package vsphere import ( "context" "errors" "fmt" "log" "math" "math/rand" "net/url" "regexp" "strconv" "strings" "sync" "sync/atomic" "time" "github.com/influxdata/telegraf/filter" "github.com/influxdata/telegraf" "github.com/vmware/govmomi/object" "github.com/vmware/govmomi/performance" "github.com/vmware/govmomi/vim25/mo" "github.com/vmware/govmomi/vim25/types" ) var isolateLUN = regexp.MustCompile(".*/([^/]+)/?$") const metricLookback = 3 // Number of time periods to look back at for non-realtime metrics const rtMetricLookback = 3 // Number of time periods to look back at for realtime metrics const maxSampleConst = 10 // Absolute maximim number of samples regardless of period const maxMetadataSamples = 100 // Number of resources to sample for metric metadata // Endpoint is a high-level representation of a connected vCenter endpoint. It is backed by the lower // level Client type. type Endpoint struct { Parent *VSphere URL *url.URL resourceKinds map[string]*resourceKind hwMarks *TSCache lun2ds map[string]string discoveryTicker *time.Ticker collectMux sync.RWMutex initialized bool clientFactory *ClientFactory busy sync.Mutex } type resourceKind struct { name string vcName string pKey string parentTag string enabled bool realTime bool sampling int32 objects objectMap filters filter.Filter paths []string collectInstances bool getObjects func(context.Context, *Endpoint, *ResourceFilter) (objectMap, error) include []string simple bool metrics performance.MetricList parent string latestSample time.Time lastColl time.Time } type metricEntry struct { tags map[string]string name string ts time.Time fields map[string]interface{} } type objectMap map[string]objectRef type objectRef struct { name string altID string ref types.ManagedObjectReference parentRef *types.ManagedObjectReference //Pointer because it must be nillable guest string dcname string } func (e *Endpoint) getParent(obj *objectRef, res *resourceKind) (*objectRef, bool) { if pKind, ok := e.resourceKinds[res.parent]; ok { if p, ok := pKind.objects[obj.parentRef.Value]; ok { return &p, true } } return nil, false } // NewEndpoint returns a new connection to a vCenter based on the URL and configuration passed // as parameters. func NewEndpoint(ctx context.Context, parent *VSphere, url *url.URL) (*Endpoint, error) { e := Endpoint{ URL: url, Parent: parent, hwMarks: NewTSCache(1 * time.Hour), lun2ds: make(map[string]string), initialized: false, clientFactory: NewClientFactory(ctx, url, parent), } e.resourceKinds = map[string]*resourceKind{ "datacenter": { name: "datacenter", vcName: "Datacenter", pKey: "dcname", parentTag: "", enabled: anythingEnabled(parent.DatacenterMetricExclude), realTime: false, sampling: 300, objects: make(objectMap), filters: newFilterOrPanic(parent.DatacenterMetricInclude, parent.DatacenterMetricExclude), paths: parent.DatacenterInclude, simple: isSimple(parent.DatacenterMetricInclude, parent.DatacenterMetricExclude), include: parent.DatacenterMetricInclude, collectInstances: parent.DatacenterInstances, getObjects: getDatacenters, parent: "", }, "cluster": { name: "cluster", vcName: "ClusterComputeResource", pKey: "clustername", parentTag: "dcname", enabled: anythingEnabled(parent.ClusterMetricExclude), realTime: false, sampling: 300, objects: make(objectMap), filters: newFilterOrPanic(parent.ClusterMetricInclude, parent.ClusterMetricExclude), paths: parent.ClusterInclude, simple: isSimple(parent.ClusterMetricInclude, parent.ClusterMetricExclude), include: parent.ClusterMetricInclude, collectInstances: parent.ClusterInstances, getObjects: getClusters, parent: "datacenter", }, "host": { name: "host", vcName: "HostSystem", pKey: "esxhostname", parentTag: "clustername", enabled: anythingEnabled(parent.HostMetricExclude), realTime: true, sampling: 20, objects: make(objectMap), filters: newFilterOrPanic(parent.HostMetricInclude, parent.HostMetricExclude), paths: parent.HostInclude, simple: isSimple(parent.HostMetricInclude, parent.HostMetricExclude), include: parent.HostMetricInclude, collectInstances: parent.HostInstances, getObjects: getHosts, parent: "cluster", }, "vm": { name: "vm", vcName: "VirtualMachine", pKey: "vmname", parentTag: "esxhostname", enabled: anythingEnabled(parent.VMMetricExclude), realTime: true, sampling: 20, objects: make(objectMap), filters: newFilterOrPanic(parent.VMMetricInclude, parent.VMMetricExclude), paths: parent.VMInclude, simple: isSimple(parent.VMMetricInclude, parent.VMMetricExclude), include: parent.VMMetricInclude, collectInstances: parent.VMInstances, getObjects: getVMs, parent: "host", }, "datastore": { name: "datastore", vcName: "Datastore", pKey: "dsname", enabled: anythingEnabled(parent.DatastoreMetricExclude), realTime: false, sampling: 300, objects: make(objectMap), filters: newFilterOrPanic(parent.DatastoreMetricInclude, parent.DatastoreMetricExclude), paths: parent.DatastoreInclude, simple: isSimple(parent.DatastoreMetricInclude, parent.DatastoreMetricExclude), include: parent.DatastoreMetricInclude, collectInstances: parent.DatastoreInstances, getObjects: getDatastores, parent: "", }, } // Start discover and other goodness err := e.init(ctx) return &e, err } func anythingEnabled(ex []string) bool { for _, s := range ex { if s == "*" { return false } } return true } func newFilterOrPanic(include []string, exclude []string) filter.Filter { f, err := filter.NewIncludeExcludeFilter(include, exclude) if err != nil { panic(fmt.Sprintf("Include/exclude filters are invalid: %s", err)) } return f } func isSimple(include []string, exclude []string) bool { if len(exclude) > 0 || len(include) == 0 { return false } for _, s := range include { if strings.Contains(s, "*") { return false } } return true } func (e *Endpoint) startDiscovery(ctx context.Context) { e.discoveryTicker = time.NewTicker(e.Parent.ObjectDiscoveryInterval.Duration) go func() { for { select { case <-e.discoveryTicker.C: err := e.discover(ctx) if err != nil && err != context.Canceled { log.Printf("E! [inputs.vsphere]: Error in discovery for %s: %v", e.URL.Host, err) } case <-ctx.Done(): log.Printf("D! [inputs.vsphere]: Exiting discovery goroutine for %s", e.URL.Host) e.discoveryTicker.Stop() return } } }() } func (e *Endpoint) initalDiscovery(ctx context.Context) { err := e.discover(ctx) if err != nil && err != context.Canceled { log.Printf("E! [inputs.vsphere]: Error in discovery for %s: %v", e.URL.Host, err) } e.startDiscovery(ctx) } func (e *Endpoint) init(ctx context.Context) error { if e.Parent.ObjectDiscoveryInterval.Duration > 0 { // Run an initial discovery. If force_discovery_on_init isn't set, we kick it off as a // goroutine without waiting for it. This will probably cause us to report an empty // dataset on the first collection, but it solves the issue of the first collection timing out. if e.Parent.ForceDiscoverOnInit { log.Printf("D! [inputs.vsphere]: Running initial discovery and waiting for it to finish") e.initalDiscovery(ctx) } else { // Otherwise, just run it in the background. We'll probably have an incomplete first metric // collection this way. go func() { e.initalDiscovery(ctx) }() } } e.initialized = true return nil } func (e *Endpoint) getMetricNameMap(ctx context.Context) (map[int32]string, error) { client, err := e.clientFactory.GetClient(ctx) if err != nil { return nil, err } mn, err := client.CounterInfoByName(ctx) if err != nil { return nil, err } names := make(map[int32]string) for name, m := range mn { names[m.Key] = name } return names, nil } func (e *Endpoint) getMetadata(ctx context.Context, obj objectRef, sampling int32) (performance.MetricList, error) { client, err := e.clientFactory.GetClient(ctx) if err != nil { return nil, err } ctx1, cancel1 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel1() metrics, err := client.Perf.AvailableMetric(ctx1, obj.ref.Reference(), sampling) if err != nil { return nil, err } return metrics, nil } func (e *Endpoint) getDatacenterName(ctx context.Context, client *Client, cache map[string]string, r types.ManagedObjectReference) string { path := make([]string, 0) returnVal := "" here := r for { if name, ok := cache[here.Reference().String()]; ok { // Populate cache for the entire chain of objects leading here. returnVal = name break } path = append(path, here.Reference().String()) o := object.NewCommon(client.Client.Client, r) var result mo.ManagedEntity ctx1, cancel1 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel1() err := o.Properties(ctx1, here, []string{"parent", "name"}, &result) if err != nil { log.Printf("W! [inputs.vsphere]: Error while resolving parent. Assuming no parent exists. Error: %s", err) break } if result.Reference().Type == "Datacenter" { // Populate cache for the entire chain of objects leading here. returnVal = result.Name break } if result.Parent == nil { log.Printf("D! [inputs.vsphere]: No parent found for %s (ascending from %s)", here.Reference(), r.Reference()) break } here = result.Parent.Reference() } for _, s := range path { cache[s] = returnVal } return returnVal } func (e *Endpoint) discover(ctx context.Context) error { e.busy.Lock() defer e.busy.Unlock() if ctx.Err() != nil { return ctx.Err() } metricNames, err := e.getMetricNameMap(ctx) if err != nil { return err } sw := NewStopwatch("discover", e.URL.Host) client, err := e.clientFactory.GetClient(ctx) if err != nil { return err } log.Printf("D! [inputs.vsphere]: Discover new objects for %s", e.URL.Host) dcNameCache := make(map[string]string) numRes := int64(0) // Populate resource objects, and endpoint instance info. newObjects := make(map[string]objectMap) for k, res := range e.resourceKinds { log.Printf("D! [inputs.vsphere] Discovering resources for %s", res.name) // Need to do this for all resource types even if they are not enabled if res.enabled || k != "vm" { rf := ResourceFilter{ finder: &Finder{client}, resType: res.vcName, paths: res.paths} ctx1, cancel1 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel1() objects, err := res.getObjects(ctx1, e, &rf) if err != nil { return err } // Fill in datacenter names where available (no need to do it for Datacenters) if res.name != "Datacenter" { for k, obj := range objects { if obj.parentRef != nil { obj.dcname = e.getDatacenterName(ctx, client, dcNameCache, *obj.parentRef) objects[k] = obj } } } // No need to collect metric metadata if resource type is not enabled if res.enabled { if res.simple { e.simpleMetadataSelect(ctx, client, res) } else { e.complexMetadataSelect(ctx, res, objects, metricNames) } } newObjects[k] = objects SendInternalCounterWithTags("discovered_objects", e.URL.Host, map[string]string{"type": res.name}, int64(len(objects))) numRes += int64(len(objects)) } } // Build lun2ds map dss := newObjects["datastore"] l2d := make(map[string]string) for _, ds := range dss { url := ds.altID m := isolateLUN.FindStringSubmatch(url) if m != nil { l2d[m[1]] = ds.name } } // Atomically swap maps e.collectMux.Lock() defer e.collectMux.Unlock() for k, v := range newObjects { e.resourceKinds[k].objects = v } e.lun2ds = l2d sw.Stop() SendInternalCounterWithTags("discovered_objects", e.URL.Host, map[string]string{"type": "instance-total"}, numRes) return nil } func (e *Endpoint) simpleMetadataSelect(ctx context.Context, client *Client, res *resourceKind) { log.Printf("D! [inputs.vsphere] Using fast metric metadata selection for %s", res.name) m, err := client.CounterInfoByName(ctx) if err != nil { log.Printf("E! [inputs.vsphere]: Error while getting metric metadata. Discovery will be incomplete. Error: %s", err) return } res.metrics = make(performance.MetricList, 0, len(res.include)) for _, s := range res.include { if pci, ok := m[s]; ok { cnt := types.PerfMetricId{ CounterId: pci.Key, } if res.collectInstances { cnt.Instance = "*" } else { cnt.Instance = "" } res.metrics = append(res.metrics, cnt) } else { log.Printf("W! [inputs.vsphere] Metric name %s is unknown. Will not be collected", s) } } } func (e *Endpoint) complexMetadataSelect(ctx context.Context, res *resourceKind, objects objectMap, metricNames map[int32]string) { // We're only going to get metadata from maxMetadataSamples resources. If we have // more resources than that, we pick maxMetadataSamples samples at random. sampledObjects := make([]objectRef, len(objects)) i := 0 for _, obj := range objects { sampledObjects[i] = obj i++ } n := len(sampledObjects) if n > maxMetadataSamples { // Shuffle samples into the maxMetadatSamples positions for i := 0; i < maxMetadataSamples; i++ { j := int(rand.Int31n(int32(i + 1))) t := sampledObjects[i] sampledObjects[i] = sampledObjects[j] sampledObjects[j] = t } sampledObjects = sampledObjects[0:maxMetadataSamples] } instInfoMux := sync.Mutex{} te := NewThrottledExecutor(e.Parent.DiscoverConcurrency) for _, obj := range sampledObjects { func(obj objectRef) { te.Run(ctx, func() { metrics, err := e.getMetadata(ctx, obj, res.sampling) if err != nil { log.Printf("E! [inputs.vsphere]: Error while getting metric metadata. Discovery will be incomplete. Error: %s", err) } mMap := make(map[string]types.PerfMetricId) for _, m := range metrics { if m.Instance != "" && res.collectInstances { m.Instance = "*" } else { m.Instance = "" } if res.filters.Match(metricNames[m.CounterId]) { mMap[strconv.Itoa(int(m.CounterId))+"|"+m.Instance] = m } } log.Printf("D! [inputs.vsphere] Found %d metrics for %s", len(mMap), obj.name) instInfoMux.Lock() defer instInfoMux.Unlock() if len(mMap) > len(res.metrics) { res.metrics = make(performance.MetricList, len(mMap)) i := 0 for _, m := range mMap { res.metrics[i] = m i++ } } }) }(obj) } te.Wait() } func getDatacenters(ctx context.Context, e *Endpoint, filter *ResourceFilter) (objectMap, error) { var resources []mo.Datacenter ctx1, cancel1 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel1() err := filter.FindAll(ctx1, &resources) if err != nil { return nil, err } m := make(objectMap, len(resources)) for _, r := range resources { m[r.ExtensibleManagedObject.Reference().Value] = objectRef{ name: r.Name, ref: r.ExtensibleManagedObject.Reference(), parentRef: r.Parent, dcname: r.Name} } return m, nil } func getClusters(ctx context.Context, e *Endpoint, filter *ResourceFilter) (objectMap, error) { var resources []mo.ClusterComputeResource ctx1, cancel1 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel1() err := filter.FindAll(ctx1, &resources) if err != nil { return nil, err } cache := make(map[string]*types.ManagedObjectReference) m := make(objectMap, len(resources)) for _, r := range resources { // We're not interested in the immediate parent (a folder), but the data center. p, ok := cache[r.Parent.Value] if !ok { ctx2, cancel2 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel2() client, err := e.clientFactory.GetClient(ctx2) if err != nil { return nil, err } o := object.NewFolder(client.Client.Client, *r.Parent) var folder mo.Folder ctx3, cancel3 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel3() err = o.Properties(ctx3, *r.Parent, []string{"parent"}, &folder) if err != nil { log.Printf("W! [inputs.vsphere] Error while getting folder parent: %e", err) p = nil } else { pp := folder.Parent.Reference() p = &pp cache[r.Parent.Value] = p } } m[r.ExtensibleManagedObject.Reference().Value] = objectRef{ name: r.Name, ref: r.ExtensibleManagedObject.Reference(), parentRef: p} } return m, nil } func getHosts(ctx context.Context, e *Endpoint, filter *ResourceFilter) (objectMap, error) { var resources []mo.HostSystem err := filter.FindAll(ctx, &resources) if err != nil { return nil, err } m := make(objectMap) for _, r := range resources { m[r.ExtensibleManagedObject.Reference().Value] = objectRef{ name: r.Name, ref: r.ExtensibleManagedObject.Reference(), parentRef: r.Parent} } return m, nil } func getVMs(ctx context.Context, e *Endpoint, filter *ResourceFilter) (objectMap, error) { var resources []mo.VirtualMachine ctx1, cancel1 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel1() err := filter.FindAll(ctx1, &resources) if err != nil { return nil, err } m := make(objectMap) for _, r := range resources { if r.Runtime.PowerState != "poweredOn" { continue } guest := "unknown" uuid := "" // Sometimes Config is unknown and returns a nil pointer // if r.Config != nil { guest = cleanGuestID(r.Config.GuestId) uuid = r.Config.Uuid } m[r.ExtensibleManagedObject.Reference().Value] = objectRef{ name: r.Name, ref: r.ExtensibleManagedObject.Reference(), parentRef: r.Runtime.Host, guest: guest, altID: uuid} } return m, nil } func getDatastores(ctx context.Context, e *Endpoint, filter *ResourceFilter) (objectMap, error) { var resources []mo.Datastore ctx1, cancel1 := context.WithTimeout(ctx, e.Parent.Timeout.Duration) defer cancel1() err := filter.FindAll(ctx1, &resources) if err != nil { return nil, err } m := make(objectMap) for _, r := range resources { url := "" if r.Info != nil { info := r.Info.GetDatastoreInfo() if info != nil { url = info.Url } } m[r.ExtensibleManagedObject.Reference().Value] = objectRef{ name: r.Name, ref: r.ExtensibleManagedObject.Reference(), parentRef: r.Parent, altID: url} } return m, nil } // Close shuts down an Endpoint and releases any resources associated with it. func (e *Endpoint) Close() { e.clientFactory.Close() } // Collect runs a round of data collections as specified in the configuration. func (e *Endpoint) Collect(ctx context.Context, acc telegraf.Accumulator) error { // If we never managed to do a discovery, collection will be a no-op. Therefore, // we need to check that a connection is available, or the collection will // silently fail. if _, err := e.clientFactory.GetClient(ctx); err != nil { return err } e.collectMux.RLock() defer e.collectMux.RUnlock() if ctx.Err() != nil { return ctx.Err() } // If discovery interval is disabled (0), discover on each collection cycle if e.Parent.ObjectDiscoveryInterval.Duration == 0 { err := e.discover(ctx) if err != nil { return err } } var wg sync.WaitGroup for k, res := range e.resourceKinds { if res.enabled { wg.Add(1) go func(k string) { defer wg.Done() err := e.collectResource(ctx, k, acc) if err != nil { acc.AddError(err) } }(k) } } wg.Wait() // Purge old timestamps from the cache e.hwMarks.Purge() return nil } // Workaround to make sure pqs is a copy of the loop variable and won't change. func submitChunkJob(ctx context.Context, te *ThrottledExecutor, job func([]types.PerfQuerySpec), pqs []types.PerfQuerySpec) { te.Run(ctx, func() { job(pqs) }) } func (e *Endpoint) chunkify(ctx context.Context, res *resourceKind, now time.Time, latest time.Time, acc telegraf.Accumulator, job func([]types.PerfQuerySpec)) { te := NewThrottledExecutor(e.Parent.CollectConcurrency) maxMetrics := e.Parent.MaxQueryMetrics if maxMetrics < 1 { maxMetrics = 1 } // Workaround for vCenter weirdness. Cluster metrics seem to count multiple times // when checking query size, so keep it at a low value. // Revisit this when we better understand the reason why vCenter counts it this way! if res.name == "cluster" && maxMetrics > 10 { maxMetrics = 10 } pqs := make([]types.PerfQuerySpec, 0, e.Parent.MaxQueryObjects) metrics := 0 total := 0 nRes := 0 for _, object := range res.objects { mr := len(res.metrics) for mr > 0 { mc := mr headroom := maxMetrics - metrics if !res.realTime && mc > headroom { // Metric query limit only applies to non-realtime metrics mc = headroom } fm := len(res.metrics) - mr pq := types.PerfQuerySpec{ Entity: object.ref, MaxSample: maxSampleConst, MetricId: res.metrics[fm : fm+mc], IntervalId: res.sampling, Format: "normal", } start, ok := e.hwMarks.Get(object.ref.Value) if !ok { // Look back 3 sampling periods by default start = latest.Add(time.Duration(-res.sampling) * time.Second * (metricLookback - 1)) } pq.StartTime = &start pq.EndTime = &now // Make sure endtime is always after start time. We may occasionally see samples from the future // returned from vCenter. This is presumably due to time drift between vCenter and EXSi nodes. if pq.StartTime.After(*pq.EndTime) { log.Printf("D! [inputs.vsphere] Future sample. Res: %s, StartTime: %s, EndTime: %s, Now: %s", pq.Entity, *pq.StartTime, *pq.EndTime, now) end := start.Add(time.Second) pq.EndTime = &end } pqs = append(pqs, pq) mr -= mc metrics += mc // We need to dump the current chunk of metrics for one of two reasons: // 1) We filled up the metric quota while processing the current resource // 2) We are at the last resource and have no more data to process. // 3) The query contains more than 100,000 individual metrics if mr > 0 || nRes >= e.Parent.MaxQueryObjects || len(pqs) > 100000 { log.Printf("D! [inputs.vsphere]: Queueing query: %d objects, %d metrics (%d remaining) of type %s for %s. Processed objects: %d. Total objects %d", len(pqs), metrics, mr, res.name, e.URL.Host, total+1, len(res.objects)) // Don't send work items if the context has been cancelled. if ctx.Err() == context.Canceled { return } // Run collection job submitChunkJob(ctx, te, job, pqs) pqs = make([]types.PerfQuerySpec, 0, e.Parent.MaxQueryObjects) metrics = 0 nRes = 0 } } total++ nRes++ } // Handle final partially filled chunk if len(pqs) > 0 { // Run collection job log.Printf("D! [inputs.vsphere]: Queuing query: %d objects, %d metrics (0 remaining) of type %s for %s. Total objects %d (final chunk)", len(pqs), metrics, res.name, e.URL.Host, len(res.objects)) submitChunkJob(ctx, te, job, pqs) } // Wait for background collection to finish te.Wait() } func (e *Endpoint) collectResource(ctx context.Context, resourceType string, acc telegraf.Accumulator) error { res := e.resourceKinds[resourceType] client, err := e.clientFactory.GetClient(ctx) if err != nil { return err } now, err := client.GetServerTime(ctx) if err != nil { return err } // Estimate the interval at which we're invoked. Use local time (not server time) // since this is about how we got invoked locally. localNow := time.Now() estInterval := time.Duration(time.Minute) if !res.lastColl.IsZero() { s := time.Duration(res.sampling) * time.Second rawInterval := localNow.Sub(res.lastColl) paddedInterval := rawInterval + time.Duration(res.sampling/2)*time.Second estInterval = paddedInterval.Truncate(s) if estInterval < s { estInterval = s } log.Printf("D! [inputs.vsphere] Raw interval %s, padded: %s, estimated: %s", rawInterval, paddedInterval, estInterval) } log.Printf("D! [inputs.vsphere] Interval estimated to %s", estInterval) res.lastColl = localNow latest := res.latestSample if !latest.IsZero() { elapsed := now.Sub(latest).Seconds() + 5.0 // Allow 5 second jitter. log.Printf("D! [inputs.vsphere]: Latest: %s, elapsed: %f, resource: %s", latest, elapsed, resourceType) if !res.realTime && elapsed < float64(res.sampling) { // No new data would be available. We're outta here! log.Printf("D! [inputs.vsphere]: Sampling period for %s of %d has not elapsed on %s", resourceType, res.sampling, e.URL.Host) return nil } } else { latest = now.Add(time.Duration(-res.sampling) * time.Second) } internalTags := map[string]string{"resourcetype": resourceType} sw := NewStopwatchWithTags("gather_duration", e.URL.Host, internalTags) log.Printf("D! [inputs.vsphere]: Collecting metrics for %d objects of type %s for %s", len(res.objects), resourceType, e.URL.Host) count := int64(0) var tsMux sync.Mutex latestSample := time.Time{} // Divide workload into chunks and process them concurrently e.chunkify(ctx, res, now, latest, acc, func(chunk []types.PerfQuerySpec) { n, localLatest, err := e.collectChunk(ctx, chunk, res, acc, now, estInterval) log.Printf("D! [inputs.vsphere] CollectChunk for %s returned %d metrics", resourceType, n) if err != nil { acc.AddError(errors.New("While collecting " + res.name + ": " + err.Error())) } atomic.AddInt64(&count, int64(n)) tsMux.Lock() defer tsMux.Unlock() if localLatest.After(latestSample) && !localLatest.IsZero() { latestSample = localLatest } }) log.Printf("D! [inputs.vsphere] Latest sample for %s set to %s", resourceType, latestSample) if !latestSample.IsZero() { res.latestSample = latestSample } sw.Stop() SendInternalCounterWithTags("gather_count", e.URL.Host, internalTags, count) return nil } func alignSamples(info []types.PerfSampleInfo, values []int64, interval time.Duration) ([]types.PerfSampleInfo, []float64) { rInfo := make([]types.PerfSampleInfo, 0, len(info)) rValues := make([]float64, 0, len(values)) bi := 1.0 var lastBucket time.Time for idx := range info { // According to the docs, SampleInfo and Value should have the same length, but we've seen corrupted // data coming back with missing values. Take care of that gracefully! if idx >= len(values) { log.Printf("D! [inputs.vsphere] len(SampleInfo)>len(Value) %d > %d", len(info), len(values)) break } v := float64(values[idx]) if v < 0 { continue } ts := info[idx].Timestamp roundedTs := ts.Truncate(interval) // Are we still working on the same bucket? if roundedTs == lastBucket { bi++ p := len(rValues) - 1 rValues[p] = ((bi-1)/bi)*float64(rValues[p]) + v/bi } else { rValues = append(rValues, v) roundedInfo := types.PerfSampleInfo{ Timestamp: roundedTs, Interval: info[idx].Interval, } rInfo = append(rInfo, roundedInfo) bi = 1.0 lastBucket = roundedTs } } //log.Printf("D! [inputs.vsphere] Aligned samples: %d collapsed into %d", len(info), len(rInfo)) return rInfo, rValues } func (e *Endpoint) collectChunk(ctx context.Context, pqs []types.PerfQuerySpec, res *resourceKind, acc telegraf.Accumulator, now time.Time, interval time.Duration) (int, time.Time, error) { log.Printf("D! [inputs.vsphere] Query for %s has %d QuerySpecs", res.name, len(pqs)) latestSample := time.Time{} count := 0 resourceType := res.name prefix := "vsphere" + e.Parent.Separator + resourceType client, err := e.clientFactory.GetClient(ctx) if err != nil { return count, latestSample, err } metricInfo, err := client.CounterInfoByName(ctx) if err != nil { return count, latestSample, err } ems, err := client.QueryMetrics(ctx, pqs) if err != nil { return count, latestSample, err } log.Printf("D! [inputs.vsphere] Query for %s returned metrics for %d objects", resourceType, len(ems)) // Iterate through results for _, em := range ems { moid := em.Entity.Reference().Value instInfo, found := res.objects[moid] if !found { log.Printf("E! [inputs.vsphere]: MOID %s not found in cache. Skipping! (This should not happen!)", moid) continue } buckets := make(map[string]metricEntry) for _, v := range em.Value { name := v.Name t := map[string]string{ "vcenter": e.URL.Host, "source": instInfo.name, "moid": moid, } // Populate tags objectRef, ok := res.objects[moid] if !ok { log.Printf("E! [inputs.vsphere]: MOID %s not found in cache. Skipping", moid) continue } e.populateTags(&objectRef, resourceType, res, t, &v) nValues := 0 alignedInfo, alignedValues := alignSamples(em.SampleInfo, v.Value, interval) for idx, sample := range alignedInfo { // According to the docs, SampleInfo and Value should have the same length, but we've seen corrupted // data coming back with missing values. Take care of that gracefully! if idx >= len(alignedValues) { log.Printf("D! [inputs.vsphere] len(SampleInfo)>len(Value) %d > %d", len(alignedInfo), len(alignedValues)) break } ts := sample.Timestamp if ts.After(latestSample) { latestSample = ts } nValues++ // Organize the metrics into a bucket per measurement. mn, fn := e.makeMetricIdentifier(prefix, name) bKey := mn + " " + v.Instance + " " + strconv.FormatInt(ts.UnixNano(), 10) bucket, found := buckets[bKey] if !found { bucket = metricEntry{name: mn, ts: ts, fields: make(map[string]interface{}), tags: t} buckets[bKey] = bucket } // Percentage values must be scaled down by 100. info, ok := metricInfo[name] if !ok { log.Printf("E! [inputs.vsphere]: Could not determine unit for %s. Skipping", name) } v := alignedValues[idx] if info.UnitInfo.GetElementDescription().Key == "percent" { bucket.fields[fn] = float64(v) / 100.0 } else { if e.Parent.UseIntSamples { bucket.fields[fn] = int64(round(v)) } else { bucket.fields[fn] = v } } count++ // Update highwater marks e.hwMarks.Put(moid, ts) } if nValues == 0 { log.Printf("D! [inputs.vsphere]: Missing value for: %s, %s", name, objectRef.name) continue } } // We've iterated through all the metrics and collected buckets for each // measurement name. Now emit them! for _, bucket := range buckets { acc.AddFields(bucket.name, bucket.fields, bucket.tags, bucket.ts) } } return count, latestSample, nil } func (e *Endpoint) populateTags(objectRef *objectRef, resourceType string, resource *resourceKind, t map[string]string, v *performance.MetricSeries) { // Map name of object. if resource.pKey != "" { t[resource.pKey] = objectRef.name } if resourceType == "vm" && objectRef.altID != "" { t["uuid"] = objectRef.altID } // Map parent reference parent, found := e.getParent(objectRef, resource) if found { t[resource.parentTag] = parent.name if resourceType == "vm" { if objectRef.guest != "" { t["guest"] = objectRef.guest } if c, ok := e.resourceKinds["cluster"].objects[parent.parentRef.Value]; ok { t["clustername"] = c.name } } } // Fill in Datacenter name if objectRef.dcname != "" { t["dcname"] = objectRef.dcname } // Determine which point tag to map to the instance name := v.Name instance := "instance-total" if v.Instance != "" { instance = v.Instance } if strings.HasPrefix(name, "cpu.") { t["cpu"] = instance } else if strings.HasPrefix(name, "datastore.") { t["lun"] = instance if ds, ok := e.lun2ds[instance]; ok { t["dsname"] = ds } else { t["dsname"] = instance } } else if strings.HasPrefix(name, "disk.") { t["disk"] = cleanDiskTag(instance) } else if strings.HasPrefix(name, "net.") { t["interface"] = instance } else if strings.HasPrefix(name, "storageAdapter.") { t["adapter"] = instance } else if strings.HasPrefix(name, "storagePath.") { t["path"] = instance } else if strings.HasPrefix(name, "sys.resource") { t["resource"] = instance } else if strings.HasPrefix(name, "vflashModule.") { t["module"] = instance } else if strings.HasPrefix(name, "virtualDisk.") { t["disk"] = instance } else if v.Instance != "" { // default t["instance"] = v.Instance } } func (e *Endpoint) makeMetricIdentifier(prefix, metric string) (string, string) { parts := strings.Split(metric, ".") if len(parts) == 1 { return prefix, parts[0] } return prefix + e.Parent.Separator + parts[0], strings.Join(parts[1:], e.Parent.Separator) } func cleanGuestID(id string) string { return strings.TrimSuffix(id, "Guest") } func cleanDiskTag(disk string) string { // Remove enclosing "<>" return strings.TrimSuffix(strings.TrimPrefix(disk, "<"), ">") } func round(x float64) float64 { t := math.Trunc(x) if math.Abs(x-t) >= 0.5 { return t + math.Copysign(1, x) } return t }