src/filesys.cpp


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/*
Minetest
Copyright (C) 2013 celeron55, Perttu Ahola <celeron55@gmail.com>

This program is free software; you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published by
the Free Software Foundation; either version 2.1 of the License, or
(at your option) any later version.

This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU Lesser General Public License for more details.

You should have received a copy of the GNU Lesser General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/

#include "filesys.h"
#include "util/string.h"
#include <iostream>
#include <stdio.h>
#include <string.h>
#include <errno.h>
#include <fstream>
#include "log.h"

namespace fs
{

#ifdef _WIN32 // WINDOWS

#define _WIN32_WINNT 0x0501
#include <windows.h>
#include <malloc.h>
#include <tchar.h> 
#include <wchar.h> 

#define BUFSIZE MAX_PATH

std::vector<DirListNode> GetDirListing(std::string pathstring)
{
	std::vector<DirListNode> listing;

	WIN32_FIND_DATA FindFileData;
	HANDLE hFind = INVALID_HANDLE_VALUE;
	DWORD dwError;
	LPTSTR DirSpec;
	INT retval;

	DirSpec = (LPTSTR) malloc (BUFSIZE);

	if( DirSpec == NULL )
	{
	  errorstream<<"GetDirListing: Insufficient memory available"<<std::endl;
	  retval = 1;
	  goto Cleanup;
	}

	// Check that the input is not larger than allowed.
	if (pathstring.size() > (BUFSIZE - 2))
	{
	  errorstream<<"GetDirListing: Input directory is too large."<<std::endl;
	  retval = 3;
	  goto Cleanup;
	}

	//_tprintf (TEXT("Target directory is %s.\n"), pathstring.c_str());

	sprintf(DirSpec, "%s", (pathstring + "\\*").c_str());

	// Find the first file in the directory.
	hFind = FindFirstFile(DirSpec, &FindFileData);

	if (hFind == INVALID_HANDLE_VALUE) 
	{
		retval = (-1);
		goto Cleanup;
	} 
	else 
	{
		// NOTE:
		// Be very sure to not include '..' in the results, it will
		// result in an epic failure when deleting stuff.

		DirListNode node;
		node.name = FindFileData.cFileName;
		node.dir = FindFileData.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY;
		if(node.name != "." && node.name != "..")
			listing.push_back(node);

		// List all the other files in the directory.
		while (FindNextFile(hFind, &FindFileData) != 0) 
		{
			DirListNode node;
			node.name = FindFileData.cFileName;
			node.dir = FindFileData.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY;
			if(node.name != "." && node.name != "..")
				listing.push_back(node);
		}

		dwError = GetLastError();
		FindClose(hFind);
		if (dwError != ERROR_NO_MORE_FILES) 
		{
			errorstream<<"GetDirListing: FindNextFile error. Error is "
					<<dwError<<std::endl;
			retval = (-1);
			goto Cleanup;
		}
	}
	retval  = 0;

Cleanup:
	free(DirSpec);

	if(retval != 0) listing.clear();

	//for(unsigned int i=0; i<listing.size(); i++){
	//	infostream<<listing[i].name<<(listing[i].dir?" (dir)":" (file)")<<std::endl;
	//}
	
	return listing;
}

bool CreateDir(std::string path)
{
	bool r = CreateDirectory(path.c_str(), NULL);
	if(r == true)
		return true;
	if(GetLastError() == ERROR_ALREADY_EXISTS)
		return true;
	return false;
}

bool PathExists(std::string path)
{
	return (GetFileAttributes(path.c_str()) != INVALID_FILE_ATTRIBUTES);
}

bool IsDir(std::string path)
{
	DWORD attr = GetFileAttributes(path.c_str());
	return (attr != INVALID_FILE_ATTRIBUTES &&
			(attr & FILE_ATTRIBUTE_DIRECTORY));
}

bool IsDirDelimiter(char c)
{
	return c == '/' || c == '\\';
}

bool RecursiveDelete(std::string path)
{
	infostream<<"Recursively deleting \""<<path<<"\""<<std::endl;

	DWORD attr = GetFileAttributes(path.c_str());
	bool is_directory = (attr != INVALID_FILE_ATTRIBUTES &&
			(attr & FILE_ATTRIBUTE_DIRECTORY));
	if(!is_directory)
	{
		infostream<<"RecursiveDelete: Deleting file "<<path<<std::endl;
		//bool did = DeleteFile(path.c_str());
		bool did = true;
		if(!did){
			errorstream<<"RecursiveDelete: Failed to delete file "
					<<path<<std::endl;
			return false;
		}
	}
	else
	{
		infostream<<"RecursiveDelete: Deleting content of directory "
				<<path<<std::endl;
		std::vector<DirListNode> content = GetDirListing(path);
		for(int i=0; i<content.size(); i++){
			const DirListNode &n = content[i];
			std::string fullpath = path + DIR_DELIM + n.name;
			bool did = RecursiveDelete(fullpath);
			if(!did){
				errorstream<<"RecursiveDelete: Failed to recurse to "
						<<fullpath<<std::endl;
				return false;
			}
		}
		infostream<<"RecursiveDelete: Deleting directory "<<path<<std::endl;
		//bool did = RemoveDirectory(path.c_str();
		bool did = true;
		if(!did){
			errorstream<<"Failed to recursively delete directory "
					<<path<<std::endl;
			return false;
		}
	}
	return true;
}

bool DeleteSingleFileOrEmptyDirectory(std::string path)
{
	DWORD attr = GetFileAttributes(path.c_str());
	bool is_directory = (attr != INVALID_FILE_ATTRIBUTES &&
			(attr & FILE_ATTRIBUTE_DIRECTORY));
	if(!is_directory)
	{
		bool did = DeleteFile(path.c_str());
		return did;
	}
	else
	{
		bool did = RemoveDirectory(path.c_str());
		return did;
	}
}

std::string TempPath()
{
	DWORD bufsize = GetTempPath(0, "");
	if(bufsize == 0){
		errorstream<<"GetTempPath failed, error = "<<GetLastError()<<std::endl;
		return "";
	}
	std::vector<char> buf(bufsize);
	DWORD len = GetTempPath(bufsize, &buf[0]);
	if(len == 0 || len > bufsize){
		errorstream<<"GetTempPath failed, error = "<<GetLastError()<<std::endl;
		return "";
	}
	return std::string(buf.begin(), buf.begin() + len);
}

#else // POSIX

#include <sys/types.h>
#include <dirent.h>
#include <sys/stat.h>
#include <sys/wait.h>
#include <unistd.h>

std::vector<DirListNode> GetDirListing(std::string pathstring)
{
	std::vector<DirListNode> listing;

    DIR *dp;
    struct dirent *dirp;
    if((dp  = opendir(pathstring.c_str())) == NULL) {
		//infostream<<"Error("<<errno<<") opening "<<pathstring<<std::endl;
        return listing;
    }

    while ((dirp = readdir(dp)) != NULL) {
		// NOTE:
		// Be very sure to not include '..' in the results, it will
		// result in an epic failure when deleting stuff.
		if(dirp->d_name[0]!='.'){
			DirListNode node;
			node.name = dirp->d_name;
			if(node.name == "." || node.name == "..")
				continue;

			int isdir = -1; // -1 means unknown

			/*
				POSIX doesn't define d_type member of struct dirent and
				certain filesystems on glibc/Linux will only return
				DT_UNKNOWN for the d_type member.

				Also we don't know whether symlinks are directories or not.
			*/
#ifdef _DIRENT_HAVE_D_TYPE
			if(dirp->d_type != DT_UNKNOWN && dirp->d_type != DT_LNK)
				isdir = (dirp->d_type == DT_DIR);
#endif /* _DIRENT_HAVE_D_TYPE */

			/*
				Was d_type DT_UNKNOWN, DT_LNK or nonexistent?
				If so, try stat().
			*/
			if(isdir == -1)
			{
				struct stat statbuf;
				if (stat((pathstring + "/" + node.name).c_str(), &statbuf))
					continue;
				isdir = ((statbuf.st_mode & S_IFDIR) == S_IFDIR);
			}
			node.dir = isdir;
			listing.push_back(node);
		}
    }
    closedir(dp);

	return listing;
}

bool CreateDir(std::string path)
{
	int r = mkdir(path.c_str(), S_IRWXU | S_IRWXG | S_IROTH | S_IXOTH);
	if(r == 0)
	{
		return true;
	}
	else
	{
		// If already exists, return true
		if(errno == EEXIST)
			return true;
		return false;
	}
}

bool PathExists(std::string path)
{
	struct stat st;
	return (stat(path.c_str(),&st) == 0);
}

bool IsDir(std::string path)
{
	struct stat statbuf;
	if(stat(path.c_str(), &statbuf))
		return false; // Actually error; but certainly not a directory
	return ((statbuf.st_mode & S_IFDIR) == S_IFDIR);
}

bool IsDirDelimiter(char c)
{
	return c == '/';
}

bool RecursiveDelete(std::string path)
{
	/*
		Execute the 'rm' command directly, by fork() and execve()
	*/
	
	infostream<<"Removing \""<<path<<"\""<<std::endl;

	//return false;
	
	pid_t child_pid = fork();

	if(child_pid == 0)
	{
		// Child
		char argv_data[3][10000];
		strcpy(argv_data[0], "/bin/rm");
		strcpy(argv_data[1], "-rf");
		strncpy(argv_data[2], path.c_str(), 10000);
		char *argv[4];
		argv[0] = argv_data[0];
		argv[1] = argv_data[1];
		argv[2] = argv_data[2];
		argv[3] = NULL;

		verbosestream<<"Executing '"<<argv[0]<<"' '"<<argv[1]<<"' '"
				<<argv[2]<<"'"<<std::endl;
		
		execv(argv[0], argv);
		
		// Execv shouldn't return. Failed.
		_exit(1);
	}
	else
	{
		// Parent
		int child_status;
		pid_t tpid;
		do{
			tpid = wait(&child_status);
			//if(tpid != child_pid) process_terminated(tpid);
		}while(tpid != child_pid);
		return (child_status == 0);
	}
}

bool DeleteSingleFileOrEmptyDirectory(std::string path)
{
	if(IsDir(path)){
		bool did = (rmdir(path.c_str()) == 0);
		if(!did)
			errorstream<<"rmdir errno: "<<errno<<": "<<strerror(errno)
					<<std::endl;
		return did;
	} else {
		bool did = (unlink(path.c_str()) == 0);
		if(!did)
			errorstream<<"unlink errno: "<<errno<<": "<<strerror(errno)
					<<std::endl;
		return did;
	}
}

std::string TempPath()
{
	/*
		Should the environment variables TMPDIR, TMP and TEMP
		and the macro P_tmpdir (if defined by stdio.h) be checked
		before falling back on /tmp?

		Probably not, because this function is intended to be
		compatible with lua's os.tmpname which under the default
		configuration hardcodes mkstemp("/tmp/lua_XXXXXX").
	*/
	return std::string(DIR_DELIM) + "tmp";
}

#endif

void GetRecursiveSubPaths(std::string path, std::vector<std::string> &dst)
{
	std::vector<DirListNode> content = GetDirListing(path);
	for(unsigned int  i=0; i<content.size(); i++){
		const DirListNode &n = content[i];
		std::string fullpath = path + DIR_DELIM + n.name;
		dst.push_back(fullpath);
		GetRecursiveSubPaths(fullpath, dst);
	}
}

bool DeletePaths(const std::vector<std::string> &paths)
{
	bool success = true;
	// Go backwards to succesfully delete the output of GetRecursiveSubPaths
	for(int i=paths.size()-1; i>=0; i--){
		const std::string &path = paths[i];
		bool did = DeleteSingleFileOrEmptyDirectory(path);
		if(!did){
			errorstream<<"Failed to delete "<<path<<std::endl;
			success = false;
		}
	}
	return success;
}

bool RecursiveDeleteContent(std::string path)
{
	infostream<<"Removing content of \""<<path<<"\""<<std::endl;
	std::vector<DirListNode> list = GetDirListing(path);
	for(unsigned int i=0; i<list.size(); i++)
	{
		if(trim(list[i].name) == "." || trim(list[i].name) == "..")
			continue;
		std::string childpath = path + DIR_DELIM + list[i].name;
		bool r = RecursiveDelete(childpath);
		if(r == false)
		{
			errorstream<<"Removing \""<<childpath<<"\" failed"<<std::endl;
			return false;
		}
	}
	return true;
}

bool CreateAllDirs(std::string path)
{

	std::vector<std::string> tocreate;
	std::string basepath = path;
	while(!PathExists(basepath))
	{
		tocreate.push_back(basepath);
		basepath = RemoveLastPathComponent(basepath);
		if(basepath.empty())
			break;
	}
	for(int i=tocreate.size()-1;i>=0;i--)
		if(!CreateDir(tocreate[i]))
			return false;
	return true;
}

bool CopyFileContents(std::string source, std::string target)
{
	FILE *sourcefile = fopen(source.c_str(), "rb");
	if(sourcefile == NULL){
		errorstream<<source<<": can't open for reading: "
			<<strerror(errno)<<std::endl;
		return false;
	}

	FILE *targetfile = fopen(target.c_str(), "wb");
	if(targetfile == NULL){
		errorstream<<target<<": can't open for writing: "
			<<strerror(errno)<<std::endl;
		fclose(sourcefile);
		return false;
	}

	size_t total = 0;
	bool retval = true;
	bool done = false;
	char readbuffer[BUFSIZ];
	while(!done){
		size_t readbytes = fread(readbuffer, 1,
				sizeof(readbuffer), sourcefile);
		total += readbytes;
		if(ferror(sourcefile)){
			errorstream<<source<<": IO error: "
				<<strerror(errno)<<std::endl;
			retval = false;
			done = true;
		}
		if(readbytes > 0){
			fwrite(readbuffer, 1, readbytes, targetfile);
		}
		if(feof(sourcefile) || ferror(sourcefile)){
			// flush destination file to catch write errors
			// (e.g. disk full)
			fflush(targetfile);
			done = true;
		}
		if(ferror(targetfile)){
			errorstream<<target<<": IO error: "
					<<strerror(errno)<<std::endl;
			retval = false;
			done = true;
		}
	}
	infostream<<"copied "<<total<<" bytes from "
		<<source<<" to "<<target<<std::endl;
	fclose(sourcefile);
	fclose(targetfile);
	return retval;
}

bool CopyDir(std::string source, std::string target)
{
	if(PathExists(source)){
		if(!PathExists(target)){
			fs::CreateAllDirs(target);
		}
		bool retval = true;
		std::vector<DirListNode> content = fs::GetDirListing(source);

		for(unsigned int i=0; i < content.size(); i++){
			std::string sourcechild = source + DIR_DELIM + content[i].name;
			std::string targetchild = target + DIR_DELIM + content[i].name;
			if(content[i].dir){
				if(!fs::CopyDir(sourcechild, targetchild)){
					retval = false;
				}
			}
			else {
				if(!fs::CopyFileContents(sourcechild, targetchild)){
					retval = false;
				}
			}
		}
		return retval;
	}
	else {
		return false;
	}
}

bool PathStartsWith(std::string path, std::string prefix)
{
	size_t pathsize = path.size();
	size_t pathpos = 0;
	size_t prefixsize = prefix.size();
	size_t prefixpos = 0;
	for(;;){
		bool delim1 = pathpos == pathsize
			|| IsDirDelimiter(path[pathpos]);
		bool delim2 = prefixpos == prefixsize
			|| IsDirDelimiter(prefix[prefixpos]);

		if(delim1 != delim2)
			return false;

		if(delim1){
			while(pathpos < pathsize &&
					IsDirDelimiter(path[pathpos]))
				++pathpos;
			while(prefixpos < prefixsize &&
					IsDirDelimiter(prefix[prefixpos]))
				++prefixpos;
			if(prefixpos == prefixsize)
				return true;
			if(pathpos == pathsize)
				return false;
		}
		else{
			size_t len = 0;
			do{
				char pathchar = path[pathpos+len];
				char prefixchar = prefix[prefixpos+len];
				if(FILESYS_CASE_INSENSITIVE){
					pathchar = tolower(pathchar);
					prefixchar = tolower(prefixchar);
				}
				if(pathchar != prefixchar)
					return false;
				++len;
			} while(pathpos+len < pathsize
					&& !IsDirDelimiter(path[pathpos+len])
					&& prefixpos+len < prefixsize
					&& !IsDirDelimiter(
						prefix[prefixpos+len]));
			pathpos += len;
			prefixpos += len;
		}
	}
}

std::string RemoveLastPathComponent(std::string path,
		std::string *removed, int count)
{
	if(removed)
		*removed = "";

	size_t remaining = path.size();

	for(int i = 0; i < count; ++i){
		// strip a dir delimiter
		while(remaining != 0 && IsDirDelimiter(path[remaining-1]))
			remaining--;
		// strip a path component
		size_t component_end = remaining;
		while(remaining != 0 && !IsDirDelimiter(path[remaining-1]))
			remaining--;
		size_t component_start = remaining;
		// strip a dir delimiter
		while(remaining != 0 && IsDirDelimiter(path[remaining-1]))
			remaining--;
		if(removed){
			std::string component = path.substr(component_start,
					component_end - component_start);
			if(i)
				*removed = component + DIR_DELIM + *removed;
			else
				*removed = component;
		}
	}
	return path.substr(0, remaining);
}

std::string RemoveRelativePathComponents(std::string path)
{
	size_t pos = path.size();
	size_t dotdot_count = 0;
	while(pos != 0){
		size_t component_with_delim_end = pos;
		// skip a dir delimiter
		while(pos != 0 && IsDirDelimiter(path[pos-1]))
			pos--;
		// strip a path component
		size_t component_end = pos;
		while(pos != 0 && !IsDirDelimiter(path[pos-1]))
			pos--;
		size_t component_start = pos;

		std::string component = path.substr(component_start,
				component_end - component_start);
		bool remove_this_component = false;
		if(component == "."){
			remove_this_component = true;
		}
		else if(component == ".."){
			remove_this_component = true;
			dotdot_count += 1;
		}
		else if(dotdot_count != 0){
			remove_this_component = true;
			dotdot_count -= 1;
		}

		if(remove_this_component){
			while(pos != 0 && IsDirDelimiter(path[pos-1]))
				pos--;
			path = path.substr(0, pos) + DIR_DELIM +
				path.substr(component_with_delim_end,
						std::string::npos);
			pos++;
		}
	}

	if(dotdot_count > 0)
		return "";

	// remove trailing dir delimiters
	pos = path.size();
	while(pos != 0 && IsDirDelimiter(path[pos-1]))
		pos--;
	return path.substr(0, pos);
}

bool safeWriteToFile(const std::string &path, const std::string &content)
{
	std::string tmp_file = path + ".~mt";

	// Write to a tmp file
	std::ofstream os(tmp_file.c_str(), std::ios::binary);
	if (!os.good())
		return false;
	os << content;
	os.flush();
	os.close();
	if (os.fail())
		return false;

	// Copy file
#ifdef _WIN32
	remove(path.c_str());
	return (rename(tmp_file.c_str(), path.c_str()) == 0);
#else
	return (rename(tmp_file.c_str(), path.c_str()) == 0);
#endif
}

} // namespace fs
/*
Minetest
Copyright (C) 2013 celeron55, Perttu Ahola <celeron55@gmail.com>

This program is free software; you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published by
the Free Software Foundation; either version 2.1 of the License, or
(at your option) any later version.

This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU Lesser General Public License for more details.

You should have received a copy of the GNU Lesser General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/

#include <iomanip>
#include <errno.h>
#include "connection.h"
#include "serialization.h"
#include "log.h"
#include "porting.h"
#include "network/networkpacket.h"
#include "util/serialize.h"
#include "util/numeric.h"
#include "util/string.h"
#include "settings.h"
#include "profiler.h"

namespace con
{

/******************************************************************************/
/* defines used for debugging and profiling                                   */
/******************************************************************************/
#ifdef NDEBUG
#define LOG(a) a
#define PROFILE(a)
#undef DEBUG_CONNECTION_KBPS
#else
/* this mutex is used to achieve log message consistency */
Mutex log_message_mutex;
#define LOG(a)                                                                 \
	{                                                                          \
	MutexAutoLock loglock(log_message_mutex);                                 \
	a;                                                                         \
	}
#define PROFILE(a) a
//#define DEBUG_CONNECTION_KBPS
#undef DEBUG_CONNECTION_KBPS
#endif


static inline float CALC_DTIME(unsigned int lasttime, unsigned int curtime) {
	float value = ( curtime - lasttime) / 1000.0;
	return MYMAX(MYMIN(value,0.1),0.0);
}

/* maximum window size to use, 0xFFFF is theoretical maximum  don't think about
 * touching it, the less you're away from it the more likely data corruption
 * will occur
 */
#define MAX_RELIABLE_WINDOW_SIZE 0x8000
 /* starting value for window size */
#define MIN_RELIABLE_WINDOW_SIZE 0x40

#define MAX_UDP_PEERS 65535

#define PING_TIMEOUT 5.0

/* maximum number of retries for reliable packets */
#define MAX_RELIABLE_RETRY 5

static u16 readPeerId(u8 *packetdata)
{
	return readU16(&packetdata[4]);
}
static u8 readChannel(u8 *packetdata)
{
	return readU8(&packetdata[6]);
}

BufferedPacket makePacket(Address &address, u8 *data, u32 datasize,
		u32 protocol_id, u16 sender_peer_id, u8 channel)
{
	u32 packet_size = datasize + BASE_HEADER_SIZE;
	BufferedPacket p(packet_size);
	p.address = address;

	writeU32(&p.data[0], protocol_id);
	writeU16(&p.data[4], sender_peer_id);
	writeU8(&p.data[6], channel);

	memcpy(&p.data[BASE_HEADER_SIZE], data, datasize);

	return p;
}

BufferedPacket makePacket(Address &address, SharedBuffer<u8> &data,
		u32 protocol_id, u16 sender_peer_id, u8 channel)
{
	return makePacket(address, *data, data.getSize(),
			protocol_id, sender_peer_id, channel);
}

SharedBuffer<u8> makeOriginalPacket(
		SharedBuffer<u8> data)
{
	u32 header_size = 1;
	u32 packet_size = data.getSize() + header_size;
	SharedBuffer<u8> b(packet_size);

	writeU8(&(b[0]), TYPE_ORIGINAL);
	if (data.getSize() > 0) {
		memcpy(&(b[header_size]), *data, data.getSize());
	}
	return b;
}

std::list<SharedBuffer<u8> > makeSplitPacket(
		SharedBuffer<u8> data,
		u32 chunksize_max,
		u16 seqnum)
{
	// Chunk packets, containing the TYPE_SPLIT header
	std::list<SharedBuffer<u8> > chunks;

	u32 chunk_header_size = 7;
	u32 maximum_data_size = chunksize_max - chunk_header_size;
	u32 start = 0;
	u32 end = 0;
	u32 chunk_num = 0;
	u16 chunk_count = 0;
	do{
		end = start + maximum_data_size - 1;
		if (end > data.getSize() - 1)
			end = data.getSize() - 1;

		u32 payload_size = end - start + 1;
		u32 packet_size = chunk_header_size + payload_size;

		SharedBuffer<u8> chunk(packet_size);

		writeU8(&chunk[0], TYPE_SPLIT);
		writeU16(&chunk[1], seqnum);
		// [3] u16 chunk_count is written at next stage
		writeU16(&chunk[5], chunk_num);
		memcpy(&chunk[chunk_header_size], &data[start], payload_size);

		chunks.push_back(chunk);
		chunk_count++;

		start = end + 1;
		chunk_num++;
	}
	while(end != data.getSize() - 1);

	for(std::list<SharedBuffer<u8> >::iterator i = chunks.begin();
		i != chunks.end(); ++i)
	{
		// Write chunk_count
		writeU16(&((*i)[3]), chunk_count);
	}

	return chunks;
}

std::list<SharedBuffer<u8> > makeAutoSplitPacket(
		SharedBuffer<u8> data,
		u32 chunksize_max,
		u16 &split_seqnum)
{
	u32 original_header_size = 1;
	std::list<SharedBuffer<u8> > list;
	if (data.getSize() + original_header_size > chunksize_max)
	{
		list = makeSplitPacket(data, chunksize_max, split_seqnum);
		split_seqnum++;
		return list;
	}
	else
	{
		list.push_back(makeOriginalPacket(data));
	}
	return list;
}

SharedBuffer<u8> makeReliablePacket(
		SharedBuffer<u8> data,
		u16 seqnum)
{
	u32 header_size = 3;
	u32 packet_size = data.getSize() + header_size;
	SharedBuffer<u8> b(packet_size);

	writeU8(&b[0], TYPE_RELIABLE);
	writeU16(&b[1], seqnum);

	memcpy(&b[header_size], *data, data.getSize());

	return b;
}

/*
	ReliablePacketBuffer
*/

ReliablePacketBuffer::ReliablePacketBuffer(): m_list_size(0) {}

void ReliablePacketBuffer::print()
{
	MutexAutoLock listlock(m_list_mutex);
	LOG(dout_con<<"Dump of ReliablePacketBuffer:" << std::endl);
	unsigned int index = 0;
	for(std::list<BufferedPacket>::iterator i = m_list.begin();
		i != m_list.end();
		++i)
	{
		u16 s = readU16(&(i->data[BASE_HEADER_SIZE+1]));
		LOG(dout_con<<index<< ":" << s << std::endl);
		index++;
	}
}
bool ReliablePacketBuffer::empty()
{
	MutexAutoLock listlock(m_list_mutex);
	return m_list.empty();
}

u32 ReliablePacketBuffer::size()
{
	return m_list_size;
}

bool ReliablePacketBuffer::containsPacket(u16 seqnum)
{
	return !(findPacket(seqnum) == m_list.end());
}

RPBSearchResult ReliablePacketBuffer::findPacket(u16 seqnum)
{
	std::list<BufferedPacket>::iterator i = m_list.begin();
	for(; i != m_list.end(); ++i)
	{
		u16 s = readU16(&(i->data[BASE_HEADER_SIZE+1]));
		/*dout_con<<"findPacket(): finding seqnum="<<seqnum
				<<", comparing to s="<<s<<std::endl;*/
		if (s == seqnum)
			break;
	}
	return i;
}
RPBSearchResult ReliablePacketBuffer::notFound()
{
	return m_list.end();
}
bool ReliablePacketBuffer::getFirstSeqnum(u16& result)
{
	MutexAutoLock listlock(m_list_mutex);
	if (m_list.empty())
		return false;
	BufferedPacket p = *m_list.begin();
	result = readU16(&p.data[BASE_HEADER_SIZE+1]);
	return true;
}

BufferedPacket ReliablePacketBuffer::popFirst()
{
	MutexAutoLock listlock(m_list_mutex);
	if (m_list.empty())
		throw NotFoundException("Buffer is empty");
	BufferedPacket p = *m_list.begin();
	m_list.erase(m_list.begin());
	--m_list_size;

	if (m_list_size == 0) {
		m_oldest_non_answered_ack = 0;
	} else {
		m_oldest_non_answered_ack =
				readU16(&(*m_list.begin()).data[BASE_HEADER_SIZE+1]);
	}
	return p;
}
BufferedPacket ReliablePacketBuffer::popSeqnum(u16 seqnum)
{
	MutexAutoLock listlock(m_list_mutex);
	RPBSearchResult r = findPacket(seqnum);
	if (r == notFound()) {
		LOG(dout_con<<"Sequence number: " << seqnum
				<< " not found in reliable buffer"<<std::endl);
		throw NotFoundException("seqnum not found in buffer");
	}
	BufferedPacket p = *r;


	RPBSearchResult next = r;
	++next;
	if (next != notFound()) {
		u16 s = readU16(&(next->data[BASE_HEADER_SIZE+1]));
		m_oldest_non_answered_ack = s;
	}

	m_list.erase(r);
	--m_list_size;

	if (m_list_size == 0)
	{ m_oldest_non_answered_ack = 0; }
	else
	{ m_oldest_non_answered_ack = readU16(&(*m_list.begin()).data[BASE_HEADER_SIZE+1]);	}
	return p;
}
void ReliablePacketBuffer::insert(BufferedPacket &p,u16 next_expected)
{
	MutexAutoLock listlock(m_list_mutex);
	if (p.data.getSize() < BASE_HEADER_SIZE + 3) {
		errorstream << "ReliablePacketBuffer::insert(): Invalid data size for "
			"reliable packet" << std::endl;
		return;
	}
	u8 type = readU8(&p.data[BASE_HEADER_SIZE + 0]);
	if (type != TYPE_RELIABLE) {
		errorstream << "ReliablePacketBuffer::insert(): type is not reliable"
			<< std::endl;
		return;
	}
	u16 seqnum = readU16(&p.data[BASE_HEADER_SIZE + 1]);

	if (!seqnum_in_window(seqnum, next_expected, MAX_RELIABLE_WINDOW_SIZE)) {
		errorstream << "ReliablePacketBuffer::insert(): seqnum is outside of "
			"expected window " << std::endl;
		return;
	}
	if (seqnum == next_expected) {
		errorstream << "ReliablePacketBuffer::insert(): seqnum is next expected"
			<< std::endl;
		return;
	}

	++m_list_size;
	sanity_check(m_list_size <= SEQNUM_MAX+1);	// FIXME: Handle the error?

	// Find the right place for the packet and insert it there
	// If list is empty, just add it
	if (m_list.empty())
	{
		m_list.push_back(p);
		m_oldest_non_answered_ack = seqnum;
		// Done.
		return;
	}

	// Otherwise find the right place
	std::list<BufferedPacket>::iterator i = m_list.begin();
	// Find the first packet in the list which has a higher seqnum
	u16 s = readU16(&(i->data[BASE_HEADER_SIZE+1]));

	/* case seqnum is smaller then next_expected seqnum */
	/* this is true e.g. on wrap around */
	if (seqnum < next_expected) {
		while(((s < seqnum) || (s >= next_expected)) && (i != m_list.end())) {
			++i;
			if (i != m_list.end())
				s = readU16(&(i->data[BASE_HEADER_SIZE+1]));
		}
	}
	/* non wrap around case (at least for incoming and next_expected */
	else
	{
		while(((s < seqnum) && (s >= next_expected)) && (i != m_list.end())) {
			++i;
			if (i != m_list.end())
				s = readU16(&(i->data[BASE_HEADER_SIZE+1]));
		}
	}

	if (s == seqnum) {
		if (
			(readU16(&(i->data[BASE_HEADER_SIZE+1])) != seqnum) ||
			(i->data.getSize() != p.data.getSize()) ||
			(i->address != p.address)
			)
		{
			/* if this happens your maximum transfer window may be to big */
			fprintf(stderr,
					"Duplicated seqnum %d non matching packet detected:\n",
					seqnum);
			fprintf(stderr, "Old: seqnum: %05d size: %04d, address: %s\n",
					readU16(&(i->data[BASE_HEADER_SIZE+1])),i->data.getSize(),
					i->address.serializeString().c_str());
			fprintf(stderr, "New: seqnum: %05d size: %04u, address: %s\n",
					readU16(&(p.data[BASE_HEADER_SIZE+1])),p.data.getSize(),
					p.address.serializeString().c_str());
			throw IncomingDataCorruption("duplicated packet isn't same as original one");
		}

		/* nothing to do this seems to be a resent packet */
		/* for paranoia reason data should be compared */
		--m_list_size;
	}
	/* insert or push back */
	else if (i != m_list.end()) {
		m_list.insert(i, p);
	}
	else {
		m_list.push_back(p);
	}

	/* update last packet number */
	m_oldest_non_answered_ack = readU16(&(*m_list.begin()).data[BASE_HEADER_SIZE+1]);
}

void ReliablePacketBuffer::incrementTimeouts(float dtime)
{
	MutexAutoLock listlock(m_list_mutex);
	for(std::list<BufferedPacket>::iterator i = m_list.begin();
		i != m_list.end(); ++i)
	{
		i->time += dtime;
		i->totaltime += dtime;
	}
}

std::list<BufferedPacket> ReliablePacketBuffer::getTimedOuts(float timeout,
													unsigned int max_packets)
{
	MutexAutoLock listlock(m_list_mutex);
	std::list<BufferedPacket> timed_outs;
	for(std::list<BufferedPacket>::iterator i = m_list.begin();
		i != m_list.end(); ++i)
	{
		if (i->time >= timeout) {
			timed_outs.push_back(*i);

			//this packet will be sent right afterwards reset timeout here
			i->time = 0.0;
			if (timed_outs.size() >= max_packets)
				break;
		}
	}
	return timed_outs;
}

/*
	IncomingSplitBuffer
*/

IncomingSplitBuffer::~IncomingSplitBuffer()
{
	MutexAutoLock listlock(m_map_mutex);
	for(std::map<u16, IncomingSplitPacket*>::iterator i = m_buf.begin();
		i != m_buf.end(); ++i)
	{
		delete i->second;
	}
}
/*
	This will throw a GotSplitPacketException when a full
	split packet is constructed.
*/
SharedBuffer<u8> IncomingSplitBuffer::insert(BufferedPacket &p, bool reliable)
{
	MutexAutoLock listlock(m_map_mutex);
	u32 headersize = BASE_HEADER_SIZE + 7;
	if (p.data.getSize() < headersize) {
		errorstream << "Invalid data size for split packet" << std::endl;
		return SharedBuffer<u8>();
	}
	u8 type = readU8(&p.data[BASE_HEADER_SIZE+0]);
	u16 seqnum = readU16(&p.data[BASE_HEADER_SIZE+1]);
	u16 chunk_count = readU16(&p.data[BASE_HEADER_SIZE+3]);
	u16 chunk_num = readU16(&p.data[BASE_HEADER_SIZE+5]);

	if (type != TYPE_SPLIT) {
		errorstream << "IncomingSplitBuffer::insert(): type is not split"
			<< std::endl;
		return SharedBuffer<u8>();
	}

	// Add if doesn't exist
	if (m_buf.find(seqnum) == m_buf.end())
	{
		IncomingSplitPacket *sp = new IncomingSplitPacket();
		sp->chunk_count = chunk_count;
		sp->reliable = reliable;
		m_buf[seqnum] = sp;
	}

	IncomingSplitPacket *sp = m_buf[seqnum];

	// TODO: These errors should be thrown or something? Dunno.
	if (chunk_count != sp->chunk_count)
		LOG(derr_con<<"Connection: WARNING: chunk_count="<<chunk_count
				<<" != sp->chunk_count="<<sp->chunk_count
				<<std::endl);
	if (reliable != sp->reliable)
		LOG(derr_con<<"Connection: WARNING: reliable="<<reliable
				<<" != sp->reliable="<<sp->reliable
				<<std::endl);

	// If chunk already exists, ignore it.
	// Sometimes two identical packets may arrive when there is network
	// lag and the server re-sends stuff.
	if (sp->chunks.find(chunk_num) != sp->chunks.end())
		return SharedBuffer<u8>();

	// Cut chunk data out of packet
	u32 chunkdatasize = p.data.getSize() - headersize;
	SharedBuffer<u8> chunkdata(chunkdatasize);
	memcpy(*chunkdata, &(p.data[headersize]), chunkdatasize);

	// Set chunk data in buffer
	sp->chunks[chunk_num] = chunkdata;

	// If not all chunks are received, return empty buffer
	if (sp->allReceived() == false)
		return SharedBuffer<u8>();

	// Calculate total size
	u32 totalsize = 0;
	for(std::map<u16, SharedBuffer<u8> >::iterator i = sp->chunks.begin();
		i != sp->chunks.end(); ++i)
	{
		totalsize += i->second.getSize();
	}

	SharedBuffer<u8> fulldata(totalsize);

	// Copy chunks to data buffer
	u32 start = 0;
	for(u32 chunk_i=0; chunk_i<sp->chunk_count;
			chunk_i++)
	{
		SharedBuffer<u8> buf = sp->chunks[chunk_i];
		u16 chunkdatasize = buf.getSize();
		memcpy(&fulldata[start], *buf, chunkdatasize);
		start += chunkdatasize;;
	}

	// Remove sp from buffer
	m_buf.erase(seqnum);
	delete sp;

	return fulldata;
}
void IncomingSplitBuffer::removeUnreliableTimedOuts(float dtime, float timeout)
{
	std::list<u16> remove_queue;
	{
		MutexAutoLock listlock(m_map_mutex);
		for(std::map<u16, IncomingSplitPacket*>::iterator i = m_buf.begin();
			i != m_buf.end(); ++i)
		{
			IncomingSplitPacket *p = i->second;
			// Reliable ones are not removed by timeout
			if (p->reliable == true)
				continue;
			p->time += dtime;
			if (p->time >= timeout)
				remove_queue.push_back(i->first);
		}
	}
	for(std::list<u16>::iterator j = remove_queue.begin();
		j != remove_queue.end(); ++j)
	{
		MutexAutoLock listlock(m_map_mutex);
		LOG(dout_con<<"NOTE: Removing timed out unreliable split packet"<<std::endl);
		delete m_buf[*j];
		m_buf.erase(*j);
	}
}

/*
	Channel
*/

Channel::Channel() :
		window_size(MIN_RELIABLE_WINDOW_SIZE),
		next_incoming_seqnum(SEQNUM_INITIAL),
		next_outgoing_seqnum(SEQNUM_INITIAL),
		next_outgoing_split_seqnum(SEQNUM_INITIAL),
		current_packet_loss(0),
		current_packet_too_late(0),
		current_packet_successfull(0),
		packet_loss_counter(0),
		current_bytes_transfered(0),
		current_bytes_received(0),
		current_bytes_lost(0),
		max_kbps(0.0),
		cur_kbps(0.0),
		avg_kbps(0.0),
		max_incoming_kbps(0.0),
		cur_incoming_kbps(0.0),
		avg_incoming_kbps(0.0),
		max_kbps_lost(0.0),
		cur_kbps_lost(0.0),
		avg_kbps_lost(0.0),
		bpm_counter(0.0),
		rate_samples(0)
{
}

Channel::~Channel()
{
}

u16 Channel::readNextIncomingSeqNum()
{
	MutexAutoLock internal(m_internal_mutex);
	return next_incoming_seqnum;
}

u16 Channel::incNextIncomingSeqNum()
{
	MutexAutoLock internal(m_internal_mutex);
	u16 retval = next_incoming_seqnum;
	next_incoming_seqnum++;
	return retval;
}

u16 Channel::readNextSplitSeqNum()
{
	MutexAutoLock internal(m_internal_mutex);
	return next_outgoing_split_seqnum;
}
void Channel::setNextSplitSeqNum(u16 seqnum)
{
	MutexAutoLock internal(m_internal_mutex);
	next_outgoing_split_seqnum = seqnum;
}

u16 Channel::getOutgoingSequenceNumber(bool& successful)
{
	MutexAutoLock internal(m_internal_mutex);
	u16 retval = next_outgoing_seqnum;
	u16 lowest_unacked_seqnumber;

	/* shortcut if there ain't any packet in outgoing list */
	if (outgoing_reliables_sent.empty())
	{
		next_outgoing_seqnum++;
		return retval;
	}

	if (outgoing_reliables_sent.getFirstSeqnum(lowest_unacked_seqnumber))
	{
		if (lowest_unacked_seqnumber < next_outgoing_seqnum) {
			// ugly cast but this one is required in order to tell compiler we
			// know about difference of two unsigned may be negative in general
			// but we already made sure it won't happen in this case
			if (((u16)(next_outgoing_seqnum - lowest_unacked_seqnumber)) > window_size) {
				successful = false;
				return 0;
			}
		}
		else {
			// ugly cast but this one is required in order to tell compiler we
			// know about difference of two unsigned may be negative in general
			// but we already made sure it won't happen in this case
			if ((next_outgoing_seqnum + (u16)(SEQNUM_MAX - lowest_unacked_seqnumber)) >
				window_size) {
				successful = false;
				return 0;
			}
		}
	}

	next_outgoing_seqnum++;
	return retval;
}

u16 Channel::readOutgoingSequenceNumber()
{
	MutexAutoLock internal(m_internal_mutex);
	return next_outgoing_seqnum;
}

bool Channel::putBackSequenceNumber(u16 seqnum)
{
	if (((seqnum + 1) % (SEQNUM_MAX+1)) == next_outgoing_seqnum) {

		next_outgoing_seqnum = seqnum;
		return true;
	}
	return false;
}

void Channel::UpdateBytesSent(unsigned int bytes, unsigned int packets)
{
	MutexAutoLock internal(m_internal_mutex);
	current_bytes_transfered += bytes;
	current_packet_successfull += packets;
}

void Channel::UpdateBytesReceived(unsigned int bytes) {
	MutexAutoLock internal(m_internal_mutex);
	current_bytes_received += bytes;
}

void Channel::UpdateBytesLost(unsigned int bytes)
{
	MutexAutoLock internal(m_internal_mutex);
	current_bytes_lost += bytes;
}


void Channel::UpdatePacketLossCounter(unsigned int count)
{
	MutexAutoLock internal(m_internal_mutex);
	current_packet_loss += count;
}

void Channel::UpdatePacketTooLateCounter()
{
	MutexAutoLock internal(m_internal_mutex);
	current_packet_too_late++;
}

void Channel::UpdateTimers(float dtime,bool legacy_peer)
{
	bpm_counter += dtime;
	packet_loss_counter += dtime;

	if (packet_loss_counter > 1.0)
	{
		packet_loss_counter -= 1.0;

		unsigned int packet_loss = 11; /* use a neutral value for initialization */
		unsigned int packets_successfull = 0;
		//unsigned int packet_too_late = 0;

		bool reasonable_amount_of_data_transmitted = false;

		{
			MutexAutoLock internal(m_internal_mutex);
			packet_loss = current_packet_loss;
			//packet_too_late = current_packet_too_late;
			packets_successfull = current_packet_successfull;

			if (current_bytes_transfered > (unsigned int) (window_size*512/2))
			{
				reasonable_amount_of_data_transmitted = true;
			}
			current_packet_loss = 0;
			current_packet_too_late = 0;
			current_packet_successfull = 0;
		}

		/* dynamic window size is only available for non legacy peers */
		if (!legacy_peer) {
			float successfull_to_lost_ratio = 0.0;
			bool done = false;

			if (packets_successfull > 0) {
				successfull_to_lost_ratio = packet_loss/packets_successfull;
			}
			else if (packet_loss > 0)
			{
				window_size = MYMAX(
						(window_size - 10),
						MIN_RELIABLE_WINDOW_SIZE);
				done = true;
			}

			if (!done)
			{
				if ((successfull_to_lost_ratio < 0.01) &&
					(window_size < MAX_RELIABLE_WINDOW_SIZE))
				{
					/* don't even think about increasing if we didn't even
					 * use major parts of our window */
					if (reasonable_amount_of_data_transmitted)
						window_size = MYMIN(
								(window_size + 100),
								MAX_RELIABLE_WINDOW_SIZE);
				}
				else if ((successfull_to_lost_ratio < 0.05) &&
						(window_size < MAX_RELIABLE_WINDOW_SIZE))
				{
					/* don't even think about increasing if we didn't even
					 * use major parts of our window */
					if (reasonable_amount_of_data_transmitted)
						window_size = MYMIN(
								(window_size + 50),
								MAX_RELIABLE_WINDOW_SIZE);
				}
				else if (successfull_to_lost_ratio > 0.15)
				{
					window_size = MYMAX(
							(window_size - 100),
							MIN_RELIABLE_WINDOW_SIZE);
				}
				else if (successfull_to_lost_ratio > 0.1)
				{
					window_size = MYMAX(
							(window_size - 50),
							MIN_RELIABLE_WINDOW_SIZE);
				}
			}
		}
	}

	if (bpm_counter > 10.0)
	{
		{
			MutexAutoLock internal(m_internal_mutex);
			cur_kbps                 =
					(((float) current_bytes_transfered)/bpm_counter)/1024.0;
			current_bytes_transfered = 0;
			cur_kbps_lost            =
					(((float) current_bytes_lost)/bpm_counter)/1024.0;
			current_bytes_lost       = 0;
			cur_incoming_kbps        =
					(((float) current_bytes_received)/bpm_counter)/1024.0;
			current_bytes_received   = 0;
			bpm_counter              = 0;
		}

		if (cur_kbps > max_kbps)
		{
			max_kbps = cur_kbps;
		}

		if (cur_kbps_lost > max_kbps_lost)
		{
			max_kbps_lost = cur_kbps_lost;
		}

		if (cur_incoming_kbps > max_incoming_kbps) {
			max_incoming_kbps = cur_incoming_kbps;
		}

		rate_samples       = MYMIN(rate_samples+1,10);
		float old_fraction = ((float) (rate_samples-1) )/( (float) rate_samples);
		avg_kbps           = avg_kbps * old_fraction +
				cur_kbps * (1.0 - old_fraction);
		avg_kbps_lost      = avg_kbps_lost * old_fraction +
				cur_kbps_lost * (1.0 - old_fraction);
		avg_incoming_kbps  = avg_incoming_kbps * old_fraction +
				cur_incoming_kbps * (1.0 - old_fraction);
	}
}


/*
	Peer
*/

PeerHelper::PeerHelper() :
	m_peer(0)
{}

PeerHelper::PeerHelper(Peer* peer) :
	m_peer(peer)
{
	if (peer != NULL)
	{
		if (!peer->IncUseCount())
		{
			m_peer = 0;
		}
	}
}

PeerHelper::~PeerHelper()
{
	if (m_peer != 0)
		m_peer->DecUseCount();

	m_peer = 0;
}

PeerHelper& PeerHelper::operator=(Peer* peer)
{
	m_peer = peer;
	if (peer != NULL)
	{
		if (!peer->IncUseCount())
		{
			m_peer = 0;
		}
	}
	return *this;
}

Peer* PeerHelper::operator->() const
{
	return m_peer;
}

Peer* PeerHelper::operator&() const
{
	return m_peer;
}

bool PeerHelper::operator!() {
	return ! m_peer;
}

bool PeerHelper::operator!=(void* ptr)
{
	return ((void*) m_peer != ptr);
}

bool Peer::IncUseCount()
{
	MutexAutoLock lock(m_exclusive_access_mutex);

	if (!m_pending_deletion)
	{
		this->m_usage++;
		return true;
	}

	return false;
}

void Peer::DecUseCount()
{
	{
		MutexAutoLock lock(m_exclusive_access_mutex);
		sanity_check(m_usage > 0);
		m_usage--;

		if (!((m_pending_deletion) && (m_usage == 0)))
			return;
	}
	delete this;
}

void Peer::RTTStatistics(float rtt, std::string profiler_id,
		unsigned int num_samples) {

	if (m_last_rtt > 0) {
		/* set min max values */
		if (rtt < m_rtt.min_rtt)
			m_rtt.min_rtt = rtt;
		if (rtt >= m_rtt.max_rtt)
			m_rtt.max_rtt = rtt;

		/* do average calculation */
		if (m_rtt.avg_rtt < 0.0)
			m_rtt.avg_rtt  = rtt;
		else
			m_rtt.avg_rtt  = m_rtt.avg_rtt * (num_samples/(num_samples-1)) +
								rtt * (1/num_samples);

		/* do jitter calculation */

		//just use some neutral value at beginning
		float jitter = m_rtt.jitter_min;

		if (rtt > m_last_rtt)
			jitter = rtt-m_last_rtt;

		if (rtt <= m_last_rtt)
			jitter = m_last_rtt - rtt;

		if (jitter < m_rtt.jitter_min)
			m_rtt.jitter_min = jitter;
		if (jitter >= m_rtt.jitter_max)
			m_rtt.jitter_max = jitter;

		if (m_rtt.jitter_avg < 0.0)
			m_rtt.jitter_avg  = jitter;
		else
			m_rtt.jitter_avg  = m_rtt.jitter_avg * (num_samples/(num_samples-1)) +
								jitter * (1/num_samples);

		if (profiler_id != "")
		{
			g_profiler->graphAdd(profiler_id + "_rtt", rtt);
			g_profiler->graphAdd(profiler_id + "_jitter", jitter);
		}
	}
	/* save values required for next loop */
	m_last_rtt = rtt;
}

bool Peer::isTimedOut(float timeout)
{
	MutexAutoLock lock(m_exclusive_access_mutex);
	u32 current_time = porting::getTimeMs();

	float dtime = CALC_DTIME(m_last_timeout_check,current_time);
	m_last_timeout_check = current_time;

	m_timeout_counter += dtime;

	return m_timeout_counter > timeout;
}

void Peer::Drop()
{
	{
		MutexAutoLock usage_lock(m_exclusive_access_mutex);
		m_pending_deletion = true;
		if (m_usage != 0)
			return;
	}

	PROFILE(std::stringstream peerIdentifier1);
	PROFILE(peerIdentifier1 << "runTimeouts[" << m_connection->getDesc()
			<< ";" << id << ";RELIABLE]");
	PROFILE(g_profiler->remove(peerIdentifier1.str()));
	PROFILE(std::stringstream peerIdentifier2);
	PROFILE(peerIdentifier2 << "sendPackets[" << m_connection->getDesc()
			<< ";" << id << ";RELIABLE]");
	PROFILE(ScopeProfiler peerprofiler(g_profiler, peerIdentifier2.str(), SPT_AVG));

	delete this;
}

UDPPeer::UDPPeer(u16 a_id, Address a_address, Connection* connection) :
	Peer(a_address,a_id,connection),
	m_pending_disconnect(false),
	resend_timeout(0.5),
	m_legacy_peer(true)
{
}

bool UDPPeer::getAddress(MTProtocols type,Address& toset)
{
	if ((type == MTP_UDP) || (type == MTP_MINETEST_RELIABLE_UDP) || (type == MTP_PRIMARY))
	{
		toset = address;
		return true;
	}

	return false;
}

void UDPPeer::setNonLegacyPeer()
{
	m_legacy_peer = false;
	for(unsigned int i=0; i< CHANNEL_COUNT; i++)
	{
		channels->setWindowSize(g_settings->getU16("max_packets_per_iteration"));
	}
}

void UDPPeer::reportRTT(float rtt)
{
	if (rtt < 0.0) {
		return;
	}
	RTTStatistics(rtt,"rudp",MAX_RELIABLE_WINDOW_SIZE*10);

	float timeout = getStat(AVG_RTT) * RESEND_TIMEOUT_FACTOR;
	if (timeout < RESEND_TIMEOUT_MIN)
		timeout = RESEND_TIMEOUT_MIN;
	if (timeout > RESEND_TIMEOUT_MAX)
		timeout = RESEND_TIMEOUT_MAX;

	MutexAutoLock usage_lock(m_exclusive_access_mutex);
	resend_timeout = timeout;
}

bool UDPPeer::Ping(float dtime,SharedBuffer<u8>& data)
{
	m_ping_timer += dtime;
	if (m_ping_timer >= PING_TIMEOUT)
	{
		// Create and send PING packet
		writeU8(&data[0], TYPE_CONTROL);
		writeU8(&data[1], CONTROLTYPE_PING);
		m_ping_timer = 0.0;
		return true;
	}
	return false;
}

void UDPPeer::PutReliableSendCommand(ConnectionCommand &c,
		unsigned int max_packet_size)
{
	if (m_pending_disconnect)
		return;

	if ( channels[c.channelnum].queued_commands.empty() &&
			/* don't queue more packets then window size */
			(channels[c.channelnum].queued_reliables.size()
			< (channels[c.channelnum].getWindowSize()/2))) {
		LOG(dout_con<<m_connection->getDesc()
				<<" processing reliable command for peer id: " << c.peer_id
				<<" data size: " << c.data.getSize() << std::endl);
		if (!processReliableSendCommand(c,max_packet_size)) {
			channels[c.channelnum].queued_commands.push_back(c);
		}
	}
	else {
		LOG(dout_con<<m_connection->getDesc()
				<<" Queueing reliable command for peer id: " << c.peer_id
				<<" data size: " << c.data.getSize() <<std::endl);
		channels[c.channelnum].queued_commands.push_back(c);
	}
}

bool UDPPeer::processReliableSendCommand(
				ConnectionCommand &c,
				unsigned int max_packet_size)
{
	if (m_pending_disconnect)
		return true;

	u32 chunksize_max = max_packet_size
							- BASE_HEADER_SIZE
							- RELIABLE_HEADER_SIZE;

	sanity_check(c.data.getSize() < MAX_RELIABLE_WINDOW_SIZE*512);

	std::list<SharedBuffer<u8> > originals;
	u16 split_sequence_number = channels[c.channelnum].readNextSplitSeqNum();

	if (c.raw)
	{
		originals.push_back(c.data);
	}
	else {
		originals = makeAutoSplitPacket(c.data, chunksize_max,split_sequence_number);
		channels[c.channelnum].setNextSplitSeqNum(split_sequence_number);
	}

	bool have_sequence_number = true;
	bool have_initial_sequence_number = false;
	std::queue<BufferedPacket> toadd;
	volatile u16 initial_sequence_number = 0;

	for(std::list<SharedBuffer<u8> >::iterator i = originals.begin();
		i != originals.end(); ++i)
	{
		u16 seqnum = channels[c.channelnum].getOutgoingSequenceNumber(have_sequence_number);

		/* oops, we don't have enough sequence numbers to send this packet */
		if (!have_sequence_number)
			break;

		if (!have_initial_sequence_number)
		{
			initial_sequence_number = seqnum;
			have_initial_sequence_number = true;
		}

		SharedBuffer<u8> reliable = makeReliablePacket(*i, seqnum);

		// Add base headers and make a packet
		BufferedPacket p = con::makePacket(address, reliable,
				m_connection->GetProtocolID(), m_connection->GetPeerID(),
				c.channelnum);

		toadd.push(p);
	}

	if (have_sequence_number) {
		volatile u16 pcount = 0;
		while(toadd.size() > 0) {
			BufferedPacket p = toadd.front();
			toadd.pop();
//			LOG(dout_con<<connection->getDesc()
//					<< " queuing reliable packet for peer_id: " << c.peer_id
//					<< " channel: " << (c.channelnum&0xFF)
//					<< " seqnum: " << readU16(&p.data[BASE_HEADER_SIZE+1])
//					<< std::endl)
			channels[c.channelnum].queued_reliables.push(p);
			pcount++;
		}
		sanity_check(channels[c.channelnum].queued_reliables.size() < 0xFFFF);
		return true;
	}
	else {
		volatile u16 packets_available = toadd.size();
		/* we didn't get a single sequence number no need to fill queue */
		if (!have_initial_sequence_number)
		{
			return false;
		}
		while(toadd.size() > 0) {
			/* remove packet */
			toadd.pop();

			bool successfully_put_back_sequence_number
				= channels[c.channelnum].putBackSequenceNumber(
					(initial_sequence_number+toadd.size() % (SEQNUM_MAX+1)));

			FATAL_ERROR_IF(!successfully_put_back_sequence_number, "error");
		}
		LOG(dout_con<<m_connection->getDesc()
				<< " Windowsize exceeded on reliable sending "
				<< c.data.getSize() << " bytes"
				<< std::endl << "\t\tinitial_sequence_number: "
				<< initial_sequence_number
				<< std::endl << "\t\tgot at most            : "
				<< packets_available << " packets"
				<< std::endl << "\t\tpackets queued         : "
				<< channels[c.channelnum].outgoing_reliables_sent.size()
				<< std::endl);
		return false;
	}
}

void UDPPeer::RunCommandQueues(
							unsigned int max_packet_size,
							unsigned int maxcommands,
							unsigned int maxtransfer)
{

	for (unsigned int i = 0; i < CHANNEL_COUNT; i++) {
		unsigned int commands_processed = 0;

		if ((channels[i].queued_commands.size() > 0) &&
				(channels[i].queued_reliables.size() < maxtransfer) &&
				(commands_processed < maxcommands)) {
			try {
				ConnectionCommand c = channels[i].queued_commands.front();

				LOG(dout_con << m_connection->getDesc()
						<< " processing queued reliable command " << std::endl);

				// Packet is processed, remove it from queue
				if (processReliableSendCommand(c,max_packet_size)) {
					channels[i].queued_commands.pop_front();
				} else {
					LOG(dout_con << m_connection->getDesc()
							<< " Failed to queue packets for peer_id: " << c.peer_id
							<< ", delaying sending of " << c.data.getSize()
							<< " bytes" << std::endl);
				}
			}
			catch (ItemNotFoundException &e) {
				// intentionally empty
			}
		}
	}
}

u16 UDPPeer::getNextSplitSequenceNumber(u8 channel)
{
	assert(channel < CHANNEL_COUNT); // Pre-condition
	return channels[channel].readNextIncomingSeqNum();
}

void UDPPeer::setNextSplitSequenceNumber(u8 channel, u16 seqnum)
{
	assert(channel < CHANNEL_COUNT); // Pre-condition
	channels[channel].setNextSplitSeqNum(seqnum);
}

SharedBuffer<u8> UDPPeer::addSpiltPacket(u8 channel,
											BufferedPacket toadd,
											bool reliable)
{
	assert(channel < CHANNEL_COUNT); // Pre-condition
	return channels[channel].incoming_splits.insert(toadd,reliable);
}

/******************************************************************************/
/* Connection Threads                                                         */
/******************************************************************************/

ConnectionSendThread::ConnectionSendThread(unsigned int max_packet_size,
		float timeout) :
	Thread("ConnectionSend"),
	m_connection(NULL),
	m_max_packet_size(max_packet_size),
	m_timeout(timeout),
	m_max_commands_per_iteration(1),
	m_max_data_packets_per_iteration(g_settings->getU16("max_packets_per_iteration")),
	m_max_packets_requeued(256)
{
}

void * ConnectionSendThread::run()
{
	assert(m_connection);

	LOG(dout_con<<m_connection->getDesc()
			<<"ConnectionSend thread started"<<std::endl);

	u32 curtime = porting::getTimeMs();
	u32 lasttime = curtime;

	PROFILE(std::stringstream ThreadIdentifier);
	PROFILE(ThreadIdentifier << "ConnectionSend: [" << m_connection->getDesc() << "]");

	/* if stop is requested don't stop immediately but try to send all        */
	/* packets first */
	while(!stopRequested() || packetsQueued()) {
		BEGIN_DEBUG_EXCEPTION_HANDLER
		PROFILE(ScopeProfiler sp(g_profiler, ThreadIdentifier.str(), SPT_AVG));

		m_iteration_packets_avaialble = m_max_data_packets_per_iteration;

		/* wait for trigger or timeout */
		m_send_sleep_semaphore.wait(50);

		/* remove all triggers */
		while(m_send_sleep_semaphore.wait(0)) {}

		lasttime = curtime;
		curtime = porting::getTimeMs();
		float dtime = CALC_DTIME(lasttime,curtime);

		/* first do all the reliable stuff */
		runTimeouts(dtime);

		/* translate commands to packets */
		ConnectionCommand c = m_connection->m_command_queue.pop_frontNoEx(0);
		while(c.type != CONNCMD_NONE)
				{
			if (c.reliable)
				processReliableCommand(c);
			else
				processNonReliableCommand(c);

			c = m_connection->m_command_queue.pop_frontNoEx(0);
		}

		/* send non reliable packets */
		sendPackets(dtime);

		END_DEBUG_EXCEPTION_HANDLER
	}

	PROFILE(g_profiler->remove(ThreadIdentifier.str()));
	return NULL;
}

void ConnectionSendThread::Trigger()
{
	m_send_sleep_semaphore.post();
}

bool ConnectionSendThread::packetsQueued()
{
	std::list<u16> peerIds = m_connection->getPeerIDs();

	if (!m_outgoing_queue.empty() && !peerIds.empty())
		return true;

	for(std::list<u16>::iterator j = peerIds.begin();
			j != peerIds.end(); ++j)
	{
		PeerHelper peer = m_connection->getPeerNoEx(*j);

		if (!peer)
			continue;

		if (dynamic_cast<UDPPeer*>(&peer) == 0)
			continue;

		for(u16 i=0; i < CHANNEL_COUNT; i++) {
			Channel *channel = &(dynamic_cast<UDPPeer*>(&peer))->channels[i];

			if (channel->queued_commands.size() > 0) {
				return true;
			}
		}
	}


	return false;
}

void ConnectionSendThread::runTimeouts(float dtime)
{
	std::list<u16> timeouted_peers;
	std::list<u16> peerIds = m_connection->getPeerIDs();

	for(std::list<u16>::iterator j = peerIds.begin();
		j != peerIds.end(); ++j)
	{
		PeerHelper peer = m_connection->getPeerNoEx(*j);

		if (!peer)
			continue;

		if (dynamic_cast<UDPPeer*>(&peer) == 0)
			continue;

		PROFILE(std::stringstream peerIdentifier);
		PROFILE(peerIdentifier << "runTimeouts[" << m_connection->getDesc()
				<< ";" << *j << ";RELIABLE]");
		PROFILE(ScopeProfiler peerprofiler(g_profiler, peerIdentifier.str(), SPT_AVG));

		SharedBuffer<u8> data(2); // data for sending ping, required here because of goto

		/*
			Check peer timeout
		*/
		if (peer->isTimedOut(m_timeout))
		{
			infostream<<m_connection->getDesc()
					<<"RunTimeouts(): Peer "<<peer->id
					<<" has timed out."
					<<" (source=peer->timeout_counter)"
					<<std::endl;
			// Add peer to the list
			timeouted_peers.push_back(peer->id);
			// Don't bother going through the buffers of this one
			continue;
		}

		float resend_timeout = dynamic_cast<UDPPeer*>(&peer)->getResendTimeout();
		bool retry_count_exceeded = false;
		for(u16 i=0; i<CHANNEL_COUNT; i++)
		{
			std::list<BufferedPacket> timed_outs;
			Channel *channel = &(dynamic_cast<UDPPeer*>(&peer))->channels[i];

			if (dynamic_cast<UDPPeer*>(&peer)->getLegacyPeer())
				channel->setWindowSize(g_settings->getU16("workaround_window_size"));

			// Remove timed out incomplete unreliable split packets
			channel->incoming_splits.removeUnreliableTimedOuts(dtime, m_timeout);

			// Increment reliable packet times
			channel->outgoing_reliables_sent.incrementTimeouts(dtime);

			unsigned int numpeers = m_connection->m_peers.size();

			if (numpeers == 0)
				return;

			// Re-send timed out outgoing reliables
			timed_outs = channel->
					outgoing_reliables_sent.getTimedOuts(resend_timeout,
							(m_max_data_packets_per_iteration/numpeers));

			channel->UpdatePacketLossCounter(timed_outs.size());
			g_profiler->graphAdd("packets_lost", timed_outs.size());

			m_iteration_packets_avaialble -= timed_outs.size();

			for(std::list<BufferedPacket>::iterator k = timed_outs.begin();
				k != timed_outs.end(); ++k)
			{
				u16 peer_id = readPeerId(*(k->data));
				u8 channelnum  = readChannel(*(k->data));
				u16 seqnum  = readU16(&(k->data[BASE_HEADER_SIZE+1]));

				channel->UpdateBytesLost(k->data.getSize());
				k->resend_count++;

				if (k-> resend_count > MAX_RELIABLE_RETRY) {
					retry_count_exceeded = true;
					timeouted_peers.push_back(peer->id);
					/* no need to check additional packets if a single one did timeout*/
					break;
				}

				LOG(derr_con<<m_connection->getDesc()
						<<"RE-SENDING timed-out RELIABLE to "
						<< k->address.serializeString()
						<< "(t/o="<<resend_timeout<<"): "
						<<"from_peer_id="<<peer_id
						<<", channel="<<((int)channelnum&0xff)
						<<", seqnum="<<seqnum
						<<std::endl);

				rawSend(*k);

				// do not handle rtt here as we can't decide if this packet was
				// lost or really takes more time to transmit
			}

			if (retry_count_exceeded) {
				break; /* no need to check other channels if we already did timeout */
			}

			channel->UpdateTimers(dtime,dynamic_cast<UDPPeer*>(&peer)->getLegacyPeer());
		}

		/* skip to next peer if we did timeout */
		if (retry_count_exceeded)
			continue;

		/* send ping if necessary */
		if (dynamic_cast<UDPPeer*>(&peer)->Ping(dtime,data)) {
			LOG(dout_con<<m_connection->getDesc()
					<<"Sending ping for peer_id: "
					<< dynamic_cast<UDPPeer*>(&peer)->id <<std::endl);
			/* this may fail if there ain't a sequence number left */
			if (!rawSendAsPacket(dynamic_cast<UDPPeer*>(&peer)->id, 0, data, true))
			{
				//retrigger with reduced ping interval
				dynamic_cast<UDPPeer*>(&peer)->Ping(4.0,data);
			}
		}

		dynamic_cast<UDPPeer*>(&peer)->RunCommandQueues(m_max_packet_size,
								m_max_commands_per_iteration,
								m_max_packets_requeued);
	}

	// Remove timed out peers
	for(std::list<u16>::iterator i = timeouted_peers.begin();
		i != timeouted_peers.end(); ++i)
	{
		LOG(derr_con<<m_connection->getDesc()
				<<"RunTimeouts(): Removing peer "<<(*i)<<std::endl);
		m_connection->deletePeer(*i, true);
	}
}

void ConnectionSendThread::rawSend(const BufferedPacket &packet)
{
	try{
		m_connection->m_udpSocket.Send(packet.address, *packet.data,
				packet.data.getSize());
		LOG(dout_con <<m_connection->getDesc()
				<< " rawSend: " << packet.data.getSize()
				<< " bytes sent" << std::endl);
	} catch(SendFailedException &e) {
		LOG(derr_con<<m_connection->getDesc()
				<<"Connection::rawSend(): SendFailedException: "
				<<packet.address.serializeString()<<std::endl);
	}
}

void ConnectionSendThread::sendAsPacketReliable(BufferedPacket& p, Channel* channel)
{
	try{
		p.absolute_send_time = porting::getTimeMs();
		// Buffer the packet
		channel->outgoing_reliables_sent.insert(p,
			(channel->readOutgoingSequenceNumber() - MAX_RELIABLE_WINDOW_SIZE)
			% (MAX_RELIABLE_WINDOW_SIZE+1));
	}
	catch(AlreadyExistsException &e)
	{
		LOG(derr_con<<m_connection->getDesc()
				<<"WARNING: Going to send a reliable packet"
				<<" in outgoing buffer" <<std::endl);
	}

	// Send the packet
	rawSend(p);
}

bool ConnectionSendThread::rawSendAsPacket(u16 peer_id, u8 channelnum,
		SharedBuffer<u8> data, bool reliable)
{
	PeerHelper peer = m_connection->getPeerNoEx(peer_id);
	if (!peer) {
		LOG(dout_con<<m_connection->getDesc()
				<<" INFO: dropped packet for non existent peer_id: "
				<< peer_id << std::endl);
		FATAL_ERROR_IF(!reliable, "Trying to send raw packet reliable but no peer found!");
		return false;
	}
	Channel *channel = &(dynamic_cast<UDPPeer*>(&peer)->channels[channelnum]);

	if (reliable)
	{
		bool have_sequence_number_for_raw_packet = true;
		u16 seqnum =
				channel->getOutgoingSequenceNumber(have_sequence_number_for_raw_packet);

		if (!have_sequence_number_for_raw_packet)
			return false;

		SharedBuffer<u8> reliable = makeReliablePacket(data, seqnum);
		Address peer_address;
		peer->getAddress(MTP_MINETEST_RELIABLE_UDP, peer_address);

		// Add base headers and make a packet
		BufferedPacket p = con::makePacket(peer_address, reliable,
				m_connection->GetProtocolID(), m_connection->GetPeerID(),
				channelnum);

		// first check if our send window is already maxed out
		if (channel->outgoing_reliables_sent.size()
				< channel->getWindowSize()) {
			LOG(dout_con<<m_connection->getDesc()
					<<" INFO: sending a reliable packet to peer_id " << peer_id
					<<" channel: " << channelnum
					<<" seqnum: " << seqnum << std::endl);
			sendAsPacketReliable(p,channel);
			return true;
		}
		else {
			LOG(dout_con<<m_connection->getDesc()
					<<" INFO: queueing reliable packet for peer_id: " << peer_id
					<<" channel: " << channelnum
					<<" seqnum: " << seqnum << std::endl);
			channel->queued_reliables.push(p);
			return false;
		}
	}
	else
	{
		Address peer_address;

		if (peer->getAddress(MTP_UDP, peer_address))
		{
			// Add base headers and make a packet
			BufferedPacket p = con::makePacket(peer_address, data,
					m_connection->GetProtocolID(), m_connection->GetPeerID(),
					channelnum);

			// Send the packet
			rawSend(p);
			return true;
		}
		else {
			LOG(dout_con<<m_connection->getDesc()
					<<" INFO: dropped unreliable packet for peer_id: " << peer_id
					<<" because of (yet) missing udp address" << std::endl);
			return false;
		}
	}

	//never reached
	return false;
}

void ConnectionSendThread::processReliableCommand(ConnectionCommand &c)
{
	assert(c.reliable);  // Pre-condition

	switch(c.type) {
	case CONNCMD_NONE:
		LOG(dout_con<<m_connection->getDesc()
				<<"UDP processing reliable CONNCMD_NONE"<<std::endl);
		return;

	case CONNCMD_SEND:
		LOG(dout_con<<m_connection->getDesc()
				<<"UDP processing reliable CONNCMD_SEND"<<std::endl);
		sendReliable(c);
		return;

	case CONNCMD_SEND_TO_ALL:
		LOG(dout_con<<m_connection->getDesc()
				<<"UDP processing CONNCMD_SEND_TO_ALL"<<std::endl);
		sendToAllReliable(c);
		return;

	case CONCMD_CREATE_PEER:
		LOG(dout_con<<m_connection->getDesc()
				<<"UDP processing reliable CONCMD_CREATE_PEER"<<std::endl);
		if (!rawSendAsPacket(c.peer_id,c.channelnum,c.data,c.reliable))
		{
			/* put to queue if we couldn't send it immediately */
			sendReliable(c);
		}
		return;

	case CONCMD_DISABLE_LEGACY:
		LOG(dout_con<<m_connection->getDesc()
				<<"UDP processing reliable CONCMD_DISABLE_LEGACY"<<std::endl);
		if (!rawSendAsPacket(c.peer_id,c.channelnum,c.data,c.reliable))
		{
			/* put to queue if we couldn't send it immediately */
			sendReliable(c);
		}
		return;

	case CONNCMD_SERVE:
	case CONNCMD_CONNECT:
	case CONNCMD_DISCONNECT:
	case CONCMD_ACK:
		FATAL_ERROR("Got command that shouldn't be reliable as reliable command");
	default:
		LOG(dout_con<<m_connection->getDesc()
				<<" Invalid reliable command type: " << c.type <<std::endl);
	}
}


void ConnectionSendThread::processNonReliableCommand(ConnectionCommand &c)
{
	assert(!c.reliable); // Pre-condition

	switch(c.type) {
	case CONNCMD_NONE:
		LOG(dout_con<<m_connection->getDesc()
				<<" UDP processing CONNCMD_NONE"<<std::endl);
		return;
	case CONNCMD_SERVE:
		LOG(dout_con<<m_connection->getDesc()
				<<" UDP processing CONNCMD_SERVE port="
				<<c.address.serializeString()<<std::endl);
		serve(c.address);
		return;
	case CONNCMD_CONNECT:
		LOG(dout_con<<m_connection->getDesc()
				<<" UDP processing CONNCMD_CONNECT"<<std::endl);
		connect(c.address);
		return;
	case CONNCMD_DISCONNECT:
		LOG(dout_con<<m_connection->getDesc()
				<<" UDP processing CONNCMD_DISCONNECT"<<std::endl);
		disconnect();
		return;
	case CONNCMD_DISCONNECT_PEER:
		LOG(dout_con<<m_connection->getDesc()
				<<" UDP processing CONNCMD_DISCONNECT_PEER"<<std::endl);
		disconnect_peer(c.peer_id);
		return;
	case CONNCMD_SEND:
		LOG(dout_con<<m_connection->getDesc()
				<<" UDP processing CONNCMD_SEND"<<std::endl);
		send(c.peer_id, c.channelnum, c.data);
		return;
	case CONNCMD_SEND_TO_ALL:
		LOG(dout_con<<m_connection->getDesc()
				<<" UDP processing CONNCMD_SEND_TO_ALL"<<std::endl);
		sendToAll(c.channelnum, c.data);
		return;
	case CONCMD_ACK:
		LOG(dout_con<<m_connection->getDesc()
				<<" UDP processing CONCMD_ACK"<<std::endl);
		sendAsPacket(c.peer_id,c.channelnum,c.data,true);
		return;
	case CONCMD_CREATE_PEER:
		FATAL_ERROR("Got command that should be reliable as unreliable command");
	default:
		LOG(dout_con<<m_connection->getDesc()
				<<" Invalid command type: " << c.type <<std::endl);
	}
}

void ConnectionSendThread::serve(Address bind_address)
{
	LOG(dout_con<<m_connection->getDesc()
			<<"UDP serving at port " << bind_address.serializeString() <<std::endl);
	try{
		m_connection->m_udpSocket.Bind(bind_address);
		m_connection->SetPeerID(PEER_ID_SERVER);
	}
	catch(SocketException &e) {
		// Create event
		ConnectionEvent ce;
		ce.bindFailed();
		m_connection->putEvent(ce);
	}
}

void ConnectionSendThread::connect(Address address)
{
	LOG(dout_con<<m_connection->getDesc()<<" connecting to "<<address.serializeString()
			<<":"<<address.getPort()<<std::endl);

	UDPPeer *peer = m_connection->createServerPeer(address);

	// Create event
	ConnectionEvent e;
	e.peerAdded(peer->id, peer->address);
	m_connection->putEvent(e);

	Address bind_addr;

	if (address.isIPv6())
		bind_addr.setAddress((IPv6AddressBytes*) NULL);
	else
		bind_addr.setAddress(0,0,0,0);

	m_connection->m_udpSocket.Bind(bind_addr);

	// Send a dummy packet to server with peer_id = PEER_ID_INEXISTENT
	m_connection->SetPeerID(PEER_ID_INEXISTENT);
	NetworkPacket pkt(0,0);
	m_connection->Send(PEER_ID_SERVER, 0, &pkt, true);
}

void ConnectionSendThread::disconnect()
{
	LOG(dout_con<<m_connection->getDesc()<<" disconnecting"<<std::endl);

	// Create and send DISCO packet
	SharedBuffer<u8> data(2);
	writeU8(&data[0], TYPE_CONTROL);
	writeU8(&data[1], CONTROLTYPE_DISCO);


	// Send to all
	std::list<u16> peerids = m_connection->getPeerIDs();

	for (std::list<u16>::iterator i = peerids.begin();
			i != peerids.end();
			++i)
	{
		sendAsPacket(*i, 0,data,false);
	}
}

void ConnectionSendThread::disconnect_peer(u16 peer_id)
{
	LOG(dout_con<<m_connection->getDesc()<<" disconnecting peer"<<std::endl);

	// Create and send DISCO packet
	SharedBuffer<u8> data(2);
	writeU8(&data[0], TYPE_CONTROL);
	writeU8(&data[1], CONTROLTYPE_DISCO);
	sendAsPacket(peer_id, 0,data,false);

	PeerHelper peer = m_connection->getPeerNoEx(peer_id);

	if (!peer)
		return;

	if (dynamic_cast<UDPPeer*>(&peer) == 0)
	{
		return;
	}

	dynamic_cast<UDPPeer*>(&peer)->m_pending_disconnect = true;
}

void ConnectionSendThread::send(u16 peer_id, u8 channelnum,
		SharedBuffer<u8> data)
{
	assert(channelnum < CHANNEL_COUNT); // Pre-condition

	PeerHelper peer = m_connection->getPeerNoEx(peer_id);
	if (!peer)
	{
		LOG(dout_con<<m_connection->getDesc()<<" peer: peer_id="<<peer_id
				<< ">>>NOT<<< found on sending packet"
				<< ", channel " << (channelnum % 0xFF)
				<< ", size: " << data.getSize() <<std::endl);
		return;
	}

	LOG(dout_con<<m_connection->getDesc()<<" sending to peer_id="<<peer_id
			<< ", channel " << (channelnum % 0xFF)
			<< ", size: " << data.getSize() <<std::endl);

	u16 split_sequence_number = peer->getNextSplitSequenceNumber(channelnum);

	u32 chunksize_max = m_max_packet_size - BASE_HEADER_SIZE;
	std::list<SharedBuffer<u8> > originals;

	originals = makeAutoSplitPacket(data, chunksize_max,split_sequence_number);

	peer->setNextSplitSequenceNumber(channelnum,split_sequence_number);

	for(std::list<SharedBuffer<u8> >::iterator i = originals.begin();
		i != originals.end(); ++i)
	{
		SharedBuffer<u8> original = *i;
		sendAsPacket(peer_id, channelnum, original);
	}
}

void ConnectionSendThread::sendReliable(ConnectionCommand &c)
{
	PeerHelper peer = m_connection->getPeerNoEx(c.peer_id);
	if (!peer)
		return;

	peer->PutReliableSendCommand(c,m_max_packet_size);
}

void ConnectionSendThread::sendToAll(u8 channelnum, SharedBuffer<u8> data)
{
	std::list<u16> peerids = m_connection->getPeerIDs();

	for (std::list<u16>::iterator i = peerids.begin();
			i != peerids.end();
			++i)
	{
		send(*i, channelnum, data);
	}
}

void ConnectionSendThread::sendToAllReliable(ConnectionCommand &c)
{
	std::list<u16> peerids = m_connection->getPeerIDs();

	for (std::list<u16>::iterator i = peerids.begin();
			i != peerids.end();
			++i)
	{
		PeerHelper peer = m_connection->getPeerNoEx(*i);

		if (!peer)
			continue;

		peer->PutReliableSendCommand(c,m_max_packet_size);
	}
}

void ConnectionSendThread::sendPackets(float dtime)
{
	std::list<u16> peerIds = m_connection->getPeerIDs();
	std::list<u16> pendingDisconnect;
	std::map<u16,bool> pending_unreliable;

	for(std::list<u16>::iterator
			j = peerIds.begin();
			j != peerIds.end(); ++j)
	{
		PeerHelper peer = m_connection->getPeerNoEx(*j);
		//peer may have been removed
		if (!peer) {
			LOG(dout_con<<m_connection->getDesc()<< " Peer not found: peer_id=" << *j << std::endl);
			continue;
		}
		peer->m_increment_packets_remaining = m_iteration_packets_avaialble/m_connection->m_peers.size();

		if (dynamic_cast<UDPPeer*>(&peer) == 0)
		{
			continue;
		}

		if (dynamic_cast<UDPPeer*>(&peer)->m_pending_disconnect)
		{
			pendingDisconnect.push_back(*j);
		}

		PROFILE(std::stringstream peerIdentifier);
		PROFILE(peerIdentifier << "sendPackets[" << m_connection->getDesc() << ";" << *j << ";RELIABLE]");
		PROFILE(ScopeProfiler peerprofiler(g_profiler, peerIdentifier.str(), SPT_AVG));

		LOG(dout_con<<m_connection->getDesc()
				<< " Handle per peer queues: peer_id=" << *j
				<< " packet quota: " << peer->m_increment_packets_remaining << std::endl);
		// first send queued reliable packets for all peers (if possible)
		for (unsigned int i=0; i < CHANNEL_COUNT; i++)
		{
			u16 next_to_ack = 0;
			dynamic_cast<UDPPeer*>(&peer)->channels[i].outgoing_reliables_sent.getFirstSeqnum(next_to_ack);
			u16 next_to_receive = 0;
			dynamic_cast<UDPPeer*>(&peer)->channels[i].incoming_reliables.getFirstSeqnum(next_to_receive);

			LOG(dout_con<<m_connection->getDesc()<< "\t channel: "
						<< i << ", peer quota:"
						<< peer->m_increment_packets_remaining
						<< std::endl
					<< "\t\t\treliables on wire: "
						<< dynamic_cast<UDPPeer*>(&peer)->channels[i].outgoing_reliables_sent.size()
						<< ", waiting for ack for " << next_to_ack
						<< std::endl
					<< "\t\t\tincoming_reliables: "
						<< dynamic_cast<UDPPeer*>(&peer)->channels[i].incoming_reliables.size()
						<< ", next reliable packet: "
						<< dynamic_cast<UDPPeer*>(&peer)->channels[i].readNextIncomingSeqNum()
						<< ", next queued: " << next_to_receive
						<< std::endl
					<< "\t\t\treliables queued : "
						<< dynamic_cast<UDPPeer*>(&peer)->channels[i].queued_reliables.size()
						<< std::endl
					<< "\t\t\tqueued commands  : "
						<< dynamic_cast<UDPPeer*>(&peer)->channels[i].queued_commands.size()
						<< std::endl);

			while ((dynamic_cast<UDPPeer*>(&peer)->channels[i].queued_reliables.size() > 0) &&
					(dynamic_cast<UDPPeer*>(&peer)->channels[i].outgoing_reliables_sent.size()
							< dynamic_cast<UDPPeer*>(&peer)->channels[i].getWindowSize())&&
							(peer->m_increment_packets_remaining > 0))
			{
				BufferedPacket p = dynamic_cast<UDPPeer*>(&peer)->channels[i].queued_reliables.front();
				dynamic_cast<UDPPeer*>(&peer)->channels[i].queued_reliables.pop();
				Channel* channel = &(dynamic_cast<UDPPeer*>(&peer)->channels[i]);
				LOG(dout_con<<m_connection->getDesc()
						<<" INFO: sending a queued reliable packet "
						<<" channel: " << i
						<<", seqnum: " << readU16(&p.data[BASE_HEADER_SIZE+1])
						<< std::endl);
				sendAsPacketReliable(p,channel);
				peer->m_increment_packets_remaining--;
			}
		}
	}

	if (m_outgoing_queue.size())
	{
		LOG(dout_con<<m_connection->getDesc()
				<< " Handle non reliable queue ("
				<< m_outgoing_queue.size() << " pkts)" << std::endl);
	}

	unsigned int initial_queuesize = m_outgoing_queue.size();
	/* send non reliable packets*/
	for(unsigned int i=0;i < initial_queuesize;i++) {
		OutgoingPacket packet = m_outgoing_queue.front();
		m_outgoing_queue.pop();

		if (packet.reliable)
			continue;

		PeerHelper peer = m_connection->getPeerNoEx(packet.peer_id);
		if (!peer) {
			LOG(dout_con<<m_connection->getDesc()
							<<" Outgoing queue: peer_id="<<packet.peer_id
							<< ">>>NOT<<< found on sending packet"
							<< ", channel " << (packet.channelnum % 0xFF)
							<< ", size: " << packet.data.getSize() <<std::endl);
			continue;
		}
		/* send acks immediately */
		else if (packet.ack)
		{
			rawSendAsPacket(packet.peer_id, packet.channelnum,
								packet.data, packet.reliable);
			peer->m_increment_packets_remaining =
					MYMIN(0,peer->m_increment_packets_remaining--);
		}
		else if (
			( peer->m_increment_packets_remaining > 0) ||
			(stopRequested())) {
			rawSendAsPacket(packet.peer_id, packet.channelnum,
					packet.data, packet.reliable);
			peer->m_increment_packets_remaining--;
		}
		else {
			m_outgoing_queue.push(packet);
			pending_unreliable[packet.peer_id] = true;
		}
	}

	for(std::list<u16>::iterator
				k = pendingDisconnect.begin();
				k != pendingDisconnect.end(); ++k)
	{
		if (!pending_unreliable[*k])
		{
			m_connection->deletePeer(*k,false);
		}
	}
}

void ConnectionSendThread::sendAsPacket(u16 peer_id, u8 channelnum,
		SharedBuffer<u8> data, bool ack)
{
	OutgoingPacket packet(peer_id, channelnum, data, false, ack);
	m_outgoing_queue.push(packet);
}

ConnectionReceiveThread::ConnectionReceiveThread(unsigned int max_packet_size) :
	Thread("ConnectionReceive"),
	m_connection(NULL)
{
}

void * ConnectionReceiveThread::run()
{
	assert(m_connection);

	LOG(dout_con<<m_connection->getDesc()
			<<"ConnectionReceive thread started"<<std::endl);

	PROFILE(std::stringstream ThreadIdentifier);
	PROFILE(ThreadIdentifier << "ConnectionReceive: [" << m_connection->getDesc() << "]");

#ifdef DEBUG_CONNECTION_KBPS
	u32 curtime = porting::getTimeMs();
	u32 lasttime = curtime;
	float debug_print_timer = 0.0;
#endif

	while(!stopRequested()) {
		BEGIN_DEBUG_EXCEPTION_HANDLER
		PROFILE(ScopeProfiler sp(g_profiler, ThreadIdentifier.str(), SPT_AVG));

#ifdef DEBUG_CONNECTION_KBPS
		lasttime = curtime;
		curtime = porting::getTimeMs();
		float dtime = CALC_DTIME(lasttime,curtime);
#endif

		/* receive packets */
		receive();

#ifdef DEBUG_CONNECTION_KBPS
		debug_print_timer += dtime;
		if (debug_print_timer > 20.0) {
			debug_print_timer -= 20.0;

			std::list<u16> peerids = m_connection->getPeerIDs();

			for (std::list<u16>::iterator i = peerids.begin();
					i != peerids.end();
					i++)
			{
				PeerHelper peer = m_connection->getPeerNoEx(*i);
				if (!peer)
					continue;

				float peer_current = 0.0;
				float peer_loss = 0.0;
				float avg_rate = 0.0;
				float avg_loss = 0.0;

				for(u16 j=0; j<CHANNEL_COUNT; j++)
				{
					peer_current +=peer->channels[j].getCurrentDownloadRateKB();
					peer_loss += peer->channels[j].getCurrentLossRateKB();
					avg_rate += peer->channels[j].getAvgDownloadRateKB();
					avg_loss += peer->channels[j].getAvgLossRateKB();
				}

				std::stringstream output;
				output << std::fixed << std::setprecision(1);
				output << "OUT to Peer " << *i << " RATES (good / loss) " << std::endl;
				output << "\tcurrent (sum): " << peer_current << "kb/s "<< peer_loss << "kb/s" << std::endl;
				output << "\taverage (sum): " << avg_rate << "kb/s "<< avg_loss << "kb/s" << std::endl;
				output << std::setfill(' ');
				for(u16 j=0; j<CHANNEL_COUNT; j++)
				{
					output << "\tcha " << j << ":"
						<< " CUR: " << std::setw(6) << peer->channels[j].getCurrentDownloadRateKB() <<"kb/s"
						<< " AVG: " << std::setw(6) << peer->channels[j].getAvgDownloadRateKB() <<"kb/s"
						<< " MAX: " << std::setw(6) << peer->channels[j].getMaxDownloadRateKB() <<"kb/s"
						<< " /"
						<< " CUR: " << std::setw(6) << peer->channels[j].getCurrentLossRateKB() <<"kb/s"
						<< " AVG: " << std::setw(6) << peer->channels[j].getAvgLossRateKB() <<"kb/s"
						<< " MAX: " << std::setw(6) << peer->channels[j].getMaxLossRateKB() <<"kb/s"
						<< " / WS: " << peer->channels[j].getWindowSize()
						<< std::endl;
				}

				fprintf(stderr,"%s\n",output.str().c_str());
			}
		}
#endif
		END_DEBUG_EXCEPTION_HANDLER
	}

	PROFILE(g_profiler->remove(ThreadIdentifier.str()));
	return NULL;
}

// Receive packets from the network and buffers and create ConnectionEvents
void ConnectionReceiveThread::receive()
{
	// use IPv6 minimum allowed MTU as receive buffer size as this is
	// theoretical reliable upper boundary of a udp packet for all IPv6 enabled
	// infrastructure
	unsigned int packet_maxsize = 1500;
	SharedBuffer<u8> packetdata(packet_maxsize);

	bool packet_queued = true;

	unsigned int loop_count = 0;

	/* first of all read packets from socket */
	/* check for incoming data available */
	while( (loop_count < 10) &&
			(m_connection->m_udpSocket.WaitData(50))) {
		loop_count++;
		try {
			if (packet_queued) {
				bool data_left = true;
				u16 peer_id;
				SharedBuffer<u8> resultdata;
				while(data_left) {
					try {
						data_left = getFromBuffers(peer_id, resultdata);
						if (data_left) {
							ConnectionEvent e;
							e.dataReceived(peer_id, resultdata);
							m_connection->putEvent(e);
						}
					}
					catch(ProcessedSilentlyException &e) {
						/* try reading again */
					}
				}
				packet_queued = false;
			}

			Address sender;
			s32 received_size = m_connection->m_udpSocket.Receive(sender, *packetdata, packet_maxsize);

			if ((received_size < BASE_HEADER_SIZE) ||
				(readU32(&packetdata[0]) != m_connection->GetProtocolID()))
			{
				LOG(derr_con<<m_connection->getDesc()
						<<"Receive(): Invalid incoming packet, "
						<<"size: " << received_size
						<<", protocol: "
						<< ((received_size >= 4) ? readU32(&packetdata[0]) : -1)
						<< std::endl);
				continue;
			}

			u16 peer_id          = readPeerId(*packetdata);
			u8 channelnum        = readChannel(*packetdata);

			if (channelnum > CHANNEL_COUNT-1) {
				LOG(derr_con<<m_connection->getDesc()
						<<"Receive(): Invalid channel "<<channelnum<<std::endl);
				throw InvalidIncomingDataException("Channel doesn't exist");
			}

			/* Try to identify peer by sender address (may happen on join) */
			if (peer_id == PEER_ID_INEXISTENT) {
				peer_id = m_connection->lookupPeer(sender);
				// We do not have to remind the peer of its
				// peer id as the CONTROLTYPE_SET_PEER_ID
				// command was sent reliably.
			}

			/* The peer was not found in our lists. Add it. */
			if (peer_id == PEER_ID_INEXISTENT) {
				peer_id = m_connection->createPeer(sender, MTP_MINETEST_RELIABLE_UDP, 0);
			}

			PeerHelper peer = m_connection->getPeerNoEx(peer_id);

			if (!peer) {
				LOG(dout_con<<m_connection->getDesc()
						<<" got packet from unknown peer_id: "
						<<peer_id<<" Ignoring."<<std::endl);
				continue;
			}

			// Validate peer address

			Address peer_address;

			if (peer->getAddress(MTP_UDP, peer_address)) {
				if (peer_address != sender) {
					LOG(derr_con<<m_connection->getDesc()
							<<m_connection->getDesc()
							<<" Peer "<<peer_id<<" sending from different address."
							" Ignoring."<<std::endl);
					continue;
				}
			}
			else {

				bool invalid_address = true;
				if (invalid_address) {
					LOG(derr_con<<m_connection->getDesc()
							<<m_connection->getDesc()
							<<" Peer "<<peer_id<<" unknown."
							" Ignoring."<<std::endl);
					continue;
				}
			}

			peer->ResetTimeout();

			Channel *channel = 0;

			if (dynamic_cast<UDPPeer*>(&peer) != 0)
			{
				channel = &(dynamic_cast<UDPPeer*>(&peer)->channels[channelnum]);
			}

			if (channel != 0) {
				channel->UpdateBytesReceived(received_size);
			}

			// Throw the received packet to channel->processPacket()

			// Make a new SharedBuffer from the data without the base headers
			SharedBuffer<u8> strippeddata(received_size - BASE_HEADER_SIZE);
			memcpy(*strippeddata, &packetdata[BASE_HEADER_SIZE],
					strippeddata.getSize());

			try{
				// Process it (the result is some data with no headers made by us)
				SharedBuffer<u8> resultdata = processPacket
						(channel, strippeddata, peer_id, channelnum, false);

				LOG(dout_con<<m_connection->getDesc()
						<<" ProcessPacket from peer_id: " << peer_id
						<< ",channel: " << (channelnum & 0xFF) << ", returned "
						<< resultdata.getSize() << " bytes" <<std::endl);

				ConnectionEvent e;
				e.dataReceived(peer_id, resultdata);
				m_connection->putEvent(e);
			}
			catch(ProcessedSilentlyException &e) {
			}
			catch(ProcessedQueued &e) {
				packet_queued = true;
			}
		}
		catch(InvalidIncomingDataException &e) {
		}
		catch(ProcessedSilentlyException &e) {
		}
	}
}

bool ConnectionReceiveThread::getFromBuffers(u16 &peer_id, SharedBuffer<u8> &dst)
{
	std::list<u16> peerids = m_connection->getPeerIDs();

	for(std::list<u16>::iterator j = peerids.begin();
		j != peerids.end(); ++j)
	{
		PeerHelper peer = m_connection->getPeerNoEx(*j);
		if (!peer)
			continue;

		if (dynamic_cast<UDPPeer*>(&peer) == 0)
			continue;

		for(u16 i=0; i<CHANNEL_COUNT; i++)