// Go port of Coda Hale's Metrics library // // // // Coda Hale's original work: package metrics import ( "os" "runtime" "strings" "time" "github.com/ledgerwatch/turbo-geth/log" ) // Enabled is checked by the constructor functions for all of the // standard metrics. If it is true, the metric returned is a stub. // // This global kill-switch helps quantify the observer effect and makes // for less cluttered pprof profiles. var Enabled = false // EnabledExpensive is a soft-flag meant for external packages to check if costly // metrics gathering is allowed or not. The goal is to separate standard metrics // for health monitoring and debug metrics that might impact runtime performance. var EnabledExpensive = false // enablerFlags is the CLI flag names to use to enable metrics collections. var enablerFlags = []string{"metrics"} // expensiveEnablerFlags is the CLI flag names to use to enable metrics collections. var expensiveEnablerFlags = []string{"metrics.expensive"} // Init enables or disables the metrics system. Since we need this to run before // any other code gets to create meters and timers, we'll actually do an ugly hack // and peek into the command line args for the metrics flag. func init() { for _, arg := range os.Args { flag := strings.TrimLeft(arg, "-") for _, enabler := range enablerFlags { if !Enabled && flag == enabler { log.Info("Enabling metrics collection") Enabled = true } } for _, enabler := range expensiveEnablerFlags { if !EnabledExpensive && flag == enabler { log.Info("Enabling expensive metrics collection") EnabledExpensive = true } } } } // CollectProcessMetrics periodically collects various metrics about the running // process. func CollectProcessMetrics(refresh time.Duration) { // Short circuit if the metrics system is disabled if !Enabled { return } refreshFreq := int64(refresh / time.Second) // Create the various data collectors cpuStats := make([]*CPUStats, 2) memstats := make([]*runtime.MemStats, 2) diskstats := make([]*DiskStats, 2) for i := 0; i < len(memstats); i++ { cpuStats[i] = new(CPUStats) memstats[i] = new(runtime.MemStats) diskstats[i] = new(DiskStats) } // Define the various metrics to collect var ( cpuSysLoad = GetOrRegisterGauge("system/cpu/sysload", DefaultRegistry) cpuSysWait = GetOrRegisterGauge("system/cpu/syswait", DefaultRegistry) cpuProcLoad = GetOrRegisterGauge("system/cpu/procload", DefaultRegistry) cpuThreads = GetOrRegisterGauge("system/cpu/threads", DefaultRegistry) cpuGoroutines = GetOrRegisterGauge("system/cpu/goroutines", DefaultRegistry) memPauses = GetOrRegisterMeter("system/memory/pauses", DefaultRegistry) memAllocs = GetOrRegisterMeter("system/memory/allocs", DefaultRegistry) memFrees = GetOrRegisterMeter("system/memory/frees", DefaultRegistry) memHeld = GetOrRegisterGauge("system/memory/held", DefaultRegistry) memUsed = GetOrRegisterGauge("system/memory/used", DefaultRegistry) diskReads = GetOrRegisterMeter("system/disk/readcount", DefaultRegistry) diskReadBytes = GetOrRegisterMeter("system/disk/readdata", DefaultRegistry) diskReadBytesCounter = GetOrRegisterCounter("system/disk/readbytes", DefaultRegistry) diskWrites = GetOrRegisterMeter("system/disk/writecount", DefaultRegistry) diskWriteBytes = GetOrRegisterMeter("system/disk/writedata", DefaultRegistry) diskWriteBytesCounter = GetOrRegisterCounter("system/disk/writebytes", DefaultRegistry) ) // Iterate loading the different stats and updating the meters for i := 1; ; i++ { location1 := i % 2 location2 := (i - 1) % 2 ReadCPUStats(cpuStats[location1]) cpuSysLoad.Update((cpuStats[location1].GlobalTime - cpuStats[location2].GlobalTime) / refreshFreq) cpuSysWait.Update((cpuStats[location1].GlobalWait - cpuStats[location2].GlobalWait) / refreshFreq) cpuProcLoad.Update((cpuStats[location1].LocalTime - cpuStats[location2].LocalTime) / refreshFreq) cpuThreads.Update(int64(threadCreateProfile.Count())) cpuGoroutines.Update(int64(runtime.NumGoroutine())) runtime.ReadMemStats(memstats[location1]) memPauses.Mark(int64(memstats[location1].PauseTotalNs - memstats[location2].PauseTotalNs)) memAllocs.Mark(int64(memstats[location1].Mallocs - memstats[location2].Mallocs)) memFrees.Mark(int64(memstats[location1].Frees - memstats[location2].Frees)) memHeld.Update(int64(memstats[location1].HeapSys - memstats[location1].HeapReleased)) memUsed.Update(int64(memstats[location1].Alloc)) if ReadDiskStats(diskstats[location1]) == nil { diskReads.Mark(diskstats[location1].ReadCount - diskstats[location2].ReadCount) diskReadBytes.Mark(diskstats[location1].ReadBytes - diskstats[location2].ReadBytes) diskWrites.Mark(diskstats[location1].WriteCount - diskstats[location2].WriteCount) diskWriteBytes.Mark(diskstats[location1].WriteBytes - diskstats[location2].WriteBytes) diskReadBytesCounter.Inc(diskstats[location1].ReadBytes - diskstats[location2].ReadBytes) diskWriteBytesCounter.Inc(diskstats[location1].WriteBytes - diskstats[location2].WriteBytes) } time.Sleep(refresh) } }