/// \file dtsc.cpp
/// Holds all code for DDVTECH Stream Container parsing/generation.
#include "dtsc.h"
#include <stdlib.h>
#include <string.h> //for memcmp
#include <arpa/inet.h> //for htonl/ntohl
char DTSC::Magic_Header[] = "DTSC";
char DTSC::Magic_Packet[] = "DTPD";
char DTSC::Magic_Packet2[] = "DTP2";
/// Initializes a DTSC::Stream with only one packet buffer.
DTSC::Stream::Stream(){
datapointertype = DTSC::INVALID;
buffercount = 1;
buffertime = 0;
}
/// Initializes a DTSC::Stream with a minimum of rbuffers packet buffers.
/// The actual buffer count may not at all times be the requested amount.
DTSC::Stream::Stream(unsigned int rbuffers, unsigned int bufferTime){
datapointertype = DTSC::INVALID;
if (rbuffers < 1){
rbuffers = 1;
}
buffercount = rbuffers;
buffertime = bufferTime;
}
/// This function does nothing, it's supposed to be overridden.
/// It will be called right before a buffer position is deleted.
void DTSC::Stream::deletionCallback(livePos deleting){}
/// Returns the time in milliseconds of the last received packet.
/// This is _not_ the time this packet was received, only the stored time.
unsigned int DTSC::Stream::getTime(){
return buffers.rbegin()->second["time"].asInt();
}
/// Attempts to parse a packet from the given std::string buffer.
/// Returns true if successful, removing the parsed part from the buffer string.
/// Returns false if invalid or not enough data is in the buffer.
/// \arg buffer The std::string buffer to attempt to parse.
bool DTSC::Stream::parsePacket(std::string & buffer){
uint32_t len;
static bool syncing = false;
if (buffer.length() > 8){
if (memcmp(buffer.c_str(), DTSC::Magic_Header, 4) == 0){
len = ntohl(((uint32_t *)buffer.c_str())[1]);
if (buffer.length() < len + 8){
return false;
}
unsigned int i = 0;
JSON::Value meta = JSON::fromDTMI((unsigned char*)buffer.c_str() + 8, len, i);
metadata = Meta(meta);
buffer.erase(0, len + 8);
if (buffer.length() <= 8){
return false;
}
}
int version = 0;
if (memcmp(buffer.c_str(), DTSC::Magic_Packet, 4) == 0){
version = 1;
}
if (memcmp(buffer.c_str(), DTSC::Magic_Packet2, 4) == 0){
version = 2;
}
if (version){
len = ntohl(((uint32_t *)buffer.c_str())[1]);
if (buffer.length() < len + 8){
return false;
}
JSON::Value newPack;
unsigned int i = 0;
if (version == 1){
newPack = JSON::fromDTMI((unsigned char*)buffer.c_str() + 8, len, i);
}
if (version == 2){
newPack = JSON::fromDTMI2((unsigned char*)buffer.c_str() + 8, len, i);
}
buffer.erase(0, len + 8);
addPacket(newPack);
syncing = false;
return true;
}
#if DEBUG >= 2
if (!syncing){
std::cerr << "Error: Invalid DTMI data detected - re-syncing" << std::endl;
syncing = true;
}
#endif
size_t magic_search = buffer.find(Magic_Packet);
size_t magic_search2 = buffer.find(Magic_Packet2);
if (magic_search2 == std::string::npos){
if (magic_search == std::string::npos){
buffer.clear();
}else{
buffer.erase(0, magic_search);
}
}else{
buffer.erase(0, magic_search2);
}
}
return false;
}
/// Attempts to parse a packet from the given Socket::Buffer.
/// Returns true if successful, removing the parsed part from the buffer.
/// Returns false if invalid or not enough data is in the buffer.
/// \arg buffer The Socket::Buffer to attempt to parse.
bool DTSC::Stream::parsePacket(Socket::Buffer & buffer){
uint32_t len;
static bool syncing = false;
if (buffer.available(8)){
std::string header_bytes = buffer.copy(8);
if (memcmp(header_bytes.c_str(), DTSC::Magic_Header, 4) == 0){
len = ntohl(((uint32_t *)header_bytes.c_str())[1]);
if ( !buffer.available(len + 8)){
return false;
}
unsigned int i = 0;
std::string wholepacket = buffer.remove(len + 8);
JSON::Value meta = JSON::fromDTMI((unsigned char*)wholepacket.c_str() + 8, len, i);
addMeta(meta);
//recursively calls itself until failure or data packet instead of header
return parsePacket(buffer);
}
int version = 0;
if (memcmp(header_bytes.c_str(), DTSC::Magic_Packet, 4) == 0){
version = 1;
}
if (memcmp(header_bytes.c_str(), DTSC::Magic_Packet2, 4) == 0){
version = 2;
}
if (version){
len = ntohl(((uint32_t *)header_bytes.c_str())[1]);
if ( !buffer.available(len + 8)){
return false;
}
JSON::Value newPack;
unsigned int i = 0;
std::string wholepacket = buffer.remove(len + 8);
if (version == 1){
newPack = JSON::fromDTMI((unsigned char*)wholepacket.c_str() + 8, len, i);
}
if (version == 2){
newPack = JSON::fromDTMI2((unsigned char*)wholepacket.c_str() + 8, len, i);
}
addPacket(newPack);
syncing = false;
return true;
}
#if DEBUG >= 2
if (!syncing){
std::cerr << "Error: Invalid DTMI data detected - syncing" << std::endl;
syncing = true;
}
#endif
buffer.get().clear();
}
return false;
}
/// Adds a keyframe packet to all tracks, so the stream can be fully played.
void DTSC::Stream::endStream(){
for (std::map<int,Track>::iterator it = metadata.tracks.begin(); it != metadata.tracks.end(); it++){
JSON::Value newPack;
newPack["time"] = it->second.lastms;
newPack["trackid"] = it->second.trackID;
newPack["keyframe"] = 1ll;
newPack["data"] = "";
addPacket(newPack);
}
}
/// Blocks until either the stream has metadata available or the sourceSocket errors.
/// This function is intended to be run before any commands are sent and thus will not throw away anything important.
void DTSC::Stream::waitForMeta(Socket::Connection & sourceSocket){
while ( !metadata && sourceSocket.connected()){
//we have data? attempt to read header
if (sourceSocket.Received().size()){
//return value is ignore because we're not interested in data packets, just metadata.
parsePacket(sourceSocket.Received());
}
//still no header? check for more data
if ( !metadata){
if (sourceSocket.spool()){
//more received? attempt to read
//return value is ignore because we're not interested in data packets, just metadata.
parsePacket(sourceSocket.Received());
}else{
//nothing extra to receive? wait a bit and retry
Util::sleep(5);
}
}
}
}
/// Resets the stream by clearing the buffers and keyframes, making sure to call the deletionCallback first.
void DTSC::Stream::resetStream(){
for (std::map<livePos, JSON::Value >::iterator it = buffers.begin(); it != buffers.end(); it++){
deletionCallback(it->first);
}
buffers.clear();
keyframes.clear();
}
/// Adds a set of metadata to the steam.
/// This is implemented by simply replacing the current metadata.
/// This effectively resets the stream.
void DTSC::Stream::addMeta(JSON::Value & newMeta){
metadata = Meta(newMeta);
}
/// Adds a single DTSC packet to the stream, updating the internal metadata if needed.
void DTSC::Stream::addPacket(JSON::Value & newPack){
long long unsigned int now = Util::getMS();
livePos newPos;
newPos.trackID = newPack["trackid"].asInt();
newPos.seekTime = newPack["time"].asInt();
if (buffercount > 1 && metadata.tracks[newPos.trackID].keys.size() > 1 && newPos.seekTime < metadata.tracks[newPos.trackID].keys.rbegin()->getTime()){
resetStream();
}
while (buffers.count(newPos) > 0){
newPos.seekTime++;
}
while (buffercount == 1 && buffers.size() > 0){
cutOneBuffer();
}
buffers[newPos] = newPack;
datapointertype = INVALID;
std::string tmp = "";
if (newPack.isMember("trackid") && newPack["trackid"].asInt() > 0){
tmp = metadata.tracks[newPack["trackid"].asInt()].type;
}
if (newPack.isMember("datatype")){
tmp = newPack["datatype"].asStringRef();
}
if (tmp == "video"){
datapointertype = VIDEO;
}
if (tmp == "audio"){
datapointertype = AUDIO;
}
if (tmp == "meta"){
datapointertype = META;
}
if (tmp == "pause_marker" || (newPack.isMember("mark") && newPack["mark"].asStringRef() == "pause")){
datapointertype = PAUSEMARK;
}
if (buffercount > 1){
metadata.update(newPack);
if (newPack.isMember("keyframe") || metadata.tracks[newPos.trackID].keys.rbegin()->getTime() == newPos.seekTime){
keyframes[newPos.trackID].insert(newPos);
}
metadata.live = true;
//throw away buffers if buffer time is met
int trid = buffers.begin()->first.trackID;
int firstTime = buffers.begin()->first.seekTime;
while (metadata.tracks[trid].keys.size() > 2 && metadata.tracks[trid].keys.rbegin()->getTime() - firstTime > buffertime){
cutOneBuffer();
trid = buffers.begin()->first.trackID;
firstTime = buffers.begin()->first.seekTime;
}
metadata.bufferWindow = buffertime;
}
}
/// Deletes a the first part of the buffer, updating the keyframes list and metadata as required.
/// Will print a warning to std::cerr if a track has less than 2 keyframes left because of this.
void DTSC::Stream::cutOneBuffer(){
int trid = buffers.begin()->first.trackID;
int delTime = buffers.begin()->first.seekTime;
if (buffercount > 1){
while (keyframes[trid].size() > 0 && keyframes[trid].begin()->seekTime <= delTime){
keyframes[trid].erase(keyframes[trid].begin());
}
while (metadata.tracks[trid].keys.size() && metadata.tracks[trid].keys[0].getTime() <= delTime){
for (int i = 0; i < metadata.tracks[trid].keys[0].getParts(); i++){
metadata.tracks[trid].parts.pop_front();
}
metadata.tracks[trid].keys.pop_front();
}
if (metadata.tracks[trid].keys.size()){
metadata.tracks[trid].firstms = metadata.tracks[trid].keys[0].getTime();
//delete fragments of which the beginning can no longer be reached
while (metadata.tracks[trid].fragments.size() && metadata.tracks[trid].fragments[0].getNumber() < metadata.tracks[trid].keys[0].getNumber()){
metadata.tracks[trid].fragments.pop_front();
//increase the missed fragments counter
metadata.tracks[trid].missedFrags++;
}
}else{
metadata.tracks[trid].fragments.clear();
}
}
deletionCallback(buffers.begin()->first);
buffers.erase(buffers.begin());
}
/// Returns a direct pointer to the data attribute of the last received packet, if available.
/// Returns NULL if no valid pointer or packet is available.
std::string & DTSC::Stream::lastData(){
return buffers.rbegin()->second["data"].strVal;
}
/// Returns the packet in this buffer number.
/// \arg num Buffer number.
JSON::Value & DTSC::Stream::getPacket(livePos num){
static JSON::Value empty;
if (buffers.find(num) == buffers.end()){
return empty;
}
return buffers[num];
}
JSON::Value & DTSC::Stream::getPacket(){
return buffers.begin()->second;
}
/// Returns the type of the last received packet.
DTSC::datatype DTSC::Stream::lastType(){
return datapointertype;
}
/// Returns true if the current stream contains at least one video track.
bool DTSC::Stream::hasVideo(){
for (std::map<int,Track>::iterator it = metadata.tracks.begin(); it != metadata.tracks.end(); it++){
if (it->second.type == "video"){
return true;
}
}
return false;
}
/// Returns true if the current stream contains at least one audio track.
bool DTSC::Stream::hasAudio(){
for (std::map<int,Track>::iterator it = metadata.tracks.begin(); it != metadata.tracks.end(); it++){
if (it->second.type == "audio"){
return true;
}
}
return false;
}
void DTSC::Stream::setBufferTime(unsigned int ms){
buffertime = ms;
}
std::string & DTSC::Stream::outPacket(){
static std::string emptystring;
if (!buffers.size() || !buffers.rbegin()->second.isObject()){
return emptystring;
}
return buffers.rbegin()->second.toNetPacked();
}
/// Returns a packed DTSC packet, ready to sent over the network.
std::string & DTSC::Stream::outPacket(livePos num){
static std::string emptystring;
if (buffers.find(num) == buffers.end() || !buffers[num].isObject()) return emptystring;
return buffers[num].toNetPacked();
}
/// Returns a packed DTSC header, ready to sent over the network.
std::string & DTSC::Stream::outHeader(){
return metadata.toJSON().toNetPacked();
}
/// Constructs a new Ring, at the given buffer position.
/// \arg v Position for buffer.
DTSC::Ring::Ring(livePos v){
b = v;
waiting = false;
starved = false;
updated = false;
playCount = 0;
}
/// Requests a new Ring, which will be created and added to the internal Ring list.
/// This Ring will be kept updated so it always points to valid data or has the starved boolean set.
/// Don't forget to call dropRing() for all requested Ring classes that are no longer neccessary!
DTSC::Ring * DTSC::Stream::getRing(){
livePos tmp = buffers.begin()->first;
std::map<int,std::set<livePos> >::iterator it;
for (it = keyframes.begin(); it != keyframes.end(); it++){
if ((*it->second.begin()).seekTime > tmp.seekTime){
tmp = *it->second.begin();
}
}
return new DTSC::Ring(tmp);
}
/// Deletes a given out Ring class from memory and internal Ring list.
/// Checks for NULL pointers and invalid pointers, silently discarding them.
void DTSC::Stream::dropRing(DTSC::Ring * ptr){
}
/// Returns 0 if seeking is possible, -1 if the wanted frame is too old, 1 if the wanted frame is too new.
/// This function looks in the header - not in the buffered data itself.
int DTSC::Stream::canSeekms(unsigned int ms){
bool too_late = false;
//no tracks? Frame too new by definition.
if ( !metadata.tracks.size()){
return 1;
}
//loop trough all the tracks
for (std::map<int,Track>::iterator it = metadata.tracks.begin(); it != metadata.tracks.end(); it++){
if (it->second.keys.size()){
if (it->second.keys[0].getTime() <= ms && it->second.keys[it->second.keys.size() - 1].getTime() >= ms){
return 0;
}
if (it->second.keys[0].getTime() > ms){too_late = true;}
}
}
//did we spot a track already past this point? return too late.
if (too_late){return -1;}
//otherwise, assume not available yet
return 1;
}
DTSC::livePos DTSC::Stream::msSeek(unsigned int ms, std::set<int> & allowedTracks){
std::set<int> seekTracks = allowedTracks;
livePos result = buffers.begin()->first;
for (std::set<int>::iterator it = allowedTracks.begin(); it != allowedTracks.end(); it++){
if (metadata.tracks[*it].type == "video"){
int trackNo = *it;
seekTracks.clear();
seekTracks.insert(trackNo);
break;
}
}
for (std::map<livePos,JSON::Value>::iterator bIt = buffers.begin(); bIt != buffers.end(); bIt++){
if (seekTracks.find(bIt->first.trackID) != seekTracks.end()){
// if (bIt->second.isMember("keyframe")){
result = bIt->first;
if (bIt->first.seekTime >= ms){
return result;
}
//}
}
}
return result;
}
/// Returns whether the current position is the last currently available position within allowedTracks.
/// Simply returns the result of getNext(pos, allowedTracks) == pos
bool DTSC::Stream::isNewest(DTSC::livePos & pos, std::set<int> & allowedTracks){
return getNext(pos, allowedTracks) == pos;
}
/// Returns the next available position within allowedTracks, or the current position if no next is availble.
DTSC::livePos DTSC::Stream::getNext(DTSC::livePos & pos, std::set<int> & allowedTracks){
std::map<livePos,JSON::Value>::iterator iter = buffers.upper_bound(pos);
while (iter != buffers.end()){
if (allowedTracks.count(iter->first.trackID)){return iter->first;}
iter++;
}
return pos;
}
/// Properly cleans up the object for erasing.
/// Drops all Ring classes that have been given out.
DTSC::Stream::~Stream(){
}
DTSC::File::File(){
F = 0;
endPos = 0;
}
DTSC::File::File(const File & rhs){
*this = rhs;
}
DTSC::File & DTSC::File::operator =(const File & rhs){
created = rhs.created;
if (rhs.F){
F = fdopen( dup(fileno(rhs.F)), (created ? "w+b": "r+b"));
}else{
F = 0;
}
endPos = rhs.endPos;
strbuffer = rhs.strbuffer;
metaStorage = rhs.metaStorage;
metadata = metaStorage;
currtime = rhs.currtime;
lastreadpos = rhs.lastreadpos;
headerSize = rhs.headerSize;
trackMapping = rhs.trackMapping;
memcpy(buffer, rhs.buffer, 4);
}
DTSC::File::operator bool() const{
return F;
}
/// Open a filename for DTSC reading/writing.
/// If create is true and file does not exist, attempt to create.
DTSC::File::File(std::string filename, bool create){
if (create){
F = fopen(filename.c_str(), "w+b");
if(!F){
std::cerr << "Could not create file" << filename << ": " << strerror(errno) << std::endl;
return;
}
//write an empty header
fseek(F, 0, SEEK_SET);
fwrite(DTSC::Magic_Header, 4, 1, F);
memset(buffer, 0, 4);
fwrite(buffer, 4, 1, F); //write 4 zero-bytes
headerSize = 0;
}else{
F = fopen(filename.c_str(), "r+b");
}
created = create;
if ( !F){
fprintf(stderr, "Could not open file %s\n", filename.c_str());
return;
}
fseek(F, 0, SEEK_END);
endPos = ftell(F);
//we now know the first 4 bytes are DTSC::Magic_Header and we have a valid file
fseek(F, 4, SEEK_SET);
if (fread(buffer, 4, 1, F) != 1){
fseek(F, 4, SEEK_SET);
memset(buffer, 0, 4);
fwrite(buffer, 4, 1, F); //write 4 zero-bytes
}else{
uint32_t * ubuffer = (uint32_t *)buffer;
headerSize = ntohl(ubuffer[0]);
}
readHeader(0);
fseek(F, 8 + headerSize, SEEK_SET);
currframe = 0;
}
/// Returns the header metadata for this file as JSON::Value.
DTSC::readOnlyMeta & DTSC::File::getMeta(){
return metadata;
}
/// (Re)writes the given string to the header area if the size is the same as the existing header.
/// Forces a write if force is set to true.
bool DTSC::File::writeHeader(std::string & header, bool force){
if (headerSize != header.size() && !force){
fprintf(stderr, "Could not overwrite header - not equal size\n");
return false;
}
headerSize = header.size();
int pSize = htonl(header.size());
fseek(F, 4, SEEK_SET);
int tmpret = fwrite((void*)( &pSize), 4, 1, F);
if (tmpret != 1){
return false;
}
fseek(F, 8, SEEK_SET);
int ret = fwrite(header.c_str(), headerSize, 1, F);
fseek(F, 8 + headerSize, SEEK_SET);
return (ret == 1);
}
/// Adds the given string as a new header to the end of the file.
/// \returns The positon the header was written at, or 0 on failure.
long long int DTSC::File::addHeader(std::string & header){
fseek(F, 0, SEEK_END);
long long int writePos = ftell(F);
int hSize = htonl(header.size());
int ret = fwrite(DTSC::Magic_Header, 4, 1, F); //write header
if (ret != 1){
return 0;
}
ret = fwrite((void*)( &hSize), 4, 1, F); //write size
if (ret != 1){
return 0;
}
ret = fwrite(header.c_str(), header.size(), 1, F); //write contents
if (ret != 1){
return 0;
}
fseek(F, 0, SEEK_END);
endPos = ftell(F);
return writePos; //return position written at
}
/// Reads the header at the given file position.
/// If the packet could not be read for any reason, the reason is printed to stderr.
/// Reading the header means the file position is moved to after the header.
void DTSC::File::readHeader(int pos){
fseek(F, pos, SEEK_SET);
if (fread(buffer, 4, 1, F) != 1){
if (feof(F)){
#if DEBUG >= 4
fprintf(stderr, "End of file reached (H%i)\n", pos);
#endif
}else{
fprintf(stderr, "Could not read header (H%i)\n", pos);
}
strbuffer = "";
metadata = readOnlyMeta();
return;
}
if (memcmp(buffer, DTSC::Magic_Header, 4) != 0){
fprintf(stderr, "Invalid header - %.4s != %.4s (H%i)\n", buffer, DTSC::Magic_Header, pos);
strbuffer = "";
metadata = readOnlyMeta();
return;
}
if (fread(buffer, 4, 1, F) != 1){
fprintf(stderr, "Could not read size (H%i)\n", pos);
strbuffer = "";
metadata = readOnlyMeta();
return;
}
uint32_t * ubuffer = (uint32_t *)buffer;
long packSize = ntohl(ubuffer[0]);
strbuffer.resize(packSize);
if (packSize){
if (fread((void*)strbuffer.c_str(), packSize, 1, F) != 1){
fprintf(stderr, "Could not read packet (H%i)\n", pos);
strbuffer = "";
metadata = readOnlyMeta();
return;
}
metaStorage = JSON::fromDTMI(strbuffer);
metadata = readOnlyMeta(metaStorage);//make readonly
}
//if there is another header, read it and replace metadata with that one.
if (metadata.moreheader){
if (metadata.moreheader < getBytePosEOF()){
readHeader(metadata.moreheader);
return;
}
}
metadata.vod = true;
metadata.live = false;
}
long int DTSC::File::getBytePosEOF(){
return endPos;
}
long int DTSC::File::getBytePos(){
return ftell(F);
}
bool DTSC::File::reachedEOF(){
return feof(F);
}
/// Reads the packet available at the current file position.
/// If the packet could not be read for any reason, the reason is printed to stderr.
/// Reading the packet means the file position is increased to the next packet.
void DTSC::File::seekNext(){
if ( !currentPositions.size()){
strbuffer = "";
jsonbuffer.null();
return;
}
fseek(F,currentPositions.begin()->bytePos, SEEK_SET);
if ( reachedEOF()){
strbuffer = "";
jsonbuffer.null();
return;
}
clearerr(F);
if ( !metadata.merged){
seek_time(currentPositions.begin()->seekTime + 1, currentPositions.begin()->trackID);
}
fseek(F,currentPositions.begin()->bytePos, SEEK_SET);
currentPositions.erase(currentPositions.begin());
lastreadpos = ftell(F);
if (fread(buffer, 4, 1, F) != 1){
if (feof(F)){
#if DEBUG >= 4
fprintf(stderr, "End of file reached.\n");
#endif
}else{
fprintf(stderr, "Could not read header\n");
}
strbuffer = "";
jsonbuffer.null();
return;
}
if (memcmp(buffer, DTSC::Magic_Header, 4) == 0){
readHeader(lastreadpos);
jsonbuffer = metadata.toJSON();
return;
}
long long unsigned int version = 0;
if (memcmp(buffer, DTSC::Magic_Packet, 4) == 0){
version = 1;
}
if (memcmp(buffer, DTSC::Magic_Packet2, 4) == 0){
version = 2;
}
if (version == 0){
fprintf(stderr, "Invalid packet header @ %#x - %.4s != %.4s\n", lastreadpos, buffer, DTSC::Magic_Packet2);
strbuffer = "";
jsonbuffer.null();
return;
}
if (fread(buffer, 4, 1, F) != 1){
fprintf(stderr, "Could not read size\n");
strbuffer = "";
jsonbuffer.null();
return;
}
uint32_t * ubuffer = (uint32_t *)buffer;
long packSize = ntohl(ubuffer[0]);
strbuffer.resize(packSize);
if (fread((void*)strbuffer.c_str(), packSize, 1, F) != 1){
fprintf(stderr, "Could not read packet\n");
strbuffer = "";
jsonbuffer.null();
return;
}
if (version == 2){
jsonbuffer = JSON::fromDTMI2(strbuffer);
}else{
jsonbuffer = JSON::fromDTMI(strbuffer);
}
if ( metadata.merged){
int tempLoc = getBytePos();
char newHeader[20];
if (fread((void*)newHeader, 20, 1, F) == 1){
if (memcmp(newHeader, DTSC::Magic_Packet2, 4) == 0){
seekPos tmpPos;
tmpPos.bytePos = tempLoc;
tmpPos.trackID = ntohl(((int*)newHeader)[2]);
if (selectedTracks.find(tmpPos.trackID) != selectedTracks.end()){
tmpPos.seekTime = ((long long unsigned int)ntohl(((int*)newHeader)[3])) << 32;
tmpPos.seekTime += ntohl(((int*)newHeader)[4]);
}else{
tmpPos.seekTime = -1;
long tid = jsonbuffer["trackid"].asInt();
for (int i = 0; i != metadata.tracks[tid].keyLen; i++){
if (metadata.tracks[tid].keys[i].getTime() > jsonbuffer["time"].asInt()){
tmpPos.seekTime = metadata.tracks[tid].keys[i].getTime();
tmpPos.bytePos = metadata.tracks[tid].keys[i].getBpos();
tmpPos.trackID = tid;
break;
}
}
}
if (tmpPos.seekTime != -1){
bool insert = true;
for (std::set<seekPos>::iterator curPosIter = currentPositions.begin(); curPosIter != currentPositions.end(); curPosIter++){
if ((*curPosIter).trackID == tmpPos.trackID && (*curPosIter).seekTime >= tmpPos.seekTime){
insert = false;
break;
}
}
if (insert){
currentPositions.insert(tmpPos);
}else{
seek_time(jsonbuffer["time"].asInt() + 1, jsonbuffer["trackid"].asInt(), true);
}
}
}
}
}
}
void DTSC::File::parseNext(){
lastreadpos = ftell(F);
if (fread(buffer, 4, 1, F) != 1){
if (feof(F)){
#if DEBUG >= 4
fprintf(stderr, "End of file reached.\n");
#endif
}else{
fprintf(stderr, "Could not read header\n");
}
strbuffer = "";
jsonbuffer.null();
return;
}
if (memcmp(buffer, DTSC::Magic_Header, 4) == 0){
if (lastreadpos != 0){
readHeader(lastreadpos);
jsonbuffer = metadata.toJSON();
}else{
if (fread(buffer, 4, 1, F) != 1){
fprintf(stderr, "Could not read size\n");
strbuffer = "";
jsonbuffer.null();
return;
}
uint32_t * ubuffer = (uint32_t *)buffer;
long packSize = ntohl(ubuffer[0]);
strbuffer.resize(packSize);
if (fread((void*)strbuffer.c_str(), packSize, 1, F) != 1){
fprintf(stderr, "Could not read packet\n");
strbuffer = "";
jsonbuffer.null();
return;
}
jsonbuffer = JSON::fromDTMI(strbuffer);
}
return;
}
long long unsigned int version = 0;
if (memcmp(buffer, DTSC::Magic_Packet, 4) == 0){
version = 1;
}
if (memcmp(buffer, DTSC::Magic_Packet2, 4) == 0){
version = 2;
}
if (version == 0){
fprintf(stderr, "Invalid packet header @ %#x - %.4s != %.4s\n", lastreadpos, buffer, DTSC::Magic_Packet2);
strbuffer = "";
jsonbuffer.null();
return;
}
if (fread(buffer, 4, 1, F) != 1){
fprintf(stderr, "Could not read size\n");
strbuffer = "";
jsonbuffer.null();
return;
}
uint32_t * ubuffer = (uint32_t *)buffer;
long packSize = ntohl(ubuffer[0]);
strbuffer.resize(packSize);
if (fread((void*)strbuffer.c_str(), packSize, 1, F) != 1){
fprintf(stderr, "Could not read packet\n");
strbuffer = "";
jsonbuffer.null();
return;
}
if (version == 2){
jsonbuffer = JSON::fromDTMI2(strbuffer);
}else{
jsonbuffer = JSON::fromDTMI(strbuffer);
}
}
/// Returns the byte positon of the start of the last packet that was read.
long long int DTSC::File::getLastReadPos(){
return lastreadpos;
}
/// Returns the internal buffer of the last read packet in raw binary format.
std::string & DTSC::File::getPacket(){
return strbuffer;
}
/// Returns the internal buffer of the last read packet in JSON format.
JSON::Value & DTSC::File::getJSON(){
return jsonbuffer;
}
bool DTSC::File::seek_time(int ms, int trackNo, bool forceSeek){
seekPos tmpPos;
tmpPos.trackID = trackNo;
if (!forceSeek && jsonbuffer && ms > jsonbuffer["time"].asInt() && trackNo >= jsonbuffer["trackid"].asInt()){
tmpPos.seekTime = jsonbuffer["time"].asInt();
tmpPos.bytePos = getBytePos();
}else{
tmpPos.seekTime = 0;
tmpPos.bytePos = 0;
}
for (int i = 0; i < metadata.tracks[trackNo].keyLen; i++){
if (metadata.tracks[trackNo].keys[i].getTime() > ms){
break;
}
if (metadata.tracks[trackNo].keys[i].getTime() > tmpPos.seekTime){
tmpPos.seekTime = metadata.tracks[trackNo].keys[i].getTime();
tmpPos.bytePos = metadata.tracks[trackNo].keys[i].getBpos();
}
}
bool foundPacket = false;
while ( !foundPacket){
lastreadpos = ftell(F);
if (reachedEOF()){
return false;
}
//Seek to first packet after ms.
seek_bpos(tmpPos.bytePos);
//read the header
char header[20];
fread((void*)header, 20, 1, F);
//check if packetID matches, if not, skip size + 8 bytes.
int packSize = ntohl(((int*)header)[1]);
int packID = ntohl(((int*)header)[2]);
if (memcmp(header,Magic_Packet2,4) != 0 || packID != trackNo){
tmpPos.bytePos += 8 + packSize;
continue;
}
//get timestamp of packet, if too large, break, if not, skip size bytes.
long long unsigned int myTime = ((long long unsigned int)ntohl(((int*)header)[3]) << 32);
myTime += ntohl(((int*)header)[4]);
tmpPos.seekTime = myTime;
if (myTime >= ms){
foundPacket = true;
}else{
tmpPos.bytePos += 8 + packSize;
continue;
}
}
currentPositions.insert(tmpPos);
}
/// Attempts to seek to the given time in ms within the file.
/// Returns true if successful, false otherwise.
bool DTSC::File::seek_time(int ms){
currentPositions.clear();
seekPos tmpPos;
for (std::set<int>::iterator it = selectedTracks.begin(); it != selectedTracks.end(); it++){
seek_bpos(0);
seek_time(ms,(*it));
}
return true;
}
bool DTSC::File::seek_bpos(int bpos){
if (fseek(F, bpos, SEEK_SET) == 0){
return true;
}
return false;
}
void DTSC::File::rewritePacket(std::string & newPacket, int bytePos){
fseek(F, bytePos, SEEK_SET);
fwrite(newPacket.c_str(), newPacket.size(), 1, F);
fseek(F, 0, SEEK_END);
if (ftell(F) > endPos){
endPos = ftell(F);
}
}
void DTSC::File::writePacket(std::string & newPacket){
fseek(F, 0, SEEK_END);
fwrite(newPacket.c_str(), newPacket.size(), 1, F); //write contents
fseek(F, 0, SEEK_END);
endPos = ftell(F);
}
void DTSC::File::writePacket(JSON::Value & newPacket){
writePacket(newPacket.toNetPacked());
}
bool DTSC::File::atKeyframe(){
if (getJSON().isMember("keyframe")){
return true;
}
long long int bTime = jsonbuffer["time"].asInt();
int trackid = jsonbuffer["trackid"].asInt();
for (int i = 0; i < metadata.tracks[trackid].keyLen; i++){
if (metadata.tracks[trackid].keys[i].getTime() >= bTime){
return (metadata.tracks[trackid].keys[i].getTime() == bTime);
}
}
return false;
}
void DTSC::File::selectTracks(std::set<int> & tracks){
selectedTracks = tracks;
if ( !currentPositions.size()){
seek_time(0);
}else{
currentPositions.clear();
}
}
/// Close the file if open
DTSC::File::~File(){
if (F){
fclose(F);
F = 0;
}
}
bool DTSC::isFixed(JSON::Value & metadata){
if (metadata.isMember("is_fixed")){return true;}
if ( !metadata.isMember("tracks")){return false;}
for (JSON::ObjIter it = metadata["tracks"].ObjBegin(); it != metadata["tracks"].ObjEnd(); it++){
if (it->second["type"].asString() == "meta"){
continue;
}
if (!it->second["keys"].isString()){
return false;
}
//Check for bpos: last element bpos != 0
std::string keyRef = it->second["keys"].asStringRef();
if (keyRef.size() < 16){
return false;
}
int offset = keyRef.size() - 17;
if (!(keyRef[offset] | keyRef[offset+1] | keyRef[offset+2] | keyRef[offset+3] | keyRef[offset+4])){
return false;
}
}
return true;
}