/* * libretroshare/src/services: p3turtle.cc * * Services for RetroShare. * * Copyright 2009 by Cyril Soler * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License Version 2 as published by the Free Software Foundation. * * This library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 * USA. * * Please report all bugs and problems to "csoler@users.sourceforge.net". * */ #include #include #include #ifdef P3TURTLE_DEBUG #include #endif #include "rsiface/rsiface.h" #include "rsiface/rspeers.h" #include "rsiface/rsfiles.h" #include "pqi/authssl.h" #include "pqi/p3connmgr.h" #include "pqi/pqinotify.h" #include "ft/ftserver.h" #include "ft/ftdatamultiplex.h" #include "ft/ftcontroller.h" #include "p3turtle.h" #include #include #include #include #include #include "util/rsdebug.h" #include "util/rsprint.h" #include "pqi/pqinetwork.h" // These number may be quite important. I setup them with sensible values, but // an in-depth test would be better to get an idea of what the ideal values // could ever be. // static const time_t TUNNEL_REQUESTS_LIFE_TIME = 120 ; /// life time for tunnel requests in the cache. static const time_t SEARCH_REQUESTS_LIFE_TIME = 120 ; /// life time for search requests in the cache static const time_t REGULAR_TUNNEL_DIGGING_TIME = 300 ; /// maximum interval between two tunnel digging campaigns. static const time_t MAXIMUM_TUNNEL_IDLE_TIME = 60 ; /// maximum life time of an unused tunnel. static const time_t TUNNEL_MANAGEMENT_LAPS_TIME = 10 ; /// look into tunnels regularly every 10 sec. p3turtle::p3turtle(p3ConnectMgr *cm,ftServer *fs) :p3Service(RS_SERVICE_TYPE_TURTLE), p3Config(CONFIG_TYPE_TURTLE), mConnMgr(cm) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ _ft_server = fs ; _ft_controller = fs->getController() ; srand(time(NULL)) ; addSerialType(new RsTurtleSerialiser()); _last_clean_time = 0 ; _last_tunnel_management_time = 0 ; _last_tunnel_campaign_time = 0 ; } int p3turtle::tick() { // Handle tunnel trafic // handleIncoming(); // handle incoming packets time_t now = time(NULL) ; // Tunnel management: // - we digg new tunnels at least every 5 min (300 sec). // - we digg new tunnels each time a new peer connects // - we digg new tunnels each time a new hash is asked for // if(now > TUNNEL_MANAGEMENT_LAPS_TIME+_last_tunnel_management_time || _force_digg_new_tunnels) { #ifdef P3TURTLE_DEBUG std::cerr << "Calling tunnel management." << std::endl ; #endif manageTunnels() ; _last_tunnel_management_time = now ; } // Clean every 10 sec. // if(now > 10+_last_clean_time) { #ifdef P3TURTLE_DEBUG std::cerr << "Calling autowash." << std::endl ; #endif autoWash() ; // clean old/unused tunnels and file hashes, as well as search and tunnel requests. _last_clean_time = now ; } #ifdef P3TURTLE_DEBUG // Dump state for debugging, every 20 sec. // static time_t last_dump = time(NULL) ; if(now > 20+last_dump) { last_dump = now ; dumpState() ; } #endif return 0 ; } // -----------------------------------------------------------------------------------// // ------------------------------ Tunnel maintenance. ------------------------------ // // -----------------------------------------------------------------------------------// // // This method handles peer connexion/deconnexion // If A connects, new tunnels should be initiated from A // If A disconnects, the tunnels passed through A should be closed. // void p3turtle::statusChange(const std::list &plist) // derived from pqiMonitor { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // We actually do not shut down tunnels when peers get down: Tunnels that // are not working properly get automatically removed after some time. // save the list of active peers. This is useful for notifying the ftContoller _online_peers = plist ; std::cerr << "p3turtle: status change triggered. Saving list of " << plist.size() << " peers." << std::endl ; /* if any have switched to 'connected' then we force digging new tunnels */ for(std::list::const_iterator pit = plist.begin(); pit != plist.end(); pit++) if ((pit->state & RS_PEER_S_FRIEND) && (pit->actions & RS_PEER_CONNECTED)) _force_digg_new_tunnels = true ; } // adds a virtual peer to the list that is communicated ot ftController. // void p3turtle::addDistantPeer(const TurtleFileHash&,TurtleTunnelId tid) { char buff[400] ; sprintf(buff,"Anonymous F2F tunnel %08x",tid) ; { _virtual_peers[TurtleVirtualPeerId(buff)] = tid ; #ifdef P3TURTLE_DEBUG assert(_local_tunnels.find(tid)!=_local_tunnels.end()) ; #endif _local_tunnels[tid].vpid = TurtleVirtualPeerId(buff) ; } } void p3turtle::getVirtualPeersList(std::list& list) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ list.clear() ; for(std::map::const_iterator it(_virtual_peers.begin());it!=_virtual_peers.end();++it) { pqipeer vp ; vp.id = it->first ; vp.name = "Virtual (distant) peer" ; vp.state = RS_PEER_S_CONNECTED ; vp.actions = RS_PEER_CONNECTED ; list.push_back(vp) ; } } // This method handles digging new tunnels as needed. // New tunnels are dug when: // - new peers have connected. The resulting tunnels should be checked against doubling. // - new hashes are submitted for handling. // void p3turtle::manageTunnels() { // Collect hashes for which tunnel digging is necessary / recommended std::vector hashes_to_digg ; { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ time_t now = time(NULL) ; bool tunnel_campain = false ; if(now > _last_tunnel_campaign_time + REGULAR_TUNNEL_DIGGING_TIME) { #ifdef P3TURTLE_DEBUG std::cerr << " Tunnel management: flaging all hashes for tunnels digging." << std::endl ; #endif tunnel_campain = true ; _last_tunnel_campaign_time = now ; } for(std::map::const_iterator it(_incoming_file_hashes.begin());it!=_incoming_file_hashes.end();++it) if(it->second.tunnels.empty() // digg new tunnels is no tunnels are available || _force_digg_new_tunnels // digg new tunnels when forced to (e.g. a new peer has connected) || tunnel_campain) // force digg new tunnels at regular (large) interval { #ifdef P3TURTLE_DEBUG std::cerr << " Tunnel management: digging new tunnels for hash " << it->first << "." << std::endl ; #endif hashes_to_digg.push_back(it->first) ; } _force_digg_new_tunnels = false ; } for(unsigned int i=0;i::iterator it(_incoming_file_hashes.find(_hashes_to_remove[i])) ; if(it == _incoming_file_hashes.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: asked to stop monitoring file hash " << _hashes_to_remove[i] << ", but this hash is actually not handled by the turtle router." << std::endl ; #endif continue ; } // copy the list of tunnels to remove. #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: stopping monitoring for file hash " << _hashes_to_remove[i] << ", and closing " << it->second.tunnels.size() << " tunnels (" ; #endif std::vector tunnels_to_remove ; for(std::vector::const_iterator it2(it->second.tunnels.begin());it2!=it->second.tunnels.end();++it2) { #ifdef P3TURTLE_DEBUG std::cerr << (void*)*it2 << "," ; #endif tunnels_to_remove.push_back(*it2) ; } #ifdef P3TURTLE_DEBUG std::cerr << ")" << std::endl ; #endif for(unsigned int k=0;k::iterator it(_search_requests_origins.begin());it!=_search_requests_origins.end();) if(now > (time_t)(it->second.time_stamp + SEARCH_REQUESTS_LIFE_TIME)) { #ifdef P3TURTLE_DEBUG std::cerr << " removed search request " << (void *)it->first << ", timeout." << std::endl ; #endif std::map::iterator tmp(it) ; ++tmp ; _search_requests_origins.erase(it) ; it = tmp ; } else ++it; } // Tunnel requests // { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ for(std::map::iterator it(_tunnel_requests_origins.begin());it!=_tunnel_requests_origins.end();) if(now > (time_t)(it->second.time_stamp + TUNNEL_REQUESTS_LIFE_TIME)) { #ifdef P3TURTLE_DEBUG std::cerr << " removed tunnel request " << (void *)it->first << ", timeout." << std::endl ; #endif std::map::iterator tmp(it) ; ++tmp ; _tunnel_requests_origins.erase(it) ; it = tmp ; } else ++it ; } // Tunnels. { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ std::vector tunnels_to_close ; for(std::map::iterator it(_local_tunnels.begin());it!=_local_tunnels.end();++it) if(now > (time_t)(it->second.time_stamp + MAXIMUM_TUNNEL_IDLE_TIME)) { #ifdef P3TURTLE_DEBUG std::cerr << " removing tunnel " << (void *)it->first << ": timeout." << std::endl ; #endif tunnels_to_close.push_back(it->first) ; } for(unsigned int i=0;i::iterator it(_local_tunnels.find(tid)) ; if(it == _local_tunnels.end()) { std::cerr << "p3turtle: was asked to close tunnel " << (void*)tid << ", which actually doesn't exist." << std::endl ; return ; } #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: Closing tunnel " << (void*)tid << std::endl ; #endif if(it->second.local_src == mConnMgr->getOwnId()) // this is a starting tunnel. We thus remove // - the virtual peer from the vpid list // - the tunnel id from the file hash // - the virtual peer from the file sources in the file transfer controller. { TurtleTunnelId tid = it->first ; TurtleVirtualPeerId vpid = it->second.vpid ; TurtleFileHash hash = it->second.hash ; #ifdef P3TURTLE_DEBUG std::cerr << " Tunnel is a starting point. Also removing:" << std::endl ; std::cerr << " Virtual Peer Id " << vpid << std::endl ; std::cerr << " Associated file source." << std::endl ; #endif _ft_controller->removeFileSource(hash,vpid) ; // Let's be cautious. Normally we should never be here without consistent information, // but still, this happens, rarely. // if(_virtual_peers.find(vpid) != _virtual_peers.end()) _virtual_peers.erase(_virtual_peers.find(vpid)) ; std::map::iterator it(_incoming_file_hashes.find(hash)) ; if(it != _incoming_file_hashes.end()) { std::vector& tunnels(it->second.tunnels) ; // Remove tunnel id from it's corresponding hash. For security we // go through the whole tab, although the tunnel id should only be listed once // in this tab. // for(unsigned int i=0;isecond.local_dst == mConnMgr->getOwnId()) // This is a ending tunnel. We also remove the virtual peer id { #ifdef P3TURTLE_DEBUG std::cerr << " Tunnel is a ending point. Also removing associated outgoing hash." ; #endif if(_outgoing_file_hashes.find(it->second.hash) != _outgoing_file_hashes.end()) _outgoing_file_hashes.erase(_outgoing_file_hashes.find(it->second.hash)) ; } _local_tunnels.erase(it) ; } void p3turtle::stopMonitoringFileTunnels(const std::string& hash) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: Marking hash " << hash << " to be removed during autowash." << std::endl ; #endif // We don't do the deletion in this process, because it can cause a race with tunnel management. _hashes_to_remove.push_back(hash) ; } // -----------------------------------------------------------------------------------// // -------------------------------- Config functions ------------------------------ // // -----------------------------------------------------------------------------------// // RsSerialiser *p3turtle::setupSerialiser() { RsSerialiser *rss = new RsSerialiser ; rss->addSerialType(new RsTurtleSerialiser) ; return rss ; } std::list p3turtle::saveList(bool& cleanup) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: saving list..." << std::endl ; #endif cleanup = true ; std::list lst ; #ifdef TO_REMOVE RsTurtleSearchResultItem *item = new RsTurtleSearchResultItem ; item->PeerId("") ; for(std::map::const_iterator it(_incoming_file_hashes.begin());it!=_incoming_file_hashes.end();++it) { TurtleFileInfo finfo ; finfo.name = it->second.name ; finfo.size = it->second.size ; finfo.hash = it->first ; #ifdef P3TURTLE_DEBUG std::cerr << " Saving item " << finfo.name << ", " << finfo.hash << ", " << finfo.size << std::endl ; #endif item->result.push_back(finfo) ; } lst.push_back(item) ; #endif return lst ; } bool p3turtle::loadList(std::list load) { #ifdef TO_REMOVE #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: loading list..." << std::endl ; #endif for(std::list::const_iterator it(load.begin());it!=load.end();++it) { RsTurtleSearchResultItem *item = dynamic_cast(*it) ; #ifdef P3TURTLE_DEBUG assert(item!=NULL) ; #endif if(item == NULL) continue ; for(std::list::const_iterator it2(item->result.begin());it2!=item->result.end();++it2) { #ifdef P3TURTLE_DEBUG std::cerr << " Restarting tunneling for: " << it2->hash << " " << it2->size << " " << it2->name << std::endl ; #endif monitorFileTunnels(it2->name,it2->hash,it2->size) ; } delete item ; } #endif return true ; } // -----------------------------------------------------------------------------------// // -------------------------------- Helper functions ------------------------------ // // -----------------------------------------------------------------------------------// // uint32_t p3turtle::generateRandomRequestId() { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ static uint64_t s = time(NULL) ; s = s*1664525 + 1013904223 ; // pseudo random number generator from Wikipedia/Numerical Recipies. return (uint32_t)(s & 0x00000000ffffffff) ; } uint32_t p3turtle::generatePersonalFilePrint(const TurtleFileHash& hash,bool b) { // whatever cooking from the file hash and OwnId that cannot be recovered. // The only important thing is that the saem hash produces the same tunnel // id. The result uses a boolean to allow generating non symmetric tunnel ids. std::string buff(hash + mConnMgr->getOwnId()) ; uint32_t res = 0 ; uint32_t decal = 0 ; for(int i=0;i<(int)buff.length();++i) { res += 7*buff[i] + decal ; if(b) decal = decal*44497+15641+(res%86243) ; else decal = decal*86243+15649+(res%44497) ; } return res ; } // -----------------------------------------------------------------------------------// // -------------------------------- Global routing. -------------------------------- // // -----------------------------------------------------------------------------------// // int p3turtle::handleIncoming() { int nhandled = 0; // While messages read // RsItem *item = NULL; while(NULL != (item = recvItem())) { nhandled++; RsTurtleGenericTunnelItem *gti = dynamic_cast(item) ; if(gti != NULL) routeGenericTunnelItem(gti) ; /// Generic packets, that travel through established tunnels. else /// These packets should be destroyed by the client. { /// Special packets that require specific treatment, because tunnels do not exist for these packets. /// These packets are destroyed here, after treatment. // switch(item->PacketSubType()) { case RS_TURTLE_SUBTYPE_STRING_SEARCH_REQUEST: case RS_TURTLE_SUBTYPE_REGEXP_SEARCH_REQUEST: handleSearchRequest(dynamic_cast(item)) ; break ; case RS_TURTLE_SUBTYPE_SEARCH_RESULT : handleSearchResult(dynamic_cast(item)) ; break ; case RS_TURTLE_SUBTYPE_OPEN_TUNNEL : handleTunnelRequest(dynamic_cast(item)) ; break ; case RS_TURTLE_SUBTYPE_TUNNEL_OK : handleTunnelResult(dynamic_cast(item)) ; break ; default: std::cerr << "p3turtle::handleIncoming: Unknown packet subtype " << item->PacketSubType() << std::endl ; } delete item; } } return nhandled; } // -----------------------------------------------------------------------------------// // -------------------------------- Search handling. ------------------------------- // // -----------------------------------------------------------------------------------// // void p3turtle::handleSearchRequest(RsTurtleSearchRequestItem *item) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // take a look at the item: // - If the item destimation is #ifdef P3TURTLE_DEBUG std::cerr << "Received search request from peer " << item->PeerId() << ": " << std::endl ; item->print(std::cerr,0) ; #endif // If the item contains an already handled search request, give up. This // happens when the same search request gets relayed by different peers // if(_search_requests_origins.find(item->request_id) != _search_requests_origins.end()) { #ifdef P3TURTLE_DEBUG std::cerr << " This is a bouncing request. Ignoring and deleting it." << std::endl ; #endif return ; } // This is a new request. Let's add it to the request map, and forward it to // open peers. TurtleRequestInfo& req( _search_requests_origins[item->request_id] ) ; req.origin = item->PeerId() ; req.time_stamp = time(NULL) ; // If it's not for us, perform a local search. If something found, forward the search result back. if(item->PeerId() != mConnMgr->getOwnId()) { #ifdef P3TURTLE_DEBUG std::cerr << " Request not from us. Performing local search" << std::endl ; #endif if(_sharing_strategy != SHARE_FRIENDS_ONLY || item->depth < 2) { std::list result ; item->performLocalSearch(result) ; RsTurtleSearchResultItem *res_item = NULL ; uint32_t item_size = 0 ; #ifdef P3TURTLE_DEBUG if(!result.empty()) std::cerr << " " << result.size() << " matches found. Sending back to origin (" << item->PeerId() << ")." << std::endl ; #endif while(!result.empty()) { // Let's chop search results items into several chunks of finite size to avoid exceeding streamer's capacity. // static const uint32_t RSTURTLE_MAX_SEARCH_RESPONSE_SIZE = 10000 ; if(res_item == NULL) { res_item = new RsTurtleSearchResultItem ; item_size = 0 ; res_item->depth = 0 ; res_item->request_id = item->request_id ; res_item->PeerId(item->PeerId()) ; // send back to the same guy } res_item->result.push_back(result.front()) ; item_size += 8 /* size */ + result.front().hash.size() + result.front().name.size() ; result.pop_front() ; if(item_size > RSTURTLE_MAX_SEARCH_RESPONSE_SIZE || result.empty()) { #ifdef P3TURTLE_DEBUG std::cerr << " Sending back chunk of size " << item_size << ", for " << res_item->result.size() << " elements." << std::endl ; #endif sendItem(res_item) ; res_item = NULL ; } } } #ifdef P3TURTLE_DEBUG else std::cerr << " Rejecting local search because strategy is FRIENDS_ONLY and item depth=" << item->depth << std::endl ; #endif } // If search depth not too large, also forward this search request to all other peers. // if(item->depth < TURTLE_MAX_SEARCH_DEPTH) { std::list onlineIds ; mConnMgr->getOnlineList(onlineIds); #ifdef P3TURTLE_DEBUG std::cerr << " Looking for online peers" << std::endl ; #endif for(std::list::const_iterator it(onlineIds.begin());it!=onlineIds.end();++it) if(*it != item->PeerId()) { #ifdef P3TURTLE_DEBUG std::cerr << " Forwarding request to peer = " << *it << std::endl ; #endif // Copy current item and modify it. RsTurtleSearchRequestItem *fwd_item = item->clone() ; ++(fwd_item->depth) ; // increase search depth fwd_item->PeerId(*it) ; sendItem(fwd_item) ; } } #ifdef P3TURTLE_DEBUG else std::cout << " Dropping this item, as search depth is " << item->depth << std::endl ; #endif } void p3turtle::handleSearchResult(RsTurtleSearchResultItem *item) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // Find who actually sent the corresponding request. // std::map::const_iterator it = _search_requests_origins.find(item->request_id) ; #ifdef P3TURTLE_DEBUG std::cerr << "Received search result:" << std::endl ; item->print(std::cerr,0) ; #endif if(it == _search_requests_origins.end()) { // This is an error: how could we receive a search result corresponding to a search item we // have forwarded but that it not in the list ?? std::cerr << __PRETTY_FUNCTION__ << ": search result has no peer direction!" << std::endl ; return ; } // Is this result's target actually ours ? ++(item->depth) ; // increase depth if(it->second.origin == mConnMgr->getOwnId()) returnSearchResult(item) ; // Yes, so send upward. else { // Nope, so forward it back. #ifdef P3TURTLE_DEBUG std::cerr << " Forwarding result back to " << it->second.origin << std::endl; #endif RsTurtleSearchResultItem *fwd_item = new RsTurtleSearchResultItem(*item) ; // copy the item // Normally here, we should setup the forward adress, so that the owner's // of the files found can be further reached by a tunnel. fwd_item->PeerId(it->second.origin) ; fwd_item->depth = 2 + (rand() % 256) ; // obfuscate the depth for non immediate friends. sendItem(fwd_item) ; } } // -----------------------------------------------------------------------------------// // --------------------------------- File Transfer. -------------------------------- // // -----------------------------------------------------------------------------------// // Routing of turtle tunnel items in a generic manner. Most tunnel packets will use this function, except packets designed for // contructing the tunnels and searching, namely TurtleSearchRequests/Results and OpenTunnel/TunnelOkItems // void p3turtle::routeGenericTunnelItem(RsTurtleGenericTunnelItem *item) { #ifdef P3TURTLE_DEBUG std::cerr << "p3Turtle: treating generic tunnel item:" << std::endl ; item->print(std::cerr,1) ; #endif RsTurtleGenericTunnelItem::Direction direction = item->travelingDirection() ; { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // look for the tunnel id. // std::map::iterator it(_local_tunnels.find(item->tunnelId())) ; if(it == _local_tunnels.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: got file map with unknown tunnel id " << (void*)item->tunnelId() << std::endl ; #endif return ; } TurtleTunnel& tunnel(it->second) ; // Only file data transfer updates tunnels time_stamp field, to avoid maintaining tunnel that are incomplete. if(item->shouldStampTunnel()) tunnel.time_stamp = time(NULL) ; // Let's figure out whether this packet is for us or not. if(direction == RsTurtleGenericTunnelItem::DIRECTION_CLIENT && tunnel.local_src != mConnMgr->getOwnId()) { #ifdef P3TURTLE_DEBUG std::cerr << " Forwarding generic item to peer " << tunnel.local_src << std::endl ; #endif item->PeerId(tunnel.local_src) ; sendItem(item) ; return ; } if(direction == RsTurtleGenericTunnelItem::DIRECTION_SERVER && tunnel.local_dst != mConnMgr->getOwnId()) { #ifdef P3TURTLE_DEBUG std::cerr << " Forwarding generic item to peer " << tunnel.local_dst << std::endl ; #endif item->PeerId(tunnel.local_dst) ; sendItem(item) ; return ; } } // The packet was not forwarded, so it is for us. Let's treat it. // This is done off-mutex, to avoid various deadlocks // switch(item->PacketSubType()) { case RS_TURTLE_SUBTYPE_FILE_REQUEST: handleRecvFileRequest(dynamic_cast(item)) ; break ; case RS_TURTLE_SUBTYPE_FILE_DATA : handleRecvFileData(dynamic_cast(item)) ; break ; case RS_TURTLE_SUBTYPE_FILE_MAP : handleRecvFileMap(dynamic_cast(item)) ; break ; case RS_TURTLE_SUBTYPE_FILE_MAP_REQUEST: handleRecvFileMapRequest(dynamic_cast(item)) ; break ; default: std::cerr << "WARNING: Unknown packet type received: id=" << (void*)(item->PacketSubType()) << ". Is somebody trying to DOS you ?" << std::endl ; #ifdef P3TURTLE_DEBUG exit(-1) ; #endif } delete item ; } void p3turtle::handleRecvFileRequest(RsTurtleFileRequestItem *item) { #ifdef P3TURTLE_DEBUG std::cerr << "p3Turtle: received file request item:" << std::endl ; item->print(std::cerr,1) ; #endif // This is a new request. Let's add it to the request map, and forward it to // open peers. TurtleVirtualPeerId vpid ; uint64_t size ; TurtleFileHash hash ; { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ std::map::iterator it2(_local_tunnels.find(item->tunnel_id)) ; if(it2 == _local_tunnels.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: got file request with unknown tunnel id " << (void*)item->tunnel_id << std::endl ; #endif return ; } TurtleTunnel& tunnel(it2->second) ; std::map::const_iterator it(_outgoing_file_hashes.find(tunnel.hash)) ; #ifdef P3TURTLE_DEBUG assert(!tunnel.hash.empty()) ; assert(it != _outgoing_file_hashes.end()) ; std::cerr << " This is an endpoint for this file request." << std::endl ; std::cerr << " Forwarding data request to the multiplexer." << std::endl ; std::cerr << " using peer_id=" << tunnel.vpid << ", hash=" << tunnel.hash << std::endl ; #endif size = it->second.size ; vpid = tunnel.vpid ; hash = tunnel.hash ; } // This call is voluntarily off-mutex gards because it can cause cross mutex locks with the multiplexer. // (Yeah, this bug was a shity hard one to catch). // _ft_server->getMultiplexer()->recvDataRequest(vpid,hash,size,item->chunk_offset,item->chunk_size) ; } void p3turtle::handleRecvFileData(RsTurtleFileDataItem *item) { #ifdef P3TURTLE_DEBUG std::cerr << "p3Turtle: received file data item:" << std::endl ; item->print(std::cerr,1) ; #endif TurtleVirtualPeerId vpid ; uint64_t size ; TurtleFileHash hash ; { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ std::map::iterator it2(_local_tunnels.find(item->tunnel_id)) ; if(it2 == _local_tunnels.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: got file data with unknown tunnel id " << (void*)item->tunnel_id << std::endl ; #endif return ; } TurtleTunnel& tunnel(it2->second) ; std::map::iterator it( _incoming_file_hashes.find(tunnel.hash) ) ; #ifdef P3TURTLE_DEBUG assert(!tunnel.hash.empty()) ; #endif if(it==_incoming_file_hashes.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "No tunnel for incoming data. Maybe the tunnel is being closed." << std::endl ; #endif return ; } const TurtleFileHashInfo& hash_info(it->second) ; #ifdef P3TURTLE_DEBUG std::cerr << " This is an endpoint for this data chunk." << std::endl ; std::cerr << " Forwarding data to the multiplexer." << std::endl ; std::cerr << " using peer_id=" << tunnel.vpid << ", hash=" << tunnel.hash << std::endl ; #endif //_ft_server->getMultiplexer()->recvData(tunnel.vpid,tunnel.hash,hash_info.size,item->chunk_offset,item->chunk_size,item->chunk_data) ; vpid = tunnel.vpid ; hash = tunnel.hash ; size = hash_info.size ; // also update the hash time stamp to show that it's actually being downloaded. it->second.time_stamp = time(NULL) ; } _ft_server->getMultiplexer()->recvData(vpid,hash,size,item->chunk_offset,item->chunk_size,item->chunk_data) ; item->chunk_data = NULL ; // this prevents deletion in the destructor of RsFileDataItem, because data will be deleted // down _ft_server->getMultiplexer()->recvData()...in ftTransferModule::recvFileData } void p3turtle::handleRecvFileMapRequest(RsTurtleFileMapRequestItem *item) { #ifdef P3TURTLE_DEBUG std::cerr << "p3Turtle: received file Map item:" << std::endl ; item->print(std::cerr,1) ; #endif std::string hash,vpid ; { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ std::map::iterator it2(_local_tunnels.find(item->tunnel_id)) ; if(it2 == _local_tunnels.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: got file data with unknown tunnel id " << (void*)item->tunnel_id << std::endl ; #endif return ; } TurtleTunnel& tunnel(it2->second) ; #ifdef P3TURTLE_DEBUG assert(!tunnel.hash.empty()) ; std::cerr << " This is an endpoint for this file map request." << std::endl ; std::cerr << " Forwarding data to the multiplexer." << std::endl ; std::cerr << " using peer_id=" << tunnel.vpid << ", hash=" << tunnel.hash << std::endl ; #endif // we should check that there is no backward call to the turtle router! // hash = tunnel.hash ; vpid = tunnel.vpid ; } _ft_server->getMultiplexer()->recvChunkMapRequest(vpid,hash,item->direction == RsTurtleGenericTunnelItem::DIRECTION_CLIENT) ; } void p3turtle::handleRecvFileMap(RsTurtleFileMapItem *item) { #ifdef P3TURTLE_DEBUG std::cerr << "p3Turtle: received file Map item:" << std::endl ; item->print(std::cerr,1) ; #endif std::string hash,vpid ; { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ std::map::iterator it2(_local_tunnels.find(item->tunnel_id)) ; if(it2 == _local_tunnels.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: got file data with unknown tunnel id " << (void*)item->tunnel_id << std::endl ; #endif return ; } TurtleTunnel& tunnel(it2->second) ; #ifdef P3TURTLE_DEBUG assert(!tunnel.hash.empty()) ; std::cerr << " This is an endpoint for this file map." << std::endl ; std::cerr << " Forwarding data to the multiplexer." << std::endl ; std::cerr << " using peer_id=" << tunnel.vpid << ", hash=" << tunnel.hash << std::endl ; #endif // We should check that there is no backward call to the turtle router! // vpid = tunnel.vpid ; hash = tunnel.hash ; } _ft_server->getMultiplexer()->recvChunkMap(vpid,hash,item->compressed_map,item->direction == RsTurtleGenericTunnelItem::DIRECTION_CLIENT) ; } // Send a data request into the correct tunnel for the given file hash void p3turtle::sendDataRequest(const std::string& peerId, const std::string& hash, uint64_t, uint64_t offset, uint32_t chunksize) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // get the proper tunnel for this file hash and peer id. std::map::const_iterator it(_virtual_peers.find(peerId)) ; if(it == _virtual_peers.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle::senddataRequest: cannot find virtual peer " << peerId << " in VP list." << std::endl ; #endif return ; } TurtleTunnelId tunnel_id = it->second ; TurtleTunnel& tunnel(_local_tunnels[tunnel_id]) ; #ifdef P3TURTLE_DEBUG assert(hash == tunnel.hash) ; #endif RsTurtleFileRequestItem *item = new RsTurtleFileRequestItem ; item->tunnel_id = tunnel_id ; // we should randomly select a tunnel, or something more clever. item->chunk_offset = offset ; item->chunk_size = chunksize ; item->PeerId(tunnel.local_dst) ; #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: sending file req (chunksize=" << item->chunk_size << ", offset=" << item->chunk_offset << ", hash=0x" << hash << ") through tunnel " << (void*)item->tunnel_id << ", next peer=" << tunnel.local_dst << std::endl ; #endif sendItem(item) ; } // Send file data into the correct tunnel for the given file hash void p3turtle::sendFileData(const std::string& peerId, const std::string& hash, uint64_t, uint64_t offset, uint32_t chunksize, void *data) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // get the proper tunnel for this file hash and peer id. std::map::const_iterator it(_virtual_peers.find(peerId)) ; if(it == _virtual_peers.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle::sendData: cannot find virtual peer " << peerId << " in VP list." << std::endl ; #endif return ; } TurtleTunnelId tunnel_id = it->second ; TurtleTunnel& tunnel(_local_tunnels[tunnel_id]) ; tunnel.time_stamp = time(NULL) ; #ifdef P3TURTLE_DEBUG assert(hash == tunnel.hash) ; #endif RsTurtleFileDataItem *item = new RsTurtleFileDataItem ; item->tunnel_id = tunnel_id ; item->chunk_offset = offset ; item->chunk_size = chunksize ; item->chunk_data = malloc(chunksize) ; if(item->chunk_data == NULL) { std::cerr << "p3turtle: Warning: failed malloc of " << chunksize << " bytes for sending data packet." << std::endl ; return ; } memcpy(item->chunk_data,(void*)((uint8_t*)data),chunksize) ; item->PeerId(tunnel.local_src) ; #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: sending file data (chunksize=" << item->chunk_size << ", offset=" << item->chunk_offset << ", hash=0x" << hash << ") through tunnel " << (void*)item->tunnel_id << ", next peer=" << tunnel.local_src << std::endl ; #endif sendItem(item) ; } void p3turtle::sendChunkMapRequest(const std::string& peerId,const std::string& hash) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // get the proper tunnel for this file hash and peer id. std::map::const_iterator it(_virtual_peers.find(peerId)) ; if(it == _virtual_peers.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle::senddataRequest: cannot find virtual peer " << peerId << " in VP list." << std::endl ; #endif return ; } TurtleTunnelId tunnel_id = it->second ; TurtleTunnel& tunnel(_local_tunnels[tunnel_id]) ; #ifdef P3TURTLE_DEBUG assert(hash == tunnel.hash) ; #endif RsTurtleFileMapRequestItem *item = new RsTurtleFileMapRequestItem ; item->tunnel_id = tunnel_id ; std::string ownid = mConnMgr->getOwnId() ; if(tunnel.local_src == ownid) { item->direction = RsTurtleGenericTunnelItem::DIRECTION_SERVER ; item->PeerId(tunnel.local_dst) ; } else if(tunnel.local_dst == ownid) { item->direction = RsTurtleGenericTunnelItem::DIRECTION_CLIENT ; item->PeerId(tunnel.local_src) ; } else std::cerr << "p3turtle::sendChunkMap: consistency error!" << std::endl ; #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: sending chunk map req to peer " << peerId << ", hash=0x" << hash << ") through tunnel " << (void*)item->tunnel_id << ", next peer=" << item->PeerId() << std::endl ; #endif sendItem(item) ; } void p3turtle::sendChunkMap(const std::string& peerId,const std::string& hash,const CompressedChunkMap& cmap) { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // get the proper tunnel for this file hash and peer id. std::map::const_iterator it(_virtual_peers.find(peerId)) ; if(it == _virtual_peers.end()) { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle::senddataRequest: cannot find virtual peer " << peerId << " in VP list." << std::endl ; #endif return ; } TurtleTunnelId tunnel_id = it->second ; TurtleTunnel& tunnel(_local_tunnels[tunnel_id]) ; #ifdef P3TURTLE_DEBUG assert(hash == tunnel.hash) ; #endif RsTurtleFileMapItem *item = new RsTurtleFileMapItem ; item->tunnel_id = tunnel_id ; item->compressed_map = cmap ; std::string ownid = mConnMgr->getOwnId() ; if(tunnel.local_src == ownid) { item->direction = RsTurtleGenericTunnelItem::DIRECTION_SERVER ; item->PeerId(tunnel.local_dst) ; } else if(tunnel.local_dst == ownid) { item->direction = RsTurtleGenericTunnelItem::DIRECTION_CLIENT ; item->PeerId(tunnel.local_src) ; } else std::cerr << "p3turtle::sendChunkMap: consistency error!" << std::endl ; #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: sending chunk map to peer " << peerId << ", hash=0x" << hash << ") through tunnel " << (void*)item->tunnel_id << ", next peer=" << item->PeerId() << std::endl ; #endif sendItem(item) ; } // This function is actually not needed: Search request to the turtle router are: // - distant search requests, handled by the router // - search requests over files being downloaded, handled by rsFiles !! // //bool p3turtle::search(std::string hash, uint64_t, uint32_t hintflags, FileInfo &info) const //{ // if(! (hintflags & RS_FILE_HINTS_TURTLE)) // this should not happen, but it's a security. // return false; // // RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // //#ifdef P3TURTLE_DEBUG // std::cerr << "p3turtle: received file search request for hash " << hash << "." << std::endl ; //#endif // // std::map::const_iterator it = _incoming_file_hashes.find(hash) ; // // if(_incoming_file_hashes.end() != it) // { // info.fname = it->second.name; // info.size = it->second.size; // info.hash = it->first; // // for(unsigned int i=0;isecond.tunnels.size();++i) // { // TransferInfo ti; // ti.peerId = getTurtlePeerId(it->second.tunnels[i]); // ti.name = "Distant peer for hash=" + hash ; // ti.tfRate = 0; // info.peers.push_back(ti); // } // //#ifdef P3TURTLE_DEBUG // std::cerr << " Found these tunnels for that hash:. "<< std::endl ; // for(unsigned int i=0;isecond.tunnels.size();++i) // std::cerr << " " << (void*)it->second.tunnels[i] << std::endl ; // // std::cerr << " answered yes. "<< std::endl ; //#endif // return true ; // } // else // { //#ifdef P3TURTLE_DEBUG // std::cerr << " responding false." << std::endl ; //#endif // return false ; // } //} bool p3turtle::isTurtlePeer(const std::string& peer_id) const { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ return _virtual_peers.find(peer_id) != _virtual_peers.end() ; } std::string p3turtle::getTurtlePeerId(TurtleTunnelId tid) const { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ std::map::const_iterator it( _local_tunnels.find(tid) ) ; #ifdef P3TURTLE_DEBUG assert(it!=_local_tunnels.end()) ; assert(it->second.vpid != "") ; #endif return it->second.vpid ; } bool p3turtle::isOnline(const std::string& peer_id) const { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // we could do something mre clever here... // return _virtual_peers.find(peer_id) != _virtual_peers.end() ; } // -----------------------------------------------------------------------------------// // -------------------------------- Tunnel handling. ------------------------------- // // -----------------------------------------------------------------------------------// // TurtleRequestId p3turtle::diggTunnel(const TurtleFileHash& hash) { #ifdef P3TURTLE_DEBUG std::cerr << "performing tunnel request. OwnId = " << mConnMgr->getOwnId() << std::endl ; #endif while(mConnMgr->getOwnId() == "") { std::cerr << "... waitting for connect manager to form own id." << std::endl ; #ifdef WIN32 Sleep(1000) ; #else sleep(1) ; #endif } TurtleRequestId id = generateRandomRequestId() ; { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // Store the request id, so that we can find the hash back when we get the response. // _incoming_file_hashes[hash].last_request = id ; } // Form a tunnel request packet that simulates a request from us. // RsTurtleOpenTunnelItem *item = new RsTurtleOpenTunnelItem ; item->PeerId(mConnMgr->getOwnId()) ; item->file_hash = hash ; item->request_id = id ; item->partial_tunnel_id = generatePersonalFilePrint(hash,true) ; item->depth = 0 ; // send it handleTunnelRequest(item) ; delete item ; return id ; } void p3turtle::handleTunnelRequest(RsTurtleOpenTunnelItem *item) { #ifdef P3TURTLE_DEBUG std::cerr << "Received tunnel request from peer " << item->PeerId() << ": " << std::endl ; item->print(std::cerr,0) ; #endif // If the item contains an already handled tunnel request, give up. This // happens when the same tunnel request gets relayed by different peers. We // have to be very careful here, not to call ftController while mTurtleMtx is // locked. // { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ if(_tunnel_requests_origins.find(item->request_id) != _tunnel_requests_origins.end()) { #ifdef P3TURTLE_DEBUG std::cerr << " This is a bouncing request. Ignoring and deleting item." << std::endl ; #endif return ; } // This is a new request. Let's add it to the request map, and forward // it to open peers, while the mutex is locked, so no-one can trigger the // lock before the data is consistent. TurtleRequestInfo& req( _tunnel_requests_origins[item->request_id] ) ; req.origin = item->PeerId() ; req.time_stamp = time(NULL) ; } // If it's not for us, perform a local search. If something found, forward the search result back. // We're off-mutex here. bool found = false ; FileInfo info ; if(item->PeerId() != mConnMgr->getOwnId()) { #ifdef P3TURTLE_DEBUG std::cerr << " Request not from us. Performing local search" << std::endl ; #endif found = (_sharing_strategy != SHARE_FRIENDS_ONLY || item->depth < 2) && performLocalHashSearch(item->file_hash,info) ; } { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ if(found) { #ifdef P3TURTLE_DEBUG std::cerr << " Local hash found. Sending tunnel ok to origin (" << item->PeerId() << ")." << std::endl ; #endif // Send back tunnel ok to the same guy // RsTurtleTunnelOkItem *res_item = new RsTurtleTunnelOkItem ; res_item->request_id = item->request_id ; res_item->tunnel_id = item->partial_tunnel_id ^ generatePersonalFilePrint(item->file_hash,false) ; res_item->PeerId(item->PeerId()) ; sendItem(res_item) ; // Note in the tunnels list that we have an ending tunnel here. TurtleTunnel tt ; tt.local_src = item->PeerId() ; tt.hash = item->file_hash ; tt.local_dst = mConnMgr->getOwnId() ; // this means us tt.time_stamp = time(NULL) ; _local_tunnels[res_item->tunnel_id] = tt ; // We add a virtual peer for that tunnel+hash combination. // addDistantPeer(item->file_hash,res_item->tunnel_id) ; // Store the size of the file, to be able to re-form data requests to the multiplexer. // _outgoing_file_hashes[item->file_hash] = info ; // We return straight, because when something is found, there's no need to digg a tunnel further. return ; } #ifdef P3TURTLE_DEBUG else std::cerr << " No hash found locally, or local file not allowed for distant peers. Forwarding. " << std::endl ; #endif } // If search depth not too large, also forward this search request to all other peers. // if(item->depth < TURTLE_MAX_SEARCH_DEPTH) { std::list onlineIds ; mConnMgr->getOnlineList(onlineIds); #ifdef P3TURTLE_DEBUG std::cerr << " Forwarding tunnel request: Looking for online peers" << std::endl ; #endif for(std::list::const_iterator it(onlineIds.begin());it!=onlineIds.end();++it) if(*it != item->PeerId()) { #ifdef P3TURTLE_DEBUG std::cerr << " Forwarding request to peer = " << *it << std::endl ; #endif // Copy current item and modify it. RsTurtleOpenTunnelItem *fwd_item = new RsTurtleOpenTunnelItem(*item) ; ++(fwd_item->depth) ; // increase tunnel depth fwd_item->PeerId(*it) ; sendItem(fwd_item) ; } } #ifdef P3TURTLE_DEBUG else std::cout << " Dropping this item, as tunnel depth is " << item->depth << std::endl ; #endif } void p3turtle::handleTunnelResult(RsTurtleTunnelOkItem *item) { bool new_tunnel = false ; TurtleFileHash new_hash ; { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ // Find who actually sent the corresponding turtle tunnel request. // std::map::const_iterator it = _tunnel_requests_origins.find(item->request_id) ; #ifdef P3TURTLE_DEBUG std::cerr << "Received tunnel result:" << std::endl ; item->print(std::cerr,0) ; #endif if(it == _tunnel_requests_origins.end()) { // This is an error: how could we receive a tunnel result corresponding to a tunnel item we // have forwarded but that it not in the list ?? std::cerr << __PRETTY_FUNCTION__ << ": tunnel result has no peer direction!" << std::endl ; return ; } // store tunnel info. bool found = (_local_tunnels.find(item->tunnel_id) != _local_tunnels.end()) ; TurtleTunnel& tunnel(_local_tunnels[item->tunnel_id]) ; if(found) { #ifdef P3TURTLE_DEBUG std::cerr << "Tunnel id " << (void*)item->tunnel_id << " is already there. Not storing." << std::endl ; #endif } else { tunnel.local_src = it->second.origin ; tunnel.local_dst = item->PeerId() ; tunnel.hash = "" ; tunnel.time_stamp = time(NULL) ; #ifdef P3TURTLE_DEBUG std::cerr << " storing tunnel info. src=" << tunnel.local_src << ", dst=" << tunnel.local_dst << ", id=" << item->tunnel_id << std::endl ; #endif } // Is this result's target actually ours ? if(it->second.origin == mConnMgr->getOwnId()) { #ifdef P3TURTLE_DEBUG std::cerr << " Tunnel starting point. Storing id=" << (void*)item->tunnel_id << " for hash (unknown) and tunnel request id " << it->second.origin << std::endl; #endif // Tunnel is ending here. Add it to the list of tunnels for the given hash. // 1 - find which file hash issued this request. This is not costly, because there is not too much file hashes to be active // at a time, and this mostly prevents from sending the hash back in the tunnel. bool found = false ; for(std::map::iterator it(_incoming_file_hashes.begin());it!=_incoming_file_hashes.end();++it) if(it->second.last_request == item->request_id) { found = true ; // add the tunnel uniquely bool found = false ; for(unsigned int j=0;jsecond.tunnels.size();++j) if(it->second.tunnels[j] == item->tunnel_id) found = true ; if(!found) it->second.tunnels.push_back(item->tunnel_id) ; tunnel.hash = it->first ; // because it's a local tunnel // Adds a virtual peer to the list of online peers. // We do this later, because of the mutex protection. // new_tunnel = true ; new_hash = it->first ; addDistantPeer(new_hash,item->tunnel_id) ; } if(!found) std::cerr << "p3turtle: error. Could not find hash that emmitted tunnel request " << (void*)item->tunnel_id << std::endl ; } else { // Nope, forward it back. #ifdef P3TURTLE_DEBUG std::cerr << " Forwarding result back to " << it->second.origin << std::endl; #endif RsTurtleTunnelOkItem *fwd_item = new RsTurtleTunnelOkItem(*item) ; // copy the item fwd_item->PeerId(it->second.origin) ; sendItem(fwd_item) ; } } // A new tunnel has been created. Add the corresponding virtual peer to the list, and // notify the file transfer controller for the new file source. This should be done off-mutex // so we deported this code here. // if(new_tunnel) { _ft_controller->addFileSource(new_hash,_local_tunnels[item->tunnel_id].vpid) ; _ft_controller->statusChange(_online_peers) ; } } // -----------------------------------------------------------------------------------// // ------------------------------ IO with libretroshare ----------------------------// // -----------------------------------------------------------------------------------// // void RsTurtleStringSearchRequestItem::performLocalSearch(std::list& result) const { /* call to core */ std::list initialResults; std::list words ; // to do: split search string into words. words.push_back(match_string) ; #ifdef P3TURTLE_DEBUG std::cerr << "Performing rsFiles->search()" << std::endl ; #endif // now, search! rsFiles->SearchKeywords(words, initialResults,DIR_FLAGS_LOCAL | DIR_FLAGS_NETWORK_WIDE); #ifdef P3TURTLE_DEBUG std::cerr << initialResults.size() << " matches found." << std::endl ; #endif result.clear() ; for(std::list::const_iterator it(initialResults.begin());it!=initialResults.end();++it) { // retain only file type if (it->type == DIR_TYPE_DIR) { #ifdef P3TURTLE_DEBUG std::cerr << " Skipping directory " << it->name << std::endl ; #endif continue; } TurtleFileInfo i ; i.hash = it->hash ; i.size = it->count ; i.name = it->name ; result.push_back(i) ; } } void RsTurtleRegExpSearchRequestItem::performLocalSearch(std::list& result) const { /* call to core */ std::list initialResults; // to do: split search string into words. Expression *exp = LinearizedExpression::toExpr(expr) ; // now, search! rsFiles->SearchBoolExp(exp,initialResults,DIR_FLAGS_LOCAL | DIR_FLAGS_NETWORK_WIDE); result.clear() ; for(std::list::const_iterator it(initialResults.begin());it!=initialResults.end();++it) { TurtleFileInfo i ; i.hash = it->hash ; i.size = it->count ; i.name = it->name ; result.push_back(i) ; } delete exp ; } TurtleRequestId p3turtle::turtleSearch(const std::string& string_to_match) { // generate a new search id. TurtleRequestId id = generateRandomRequestId() ; // Form a request packet that simulates a request from us. // RsTurtleStringSearchRequestItem *item = new RsTurtleStringSearchRequestItem ; #ifdef P3TURTLE_DEBUG std::cerr << "performing search. OwnId = " << mConnMgr->getOwnId() << std::endl ; #endif while(mConnMgr->getOwnId() == "") { std::cerr << "... waitting for connect manager to form own id." << std::endl ; #ifdef WIN32 Sleep(1000) ; #else sleep(1) ; #endif } item->PeerId(mConnMgr->getOwnId()) ; item->match_string = string_to_match ; item->request_id = id ; item->depth = 0 ; // send it handleSearchRequest(item) ; delete item ; return id ; } TurtleRequestId p3turtle::turtleSearch(const LinearizedExpression& expr) { // generate a new search id. TurtleRequestId id = generateRandomRequestId() ; // Form a request packet that simulates a request from us. // RsTurtleRegExpSearchRequestItem *item = new RsTurtleRegExpSearchRequestItem ; #ifdef P3TURTLE_DEBUG std::cerr << "performing search. OwnId = " << mConnMgr->getOwnId() << std::endl ; #endif while(mConnMgr->getOwnId() == "") { std::cerr << "... waitting for connect manager to form own id." << std::endl ; #ifdef WIN32 Sleep(1000) ; #else sleep(1) ; #endif } item->PeerId(mConnMgr->getOwnId()) ; item->expr = expr ; item->request_id = id ; item->depth = 0 ; // send it handleSearchRequest(item) ; delete item ; return id ; } void p3turtle::monitorFileTunnels(const std::string& name,const std::string& file_hash,uint64_t size) { { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ if(_incoming_file_hashes.find(file_hash) != _incoming_file_hashes.end()) // download already asked. { #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: File hash " << file_hash << " already in pool. Returning." << std::endl ; #endif return ; } #ifdef P3TURTLE_DEBUG std::cerr << "p3turtle: Received order for turtle download fo hash " << file_hash << std::endl ; #endif // No tunnels at start, but this triggers digging new tunnels. // _incoming_file_hashes[file_hash].tunnels.clear(); _force_digg_new_tunnels = true ; // also should send associated request to the file transfer module. _incoming_file_hashes[file_hash].size = size ; _incoming_file_hashes[file_hash].name = name ; _incoming_file_hashes[file_hash].time_stamp = time(NULL) ; } IndicateConfigChanged() ; // initiates saving of handled hashes. } void p3turtle::returnSearchResult(RsTurtleSearchResultItem *item) { // just cout for now, but it should be notified to the gui #ifdef P3TURTLE_DEBUG std::cerr << " Returning result for search request " << (void*)item->request_id << " upwards." << std::endl ; #endif rsicontrol->getNotify().notifyTurtleSearchResult(item->request_id,item->result) ; } /// Warning: this function should never be called while the turtle mutex is locked. /// Otherwize this is a possible source of cross-lock with the File mutex. // bool p3turtle::performLocalHashSearch(const TurtleFileHash& hash,FileInfo& info) { return rsFiles->FileDetails(hash, RS_FILE_HINTS_LOCAL | RS_FILE_HINTS_EXTRA | RS_FILE_HINTS_SPEC_ONLY | RS_FILE_HINTS_DOWNLOAD, info); } static std::string printNumber(uint64_t num,bool hex=false) { if(hex) { char tmp[100] ; if(num < (((uint64_t)1)<<32)) sprintf(tmp,"%08x", uint32_t(num)) ; else sprintf(tmp,"%08x%08x", uint32_t(num >> 32),uint32_t(num & ( (1<<32)-1 ))) ; return std::string(tmp) ; } else { std::ostringstream out ; out << num ; return out.str() ; } } void p3turtle::getInfo( std::vector >& hashes_info, std::vector >& tunnels_info, std::vector >& search_reqs_info, std::vector >& tunnel_reqs_info) const { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ time_t now = time(NULL) ; hashes_info.clear() ; for(std::map::const_iterator it(_incoming_file_hashes.begin());it!=_incoming_file_hashes.end();++it) { hashes_info.push_back(std::vector()) ; std::vector& hashes(hashes_info.back()) ; hashes.push_back(it->first) ; hashes.push_back(it->second.name) ; hashes.push_back(printNumber(it->second.tunnels.size())) ; hashes.push_back(printNumber(now - it->second.time_stamp)+" secs ago") ; } #ifdef A_VOIR for(std::map::const_iterator it(_outgoing_file_hashes.begin());it!=_outgoing_file_hashes.end();++it) std::cerr << " hash=0x" << it->first << ", name=" << it->second.fname << ", size=" << it->second.size << std::endl ; #endif tunnels_info.clear(); for(std::map::const_iterator it(_local_tunnels.begin());it!=_local_tunnels.end();++it) { tunnels_info.push_back(std::vector()) ; std::vector& tunnel(tunnels_info.back()) ; tunnel.push_back(printNumber(it->first,true)) ; RsPeerDetails sslDetails; rsPeers->getPeerDetails(it->second.local_src,sslDetails) ; tunnel.push_back(sslDetails.name + " - " + sslDetails.location) ; rsPeers->getPeerDetails(it->second.local_dst,sslDetails) ; tunnel.push_back(sslDetails.name + " - " + sslDetails.location) ; tunnel.push_back(it->second.hash) ; tunnel.push_back(printNumber(now-it->second.time_stamp) + " secs ago") ; } search_reqs_info.clear(); for(std::map::const_iterator it(_search_requests_origins.begin());it!=_search_requests_origins.end();++it) { search_reqs_info.push_back(std::vector()) ; std::vector& search_req(search_reqs_info.back()) ; search_req.push_back(printNumber(it->first,true)) ; RsPeerDetails sslDetails; rsPeers->getPeerDetails(it->second.origin,sslDetails) ; search_req.push_back(sslDetails.name + " - " + sslDetails.location) ; search_req.push_back(printNumber(now - it->second.time_stamp) + " secs ago") ; } tunnel_reqs_info.clear(); for(std::map::const_iterator it(_tunnel_requests_origins.begin());it!=_tunnel_requests_origins.end();++it) { tunnel_reqs_info.push_back(std::vector()) ; std::vector& tunnel_req(tunnel_reqs_info.back()) ; tunnel_req.push_back(printNumber(it->first,true)) ; RsPeerDetails sslDetails; rsPeers->getPeerDetails(it->second.origin,sslDetails) ; tunnel_req.push_back(sslDetails.name + " - " + sslDetails.location) ; tunnel_req.push_back(printNumber(now - it->second.time_stamp) + " secs ago") ; } } #ifdef P3TURTLE_DEBUG void p3turtle::dumpState() { RsStackMutex stack(mTurtleMtx); /********** STACK LOCKED MTX ******/ time_t now = time(NULL) ; std::cerr << std::endl ; std::cerr << "********************** Turtle router dump ******************" << std::endl ; std::cerr << " Active incoming file hashes: " << _incoming_file_hashes.size() << std::endl ; for(std::map::const_iterator it(_incoming_file_hashes.begin());it!=_incoming_file_hashes.end();++it) { std::cerr << " hash=0x" << it->first << ", name=" << it->second.name << ", size=" << it->second.size << ", tunnel ids =" ; for(std::vector::const_iterator it2(it->second.tunnels.begin());it2!=it->second.tunnels.end();++it2) std::cerr << " " << (void*)*it2 ; std::cerr << ", last_req=" << (void*)it->second.last_request << ", time_stamp = " << it->second.time_stamp << "(" << now-it->second.time_stamp << " secs ago)" << std::endl ; } std::cerr << " Active outgoing file hashes: " << _outgoing_file_hashes.size() << std::endl ; for(std::map::const_iterator it(_outgoing_file_hashes.begin());it!=_outgoing_file_hashes.end();++it) std::cerr << " hash=0x" << it->first << ", name=" << it->second.fname << ", size=" << it->second.size << std::endl ; std::cerr << " Local tunnels:" << std::endl ; for(std::map::const_iterator it(_local_tunnels.begin());it!=_local_tunnels.end();++it) std::cerr << " " << (void*)it->first << ": from=" << it->second.local_src << ", to=" << it->second.local_dst << ", hash=0x" << it->second.hash << ", ts=" << it->second.time_stamp << " (" << now-it->second.time_stamp << " secs ago)" << ", peer id =" << it->second.vpid << std::endl ; std::cerr << " buffered request origins: " << std::endl ; std::cerr << " Search requests: " << _search_requests_origins.size() << std::endl ; for(std::map::const_iterator it(_search_requests_origins.begin());it!=_search_requests_origins.end();++it) std::cerr << " " << (void*)it->first << ": from=" << it->second.origin << ", ts=" << it->second.time_stamp << " (" << now-it->second.time_stamp << " secs ago)" << std::endl ; std::cerr << " Tunnel requests: " << _tunnel_requests_origins.size() << std::endl ; for(std::map::const_iterator it(_tunnel_requests_origins.begin());it!=_tunnel_requests_origins.end();++it) std::cerr << " " << (void*)it->first << ": from=" << it->second.origin << ", ts=" << it->second.time_stamp << " (" << now-it->second.time_stamp << " secs ago)" << std::endl ; std::cerr << " Virtual peers:" << std::endl ; for(std::map::const_iterator it(_virtual_peers.begin());it!=_virtual_peers.end();++it) std::cerr << " id=" << it->first << ", tunnel=" << (void*)(it->second) << std::endl ; std::cerr << " Online peers: " << std::endl ; for(std::list::const_iterator it(_online_peers.begin());it!=_online_peers.end();++it) std::cerr << " id=" << it->id << ", name=" << it->name << ", state=" << it->state << ", actions=" << it->actions << std::endl ; } #endif