// +build windows package process import ( "bufio" "context" "errors" "fmt" "io" "os" "reflect" "strings" "syscall" "time" "unicode/utf16" "unsafe" "github.com/shirou/gopsutil/cpu" "github.com/shirou/gopsutil/internal/common" "github.com/shirou/gopsutil/net" "golang.org/x/sys/windows" ) var ( modntdll = windows.NewLazySystemDLL("ntdll.dll") procNtResumeProcess = modntdll.NewProc("NtResumeProcess") procNtSuspendProcess = modntdll.NewProc("NtSuspendProcess") modpsapi = windows.NewLazySystemDLL("psapi.dll") procGetProcessMemoryInfo = modpsapi.NewProc("GetProcessMemoryInfo") procGetProcessImageFileNameW = modpsapi.NewProc("GetProcessImageFileNameW") advapi32 = windows.NewLazySystemDLL("advapi32.dll") procLookupPrivilegeValue = advapi32.NewProc("LookupPrivilegeValueW") procAdjustTokenPrivileges = advapi32.NewProc("AdjustTokenPrivileges") procQueryFullProcessImageNameW = common.Modkernel32.NewProc("QueryFullProcessImageNameW") procGetPriorityClass = common.Modkernel32.NewProc("GetPriorityClass") procGetProcessIoCounters = common.Modkernel32.NewProc("GetProcessIoCounters") procGetNativeSystemInfo = common.Modkernel32.NewProc("GetNativeSystemInfo") processorArchitecture uint ) const processQueryInformation = windows.PROCESS_QUERY_LIMITED_INFORMATION type SystemProcessInformation struct { NextEntryOffset uint64 NumberOfThreads uint64 Reserved1 [48]byte Reserved2 [3]byte UniqueProcessID uintptr Reserved3 uintptr HandleCount uint64 Reserved4 [4]byte Reserved5 [11]byte PeakPagefileUsage uint64 PrivatePageCount uint64 Reserved6 [6]uint64 } type systemProcessorInformation struct { ProcessorArchitecture uint16 ProcessorLevel uint16 ProcessorRevision uint16 Reserved uint16 ProcessorFeatureBits uint16 } type systemInfo struct { wProcessorArchitecture uint16 wReserved uint16 dwPageSize uint32 lpMinimumApplicationAddress uintptr lpMaximumApplicationAddress uintptr dwActiveProcessorMask uintptr dwNumberOfProcessors uint32 dwProcessorType uint32 dwAllocationGranularity uint32 wProcessorLevel uint16 wProcessorRevision uint16 } // Memory_info_ex is different between OSes type MemoryInfoExStat struct { } type MemoryMapsStat struct { } // ioCounters is an equivalent representation of IO_COUNTERS in the Windows API. // https://docs.microsoft.com/windows/win32/api/winnt/ns-winnt-io_counters type ioCounters struct { ReadOperationCount uint64 WriteOperationCount uint64 OtherOperationCount uint64 ReadTransferCount uint64 WriteTransferCount uint64 OtherTransferCount uint64 } type processBasicInformation32 struct { Reserved1 uint32 PebBaseAddress uint32 Reserved2 uint32 Reserved3 uint32 UniqueProcessId uint32 Reserved4 uint32 } type processBasicInformation64 struct { Reserved1 uint64 PebBaseAddress uint64 Reserved2 uint64 Reserved3 uint64 UniqueProcessId uint64 Reserved4 uint64 } type processEnvironmentBlock32 struct { Reserved1 [2]uint8 BeingDebugged uint8 Reserved2 uint8 Reserved3 [2]uint32 Ldr uint32 ProcessParameters uint32 // More fields which we don't use so far } type processEnvironmentBlock64 struct { Reserved1 [2]uint8 BeingDebugged uint8 Reserved2 uint8 _ [4]uint8 // padding, since we are 64 bit, the next pointer is 64 bit aligned (when compiling for 32 bit, this is not the case without manual padding) Reserved3 [2]uint64 Ldr uint64 ProcessParameters uint64 // More fields which we don't use so far } type rtlUserProcessParameters32 struct { Reserved1 [16]uint8 ConsoleHandle uint32 ConsoleFlags uint32 StdInputHandle uint32 StdOutputHandle uint32 StdErrorHandle uint32 CurrentDirectoryPathNameLength uint16 _ uint16 // Max Length CurrentDirectoryPathAddress uint32 CurrentDirectoryHandle uint32 DllPathNameLength uint16 _ uint16 // Max Length DllPathAddress uint32 ImagePathNameLength uint16 _ uint16 // Max Length ImagePathAddress uint32 CommandLineLength uint16 _ uint16 // Max Length CommandLineAddress uint32 EnvironmentAddress uint32 // More fields which we don't use so far } type rtlUserProcessParameters64 struct { Reserved1 [16]uint8 ConsoleHandle uint64 ConsoleFlags uint64 StdInputHandle uint64 StdOutputHandle uint64 StdErrorHandle uint64 CurrentDirectoryPathNameLength uint16 _ uint16 // Max Length _ uint32 // Padding CurrentDirectoryPathAddress uint64 CurrentDirectoryHandle uint64 DllPathNameLength uint16 _ uint16 // Max Length _ uint32 // Padding DllPathAddress uint64 ImagePathNameLength uint16 _ uint16 // Max Length _ uint32 // Padding ImagePathAddress uint64 CommandLineLength uint16 _ uint16 // Max Length _ uint32 // Padding CommandLineAddress uint64 EnvironmentAddress uint64 // More fields which we don't use so far } type winLUID struct { LowPart winDWord HighPart winLong } // LUID_AND_ATTRIBUTES type winLUIDAndAttributes struct { Luid winLUID Attributes winDWord } // TOKEN_PRIVILEGES type winTokenPriviledges struct { PrivilegeCount winDWord Privileges [1]winLUIDAndAttributes } type winLong int32 type winDWord uint32 func init() { var systemInfo systemInfo procGetNativeSystemInfo.Call(uintptr(unsafe.Pointer(&systemInfo))) processorArchitecture = uint(systemInfo.wProcessorArchitecture) // enable SeDebugPrivilege https://github.com/midstar/proci/blob/6ec79f57b90ba3d9efa2a7b16ef9c9369d4be875/proci_windows.go#L80-L119 handle, err := syscall.GetCurrentProcess() if err != nil { return } var token syscall.Token err = syscall.OpenProcessToken(handle, 0x0028, &token) if err != nil { return } defer token.Close() tokenPriviledges := winTokenPriviledges{PrivilegeCount: 1} lpName := syscall.StringToUTF16("SeDebugPrivilege") ret, _, _ := procLookupPrivilegeValue.Call( 0, uintptr(unsafe.Pointer(&lpName[0])), uintptr(unsafe.Pointer(&tokenPriviledges.Privileges[0].Luid))) if ret == 0 { return } tokenPriviledges.Privileges[0].Attributes = 0x00000002 // SE_PRIVILEGE_ENABLED procAdjustTokenPrivileges.Call( uintptr(token), 0, uintptr(unsafe.Pointer(&tokenPriviledges)), uintptr(unsafe.Sizeof(tokenPriviledges)), 0, 0) } func pidsWithContext(ctx context.Context) ([]int32, error) { // inspired by https://gist.github.com/henkman/3083408 // and https://github.com/giampaolo/psutil/blob/1c3a15f637521ba5c0031283da39c733fda53e4c/psutil/arch/windows/process_info.c#L315-L329 var ret []int32 var read uint32 = 0 var psSize uint32 = 1024 const dwordSize uint32 = 4 for { ps := make([]uint32, psSize) if err := windows.EnumProcesses(ps, &read); err != nil { return nil, err } if uint32(len(ps)) == read { // ps buffer was too small to host every results, retry with a bigger one psSize += 1024 continue } for _, pid := range ps[:read/dwordSize] { ret = append(ret, int32(pid)) } return ret, nil } } func PidExistsWithContext(ctx context.Context, pid int32) (bool, error) { if pid == 0 { // special case for pid 0 System Idle Process return true, nil } if pid < 0 { return false, fmt.Errorf("invalid pid %v", pid) } if pid%4 != 0 { // OpenProcess will succeed even on non-existing pid here https://devblogs.microsoft.com/oldnewthing/20080606-00/?p=22043 // so we list every pid just to be sure and be future-proof pids, err := PidsWithContext(ctx) if err != nil { return false, err } for _, i := range pids { if i == pid { return true, err } } return false, err } const STILL_ACTIVE = 259 // https://docs.microsoft.com/en-us/windows/win32/api/processthreadsapi/nf-processthreadsapi-getexitcodeprocess h, err := windows.OpenProcess(processQueryInformation, false, uint32(pid)) if err == windows.ERROR_ACCESS_DENIED { return true, nil } if err == windows.ERROR_INVALID_PARAMETER { return false, nil } if err != nil { return false, err } defer syscall.CloseHandle(syscall.Handle(h)) var exitCode uint32 err = windows.GetExitCodeProcess(h, &exitCode) return exitCode == STILL_ACTIVE, err } func (p *Process) PpidWithContext(ctx context.Context) (int32, error) { // if cached already, return from cache cachedPpid := p.getPpid() if cachedPpid != 0 { return cachedPpid, nil } ppid, _, _, err := getFromSnapProcess(p.Pid) if err != nil { return 0, err } // no errors and not cached already, so cache it p.setPpid(ppid) return ppid, nil } func (p *Process) NameWithContext(ctx context.Context) (string, error) { ppid, _, name, err := getFromSnapProcess(p.Pid) if err != nil { return "", fmt.Errorf("could not get Name: %s", err) } // if no errors and not cached already, cache ppid p.parent = ppid if 0 == p.getPpid() { p.setPpid(ppid) } return name, nil } func (p *Process) TgidWithContext(ctx context.Context) (int32, error) { return 0, common.ErrNotImplementedError } func (p *Process) ExeWithContext(ctx context.Context) (string, error) { c, err := windows.OpenProcess(processQueryInformation, false, uint32(p.Pid)) if err != nil { return "", err } defer windows.CloseHandle(c) buf := make([]uint16, syscall.MAX_LONG_PATH) size := uint32(syscall.MAX_LONG_PATH) if err := procQueryFullProcessImageNameW.Find(); err == nil { // Vista+ ret, _, err := procQueryFullProcessImageNameW.Call( uintptr(c), uintptr(0), uintptr(unsafe.Pointer(&buf[0])), uintptr(unsafe.Pointer(&size))) if ret == 0 { return "", err } return windows.UTF16ToString(buf[:]), nil } // XP fallback ret, _, err := procGetProcessImageFileNameW.Call(uintptr(c), uintptr(unsafe.Pointer(&buf[0])), uintptr(size)) if ret == 0 { return "", err } return common.ConvertDOSPath(windows.UTF16ToString(buf[:])), nil } func (p *Process) CmdlineWithContext(_ context.Context) (string, error) { cmdline, err := getProcessCommandLine(p.Pid) if err != nil { return "", fmt.Errorf("could not get CommandLine: %s", err) } return cmdline, nil } func (p *Process) CmdlineSliceWithContext(ctx context.Context) ([]string, error) { cmdline, err := p.CmdlineWithContext(ctx) if err != nil { return nil, err } return strings.Split(cmdline, " "), nil } func (p *Process) createTimeWithContext(ctx context.Context) (int64, error) { ru, err := getRusage(p.Pid) if err != nil { return 0, fmt.Errorf("could not get CreationDate: %s", err) } return ru.CreationTime.Nanoseconds() / 1000000, nil } func (p *Process) CwdWithContext(_ context.Context) (string, error) { h, err := windows.OpenProcess(processQueryInformation|windows.PROCESS_VM_READ, false, uint32(p.Pid)) if err == windows.ERROR_ACCESS_DENIED || err == windows.ERROR_INVALID_PARAMETER { return "", nil } if err != nil { return "", err } defer syscall.CloseHandle(syscall.Handle(h)) procIs32Bits := is32BitProcess(h) if procIs32Bits { userProcParams, err := getUserProcessParams32(h) if err != nil { return "", err } if userProcParams.CurrentDirectoryPathNameLength > 0 { cwd := readProcessMemory(syscall.Handle(h), procIs32Bits, uint64(userProcParams.CurrentDirectoryPathAddress), uint(userProcParams.CurrentDirectoryPathNameLength)) if len(cwd) != int(userProcParams.CurrentDirectoryPathAddress) { return "", errors.New("cannot read current working directory") } return convertUTF16ToString(cwd), nil } } else { userProcParams, err := getUserProcessParams64(h) if err != nil { return "", err } if userProcParams.CurrentDirectoryPathNameLength > 0 { cwd := readProcessMemory(syscall.Handle(h), procIs32Bits, userProcParams.CurrentDirectoryPathAddress, uint(userProcParams.CurrentDirectoryPathNameLength)) if len(cwd) != int(userProcParams.CurrentDirectoryPathNameLength) { return "", errors.New("cannot read current working directory") } return convertUTF16ToString(cwd), nil } } //if we reach here, we have no cwd return "", nil } func (p *Process) ParentWithContext(ctx context.Context) (*Process, error) { ppid, err := p.PpidWithContext(ctx) if err != nil { return nil, fmt.Errorf("could not get ParentProcessID: %s", err) } return NewProcessWithContext(ctx, ppid) } func (p *Process) StatusWithContext(ctx context.Context) (string, error) { return "", common.ErrNotImplementedError } func (p *Process) ForegroundWithContext(ctx context.Context) (bool, error) { return false, common.ErrNotImplementedError } func (p *Process) UsernameWithContext(ctx context.Context) (string, error) { pid := p.Pid c, err := windows.OpenProcess(processQueryInformation, false, uint32(pid)) if err != nil { return "", err } defer windows.CloseHandle(c) var token syscall.Token err = syscall.OpenProcessToken(syscall.Handle(c), syscall.TOKEN_QUERY, &token) if err != nil { return "", err } defer token.Close() tokenUser, err := token.GetTokenUser() if err != nil { return "", err } user, domain, _, err := tokenUser.User.Sid.LookupAccount("") return domain + "\\" + user, err } func (p *Process) UidsWithContext(ctx context.Context) ([]int32, error) { return nil, common.ErrNotImplementedError } func (p *Process) GidsWithContext(ctx context.Context) ([]int32, error) { return nil, common.ErrNotImplementedError } func (p *Process) GroupsWithContext(ctx context.Context) ([]int32, error) { return nil, common.ErrNotImplementedError } func (p *Process) TerminalWithContext(ctx context.Context) (string, error) { return "", common.ErrNotImplementedError } // priorityClasses maps a win32 priority class to its WMI equivalent Win32_Process.Priority // https://docs.microsoft.com/en-us/windows/desktop/api/processthreadsapi/nf-processthreadsapi-getpriorityclass // https://docs.microsoft.com/en-us/windows/desktop/cimwin32prov/win32-process var priorityClasses = map[int]int32{ 0x00008000: 10, // ABOVE_NORMAL_PRIORITY_CLASS 0x00004000: 6, // BELOW_NORMAL_PRIORITY_CLASS 0x00000080: 13, // HIGH_PRIORITY_CLASS 0x00000040: 4, // IDLE_PRIORITY_CLASS 0x00000020: 8, // NORMAL_PRIORITY_CLASS 0x00000100: 24, // REALTIME_PRIORITY_CLASS } func (p *Process) NiceWithContext(ctx context.Context) (int32, error) { c, err := windows.OpenProcess(processQueryInformation, false, uint32(p.Pid)) if err != nil { return 0, err } defer windows.CloseHandle(c) ret, _, err := procGetPriorityClass.Call(uintptr(c)) if ret == 0 { return 0, err } priority, ok := priorityClasses[int(ret)] if !ok { return 0, fmt.Errorf("unknown priority class %v", ret) } return priority, nil } func (p *Process) IOniceWithContext(ctx context.Context) (int32, error) { return 0, common.ErrNotImplementedError } func (p *Process) RlimitWithContext(ctx context.Context) ([]RlimitStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) RlimitUsageWithContext(ctx context.Context, gatherUsed bool) ([]RlimitStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) IOCountersWithContext(ctx context.Context) (*IOCountersStat, error) { c, err := windows.OpenProcess(processQueryInformation, false, uint32(p.Pid)) if err != nil { return nil, err } defer windows.CloseHandle(c) var ioCounters ioCounters ret, _, err := procGetProcessIoCounters.Call(uintptr(c), uintptr(unsafe.Pointer(&ioCounters))) if ret == 0 { return nil, err } stats := &IOCountersStat{ ReadCount: ioCounters.ReadOperationCount, ReadBytes: ioCounters.ReadTransferCount, WriteCount: ioCounters.WriteOperationCount, WriteBytes: ioCounters.WriteTransferCount, } return stats, nil } func (p *Process) NumCtxSwitchesWithContext(ctx context.Context) (*NumCtxSwitchesStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) NumFDsWithContext(ctx context.Context) (int32, error) { return 0, common.ErrNotImplementedError } func (p *Process) NumThreadsWithContext(ctx context.Context) (int32, error) { ppid, ret, _, err := getFromSnapProcess(p.Pid) if err != nil { return 0, err } // if no errors and not cached already, cache ppid p.parent = ppid if 0 == p.getPpid() { p.setPpid(ppid) } return ret, nil } func (p *Process) ThreadsWithContext(ctx context.Context) (map[int32]*cpu.TimesStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) TimesWithContext(ctx context.Context) (*cpu.TimesStat, error) { sysTimes, err := getProcessCPUTimes(p.Pid) if err != nil { return nil, err } // User and kernel times are represented as a FILETIME structure // which contains a 64-bit value representing the number of // 100-nanosecond intervals since January 1, 1601 (UTC): // http://msdn.microsoft.com/en-us/library/ms724284(VS.85).aspx // To convert it into a float representing the seconds that the // process has executed in user/kernel mode I borrowed the code // below from psutil's _psutil_windows.c, and in turn from Python's // Modules/posixmodule.c user := float64(sysTimes.UserTime.HighDateTime)*429.4967296 + float64(sysTimes.UserTime.LowDateTime)*1e-7 kernel := float64(sysTimes.KernelTime.HighDateTime)*429.4967296 + float64(sysTimes.KernelTime.LowDateTime)*1e-7 return &cpu.TimesStat{ User: user, System: kernel, }, nil } func (p *Process) CPUAffinityWithContext(ctx context.Context) ([]int32, error) { return nil, common.ErrNotImplementedError } func (p *Process) MemoryInfoWithContext(ctx context.Context) (*MemoryInfoStat, error) { mem, err := getMemoryInfo(p.Pid) if err != nil { return nil, err } ret := &MemoryInfoStat{ RSS: uint64(mem.WorkingSetSize), VMS: uint64(mem.PagefileUsage), } return ret, nil } func (p *Process) MemoryInfoExWithContext(ctx context.Context) (*MemoryInfoExStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) PageFaultsWithContext(ctx context.Context) (*PageFaultsStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) ChildrenWithContext(ctx context.Context) ([]*Process, error) { out := []*Process{} snap, err := windows.CreateToolhelp32Snapshot(windows.TH32CS_SNAPPROCESS, uint32(0)) if err != nil { return out, err } defer windows.CloseHandle(snap) var pe32 windows.ProcessEntry32 pe32.Size = uint32(unsafe.Sizeof(pe32)) if err := windows.Process32First(snap, &pe32); err != nil { return out, err } for { if pe32.ParentProcessID == uint32(p.Pid) { p, err := NewProcessWithContext(ctx, int32(pe32.ProcessID)) if err == nil { out = append(out, p) } } if err = windows.Process32Next(snap, &pe32); err != nil { break } } return out, nil } func (p *Process) OpenFilesWithContext(ctx context.Context) ([]OpenFilesStat, error) { files := make([]OpenFilesStat, 0) fileExists := make(map[string]bool) process, err := windows.OpenProcess(common.ProcessQueryInformation, false, uint32(p.Pid)) if err != nil { return nil, err } buffer := make([]byte, 1024) var size uint32 st := common.CallWithExpandingBuffer( func() common.NtStatus { return common.NtQuerySystemInformation( common.SystemExtendedHandleInformationClass, &buffer[0], uint32(len(buffer)), &size, ) }, &buffer, &size, ) if st.IsError() { return nil, st.Error() } handlesList := (*common.SystemExtendedHandleInformation)(unsafe.Pointer(&buffer[0])) handles := make([]common.SystemExtendedHandleTableEntryInformation, int(handlesList.NumberOfHandles)) hdr := (*reflect.SliceHeader)(unsafe.Pointer(&handles)) hdr.Data = uintptr(unsafe.Pointer(&handlesList.Handles[0])) currentProcess, err := windows.GetCurrentProcess() if err != nil { return nil, err } for _, handle := range handles { var file uintptr if int32(handle.UniqueProcessId) != p.Pid { continue } if windows.DuplicateHandle(process, windows.Handle(handle.HandleValue), currentProcess, (*windows.Handle)(&file), 0, true, windows.DUPLICATE_SAME_ACCESS) != nil { continue } fileType, _ := windows.GetFileType(windows.Handle(file)) if fileType != windows.FILE_TYPE_DISK { continue } var fileName string ch := make(chan struct{}) go func() { var buf [syscall.MAX_LONG_PATH]uint16 n, err := windows.GetFinalPathNameByHandle(windows.Handle(file), &buf[0], syscall.MAX_LONG_PATH, 0) if err != nil { return } fileName = string(utf16.Decode(buf[:n])) ch <- struct{}{} }() select { case <-time.NewTimer(100 * time.Millisecond).C: continue case <-ch: fileInfo, _ := os.Stat(fileName) if fileInfo.IsDir() { continue } if _, exists := fileExists[fileName]; !exists { files = append(files, OpenFilesStat{ Path: fileName, Fd: uint64(file), }) fileExists[fileName] = true } case <-ctx.Done(): return files, ctx.Err() } } return files, nil } func (p *Process) ConnectionsWithContext(ctx context.Context) ([]net.ConnectionStat, error) { return net.ConnectionsPidWithContext(ctx, "all", p.Pid) } func (p *Process) ConnectionsMaxWithContext(ctx context.Context, max int) ([]net.ConnectionStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) NetIOCountersWithContext(ctx context.Context, pernic bool) ([]net.IOCountersStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) MemoryMapsWithContext(ctx context.Context, grouped bool) (*[]MemoryMapsStat, error) { return nil, common.ErrNotImplementedError } func (p *Process) SendSignalWithContext(ctx context.Context, sig syscall.Signal) error { return common.ErrNotImplementedError } func (p *Process) SuspendWithContext(ctx context.Context) error { c, err := windows.OpenProcess(windows.PROCESS_SUSPEND_RESUME, false, uint32(p.Pid)) if err != nil { return err } defer windows.CloseHandle(c) r1, _, _ := procNtSuspendProcess.Call(uintptr(c)) if r1 != 0 { // See https://docs.microsoft.com/en-us/openspecs/windows_protocols/ms-erref/596a1078-e883-4972-9bbc-49e60bebca55 return fmt.Errorf("NtStatus='0x%.8X'", r1) } return nil } func (p *Process) ResumeWithContext(ctx context.Context) error { c, err := windows.OpenProcess(windows.PROCESS_SUSPEND_RESUME, false, uint32(p.Pid)) if err != nil { return err } defer windows.CloseHandle(c) r1, _, _ := procNtResumeProcess.Call(uintptr(c)) if r1 != 0 { // See https://docs.microsoft.com/en-us/openspecs/windows_protocols/ms-erref/596a1078-e883-4972-9bbc-49e60bebca55 return fmt.Errorf("NtStatus='0x%.8X'", r1) } return nil } func (p *Process) TerminateWithContext(ctx context.Context) error { proc, err := windows.OpenProcess(windows.PROCESS_TERMINATE, false, uint32(p.Pid)) if err != nil { return err } err = windows.TerminateProcess(proc, 0) windows.CloseHandle(proc) return err } func (p *Process) KillWithContext(ctx context.Context) error { process, err := os.FindProcess(int(p.Pid)) if err != nil { return err } return process.Kill() } func (p *Process) EnvironWithContext(ctx context.Context) ([]string, error) { envVars, err := getProcessEnvironmentVariables(p.Pid, ctx) if err != nil { return nil, fmt.Errorf("could not get environment variables: %s", err) } return envVars, nil } // retrieve Ppid in a thread-safe manner func (p *Process) getPpid() int32 { p.parentMutex.RLock() defer p.parentMutex.RUnlock() return p.parent } // cache Ppid in a thread-safe manner (WINDOWS ONLY) // see https://psutil.readthedocs.io/en/latest/#psutil.Process.ppid func (p *Process) setPpid(ppid int32) { p.parentMutex.Lock() defer p.parentMutex.Unlock() p.parent = ppid } func getFromSnapProcess(pid int32) (int32, int32, string, error) { snap, err := windows.CreateToolhelp32Snapshot(windows.TH32CS_SNAPPROCESS, uint32(pid)) if err != nil { return 0, 0, "", err } defer windows.CloseHandle(snap) var pe32 windows.ProcessEntry32 pe32.Size = uint32(unsafe.Sizeof(pe32)) if err = windows.Process32First(snap, &pe32); err != nil { return 0, 0, "", err } for { if pe32.ProcessID == uint32(pid) { szexe := windows.UTF16ToString(pe32.ExeFile[:]) return int32(pe32.ParentProcessID), int32(pe32.Threads), szexe, nil } if err = windows.Process32Next(snap, &pe32); err != nil { break } } return 0, 0, "", fmt.Errorf("couldn't find pid: %d", pid) } func ProcessesWithContext(ctx context.Context) ([]*Process, error) { out := []*Process{} pids, err := PidsWithContext(ctx) if err != nil { return out, fmt.Errorf("could not get Processes %s", err) } for _, pid := range pids { p, err := NewProcessWithContext(ctx, pid) if err != nil { continue } out = append(out, p) } return out, nil } func getRusage(pid int32) (*windows.Rusage, error) { var CPU windows.Rusage c, err := windows.OpenProcess(processQueryInformation, false, uint32(pid)) if err != nil { return nil, err } defer windows.CloseHandle(c) if err := windows.GetProcessTimes(c, &CPU.CreationTime, &CPU.ExitTime, &CPU.KernelTime, &CPU.UserTime); err != nil { return nil, err } return &CPU, nil } func getMemoryInfo(pid int32) (PROCESS_MEMORY_COUNTERS, error) { var mem PROCESS_MEMORY_COUNTERS c, err := windows.OpenProcess(processQueryInformation, false, uint32(pid)) if err != nil { return mem, err } defer windows.CloseHandle(c) if err := getProcessMemoryInfo(c, &mem); err != nil { return mem, err } return mem, err } func getProcessMemoryInfo(h windows.Handle, mem *PROCESS_MEMORY_COUNTERS) (err error) { r1, _, e1 := syscall.Syscall(procGetProcessMemoryInfo.Addr(), 3, uintptr(h), uintptr(unsafe.Pointer(mem)), uintptr(unsafe.Sizeof(*mem))) if r1 == 0 { if e1 != 0 { err = error(e1) } else { err = syscall.EINVAL } } return } type SYSTEM_TIMES struct { CreateTime syscall.Filetime ExitTime syscall.Filetime KernelTime syscall.Filetime UserTime syscall.Filetime } func getProcessCPUTimes(pid int32) (SYSTEM_TIMES, error) { var times SYSTEM_TIMES h, err := windows.OpenProcess(processQueryInformation, false, uint32(pid)) if err != nil { return times, err } defer windows.CloseHandle(h) err = syscall.GetProcessTimes( syscall.Handle(h), ×.CreateTime, ×.ExitTime, ×.KernelTime, ×.UserTime, ) return times, err } func getUserProcessParams32(handle windows.Handle) (rtlUserProcessParameters32, error) { pebAddress, err := queryPebAddress(syscall.Handle(handle), true) if err != nil { return rtlUserProcessParameters32{}, fmt.Errorf("cannot locate process PEB: %w", err) } buf := readProcessMemory(syscall.Handle(handle), true, pebAddress, uint(unsafe.Sizeof(processEnvironmentBlock32{}))) if len(buf) != int(unsafe.Sizeof(processEnvironmentBlock32{})) { return rtlUserProcessParameters32{}, fmt.Errorf("cannot read process PEB") } peb := (*processEnvironmentBlock32)(unsafe.Pointer(&buf[0])) userProcessAddress := uint64(peb.ProcessParameters) buf = readProcessMemory(syscall.Handle(handle), true, userProcessAddress, uint(unsafe.Sizeof(rtlUserProcessParameters32{}))) if len(buf) != int(unsafe.Sizeof(rtlUserProcessParameters32{})) { return rtlUserProcessParameters32{}, fmt.Errorf("cannot read user process parameters") } return *(*rtlUserProcessParameters32)(unsafe.Pointer(&buf[0])), nil } func getUserProcessParams64(handle windows.Handle) (rtlUserProcessParameters64, error) { pebAddress, err := queryPebAddress(syscall.Handle(handle), false) if err != nil { return rtlUserProcessParameters64{}, fmt.Errorf("cannot locate process PEB: %w", err) } buf := readProcessMemory(syscall.Handle(handle), false, pebAddress, uint(unsafe.Sizeof(processEnvironmentBlock64{}))) if len(buf) != int(unsafe.Sizeof(processEnvironmentBlock64{})) { return rtlUserProcessParameters64{}, fmt.Errorf("cannot read process PEB") } peb := (*processEnvironmentBlock64)(unsafe.Pointer(&buf[0])) userProcessAddress := peb.ProcessParameters buf = readProcessMemory(syscall.Handle(handle), false, userProcessAddress, uint(unsafe.Sizeof(rtlUserProcessParameters64{}))) if len(buf) != int(unsafe.Sizeof(rtlUserProcessParameters64{})) { return rtlUserProcessParameters64{}, fmt.Errorf("cannot read user process parameters") } return *(*rtlUserProcessParameters64)(unsafe.Pointer(&buf[0])), nil } func is32BitProcess(h windows.Handle) bool { const ( PROCESSOR_ARCHITECTURE_INTEL = 0 PROCESSOR_ARCHITECTURE_ARM = 5 PROCESSOR_ARCHITECTURE_ARM64 = 12 PROCESSOR_ARCHITECTURE_IA64 = 6 PROCESSOR_ARCHITECTURE_AMD64 = 9 ) var procIs32Bits bool switch processorArchitecture { case PROCESSOR_ARCHITECTURE_INTEL: fallthrough case PROCESSOR_ARCHITECTURE_ARM: procIs32Bits = true case PROCESSOR_ARCHITECTURE_ARM64: fallthrough case PROCESSOR_ARCHITECTURE_IA64: fallthrough case PROCESSOR_ARCHITECTURE_AMD64: var wow64 uint ret, _, _ := common.ProcNtQueryInformationProcess.Call( uintptr(h), uintptr(common.ProcessWow64Information), uintptr(unsafe.Pointer(&wow64)), uintptr(unsafe.Sizeof(wow64)), uintptr(0), ) if int(ret) >= 0 { if wow64 != 0 { procIs32Bits = true } } else { //if the OS does not support the call, we fallback into the bitness of the app if unsafe.Sizeof(wow64) == 4 { procIs32Bits = true } } default: //for other unknown platforms, we rely on process platform if unsafe.Sizeof(processorArchitecture) == 8 { procIs32Bits = false } else { procIs32Bits = true } } return procIs32Bits } func getProcessEnvironmentVariables(pid int32, ctx context.Context) ([]string, error) { h, err := windows.OpenProcess(processQueryInformation|windows.PROCESS_VM_READ, false, uint32(pid)) if err == windows.ERROR_ACCESS_DENIED || err == windows.ERROR_INVALID_PARAMETER { return nil, nil } if err != nil { return nil, err } defer syscall.CloseHandle(syscall.Handle(h)) procIs32Bits := is32BitProcess(h) var processParameterBlockAddress uint64 if procIs32Bits { peb, err := getUserProcessParams32(h) if err != nil { return nil, err } processParameterBlockAddress = uint64(peb.EnvironmentAddress) } else { peb, err := getUserProcessParams64(h) if err != nil { return nil, err } processParameterBlockAddress = peb.EnvironmentAddress } envvarScanner := bufio.NewScanner(&processReader{ processHandle: h, is32BitProcess: procIs32Bits, offset: processParameterBlockAddress, }) envvarScanner.Split(func(data []byte, atEOF bool) (advance int, token []byte, err error) { if atEOF && len(data) == 0 { return 0, nil, nil } // Check for UTF-16 zero character for i := 0; i < len(data)-1; i += 2 { if data[i] == 0 && data[i+1] == 0 { return i + 2, data[0:i], nil } } if atEOF { return len(data), data, nil } // Request more data return 0, nil, nil }) var envVars []string for envvarScanner.Scan() { entry := envvarScanner.Bytes() if len(entry) == 0 { break // Block is finished } envVars = append(envVars, convertUTF16ToString(entry)) select { case <-ctx.Done(): break default: continue } } if err := envvarScanner.Err(); err != nil { return nil, err } return envVars, nil } type processReader struct { processHandle windows.Handle is32BitProcess bool offset uint64 } func (p *processReader) Read(buf []byte) (int, error) { processMemory := readProcessMemory(syscall.Handle(p.processHandle), p.is32BitProcess, p.offset, uint(len(buf))) if len(processMemory) == 0 { return 0, io.EOF } copy(buf, processMemory) p.offset += uint64(len(processMemory)) return len(processMemory), nil } func getProcessCommandLine(pid int32) (string, error) { h, err := windows.OpenProcess(processQueryInformation|windows.PROCESS_VM_READ, false, uint32(pid)) if err == windows.ERROR_ACCESS_DENIED || err == windows.ERROR_INVALID_PARAMETER { return "", nil } if err != nil { return "", err } defer syscall.CloseHandle(syscall.Handle(h)) procIs32Bits := is32BitProcess(h) if procIs32Bits { userProcParams, err := getUserProcessParams32(h) if err != nil { return "", err } if userProcParams.CommandLineLength > 0 { cmdLine := readProcessMemory(syscall.Handle(h), procIs32Bits, uint64(userProcParams.CommandLineAddress), uint(userProcParams.CommandLineLength)) if len(cmdLine) != int(userProcParams.CommandLineLength) { return "", errors.New("cannot read cmdline") } return convertUTF16ToString(cmdLine), nil } } else { userProcParams, err := getUserProcessParams64(h) if err != nil { return "", err } if userProcParams.CommandLineLength > 0 { cmdLine := readProcessMemory(syscall.Handle(h), procIs32Bits, userProcParams.CommandLineAddress, uint(userProcParams.CommandLineLength)) if len(cmdLine) != int(userProcParams.CommandLineLength) { return "", errors.New("cannot read cmdline") } return convertUTF16ToString(cmdLine), nil } } //if we reach here, we have no command line return "", nil } func convertUTF16ToString(src []byte) string { srcLen := len(src) / 2 codePoints := make([]uint16, srcLen) srcIdx := 0 for i := 0; i < srcLen; i++ { codePoints[i] = uint16(src[srcIdx]) | uint16(src[srcIdx+1])<<8 srcIdx += 2 } return syscall.UTF16ToString(codePoints) }