, uint8_t fb_pkt_count, TwccPacketStatu
string delta_str; string delta_str;
while (!status.empty()) { while (!status.empty()) {
{ {
//第一个rtp的状态 // 第一个rtp的状态
auto symbol = status.begin()->second.first; auto symbol = status.begin()->second.first;
int16_t count = 0; int16_t count = 0;
for (auto &pr : status) { for (auto &pr : status) {
if (pr.second.first != symbol) { if (pr.second.first != symbol) {
//状态发送变更了本chunk结束 // 状态发送变更了本chunk结束
break; break;
} }
if (++count >= (0xFFFF >> 3)) { if (++count >= (0xFFFF >> 3)) {
//RunLengthChunk 13个bit表明rtp个数最多可以表述0xFFFF >> 3个rtp状态 // RunLengthChunk 13个bit表明rtp个数最多可以表述0xFFFF >> 3个rtp状态
break; break;
} }
} }
if (count >= 7) { if (count >= 7) {
//连续状态相同个数大于6个时使用RunLengthChunk模式比较节省带宽 // 连续状态相同个数大于6个时使用RunLengthChunk模式比较节省带宽
RunLengthChunk chunk(symbol, count); RunLengthChunk chunk(symbol, count);
fci.append((char *)&chunk, RunLengthChunk::kSize); fci.append((char *)&chunk, RunLengthChunk::kSize);
appendDeltaString(delta_str, status, count); appendDeltaString(delta_str, status, count);
@ -523,20 +529,20 @@ string FCI_TWCC::create(uint32_t ref_time, uint8_t fb_pkt_count, TwccPacketStatu
} }
{ {
//StatusVecChunk模式 // StatusVecChunk模式
//symbol_list中元素是1个bit // symbol_list中元素是1个bit
auto symbol = 0; auto symbol = 0;
vector<SymbolStatus> vec; vector<SymbolStatus> vec;
for (auto &pr : status) { for (auto &pr : status) {
vec.push_back(pr.second.first); vec.push_back(pr.second.first);
if (pr.second.first >= SymbolStatus::large_delta) { if (pr.second.first >= SymbolStatus::large_delta) {
//symbol_list中元素是2个bit // symbol_list中元素是2个bit
symbol = 1; symbol = 1;
} }
if (vec.size() << symbol >= 14) { if (vec.size() << symbol >= 14) {
//symbol为0时最多存放14个rtp的状态 // symbol为0时最多存放14个rtp的状态
//symbol为1时最多存放7个rtp的状态 // symbol为1时最多存放7个rtp的状态
break; break;
} }
} }
@ -547,9 +553,9 @@ string FCI_TWCC::create(uint32_t ref_time, uint8_t fb_pkt_count, TwccPacketStatu
} }
} }
//recv delta部分 // recv delta部分
fci.append(delta_str); fci.append(delta_str);
return fci; return fci;
} }
}//namespace mediakit } // namespace mediakit

207
src/Rtcp/RtcpFCI.h
View File

@ -11,37 +11,37 @@
#ifndef ZLMEDIAKIT_RTCPFCI_H #ifndef ZLMEDIAKIT_RTCPFCI_H
#define ZLMEDIAKIT_RTCPFCI_H #define ZLMEDIAKIT_RTCPFCI_H
#include "Rtcp.h"
#include "Common/config.h" #include "Common/config.h"
#include "Rtcp.h"
namespace mediakit { namespace mediakit {
/////////////////////////////////////////// PSFB //////////////////////////////////////////////////// /////////////////////////////////////////// PSFB ////////////////////////////////////////////////////
//PSFB fmt = 2 // PSFB fmt = 2
//https://tools.ietf.org/html/rfc4585#section-6.3.2.2 // https://tools.ietf.org/html/rfc4585#section-6.3.2.2
// 0 1 2 3 // 0 1 2 3
// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 // 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | First | Number | PictureID | // | First | Number | PictureID |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
//First: 13 bits // First: 13 bits
// The macroblock (MB) address of the first lost macroblock. The MB // The macroblock (MB) address of the first lost macroblock. The MB
// numbering is done such that the macroblock in the upper left // numbering is done such that the macroblock in the upper left
// corner of the picture is considered macroblock number 1 and the // corner of the picture is considered macroblock number 1 and the
// number for each macroblock increases from left to right and then // number for each macroblock increases from left to right and then
// from top to bottom in raster-scan order (such that if there is a // from top to bottom in raster-scan order (such that if there is a
// total of N macroblocks in a picture, the bottom right macroblock // total of N macroblocks in a picture, the bottom right macroblock
// is considered macroblock number N). // is considered macroblock number N).
// //
// Number: 13 bits // Number: 13 bits
// The number of lost macroblocks, in scan order as discussed above. // The number of lost macroblocks, in scan order as discussed above.
// //
// PictureID: 6 bits // PictureID: 6 bits
// The six least significant bits of the codec-specific identifier // The six least significant bits of the codec-specific identifier
// that is used to reference the picture in which the loss of the // that is used to reference the picture in which the loss of the
// macroblock(s) has occurred. For many video codecs, the PictureID // macroblock(s) has occurred. For many video codecs, the PictureID
// is identical to the Temporal Reference. // is identical to the Temporal Reference.
class FCI_SLI { class FCI_SLI {
public: public:
static size_t constexpr kSize = 4; static size_t constexpr kSize = 4;
@ -101,15 +101,15 @@ public:
} PACKED; } PACKED;
#endif #endif
//PSFB fmt = 4 // PSFB fmt = 4
//https://tools.ietf.org/html/rfc5104#section-4.3.1.1 // https://tools.ietf.org/html/rfc5104#section-4.3.1.1
// 0 1 2 3 // 0 1 2 3
// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 // 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | SSRC | // | SSRC |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | Seq nr. | Reserved | // | Seq nr. | Reserved |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
class FCI_FIR { class FCI_FIR {
public: public:
static size_t constexpr kSize = 8; static size_t constexpr kSize = 8;
@ -188,34 +188,34 @@ private:
#endif #endif
//PSFB fmt = 15 // PSFB fmt = 15
//https://tools.ietf.org/html/draft-alvestrand-rmcat-remb-03 // https://tools.ietf.org/html/draft-alvestrand-rmcat-remb-03
// 0 1 2 3 // 0 1 2 3
// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 // 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | Unique identifier 'R' 'E' 'M' 'B' | // | Unique identifier 'R' 'E' 'M' 'B' |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | Num SSRC | BR Exp | BR Mantissa | // | Num SSRC | BR Exp | BR Mantissa |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | SSRC feedback | // | SSRC feedback |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | ... | // | ... |
// Num SSRC (8 bits): Number of SSRCs in this message. // Num SSRC (8 bits): Number of SSRCs in this message.
// //
// BR Exp (6 bits): The exponential scaling of the mantissa for the // BR Exp (6 bits): The exponential scaling of the mantissa for the
// maximum total media bit rate value, ignoring all packet // maximum total media bit rate value, ignoring all packet
// overhead. The value is an unsigned integer [0..63], as // overhead. The value is an unsigned integer [0..63], as
// in RFC 5104 section 4.2.2.1. // in RFC 5104 section 4.2.2.1.
// //
// BR Mantissa (18 bits): The mantissa of the maximum total media bit // BR Mantissa (18 bits): The mantissa of the maximum total media bit
// rate (ignoring all packet overhead) that the sender of // rate (ignoring all packet overhead) that the sender of
// the REMB estimates. The BR is the estimate of the // the REMB estimates. The BR is the estimate of the
// traveled path for the SSRCs reported in this message. // traveled path for the SSRCs reported in this message.
// The value is an unsigned integer in number of bits per // The value is an unsigned integer in number of bits per
// second. // second.
// //
// SSRC feedback (32 bits) Consists of one or more SSRC entries which // SSRC feedback (32 bits) Consists of one or more SSRC entries which
// this feedback message applies to. // this feedback message applies to.
class FCI_REMB { class FCI_REMB {
public: public:
static size_t constexpr kSize = 8; static size_t constexpr kSize = 8;
@ -227,9 +227,9 @@ public:
std::vector<uint32_t> getSSRC(); std::vector<uint32_t> getSSRC();
private: private:
//Unique identifier 'R' 'E' 'M' 'B' // Unique identifier 'R' 'E' 'M' 'B'
char magic[4]; char magic[4];
//Num SSRC (8 bits)/BR Exp (6 bits)/ BR Mantissa (18 bits) // Num SSRC (8 bits)/BR Exp (6 bits)/ BR Mantissa (18 bits)
uint8_t bitrate[4]; uint8_t bitrate[4];
// SSRC feedback (32 bits) Consists of one or more SSRC entries which // SSRC feedback (32 bits) Consists of one or more SSRC entries which
// this feedback message applies to. // this feedback message applies to.
@ -238,13 +238,13 @@ private:
/////////////////////////////////////////// RTPFB //////////////////////////////////////////////////// /////////////////////////////////////////// RTPFB ////////////////////////////////////////////////////
//RTPFB fmt = 1 // RTPFB fmt = 1
//https://tools.ietf.org/html/rfc4585#section-6.2.1 // https://tools.ietf.org/html/rfc4585#section-6.2.1
// 0 1 2 3 // 0 1 2 3
// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 // 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | PID | BLP | // | PID | BLP |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
class FCI_NACK { class FCI_NACK {
public: public:
static constexpr size_t kSize = 4; static constexpr size_t kSize = 4;
@ -255,8 +255,8 @@ public:
void check(size_t size); void check(size_t size);
uint16_t getPid() const; uint16_t getPid() const;
uint16_t getBlp() const; uint16_t getBlp() const;
//返回丢包列表总长度17第一个包必丢 // 返回丢包列表总长度17第一个包必丢
// TODO: replace std::bitset // TODO: replace std::bitset
std::vector<bool> getBitArray() const; std::vector<bool> getBitArray() const;
std::string dumpString() const; std::string dumpString() const;
@ -318,47 +318,48 @@ public:
} PACKED; } PACKED;
#endif #endif
enum class SymbolStatus : uint8_t{ enum class SymbolStatus : uint8_t {
//Packet not received // Packet not received
not_received = 0, not_received = 0,
//Packet received, small delta 所谓small detal是指能用一个字节表示的数值 // Packet received, small delta 所谓small detal是指能用一个字节表示的数值
small_delta = 1, small_delta = 1,
// Packet received, large ornegative delta large即是能用两个字节表示的数值 // Packet received, large ornegative delta large即是能用两个字节表示的数值
large_delta = 2, large_delta = 2,
//Reserved // Reserved
reserved = 3 reserved = 3
}; };
//RTPFB fmt = 15 // RTPFB fmt = 15
//https://tools.ietf.org/html/draft-holmer-rmcat-transport-wide-cc-extensions-01#section-3.1 // https://tools.ietf.org/html/draft-holmer-rmcat-transport-wide-cc-extensions-01#section-3.1
//https://zhuanlan.zhihu.com/p/206656654 // https://zhuanlan.zhihu.com/p/206656654
// 0 1 2 3 // 0 1 2 3
// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 // 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | base sequence number | packet status count | // | base sequence number | packet status count |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | reference time | fb pkt. count | // | reference time | fb pkt. count |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | packet chunk | packet chunk | // | packet chunk | packet chunk |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// . . // . .
// . . // . .
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | packet chunk | recv delta | recv delta | // | packet chunk | recv delta | recv delta |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// . . // . .
// . . // . .
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | recv delta | recv delta | zero padding | // | recv delta | recv delta | zero padding |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ // +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
class FCI_TWCC{ class FCI_TWCC {
public: public:
static size_t constexpr kSize = 8; static size_t constexpr kSize = 8;
using TwccPacketStatus = std::map<uint16_t/*rtp ext seq*/, std::pair<SymbolStatus, int16_t/*recv delta,单位为250us*/> >; using TwccPacketStatus
= std::map<uint16_t /*rtp ext seq*/, std::pair<SymbolStatus, int16_t /*recv delta,单位为250us*/>>;
void check(size_t size); void check(size_t size);
std::string dumpString(size_t total_size) const; std::string dumpString(size_t total_size) const;
uint16_t getBaseSeq() const; uint16_t getBaseSeq() const;
//单位64ms // 单位64ms
uint32_t getReferenceTime() const; uint32_t getReferenceTime() const;
uint16_t getPacketCount() const; uint16_t getPacketCount() const;
TwccPacketStatus getPacketChunkList(size_t total_size) const; TwccPacketStatus getPacketChunkList(size_t total_size) const;
@ -366,15 +367,15 @@ public:
static std::string create(uint32_t ref_time, uint8_t fb_pkt_count, TwccPacketStatus &status); static std::string create(uint32_t ref_time, uint8_t fb_pkt_count, TwccPacketStatus &status);
private: private:
//base sequence number,基础序号,本次反馈的第一个包的序号;也就是RTP扩展头的序列号 // base sequence number,基础序号,本次反馈的第一个包的序号;也就是RTP扩展头的序列号
uint16_t base_seq; uint16_t base_seq;
//packet status count, 包个数,本次反馈包含多少个包的状态;从基础序号开始算 // packet status count, 包个数,本次反馈包含多少个包的状态;从基础序号开始算
uint16_t pkt_status_count; uint16_t pkt_status_count;
//reference time,基准时间,绝对时间;计算该包中每个媒体包的到达时间都要基于这个基准时间计算 // reference time,基准时间,绝对时间;计算该包中每个媒体包的到达时间都要基于这个基准时间计算
uint8_t ref_time[3]; uint8_t ref_time[3];
//feedback packet count,反馈包号,本包是第几个transport-cc包每次加1 | // feedback packet count,反馈包号,本包是第几个transport-cc包每次加1 |
uint8_t fb_pkt_count; uint8_t fb_pkt_count;
} PACKED; } PACKED;
} //namespace mediakit } // namespace mediakit
#endif //ZLMEDIAKIT_RTCPFCI_H #endif // ZLMEDIAKIT_RTCPFCI_H

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webrtc/WebRtcTransport.cpp
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