/// \file flv_tag.cpp
/// Holds all code for the FLV namespace.
#include "flv_tag.h"
#include "amf.h"
#include "rtmpchunks.h"
#include <stdio.h> //for Tag::FileLoader
#include <unistd.h> //for Tag::FileLoader
#include <fcntl.h> //for Tag::FileLoader
#include <stdlib.h> //malloc
#include <string.h> //memcpy
#include <sstream>
/// Holds the last FLV header parsed.
/// Defaults to a audio+video header on FLV version 0x01 if no header received yet.
char FLV::Header[13] = {'F', 'L', 'V', 0x01, 0x05, 0, 0, 0, 0x09, 0, 0, 0, 0};
bool FLV::Parse_Error = false; ///< This variable is set to true if a problem is encountered while parsing the FLV.
std::string FLV::Error_Str = "";
/// Checks a FLV Header for validness. Returns true if the header is valid, false
/// if the header is not. Not valid can mean:
/// - Not starting with the string "FLV".
/// - The DataOffset is not 9 bytes.
/// - The PreviousTagSize is not 0 bytes.
///
/// Note that we see PreviousTagSize as part of the FLV header, not part of the tag header!
bool FLV::check_header(char * header){
if (header[0] != 'F') return false;
if (header[1] != 'L') return false;
if (header[2] != 'V') return false;
if (header[5] != 0) return false;
if (header[6] != 0) return false;
if (header[7] != 0) return false;
if (header[8] != 0x09) return false;
if (header[9] != 0) return false;
if (header[10] != 0) return false;
if (header[11] != 0) return false;
if (header[12] != 0) return false;
return true;
}//FLV::check_header
/// Checks the first 3 bytes for the string "FLV". Implementing a basic FLV header check,
/// returning true if it is, false if not.
bool FLV::is_header(char * header){
if (header[0] != 'F') return false;
if (header[1] != 'L') return false;
if (header[2] != 'V') return false;
return true;
}//FLV::is_header
/// True if this media type requires init data.
/// Will always return false if the tag type is not 0x08 or 0x09.
/// Returns true for H263, AVC (H264), AAC.
/// \todo Check if MP3 does or does not require init data...
bool FLV::Tag::needsInitData(){
switch (data[0]){
case 0x09:
switch (data[11] & 0x0F){
case 2: return true; break;//H263 requires init data
case 7: return true; break;//AVC requires init data
default: return false; break;//other formats do not
}
break;
case 0x08:
switch (data[11] & 0xF0){
case 0x20: return false; break;//MP3 does not...? Unsure.
case 0xA0: return true; break;//AAC requires init data
case 0xE0: return false; break;//MP38kHz does not...?
default: return false; break;//other formats do not
}
break;
}
return false;//only audio/video can require init data
}
/// True if current tag is init data for this media type.
bool FLV::Tag::isInitData(){
switch (data[0]){
case 0x09:
switch (data[11] & 0xF0){
case 0x50: return true; break;
}
if ((data[11] & 0x0F) == 7){
switch (data[12]){
case 0: return true; break;
}
}
break;
case 0x08:
if ((data[12] == 0) && ((data[11] & 0xF0) == 0xA0)){
return true;
}
break;
}
return false;
}
/// Returns a std::string describing the tag in detail.
/// The string includes information about whether the tag is
/// audio, video or metadata, what encoding is used, and the details
/// of the encoding itself.
std::string FLV::Tag::tagType(){
std::stringstream R;
R << len << " bytes of ";
switch (data[0]){
case 0x09:
switch (data[11] & 0x0F){
case 1: R << "JPEG"; break;
case 2: R << "H263"; break;
case 3: R << "ScreenVideo1"; break;
case 4: R << "VP6"; break;
case 5: R << "VP6Alpha"; break;
case 6: R << "ScreenVideo2"; break;
case 7: R << "H264"; break;
default: R << "unknown"; break;
}
R << " video ";
switch (data[11] & 0xF0){
case 0x10: R << "keyframe"; break;
case 0x20: R << "iframe"; break;
case 0x30: R << "disposableiframe"; break;
case 0x40: R << "generatedkeyframe"; break;
case 0x50: R << "videoinfo"; break;
}
if ((data[11] & 0x0F) == 7){
switch (data[12]){
case 0: R << " header"; break;
case 1: R << " NALU"; break;
case 2: R << " endofsequence"; break;
}
}
break;
case 0x08:
switch (data[11] & 0xF0){
case 0x00: R << "linear PCM PE"; break;
case 0x10: R << "ADPCM"; break;
case 0x20: R << "MP3"; break;
case 0x30: R << "linear PCM LE"; break;
case 0x40: R << "Nelly16kHz"; break;
case 0x50: R << "Nelly8kHz"; break;
case 0x60: R << "Nelly"; break;
case 0x70: R << "G711A-law"; break;
case 0x80: R << "G711mu-law"; break;
case 0x90: R << "reserved"; break;
case 0xA0: R << "AAC"; break;
case 0xB0: R << "Speex"; break;
case 0xE0: R << "MP38kHz"; break;
case 0xF0: R << "DeviceSpecific"; break;
default: R << "unknown"; break;
}
switch (data[11] & 0x0C){
case 0x0: R << " 5.5kHz"; break;
case 0x4: R << " 11kHz"; break;
case 0x8: R << " 22kHz"; break;
case 0xC: R << " 44kHz"; break;
}
switch (data[11] & 0x02){
case 0: R << " 8bit"; break;
case 2: R << " 16bit"; break;
}
switch (data[11] & 0x01){
case 0: R << " mono"; break;
case 1: R << " stereo"; break;
}
R << " audio";
if ((data[12] == 0) && ((data[11] & 0xF0) == 0xA0)){
R << " initdata";
}
break;
case 0x12:{
R << "(meta)data: ";
AMF::Object metadata = AMF::parse((unsigned char*)data+11, len-15);
R << metadata.Print();
break;
}
default:
R << "unknown";
break;
}
return R.str();
}//FLV::Tag::tagtype
/// Returns the 32-bit timestamp of this tag.
unsigned int FLV::Tag::tagTime(){
return (data[4] << 16) + (data[5] << 8) + data[6] + (data[7] << 24);
}//tagTime getter
/// Sets the 32-bit timestamp of this tag.
void FLV::Tag::tagTime(unsigned int T){
data[4] = ((T >> 16) & 0xFF);
data[5] = ((T >> 8) & 0xFF);
data[6] = (T & 0xFF);
data[7] = ((T >> 24) & 0xFF);
}//tagTime setter
/// Constructor for a new, empty, tag.
/// The buffer length is initialized to 0, and later automatically
/// increased if neccesary.
FLV::Tag::Tag(){
len = 0; buf = 0; data = 0; isKeyframe = false; done = true; sofar = 0;
}//empty constructor
/// Copy constructor, copies the contents of an existing tag.
/// The buffer length is initialized to the actual size of the tag
/// that is being copied, and later automaticallt increased if
/// neccesary.
FLV::Tag::Tag(const Tag& O){
done = true;
sofar = 0;
buf = O.len;
len = buf;
if (len > 0){
data = (char*)malloc(len);
memcpy(data, O.data, len);
}else{
data = 0;
}
isKeyframe = O.isKeyframe;
}//copy constructor
/// Copy constructor from a RTMP chunk.
/// Copies the contents of a RTMP chunk into a valid FLV tag.
/// Exactly the same as making a chunk by through the default (empty) constructor
/// and then calling FLV::Tag::ChunkLoader with the chunk as argument.
FLV::Tag::Tag(const RTMPStream::Chunk& O){
len = 0; buf = 0; data = 0; isKeyframe = false; done = true; sofar = 0;
ChunkLoader(O);
}
/// Assignment operator - works exactly like the copy constructor.
/// This operator checks for self-assignment.
FLV::Tag & FLV::Tag::operator= (const FLV::Tag& O){
if (this != &O){//no self-assignment
len = O.len;
if (len > 0){
if (!data){
data = (char*)malloc(len);
buf = len;
}else{
if (buf < len){
data = (char*)realloc(data, len);
buf = len;
}
}
memcpy(data, O.data, len);
}
isKeyframe = O.isKeyframe;
}
return *this;
}//assignment operator
/// FLV loader function from DTSC.
/// Takes the DTSC data and makes it into FLV.
bool FLV::Tag::DTSCLoader(DTSC::Stream & S){
switch (S.lastType()){
case DTSC::VIDEO:
len = S.lastData().length() + 16;
if (S.metadata.getContentP("video") && S.metadata.getContentP("video")->getContentP("codec")){
if (S.metadata.getContentP("video")->getContentP("codec")->StrValue() == "H264"){len += 4;}
}
break;
case DTSC::AUDIO:
len = S.lastData().length() + 16;
if (S.metadata.getContentP("audio") && S.metadata.getContentP("audio")->getContentP("codec")){
if (S.metadata.getContentP("audio")->getContentP("codec")->StrValue() == "AAC"){len += 1;}
}
break;
case DTSC::META:
len = S.lastData().length() + 15;
break;
default://ignore all other types (there are currently no other types...)
break;
}
if (len > 0){
if (!data){
data = (char*)malloc(len);
buf = len;
}else{
if (buf < len){
data = (char*)realloc(data, len);
buf = len;
}
}
switch (S.lastType()){
case DTSC::VIDEO:
if ((unsigned int)len == S.lastData().length() + 16){
memcpy(data+12, S.lastData().c_str(), S.lastData().length());
}else{
memcpy(data+16, S.lastData().c_str(), S.lastData().length());
if (S.getPacket().getContentP("nalu")){data[12] = 1;}else{data[12] = 2;}
int offset = S.getPacket().getContentP("offset")->NumValue();
data[13] = (offset >> 16) & 0xFF;
data[14] = (offset >> 8) & 0XFF;
data[15] = offset & 0xFF;
}
data[11] = 0;
if (S.metadata.getContentP("video")->getContentP("codec")->StrValue() == "H264"){data[11] += 7;}
if (S.metadata.getContentP("video")->getContentP("codec")->StrValue() == "H263"){data[11] += 2;}
if (S.getPacket().getContentP("keyframe")){data[11] += 0x10;}
if (S.getPacket().getContentP("interframe")){data[11] += 0x20;}
if (S.getPacket().getContentP("disposableframe")){data[11] += 0x30;}
break;
case DTSC::AUDIO:{
if ((unsigned int)len == S.lastData().length() + 16){
memcpy(data+12, S.lastData().c_str(), S.lastData().length());
}else{
memcpy(data+13, S.lastData().c_str(), S.lastData().length());
data[12] = 1;//raw AAC data, not sequence header
}
data[11] = 0;
if (S.metadata.getContentP("audio")->getContentP("codec")->StrValue() == "AAC"){data[11] += 0xA0;}
if (S.metadata.getContentP("audio")->getContentP("codec")->StrValue() == "MP3"){data[11] += 0x20;}
unsigned int datarate = S.metadata.getContentP("audio")->getContentP("rate")->NumValue();
if (datarate >= 44100){
data[11] += 0x0C;
}else if(datarate >= 22050){
data[11] += 0x08;
}else if(datarate >= 11025){
data[11] += 0x04;
}
if (S.metadata.getContentP("audio")->getContentP("size")->NumValue() == 16){data[11] += 0x02;}
if (S.metadata.getContentP("audio")->getContentP("channels")->NumValue() > 1){data[11] += 0x01;}
break;
}
case DTSC::META:
memcpy(data+11, S.lastData().c_str(), S.lastData().length());
break;
default: break;
}
}
setLen();
switch (S.lastType()){
case DTSC::VIDEO: data[0] = 0x09; break;
case DTSC::AUDIO: data[0] = 0x08; break;
case DTSC::META: data[0] = 0x12; break;
default: break;
}
data[1] = ((len-15) >> 16) & 0xFF;
data[2] = ((len-15) >> 8) & 0xFF;
data[3] = (len-15) & 0xFF;
data[8] = 0;
data[9] = 0;
data[10] = 0;
tagTime(S.getPacket().getContentP("time")->NumValue());
return true;
}
/// Helper function that properly sets the tag length from the internal len variable.
void FLV::Tag::setLen(){
int len4 = len - 4;
int i = len;
data[--i] = (len4) & 0xFF;
len4 >>= 8;
data[--i] = (len4) & 0xFF;
len4 >>= 8;
data[--i] = (len4) & 0xFF;
len4 >>= 8;
data[--i] = (len4) & 0xFF;
}
/// FLV Video init data loader function from DTSC.
/// Takes the DTSC Video init data and makes it into FLV.
/// Assumes init data is available - so check before calling!
bool FLV::Tag::DTSCVideoInit(DTSC::Stream & S){
if (S.metadata.getContentP("video")->getContentP("codec")->StrValue() == "H264"){
len = S.metadata.getContentP("video")->getContentP("init")->StrValue().length() + 20;
}
if (len > 0){
if (!data){
data = (char*)malloc(len);
buf = len;
}else{
if (buf < len){
data = (char*)realloc(data, len);
buf = len;
}
}
memcpy(data+16, S.metadata.getContentP("video")->getContentP("init")->StrValue().c_str(), len-20);
data[12] = 0;//H264 sequence header
data[13] = 0;
data[14] = 0;
data[15] = 0;
data[11] = 0x17;//H264 keyframe (0x07 & 0x10)
}
setLen();
data[0] = 0x09;
data[1] = ((len-15) >> 16) & 0xFF;
data[2] = ((len-15) >> 8) & 0xFF;
data[3] = (len-15) & 0xFF;
data[8] = 0;
data[9] = 0;
data[10] = 0;
tagTime(0);
return true;
}
/// FLV Audio init data loader function from DTSC.
/// Takes the DTSC Audio init data and makes it into FLV.
/// Assumes init data is available - so check before calling!
bool FLV::Tag::DTSCAudioInit(DTSC::Stream & S){
len = 0;
if (S.metadata.getContentP("audio")->getContentP("codec")->StrValue() == "AAC"){
len = S.metadata.getContentP("audio")->getContentP("init")->StrValue().length() + 17;
}
if (len > 0){
if (!data){
data = (char*)malloc(len);
buf = len;
}else{
if (buf < len){
data = (char*)realloc(data, len);
buf = len;
}
}
memcpy(data+13, S.metadata.getContentP("audio")->getContentP("init")->StrValue().c_str(), len-17);
data[12] = 0;//AAC sequence header
data[11] = 0;
if (S.metadata.getContentP("audio")->getContentP("codec")->StrValue() == "AAC"){data[11] += 0xA0;}
if (S.metadata.getContentP("audio")->getContentP("codec")->StrValue() == "MP3"){data[11] += 0x20;}
unsigned int datarate = S.metadata.getContentP("audio")->getContentP("rate")->NumValue();
if (datarate >= 44100){
data[11] += 0x0C;
}else if(datarate >= 22050){
data[11] += 0x08;
}else if(datarate >= 11025){
data[11] += 0x04;
}
if (S.metadata.getContentP("audio")->getContentP("size")->NumValue() == 16){data[11] += 0x02;}
if (S.metadata.getContentP("audio")->getContentP("channels")->NumValue() > 1){data[11] += 0x01;}
}
setLen();
data[0] = 0x08;
data[1] = ((len-15) >> 16) & 0xFF;
data[2] = ((len-15) >> 8) & 0xFF;
data[3] = (len-15) & 0xFF;
data[8] = 0;
data[9] = 0;
data[10] = 0;
tagTime(0);
return true;
}
/// FLV metadata loader function from DTSC.
/// Takes the DTSC metadata and makes it into FLV.
/// Assumes metadata is available - so check before calling!
bool FLV::Tag::DTSCMetaInit(DTSC::Stream & S){
AMF::Object amfdata("root", AMF::AMF0_DDV_CONTAINER);
amfdata.addContent(AMF::Object("", "onMetaData"));
amfdata.addContent(AMF::Object("", AMF::AMF0_ECMA_ARRAY));
if (S.metadata.getContentP("video")){
amfdata.getContentP(1)->addContent(AMF::Object("hasVideo", 1, AMF::AMF0_BOOL));
if (S.metadata.getContentP("video")->getContentP("codec")->StrValue() == "H264"){
amfdata.getContentP(1)->addContent(AMF::Object("videocodecid", 7, AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("video")->getContentP("codec")->StrValue() == "VP6"){
amfdata.getContentP(1)->addContent(AMF::Object("videocodecid", 4, AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("video")->getContentP("codec")->StrValue() == "H263"){
amfdata.getContentP(1)->addContent(AMF::Object("videocodecid", 2, AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("video")->getContentP("width")){
amfdata.getContentP(1)->addContent(AMF::Object("width", S.metadata.getContentP("video")->getContentP("width")->NumValue(), AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("video")->getContentP("height")){
amfdata.getContentP(1)->addContent(AMF::Object("height", S.metadata.getContentP("video")->getContentP("height")->NumValue(), AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("video")->getContentP("fpks")){
amfdata.getContentP(1)->addContent(AMF::Object("framerate", (double)S.metadata.getContentP("video")->getContentP("fpks")->NumValue() / 1000.0, AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("video")->getContentP("bps")){
amfdata.getContentP(1)->addContent(AMF::Object("videodatarate", ((double)S.metadata.getContentP("video")->getContentP("bps")->NumValue() * 8.0) / 1024.0, AMF::AMF0_NUMBER));
}
}
if (S.metadata.getContentP("audio")){
amfdata.getContentP(1)->addContent(AMF::Object("hasAudio", 1, AMF::AMF0_BOOL));
amfdata.getContentP(1)->addContent(AMF::Object("audiodelay", 0, AMF::AMF0_NUMBER));
if (S.metadata.getContentP("audio")->getContentP("codec")->StrValue() == "AAC"){
amfdata.getContentP(1)->addContent(AMF::Object("audiocodecid", 10, AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("audio")->getContentP("codec")->StrValue() == "MP3"){
amfdata.getContentP(1)->addContent(AMF::Object("audiocodecid", 2, AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("audio")->getContentP("channels")){
if (S.metadata.getContentP("audio")->getContentP("channels")->NumValue() > 1){
amfdata.getContentP(1)->addContent(AMF::Object("stereo", 1, AMF::AMF0_BOOL));
}else{
amfdata.getContentP(1)->addContent(AMF::Object("stereo", 0, AMF::AMF0_BOOL));
}
}
if (S.metadata.getContentP("audio")->getContentP("rate")){
amfdata.getContentP(1)->addContent(AMF::Object("audiosamplerate", S.metadata.getContentP("audio")->getContentP("rate")->NumValue(), AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("audio")->getContentP("size")){
amfdata.getContentP(1)->addContent(AMF::Object("audiosamplesize", S.metadata.getContentP("audio")->getContentP("size")->NumValue(), AMF::AMF0_NUMBER));
}
if (S.metadata.getContentP("audio")->getContentP("bps")){
amfdata.getContentP(1)->addContent(AMF::Object("audiodatarate", ((double)S.metadata.getContentP("audio")->getContentP("bps")->NumValue() * 8.0) / 1024.0, AMF::AMF0_NUMBER));
}
}
std::string tmp = amfdata.Pack();
len = tmp.length() + 15;
if (len > 0){
if (!data){
data = (char*)malloc(len);
buf = len;
}else{
if (buf < len){
data = (char*)realloc(data, len);
buf = len;
}
}
memcpy(data+11, tmp.c_str(), len-15);
}
setLen();
data[0] = 0x12;
data[1] = ((len-15) >> 16) & 0xFF;
data[2] = ((len-15) >> 8) & 0xFF;
data[3] = (len-15) & 0xFF;
data[8] = 0;
data[9] = 0;
data[10] = 0;
tagTime(0);
return true;
}
/// FLV loader function from chunk.
/// Copies the contents and wraps it in a FLV header.
bool FLV::Tag::ChunkLoader(const RTMPStream::Chunk& O){
len = O.len + 15;
if (len > 0){
if (!data){
data = (char*)malloc(len);
buf = len;
}else{
if (buf < len){
data = (char*)realloc(data, len);
buf = len;
}
}
memcpy(data+11, &(O.data[0]), O.len);
}
setLen();
data[0] = O.msg_type_id;
data[3] = O.len & 0xFF;
data[2] = (O.len >> 8) & 0xFF;
data[1] = (O.len >> 16) & 0xFF;
tagTime(O.timestamp);
return true;
}
/// Helper function for FLV::MemLoader.
/// This function will try to read count bytes from data buffer D into buffer.
/// This function should be called repeatedly until true.
/// P and sofar are not the same value, because D may not start with the current tag.
/// \param buffer The target buffer.
/// \param count Amount of bytes to read.
/// \param sofar Current amount read.
/// \param D The location of the data buffer.
/// \param S The size of the data buffer.
/// \param P The current position in the data buffer. Will be updated to reflect new position.
/// \return True if count bytes are read succesfully, false otherwise.
bool FLV::Tag::MemReadUntil(char * buffer, unsigned int count, unsigned int & sofar, char * D, unsigned int S, unsigned int & P){
if (sofar >= count){return true;}
int r = 0;
if (P+(count-sofar) > S){r = S-P;}else{r = count-sofar;}
memcpy(buffer+sofar, D+P, r);
P += r;
sofar += r;
if (sofar >= count){return true;}
return false;
}//Tag::MemReadUntil
/// Try to load a tag from a data buffer in memory.
/// This is a stateful function - if fed incorrect data, it will most likely never return true again!
/// While this function returns false, the Tag might not contain valid data.
/// \param D The location of the data buffer.
/// \param S The size of the data buffer.
/// \param P The current position in the data buffer. Will be updated to reflect new position.
/// \return True if a whole tag is succesfully read, false otherwise.
bool FLV::Tag::MemLoader(char * D, unsigned int S, unsigned int & P){
if (buf < 15){data = (char*)realloc(data, 15); buf = 15;}
if (done){
//read a header
if (MemReadUntil(data, 11, sofar, D, S, P)){
//if its a correct FLV header, throw away and read tag header
if (FLV::is_header(data)){
if (MemReadUntil(data, 13, sofar, D, S, P)){
if (FLV::check_header(data)){
sofar = 0;
memcpy(FLV::Header, data, 13);
}else{FLV::Parse_Error = true; Error_Str = "Invalid header received."; return false;}
}
}else{
//if a tag header, calculate length and read tag body
len = data[3] + 15;
len += (data[2] << 8);
len += (data[1] << 16);
if (buf < len){data = (char*)realloc(data, len); buf = len;}
if (data[0] > 0x12){
data[0] += 32;
FLV::Parse_Error = true;
Error_Str = "Invalid Tag received (";
Error_Str += data[0];
Error_Str += ").";
return false;
}
done = false;
}
}
}else{
//read tag body
if (MemReadUntil(data, len, sofar, D, S, P)){
//calculate keyframeness, next time read header again, return true
if ((data[0] == 0x09) && (((data[11] & 0xf0) >> 4) == 1)){isKeyframe = true;}else{isKeyframe = false;}
done = true;
sofar = 0;
return true;
}
}
return false;
}//Tag::MemLoader
/// Helper function for FLV::SockLoader.
/// This function will try to read count bytes from socket sock into buffer.
/// This function should be called repeatedly until true.
/// \param buffer The target buffer.
/// \param count Amount of bytes to read.
/// \param sofar Current amount read.
/// \param sock Socket to read from.
/// \return True if count bytes are read succesfully, false otherwise.
bool FLV::Tag::SockReadUntil(char * buffer, unsigned int count, unsigned int & sofar, Socket::Connection & sock){
if (sofar >= count){return true;}
int r = 0;
r = sock.iread(buffer + sofar,count-sofar);
sofar += r;
if (sofar >= count){return true;}
return false;
}//Tag::SockReadUntil
/// Try to load a tag from a socket.
/// This is a stateful function - if fed incorrect data, it will most likely never return true again!
/// While this function returns false, the Tag might not contain valid data.
/// \param sock The socket to read from.
/// \return True if a whole tag is succesfully read, false otherwise.
bool FLV::Tag::SockLoader(Socket::Connection sock){
if (buf < 15){data = (char*)realloc(data, 15); buf = 15;}
if (done){
if (SockReadUntil(data, 11, sofar, sock)){
//if its a correct FLV header, throw away and read tag header
if (FLV::is_header(data)){
if (SockReadUntil(data, 13, sofar, sock)){
if (FLV::check_header(data)){
sofar = 0;
memcpy(FLV::Header, data, 13);
}else{FLV::Parse_Error = true; Error_Str = "Invalid header received."; return false;}
}
}else{
//if a tag header, calculate length and read tag body
len = data[3] + 15;
len += (data[2] << 8);
len += (data[1] << 16);
if (buf < len){data = (char*)realloc(data, len); buf = len;}
if (data[0] > 0x12){
data[0] += 32;
FLV::Parse_Error = true;
Error_Str = "Invalid Tag received (";
Error_Str += data[0];
Error_Str += ").";
return false;
}
done = false;
}
}
}else{
//read tag body
if (SockReadUntil(data, len, sofar, sock)){
//calculate keyframeness, next time read header again, return true
if ((data[0] == 0x09) && (((data[11] & 0xf0) >> 4) == 1)){isKeyframe = true;}else{isKeyframe = false;}
done = true;
sofar = 0;
return true;
}
}
return false;
}//Tag::SockLoader
/// Try to load a tag from a socket.
/// This is a stateful function - if fed incorrect data, it will most likely never return true again!
/// While this function returns false, the Tag might not contain valid data.
/// \param sock The socket to read from.
/// \return True if a whole tag is succesfully read, false otherwise.
bool FLV::Tag::SockLoader(int sock){
return SockLoader(Socket::Connection(sock));
}//Tag::SockLoader
/// Helper function for FLV::FileLoader.
/// This function will try to read count bytes from file f into buffer.
/// This function should be called repeatedly until true.
/// \param buffer The target buffer.
/// \param count Amount of bytes to read.
/// \param sofar Current amount read.
/// \param f File to read from.
/// \return True if count bytes are read succesfully, false otherwise.
bool FLV::Tag::FileReadUntil(char * buffer, unsigned int count, unsigned int & sofar, FILE * f){
if (sofar >= count){return true;}
int r = 0;
r = fread(buffer + sofar,1,count-sofar,f);
if (r < 0){FLV::Parse_Error = true; Error_Str = "File reading error."; return false;}
sofar += r;
if (sofar >= count){return true;}
return false;
}
/// Try to load a tag from a file.
/// This is a stateful function - if fed incorrect data, it will most likely never return true again!
/// While this function returns false, the Tag might not contain valid data.
/// \param f The file to read from.
/// \return True if a whole tag is succesfully read, false otherwise.
bool FLV::Tag::FileLoader(FILE * f){
int preflags = fcntl(fileno(f), F_GETFL, 0);
int postflags = preflags | O_NONBLOCK;
fcntl(fileno(f), F_SETFL, postflags);
if (buf < 15){data = (char*)realloc(data, 15); buf = 15;}
if (done){
//read a header
if (FileReadUntil(data, 11, sofar, f)){
//if its a correct FLV header, throw away and read tag header
if (FLV::is_header(data)){
if (FileReadUntil(data, 13, sofar, f)){
if (FLV::check_header(data)){
sofar = 0;
memcpy(FLV::Header, data, 13);
}else{FLV::Parse_Error = true; Error_Str = "Invalid header received."; return false;}
}
}else{
//if a tag header, calculate length and read tag body
len = data[3] + 15;
len += (data[2] << 8);
len += (data[1] << 16);
if (buf < len){data = (char*)realloc(data, len); buf = len;}
if (data[0] > 0x12){
data[0] += 32;
FLV::Parse_Error = true;
Error_Str = "Invalid Tag received (";
Error_Str += data[0];
Error_Str += ").";
return false;
}
done = false;
}
}
}else{
//read tag body
if (FileReadUntil(data, len, sofar, f)){
//calculate keyframeness, next time read header again, return true
if ((data[0] == 0x09) && (((data[11] & 0xf0) >> 4) == 1)){isKeyframe = true;}else{isKeyframe = false;}
done = true;
sofar = 0;
fcntl(fileno(f), F_SETFL, preflags);
return true;
}
}
fcntl(fileno(f), F_SETFL, preflags);
return false;
}//FLV_GetPacket
DTSC::DTMI FLV::Tag::toDTSC(DTSC::DTMI & metadata){
DTSC::DTMI pack_out; // Storage for outgoing DTMI data.
if (data[0] == 0x12){
AMF::Object meta_in = AMF::parse((unsigned char*)data+11, len-15);
if (meta_in.getContentP(0) && (meta_in.getContentP(0)->StrValue() == "onMetaData") && meta_in.getContentP(1)){
AMF::Object * tmp = meta_in.getContentP(1);
if (tmp->getContentP("videocodecid")){
switch ((unsigned int)tmp->getContentP("videocodecid")->NumValue()){
case 2: Meta_Put(metadata, "video", "codec", "H263"); break;
case 4: Meta_Put(metadata, "video", "codec", "VP6"); break;
case 7: Meta_Put(metadata, "video", "codec", "H264"); break;
default: Meta_Put(metadata, "video", "codec", "?"); break;
}
}
if (tmp->getContentP("audiocodecid")){
switch ((unsigned int)tmp->getContentP("audiocodecid")->NumValue()){
case 2: Meta_Put(metadata, "audio", "codec", "MP3"); break;
case 10: Meta_Put(metadata, "audio", "codec", "AAC"); break;
default: Meta_Put(metadata, "audio", "codec", "?"); break;
}
}
if (tmp->getContentP("width")){
Meta_Put(metadata, "video", "width", tmp->getContentP("width")->NumValue());
}
if (tmp->getContentP("height")){
Meta_Put(metadata, "video", "height", tmp->getContentP("height")->NumValue());
}
if (tmp->getContentP("framerate")){
Meta_Put(metadata, "video", "fpks", tmp->getContentP("framerate")->NumValue()*1000);
}
if (tmp->getContentP("videodatarate")){
Meta_Put(metadata, "video", "bps", (tmp->getContentP("videodatarate")->NumValue()*1024)/8);
}
if (tmp->getContentP("audiodatarate")){
Meta_Put(metadata, "audio", "bps", (tmp->getContentP("audiodatarate")->NumValue()*1024)/8);
}
if (tmp->getContentP("audiosamplerate")){
Meta_Put(metadata, "audio", "rate", tmp->getContentP("audiosamplerate")->NumValue());
}
if (tmp->getContentP("audiosamplesize")){
Meta_Put(metadata, "audio", "size", tmp->getContentP("audiosamplesize")->NumValue());
}
if (tmp->getContentP("stereo")){
if (tmp->getContentP("stereo")->NumValue() == 1){
Meta_Put(metadata, "audio", "channels", 2);
}else{
Meta_Put(metadata, "audio", "channels", 1);
}
}
}
return pack_out;//empty
}
if (data[0] == 0x08){
char audiodata = data[11];
if (needsInitData() && isInitData()){
if ((audiodata & 0xF0) == 0xA0){
Meta_Put(metadata, "audio", "init", std::string((char*)data+13, (size_t)len-17));
}else{
Meta_Put(metadata, "audio", "init", std::string((char*)data+12, (size_t)len-16));
}
return pack_out;//skip rest of parsing, get next tag.
}
pack_out = DTSC::DTMI("audio", DTSC::DTMI_ROOT);
pack_out.addContent(DTSC::DTMI("datatype", "audio"));
pack_out.addContent(DTSC::DTMI("time", tagTime()));
if (!Meta_Has(metadata, "audio", "codec")){
switch (audiodata & 0xF0){
case 0x20: Meta_Put(metadata, "audio", "codec", "MP3"); break;
case 0xA0: Meta_Put(metadata, "audio", "codec", "AAC"); break;
default: Meta_Put(metadata, "audio", "codec", "?"); break;
}
}
if (!Meta_Has(metadata, "audio", "rate")){
switch (audiodata & 0x0C){
case 0x0: Meta_Put(metadata, "audio", "rate", 5512); break;
case 0x4: Meta_Put(metadata, "audio", "rate", 11025); break;
case 0x8: Meta_Put(metadata, "audio", "rate", 22050); break;
case 0xC: Meta_Put(metadata, "audio", "rate", 44100); break;
}
}
if (!Meta_Has(metadata, "audio", "size")){
switch (audiodata & 0x02){
case 0x0: Meta_Put(metadata, "audio", "size", 8); break;
case 0x2: Meta_Put(metadata, "audio", "size", 16); break;
}
}
if (!Meta_Has(metadata, "audio", "channels")){
switch (audiodata & 0x01){
case 0x0: Meta_Put(metadata, "audio", "channels", 1); break;
case 0x1: Meta_Put(metadata, "audio", "channels", 2); break;
}
}
if ((audiodata & 0xF0) == 0xA0){
pack_out.addContent(DTSC::DTMI("data", std::string((char*)data+13, (size_t)len-17)));
}else{
pack_out.addContent(DTSC::DTMI("data", std::string((char*)data+12, (size_t)len-16)));
}
return pack_out;
}
if (data[0] == 0x09){
char videodata = data[11];
if (needsInitData() && isInitData()){
if ((videodata & 0x0F) == 7){
Meta_Put(metadata, "video", "init", std::string((char*)data+16, (size_t)len-20));
}else{
Meta_Put(metadata, "video", "init", std::string((char*)data+12, (size_t)len-16));
}
return pack_out;//skip rest of parsing, get next tag.
}
if (!Meta_Has(metadata, "video", "codec")){
switch (videodata & 0x0F){
case 2: Meta_Put(metadata, "video", "codec", "H263"); break;
case 4: Meta_Put(metadata, "video", "codec", "VP6"); break;
case 7: Meta_Put(metadata, "video", "codec", "H264"); break;
default: Meta_Put(metadata, "video", "codec", "?"); break;
}
}
pack_out = DTSC::DTMI("video", DTSC::DTMI_ROOT);
pack_out.addContent(DTSC::DTMI("datatype", "video"));
switch (videodata & 0xF0){
case 0x10: pack_out.addContent(DTSC::DTMI("keyframe", 1)); break;
case 0x20: pack_out.addContent(DTSC::DTMI("interframe", 1)); break;
case 0x30: pack_out.addContent(DTSC::DTMI("disposableframe", 1)); break;
case 0x40: pack_out.addContent(DTSC::DTMI("keyframe", 1)); break;
case 0x50: return DTSC::DTMI(); break;//the video info byte we just throw away - useless to us...
}
pack_out.addContent(DTSC::DTMI("time", tagTime()));
if ((videodata & 0x0F) == 7){
switch (data[12]){
case 1: pack_out.addContent(DTSC::DTMI("nalu", 1)); break;
case 2: pack_out.addContent(DTSC::DTMI("nalu_end", 1)); break;
}
int offset = (data[13] << 16) + (data[14] << 8) + data[15];
offset = (offset << 8) >> 8;
pack_out.addContent(DTSC::DTMI("offset", offset));
pack_out.addContent(DTSC::DTMI("data", std::string((char*)data+16, (size_t)len-20)));
}else{
pack_out.addContent(DTSC::DTMI("data", std::string((char*)data+12, (size_t)len-16)));
}
return pack_out;
}
return pack_out;//should never get here
}//FLV::Tag::toDTSC
/// Inserts std::string type metadata into the passed DTMI object.
/// \arg meta The DTMI object to put the metadata into.
/// \arg cat Metadata category to insert into.
/// \arg elem Element name to put into the category.
/// \arg val Value to put into the element name.
void FLV::Tag::Meta_Put(DTSC::DTMI & meta, std::string cat, std::string elem, std::string val){
if (meta.getContentP(cat) == 0){meta.addContent(DTSC::DTMI(cat));}
meta.getContentP(cat)->addContent(DTSC::DTMI(elem, val));
}
/// Inserts uint64_t type metadata into the passed DTMI object.
/// \arg meta The DTMI object to put the metadata into.
/// \arg cat Metadata category to insert into.
/// \arg elem Element name to put into the category.
/// \arg val Value to put into the element name.
void FLV::Tag::Meta_Put(DTSC::DTMI & meta, std::string cat, std::string elem, uint64_t val){
if (meta.getContentP(cat) == 0){meta.addContent(DTSC::DTMI(cat));}
meta.getContentP(cat)->addContent(DTSC::DTMI(elem, val));
}
/// Returns true if the named category and elementname are available in the metadata.
/// \arg meta The DTMI object to check.
/// \arg cat Metadata category to check.
/// \arg elem Element name to check.
bool FLV::Tag::Meta_Has(DTSC::DTMI & meta, std::string cat, std::string elem){
if (meta.getContentP(cat) == 0){return false;}
if (meta.getContentP(cat)->getContentP(elem) == 0){return false;}
return true;
}