// getFsInfo writes metrics.Capacity and metrics.Available from the filesystem
// info
func (md *metricsDu) getFsInfo(metrics *Metrics) error {
available, capacity, _, err := util.FsInfo(md.path)
if err != nil {
return fmt.Errorf("Failed to get FsInfo due to error %v", err)
}
metrics.Available = resource.NewQuantity(available, resource.BinarySI)
metrics.Capacity = resource.NewQuantity(capacity, resource.BinarySI)
return nil
}
func newPVC(name string) api.PersistentVolumeClaim {
return api.PersistentVolumeClaim{
ObjectMeta: api.ObjectMeta{
Name: name,
},
Spec: api.PersistentVolumeClaimSpec{
Resources: api.ResourceRequirements{
Requests: api.ResourceList{
api.ResourceStorage: *resource.NewQuantity(1, resource.BinarySI),
},
},
},
}
}
// FuzzerFor can randomly populate api objects that are destined for version.
func FuzzerFor(t *testing.T, version unversioned.GroupVersion, src rand.Source) *fuzz.Fuzzer {
f := fuzz.New().NilChance(.5).NumElements(1, 1)
if src != nil {
f.RandSource(src)
}
f.Funcs(
func(j *int, c fuzz.Continue) {
*j = int(c.Int31())
},
func(j **int, c fuzz.Continue) {
if c.RandBool() {
i := int(c.Int31())
*j = &i
} else {
*j = nil
}
},
func(q *resource.Quantity, c fuzz.Continue) {
*q = *resource.NewQuantity(c.Int63n(1000), resource.DecimalExponent)
},
func(j *runtime.TypeMeta, c fuzz.Continue) {
// We have to customize the randomization of TypeMetas because their
// APIVersion and Kind must remain blank in memory.
j.APIVersion = ""
j.Kind = ""
},
func(j *unversioned.TypeMeta, c fuzz.Continue) {
// We have to customize the randomization of TypeMetas because their
// APIVersion and Kind must remain blank in memory.
j.APIVersion = ""
j.Kind = ""
},
func(j *api.ObjectMeta, c fuzz.Continue) {
j.Name = c.RandString()
j.ResourceVersion = strconv.FormatUint(c.RandUint64(), 10)
j.SelfLink = c.RandString()
j.UID = types.UID(c.RandString())
j.GenerateName = c.RandString()
var sec, nsec int64
c.Fuzz(&sec)
c.Fuzz(&nsec)
j.CreationTimestamp = unversioned.Unix(sec, nsec).Rfc3339Copy()
},
func(j *api.ObjectReference, c fuzz.Continue) {
// We have to customize the randomization of TypeMetas because their
// APIVersion and Kind must remain blank in memory.
j.APIVersion = c.RandString()
j.Kind = c.RandString()
j.Namespace = c.RandString()
j.Name = c.RandString()
j.ResourceVersion = strconv.FormatUint(c.RandUint64(), 10)
j.FieldPath = c.RandString()
},
func(j *unversioned.ListMeta, c fuzz.Continue) {
j.ResourceVersion = strconv.FormatUint(c.RandUint64(), 10)
j.SelfLink = c.RandString()
},
func(j *api.ListOptions, c fuzz.Continue) {
label, _ := labels.Parse("a=b")
j.LabelSelector = label
field, _ := fields.ParseSelector("a=b")
j.FieldSelector = field
},
func(j *api.PodExecOptions, c fuzz.Continue) {
j.Stdout = true
j.Stderr = true
},
func(j *api.PodAttachOptions, c fuzz.Continue) {
j.Stdout = true
j.Stderr = true
},
func(s *api.PodSpec, c fuzz.Continue) {
c.FuzzNoCustom(s)
// has a default value
ttl := int64(30)
if c.RandBool() {
ttl = int64(c.Uint32())
}
s.TerminationGracePeriodSeconds = &ttl
c.Fuzz(s.SecurityContext)
if s.SecurityContext == nil {
s.SecurityContext = new(api.PodSecurityContext)
}
},
func(j *api.PodPhase, c fuzz.Continue) {
statuses := []api.PodPhase{api.PodPending, api.PodRunning, api.PodFailed, api.PodUnknown}
*j = statuses[c.Rand.Intn(len(statuses))]
},
func(j *api.Binding, c fuzz.Continue) {
c.Fuzz(&j.ObjectMeta)
j.Target.Name = c.RandString()
},
func(j *api.ReplicationControllerSpec, c fuzz.Continue) {
c.FuzzNoCustom(j) // fuzz self without calling this function again
//j.TemplateRef = nil // this is required for round trip
},
func(j *extensions.DeploymentStrategy, c fuzz.Continue) {
c.FuzzNoCustom(j) // fuzz self without calling this function again
// Ensure that strategyType is one of valid values.
strategyTypes := []extensions.DeploymentStrategyType{extensions.RecreateDeploymentStrategyType, extensions.RollingUpdateDeploymentStrategyType}
j.Type = strategyTypes[c.Rand.Intn(len(strategyTypes))]
if j.Type != extensions.RollingUpdateDeploymentStrategyType {
j.RollingUpdate = nil
} else {
rollingUpdate := extensions.RollingUpdateDeployment{}
if c.RandBool() {
rollingUpdate.MaxUnavailable = intstr.FromInt(int(c.RandUint64()))
rollingUpdate.MaxSurge = intstr.FromInt(int(c.RandUint64()))
} else {
rollingUpdate.MaxSurge = intstr.FromString(fmt.Sprintf("%d%%", c.RandUint64()))
}
j.RollingUpdate = &rollingUpdate
}
},
func(j *batch.JobSpec, c fuzz.Continue) {
c.FuzzNoCustom(j) // fuzz self without calling this function again
completions := int32(c.Rand.Int31())
parallelism := int32(c.Rand.Int31())
j.Completions = &completions
j.Parallelism = ¶llelism
if c.Rand.Int31()%2 == 0 {
j.ManualSelector = newBool(true)
} else {
j.ManualSelector = nil
}
},
func(cp *batch.ConcurrencyPolicy, c fuzz.Continue) {
policies := []batch.ConcurrencyPolicy{batch.AllowConcurrent, batch.ForbidConcurrent, batch.ReplaceConcurrent}
*cp = policies[c.Rand.Intn(len(policies))]
},
func(j *api.List, c fuzz.Continue) {
c.FuzzNoCustom(j) // fuzz self without calling this function again
// TODO: uncomment when round trip starts from a versioned object
if false { //j.Items == nil {
j.Items = []runtime.Object{}
}
},
func(j *runtime.Object, c fuzz.Continue) {
// TODO: uncomment when round trip starts from a versioned object
if true { //c.RandBool() {
*j = &runtime.Unknown{
// We do not set TypeMeta here because it is not carried through a round trip
Raw: []byte(`{"apiVersion":"unknown.group/unknown","kind":"Something","someKey":"someValue"}`),
ContentType: runtime.ContentTypeJSON,
}
} else {
types := []runtime.Object{&api.Pod{}, &api.ReplicationController{}}
t := types[c.Rand.Intn(len(types))]
c.Fuzz(t)
*j = t
}
},
func(q *api.ResourceRequirements, c fuzz.Continue) {
randomQuantity := func() resource.Quantity {
var q resource.Quantity
c.Fuzz(&q)
// precalc the string for benchmarking purposes
_ = q.String()
return q
}
q.Limits = make(api.ResourceList)
q.Requests = make(api.ResourceList)
cpuLimit := randomQuantity()
q.Limits[api.ResourceCPU] = *cpuLimit.Copy()
q.Requests[api.ResourceCPU] = *cpuLimit.Copy()
memoryLimit := randomQuantity()
q.Limits[api.ResourceMemory] = *memoryLimit.Copy()
q.Requests[api.ResourceMemory] = *memoryLimit.Copy()
storageLimit := randomQuantity()
q.Limits[api.ResourceStorage] = *storageLimit.Copy()
q.Requests[api.ResourceStorage] = *storageLimit.Copy()
},
func(q *api.LimitRangeItem, c fuzz.Continue) {
var cpuLimit resource.Quantity
c.Fuzz(&cpuLimit)
q.Type = api.LimitTypeContainer
q.Default = make(api.ResourceList)
q.Default[api.ResourceCPU] = *(cpuLimit.Copy())
q.DefaultRequest = make(api.ResourceList)
q.DefaultRequest[api.ResourceCPU] = *(cpuLimit.Copy())
q.Max = make(api.ResourceList)
q.Max[api.ResourceCPU] = *(cpuLimit.Copy())
q.Min = make(api.ResourceList)
q.Min[api.ResourceCPU] = *(cpuLimit.Copy())
q.MaxLimitRequestRatio = make(api.ResourceList)
q.MaxLimitRequestRatio[api.ResourceCPU] = resource.MustParse("10")
},
func(p *api.PullPolicy, c fuzz.Continue) {
policies := []api.PullPolicy{api.PullAlways, api.PullNever, api.PullIfNotPresent}
*p = policies[c.Rand.Intn(len(policies))]
},
func(rp *api.RestartPolicy, c fuzz.Continue) {
policies := []api.RestartPolicy{api.RestartPolicyAlways, api.RestartPolicyNever, api.RestartPolicyOnFailure}
*rp = policies[c.Rand.Intn(len(policies))]
},
// Only api.DownwardAPIVolumeFile needs to have a specific func since FieldRef has to be
// defaulted to a version otherwise roundtrip will fail
// For the remaining volume plugins the default fuzzer is enough.
func(m *api.DownwardAPIVolumeFile, c fuzz.Continue) {
m.Path = c.RandString()
versions := []string{"v1"}
m.FieldRef = &api.ObjectFieldSelector{}
m.FieldRef.APIVersion = versions[c.Rand.Intn(len(versions))]
m.FieldRef.FieldPath = c.RandString()
},
func(vs *api.VolumeSource, c fuzz.Continue) {
// Exactly one of the fields must be set.
v := reflect.ValueOf(vs).Elem()
i := int(c.RandUint64() % uint64(v.NumField()))
t := v.Field(i).Addr()
for v.Field(i).IsNil() {
c.Fuzz(t.Interface())
}
},
func(i *api.ISCSIVolumeSource, c fuzz.Continue) {
i.ISCSIInterface = c.RandString()
if i.ISCSIInterface == "" {
i.ISCSIInterface = "default"
}
},
func(d *api.DNSPolicy, c fuzz.Continue) {
policies := []api.DNSPolicy{api.DNSClusterFirst, api.DNSDefault}
*d = policies[c.Rand.Intn(len(policies))]
},
func(p *api.Protocol, c fuzz.Continue) {
protocols := []api.Protocol{api.ProtocolTCP, api.ProtocolUDP}
*p = protocols[c.Rand.Intn(len(protocols))]
},
func(p *api.ServiceAffinity, c fuzz.Continue) {
types := []api.ServiceAffinity{api.ServiceAffinityClientIP, api.ServiceAffinityNone}
*p = types[c.Rand.Intn(len(types))]
},
func(p *api.ServiceType, c fuzz.Continue) {
types := []api.ServiceType{api.ServiceTypeClusterIP, api.ServiceTypeNodePort, api.ServiceTypeLoadBalancer}
*p = types[c.Rand.Intn(len(types))]
},
func(ct *api.Container, c fuzz.Continue) {
c.FuzzNoCustom(ct) // fuzz self without calling this function again
ct.TerminationMessagePath = "/" + ct.TerminationMessagePath // Must be non-empty
},
func(p *api.Probe, c fuzz.Continue) {
c.FuzzNoCustom(p)
// These fields have default values.
intFieldsWithDefaults := [...]string{"TimeoutSeconds", "PeriodSeconds", "SuccessThreshold", "FailureThreshold"}
v := reflect.ValueOf(p).Elem()
for _, field := range intFieldsWithDefaults {
f := v.FieldByName(field)
if f.Int() == 0 {
f.SetInt(1)
}
}
},
func(ev *api.EnvVar, c fuzz.Continue) {
ev.Name = c.RandString()
if c.RandBool() {
ev.Value = c.RandString()
} else {
ev.ValueFrom = &api.EnvVarSource{}
ev.ValueFrom.FieldRef = &api.ObjectFieldSelector{}
var versions []unversioned.GroupVersion
for _, testGroup := range testapi.Groups {
versions = append(versions, *testGroup.GroupVersion())
}
ev.ValueFrom.FieldRef.APIVersion = versions[c.Rand.Intn(len(versions))].String()
ev.ValueFrom.FieldRef.FieldPath = c.RandString()
}
},
func(sc *api.SecurityContext, c fuzz.Continue) {
c.FuzzNoCustom(sc) // fuzz self without calling this function again
if c.RandBool() {
priv := c.RandBool()
sc.Privileged = &priv
}
if c.RandBool() {
sc.Capabilities = &api.Capabilities{
Add: make([]api.Capability, 0),
Drop: make([]api.Capability, 0),
}
c.Fuzz(&sc.Capabilities.Add)
c.Fuzz(&sc.Capabilities.Drop)
}
},
func(s *api.Secret, c fuzz.Continue) {
c.FuzzNoCustom(s) // fuzz self without calling this function again
s.Type = api.SecretTypeOpaque
},
func(r *api.RBDVolumeSource, c fuzz.Continue) {
r.RBDPool = c.RandString()
if r.RBDPool == "" {
r.RBDPool = "rbd"
}
r.RadosUser = c.RandString()
if r.RadosUser == "" {
r.RadosUser = "******"
}
r.Keyring = c.RandString()
if r.Keyring == "" {
r.Keyring = "/etc/ceph/keyring"
}
},
func(pv *api.PersistentVolume, c fuzz.Continue) {
c.FuzzNoCustom(pv) // fuzz self without calling this function again
types := []api.PersistentVolumePhase{api.VolumeAvailable, api.VolumePending, api.VolumeBound, api.VolumeReleased, api.VolumeFailed}
pv.Status.Phase = types[c.Rand.Intn(len(types))]
pv.Status.Message = c.RandString()
reclamationPolicies := []api.PersistentVolumeReclaimPolicy{api.PersistentVolumeReclaimRecycle, api.PersistentVolumeReclaimRetain}
pv.Spec.PersistentVolumeReclaimPolicy = reclamationPolicies[c.Rand.Intn(len(reclamationPolicies))]
},
func(pvc *api.PersistentVolumeClaim, c fuzz.Continue) {
c.FuzzNoCustom(pvc) // fuzz self without calling this function again
types := []api.PersistentVolumeClaimPhase{api.ClaimBound, api.ClaimPending, api.ClaimLost}
pvc.Status.Phase = types[c.Rand.Intn(len(types))]
},
func(s *api.NamespaceSpec, c fuzz.Continue) {
s.Finalizers = []api.FinalizerName{api.FinalizerKubernetes}
},
func(s *api.NamespaceStatus, c fuzz.Continue) {
s.Phase = api.NamespaceActive
},
func(http *api.HTTPGetAction, c fuzz.Continue) {
c.FuzzNoCustom(http) // fuzz self without calling this function again
http.Path = "/" + http.Path // can't be blank
http.Scheme = "x" + http.Scheme // can't be blank
},
func(ss *api.ServiceSpec, c fuzz.Continue) {
c.FuzzNoCustom(ss) // fuzz self without calling this function again
if len(ss.Ports) == 0 {
// There must be at least 1 port.
ss.Ports = append(ss.Ports, api.ServicePort{})
c.Fuzz(&ss.Ports[0])
}
for i := range ss.Ports {
switch ss.Ports[i].TargetPort.Type {
case intstr.Int:
ss.Ports[i].TargetPort.IntVal = 1 + ss.Ports[i].TargetPort.IntVal%65535 // non-zero
case intstr.String:
ss.Ports[i].TargetPort.StrVal = "x" + ss.Ports[i].TargetPort.StrVal // non-empty
}
}
},
func(n *api.Node, c fuzz.Continue) {
c.FuzzNoCustom(n)
n.Spec.ExternalID = "external"
},
func(s *api.NodeStatus, c fuzz.Continue) {
c.FuzzNoCustom(s)
s.Allocatable = s.Capacity
},
func(s *autoscaling.HorizontalPodAutoscalerSpec, c fuzz.Continue) {
c.FuzzNoCustom(s) // fuzz self without calling this function again
minReplicas := int32(c.Rand.Int31())
s.MinReplicas = &minReplicas
targetCpu := int32(c.RandUint64())
s.TargetCPUUtilizationPercentage = &targetCpu
},
func(psp *extensions.PodSecurityPolicySpec, c fuzz.Continue) {
c.FuzzNoCustom(psp) // fuzz self without calling this function again
runAsUserRules := []extensions.RunAsUserStrategy{extensions.RunAsUserStrategyMustRunAsNonRoot, extensions.RunAsUserStrategyMustRunAs, extensions.RunAsUserStrategyRunAsAny}
psp.RunAsUser.Rule = runAsUserRules[c.Rand.Intn(len(runAsUserRules))]
seLinuxRules := []extensions.SELinuxStrategy{extensions.SELinuxStrategyRunAsAny, extensions.SELinuxStrategyMustRunAs}
psp.SELinux.Rule = seLinuxRules[c.Rand.Intn(len(seLinuxRules))]
},
func(s *extensions.Scale, c fuzz.Continue) {
c.FuzzNoCustom(s) // fuzz self without calling this function again
// TODO: Implement a fuzzer to generate valid keys, values and operators for
// selector requirements.
if s.Status.Selector != nil {
s.Status.Selector = &unversioned.LabelSelector{
MatchLabels: map[string]string{
"testlabelkey": "testlabelval",
},
MatchExpressions: []unversioned.LabelSelectorRequirement{
{
Key: "testkey",
Operator: unversioned.LabelSelectorOpIn,
Values: []string{"val1", "val2", "val3"},
},
},
}
}
},
func(r *runtime.RawExtension, c fuzz.Continue) {
// Pick an arbitrary type and fuzz it
types := []runtime.Object{&api.Pod{}, &extensions.Deployment{}, &api.Service{}}
obj := types[c.Rand.Intn(len(types))]
c.Fuzz(obj)
// Find a codec for converting the object to raw bytes. This is necessary for the
// api version and kind to be correctly set be serialization.
var codec runtime.Codec
switch obj.(type) {
case *api.Pod:
codec = testapi.Default.Codec()
case *extensions.Deployment:
codec = testapi.Extensions.Codec()
case *api.Service:
codec = testapi.Default.Codec()
default:
t.Errorf("Failed to find codec for object type: %T", obj)
return
}
// Convert the object to raw bytes
bytes, err := runtime.Encode(codec, obj)
if err != nil {
t.Errorf("Failed to encode object: %v", err)
return
}
// Set the bytes field on the RawExtension
r.Raw = bytes
},
)
return f
}
func parseMesosState(blob []byte) (*mesosState, error) {
type State struct {
ClusterName string `json:"cluster"`
Slaves []*struct {
Id string `json:"id"` // ex: 20150106-162714-3815890698-5050-2453-S2
Pid string `json:"pid"` // ex: slave(1)@10.22.211.18:5051
Hostname string `json:"hostname"` // ex: 10.22.211.18, or slave-123.nowhere.com
Resources map[string]interface{} `json:"resources"` // ex: {"mem": 123, "ports": "[31000-3200]"}
} `json:"slaves"`
Frameworks []*struct {
Id string `json:"id"` // ex: 20151105-093752-3745622208-5050-1-0000
Pid string `json:"pid"` // ex: scheduler(1)@192.168.65.228:57124
Executors []*struct {
SlaveId string `json:"slave_id"` // ex: 20151105-093752-3745622208-5050-1-S1
ExecutorId string `json:"executor_id"` // ex: 6704d375c68fee1e_k8sm-executor
Name string `json:"name"` // ex: Kubelet-Executor
} `json:"executors"`
} `json:"frameworks"`
}
state := &State{ClusterName: defaultClusterName}
if err := json.Unmarshal(blob, state); err != nil {
return nil, err
}
executorSlaveIds := map[string]struct{}{}
for _, f := range state.Frameworks {
for _, e := range f.Executors {
// Note that this simple comparison breaks when we support more than one
// k8s instance in a cluster. At the moment this is not possible for
// a number of reasons.
// TODO(sttts): find way to detect executors of this k8s instance
if e.Name == KubernetesExecutorName {
executorSlaveIds[e.SlaveId] = struct{}{}
}
}
}
nodes := map[string]*slaveNode{} // by hostname
for _, slave := range state.Slaves {
if slave.Hostname == "" {
continue
}
node := &slaveNode{hostname: slave.Hostname}
cap := api.ResourceList{}
if slave.Resources != nil && len(slave.Resources) > 0 {
// attempt to translate CPU (cores) and memory (MB) resources
if cpu, found := slave.Resources["cpus"]; found {
if cpuNum, ok := cpu.(float64); ok {
cap[api.ResourceCPU] = *resource.NewQuantity(int64(cpuNum), resource.DecimalSI)
} else {
log.Warningf("unexpected slave cpu resource type %T: %v", cpu, cpu)
}
} else {
log.Warningf("slave failed to report cpu resource")
}
if mem, found := slave.Resources["mem"]; found {
if memNum, ok := mem.(float64); ok {
cap[api.ResourceMemory] = *resource.NewQuantity(int64(memNum), resource.BinarySI)
} else {
log.Warningf("unexpected slave mem resource type %T: %v", mem, mem)
}
} else {
log.Warningf("slave failed to report mem resource")
}
}
if len(cap) > 0 {
node.resources = &api.NodeResources{
Capacity: cap,
}
log.V(4).Infof("node %q reporting capacity %v", node.hostname, cap)
}
if _, ok := executorSlaveIds[slave.Id]; ok {
node.kubeletRunning = true
}
nodes[node.hostname] = node
}
result := &mesosState{
clusterName: state.ClusterName,
nodes: nodes,
}
return result, nil
}
func (tc *testCase) prepareTestClient(t *testing.T) *fake.Clientset {
namespace := "test-namespace"
tc.namespace = namespace
podNamePrefix := "test-pod"
podLabels := map[string]string{"name": podNamePrefix}
tc.selector = labels.SelectorFromSet(podLabels)
fakeClient := &fake.Clientset{}
fakeClient.AddReactor("list", "pods", func(action core.Action) (handled bool, ret runtime.Object, err error) {
if tc.podListOverride != nil {
return true, tc.podListOverride, nil
}
obj := &api.PodList{}
for i := 0; i < tc.replicas; i++ {
podName := fmt.Sprintf("%s-%d", podNamePrefix, i)
pod := buildPod(namespace, podName, podLabels, api.PodRunning)
obj.Items = append(obj.Items, pod)
}
return true, obj, nil
})
if tc.useMetricsApi {
fakeClient.AddProxyReactor("services", func(action core.Action) (handled bool, ret restclient.ResponseWrapper, err error) {
metrics := []*metrics_api.PodMetrics{}
for i, containers := range tc.reportedPodMetrics {
metric := &metrics_api.PodMetrics{
ObjectMeta: v1.ObjectMeta{
Name: fmt.Sprintf("%s-%d", podNamePrefix, i),
Namespace: namespace,
},
Timestamp: unversioned.Time{Time: fixedTimestamp.Add(time.Duration(tc.targetTimestamp) * time.Minute)},
Containers: []metrics_api.ContainerMetrics{},
}
for j, cpu := range containers {
cm := metrics_api.ContainerMetrics{
Name: fmt.Sprintf("%s-%d-container-%d", podNamePrefix, i, j),
Usage: v1.ResourceList{
v1.ResourceCPU: *resource.NewMilliQuantity(
cpu,
resource.DecimalSI),
v1.ResourceMemory: *resource.NewQuantity(
int64(1024*1024),
resource.BinarySI),
},
}
metric.Containers = append(metric.Containers, cm)
}
metrics = append(metrics, metric)
}
heapsterRawMemResponse, _ := json.Marshal(&metrics)
return true, newFakeResponseWrapper(heapsterRawMemResponse), nil
})
} else {
fakeClient.AddProxyReactor("services", func(action core.Action) (handled bool, ret restclient.ResponseWrapper, err error) {
metrics := heapster.MetricResultList{}
var latestTimestamp time.Time
for _, reportedMetricPoints := range tc.reportedMetricsPoints {
var heapsterMetricPoints []heapster.MetricPoint
for _, reportedMetricPoint := range reportedMetricPoints {
timestamp := fixedTimestamp.Add(time.Duration(reportedMetricPoint.timestamp) * time.Minute)
if latestTimestamp.Before(timestamp) {
latestTimestamp = timestamp
}
heapsterMetricPoint := heapster.MetricPoint{Timestamp: timestamp, Value: reportedMetricPoint.level, FloatValue: nil}
heapsterMetricPoints = append(heapsterMetricPoints, heapsterMetricPoint)
}
metric := heapster.MetricResult{
Metrics: heapsterMetricPoints,
LatestTimestamp: latestTimestamp,
}
metrics.Items = append(metrics.Items, metric)
}
heapsterRawMemResponse, _ := json.Marshal(&metrics)
return true, newFakeResponseWrapper(heapsterRawMemResponse), nil
})
}
return fakeClient
}
