#pragma once #include #include #include #include #include #include // DDK macros #define CTL_CODE(DeviceType, Function, Method, Access) \ (((DeviceType) << 16) | ((Access) << 14) | ((Function) << 2) | (Method)) #define FILE_DEVICE_UNKNOWN 0x00000022 #define FILE_ANY_ACCESS 0x00000000 #define METHOD_BUFFERED 0 /* From OpenVPN tap driver, common.h */ #define TAP_CONTROL_CODE(request, method) \ CTL_CODE(FILE_DEVICE_UNKNOWN, request, method, FILE_ANY_ACCESS) #define TAP_IOCTL_GET_MAC TAP_CONTROL_CODE(1, METHOD_BUFFERED) #define TAP_IOCTL_GET_VERSION TAP_CONTROL_CODE(2, METHOD_BUFFERED) #define TAP_IOCTL_GET_MTU TAP_CONTROL_CODE(3, METHOD_BUFFERED) #define TAP_IOCTL_GET_INFO TAP_CONTROL_CODE(4, METHOD_BUFFERED) #define TAP_IOCTL_CONFIG_POINT_TO_POINT TAP_CONTROL_CODE(5, METHOD_BUFFERED) #define TAP_IOCTL_SET_MEDIA_STATUS TAP_CONTROL_CODE(6, METHOD_BUFFERED) #define TAP_IOCTL_CONFIG_DHCP_MASQ TAP_CONTROL_CODE(7, METHOD_BUFFERED) #define TAP_IOCTL_GET_LOG_LINE TAP_CONTROL_CODE(8, METHOD_BUFFERED) #define TAP_IOCTL_CONFIG_DHCP_SET_OPT TAP_CONTROL_CODE(9, METHOD_BUFFERED) #define TAP_IOCTL_CONFIG_TUN TAP_CONTROL_CODE(10, METHOD_BUFFERED) /* Windows registry crap */ #define MAX_KEY_LENGTH 255 #define MAX_VALUE_NAME 16383 #define NETWORK_ADAPTERS \ "SYSTEM\\CurrentControlSet\\Control\\Class\\{4D36E972-E325-11CE-BFC1-" \ "08002BE10318}" typedef unsigned long IPADDR; namespace llarp::vpn { static char* reg_query(char* key_name) { HKEY adapters, adapter; DWORD i, ret, len; char* deviceid = nullptr; DWORD sub_keys = 0; ret = RegOpenKeyEx(HKEY_LOCAL_MACHINE, TEXT(key_name), 0, KEY_READ, &adapters); if (ret != ERROR_SUCCESS) { return nullptr; } ret = RegQueryInfoKey( adapters, NULL, NULL, NULL, &sub_keys, NULL, NULL, NULL, NULL, NULL, NULL, NULL); if (ret != ERROR_SUCCESS) { return nullptr; } if (sub_keys <= 0) { return nullptr; } /* Walk througt all adapters */ for (i = 0; i < sub_keys; i++) { char new_key[MAX_KEY_LENGTH]; char data[256]; TCHAR key[MAX_KEY_LENGTH]; DWORD keylen = MAX_KEY_LENGTH; /* Get the adapter key name */ ret = RegEnumKeyEx(adapters, i, key, &keylen, NULL, NULL, NULL, NULL); if (ret != ERROR_SUCCESS) { continue; } /* Append it to NETWORK_ADAPTERS and open it */ snprintf(new_key, sizeof new_key, "%s\\%s", key_name, key); ret = RegOpenKeyEx(HKEY_LOCAL_MACHINE, TEXT(new_key), 0, KEY_READ, &adapter); if (ret != ERROR_SUCCESS) { continue; } /* Check its values */ len = sizeof data; ret = RegQueryValueEx(adapter, "ComponentId", NULL, NULL, (LPBYTE)data, &len); if (ret != ERROR_SUCCESS) { /* This value doesn't exist in this adaptater tree */ goto clean; } /* If its a tap adapter, its all good */ if (strncmp(data, "tap0901", 7) == 0) { DWORD type; len = sizeof data; ret = RegQueryValueEx(adapter, "NetCfgInstanceId", NULL, &type, (LPBYTE)data, &len); if (ret != ERROR_SUCCESS) { goto clean; } deviceid = strdup(data); break; } clean: RegCloseKey(adapter); } RegCloseKey(adapters); return deviceid; } class Win32Interface : public NetworkInterface { std::atomic m_Run; HANDLE m_Device, m_IOCP; std::vector m_Threads; thread::Queue m_ReadQueue; const InterfaceInfo m_Info; static std::wstring get_win_sys_path() { wchar_t win_sys_path[MAX_PATH] = {0}; const wchar_t* default_sys_path = L"C:\\Windows\\system32"; if (!GetSystemDirectoryW(win_sys_path, _countof(win_sys_path))) { wcsncpy(win_sys_path, default_sys_path, _countof(win_sys_path)); win_sys_path[_countof(win_sys_path) - 1] = L'\0'; } return win_sys_path; } static std::string NetSHCommand() { std::wstring wcmd = get_win_sys_path() + L"\\netsh.exe"; using convert_type = std::codecvt_utf8; std::wstring_convert converter; return converter.to_bytes(wcmd); } static void NetSH(std::string commands) { commands = NetSHCommand() + " " + commands; ::system(commands.c_str()); } public: Win32Interface(InterfaceInfo info) : m_ReadQueue{1024}, m_Info{std::move(info)} { DWORD len; const auto device_id = reg_query(NETWORK_ADAPTERS); if (device_id == nullptr) { LogError("cannot query registry"); throw std::invalid_argument{"cannot query registery"}; } std::stringstream ss; ss << "\\\\.\\Global\\" << device_id << ".tap"; const auto fname = ss.str(); m_Device = CreateFile( fname.c_str(), GENERIC_WRITE | GENERIC_READ, FILE_SHARE_READ | FILE_SHARE_WRITE, 0, OPEN_EXISTING, FILE_ATTRIBUTE_SYSTEM | FILE_FLAG_OVERLAPPED, 0); if (m_Device == INVALID_HANDLE_VALUE) { LogError("failed to open device"); throw std::invalid_argument{"cannot open " + fname}; } LogInfo("putting interface up..."); ULONG flag = 1; // put the interface up if (not DeviceIoControl( m_Device, TAP_IOCTL_SET_MEDIA_STATUS, &flag, sizeof(flag), &flag, sizeof(flag), &len, nullptr)) { LogError("cannot up interface up"); throw std::invalid_argument{"cannot put interface up"}; } LogInfo("setting addresses"); // set ipv4 addresses for (const auto& ifaddr : m_Info.addrs) { if (ifaddr.fam == AF_INET) { IPADDR sock[3]{}; const nuint32_t addr = xhtonl(net::TruncateV6(ifaddr.range.addr)); const nuint32_t mask = xhtonl(net::TruncateV6(ifaddr.range.netmask_bits)); LogInfo("address ", addr, " netmask ", mask); sock[0] = addr.n; sock[1] = addr.n & mask.n; sock[2] = mask.n; if (not DeviceIoControl( m_Device, TAP_IOCTL_CONFIG_TUN, &sock, sizeof(sock), &sock, sizeof(sock), &len, nullptr)) { LogError("cannot set address"); throw std::invalid_argument{"cannot configure tun interface address"}; } IPADDR ep[4]{}; ep[0] = addr.n; ep[1] = mask.n; ep[2] = (addr.n | ~mask.n) - htonl(1); ep[3] = 31536000; if (not DeviceIoControl( m_Device, TAP_IOCTL_CONFIG_DHCP_MASQ, ep, sizeof(ep), ep, sizeof(ep), &len, nullptr)) { LogError("cannot set dhcp masq"); throw std::invalid_argument{"Cannot configure tun interface dhcp"}; } #pragma pack(push) #pragma pack(1) struct opt { uint8_t dhcp_opt; uint8_t length; uint32_t value; } dns, gateway; #pragma pack(pop) const nuint32_t dnsaddr{xhtonl(m_Info.dnsaddr)}; dns.dhcp_opt = 6; dns.length = 4; dns.value = dnsaddr.n; gateway.dhcp_opt = 3; gateway.length = 4; gateway.value = addr.n + htonl(1); if (not DeviceIoControl( m_Device, TAP_IOCTL_CONFIG_DHCP_SET_OPT, &gateway, sizeof(gateway), &gateway, sizeof(gateway), &len, nullptr)) { LogError("cannot set gateway"); throw std::invalid_argument{"cannot set tun gateway"}; } if (not DeviceIoControl( m_Device, TAP_IOCTL_CONFIG_DHCP_SET_OPT, &dns, sizeof(dns), &dns, sizeof(dns), &len, nullptr)) { LogError("cannot set dns"); throw std::invalid_argument{"cannot set tun dns"}; } } } // set ipv6 addresses /* for (const auto& ifaddr : m_Info.addrs) { if (ifaddr.fam == AF_INET6) { IPRange range = ifaddr.range; range.netmask_bits = netmask_ipv6_bits(128); NetSH( "interface ipv6 set address " + std::to_string(ifindex) + " " + range.ToString() + " store=active"); } } */ } ~Win32Interface() { ULONG flag = 0; DWORD len; // put the interface down DeviceIoControl( m_Device, TAP_IOCTL_SET_MEDIA_STATUS, &flag, sizeof(flag), &flag, sizeof(flag), &len, nullptr); m_Run = false; CloseHandle(m_IOCP); // close the handle CloseHandle(m_Device); // close the reader threads for (auto& thread : m_Threads) CloseHandle(thread); } int PollFD() const override { return -1; } bool HasNextPacket() override { return not m_ReadQueue.empty(); } std::string IfName() const override { return ""; } static DWORD FAR PASCAL Loop(void* u) { static_cast(u)->ReadLoop(); return 0; } void Start() { m_Run = true; const auto numThreads = std::thread::hardware_concurrency(); m_IOCP = CreateIoCompletionPort(m_Device, nullptr, (ULONG_PTR)this, 1 + numThreads); for (size_t idx = 0; idx < numThreads; ++idx) m_Threads.push_back(CreateThread(nullptr, 0, &Loop, this, 0, nullptr)); } net::IPPacket ReadNextPacket() { return m_ReadQueue.popFront(); } struct asio_evt_pkt { explicit asio_evt_pkt(bool _read) : read{_read} {} OVERLAPPED hdr = {0, 0, 0, 0, nullptr}; // must be first, since this is part of the IO call bool read; net::IPPacket pkt; void Read(HANDLE dev) { ReadFile(dev, pkt.buf, sizeof(pkt.buf), nullptr, &hdr); } }; bool WritePacket(net::IPPacket pkt) { LogDebug("write packet ", pkt.sz); asio_evt_pkt* ev = new asio_evt_pkt{false}; std::copy_n(pkt.buf, pkt.sz, ev->pkt.buf); ev->pkt.sz = pkt.sz; WriteFile(m_Device, ev->pkt.buf, ev->pkt.sz, nullptr, &ev->hdr); return true; } void ReadLoop() { std::unique_ptr ev = std::make_unique(true); ev->Read(m_Device); while (m_Run) { DWORD size; ULONG_PTR user; OVERLAPPED* ovl = nullptr; if (not GetQueuedCompletionStatus(m_IOCP, &size, &user, &ovl, 1000)) continue; asio_evt_pkt* pkt = (asio_evt_pkt*)ovl; LogDebug("got iocp event size=", size, " read=", pkt->read); if (pkt->read) { pkt->pkt.sz = size; m_ReadQueue.pushBack(pkt->pkt); pkt->Read(m_Device); } else delete pkt; } } }; class Win32Platform : public Platform { public: std::shared_ptr ObtainInterface(InterfaceInfo info) override { auto netif = std::make_shared(std::move(info)); netif->Start(); return netif; }; }; } // namespace llarp::vpn