/
memory_manager_test.go
716 lines (596 loc) · 22.6 KB
/
memory_manager_test.go
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//go:build linux
// +build linux
/*
Copyright 2017 The Kubernetes Authors.
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
package e2enode
import (
"context"
"encoding/json"
"fmt"
"os"
"os/exec"
"regexp"
"sort"
"strconv"
"strings"
"time"
v1 "k8s.io/api/core/v1"
"k8s.io/apimachinery/pkg/api/resource"
metav1 "k8s.io/apimachinery/pkg/apis/meta/v1"
kubeletpodresourcesv1 "k8s.io/kubelet/pkg/apis/podresources/v1"
kubeletconfig "k8s.io/kubernetes/pkg/kubelet/apis/config"
"k8s.io/kubernetes/pkg/kubelet/apis/podresources"
"k8s.io/kubernetes/pkg/kubelet/cm/memorymanager/state"
"k8s.io/kubernetes/pkg/kubelet/util"
"k8s.io/kubernetes/test/e2e/feature"
"k8s.io/kubernetes/test/e2e/framework"
e2epod "k8s.io/kubernetes/test/e2e/framework/pod"
admissionapi "k8s.io/pod-security-admission/api"
"k8s.io/utils/cpuset"
"k8s.io/utils/pointer"
"github.com/onsi/ginkgo/v2"
"github.com/onsi/gomega"
)
const (
evictionHardMemory = "memory.available"
resourceMemory = "memory"
staticPolicy = "Static"
nonePolicy = "None"
hugepages2MiCount = 8
)
// Helper for makeMemoryManagerPod().
type memoryManagerCtnAttributes struct {
ctnName string
cpus string
memory string
hugepages2Mi string
}
// makeMemoryManagerContainers returns slice of containers with provided attributes and indicator of hugepages mount needed for those.
func makeMemoryManagerContainers(ctnCmd string, ctnAttributes []memoryManagerCtnAttributes) ([]v1.Container, bool) {
hugepagesMount := false
var containers []v1.Container
for _, ctnAttr := range ctnAttributes {
ctn := v1.Container{
Name: ctnAttr.ctnName,
Image: busyboxImage,
Resources: v1.ResourceRequirements{
Limits: v1.ResourceList{
v1.ResourceCPU: resource.MustParse(ctnAttr.cpus),
v1.ResourceMemory: resource.MustParse(ctnAttr.memory),
},
},
Command: []string{"sh", "-c", ctnCmd},
}
if ctnAttr.hugepages2Mi != "" {
hugepagesMount = true
ctn.Resources.Limits[hugepagesResourceName2Mi] = resource.MustParse(ctnAttr.hugepages2Mi)
ctn.VolumeMounts = []v1.VolumeMount{
{
Name: "hugepages-2mi",
MountPath: "/hugepages-2Mi",
},
}
}
containers = append(containers, ctn)
}
return containers, hugepagesMount
}
// makeMemoryMangerPod returns a pod with the provided ctnAttributes.
func makeMemoryManagerPod(podName string, initCtnAttributes, ctnAttributes []memoryManagerCtnAttributes) *v1.Pod {
hugepagesMount := false
memsetCmd := "grep Mems_allowed_list /proc/self/status | cut -f2"
memsetSleepCmd := memsetCmd + "&& sleep 1d"
var containers, initContainers []v1.Container
if len(initCtnAttributes) > 0 {
initContainers, _ = makeMemoryManagerContainers(memsetCmd, initCtnAttributes)
}
containers, hugepagesMount = makeMemoryManagerContainers(memsetSleepCmd, ctnAttributes)
pod := &v1.Pod{
ObjectMeta: metav1.ObjectMeta{
GenerateName: podName,
},
Spec: v1.PodSpec{
RestartPolicy: v1.RestartPolicyNever,
Containers: containers,
InitContainers: initContainers,
},
}
if hugepagesMount {
pod.Spec.Volumes = []v1.Volume{
{
Name: "hugepages-2mi",
VolumeSource: v1.VolumeSource{
EmptyDir: &v1.EmptyDirVolumeSource{
Medium: mediumHugepages2Mi,
},
},
},
}
}
return pod
}
func getMemoryManagerState() (*state.MemoryManagerCheckpoint, error) {
if _, err := os.Stat(memoryManagerStateFile); os.IsNotExist(err) {
return nil, fmt.Errorf("the memory manager state file %s does not exist", memoryManagerStateFile)
}
out, err := exec.Command("/bin/sh", "-c", fmt.Sprintf("cat %s", memoryManagerStateFile)).Output()
if err != nil {
return nil, fmt.Errorf("failed to run command 'cat %s': out: %s, err: %w", memoryManagerStateFile, out, err)
}
memoryManagerCheckpoint := &state.MemoryManagerCheckpoint{}
if err := json.Unmarshal(out, memoryManagerCheckpoint); err != nil {
return nil, fmt.Errorf("failed to unmarshal memory manager state file: %w", err)
}
return memoryManagerCheckpoint, nil
}
func getAllocatableMemoryFromStateFile(s *state.MemoryManagerCheckpoint) []state.Block {
var allocatableMemory []state.Block
for numaNodeID, numaNodeState := range s.MachineState {
for resourceName, memoryTable := range numaNodeState.MemoryMap {
if memoryTable.Allocatable == 0 {
continue
}
block := state.Block{
NUMAAffinity: []int{numaNodeID},
Type: resourceName,
Size: memoryTable.Allocatable,
}
allocatableMemory = append(allocatableMemory, block)
}
}
return allocatableMemory
}
type memoryManagerKubeletParams struct {
policy string
systemReservedMemory []kubeletconfig.MemoryReservation
systemReserved map[string]string
kubeReserved map[string]string
evictionHard map[string]string
}
func updateKubeletConfigWithMemoryManagerParams(initialCfg *kubeletconfig.KubeletConfiguration, params *memoryManagerKubeletParams) {
if initialCfg.FeatureGates == nil {
initialCfg.FeatureGates = map[string]bool{}
}
initialCfg.MemoryManagerPolicy = params.policy
// update system-reserved
if initialCfg.SystemReserved == nil {
initialCfg.SystemReserved = map[string]string{}
}
for resourceName, value := range params.systemReserved {
initialCfg.SystemReserved[resourceName] = value
}
// update kube-reserved
if initialCfg.KubeReserved == nil {
initialCfg.KubeReserved = map[string]string{}
}
for resourceName, value := range params.kubeReserved {
initialCfg.KubeReserved[resourceName] = value
}
// update hard eviction threshold
if initialCfg.EvictionHard == nil {
initialCfg.EvictionHard = map[string]string{}
}
for resourceName, value := range params.evictionHard {
initialCfg.EvictionHard[resourceName] = value
}
// update reserved memory
if initialCfg.ReservedMemory == nil {
initialCfg.ReservedMemory = []kubeletconfig.MemoryReservation{}
}
initialCfg.ReservedMemory = append(initialCfg.ReservedMemory, params.systemReservedMemory...)
}
func getAllNUMANodes() []int {
outData, err := exec.Command("/bin/sh", "-c", "lscpu").Output()
framework.ExpectNoError(err)
numaNodeRegex, err := regexp.Compile(`NUMA node(\d+) CPU\(s\):`)
framework.ExpectNoError(err)
matches := numaNodeRegex.FindAllSubmatch(outData, -1)
var numaNodes []int
for _, m := range matches {
n, err := strconv.Atoi(string(m[1]))
framework.ExpectNoError(err)
numaNodes = append(numaNodes, n)
}
sort.Ints(numaNodes)
return numaNodes
}
// Serial because the test updates kubelet configuration.
var _ = SIGDescribe("Memory Manager", framework.WithDisruptive(), framework.WithSerial(), feature.MemoryManager, func() {
// TODO: add more complex tests that will include interaction between CPUManager, MemoryManager and TopologyManager
var (
allNUMANodes []int
ctnParams, initCtnParams []memoryManagerCtnAttributes
is2MiHugepagesSupported *bool
isMultiNUMASupported *bool
testPod *v1.Pod
)
f := framework.NewDefaultFramework("memory-manager-test")
f.NamespacePodSecurityLevel = admissionapi.LevelPrivileged
memoryQuantity := resource.MustParse("1100Mi")
defaultKubeParams := &memoryManagerKubeletParams{
systemReservedMemory: []kubeletconfig.MemoryReservation{
{
NumaNode: 0,
Limits: v1.ResourceList{
resourceMemory: memoryQuantity,
},
},
},
systemReserved: map[string]string{resourceMemory: "500Mi"},
kubeReserved: map[string]string{resourceMemory: "500Mi"},
evictionHard: map[string]string{evictionHardMemory: "100Mi"},
}
verifyMemoryPinning := func(ctx context.Context, pod *v1.Pod, numaNodeIDs []int) {
ginkgo.By("Verifying the NUMA pinning")
output, err := e2epod.GetPodLogs(ctx, f.ClientSet, f.Namespace.Name, pod.Name, pod.Spec.Containers[0].Name)
framework.ExpectNoError(err)
currentNUMANodeIDs, err := cpuset.Parse(strings.Trim(output, "\n"))
framework.ExpectNoError(err)
gomega.Expect(numaNodeIDs).To(gomega.Equal(currentNUMANodeIDs.List()))
}
waitingForHugepages := func(ctx context.Context, hugepagesCount int) {
gomega.Eventually(ctx, func(ctx context.Context) error {
node, err := f.ClientSet.CoreV1().Nodes().Get(ctx, framework.TestContext.NodeName, metav1.GetOptions{})
if err != nil {
return err
}
capacity, ok := node.Status.Capacity[v1.ResourceName(hugepagesResourceName2Mi)]
if !ok {
return fmt.Errorf("the node does not have the resource %s", hugepagesResourceName2Mi)
}
size, succeed := capacity.AsInt64()
if !succeed {
return fmt.Errorf("failed to convert quantity to int64")
}
// 512 Mb, the expected size in bytes
expectedSize := int64(hugepagesCount * hugepagesSize2M * 1024)
if size != expectedSize {
return fmt.Errorf("the actual size %d is different from the expected one %d", size, expectedSize)
}
return nil
}, time.Minute, framework.Poll).Should(gomega.BeNil())
}
ginkgo.BeforeEach(func(ctx context.Context) {
if isMultiNUMASupported == nil {
isMultiNUMASupported = pointer.BoolPtr(isMultiNUMA())
}
if is2MiHugepagesSupported == nil {
is2MiHugepagesSupported = pointer.BoolPtr(isHugePageAvailable(hugepagesSize2M))
}
if len(allNUMANodes) == 0 {
allNUMANodes = getAllNUMANodes()
}
// allocate hugepages
if *is2MiHugepagesSupported {
ginkgo.By("Configuring hugepages")
gomega.Eventually(ctx, func() error {
return configureHugePages(hugepagesSize2M, hugepages2MiCount, pointer.IntPtr(0))
}, 30*time.Second, framework.Poll).Should(gomega.BeNil())
}
})
// dynamically update the kubelet configuration
ginkgo.JustBeforeEach(func(ctx context.Context) {
// allocate hugepages
if *is2MiHugepagesSupported {
ginkgo.By("Waiting for hugepages resource to become available on the local node")
waitingForHugepages(ctx, hugepages2MiCount)
for i := 0; i < len(ctnParams); i++ {
ctnParams[i].hugepages2Mi = "8Mi"
}
}
if len(ctnParams) > 0 {
testPod = makeMemoryManagerPod(ctnParams[0].ctnName, initCtnParams, ctnParams)
}
})
ginkgo.JustAfterEach(func(ctx context.Context) {
// delete the test pod
if testPod != nil && testPod.Name != "" {
e2epod.NewPodClient(f).DeleteSync(ctx, testPod.Name, metav1.DeleteOptions{}, 2*time.Minute)
}
// release hugepages
if *is2MiHugepagesSupported {
ginkgo.By("Releasing allocated hugepages")
gomega.Eventually(ctx, func() error {
// configure hugepages on the NUMA node 0 to avoid hugepages split across NUMA nodes
return configureHugePages(hugepagesSize2M, 0, pointer.IntPtr(0))
}, 90*time.Second, 15*time.Second).ShouldNot(gomega.HaveOccurred(), "failed to release hugepages")
}
})
ginkgo.Context("with static policy", func() {
tempSetCurrentKubeletConfig(f, func(ctx context.Context, initialConfig *kubeletconfig.KubeletConfiguration) {
kubeParams := *defaultKubeParams
kubeParams.policy = staticPolicy
updateKubeletConfigWithMemoryManagerParams(initialConfig, &kubeParams)
})
ginkgo.JustAfterEach(func() {
// reset containers attributes
ctnParams = []memoryManagerCtnAttributes{}
initCtnParams = []memoryManagerCtnAttributes{}
})
// TODO: move the test to pod resource API test suite, see - https://github.com/kubernetes/kubernetes/issues/101945
ginkgo.It("should report memory data during request to pod resources GetAllocatableResources", func(ctx context.Context) {
endpoint, err := util.LocalEndpoint(defaultPodResourcesPath, podresources.Socket)
framework.ExpectNoError(err)
cli, conn, err := podresources.GetV1Client(endpoint, defaultPodResourcesTimeout, defaultPodResourcesMaxSize)
framework.ExpectNoError(err)
defer conn.Close()
resp, err := cli.GetAllocatableResources(ctx, &kubeletpodresourcesv1.AllocatableResourcesRequest{})
framework.ExpectNoError(err)
gomega.Expect(resp.Memory).ToNot(gomega.BeEmpty())
stateData, err := getMemoryManagerState()
framework.ExpectNoError(err)
stateAllocatableMemory := getAllocatableMemoryFromStateFile(stateData)
gomega.Expect(resp.Memory).To(gomega.HaveLen(len(stateAllocatableMemory)))
for _, containerMemory := range resp.Memory {
gomega.Expect(containerMemory.Topology).NotTo(gomega.BeNil())
gomega.Expect(containerMemory.Topology.Nodes).To(gomega.HaveLen(1))
gomega.Expect(containerMemory.Topology.Nodes[0]).NotTo(gomega.BeNil())
numaNodeID := int(containerMemory.Topology.Nodes[0].ID)
for _, numaStateMemory := range stateAllocatableMemory {
gomega.Expect(numaStateMemory.NUMAAffinity).To(gomega.HaveLen(1))
if numaNodeID != numaStateMemory.NUMAAffinity[0] {
continue
}
if containerMemory.MemoryType != string(numaStateMemory.Type) {
continue
}
gomega.Expect(containerMemory.Size_).To(gomega.BeEquivalentTo(numaStateMemory.Size))
}
}
gomega.Expect(resp.Memory).ToNot(gomega.BeEmpty())
})
ginkgo.When("guaranteed pod has init and app containers", func() {
ginkgo.BeforeEach(func() {
// override containers parameters
ctnParams = []memoryManagerCtnAttributes{
{
ctnName: "memory-manager-static",
cpus: "100m",
memory: "128Mi",
},
}
// override init container parameters
initCtnParams = []memoryManagerCtnAttributes{
{
ctnName: "init-memory-manager-static",
cpus: "100m",
memory: "128Mi",
},
}
})
ginkgo.It("should succeed to start the pod", func(ctx context.Context) {
ginkgo.By("Running the test pod")
testPod = e2epod.NewPodClient(f).CreateSync(ctx, testPod)
// it no taste to verify NUMA pinning when the node has only one NUMA node
if !*isMultiNUMASupported {
return
}
verifyMemoryPinning(ctx, testPod, []int{0})
})
})
ginkgo.When("guaranteed pod has only app containers", func() {
ginkgo.BeforeEach(func() {
// override containers parameters
ctnParams = []memoryManagerCtnAttributes{
{
ctnName: "memory-manager-static",
cpus: "100m",
memory: "128Mi",
},
}
})
ginkgo.It("should succeed to start the pod", func(ctx context.Context) {
ginkgo.By("Running the test pod")
testPod = e2epod.NewPodClient(f).CreateSync(ctx, testPod)
// it no taste to verify NUMA pinning when the node has only one NUMA node
if !*isMultiNUMASupported {
return
}
verifyMemoryPinning(ctx, testPod, []int{0})
})
})
ginkgo.When("multiple guaranteed pods started", func() {
var testPod2 *v1.Pod
ginkgo.BeforeEach(func() {
// override containers parameters
ctnParams = []memoryManagerCtnAttributes{
{
ctnName: "memory-manager-static",
cpus: "100m",
memory: "128Mi",
},
}
})
ginkgo.JustBeforeEach(func() {
testPod2 = makeMemoryManagerPod("memory-manager-static", initCtnParams, ctnParams)
})
ginkgo.It("should succeed to start all pods", func(ctx context.Context) {
ginkgo.By("Running the test pod and the test pod 2")
testPod = e2epod.NewPodClient(f).CreateSync(ctx, testPod)
ginkgo.By("Running the test pod 2")
testPod2 = e2epod.NewPodClient(f).CreateSync(ctx, testPod2)
// it no taste to verify NUMA pinning when the node has only one NUMA node
if !*isMultiNUMASupported {
return
}
verifyMemoryPinning(ctx, testPod, []int{0})
verifyMemoryPinning(ctx, testPod2, []int{0})
})
// TODO: move the test to pod resource API test suite, see - https://github.com/kubernetes/kubernetes/issues/101945
ginkgo.It("should report memory data for each guaranteed pod and container during request to pod resources List", func(ctx context.Context) {
ginkgo.By("Running the test pod and the test pod 2")
testPod = e2epod.NewPodClient(f).CreateSync(ctx, testPod)
ginkgo.By("Running the test pod 2")
testPod2 = e2epod.NewPodClient(f).CreateSync(ctx, testPod2)
endpoint, err := util.LocalEndpoint(defaultPodResourcesPath, podresources.Socket)
framework.ExpectNoError(err)
cli, conn, err := podresources.GetV1Client(endpoint, defaultPodResourcesTimeout, defaultPodResourcesMaxSize)
framework.ExpectNoError(err)
defer conn.Close()
resp, err := cli.List(ctx, &kubeletpodresourcesv1.ListPodResourcesRequest{})
framework.ExpectNoError(err)
for _, pod := range []*v1.Pod{testPod, testPod2} {
for _, podResource := range resp.PodResources {
if podResource.Name != pod.Name {
continue
}
for _, c := range pod.Spec.Containers {
for _, containerResource := range podResource.Containers {
if containerResource.Name != c.Name {
continue
}
for _, containerMemory := range containerResource.Memory {
q := c.Resources.Limits[v1.ResourceName(containerMemory.MemoryType)]
value, ok := q.AsInt64()
gomega.Expect(ok).To(gomega.BeTrue())
gomega.Expect(value).To(gomega.BeEquivalentTo(containerMemory.Size_))
}
}
}
}
}
})
ginkgo.JustAfterEach(func(ctx context.Context) {
// delete the test pod 2
if testPod2.Name != "" {
e2epod.NewPodClient(f).DeleteSync(ctx, testPod2.Name, metav1.DeleteOptions{}, 2*time.Minute)
}
})
})
// the test requires at least two NUMA nodes
// test on each NUMA node will start the pod that will consume almost all memory of the NUMA node except 256Mi
// after it will start an additional pod with the memory request that can not be satisfied by the single NUMA node
// free memory
ginkgo.When("guaranteed pod memory request is bigger than free memory on each NUMA node", func() {
var workloadPods []*v1.Pod
ginkgo.BeforeEach(func() {
if !*isMultiNUMASupported {
ginkgo.Skip("The machines has less than two NUMA nodes")
}
ctnParams = []memoryManagerCtnAttributes{
{
ctnName: "memory-manager-static",
cpus: "100m",
memory: "384Mi",
},
}
})
ginkgo.JustBeforeEach(func(ctx context.Context) {
stateData, err := getMemoryManagerState()
framework.ExpectNoError(err)
for _, memoryState := range stateData.MachineState {
// consume all memory except of 256Mi on each NUMA node via workload pods
workloadPodMemory := memoryState.MemoryMap[v1.ResourceMemory].Free - 256*1024*1024
memoryQuantity := resource.NewQuantity(int64(workloadPodMemory), resource.BinarySI)
workloadCtnAttrs := []memoryManagerCtnAttributes{
{
ctnName: "workload-pod",
cpus: "100m",
memory: memoryQuantity.String(),
},
}
workloadPod := makeMemoryManagerPod(workloadCtnAttrs[0].ctnName, initCtnParams, workloadCtnAttrs)
workloadPod = e2epod.NewPodClient(f).CreateSync(ctx, workloadPod)
workloadPods = append(workloadPods, workloadPod)
}
})
ginkgo.It("should be rejected", func(ctx context.Context) {
ginkgo.By("Creating the pod")
testPod = e2epod.NewPodClient(f).Create(ctx, testPod)
ginkgo.By("Checking that pod failed to start because of admission error")
gomega.Eventually(ctx, func() bool {
tmpPod, err := e2epod.NewPodClient(f).Get(ctx, testPod.Name, metav1.GetOptions{})
framework.ExpectNoError(err)
if tmpPod.Status.Phase != v1.PodFailed {
return false
}
if tmpPod.Status.Reason != "UnexpectedAdmissionError" {
return false
}
if !strings.Contains(tmpPod.Status.Message, "Allocate failed due to [memorymanager]") {
return false
}
return true
}, time.Minute, 5*time.Second).Should(
gomega.BeTrue(),
"the pod succeeded to start, when it should fail with the admission error",
)
})
ginkgo.JustAfterEach(func(ctx context.Context) {
for _, workloadPod := range workloadPods {
if workloadPod.Name != "" {
e2epod.NewPodClient(f).DeleteSync(ctx, workloadPod.Name, metav1.DeleteOptions{}, 2*time.Minute)
}
}
})
})
})
ginkgo.Context("with none policy", func() {
tempSetCurrentKubeletConfig(f, func(ctx context.Context, initialConfig *kubeletconfig.KubeletConfiguration) {
kubeParams := *defaultKubeParams
kubeParams.policy = nonePolicy
updateKubeletConfigWithMemoryManagerParams(initialConfig, &kubeParams)
})
// empty context to configure same container parameters for all tests
ginkgo.Context("", func() {
ginkgo.BeforeEach(func() {
// override pod parameters
ctnParams = []memoryManagerCtnAttributes{
{
ctnName: "memory-manager-none",
cpus: "100m",
memory: "128Mi",
},
}
})
// TODO: move the test to pod resource API test suite, see - https://github.com/kubernetes/kubernetes/issues/101945
ginkgo.It("should not report any memory data during request to pod resources GetAllocatableResources", func(ctx context.Context) {
endpoint, err := util.LocalEndpoint(defaultPodResourcesPath, podresources.Socket)
framework.ExpectNoError(err)
cli, conn, err := podresources.GetV1Client(endpoint, defaultPodResourcesTimeout, defaultPodResourcesMaxSize)
framework.ExpectNoError(err)
defer conn.Close()
resp, err := cli.GetAllocatableResources(ctx, &kubeletpodresourcesv1.AllocatableResourcesRequest{})
framework.ExpectNoError(err)
gomega.Expect(resp.Memory).To(gomega.BeEmpty())
})
// TODO: move the test to pod resource API test suite, see - https://github.com/kubernetes/kubernetes/issues/101945
ginkgo.It("should not report any memory data during request to pod resources List", func(ctx context.Context) {
testPod = e2epod.NewPodClient(f).CreateSync(ctx, testPod)
endpoint, err := util.LocalEndpoint(defaultPodResourcesPath, podresources.Socket)
framework.ExpectNoError(err)
cli, conn, err := podresources.GetV1Client(endpoint, defaultPodResourcesTimeout, defaultPodResourcesMaxSize)
framework.ExpectNoError(err)
defer conn.Close()
resp, err := cli.List(ctx, &kubeletpodresourcesv1.ListPodResourcesRequest{})
framework.ExpectNoError(err)
for _, podResource := range resp.PodResources {
if podResource.Name != testPod.Name {
continue
}
for _, containerResource := range podResource.Containers {
gomega.Expect(containerResource.Memory).To(gomega.BeEmpty())
}
}
})
ginkgo.It("should succeed to start the pod", func(ctx context.Context) {
testPod = e2epod.NewPodClient(f).CreateSync(ctx, testPod)
// it no taste to verify NUMA pinning when the node has only one NUMA node
if !*isMultiNUMASupported {
return
}
verifyMemoryPinning(ctx, testPod, allNUMANodes)
})
})
})
})