// Copyright (c) Tailscale Inc & AUTHORS // SPDX-License-Identifier: BSD-3-Clause package winutil import ( "errors" "fmt" "log" "os" "os/exec" "os/user" "runtime" "strings" "syscall" "time" "unsafe" "github.com/dblohm7/wingoes" "golang.org/x/sys/windows" "golang.org/x/sys/windows/registry" ) const ( regBase = `SOFTWARE\Tailscale IPN` regPolicyBase = `SOFTWARE\Policies\Tailscale` ) // ErrNoShell is returned when the shell process is not found. var ErrNoShell = errors.New("no Shell process is present") // ErrNoValue is returned when the value doesn't exist in the registry. var ErrNoValue = registry.ErrNotExist // GetDesktopPID searches the PID of the process that's running the // currently active desktop. Returns ErrNoShell if the shell is not present. // Usually the PID will be for explorer.exe. func GetDesktopPID() (uint32, error) { hwnd := windows.GetShellWindow() if hwnd == 0 { return 0, ErrNoShell } var pid uint32 windows.GetWindowThreadProcessId(hwnd, &pid) if pid == 0 { return 0, fmt.Errorf("invalid PID for HWND %v", hwnd) } return pid, nil } func getPolicyString(name string) (string, error) { s, err := getRegStringInternal(regPolicyBase, name) if err != nil { // Fall back to the legacy path return getRegString(name) } return s, err } func getRegString(name string) (string, error) { s, err := getRegStringInternal(regBase, name) if err != nil { return "", err } return s, err } func getPolicyInteger(name string) (uint64, error) { i, err := getRegIntegerInternal(regPolicyBase, name) if err != nil { // Fall back to the legacy path return getRegInteger(name) } return i, err } func getRegInteger(name string) (uint64, error) { i, err := getRegIntegerInternal(regBase, name) if err != nil { return 0, err } return i, err } func getRegStringInternal(subKey, name string) (string, error) { key, err := registry.OpenKey(registry.LOCAL_MACHINE, subKey, registry.READ) if err != nil { if err != ErrNoValue { log.Printf("registry.OpenKey(%v): %v", subKey, err) } return "", err } defer key.Close() val, _, err := key.GetStringValue(name) if err != nil { if err != ErrNoValue { log.Printf("registry.GetStringValue(%v): %v", name, err) } return "", err } return val, nil } // GetRegStrings looks up a registry value in the local machine path, or returns // the given default if it can't. func GetRegStrings(name string, defval []string) []string { s, err := getRegStringsInternal(regBase, name) if err != nil { return defval } return s } func getRegStringsInternal(subKey, name string) ([]string, error) { key, err := registry.OpenKey(registry.LOCAL_MACHINE, subKey, registry.READ) if err != nil { if err != ErrNoValue { log.Printf("registry.OpenKey(%v): %v", subKey, err) } return nil, err } defer key.Close() val, _, err := key.GetStringsValue(name) if err != nil { if err != ErrNoValue { log.Printf("registry.GetStringValue(%v): %v", name, err) } return nil, err } return val, nil } // SetRegStrings sets a MULTI_SZ value in the in the local machine path // to the strings specified by values. func SetRegStrings(name string, values []string) error { return setRegStringsInternal(regBase, name, values) } func setRegStringsInternal(subKey, name string, values []string) error { key, _, err := registry.CreateKey(registry.LOCAL_MACHINE, subKey, registry.SET_VALUE) if err != nil { log.Printf("registry.CreateKey(%v): %v", subKey, err) } defer key.Close() return key.SetStringsValue(name, values) } // DeleteRegValue removes a registry value in the local machine path. func DeleteRegValue(name string) error { return deleteRegValueInternal(regBase, name) } func deleteRegValueInternal(subKey, name string) error { key, err := registry.OpenKey(registry.LOCAL_MACHINE, subKey, registry.SET_VALUE) if err == ErrNoValue { return nil } if err != nil { log.Printf("registry.OpenKey(%v): %v", subKey, err) return err } defer key.Close() err = key.DeleteValue(name) if err == ErrNoValue { err = nil } return err } func getRegIntegerInternal(subKey, name string) (uint64, error) { key, err := registry.OpenKey(registry.LOCAL_MACHINE, subKey, registry.READ) if err != nil { if err != ErrNoValue { log.Printf("registry.OpenKey(%v): %v", subKey, err) } return 0, err } defer key.Close() val, _, err := key.GetIntegerValue(name) if err != nil { if err != ErrNoValue { log.Printf("registry.GetIntegerValue(%v): %v", name, err) } return 0, err } return val, nil } var ( kernel32 = syscall.NewLazyDLL("kernel32.dll") procWTSGetActiveConsoleSessionId = kernel32.NewProc("WTSGetActiveConsoleSessionId") ) // TODO(crawshaw): replace with x/sys/windows... one day. // https://go-review.googlesource.com/c/sys/+/331909 func WTSGetActiveConsoleSessionId() uint32 { r1, _, _ := procWTSGetActiveConsoleSessionId.Call() return uint32(r1) } func isSIDValidPrincipal(uid string) bool { usid, err := syscall.StringToSid(uid) if err != nil { return false } _, _, accType, err := usid.LookupAccount("") if err != nil { return false } switch accType { case syscall.SidTypeUser, syscall.SidTypeGroup, syscall.SidTypeDomain, syscall.SidTypeAlias, syscall.SidTypeWellKnownGroup, syscall.SidTypeComputer: return true default: // Reject deleted users, invalid SIDs, unknown SIDs, mandatory label SIDs, etc. return false } } // EnableCurrentThreadPrivilege enables the named privilege in the current // thread access token. The current goroutine is also locked to the OS thread // (runtime.LockOSThread). Callers must call the returned disable function when // done with the privileged task. func EnableCurrentThreadPrivilege(name string) (disable func() error, err error) { runtime.LockOSThread() if err := windows.ImpersonateSelf(windows.SecurityImpersonation); err != nil { runtime.UnlockOSThread() return nil, err } disable = func() error { defer runtime.UnlockOSThread() return windows.RevertToSelf() } defer func() { if err != nil { disable() } }() var t windows.Token err = windows.OpenThreadToken(windows.CurrentThread(), windows.TOKEN_QUERY|windows.TOKEN_ADJUST_PRIVILEGES, false, &t) if err != nil { return nil, err } defer t.Close() var tp windows.Tokenprivileges privStr, err := syscall.UTF16PtrFromString(name) if err != nil { return nil, err } err = windows.LookupPrivilegeValue(nil, privStr, &tp.Privileges[0].Luid) if err != nil { return nil, err } tp.PrivilegeCount = 1 tp.Privileges[0].Attributes = windows.SE_PRIVILEGE_ENABLED return disable, windows.AdjustTokenPrivileges(t, false, &tp, 0, nil, nil) } // StartProcessAsChild starts exePath process as a child of parentPID. // StartProcessAsChild copies parentPID's environment variables into // the new process, along with any optional environment variables in extraEnv. func StartProcessAsChild(parentPID uint32, exePath string, extraEnv []string) error { // The rest of this function requires SeDebugPrivilege to be held. // // According to https://docs.microsoft.com/en-us/windows/win32/procthread/process-security-and-access-rights // // ... To open a handle to another process and obtain full access rights, // you must enable the SeDebugPrivilege privilege. ... // // But we only need PROCESS_CREATE_PROCESS. So perhaps SeDebugPrivilege is too much. // // https://devblogs.microsoft.com/oldnewthing/20080314-00/?p=23113 // // TODO: try look for something less than SeDebugPrivilege disableSeDebug, err := EnableCurrentThreadPrivilege("SeDebugPrivilege") if err != nil { return err } defer disableSeDebug() ph, err := windows.OpenProcess( windows.PROCESS_CREATE_PROCESS|windows.PROCESS_QUERY_INFORMATION|windows.PROCESS_DUP_HANDLE, false, parentPID) if err != nil { return err } defer windows.CloseHandle(ph) var pt windows.Token err = windows.OpenProcessToken(ph, windows.TOKEN_QUERY, &pt) if err != nil { return err } defer pt.Close() env, err := pt.Environ(false) if err != nil { return err } env = append(env, extraEnv...) sys := &syscall.SysProcAttr{ParentProcess: syscall.Handle(ph)} cmd := exec.Command(exePath) cmd.Env = env cmd.SysProcAttr = sys return cmd.Start() } // StartProcessAsCurrentGUIUser is like StartProcessAsChild, but if finds // current logged in user desktop process (normally explorer.exe), // and passes found PID to StartProcessAsChild. func StartProcessAsCurrentGUIUser(exePath string, extraEnv []string) error { // as described in https://devblogs.microsoft.com/oldnewthing/20190425-00/?p=102443 desktop, err := GetDesktopPID() if err != nil { return fmt.Errorf("failed to find desktop: %v", err) } err = StartProcessAsChild(desktop, exePath, extraEnv) if err != nil { return fmt.Errorf("failed to start executable: %v", err) } return nil } // CreateAppMutex creates a named Windows mutex, returning nil if the mutex // is created successfully or an error if the mutex already exists or could not // be created for some other reason. func CreateAppMutex(name string) (windows.Handle, error) { return windows.CreateMutex(nil, false, windows.StringToUTF16Ptr(name)) } func getTokenInfo(token windows.Token, infoClass uint32) ([]byte, error) { var desiredLen uint32 err := windows.GetTokenInformation(token, infoClass, nil, 0, &desiredLen) if err != nil && err != windows.ERROR_INSUFFICIENT_BUFFER { return nil, err } buf := make([]byte, desiredLen) actualLen := desiredLen err = windows.GetTokenInformation(token, infoClass, &buf[0], desiredLen, &actualLen) return buf, err } func getTokenUserInfo(token windows.Token) (*windows.Tokenuser, error) { buf, err := getTokenInfo(token, windows.TokenUser) if err != nil { return nil, err } return (*windows.Tokenuser)(unsafe.Pointer(&buf[0])), nil } func getTokenPrimaryGroupInfo(token windows.Token) (*windows.Tokenprimarygroup, error) { buf, err := getTokenInfo(token, windows.TokenPrimaryGroup) if err != nil { return nil, err } return (*windows.Tokenprimarygroup)(unsafe.Pointer(&buf[0])), nil } type tokenElevationType int32 const ( tokenElevationTypeDefault tokenElevationType = 1 tokenElevationTypeFull tokenElevationType = 2 tokenElevationTypeLimited tokenElevationType = 3 ) func getTokenElevationType(token windows.Token) (result tokenElevationType, err error) { var actualLen uint32 p := (*byte)(unsafe.Pointer(&result)) err = windows.GetTokenInformation(token, windows.TokenElevationType, p, uint32(unsafe.Sizeof(result)), &actualLen) return result, err } // IsTokenLimited returns whether token is a limited UAC token. func IsTokenLimited(token windows.Token) (bool, error) { elevationType, err := getTokenElevationType(token) if err != nil { return false, err } return elevationType == tokenElevationTypeLimited, nil } // UserSIDs contains the SIDs for a Windows NT token object's associated user // as well as its primary group. type UserSIDs struct { User *windows.SID PrimaryGroup *windows.SID } // GetCurrentUserSIDs returns a UserSIDs struct containing SIDs for the // current process' user and primary group. func GetCurrentUserSIDs() (*UserSIDs, error) { token, err := windows.OpenCurrentProcessToken() if err != nil { return nil, err } defer token.Close() userInfo, err := getTokenUserInfo(token) if err != nil { return nil, err } primaryGroup, err := getTokenPrimaryGroupInfo(token) if err != nil { return nil, err } return &UserSIDs{userInfo.User.Sid, primaryGroup.PrimaryGroup}, nil } // IsCurrentProcessElevated returns true when the current process is // running with an elevated token, implying Administrator access. func IsCurrentProcessElevated() bool { token, err := windows.OpenCurrentProcessToken() if err != nil { return false } defer token.Close() return token.IsElevated() } // keyOpenTimeout is how long we wait for a registry key to appear. For some // reason, registry keys tied to ephemeral interfaces can take a long while to // appear after interface creation, and we can end up racing with that. const keyOpenTimeout = 20 * time.Second // RegistryPath represents a path inside a root registry.Key. type RegistryPath string // RegistryPathPrefix specifies a RegistryPath prefix that must be suffixed with // another RegistryPath to make a valid RegistryPath. type RegistryPathPrefix string // WithSuffix returns a RegistryPath with the given suffix appended. func (p RegistryPathPrefix) WithSuffix(suf string) RegistryPath { return RegistryPath(string(p) + suf) } const ( IPv4TCPIPBase RegistryPath = `SYSTEM\CurrentControlSet\Services\Tcpip\Parameters` IPv6TCPIPBase RegistryPath = `SYSTEM\CurrentControlSet\Services\Tcpip6\Parameters` NetBTBase RegistryPath = `SYSTEM\CurrentControlSet\Services\NetBT\Parameters` IPv4TCPIPInterfacePrefix RegistryPathPrefix = `SYSTEM\CurrentControlSet\Services\Tcpip\Parameters\Interfaces\` IPv6TCPIPInterfacePrefix RegistryPathPrefix = `SYSTEM\CurrentControlSet\Services\Tcpip6\Parameters\Interfaces\` NetBTInterfacePrefix RegistryPathPrefix = `SYSTEM\CurrentControlSet\Services\NetBT\Parameters\Interfaces\Tcpip_` ) // ErrKeyWaitTimeout is returned by OpenKeyWait when calls timeout. var ErrKeyWaitTimeout = errors.New("timeout waiting for registry key") // OpenKeyWait opens a registry key, waiting for it to appear if necessary. It // returns the opened key, or ErrKeyWaitTimeout if the key does not appear // within 20s. The caller must call Close on the returned key. func OpenKeyWait(k registry.Key, path RegistryPath, access uint32) (registry.Key, error) { runtime.LockOSThread() defer runtime.UnlockOSThread() deadline := time.Now().Add(keyOpenTimeout) pathSpl := strings.Split(string(path), "\\") for i := 0; ; i++ { keyName := pathSpl[i] isLast := i+1 == len(pathSpl) event, err := windows.CreateEvent(nil, 0, 0, nil) if err != nil { return 0, fmt.Errorf("windows.CreateEvent: %w", err) } defer windows.CloseHandle(event) var key registry.Key for { err = windows.RegNotifyChangeKeyValue(windows.Handle(k), false, windows.REG_NOTIFY_CHANGE_NAME, event, true) if err != nil { return 0, fmt.Errorf("windows.RegNotifyChangeKeyValue: %w", err) } var accessFlags uint32 if isLast { accessFlags = access } else { accessFlags = registry.NOTIFY } key, err = registry.OpenKey(k, keyName, accessFlags) if err == windows.ERROR_FILE_NOT_FOUND || err == windows.ERROR_PATH_NOT_FOUND { timeout := time.Until(deadline) / time.Millisecond if timeout < 0 { timeout = 0 } s, err := windows.WaitForSingleObject(event, uint32(timeout)) if err != nil { return 0, fmt.Errorf("windows.WaitForSingleObject: %w", err) } if s == uint32(windows.WAIT_TIMEOUT) { // windows.WAIT_TIMEOUT status const is misclassified as error in golang.org/x/sys/windows return 0, ErrKeyWaitTimeout } } else if err != nil { return 0, fmt.Errorf("registry.OpenKey(%v): %w", path, err) } else { if isLast { return key, nil } defer key.Close() break } } k = key } } func lookupPseudoUser(uid string) (*user.User, error) { sid, err := windows.StringToSid(uid) if err != nil { return nil, err } // We're looking for SIDs "S-1-5-x" where 17 <= x <= 20. // This is checking for the the "5" if sid.IdentifierAuthority() != windows.SECURITY_NT_AUTHORITY { return nil, fmt.Errorf(`SID %q does not use "NT AUTHORITY"`, uid) } // This is ensuring that there is only one sub-authority. // In other words, only one value after the "5". if sid.SubAuthorityCount() != 1 { return nil, fmt.Errorf("SID %q should have only one subauthority", uid) } // Get that sub-authority value (this is "x" above) and check it. rid := sid.SubAuthority(0) if rid < 17 || rid > 20 { return nil, fmt.Errorf("SID %q does not represent a known pseudo-user", uid) } // We've got one of the known pseudo-users. Look up the localized name of the // account. username, domain, _, err := sid.LookupAccount("") if err != nil { return nil, err } // This call is best-effort. If it fails, homeDir will be empty. homeDir, _ := findHomeDirInRegistry(uid) result := &user.User{ Uid: uid, Gid: uid, // Gid == Uid with these accounts. Username: fmt.Sprintf(`%s\%s`, domain, username), Name: username, HomeDir: homeDir, } return result, nil } // findHomeDirInRegistry finds the user home path based on the uid. // This is borrowed from Go's std lib. func findHomeDirInRegistry(uid string) (dir string, err error) { k, err := registry.OpenKey(registry.LOCAL_MACHINE, `SOFTWARE\Microsoft\Windows NT\CurrentVersion\ProfileList\`+uid, registry.QUERY_VALUE) if err != nil { return "", err } defer k.Close() dir, _, err = k.GetStringValue("ProfileImagePath") if err != nil { return "", err } return dir, nil } const ( _RESTART_NO_CRASH = 1 _RESTART_NO_HANG = 2 _RESTART_NO_PATCH = 4 _RESTART_NO_REBOOT = 8 ) func registerForRestart(opts RegisterForRestartOpts) error { var flags uint32 if !opts.RestartOnCrash { flags |= _RESTART_NO_CRASH } if !opts.RestartOnHang { flags |= _RESTART_NO_HANG } if !opts.RestartOnUpgrade { flags |= _RESTART_NO_PATCH } if !opts.RestartOnReboot { flags |= _RESTART_NO_REBOOT } var cmdLine *uint16 if opts.UseCmdLineArgs { if len(opts.CmdLineArgs) == 0 { // re-use our current args, excluding the exe name itself opts.CmdLineArgs = os.Args[1:] } var b strings.Builder for _, arg := range opts.CmdLineArgs { if b.Len() > 0 { b.WriteByte(' ') } b.WriteString(windows.EscapeArg(arg)) } if b.Len() > 0 { var err error cmdLine, err = windows.UTF16PtrFromString(b.String()) if err != nil { return err } } } hr := registerApplicationRestart(cmdLine, flags) if e := wingoes.ErrorFromHRESULT(hr); e.Failed() { return e } return nil }