// Copyright (c) 2012 VMware, Inc. package sigar /* #include #include #include #include #include #include #include #include #include */ import "C" import ( "bytes" "encoding/binary" "fmt" "io" "syscall" "time" "unsafe" ) func (self *LoadAverage) Get() error { avg := []C.double{0, 0, 0} C.getloadavg(&avg[0], C.int(len(avg))) self.One = float64(avg[0]) self.Five = float64(avg[1]) self.Fifteen = float64(avg[2]) return nil } func (self *Uptime) Get() error { tv := syscall.Timeval32{} if err := sysctlbyname("kern.boottime", &tv); err != nil { return err } self.Length = time.Since(time.Unix(int64(tv.Sec), int64(tv.Usec)*1000)).Seconds() return nil } func (self *Mem) Get() error { var vmstat C.vm_statistics_data_t if err := sysctlbyname("hw.memsize", &self.Total); err != nil { return err } if err := vm_info(&vmstat); err != nil { return err } kern := uint64(vmstat.inactive_count) << 12 self.Free = uint64(vmstat.free_count) << 12 self.Used = self.Total - self.Free self.ActualFree = self.Free + kern self.ActualUsed = self.Used - kern return nil } type xsw_usage struct { Total, Avail, Used uint64 } func (self *Swap) Get() error { sw_usage := xsw_usage{} if err := sysctlbyname("vm.swapusage", &sw_usage); err != nil { return err } self.Total = sw_usage.Total self.Used = sw_usage.Used self.Free = sw_usage.Avail return nil } func (self *Cpu) Get() error { var count C.mach_msg_type_number_t = C.HOST_CPU_LOAD_INFO_COUNT var cpuload C.host_cpu_load_info_data_t status := C.host_statistics(C.host_t(C.mach_host_self()), C.HOST_CPU_LOAD_INFO, C.host_info_t(unsafe.Pointer(&cpuload)), &count) if status != C.KERN_SUCCESS { return fmt.Errorf("host_statistics error=%d", status) } self.User = uint64(cpuload.cpu_ticks[C.CPU_STATE_USER]) self.Sys = uint64(cpuload.cpu_ticks[C.CPU_STATE_SYSTEM]) self.Idle = uint64(cpuload.cpu_ticks[C.CPU_STATE_IDLE]) self.Nice = uint64(cpuload.cpu_ticks[C.CPU_STATE_NICE]) return nil } func (self *CpuList) Get() error { var count C.mach_msg_type_number_t var cpuload *C.processor_cpu_load_info_data_t var ncpu C.natural_t status := C.host_processor_info(C.host_t(C.mach_host_self()), C.PROCESSOR_CPU_LOAD_INFO, &ncpu, (*C.processor_info_array_t)(unsafe.Pointer(&cpuload)), &count) if status != C.KERN_SUCCESS { return fmt.Errorf("host_processor_info error=%d", status) } // jump through some cgo casting hoops and ensure we properly free // the memory that cpuload points to target := C.vm_map_t(C.mach_task_self_) address := C.vm_address_t(uintptr(unsafe.Pointer(cpuload))) defer C.vm_deallocate(target, address, C.vm_size_t(ncpu)) // the body of struct processor_cpu_load_info // aka processor_cpu_load_info_data_t var cpu_ticks [C.CPU_STATE_MAX]uint32 // copy the cpuload array to a []byte buffer // where we can binary.Read the data size := int(ncpu) * binary.Size(cpu_ticks) buf := C.GoBytes(unsafe.Pointer(cpuload), C.int(size)) bbuf := bytes.NewBuffer(buf) self.List = make([]Cpu, 0, ncpu) for i := 0; i < int(ncpu); i++ { cpu := Cpu{} err := binary.Read(bbuf, binary.LittleEndian, &cpu_ticks) if err != nil { return err } cpu.User = uint64(cpu_ticks[C.CPU_STATE_USER]) cpu.Sys = uint64(cpu_ticks[C.CPU_STATE_SYSTEM]) cpu.Idle = uint64(cpu_ticks[C.CPU_STATE_IDLE]) cpu.Nice = uint64(cpu_ticks[C.CPU_STATE_NICE]) self.List = append(self.List, cpu) } return nil } func (self *FileSystemList) Get() error { num, err := getfsstat(nil, C.MNT_NOWAIT) if num < 0 { return err } buf := make([]syscall.Statfs_t, num) num, err = getfsstat(buf, C.MNT_NOWAIT) if err != nil { return err } fslist := make([]FileSystem, 0, num) for i := 0; i < num; i++ { fs := FileSystem{} fs.DirName = bytePtrToString(&buf[i].Mntonname[0]) fs.DevName = bytePtrToString(&buf[i].Mntfromname[0]) fs.SysTypeName = bytePtrToString(&buf[i].Fstypename[0]) fslist = append(fslist, fs) } self.List = fslist return err } func (self *ProcList) Get() error { n := C.proc_listpids(C.PROC_ALL_PIDS, 0, nil, 0) if n <= 0 { return syscall.EINVAL } buf := make([]byte, n) n = C.proc_listpids(C.PROC_ALL_PIDS, 0, unsafe.Pointer(&buf[0]), n) if n <= 0 { return syscall.ENOMEM } var pid int32 num := int(n) / binary.Size(pid) list := make([]int, 0, num) bbuf := bytes.NewBuffer(buf) for i := 0; i < num; i++ { if err := binary.Read(bbuf, binary.LittleEndian, &pid); err != nil { return err } if pid == 0 { continue } list = append(list, int(pid)) } self.List = list return nil } func (self *ProcState) Get(pid int) error { info := C.struct_proc_taskallinfo{} if err := task_info(pid, &info); err != nil { return err } self.Name = C.GoString(&info.pbsd.pbi_comm[0]) switch info.pbsd.pbi_status { case C.SIDL: self.State = RunStateIdle case C.SRUN: self.State = RunStateRun case C.SSLEEP: self.State = RunStateSleep case C.SSTOP: self.State = RunStateStop case C.SZOMB: self.State = RunStateZombie default: self.State = RunStateUnknown } self.Ppid = int(info.pbsd.pbi_ppid) self.Tty = int(info.pbsd.e_tdev) self.Priority = int(info.ptinfo.pti_priority) self.Nice = int(info.pbsd.pbi_nice) return nil } func (self *ProcMem) Get(pid int) error { info := C.struct_proc_taskallinfo{} if err := task_info(pid, &info); err != nil { return err } self.Size = uint64(info.ptinfo.pti_virtual_size) self.Resident = uint64(info.ptinfo.pti_resident_size) self.PageFaults = uint64(info.ptinfo.pti_faults) return nil } func (self *ProcTime) Get(pid int) error { info := C.struct_proc_taskallinfo{} if err := task_info(pid, &info); err != nil { return err } self.User = uint64(info.ptinfo.pti_total_user) / uint64(time.Millisecond) self.Sys = uint64(info.ptinfo.pti_total_system) / uint64(time.Millisecond) self.Total = self.User + self.Sys self.StartTime = (uint64(info.pbsd.pbi_start_tvsec) * 1000) + (uint64(info.pbsd.pbi_start_tvusec) / 1000) return nil } func (self *ProcArgs) Get(pid int) error { var args []string argv := func(arg string) { args = append(args, arg) } err := kern_procargs(pid, nil, argv, nil) self.List = args return err } func (self *ProcExe) Get(pid int) error { exe := func(arg string) { self.Name = arg } return kern_procargs(pid, exe, nil, nil) } // wrapper around sysctl KERN_PROCARGS2 // callbacks params are optional, // up to the caller as to which pieces of data they want func kern_procargs(pid int, exe func(string), argv func(string), env func(string, string)) error { mib := []C.int{C.CTL_KERN, C.KERN_PROCARGS2, C.int(pid)} argmax := uintptr(C.ARG_MAX) buf := make([]byte, argmax) err := sysctl(mib, &buf[0], &argmax, nil, 0) if err != nil { return nil } bbuf := bytes.NewBuffer(buf) bbuf.Truncate(int(argmax)) var argc int32 binary.Read(bbuf, binary.LittleEndian, &argc) path, err := bbuf.ReadBytes(0) if exe != nil { exe(string(chop(path))) } // skip trailing \0's for { c, _ := bbuf.ReadByte() if c != 0 { bbuf.UnreadByte() break // start of argv[0] } } for i := 0; i < int(argc); i++ { arg, err := bbuf.ReadBytes(0) if err == io.EOF { break } if argv != nil { argv(string(chop(arg))) } } if env == nil { return nil } delim := []byte{61} // "=" for { line, err := bbuf.ReadBytes(0) if err == io.EOF || line[0] == 0 { break } pair := bytes.SplitN(chop(line), delim, 2) env(string(pair[0]), string(pair[1])) } return nil } // XXX copied from zsyscall_darwin_amd64.go func sysctl(mib []C.int, old *byte, oldlen *uintptr, new *byte, newlen uintptr) (err error) { var p0 unsafe.Pointer p0 = unsafe.Pointer(&mib[0]) _, _, e1 := syscall.Syscall6(syscall.SYS___SYSCTL, uintptr(p0), uintptr(len(mib)), uintptr(unsafe.Pointer(old)), uintptr(unsafe.Pointer(oldlen)), uintptr(unsafe.Pointer(new)), uintptr(newlen)) if e1 != 0 { err = e1 } return } func vm_info(vmstat *C.vm_statistics_data_t) error { var count C.mach_msg_type_number_t = C.HOST_VM_INFO_COUNT status := C.host_statistics( C.host_t(C.mach_host_self()), C.HOST_VM_INFO, C.host_info_t(unsafe.Pointer(vmstat)), &count) if status != C.KERN_SUCCESS { return fmt.Errorf("host_statistics=%d", status) } return nil } // generic Sysctl buffer unmarshalling func sysctlbyname(name string, data interface{}) (err error) { val, err := syscall.Sysctl(name) if err != nil { return err } buf := []byte(val) switch v := data.(type) { case *uint64: *v = *(*uint64)(unsafe.Pointer(&buf[0])) return } bbuf := bytes.NewBuffer([]byte(val)) return binary.Read(bbuf, binary.LittleEndian, data) } // syscall.Getfsstat() wrapper is broken, roll our own to workaround. func getfsstat(buf []syscall.Statfs_t, flags int) (n int, err error) { var ptr uintptr var size uintptr if len(buf) > 0 { ptr = uintptr(unsafe.Pointer(&buf[0])) size = unsafe.Sizeof(buf[0]) * uintptr(len(buf)) } else { ptr = uintptr(0) size = uintptr(0) } trap := uintptr(syscall.SYS_GETFSSTAT64) ret, _, errno := syscall.Syscall(trap, ptr, size, uintptr(flags)) n = int(ret) if errno != 0 { err = errno } return } func task_info(pid int, info *C.struct_proc_taskallinfo) error { size := C.int(unsafe.Sizeof(*info)) ptr := unsafe.Pointer(info) n := C.proc_pidinfo(C.int(pid), C.PROC_PIDTASKALLINFO, 0, ptr, size) if n != size { return syscall.ENOMEM } return nil }