/* * ZeroTier One - Global Peer to Peer Ethernet * Copyright (C) 2011-2014 ZeroTier Networks LLC * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * * -- * * ZeroTier may be used and distributed under the terms of the GPLv3, which * are available at: http://www.gnu.org/licenses/gpl-3.0.html * * If you would like to embed ZeroTier into a commercial application or * redistribute it in a modified binary form, please contact ZeroTier Networks * LLC. Start here: http://www.zerotier.com/ */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../node/Constants.hpp" #include "WindowsEthernetTap.hpp" #include "WindowsEthernetTapFactory.hpp" #include "../node/Utils.hpp" #include "../node/Mutex.hpp" #include "..\windows\TapDriver\tap-windows.h" // ff:ff:ff:ff:ff:ff with no ADI static const ZeroTier::MulticastGroup _blindWildcardMulticastGroup(ZeroTier::MAC(0xff),0); #define ZT_WINDOWS_CREATE_FAKE_DEFAULT_ROUTE namespace ZeroTier { // Only create or delete devices one at a time static Mutex _systemTapInitLock; WindowsEthernetTap::WindowsEthernetTap( const char *pathToHelpers, const MAC &mac, unsigned int mtu, unsigned int metric, uint64_t nwid, const char *desiredDevice, const char *friendlyName, void (*handler)(void *,const MAC &,const MAC &,unsigned int,const Buffer<4096> &), void *arg) : EthernetTap("WindowsEthernetTap",mac,mtu,metric), _handler(handler), _arg(arg), _nwid(nwid), _tap(INVALID_HANDLE_VALUE), _injectSemaphore(INVALID_HANDLE_VALUE), _pathToHelpers(pathToHelpers), _run(true), _initialized(false), _enabled(true) { char subkeyName[4096]; char subkeyClass[4096]; char data[4096]; char tag[24]; if (mtu > 2800) throw std::runtime_error("MTU too large for Windows tap"); Mutex::Lock _l(_systemTapInitLock); HKEY nwAdapters; if (RegOpenKeyExA(HKEY_LOCAL_MACHINE,"SYSTEM\\CurrentControlSet\\Control\\Class\\{4D36E972-E325-11CE-BFC1-08002BE10318}",0,KEY_READ|KEY_WRITE,&nwAdapters) != ERROR_SUCCESS) throw std::runtime_error("unable to open registry key for network adapter enumeration"); std::set existingDeviceInstances; std::string mySubkeyName; // We "tag" registry entries with the network ID to identify persistent devices Utils::snprintf(tag,sizeof(tag),"%.16llx",(unsigned long long)nwid); // Look for the tap instance that corresponds with this network for(DWORD subkeyIndex=0;;++subkeyIndex) { DWORD type; DWORD dataLen; DWORD subkeyNameLen = sizeof(subkeyName); DWORD subkeyClassLen = sizeof(subkeyClass); FILETIME lastWriteTime; if (RegEnumKeyExA(nwAdapters,subkeyIndex,subkeyName,&subkeyNameLen,(DWORD *)0,subkeyClass,&subkeyClassLen,&lastWriteTime) == ERROR_SUCCESS) { type = 0; dataLen = sizeof(data); if (RegGetValueA(nwAdapters,subkeyName,"ComponentId",RRF_RT_ANY,&type,(PVOID)data,&dataLen) == ERROR_SUCCESS) { data[dataLen] = '\0'; if (!strnicmp(data,"zttap",5)) { std::string instanceId; type = 0; dataLen = sizeof(data); if (RegGetValueA(nwAdapters,subkeyName,"NetCfgInstanceId",RRF_RT_ANY,&type,(PVOID)data,&dataLen) == ERROR_SUCCESS) { instanceId.assign(data,dataLen); existingDeviceInstances.insert(instanceId); } std::string instanceIdPath; type = 0; dataLen = sizeof(data); if (RegGetValueA(nwAdapters,subkeyName,"DeviceInstanceID",RRF_RT_ANY,&type,(PVOID)data,&dataLen) == ERROR_SUCCESS) instanceIdPath.assign(data,dataLen); if ((_netCfgInstanceId.length() == 0)&&(instanceId.length() != 0)&&(instanceIdPath.length() != 0)) { type = 0; dataLen = sizeof(data); if (RegGetValueA(nwAdapters,subkeyName,"_ZeroTierTapIdentifier",RRF_RT_ANY,&type,(PVOID)data,&dataLen) == ERROR_SUCCESS) { data[dataLen] = '\0'; if (!strcmp(data,tag)) { _netCfgInstanceId = instanceId; _deviceInstanceId = instanceIdPath; mySubkeyName = subkeyName; break; // found it! } } } } } } else break; // no more subkeys or error occurred enumerating them } // If there is no device, try to create one bool creatingNewDevice = (_netCfgInstanceId.length() == 0); if (creatingNewDevice) { // Log devcon output to a file HANDLE devconLog = CreateFileA((_pathToHelpers + "\\devcon.log").c_str(),GENERIC_WRITE,FILE_SHARE_READ|FILE_SHARE_WRITE,NULL,OPEN_ALWAYS,FILE_ATTRIBUTE_NORMAL,NULL); if (devconLog != INVALID_HANDLE_VALUE) SetFilePointer(devconLog,0,0,FILE_END); // Execute devcon to install an instance of the Microsoft Loopback Adapter STARTUPINFOA startupInfo; startupInfo.cb = sizeof(startupInfo); if (devconLog != INVALID_HANDLE_VALUE) { SetFilePointer(devconLog,0,0,FILE_END); startupInfo.hStdOutput = devconLog; startupInfo.hStdError = devconLog; } PROCESS_INFORMATION processInfo; memset(&startupInfo,0,sizeof(STARTUPINFOA)); memset(&processInfo,0,sizeof(PROCESS_INFORMATION)); if (!CreateProcessA(NULL,(LPSTR)(std::string("\"") + _pathToHelpers + WindowsEthernetTapFactory::WINENV.devcon + "\" install \"" + _pathToHelpers + WindowsEthernetTapFactory::WINENV.tapDriver + "\" zttap200").c_str(),NULL,NULL,FALSE,0,NULL,NULL,&startupInfo,&processInfo)) { RegCloseKey(nwAdapters); if (devconLog != INVALID_HANDLE_VALUE) CloseHandle(devconLog); throw std::runtime_error(std::string("unable to find or execute devcon at ") + WindowsEthernetTapFactory::WINENV.devcon); } WaitForSingleObject(processInfo.hProcess,INFINITE); CloseHandle(processInfo.hProcess); CloseHandle(processInfo.hThread); if (devconLog != INVALID_HANDLE_VALUE) CloseHandle(devconLog); // Scan for the new instance by simply looking for taps that weren't originally there... for(DWORD subkeyIndex=0;;++subkeyIndex) { DWORD type; DWORD dataLen; DWORD subkeyNameLen = sizeof(subkeyName); DWORD subkeyClassLen = sizeof(subkeyClass); FILETIME lastWriteTime; if (RegEnumKeyExA(nwAdapters,subkeyIndex,subkeyName,&subkeyNameLen,(DWORD *)0,subkeyClass,&subkeyClassLen,&lastWriteTime) == ERROR_SUCCESS) { type = 0; dataLen = sizeof(data); if (RegGetValueA(nwAdapters,subkeyName,"ComponentId",RRF_RT_ANY,&type,(PVOID)data,&dataLen) == ERROR_SUCCESS) { data[dataLen] = '\0'; if (!strnicmp(data,"zttap",5)) { type = 0; dataLen = sizeof(data); if (RegGetValueA(nwAdapters,subkeyName,"NetCfgInstanceId",RRF_RT_ANY,&type,(PVOID)data,&dataLen) == ERROR_SUCCESS) { if (existingDeviceInstances.count(std::string(data,dataLen)) == 0) { RegSetKeyValueA(nwAdapters,subkeyName,"_ZeroTierTapIdentifier",REG_SZ,tag,(DWORD)(strlen(tag)+1)); _netCfgInstanceId.assign(data,dataLen); type = 0; dataLen = sizeof(data); if (RegGetValueA(nwAdapters,subkeyName,"DeviceInstanceID",RRF_RT_ANY,&type,(PVOID)data,&dataLen) == ERROR_SUCCESS) _deviceInstanceId.assign(data,dataLen); mySubkeyName = subkeyName; // Disable DHCP by default on newly created devices HKEY tcpIpInterfaces; if (RegOpenKeyExA(HKEY_LOCAL_MACHINE,"SYSTEM\\CurrentControlSet\\services\\Tcpip\\Parameters\\Interfaces",0,KEY_READ|KEY_WRITE,&tcpIpInterfaces) == ERROR_SUCCESS) { DWORD enable = 0; RegSetKeyValueA(tcpIpInterfaces,_netCfgInstanceId.c_str(),"EnableDHCP",REG_DWORD,&enable,sizeof(enable)); RegCloseKey(tcpIpInterfaces); } break; // found it! } } } } } else break; // no more keys or error occurred } } if (_netCfgInstanceId.length() > 0) { char tmps[64]; unsigned int tmpsl = Utils::snprintf(tmps,sizeof(tmps),"%.2X-%.2X-%.2X-%.2X-%.2X-%.2X",(unsigned int)mac[0],(unsigned int)mac[1],(unsigned int)mac[2],(unsigned int)mac[3],(unsigned int)mac[4],(unsigned int)mac[5]) + 1; RegSetKeyValueA(nwAdapters,mySubkeyName.c_str(),"NetworkAddress",REG_SZ,tmps,tmpsl); RegSetKeyValueA(nwAdapters,mySubkeyName.c_str(),"MAC",REG_SZ,tmps,tmpsl); DWORD tmp = mtu; RegSetKeyValueA(nwAdapters,mySubkeyName.c_str(),"MTU",REG_DWORD,(LPCVOID)&tmp,sizeof(tmp)); //tmp = NDIS_DEVICE_TYPE_ENDPOINT; tmp = 0; RegSetKeyValueA(nwAdapters,mySubkeyName.c_str(),"*NdisDeviceType",REG_DWORD,(LPCVOID)&tmp,sizeof(tmp)); tmp = IF_TYPE_ETHERNET_CSMACD; RegSetKeyValueA(nwAdapters,mySubkeyName.c_str(),"*IfType",REG_DWORD,(LPCVOID)&tmp,sizeof(tmp)); if (creatingNewDevice) { tmp = 0; RegSetKeyValueA(nwAdapters,mySubkeyName.c_str(),"EnableDHCP",REG_DWORD,(LPCVOID)&tmp,sizeof(tmp)); } RegCloseKey(nwAdapters); } else { RegCloseKey(nwAdapters); throw std::runtime_error("unable to find or create tap adapter"); } // Convert device GUID junk... blech... is there an easier way to do this? { char nobraces[128]; const char *nbtmp1 = _netCfgInstanceId.c_str(); char *nbtmp2 = nobraces; while (*nbtmp1) { if ((*nbtmp1 != '{')&&(*nbtmp1 != '}')) *nbtmp2++ = *nbtmp1; ++nbtmp1; } *nbtmp2 = (char)0; if (UuidFromStringA((RPC_CSTR)nobraces,&_deviceGuid) != RPC_S_OK) throw std::runtime_error("unable to convert instance ID GUID to native GUID (invalid NetCfgInstanceId in registry?)"); } // Look up interface LUID... why are there (at least) four fucking ways to refer to a network device in Windows? if (ConvertInterfaceGuidToLuid(&_deviceGuid,&_deviceLuid) != NO_ERROR) throw std::runtime_error("unable to convert device interface GUID to LUID"); if (friendlyName) setFriendlyName(friendlyName); // Start background thread that actually performs I/O _injectSemaphore = CreateSemaphore(NULL,0,1,NULL); _thread = Thread::start(this); // Certain functions can now work (e.g. ips()) _initialized = true; } WindowsEthernetTap::~WindowsEthernetTap() { _run = false; ReleaseSemaphore(_injectSemaphore,1,NULL); Thread::join(_thread); CloseHandle(_injectSemaphore); _disableTapDevice(); } void WindowsEthernetTap::setEnabled(bool en) { _enabled = en; } bool WindowsEthernetTap::enabled() const { return _enabled; } bool WindowsEthernetTap::addIP(const InetAddress &ip) { if (!_initialized) return false; if (!ip.netmaskBits()) // sanity check... netmask of 0.0.0.0 is WUT? return false; std::set haveIps(ips()); try { // Add IP to interface at the netlink level if not already assigned. if (!haveIps.count(ip)) { MIB_UNICASTIPADDRESS_ROW ipr; InitializeUnicastIpAddressEntry(&ipr); if (ip.isV4()) { ipr.Address.Ipv4.sin_family = AF_INET; ipr.Address.Ipv4.sin_addr.S_un.S_addr = *((const uint32_t *)ip.rawIpData()); ipr.OnLinkPrefixLength = ip.port(); if (ipr.OnLinkPrefixLength >= 32) return false; } else if (ip.isV6()) { ipr.Address.Ipv6.sin6_family = AF_INET6; memcpy(ipr.Address.Ipv6.sin6_addr.u.Byte,ip.rawIpData(),16); ipr.OnLinkPrefixLength = ip.port(); if (ipr.OnLinkPrefixLength >= 128) return false; } else return false; ipr.PrefixOrigin = IpPrefixOriginManual; ipr.SuffixOrigin = IpSuffixOriginManual; ipr.ValidLifetime = 0xffffffff; ipr.PreferredLifetime = 0xffffffff; ipr.InterfaceLuid = _deviceLuid; ipr.InterfaceIndex = _getDeviceIndex(); if (CreateUnicastIpAddressEntry(&ipr) == NO_ERROR) { haveIps.insert(ip); } else { return false; } } std::vector regIps(_getRegistryIPv4Value("IPAddress")); if (std::find(regIps.begin(),regIps.end(),ip.toIpString()) == regIps.end()) { std::vector regSubnetMasks(_getRegistryIPv4Value("SubnetMask")); regIps.push_back(ip.toIpString()); regSubnetMasks.push_back(ip.netmask().toIpString()); _setRegistryIPv4Value("IPAddress",regIps); _setRegistryIPv4Value("SubnetMask",regSubnetMasks); } //_syncIpsWithRegistry(haveIps,_netCfgInstanceId); } catch ( ... ) { return false; } return true; } bool WindowsEthernetTap::removeIP(const InetAddress &ip) { if (!_initialized) return false; try { MIB_UNICASTIPADDRESS_TABLE *ipt = (MIB_UNICASTIPADDRESS_TABLE *)0; if (GetUnicastIpAddressTable(AF_UNSPEC,&ipt) == NO_ERROR) { for(DWORD i=0;iNumEntries;++i) { if (ipt->Table[i].InterfaceLuid.Value == _deviceLuid.Value) { InetAddress addr; switch(ipt->Table[i].Address.si_family) { case AF_INET: addr.set(&(ipt->Table[i].Address.Ipv4.sin_addr.S_un.S_addr),4,ipt->Table[i].OnLinkPrefixLength); break; case AF_INET6: addr.set(ipt->Table[i].Address.Ipv6.sin6_addr.u.Byte,16,ipt->Table[i].OnLinkPrefixLength); if (addr.isLinkLocal()) continue; // can't remove link-local IPv6 addresses break; } if (addr == ip) { DeleteUnicastIpAddressEntry(&(ipt->Table[i])); FreeMibTable(ipt); std::vector regIps(_getRegistryIPv4Value("IPAddress")); std::vector regSubnetMasks(_getRegistryIPv4Value("SubnetMask")); std::string ipstr(ip.toIpString()); for(std::vector::iterator rip(regIps.begin()),rm(regSubnetMasks.begin());((rip!=regIps.end())&&(rm!=regSubnetMasks.end()));++rip,++rm) { if (*rip == ipstr) { regIps.erase(rip); regSubnetMasks.erase(rm); _setRegistryIPv4Value("IPAddress",regIps); _setRegistryIPv4Value("SubnetMask",regSubnetMasks); break; } } return true; } } } FreeMibTable((PVOID)ipt); } } catch ( ... ) {} return false; } std::set WindowsEthernetTap::ips() const { static const InetAddress linkLocalLoopback("fe80::1",64); // what is this and why does Windows assign it? std::set addrs; if (!_initialized) return addrs; try { MIB_UNICASTIPADDRESS_TABLE *ipt = (MIB_UNICASTIPADDRESS_TABLE *)0; if (GetUnicastIpAddressTable(AF_UNSPEC,&ipt) == NO_ERROR) { for(DWORD i=0;iNumEntries;++i) { if (ipt->Table[i].InterfaceLuid.Value == _deviceLuid.Value) { switch(ipt->Table[i].Address.si_family) { case AF_INET: { InetAddress ip(&(ipt->Table[i].Address.Ipv4.sin_addr.S_un.S_addr),4,ipt->Table[i].OnLinkPrefixLength); if (ip != InetAddress::LO4) addrs.insert(ip); } break; case AF_INET6: { InetAddress ip(ipt->Table[i].Address.Ipv6.sin6_addr.u.Byte,16,ipt->Table[i].OnLinkPrefixLength); if ((ip != linkLocalLoopback)&&(ip != InetAddress::LO6)) addrs.insert(ip); } break; } } } FreeMibTable(ipt); } } catch ( ... ) {} // sanity check, shouldn't happen unless out of memory return addrs; } void WindowsEthernetTap::put(const MAC &from,const MAC &to,unsigned int etherType,const void *data,unsigned int len) { if ((!_initialized)||(!_enabled)||(_tap == INVALID_HANDLE_VALUE)||(len > (ZT_IF_MTU))) return; Mutex::Lock _l(_injectPending_m); _injectPending.push( std::pair,unsigned int>(Array(),len + 14) ); char *d = _injectPending.back().first.data; to.copyTo(d,6); from.copyTo(d + 6,6); d[12] = (char)((etherType >> 8) & 0xff); d[13] = (char)(etherType & 0xff); memcpy(d + 14,data,len); ReleaseSemaphore(_injectSemaphore,1,NULL); } std::string WindowsEthernetTap::deviceName() const { char tmp[1024]; if (ConvertInterfaceLuidToNameA(&_deviceLuid,tmp,sizeof(tmp)) != NO_ERROR) return std::string("[ConvertInterfaceLuidToName() failed]"); return std::string(tmp); } void WindowsEthernetTap::setFriendlyName(const char *dn) { if (!_initialized) return; HKEY ifp; if (RegOpenKeyExA(HKEY_LOCAL_MACHINE,(std::string("SYSTEM\\CurrentControlSet\\Control\\Network\\{4D36E972-E325-11CE-BFC1-08002BE10318}\\") + _netCfgInstanceId).c_str(),0,KEY_READ|KEY_WRITE,&ifp) == ERROR_SUCCESS) { RegSetKeyValueA(ifp,"Connection","Name",REG_SZ,(LPCVOID)dn,(DWORD)(strlen(dn)+1)); RegCloseKey(ifp); } } bool WindowsEthernetTap::updateMulticastGroups(std::set &groups) { if (!_initialized) return false; HANDLE t = _tap; if (t == INVALID_HANDLE_VALUE) return false; std::set newGroups; // Ensure that groups are added for each IP... this handles the MAC:ADI // groups that are created from IPv4 addresses. Some of these may end // up being duplicates of what the IOCTL returns but that's okay since // the set<> will filter that. std::set ipaddrs(ips()); for(std::set::const_iterator i(ipaddrs.begin());i!=ipaddrs.end();++i) newGroups.insert(MulticastGroup::deriveMulticastGroupForAddressResolution(*i)); // The ZT1 tap driver supports an IOCTL to get multicast memberships at the L2 // level... something Windows does not seem to expose ordinarily. This lets // pretty much anything work... IPv4, IPv6, IPX, oldskool Netbios, who knows... unsigned char mcastbuf[TAP_WIN_IOCTL_GET_MULTICAST_MEMBERSHIPS_OUTPUT_BUF_SIZE]; DWORD bytesReturned = 0; if (DeviceIoControl(t,TAP_WIN_IOCTL_GET_MULTICAST_MEMBERSHIPS,(LPVOID)0,0,(LPVOID)mcastbuf,sizeof(mcastbuf),&bytesReturned,NULL)) { MAC mac; DWORD i = 0; while ((i + 6) <= bytesReturned) { mac.setTo(mcastbuf + i,6); i += 6; if ((mac.isMulticast())&&(!mac.isBroadcast())) { // exclude the nulls that may be returned or any other junk Windows puts in there newGroups.insert(MulticastGroup(mac,0)); } } } bool changed = false; for(std::set::iterator mg(newGroups.begin());mg!=newGroups.end();++mg) { if (!groups.count(*mg)) { groups.insert(*mg); changed = true; } } for(std::set::iterator mg(groups.begin());mg!=groups.end();) { if ((!newGroups.count(*mg))&&(*mg != _blindWildcardMulticastGroup)) { groups.erase(mg++); changed = true; } else ++mg; } return changed; } void WindowsEthernetTap::threadMain() throw() { char tapPath[256]; OVERLAPPED tapOvlRead,tapOvlWrite; HANDLE wait4[3]; char *tapReadBuf = (char *)0; // Shouldn't be needed, but Windows does not overcommit. This Windows // tap code is defensive to schizoid paranoia degrees. while (!tapReadBuf) { tapReadBuf = (char *)::malloc(ZT_IF_MTU + 32); if (!tapReadBuf) Sleep(1000); } // Tap is in this weird Windows global pseudo file space Utils::snprintf(tapPath,sizeof(tapPath),"\\\\.\\Global\\%s.tap",_netCfgInstanceId.c_str()); /* More insanity: repetatively try to enable/disable tap device. The first * time we succeed, close it and do it again. This is to fix a driver init * bug that seems to be extremely non-deterministic and to only occur after * headless MSI upgrade. It cannot be reproduced in any other circumstance. * * Eventually when ZeroTier has actual money we will have someone create an * NDIS6 tap driver. Yes, we'll likely be cool and open source it. */ bool throwOneAway = true; while (_run) { _disableTapDevice(); Sleep(250); if (!_enableTapDevice()) { ::free(tapReadBuf); _enabled = false; return; // only happens if devcon is missing or totally fails } Sleep(250); _tap = CreateFileA(tapPath,GENERIC_READ|GENERIC_WRITE,0,NULL,OPEN_EXISTING,FILE_ATTRIBUTE_SYSTEM|FILE_FLAG_OVERLAPPED,NULL); if (_tap == INVALID_HANDLE_VALUE) { Sleep(500); continue; } uint32_t tmpi = 1; DWORD bytesReturned = 0; DeviceIoControl(_tap,TAP_WIN_IOCTL_SET_MEDIA_STATUS,&tmpi,sizeof(tmpi),&tmpi,sizeof(tmpi),&bytesReturned,NULL); if (throwOneAway) { throwOneAway = false; CloseHandle(_tap); _tap = INVALID_HANDLE_VALUE; Sleep(250); continue; } else break; } /* code not currently used, but keep it around cause it was hard to figure out... CoInitializeEx(NULL,COINIT_MULTITHREADED); CComPtr nlm; nlm.CoCreateInstance(CLSID_NetworkListManager); if (nlm) { for(int i=0;i<8;++i) { // wait up to 8s for the NLM (network awareness) to find and initialize its awareness of our new network CComPtr nlmNets; bool foundMyNet = false; if (SUCCEEDED(nlm->GetNetworks(NLM_ENUM_NETWORK_ALL,&nlmNets))) { DWORD dwReturn = 0; while (!foundMyNet) { CComPtr nlmNet; HRESULT hr = nlmNets->Next(1,&nlmNet,&dwReturn); if ((hr == S_OK)&&(dwReturn > 0)&&(nlmNet)) { CComPtr nlmNetConns; if (SUCCEEDED(nlmNet->GetNetworkConnections(&nlmNetConns))) { for(;;) { CComPtr nlmNetConn; hr = nlmNetConns->Next(1,&nlmNetConn,&dwReturn); if ((hr == S_OK)&&(dwReturn > 0)&&(nlmNetConn)) { GUID netAdapterId; nlmNetConn->GetAdapterId(&netAdapterId); if (netAdapterId == _deviceGuid) { foundMyNet = true; printf("*** Found my net!\n"); nlmNet->SetName(L"ZeroTier One Network"); break; } } else break; } } } else break; } } if (foundMyNet) break; else Thread::sleep(1000); } } */ #ifdef ZT_WINDOWS_CREATE_FAKE_DEFAULT_ROUTE /* This inserts a fake default route and a fake ARP entry, forcing * Windows to detect this as a "real" network and apply proper * firewall rules. * * This hack is completely stupid, but Windows made me do it * by being broken and insane. * * Background: Windows tries to detect its network location by * matching it to the ARP address of the default route. Networks * without default routes are "unidentified networks" and cannot * have their firewall classification changed by the user (easily). * * Yes, you read that right. * * The common workaround is to set *NdisDeviceType to 1, which * totally disables all Windows firewall functionality. This is * the answer you'll find on most forums for things like OpenVPN. * * Yes, you read that right. * * But these networks don't usually have default routes, so what * do we do? Answer: add a fake one that's never used and goes * nowhere. But it's got to resolve to an ARP address. So why * don't we just make up one of those too?!? Shove it in there * as a permanent statuc ARP entry and now Windows will think it * has a real live default route at our bogus IP. * * We'll have to see what DHCP does with this. In the future we * probably will not want to do this on DHCP-enabled networks, so * when we enable DHCP we will go in and yank this wacko hacko from * the routing table before doing so. * * But yes, this works, and it makes our networks look and behave * the way they should. * * Like Jesse Pinkman would say: "YEEEEAAH BITCH!" */ for(int i=0;i<8;++i) { // also wait up to 8s for this, though if we got the NLM part we're probably okay MIB_IPFORWARD_ROW2 nr; memset(&nr,0,sizeof(nr)); InitializeIpForwardEntry(&nr); nr.InterfaceLuid.Value = _deviceLuid.Value; nr.DestinationPrefix.Prefix.si_family = AF_INET; // rest is left as 0.0.0.0/0 nr.NextHop.si_family = AF_INET; nr.NextHop.Ipv4.sin_addr.s_addr = 0x01010101; // 1.1.1.1 nr.Metric = 9999; // do not use as real default route nr.Protocol = MIB_IPPROTO_NETMGMT; DWORD result = CreateIpForwardEntry2(&nr); if (result == NO_ERROR) { MIB_IPNET_ROW2 ipnr; memset(&ipnr,0,sizeof(ipnr)); ipnr.Address.si_family = AF_INET; ipnr.Address.Ipv4.sin_addr.s_addr = 0x01010101; ipnr.InterfaceLuid.Value = _deviceLuid.Value; ipnr.PhysicalAddress[0] = _mac[0] ^ 0x10; // just make something up that's consistent and not part of this net ipnr.PhysicalAddress[1] = 0x00; ipnr.PhysicalAddress[2] = (UCHAR)((_deviceGuid.Data1 >> 24) & 0xff); ipnr.PhysicalAddress[3] = (UCHAR)((_deviceGuid.Data1 >> 16) & 0xff); ipnr.PhysicalAddress[4] = (UCHAR)((_deviceGuid.Data1 >> 8) & 0xff); ipnr.PhysicalAddress[5] = (UCHAR)(_deviceGuid.Data1 & 0xff); ipnr.PhysicalAddressLength = 6; ipnr.State = NlnsPermanent; ipnr.IsRouter = 1; ipnr.IsUnreachable = 0; ipnr.ReachabilityTime.LastReachable = 0x0fffffff; CreateIpNetEntry2(&ipnr); break; // stop retrying, we're done } else Thread::sleep(1000); } #endif memset(&tapOvlRead,0,sizeof(tapOvlRead)); tapOvlRead.hEvent = CreateEvent(NULL,TRUE,FALSE,NULL); memset(&tapOvlWrite,0,sizeof(tapOvlWrite)); tapOvlWrite.hEvent = CreateEvent(NULL,TRUE,FALSE,NULL); wait4[0] = _injectSemaphore; wait4[1] = tapOvlRead.hEvent; wait4[2] = tapOvlWrite.hEvent; // only included if writeInProgress is true // Start overlapped read, which is always active ReadFile(_tap,tapReadBuf,sizeof(tapReadBuf),NULL,&tapOvlRead); bool writeInProgress = false; for(;;) { if (!_run) break; DWORD r = WaitForMultipleObjectsEx(writeInProgress ? 3 : 2,wait4,FALSE,10000,TRUE); if (!_run) break; if ((r == WAIT_TIMEOUT)||(r == WAIT_FAILED)) continue; if (HasOverlappedIoCompleted(&tapOvlRead)) { DWORD bytesRead = 0; if (GetOverlappedResult(_tap,&tapOvlRead,&bytesRead,FALSE)) { if ((bytesRead > 14)&&(_enabled)) { MAC to(tapReadBuf,6); MAC from(tapReadBuf + 6,6); unsigned int etherType = ((((unsigned int)tapReadBuf[12]) & 0xff) << 8) | (((unsigned int)tapReadBuf[13]) & 0xff); try { Buffer<4096> tmp(tapReadBuf + 14,bytesRead - 14); _handler(_arg,from,to,etherType,tmp); } catch ( ... ) {} // handlers should not throw } } ReadFile(_tap,tapReadBuf,ZT_IF_MTU + 32,NULL,&tapOvlRead); } if (writeInProgress) { if (HasOverlappedIoCompleted(&tapOvlWrite)) { writeInProgress = false; _injectPending_m.lock(); _injectPending.pop(); } else continue; // still writing, so skip code below and wait } else _injectPending_m.lock(); if (!_injectPending.empty()) { WriteFile(_tap,_injectPending.front().first.data,_injectPending.front().second,NULL,&tapOvlWrite); writeInProgress = true; } _injectPending_m.unlock(); } CancelIo(_tap); CloseHandle(tapOvlRead.hEvent); CloseHandle(tapOvlWrite.hEvent); CloseHandle(_tap); _tap = INVALID_HANDLE_VALUE; ::free(tapReadBuf); } bool WindowsEthernetTap::_disableTapDevice() { HANDLE devconLog = CreateFileA((_pathToHelpers + "\\devcon.log").c_str(),GENERIC_WRITE,FILE_SHARE_READ|FILE_SHARE_WRITE,NULL,OPEN_ALWAYS,FILE_ATTRIBUTE_NORMAL,NULL); if (devconLog != INVALID_HANDLE_VALUE) SetFilePointer(devconLog,0,0,FILE_END); STARTUPINFOA startupInfo; startupInfo.cb = sizeof(startupInfo); if (devconLog != INVALID_HANDLE_VALUE) { startupInfo.hStdOutput = devconLog; startupInfo.hStdError = devconLog; } PROCESS_INFORMATION processInfo; memset(&startupInfo,0,sizeof(STARTUPINFOA)); memset(&processInfo,0,sizeof(PROCESS_INFORMATION)); if (!CreateProcessA(NULL,(LPSTR)(std::string("\"") + _pathToHelpers + WindowsEthernetTapFactory::WINENV.devcon + "\" disable @" + _deviceInstanceId).c_str(),NULL,NULL,FALSE,0,NULL,NULL,&startupInfo,&processInfo)) { if (devconLog != INVALID_HANDLE_VALUE) CloseHandle(devconLog); return false; } WaitForSingleObject(processInfo.hProcess,INFINITE); CloseHandle(processInfo.hProcess); CloseHandle(processInfo.hThread); if (devconLog != INVALID_HANDLE_VALUE) CloseHandle(devconLog); return true; } bool WindowsEthernetTap::_enableTapDevice() { HANDLE devconLog = CreateFileA((_pathToHelpers + "\\devcon.log").c_str(),GENERIC_WRITE,FILE_SHARE_READ|FILE_SHARE_WRITE,NULL,OPEN_ALWAYS,FILE_ATTRIBUTE_NORMAL,NULL); if (devconLog != INVALID_HANDLE_VALUE) SetFilePointer(devconLog,0,0,FILE_END); STARTUPINFOA startupInfo; startupInfo.cb = sizeof(startupInfo); if (devconLog != INVALID_HANDLE_VALUE) { startupInfo.hStdOutput = devconLog; startupInfo.hStdError = devconLog; } PROCESS_INFORMATION processInfo; memset(&startupInfo,0,sizeof(STARTUPINFOA)); memset(&processInfo,0,sizeof(PROCESS_INFORMATION)); if (!CreateProcessA(NULL,(LPSTR)(std::string("\"") + _pathToHelpers + WindowsEthernetTapFactory::WINENV.devcon + "\" enable @" + _deviceInstanceId).c_str(),NULL,NULL,FALSE,0,NULL,NULL,&startupInfo,&processInfo)) { if (devconLog != INVALID_HANDLE_VALUE) CloseHandle(devconLog); return false; } WaitForSingleObject(processInfo.hProcess,INFINITE); CloseHandle(processInfo.hProcess); CloseHandle(processInfo.hThread); if (devconLog != INVALID_HANDLE_VALUE) CloseHandle(devconLog); return true; } NET_IFINDEX WindowsEthernetTap::_getDeviceIndex() { MIB_IF_TABLE2 *ift = (MIB_IF_TABLE2 *)0; if (GetIfTable2Ex(MibIfTableRaw,&ift) != NO_ERROR) throw std::runtime_error("GetIfTable2Ex() failed"); for(ULONG i=0;iNumEntries;++i) { if (ift->Table[i].InterfaceLuid.Value == _deviceLuid.Value) { NET_IFINDEX idx = ift->Table[i].InterfaceIndex; FreeMibTable(ift); return idx; } } FreeMibTable(&ift); throw std::runtime_error("interface not found"); } std::vector WindowsEthernetTap::_getRegistryIPv4Value(const char *regKey) { std::vector value; HKEY tcpIpInterfaces; if (RegOpenKeyExA(HKEY_LOCAL_MACHINE,"SYSTEM\\CurrentControlSet\\services\\Tcpip\\Parameters\\Interfaces",0,KEY_READ|KEY_WRITE,&tcpIpInterfaces) == ERROR_SUCCESS) { char buf[16384]; DWORD len = sizeof(buf); DWORD kt = REG_MULTI_SZ; if (RegGetValueA(tcpIpInterfaces,_netCfgInstanceId.c_str(),regKey,0,&kt,&buf,&len) == ERROR_SUCCESS) { switch(kt) { case REG_SZ: if (len > 0) value.push_back(std::string(buf)); break; case REG_MULTI_SZ: { for(DWORD k=0,s=0;k &value) { std::string regMulti; for(std::vector::const_iterator s(value.begin());s!=value.end();++s) { regMulti.append(*s); regMulti.push_back((char)0); } HKEY tcpIpInterfaces; if (RegOpenKeyExA(HKEY_LOCAL_MACHINE,"SYSTEM\\CurrentControlSet\\services\\Tcpip\\Parameters\\Interfaces",0,KEY_READ|KEY_WRITE,&tcpIpInterfaces) == ERROR_SUCCESS) { if (regMulti.length() > 0) { regMulti.push_back((char)0); RegSetKeyValueA(tcpIpInterfaces,_netCfgInstanceId.c_str(),regKey,REG_MULTI_SZ,regMulti.data(),(DWORD)regMulti.length()); } else { RegDeleteKeyValueA(tcpIpInterfaces,_netCfgInstanceId.c_str(),regKey); } RegCloseKey(tcpIpInterfaces); } } } // namespace ZeroTier