package procstat import ( "bytes" "fmt" "io/ioutil" "os/exec" "path/filepath" "strconv" "time" "github.com/influxdata/telegraf" "github.com/influxdata/telegraf/plugins/inputs" "github.com/shirou/gopsutil/process" ) var ( defaultPIDFinder = NewPgrep defaultProcess = NewProc ) type PID int32 type Procstat struct { PidFinder string `toml:"pid_finder"` PidFile string `toml:"pid_file"` Exe string Pattern string Prefix string CmdLineTag bool `toml:"cmdline_tag"` ProcessName string User string SystemdUnit string CGroup string `toml:"cgroup"` PidTag bool WinService string `toml:"win_service"` finder PIDFinder createPIDFinder func() (PIDFinder, error) procs map[PID]Process createProcess func(PID) (Process, error) } var sampleConfig = ` ## PID file to monitor process pid_file = "/var/run/nginx.pid" ## executable name (ie, pgrep ) # exe = "nginx" ## pattern as argument for pgrep (ie, pgrep -f ) # pattern = "nginx" ## user as argument for pgrep (ie, pgrep -u ) # user = "nginx" ## Systemd unit name # systemd_unit = "nginx.service" ## CGroup name or path # cgroup = "systemd/system.slice/nginx.service" ## Windows service name # win_service = "" ## override for process_name ## This is optional; default is sourced from /proc//status # process_name = "bar" ## Field name prefix # prefix = "" ## When true add the full cmdline as a tag. # cmdline_tag = false ## Add PID as a tag instead of a field; useful to differentiate between ## processes whose tags are otherwise the same. Can create a large number ## of series, use judiciously. # pid_tag = false ## Method to use when finding process IDs. Can be one of 'pgrep', or ## 'native'. The pgrep finder calls the pgrep executable in the PATH while ## the native finder performs the search directly in a manor dependent on the ## platform. Default is 'pgrep' # pid_finder = "pgrep" ` func (_ *Procstat) SampleConfig() string { return sampleConfig } func (_ *Procstat) Description() string { return "Monitor process cpu and memory usage" } func (p *Procstat) Gather(acc telegraf.Accumulator) error { if p.createPIDFinder == nil { switch p.PidFinder { case "native": p.createPIDFinder = NewNativeFinder case "pgrep": p.createPIDFinder = NewPgrep default: p.PidFinder = "pgrep" p.createPIDFinder = defaultPIDFinder } } if p.createProcess == nil { p.createProcess = defaultProcess } pids, tags, err := p.findPids(acc) if err != nil { fields := map[string]interface{}{ "pid_count": 0, "running": 0, "result_code": 1, } tags := map[string]string{ "pid_finder": p.PidFinder, "result": "lookup_error", } acc.AddFields("procstat_lookup", fields, tags) return err } procs, err := p.updateProcesses(pids, tags, p.procs) if err != nil { acc.AddError(fmt.Errorf("E! Error: procstat getting process, exe: [%s] pidfile: [%s] pattern: [%s] user: [%s] %s", p.Exe, p.PidFile, p.Pattern, p.User, err.Error())) } p.procs = procs for _, proc := range p.procs { p.addMetric(proc, acc) } fields := map[string]interface{}{ "pid_count": len(pids), "running": len(procs), "result_code": 0, } tags["pid_finder"] = p.PidFinder tags["result"] = "success" acc.AddFields("procstat_lookup", fields, tags) return nil } // Add metrics a single Process func (p *Procstat) addMetric(proc Process, acc telegraf.Accumulator) { var prefix string if p.Prefix != "" { prefix = p.Prefix + "_" } fields := map[string]interface{}{} //If process_name tag is not already set, set to actual name if _, nameInTags := proc.Tags()["process_name"]; !nameInTags { name, err := proc.Name() if err == nil { proc.Tags()["process_name"] = name } } //If user tag is not already set, set to actual name if _, ok := proc.Tags()["user"]; !ok { user, err := proc.Username() if err == nil { proc.Tags()["user"] = user } } //If pid is not present as a tag, include it as a field. if _, pidInTags := proc.Tags()["pid"]; !pidInTags { fields["pid"] = int32(proc.PID()) } //If cmd_line tag is true and it is not already set add cmdline as a tag if p.CmdLineTag { if _, ok := proc.Tags()["cmdline"]; !ok { Cmdline, err := proc.Cmdline() if err == nil { proc.Tags()["cmdline"] = Cmdline } } } numThreads, err := proc.NumThreads() if err == nil { fields[prefix+"num_threads"] = numThreads } fds, err := proc.NumFDs() if err == nil { fields[prefix+"num_fds"] = fds } ctx, err := proc.NumCtxSwitches() if err == nil { fields[prefix+"voluntary_context_switches"] = ctx.Voluntary fields[prefix+"involuntary_context_switches"] = ctx.Involuntary } faults, err := proc.PageFaults() if err == nil { fields[prefix+"minor_faults"] = faults.MinorFaults fields[prefix+"major_faults"] = faults.MajorFaults fields[prefix+"child_minor_faults"] = faults.ChildMinorFaults fields[prefix+"child_major_faults"] = faults.ChildMajorFaults } io, err := proc.IOCounters() if err == nil { fields[prefix+"read_count"] = io.ReadCount fields[prefix+"write_count"] = io.WriteCount fields[prefix+"read_bytes"] = io.ReadBytes fields[prefix+"write_bytes"] = io.WriteBytes } cpu_time, err := proc.Times() if err == nil { fields[prefix+"cpu_time_user"] = cpu_time.User fields[prefix+"cpu_time_system"] = cpu_time.System fields[prefix+"cpu_time_idle"] = cpu_time.Idle fields[prefix+"cpu_time_nice"] = cpu_time.Nice fields[prefix+"cpu_time_iowait"] = cpu_time.Iowait fields[prefix+"cpu_time_irq"] = cpu_time.Irq fields[prefix+"cpu_time_soft_irq"] = cpu_time.Softirq fields[prefix+"cpu_time_steal"] = cpu_time.Steal fields[prefix+"cpu_time_stolen"] = cpu_time.Stolen fields[prefix+"cpu_time_guest"] = cpu_time.Guest fields[prefix+"cpu_time_guest_nice"] = cpu_time.GuestNice } cpu_perc, err := proc.Percent(time.Duration(0)) if err == nil { fields[prefix+"cpu_usage"] = cpu_perc } mem, err := proc.MemoryInfo() if err == nil { fields[prefix+"memory_rss"] = mem.RSS fields[prefix+"memory_vms"] = mem.VMS fields[prefix+"memory_swap"] = mem.Swap fields[prefix+"memory_data"] = mem.Data fields[prefix+"memory_stack"] = mem.Stack fields[prefix+"memory_locked"] = mem.Locked } rlims, err := proc.RlimitUsage(true) if err == nil { for _, rlim := range rlims { var name string switch rlim.Resource { case process.RLIMIT_CPU: name = "cpu_time" case process.RLIMIT_DATA: name = "memory_data" case process.RLIMIT_STACK: name = "memory_stack" case process.RLIMIT_RSS: name = "memory_rss" case process.RLIMIT_NOFILE: name = "num_fds" case process.RLIMIT_MEMLOCK: name = "memory_locked" case process.RLIMIT_AS: name = "memory_vms" case process.RLIMIT_LOCKS: name = "file_locks" case process.RLIMIT_SIGPENDING: name = "signals_pending" case process.RLIMIT_NICE: name = "nice_priority" case process.RLIMIT_RTPRIO: name = "realtime_priority" default: continue } fields[prefix+"rlimit_"+name+"_soft"] = rlim.Soft fields[prefix+"rlimit_"+name+"_hard"] = rlim.Hard if name != "file_locks" { // gopsutil doesn't currently track the used file locks count fields[prefix+name] = rlim.Used } } } acc.AddFields("procstat", fields, proc.Tags()) } // Update monitored Processes func (p *Procstat) updateProcesses(pids []PID, tags map[string]string, prevInfo map[PID]Process) (map[PID]Process, error) { procs := make(map[PID]Process, len(prevInfo)) for _, pid := range pids { info, ok := prevInfo[pid] if ok { // Assumption: if a process has no name, it probably does not exist if name, _ := info.Name(); name == "" { continue } procs[pid] = info } else { proc, err := p.createProcess(pid) if err != nil { // No problem; process may have ended after we found it continue } // Assumption: if a process has no name, it probably does not exist if name, _ := proc.Name(); name == "" { continue } procs[pid] = proc // Add initial tags for k, v := range tags { proc.Tags()[k] = v } // Add pid tag if needed if p.PidTag { proc.Tags()["pid"] = strconv.Itoa(int(pid)) } if p.ProcessName != "" { proc.Tags()["process_name"] = p.ProcessName } } } return procs, nil } // Create and return PIDGatherer lazily func (p *Procstat) getPIDFinder() (PIDFinder, error) { if p.finder == nil { f, err := p.createPIDFinder() if err != nil { return nil, err } p.finder = f } return p.finder, nil } // Get matching PIDs and their initial tags func (p *Procstat) findPids(acc telegraf.Accumulator) ([]PID, map[string]string, error) { var pids []PID tags := make(map[string]string) var err error f, err := p.getPIDFinder() if err != nil { return nil, nil, err } if p.PidFile != "" { pids, err = f.PidFile(p.PidFile) tags = map[string]string{"pidfile": p.PidFile} } else if p.Exe != "" { pids, err = f.Pattern(p.Exe) tags = map[string]string{"exe": p.Exe} } else if p.Pattern != "" { pids, err = f.FullPattern(p.Pattern) tags = map[string]string{"pattern": p.Pattern} } else if p.User != "" { pids, err = f.Uid(p.User) tags = map[string]string{"user": p.User} } else if p.SystemdUnit != "" { pids, err = p.systemdUnitPIDs() tags = map[string]string{"systemd_unit": p.SystemdUnit} } else if p.CGroup != "" { pids, err = p.cgroupPIDs() tags = map[string]string{"cgroup": p.CGroup} } else if p.WinService != "" { pids, err = p.winServicePIDs() tags = map[string]string{"win_service": p.WinService} } else { err = fmt.Errorf("Either exe, pid_file, user, pattern, systemd_unit, cgroup, or win_service must be specified") } return pids, tags, err } // execCommand is so tests can mock out exec.Command usage. var execCommand = exec.Command func (p *Procstat) systemdUnitPIDs() ([]PID, error) { var pids []PID cmd := execCommand("systemctl", "show", p.SystemdUnit) out, err := cmd.Output() if err != nil { return nil, err } for _, line := range bytes.Split(out, []byte{'\n'}) { kv := bytes.SplitN(line, []byte{'='}, 2) if len(kv) != 2 { continue } if !bytes.Equal(kv[0], []byte("MainPID")) { continue } if len(kv[1]) == 0 { return nil, nil } pid, err := strconv.Atoi(string(kv[1])) if err != nil { return nil, fmt.Errorf("invalid pid '%s'", kv[1]) } pids = append(pids, PID(pid)) } return pids, nil } func (p *Procstat) cgroupPIDs() ([]PID, error) { var pids []PID procsPath := p.CGroup if procsPath[0] != '/' { procsPath = "/sys/fs/cgroup/" + procsPath } procsPath = filepath.Join(procsPath, "cgroup.procs") out, err := ioutil.ReadFile(procsPath) if err != nil { return nil, err } for _, pidBS := range bytes.Split(out, []byte{'\n'}) { if len(pidBS) == 0 { continue } pid, err := strconv.Atoi(string(pidBS)) if err != nil { return nil, fmt.Errorf("invalid pid '%s'", pidBS) } pids = append(pids, PID(pid)) } return pids, nil } func (p *Procstat) winServicePIDs() ([]PID, error) { var pids []PID pid, err := queryPidWithWinServiceName(p.WinService) if err != nil { return pids, err } pids = append(pids, PID(pid)) return pids, nil } func init() { inputs.Add("procstat", func() telegraf.Input { return &Procstat{} }) }