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proxier.go
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proxier.go
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/*
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 ipvs
import (
"bytes"
"fmt"
"io/ioutil"
"net"
"regexp"
"strconv"
"strings"
"sync"
"sync/atomic"
"time"
"k8s.io/klog"
"k8s.io/api/core/v1"
"k8s.io/apimachinery/pkg/types"
"k8s.io/apimachinery/pkg/util/sets"
"k8s.io/apimachinery/pkg/util/wait"
"k8s.io/client-go/tools/record"
"k8s.io/kubernetes/pkg/proxy"
"k8s.io/kubernetes/pkg/proxy/healthcheck"
"k8s.io/kubernetes/pkg/proxy/metrics"
utilproxy "k8s.io/kubernetes/pkg/proxy/util"
"k8s.io/kubernetes/pkg/util/async"
"k8s.io/kubernetes/pkg/util/conntrack"
utilipset "k8s.io/kubernetes/pkg/util/ipset"
utiliptables "k8s.io/kubernetes/pkg/util/iptables"
utilipvs "k8s.io/kubernetes/pkg/util/ipvs"
utilnet "k8s.io/kubernetes/pkg/util/net"
utilsysctl "k8s.io/kubernetes/pkg/util/sysctl"
utilexec "k8s.io/utils/exec"
)
const (
// kubeServicesChain is the services portal chain
kubeServicesChain utiliptables.Chain = "KUBE-SERVICES"
// KubeFireWallChain is the kubernetes firewall chain.
KubeFireWallChain utiliptables.Chain = "KUBE-FIREWALL"
// kubePostroutingChain is the kubernetes postrouting chain
kubePostroutingChain utiliptables.Chain = "KUBE-POSTROUTING"
// KubeMarkMasqChain is the mark-for-masquerade chain
KubeMarkMasqChain utiliptables.Chain = "KUBE-MARK-MASQ"
// KubeNodePortChain is the kubernetes node port chain
KubeNodePortChain utiliptables.Chain = "KUBE-NODE-PORT"
// KubeMarkDropChain is the mark-for-drop chain
KubeMarkDropChain utiliptables.Chain = "KUBE-MARK-DROP"
// KubeForwardChain is the kubernetes forward chain
KubeForwardChain utiliptables.Chain = "KUBE-FORWARD"
// KubeLoadBalancerChain is the kubernetes chain for loadbalancer type service
KubeLoadBalancerChain utiliptables.Chain = "KUBE-LOAD-BALANCER"
// DefaultScheduler is the default ipvs scheduler algorithm - round robin.
DefaultScheduler = "rr"
// DefaultDummyDevice is the default dummy interface which ipvs service address will bind to it.
DefaultDummyDevice = "kube-ipvs0"
)
// iptablesJumpChain is tables of iptables chains that ipvs proxier used to install iptables or cleanup iptables.
// `to` is the iptables chain we want to operate.
// `from` is the source iptables chain
var iptablesJumpChain = []struct {
table utiliptables.Table
from utiliptables.Chain
to utiliptables.Chain
comment string
}{
{utiliptables.TableNAT, utiliptables.ChainOutput, kubeServicesChain, "kubernetes service portals"},
{utiliptables.TableNAT, utiliptables.ChainPrerouting, kubeServicesChain, "kubernetes service portals"},
{utiliptables.TableNAT, utiliptables.ChainPostrouting, kubePostroutingChain, "kubernetes postrouting rules"},
{utiliptables.TableFilter, utiliptables.ChainForward, KubeForwardChain, "kubernetes forwarding rules"},
}
var iptablesChains = []struct {
table utiliptables.Table
chain utiliptables.Chain
}{
{utiliptables.TableNAT, kubeServicesChain},
{utiliptables.TableNAT, kubePostroutingChain},
{utiliptables.TableNAT, KubeFireWallChain},
{utiliptables.TableNAT, KubeNodePortChain},
{utiliptables.TableNAT, KubeLoadBalancerChain},
{utiliptables.TableNAT, KubeMarkMasqChain},
{utiliptables.TableFilter, KubeForwardChain},
}
// ipsetInfo is all ipset we needed in ipvs proxier
var ipsetInfo = []struct {
name string
setType utilipset.Type
comment string
}{
{kubeLoopBackIPSet, utilipset.HashIPPortIP, kubeLoopBackIPSetComment},
{kubeClusterIPSet, utilipset.HashIPPort, kubeClusterIPSetComment},
{kubeExternalIPSet, utilipset.HashIPPort, kubeExternalIPSetComment},
{kubeLoadBalancerSet, utilipset.HashIPPort, kubeLoadBalancerSetComment},
{kubeLoadbalancerFWSet, utilipset.HashIPPort, kubeLoadbalancerFWSetComment},
{kubeLoadBalancerLocalSet, utilipset.HashIPPort, kubeLoadBalancerLocalSetComment},
{kubeLoadBalancerSourceIPSet, utilipset.HashIPPortIP, kubeLoadBalancerSourceIPSetComment},
{kubeLoadBalancerSourceCIDRSet, utilipset.HashIPPortNet, kubeLoadBalancerSourceCIDRSetComment},
{kubeNodePortSetTCP, utilipset.BitmapPort, kubeNodePortSetTCPComment},
{kubeNodePortLocalSetTCP, utilipset.BitmapPort, kubeNodePortLocalSetTCPComment},
{kubeNodePortSetUDP, utilipset.BitmapPort, kubeNodePortSetUDPComment},
{kubeNodePortLocalSetUDP, utilipset.BitmapPort, kubeNodePortLocalSetUDPComment},
{kubeNodePortSetSCTP, utilipset.BitmapPort, kubeNodePortSetSCTPComment},
{kubeNodePortLocalSetSCTP, utilipset.BitmapPort, kubeNodePortLocalSetSCTPComment},
}
// ipsetWithIptablesChain is the ipsets list with iptables source chain and the chain jump to
// `iptables -t nat -A <from> -m set --match-set <name> <matchType> -j <to>`
// example: iptables -t nat -A KUBE-SERVICES -m set --match-set KUBE-NODE-PORT-TCP dst -j KUBE-NODE-PORT
// ipsets with other match rules will be created Individually.
// Note: kubeNodePortLocalSetTCP must be prior to kubeNodePortSetTCP, the same for UDP.
var ipsetWithIptablesChain = []struct {
name string
from string
to string
matchType string
protocolMatch string
}{
{kubeLoopBackIPSet, string(kubePostroutingChain), "MASQUERADE", "dst,dst,src", ""},
{kubeLoadBalancerSet, string(kubeServicesChain), string(KubeLoadBalancerChain), "dst,dst", ""},
{kubeLoadbalancerFWSet, string(KubeLoadBalancerChain), string(KubeFireWallChain), "dst,dst", ""},
{kubeLoadBalancerSourceCIDRSet, string(KubeFireWallChain), "RETURN", "dst,dst,src", ""},
{kubeLoadBalancerSourceIPSet, string(KubeFireWallChain), "RETURN", "dst,dst,src", ""},
{kubeLoadBalancerLocalSet, string(KubeLoadBalancerChain), "RETURN", "dst,dst", ""},
{kubeNodePortLocalSetTCP, string(KubeNodePortChain), "RETURN", "dst", "tcp"},
{kubeNodePortSetTCP, string(KubeNodePortChain), string(KubeMarkMasqChain), "dst", "tcp"},
{kubeNodePortLocalSetUDP, string(KubeNodePortChain), "RETURN", "dst", "udp"},
{kubeNodePortSetUDP, string(KubeNodePortChain), string(KubeMarkMasqChain), "dst", "udp"},
{kubeNodePortSetSCTP, string(kubeServicesChain), string(KubeNodePortChain), "dst", "sctp"},
{kubeNodePortLocalSetSCTP, string(KubeNodePortChain), "RETURN", "dst", "sctp"},
}
// In IPVS proxy mode, the following flags need to be set
const sysctlRouteLocalnet = "net/ipv4/conf/all/route_localnet"
const sysctlBridgeCallIPTables = "net/bridge/bridge-nf-call-iptables"
const sysctlVSConnTrack = "net/ipv4/vs/conntrack"
const sysctlConnReuse = "net/ipv4/vs/conn_reuse_mode"
const sysctlExpireNoDestConn = "net/ipv4/vs/expire_nodest_conn"
const sysctlExpireQuiescentTemplate = "net/ipv4/vs/expire_quiescent_template"
const sysctlForward = "net/ipv4/ip_forward"
const sysctlArpIgnore = "net/ipv4/conf/all/arp_ignore"
const sysctlArpAnnounce = "net/ipv4/conf/all/arp_announce"
// Proxier is an ipvs based proxy for connections between a localhost:lport
// and services that provide the actual backends.
type Proxier struct {
// endpointsChanges and serviceChanges contains all changes to endpoints and
// services that happened since last syncProxyRules call. For a single object,
// changes are accumulated, i.e. previous is state from before all of them,
// current is state after applying all of those.
endpointsChanges *proxy.EndpointChangeTracker
serviceChanges *proxy.ServiceChangeTracker
mu sync.Mutex // protects the following fields
serviceMap proxy.ServiceMap
endpointsMap proxy.EndpointsMap
portsMap map[utilproxy.LocalPort]utilproxy.Closeable
// endpointsSynced and servicesSynced are set to true when corresponding
// objects are synced after startup. This is used to avoid updating ipvs rules
// with some partial data after kube-proxy restart.
endpointsSynced bool
servicesSynced bool
initialized int32
syncRunner *async.BoundedFrequencyRunner // governs calls to syncProxyRules
// These are effectively const and do not need the mutex to be held.
syncPeriod time.Duration
minSyncPeriod time.Duration
// Values are CIDR's to exclude when cleaning up IPVS rules.
excludeCIDRs []string
// Set to true to set sysctls arp_ignore and arp_announce
strictARP bool
iptables utiliptables.Interface
ipvs utilipvs.Interface
ipset utilipset.Interface
exec utilexec.Interface
masqueradeAll bool
masqueradeMark string
clusterCIDR string
hostname string
nodeIP net.IP
portMapper utilproxy.PortOpener
recorder record.EventRecorder
healthChecker healthcheck.Server
healthzServer healthcheck.HealthzUpdater
ipvsScheduler string
// Added as a member to the struct to allow injection for testing.
ipGetter IPGetter
// The following buffers are used to reuse memory and avoid allocations
// that are significantly impacting performance.
iptablesData *bytes.Buffer
filterChainsData *bytes.Buffer
natChains *bytes.Buffer
filterChains *bytes.Buffer
natRules *bytes.Buffer
filterRules *bytes.Buffer
// Added as a member to the struct to allow injection for testing.
netlinkHandle NetLinkHandle
// ipsetList is the list of ipsets that ipvs proxier used.
ipsetList map[string]*IPSet
// Values are as a parameter to select the interfaces which nodeport works.
nodePortAddresses []string
// networkInterfacer defines an interface for several net library functions.
// Inject for test purpose.
networkInterfacer utilproxy.NetworkInterfacer
gracefuldeleteManager *GracefulTerminationManager
}
// IPGetter helps get node network interface IP
type IPGetter interface {
NodeIPs() ([]net.IP, error)
}
// realIPGetter is a real NodeIP handler, it implements IPGetter.
type realIPGetter struct {
// nl is a handle for revoking netlink interface
nl NetLinkHandle
}
// NodeIPs returns all LOCAL type IP addresses from host which are taken as the Node IPs of NodePort service.
// It will list source IP exists in local route table with `kernel` protocol type, and filter out IPVS proxier
// created dummy device `kube-ipvs0` For example,
// $ ip route show table local type local proto kernel
// 10.0.0.1 dev kube-ipvs0 scope host src 10.0.0.1
// 10.0.0.10 dev kube-ipvs0 scope host src 10.0.0.10
// 10.0.0.252 dev kube-ipvs0 scope host src 10.0.0.252
// 100.106.89.164 dev eth0 scope host src 100.106.89.164
// 127.0.0.0/8 dev lo scope host src 127.0.0.1
// 127.0.0.1 dev lo scope host src 127.0.0.1
// 172.17.0.1 dev docker0 scope host src 172.17.0.1
// 192.168.122.1 dev virbr0 scope host src 192.168.122.1
// Then filter out dev==kube-ipvs0, and cut the unique src IP fields,
// Node IP set: [100.106.89.164, 127.0.0.1, 192.168.122.1]
func (r *realIPGetter) NodeIPs() (ips []net.IP, err error) {
// Pass in empty filter device name for list all LOCAL type addresses.
nodeAddress, err := r.nl.GetLocalAddresses("", DefaultDummyDevice)
if err != nil {
return nil, fmt.Errorf("error listing LOCAL type addresses from host, error: %v", err)
}
// translate ip string to IP
for _, ipStr := range nodeAddress.UnsortedList() {
ips = append(ips, net.ParseIP(ipStr))
}
return ips, nil
}
// Proxier implements ProxyProvider
var _ proxy.ProxyProvider = &Proxier{}
// NewProxier returns a new Proxier given an iptables and ipvs Interface instance.
// Because of the iptables and ipvs logic, it is assumed that there is only a single Proxier active on a machine.
// An error will be returned if it fails to update or acquire the initial lock.
// Once a proxier is created, it will keep iptables and ipvs rules up to date in the background and
// will not terminate if a particular iptables or ipvs call fails.
func NewProxier(ipt utiliptables.Interface,
ipvs utilipvs.Interface,
ipset utilipset.Interface,
sysctl utilsysctl.Interface,
exec utilexec.Interface,
syncPeriod time.Duration,
minSyncPeriod time.Duration,
excludeCIDRs []string,
strictARP bool,
masqueradeAll bool,
masqueradeBit int,
clusterCIDR string,
hostname string,
nodeIP net.IP,
recorder record.EventRecorder,
healthzServer healthcheck.HealthzUpdater,
scheduler string,
nodePortAddresses []string,
) (*Proxier, error) {
// Set the route_localnet sysctl we need for
if val, _ := sysctl.GetSysctl(sysctlRouteLocalnet); val != 1 {
if err := sysctl.SetSysctl(sysctlRouteLocalnet, 1); err != nil {
return nil, fmt.Errorf("can't set sysctl %s: %v", sysctlRouteLocalnet, err)
}
}
// Proxy needs br_netfilter and bridge-nf-call-iptables=1 when containers
// are connected to a Linux bridge (but not SDN bridges). Until most
// plugins handle this, log when config is missing
if val, err := sysctl.GetSysctl(sysctlBridgeCallIPTables); err == nil && val != 1 {
klog.Infof("missing br-netfilter module or unset sysctl br-nf-call-iptables; proxy may not work as intended")
}
// Set the conntrack sysctl we need for
if val, _ := sysctl.GetSysctl(sysctlVSConnTrack); val != 1 {
if err := sysctl.SetSysctl(sysctlVSConnTrack, 1); err != nil {
return nil, fmt.Errorf("can't set sysctl %s: %v", sysctlVSConnTrack, err)
}
}
// Set the connection reuse mode
if val, _ := sysctl.GetSysctl(sysctlConnReuse); val != 0 {
if err := sysctl.SetSysctl(sysctlConnReuse, 0); err != nil {
return nil, fmt.Errorf("can't set sysctl %s: %v", sysctlConnReuse, err)
}
}
// Set the expire_nodest_conn sysctl we need for
if val, _ := sysctl.GetSysctl(sysctlExpireNoDestConn); val != 1 {
if err := sysctl.SetSysctl(sysctlExpireNoDestConn, 1); err != nil {
return nil, fmt.Errorf("can't set sysctl %s: %v", sysctlExpireNoDestConn, err)
}
}
// Set the expire_quiescent_template sysctl we need for
if val, _ := sysctl.GetSysctl(sysctlExpireQuiescentTemplate); val != 1 {
if err := sysctl.SetSysctl(sysctlExpireQuiescentTemplate, 1); err != nil {
return nil, fmt.Errorf("can't set sysctl %s: %v", sysctlExpireQuiescentTemplate, err)
}
}
// Set the ip_forward sysctl we need for
if val, _ := sysctl.GetSysctl(sysctlForward); val != 1 {
if err := sysctl.SetSysctl(sysctlForward, 1); err != nil {
return nil, fmt.Errorf("can't set sysctl %s: %v", sysctlForward, err)
}
}
if strictARP {
// Set the arp_ignore sysctl we need for
if val, _ := sysctl.GetSysctl(sysctlArpIgnore); val != 1 {
if err := sysctl.SetSysctl(sysctlArpIgnore, 1); err != nil {
return nil, fmt.Errorf("can't set sysctl %s: %v", sysctlArpIgnore, err)
}
}
// Set the arp_announce sysctl we need for
if val, _ := sysctl.GetSysctl(sysctlArpAnnounce); val != 2 {
if err := sysctl.SetSysctl(sysctlArpAnnounce, 2); err != nil {
return nil, fmt.Errorf("can't set sysctl %s: %v", sysctlArpAnnounce, err)
}
}
}
// Generate the masquerade mark to use for SNAT rules.
masqueradeValue := 1 << uint(masqueradeBit)
masqueradeMark := fmt.Sprintf("%#08x/%#08x", masqueradeValue, masqueradeValue)
if nodeIP == nil {
klog.Warningf("invalid nodeIP, initializing kube-proxy with 127.0.0.1 as nodeIP")
nodeIP = net.ParseIP("127.0.0.1")
}
isIPv6 := utilnet.IsIPv6(nodeIP)
klog.V(2).Infof("nodeIP: %v, isIPv6: %v", nodeIP, isIPv6)
if len(clusterCIDR) == 0 {
klog.Warningf("clusterCIDR not specified, unable to distinguish between internal and external traffic")
} else if utilnet.IsIPv6CIDR(clusterCIDR) != isIPv6 {
return nil, fmt.Errorf("clusterCIDR %s has incorrect IP version: expect isIPv6=%t", clusterCIDR, isIPv6)
}
if len(scheduler) == 0 {
klog.Warningf("IPVS scheduler not specified, use %s by default", DefaultScheduler)
scheduler = DefaultScheduler
}
healthChecker := healthcheck.NewServer(hostname, recorder, nil, nil) // use default implementations of deps
proxier := &Proxier{
portsMap: make(map[utilproxy.LocalPort]utilproxy.Closeable),
serviceMap: make(proxy.ServiceMap),
serviceChanges: proxy.NewServiceChangeTracker(newServiceInfo, &isIPv6, recorder),
endpointsMap: make(proxy.EndpointsMap),
endpointsChanges: proxy.NewEndpointChangeTracker(hostname, nil, &isIPv6, recorder),
syncPeriod: syncPeriod,
minSyncPeriod: minSyncPeriod,
excludeCIDRs: excludeCIDRs,
iptables: ipt,
masqueradeAll: masqueradeAll,
masqueradeMark: masqueradeMark,
exec: exec,
clusterCIDR: clusterCIDR,
hostname: hostname,
nodeIP: nodeIP,
portMapper: &listenPortOpener{},
recorder: recorder,
healthChecker: healthChecker,
healthzServer: healthzServer,
ipvs: ipvs,
ipvsScheduler: scheduler,
ipGetter: &realIPGetter{nl: NewNetLinkHandle()},
iptablesData: bytes.NewBuffer(nil),
filterChainsData: bytes.NewBuffer(nil),
natChains: bytes.NewBuffer(nil),
natRules: bytes.NewBuffer(nil),
filterChains: bytes.NewBuffer(nil),
filterRules: bytes.NewBuffer(nil),
netlinkHandle: NewNetLinkHandle(),
ipset: ipset,
nodePortAddresses: nodePortAddresses,
networkInterfacer: utilproxy.RealNetwork{},
gracefuldeleteManager: NewGracefulTerminationManager(ipvs),
}
// initialize ipsetList with all sets we needed
proxier.ipsetList = make(map[string]*IPSet)
for _, is := range ipsetInfo {
proxier.ipsetList[is.name] = NewIPSet(ipset, is.name, is.setType, isIPv6, is.comment)
}
burstSyncs := 2
klog.V(3).Infof("minSyncPeriod: %v, syncPeriod: %v, burstSyncs: %d", minSyncPeriod, syncPeriod, burstSyncs)
proxier.syncRunner = async.NewBoundedFrequencyRunner("sync-runner", proxier.syncProxyRules, minSyncPeriod, syncPeriod, burstSyncs)
proxier.gracefuldeleteManager.Run()
return proxier, nil
}
// internal struct for string service information
type serviceInfo struct {
*proxy.BaseServiceInfo
// The following fields are computed and stored for performance reasons.
serviceNameString string
}
// returns a new proxy.ServicePort which abstracts a serviceInfo
func newServiceInfo(port *v1.ServicePort, service *v1.Service, baseInfo *proxy.BaseServiceInfo) proxy.ServicePort {
info := &serviceInfo{BaseServiceInfo: baseInfo}
// Store the following for performance reasons.
svcName := types.NamespacedName{Namespace: service.Namespace, Name: service.Name}
svcPortName := proxy.ServicePortName{NamespacedName: svcName, Port: port.Name}
info.serviceNameString = svcPortName.String()
return info
}
// KernelHandler can handle the current installed kernel modules.
type KernelHandler interface {
GetModules() ([]string, error)
}
// LinuxKernelHandler implements KernelHandler interface.
type LinuxKernelHandler struct {
executor utilexec.Interface
}
// NewLinuxKernelHandler initializes LinuxKernelHandler with exec.
func NewLinuxKernelHandler() *LinuxKernelHandler {
return &LinuxKernelHandler{
executor: utilexec.New(),
}
}
// GetModules returns all installed kernel modules.
func (handle *LinuxKernelHandler) GetModules() ([]string, error) {
// Check whether IPVS required kernel modules are built-in
kernelVersion, ipvsModules, err := utilipvs.GetKernelVersionAndIPVSMods(handle.executor)
if err != nil {
return nil, err
}
builtinModsFilePath := fmt.Sprintf("/lib/modules/%s/modules.builtin", kernelVersion)
b, err := ioutil.ReadFile(builtinModsFilePath)
if err != nil {
klog.Warningf("Failed to read file %s with error %v. You can ignore this message when kube-proxy is running inside container without mounting /lib/modules", builtinModsFilePath, err)
}
var bmods []string
for _, module := range ipvsModules {
if match, _ := regexp.Match(module+".ko", b); match {
bmods = append(bmods, module)
}
}
// Try to load IPVS required kernel modules using modprobe first
for _, kmod := range ipvsModules {
err := handle.executor.Command("modprobe", "--", kmod).Run()
if err != nil {
klog.Warningf("Failed to load kernel module %v with modprobe. "+
"You can ignore this message when kube-proxy is running inside container without mounting /lib/modules", kmod)
}
}
// Find out loaded kernel modules
out, err := handle.executor.Command("cut", "-f1", "-d", " ", "/proc/modules").CombinedOutput()
if err != nil {
return nil, err
}
mods := strings.Split(string(out), "\n")
return append(mods, bmods...), nil
}
// CanUseIPVSProxier returns true if we can use the ipvs Proxier.
// This is determined by checking if all the required kernel modules can be loaded. It may
// return an error if it fails to get the kernel modules information without error, in which
// case it will also return false.
func CanUseIPVSProxier(handle KernelHandler, ipsetver IPSetVersioner) (bool, error) {
mods, err := handle.GetModules()
if err != nil {
return false, fmt.Errorf("error getting installed ipvs required kernel modules: %v", err)
}
wantModules := sets.NewString()
loadModules := sets.NewString()
linuxKernelHandler := NewLinuxKernelHandler()
_, ipvsModules, _ := utilipvs.GetKernelVersionAndIPVSMods(linuxKernelHandler.executor)
wantModules.Insert(ipvsModules...)
loadModules.Insert(mods...)
modules := wantModules.Difference(loadModules).UnsortedList()
var missingMods []string
ConntrackiMissingCounter := 0
for _, mod := range modules {
if strings.Contains(mod, "nf_conntrack") {
ConntrackiMissingCounter++
} else {
missingMods = append(missingMods, mod)
}
}
if ConntrackiMissingCounter == 2 {
missingMods = append(missingMods, "nf_conntrack_ipv4(or nf_conntrack for Linux kernel 4.19 and later)")
}
if len(missingMods) != 0 {
return false, fmt.Errorf("IPVS proxier will not be used because the following required kernel modules are not loaded: %v", missingMods)
}
// Check ipset version
versionString, err := ipsetver.GetVersion()
if err != nil {
return false, fmt.Errorf("error getting ipset version, error: %v", err)
}
if !checkMinVersion(versionString) {
return false, fmt.Errorf("ipset version: %s is less than min required version: %s", versionString, MinIPSetCheckVersion)
}
return true, nil
}
// CleanupIptablesLeftovers removes all iptables rules and chains created by the Proxier
// It returns true if an error was encountered. Errors are logged.
func cleanupIptablesLeftovers(ipt utiliptables.Interface) (encounteredError bool) {
// Unlink the iptables chains created by ipvs Proxier
for _, jc := range iptablesJumpChain {
args := []string{
"-m", "comment", "--comment", jc.comment,
"-j", string(jc.to),
}
if err := ipt.DeleteRule(jc.table, jc.from, args...); err != nil {
if !utiliptables.IsNotFoundError(err) {
klog.Errorf("Error removing iptables rules in ipvs proxier: %v", err)
encounteredError = true
}
}
}
// Flush and remove all of our chains. Flushing all chains before removing them also removes all links between chains first.
for _, ch := range iptablesChains {
if err := ipt.FlushChain(ch.table, ch.chain); err != nil {
if !utiliptables.IsNotFoundError(err) {
klog.Errorf("Error removing iptables rules in ipvs proxier: %v", err)
encounteredError = true
}
}
}
// Remove all of our chains.
for _, ch := range iptablesChains {
if err := ipt.DeleteChain(ch.table, ch.chain); err != nil {
if !utiliptables.IsNotFoundError(err) {
klog.Errorf("Error removing iptables rules in ipvs proxier: %v", err)
encounteredError = true
}
}
}
return encounteredError
}
// CleanupLeftovers clean up all ipvs and iptables rules created by ipvs Proxier.
func CleanupLeftovers(ipvs utilipvs.Interface, ipt utiliptables.Interface, ipset utilipset.Interface, cleanupIPVS bool) (encounteredError bool) {
if cleanupIPVS {
// Return immediately when ipvs interface is nil - Probably initialization failed in somewhere.
if ipvs == nil {
return true
}
encounteredError = false
err := ipvs.Flush()
if err != nil {
klog.Errorf("Error flushing IPVS rules: %v", err)
encounteredError = true
}
}
// Delete dummy interface created by ipvs Proxier.
nl := NewNetLinkHandle()
err := nl.DeleteDummyDevice(DefaultDummyDevice)
if err != nil {
klog.Errorf("Error deleting dummy device %s created by IPVS proxier: %v", DefaultDummyDevice, err)
encounteredError = true
}
// Clear iptables created by ipvs Proxier.
encounteredError = cleanupIptablesLeftovers(ipt) || encounteredError
// Destroy ip sets created by ipvs Proxier. We should call it after cleaning up
// iptables since we can NOT delete ip set which is still referenced by iptables.
for _, set := range ipsetInfo {
err = ipset.DestroySet(set.name)
if err != nil {
if !utilipset.IsNotFoundError(err) {
klog.Errorf("Error removing ipset %s, error: %v", set.name, err)
encounteredError = true
}
}
}
return encounteredError
}
// Sync is called to synchronize the proxier state to iptables and ipvs as soon as possible.
func (proxier *Proxier) Sync() {
proxier.syncRunner.Run()
}
// SyncLoop runs periodic work. This is expected to run as a goroutine or as the main loop of the app. It does not return.
func (proxier *Proxier) SyncLoop() {
// Update healthz timestamp at beginning in case Sync() never succeeds.
if proxier.healthzServer != nil {
proxier.healthzServer.UpdateTimestamp()
}
proxier.syncRunner.Loop(wait.NeverStop)
}
func (proxier *Proxier) setInitialized(value bool) {
var initialized int32
if value {
initialized = 1
}
atomic.StoreInt32(&proxier.initialized, initialized)
}
func (proxier *Proxier) isInitialized() bool {
return atomic.LoadInt32(&proxier.initialized) > 0
}
// OnServiceAdd is called whenever creation of new service object is observed.
func (proxier *Proxier) OnServiceAdd(service *v1.Service) {
proxier.OnServiceUpdate(nil, service)
}
// OnServiceUpdate is called whenever modification of an existing service object is observed.
func (proxier *Proxier) OnServiceUpdate(oldService, service *v1.Service) {
if proxier.serviceChanges.Update(oldService, service) && proxier.isInitialized() {
proxier.syncRunner.Run()
}
}
// OnServiceDelete is called whenever deletion of an existing service object is observed.
func (proxier *Proxier) OnServiceDelete(service *v1.Service) {
proxier.OnServiceUpdate(service, nil)
}
// OnServiceSynced is called once all the initial even handlers were called and the state is fully propagated to local cache.
func (proxier *Proxier) OnServiceSynced() {
proxier.mu.Lock()
proxier.servicesSynced = true
proxier.setInitialized(proxier.servicesSynced && proxier.endpointsSynced)
proxier.mu.Unlock()
// Sync unconditionally - this is called once per lifetime.
proxier.syncProxyRules()
}
// OnEndpointsAdd is called whenever creation of new endpoints object is observed.
func (proxier *Proxier) OnEndpointsAdd(endpoints *v1.Endpoints) {
proxier.OnEndpointsUpdate(nil, endpoints)
}
// OnEndpointsUpdate is called whenever modification of an existing endpoints object is observed.
func (proxier *Proxier) OnEndpointsUpdate(oldEndpoints, endpoints *v1.Endpoints) {
if proxier.endpointsChanges.Update(oldEndpoints, endpoints) && proxier.isInitialized() {
proxier.syncRunner.Run()
}
}
// OnEndpointsDelete is called whenever deletion of an existing endpoints object is observed.
func (proxier *Proxier) OnEndpointsDelete(endpoints *v1.Endpoints) {
proxier.OnEndpointsUpdate(endpoints, nil)
}
// OnEndpointsSynced is called once all the initial event handlers were called and the state is fully propagated to local cache.
func (proxier *Proxier) OnEndpointsSynced() {
proxier.mu.Lock()
proxier.endpointsSynced = true
proxier.setInitialized(proxier.servicesSynced && proxier.endpointsSynced)
proxier.mu.Unlock()
// Sync unconditionally - this is called once per lifetime.
proxier.syncProxyRules()
}
// EntryInvalidErr indicates if an ipset entry is invalid or not
const EntryInvalidErr = "error adding entry %s to ipset %s"
// This is where all of the ipvs calls happen.
// assumes proxier.mu is held
func (proxier *Proxier) syncProxyRules() {
proxier.mu.Lock()
defer proxier.mu.Unlock()
start := time.Now()
defer func() {
metrics.SyncProxyRulesLatency.Observe(metrics.SinceInMicroseconds(start))
klog.V(4).Infof("syncProxyRules took %v", time.Since(start))
}()
// don't sync rules till we've received services and endpoints
if !proxier.endpointsSynced || !proxier.servicesSynced {
klog.V(2).Info("Not syncing ipvs rules until Services and Endpoints have been received from master")
return
}
// We assume that if this was called, we really want to sync them,
// even if nothing changed in the meantime. In other words, callers are
// responsible for detecting no-op changes and not calling this function.
serviceUpdateResult := proxy.UpdateServiceMap(proxier.serviceMap, proxier.serviceChanges)
endpointUpdateResult := proxy.UpdateEndpointsMap(proxier.endpointsMap, proxier.endpointsChanges)
staleServices := serviceUpdateResult.UDPStaleClusterIP
// merge stale services gathered from updateEndpointsMap
for _, svcPortName := range endpointUpdateResult.StaleServiceNames {
if svcInfo, ok := proxier.serviceMap[svcPortName]; ok && svcInfo != nil && svcInfo.GetProtocol() == v1.ProtocolUDP {
klog.V(2).Infof("Stale udp service %v -> %s", svcPortName, svcInfo.ClusterIPString())
staleServices.Insert(svcInfo.ClusterIPString())
}
}
klog.V(3).Infof("Syncing ipvs Proxier rules")
// Begin install iptables
// Reset all buffers used later.
// This is to avoid memory reallocations and thus improve performance.
proxier.natChains.Reset()
proxier.natRules.Reset()
proxier.filterChains.Reset()
proxier.filterRules.Reset()
// Write table headers.
writeLine(proxier.filterChains, "*filter")
writeLine(proxier.natChains, "*nat")
proxier.createAndLinkeKubeChain()
// make sure dummy interface exists in the system where ipvs Proxier will bind service address on it
_, err := proxier.netlinkHandle.EnsureDummyDevice(DefaultDummyDevice)
if err != nil {
klog.Errorf("Failed to create dummy interface: %s, error: %v", DefaultDummyDevice, err)
return
}
// make sure ip sets exists in the system.
for _, set := range proxier.ipsetList {
if err := ensureIPSet(set); err != nil {
return
}
set.resetEntries()
}
// Accumulate the set of local ports that we will be holding open once this update is complete
replacementPortsMap := map[utilproxy.LocalPort]utilproxy.Closeable{}
// activeIPVSServices represents IPVS service successfully created in this round of sync
activeIPVSServices := map[string]bool{}
// currentIPVSServices represent IPVS services listed from the system
currentIPVSServices := make(map[string]*utilipvs.VirtualServer)
// activeBindAddrs represents ip address successfully bind to DefaultDummyDevice in this round of sync
activeBindAddrs := map[string]bool{}
// Build IPVS rules for each service.
for svcName, svc := range proxier.serviceMap {
svcInfo, ok := svc.(*serviceInfo)
if !ok {
klog.Errorf("Failed to cast serviceInfo %q", svcName.String())
continue
}
protocol := strings.ToLower(string(svcInfo.Protocol))
// Precompute svcNameString; with many services the many calls
// to ServicePortName.String() show up in CPU profiles.
svcNameString := svcName.String()
// Handle traffic that loops back to the originator with SNAT.
for _, e := range proxier.endpointsMap[svcName] {
ep, ok := e.(*proxy.BaseEndpointInfo)
if !ok {
klog.Errorf("Failed to cast BaseEndpointInfo %q", e.String())
continue
}
if !ep.IsLocal {
continue
}
epIP := ep.IP()
epPort, err := ep.Port()
// Error parsing this endpoint has been logged. Skip to next endpoint.
if epIP == "" || err != nil {
continue
}
entry := &utilipset.Entry{
IP: epIP,
Port: epPort,
Protocol: protocol,
IP2: epIP,
SetType: utilipset.HashIPPortIP,
}
if valid := proxier.ipsetList[kubeLoopBackIPSet].validateEntry(entry); !valid {
klog.Errorf("%s", fmt.Sprintf(EntryInvalidErr, entry, proxier.ipsetList[kubeLoopBackIPSet].Name))
continue
}
proxier.ipsetList[kubeLoopBackIPSet].activeEntries.Insert(entry.String())
}
// Capture the clusterIP.
// ipset call
entry := &utilipset.Entry{
IP: svcInfo.ClusterIP.String(),
Port: svcInfo.Port,
Protocol: protocol,
SetType: utilipset.HashIPPort,
}
// add service Cluster IP:Port to kubeServiceAccess ip set for the purpose of solving hairpin.
// proxier.kubeServiceAccessSet.activeEntries.Insert(entry.String())
if valid := proxier.ipsetList[kubeClusterIPSet].validateEntry(entry); !valid {
klog.Errorf("%s", fmt.Sprintf(EntryInvalidErr, entry, proxier.ipsetList[kubeClusterIPSet].Name))
continue
}
proxier.ipsetList[kubeClusterIPSet].activeEntries.Insert(entry.String())
// ipvs call
serv := &utilipvs.VirtualServer{
Address: svcInfo.ClusterIP,
Port: uint16(svcInfo.Port),
Protocol: string(svcInfo.Protocol),
Scheduler: proxier.ipvsScheduler,
}
// Set session affinity flag and timeout for IPVS service
if svcInfo.SessionAffinityType == v1.ServiceAffinityClientIP {
serv.Flags |= utilipvs.FlagPersistent
serv.Timeout = uint32(svcInfo.StickyMaxAgeSeconds)
}
// We need to bind ClusterIP to dummy interface, so set `bindAddr` parameter to `true` in syncService()
if err := proxier.syncService(svcNameString, serv, true); err == nil {
activeIPVSServices[serv.String()] = true
activeBindAddrs[serv.Address.String()] = true
// ExternalTrafficPolicy only works for NodePort and external LB traffic, does not affect ClusterIP
// So we still need clusterIP rules in onlyNodeLocalEndpoints mode.
if err := proxier.syncEndpoint(svcName, false, serv); err != nil {
klog.Errorf("Failed to sync endpoint for service: %v, err: %v", serv, err)
}
} else {
klog.Errorf("Failed to sync service: %v, err: %v", serv, err)
}
// Capture externalIPs.
for _, externalIP := range svcInfo.ExternalIPs {
if local, err := utilproxy.IsLocalIP(externalIP); err != nil {
klog.Errorf("can't determine if IP is local, assuming not: %v", err)
// We do not start listening on SCTP ports, according to our agreement in the
// SCTP support KEP
} else if local && (svcInfo.GetProtocol() != v1.ProtocolSCTP) {
lp := utilproxy.LocalPort{
Description: "externalIP for " + svcNameString,
IP: externalIP,
Port: svcInfo.Port,
Protocol: protocol,
}
if proxier.portsMap[lp] != nil {
klog.V(4).Infof("Port %s was open before and is still needed", lp.String())
replacementPortsMap[lp] = proxier.portsMap[lp]
} else {
socket, err := proxier.portMapper.OpenLocalPort(&lp)
if err != nil {
msg := fmt.Sprintf("can't open %s, skipping this externalIP: %v", lp.String(), err)
proxier.recorder.Eventf(
&v1.ObjectReference{
Kind: "Node",
Name: proxier.hostname,
UID: types.UID(proxier.hostname),
Namespace: "",
}, v1.EventTypeWarning, err.Error(), msg)
klog.Error(msg)
continue
}
replacementPortsMap[lp] = socket
}
} // We're holding the port, so it's OK to install IPVS rules.
// ipset call
entry := &utilipset.Entry{
IP: externalIP,
Port: svcInfo.Port,
Protocol: protocol,
SetType: utilipset.HashIPPort,
}
// We have to SNAT packets to external IPs.
if valid := proxier.ipsetList[kubeExternalIPSet].validateEntry(entry); !valid {
klog.Errorf("%s", fmt.Sprintf(EntryInvalidErr, entry, proxier.ipsetList[kubeExternalIPSet].Name))
continue
}
proxier.ipsetList[kubeExternalIPSet].activeEntries.Insert(entry.String())
// ipvs call
serv := &utilipvs.VirtualServer{
Address: net.ParseIP(externalIP),
Port: uint16(svcInfo.Port),
Protocol: string(svcInfo.Protocol),
Scheduler: proxier.ipvsScheduler,
}
if svcInfo.SessionAffinityType == v1.ServiceAffinityClientIP {
serv.Flags |= utilipvs.FlagPersistent
serv.Timeout = uint32(svcInfo.StickyMaxAgeSeconds)
}
if err := proxier.syncService(svcNameString, serv, true); err == nil {
activeIPVSServices[serv.String()] = true
activeBindAddrs[serv.Address.String()] = true
if err := proxier.syncEndpoint(svcName, false, serv); err != nil {
klog.Errorf("Failed to sync endpoint for service: %v, err: %v", serv, err)
}
} else {
klog.Errorf("Failed to sync service: %v, err: %v", serv, err)
}
}
// Capture load-balancer ingress.
for _, ingress := range svcInfo.LoadBalancerStatus.Ingress {
if ingress.IP != "" {
// ipset call
entry = &utilipset.Entry{
IP: ingress.IP,
Port: svcInfo.Port,
Protocol: protocol,
SetType: utilipset.HashIPPort,
}
// add service load balancer ingressIP:Port to kubeServiceAccess ip set for the purpose of solving hairpin.
// proxier.kubeServiceAccessSet.activeEntries.Insert(entry.String())
// If we are proxying globally, we need to masquerade in case we cross nodes.
// If we are proxying only locally, we can retain the source IP.
if valid := proxier.ipsetList[kubeLoadBalancerSet].validateEntry(entry); !valid {
klog.Errorf("%s", fmt.Sprintf(EntryInvalidErr, entry, proxier.ipsetList[kubeLoadBalancerSet].Name))
continue
}
proxier.ipsetList[kubeLoadBalancerSet].activeEntries.Insert(entry.String())
// insert loadbalancer entry to lbIngressLocalSet if service externaltrafficpolicy=local
if svcInfo.OnlyNodeLocalEndpoints {
if valid := proxier.ipsetList[kubeLoadBalancerLocalSet].validateEntry(entry); !valid {
klog.Errorf("%s", fmt.Sprintf(EntryInvalidErr, entry, proxier.ipsetList[kubeLoadBalancerLocalSet].Name))
continue
}
proxier.ipsetList[kubeLoadBalancerLocalSet].activeEntries.Insert(entry.String())
}
if len(svcInfo.LoadBalancerSourceRanges) != 0 {
// The service firewall rules are created based on ServiceSpec.loadBalancerSourceRanges field.
// This currently works for loadbalancers that preserves source ips.
// For loadbalancers which direct traffic to service NodePort, the firewall rules will not apply.
if valid := proxier.ipsetList[kubeLoadbalancerFWSet].validateEntry(entry); !valid {
klog.Errorf("%s", fmt.Sprintf(EntryInvalidErr, entry, proxier.ipsetList[kubeLoadbalancerFWSet].Name))
continue
}
proxier.ipsetList[kubeLoadbalancerFWSet].activeEntries.Insert(entry.String())
allowFromNode := false
for _, src := range svcInfo.LoadBalancerSourceRanges {
// ipset call
entry = &utilipset.Entry{
IP: ingress.IP,
Port: svcInfo.Port,
Protocol: protocol,
Net: src,
SetType: utilipset.HashIPPortNet,
}
// enumerate all white list source cidr
if valid := proxier.ipsetList[kubeLoadBalancerSourceCIDRSet].validateEntry(entry); !valid {
klog.Errorf("%s", fmt.Sprintf(EntryInvalidErr, entry, proxier.ipsetList[kubeLoadBalancerSourceCIDRSet].Name))
continue
}
proxier.ipsetList[kubeLoadBalancerSourceCIDRSet].activeEntries.Insert(entry.String())
// ignore error because it has been validated
_, cidr, _ := net.ParseCIDR(src)
if cidr.Contains(proxier.nodeIP) {