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proxier.go
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proxier.go
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/*
Copyright 2015 The Kubernetes Authors All rights reserved.
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 iptables
//
// NOTE: this needs to be tested in e2e since it uses iptables for everything.
//
import (
"bytes"
"crypto/sha256"
"encoding/base32"
"fmt"
"net"
"os"
"reflect"
"strconv"
"strings"
"sync"
"time"
"github.com/coreos/go-semver/semver"
"github.com/davecgh/go-spew/spew"
"github.com/golang/glog"
"k8s.io/kubernetes/pkg/api"
"k8s.io/kubernetes/pkg/proxy"
"k8s.io/kubernetes/pkg/types"
utilexec "k8s.io/kubernetes/pkg/util/exec"
utiliptables "k8s.io/kubernetes/pkg/util/iptables"
"k8s.io/kubernetes/pkg/util/sets"
"k8s.io/kubernetes/pkg/util/slice"
utilsysctl "k8s.io/kubernetes/pkg/util/sysctl"
)
const (
// iptablesMinVersion is the minimum version of iptables for which we will use the Proxier
// from this package instead of the userspace Proxier. While most of the
// features we need were available earlier, the '-C' flag was added more
// recently. We use that indirectly in Ensure* functions, and if we don't
// have it, we have to be extra careful about the exact args we feed in being
// the same as the args we read back (iptables itself normalizes some args).
// This is the "new" Proxier, so we require "new" versions of tools.
iptablesMinVersion = utiliptables.MinCheckVersion
// the services chain
kubeServicesChain utiliptables.Chain = "KUBE-SERVICES"
// the nodeports chain
kubeNodePortsChain utiliptables.Chain = "KUBE-NODEPORTS"
// the kubernetes postrouting chain
kubePostroutingChain utiliptables.Chain = "KUBE-POSTROUTING"
// the mark-for-masquerade chain
KubeMarkMasqChain utiliptables.Chain = "KUBE-MARK-MASQ"
// the mark we apply to traffic needing SNAT
// TODO(thockin): Remove this for v1.3 or v1.4.
oldIptablesMasqueradeMark = "0x4d415351"
// the mark-for-drop chain
KubeMarkDropChain utiliptables.Chain = "KUBE-MARK-DROP"
)
// IptablesVersioner can query the current iptables version.
type IptablesVersioner interface {
// returns "X.Y.Z"
GetVersion() (string, error)
}
// KernelCompatTester tests whether the required kernel capabilities are
// present to run the iptables proxier.
type KernelCompatTester interface {
IsCompatible() error
}
// CanUseIptablesProxier returns true if we should use the iptables Proxier
// instead of the "classic" userspace Proxier. This is determined by checking
// the iptables version and for the existence of kernel features. It may return
// an error if it fails to get the iptables version without error, in which
// case it will also return false.
func CanUseIptablesProxier(iptver IptablesVersioner, kcompat KernelCompatTester) (bool, error) {
minVersion, err := semver.NewVersion(iptablesMinVersion)
if err != nil {
return false, err
}
// returns "X.Y.Z"
versionString, err := iptver.GetVersion()
if err != nil {
return false, err
}
version, err := semver.NewVersion(versionString)
if err != nil {
return false, err
}
if version.LessThan(*minVersion) {
return false, nil
}
// Check that the kernel supports what we need.
if err := kcompat.IsCompatible(); err != nil {
return false, err
}
return true, nil
}
type LinuxKernelCompatTester struct{}
func (lkct LinuxKernelCompatTester) IsCompatible() error {
// Check for the required sysctls. We don't care about the value, just
// that it exists. If this Proxier is chosen, we'll initialize it as we
// need.
_, err := utilsysctl.GetSysctl(sysctlRouteLocalnet)
return err
}
const sysctlRouteLocalnet = "net/ipv4/conf/all/route_localnet"
const sysctlBridgeCallIptables = "net/bridge/bridge-nf-call-iptables"
// internal struct for string service information
type serviceInfo struct {
clusterIP net.IP
port int
protocol api.Protocol
nodePort int
loadBalancerStatus api.LoadBalancerStatus
sessionAffinityType api.ServiceAffinity
stickyMaxAgeSeconds int
externalIPs []string
loadBalancerSourceRanges []string
}
// returns a new serviceInfo struct
func newServiceInfo(service proxy.ServicePortName) *serviceInfo {
return &serviceInfo{
sessionAffinityType: api.ServiceAffinityNone, // default
stickyMaxAgeSeconds: 180, // TODO: paramaterize this in the API.
}
}
// Proxier is an iptables based proxy for connections between a localhost:lport
// and services that provide the actual backends.
type Proxier struct {
mu sync.Mutex // protects the following fields
serviceMap map[proxy.ServicePortName]*serviceInfo
endpointsMap map[proxy.ServicePortName][]string
portsMap map[localPort]closeable
haveReceivedServiceUpdate bool // true once we've seen an OnServiceUpdate event
haveReceivedEndpointsUpdate bool // true once we've seen an OnEndpointsUpdate event
// These are effectively const and do not need the mutex to be held.
syncPeriod time.Duration
iptables utiliptables.Interface
masqueradeAll bool
masqueradeMark string
exec utilexec.Interface
clusterCIDR string
hostname string
nodeIP net.IP
}
type localPort struct {
desc string
ip string
port int
protocol string
}
func (lp *localPort) String() string {
return fmt.Sprintf("%q (%s:%d/%s)", lp.desc, lp.ip, lp.port, lp.protocol)
}
type closeable interface {
Close() error
}
// Proxier implements ProxyProvider
var _ proxy.ProxyProvider = &Proxier{}
// NewProxier returns a new Proxier given an iptables Interface instance.
// Because of the iptables logic, it is assumed that there is only a single Proxier active on a machine.
// An error will be returned if iptables fails to update or acquire the initial lock.
// Once a proxier is created, it will keep iptables up to date in the background and
// will not terminate if a particular iptables call fails.
func NewProxier(ipt utiliptables.Interface, exec utilexec.Interface, syncPeriod time.Duration, masqueradeAll bool, masqueradeBit int, clusterCIDR string, hostname string, nodeIP net.IP) (*Proxier, error) {
// Set the route_localnet sysctl we need for
if err := utilsysctl.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
warnBrNetfilter := false
if _, err := os.Stat("/sys/module/br_netfilter"); os.IsNotExist(err) {
warnBrNetfilter = true
}
if val, err := utilsysctl.GetSysctl(sysctlBridgeCallIptables); err == nil && val != 1 {
warnBrNetfilter = true
}
if warnBrNetfilter {
glog.Infof("missing br-netfilter module or unset br-nf-call-iptables; proxy may not work as intended")
}
// Generate the masquerade mark to use for SNAT rules.
if masqueradeBit < 0 || masqueradeBit > 31 {
return nil, fmt.Errorf("invalid iptables-masquerade-bit %v not in [0, 31]", masqueradeBit)
}
masqueradeValue := 1 << uint(masqueradeBit)
masqueradeMark := fmt.Sprintf("%#08x/%#08x", masqueradeValue, masqueradeValue)
if nodeIP == nil {
glog.Warningf("invalid nodeIP, initialize kube-proxy with 127.0.0.1 as nodeIP")
nodeIP = net.ParseIP("127.0.0.1")
}
return &Proxier{
serviceMap: make(map[proxy.ServicePortName]*serviceInfo),
endpointsMap: make(map[proxy.ServicePortName][]string),
portsMap: make(map[localPort]closeable),
syncPeriod: syncPeriod,
iptables: ipt,
masqueradeAll: masqueradeAll,
masqueradeMark: masqueradeMark,
exec: exec,
clusterCIDR: clusterCIDR,
hostname: hostname,
nodeIP: nodeIP,
}, nil
}
// CleanupLeftovers removes all iptables rules and chains created by the Proxier
// It returns true if an error was encountered. Errors are logged.
func CleanupLeftovers(ipt utiliptables.Interface) (encounteredError bool) {
// Unlink the services chain.
args := []string{
"-m", "comment", "--comment", "kubernetes service portals",
"-j", string(kubeServicesChain),
}
tableChainsWithJumpServices := []struct {
table utiliptables.Table
chain utiliptables.Chain
}{
{utiliptables.TableFilter, utiliptables.ChainOutput},
{utiliptables.TableNAT, utiliptables.ChainOutput},
{utiliptables.TableNAT, utiliptables.ChainPrerouting},
}
for _, tc := range tableChainsWithJumpServices {
if err := ipt.DeleteRule(tc.table, tc.chain, args...); err != nil {
if !utiliptables.IsNotFoundError(err) {
glog.Errorf("Error removing pure-iptables proxy rule: %v", err)
encounteredError = true
}
}
}
// Unlink the postrouting chain.
args = []string{
"-m", "comment", "--comment", "kubernetes postrouting rules",
"-j", string(kubePostroutingChain),
}
if err := ipt.DeleteRule(utiliptables.TableNAT, utiliptables.ChainPostrouting, args...); err != nil {
if !utiliptables.IsNotFoundError(err) {
glog.Errorf("Error removing pure-iptables proxy rule: %v", err)
encounteredError = true
}
}
// Flush and remove all of our chains.
if iptablesSaveRaw, err := ipt.Save(utiliptables.TableNAT); err != nil {
glog.Errorf("Failed to execute iptables-save for %s: %v", utiliptables.TableNAT, err)
encounteredError = true
} else {
existingNATChains := utiliptables.GetChainLines(utiliptables.TableNAT, iptablesSaveRaw)
natChains := bytes.NewBuffer(nil)
natRules := bytes.NewBuffer(nil)
writeLine(natChains, "*nat")
// Start with chains we know we need to remove.
for _, chain := range []utiliptables.Chain{kubeServicesChain, kubeNodePortsChain, kubePostroutingChain, KubeMarkMasqChain} {
if _, found := existingNATChains[chain]; found {
chainString := string(chain)
writeLine(natChains, existingNATChains[chain]) // flush
writeLine(natRules, "-X", chainString) // delete
}
}
// Hunt for service and endpoint chains.
for chain := range existingNATChains {
chainString := string(chain)
if strings.HasPrefix(chainString, "KUBE-SVC-") || strings.HasPrefix(chainString, "KUBE-SEP-") || strings.HasPrefix(chainString, "KUBE-FW-") {
writeLine(natChains, existingNATChains[chain]) // flush
writeLine(natRules, "-X", chainString) // delete
}
}
writeLine(natRules, "COMMIT")
natLines := append(natChains.Bytes(), natRules.Bytes()...)
// Write it.
err = ipt.Restore(utiliptables.TableNAT, natLines, utiliptables.NoFlushTables, utiliptables.RestoreCounters)
if err != nil {
glog.Errorf("Failed to execute iptables-restore for %s: %v", utiliptables.TableNAT, err)
encounteredError = true
}
}
{
filterBuf := bytes.NewBuffer(nil)
writeLine(filterBuf, "*filter")
writeLine(filterBuf, fmt.Sprintf(":%s - [0:0]", kubeServicesChain))
writeLine(filterBuf, fmt.Sprintf("-X %s", kubeServicesChain))
writeLine(filterBuf, "COMMIT")
// Write it.
if err := ipt.Restore(utiliptables.TableFilter, filterBuf.Bytes(), utiliptables.NoFlushTables, utiliptables.RestoreCounters); err != nil {
glog.Errorf("Failed to execute iptables-restore for %s: %v", utiliptables.TableFilter, err)
encounteredError = true
}
}
// Clean up the older SNAT rule which was directly in POSTROUTING.
// TODO(thockin): Remove this for v1.3 or v1.4.
args = []string{
"-m", "comment", "--comment", "kubernetes service traffic requiring SNAT",
"-m", "mark", "--mark", oldIptablesMasqueradeMark,
"-j", "MASQUERADE",
}
if err := ipt.DeleteRule(utiliptables.TableNAT, utiliptables.ChainPostrouting, args...); err != nil {
if !utiliptables.IsNotFoundError(err) {
glog.Errorf("Error removing old-style SNAT rule: %v", err)
encounteredError = true
}
}
return encounteredError
}
func (proxier *Proxier) sameConfig(info *serviceInfo, service *api.Service, port *api.ServicePort) bool {
if info.protocol != port.Protocol || info.port != int(port.Port) || info.nodePort != int(port.NodePort) {
return false
}
if !info.clusterIP.Equal(net.ParseIP(service.Spec.ClusterIP)) {
return false
}
if !ipsEqual(info.externalIPs, service.Spec.ExternalIPs) {
return false
}
if !api.LoadBalancerStatusEqual(&info.loadBalancerStatus, &service.Status.LoadBalancer) {
return false
}
if info.sessionAffinityType != service.Spec.SessionAffinity {
return false
}
return true
}
func ipsEqual(lhs, rhs []string) bool {
if len(lhs) != len(rhs) {
return false
}
for i := range lhs {
if lhs[i] != rhs[i] {
return false
}
}
return true
}
// Sync is called to immediately synchronize the proxier state to iptables
func (proxier *Proxier) Sync() {
proxier.mu.Lock()
defer proxier.mu.Unlock()
proxier.syncProxyRules()
}
// 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() {
t := time.NewTicker(proxier.syncPeriod)
defer t.Stop()
for {
<-t.C
glog.V(6).Infof("Periodic sync")
proxier.Sync()
}
}
// OnServiceUpdate tracks the active set of service proxies.
// They will be synchronized using syncProxyRules()
func (proxier *Proxier) OnServiceUpdate(allServices []api.Service) {
start := time.Now()
defer func() {
glog.V(4).Infof("OnServiceUpdate took %v for %d services", time.Since(start), len(allServices))
}()
proxier.mu.Lock()
defer proxier.mu.Unlock()
proxier.haveReceivedServiceUpdate = true
activeServices := make(map[proxy.ServicePortName]bool) // use a map as a set
for i := range allServices {
service := &allServices[i]
svcName := types.NamespacedName{
Namespace: service.Namespace,
Name: service.Name,
}
// if ClusterIP is "None" or empty, skip proxying
if !api.IsServiceIPSet(service) {
glog.V(3).Infof("Skipping service %s due to clusterIP = %q", svcName, service.Spec.ClusterIP)
continue
}
for i := range service.Spec.Ports {
servicePort := &service.Spec.Ports[i]
serviceName := proxy.ServicePortName{
NamespacedName: svcName,
Port: servicePort.Name,
}
activeServices[serviceName] = true
info, exists := proxier.serviceMap[serviceName]
if exists && proxier.sameConfig(info, service, servicePort) {
// Nothing changed.
continue
}
if exists {
// Something changed.
glog.V(3).Infof("Something changed for service %q: removing it", serviceName)
delete(proxier.serviceMap, serviceName)
}
serviceIP := net.ParseIP(service.Spec.ClusterIP)
glog.V(1).Infof("Adding new service %q at %s:%d/%s", serviceName, serviceIP, servicePort.Port, servicePort.Protocol)
info = newServiceInfo(serviceName)
info.clusterIP = serviceIP
info.port = int(servicePort.Port)
info.protocol = servicePort.Protocol
info.nodePort = int(servicePort.NodePort)
info.externalIPs = service.Spec.ExternalIPs
// Deep-copy in case the service instance changes
info.loadBalancerStatus = *api.LoadBalancerStatusDeepCopy(&service.Status.LoadBalancer)
info.sessionAffinityType = service.Spec.SessionAffinity
info.loadBalancerSourceRanges = service.Spec.LoadBalancerSourceRanges
proxier.serviceMap[serviceName] = info
glog.V(4).Infof("added serviceInfo(%s): %s", serviceName, spew.Sdump(info))
}
}
staleUDPServices := sets.NewString()
// Remove services missing from the update.
for name := range proxier.serviceMap {
if !activeServices[name] {
glog.V(1).Infof("Removing service %q", name)
if proxier.serviceMap[name].protocol == api.ProtocolUDP {
staleUDPServices.Insert(proxier.serviceMap[name].clusterIP.String())
}
delete(proxier.serviceMap, name)
}
}
proxier.syncProxyRules()
proxier.deleteServiceConnections(staleUDPServices.List())
}
// OnEndpointsUpdate takes in a slice of updated endpoints.
func (proxier *Proxier) OnEndpointsUpdate(allEndpoints []api.Endpoints) {
start := time.Now()
defer func() {
glog.V(4).Infof("OnEndpointsUpdate took %v for %d endpoints", time.Since(start), len(allEndpoints))
}()
proxier.mu.Lock()
defer proxier.mu.Unlock()
proxier.haveReceivedEndpointsUpdate = true
activeEndpoints := make(map[proxy.ServicePortName]bool) // use a map as a set
staleConnections := make(map[endpointServicePair]bool)
// Update endpoints for services.
for i := range allEndpoints {
svcEndpoints := &allEndpoints[i]
// We need to build a map of portname -> all ip:ports for that
// portname. Explode Endpoints.Subsets[*] into this structure.
portsToEndpoints := map[string][]hostPortPair{}
for i := range svcEndpoints.Subsets {
ss := &svcEndpoints.Subsets[i]
for i := range ss.Ports {
port := &ss.Ports[i]
for i := range ss.Addresses {
addr := &ss.Addresses[i]
portsToEndpoints[port.Name] = append(portsToEndpoints[port.Name], hostPortPair{addr.IP, int(port.Port)})
}
}
}
for portname := range portsToEndpoints {
svcPort := proxy.ServicePortName{NamespacedName: types.NamespacedName{Namespace: svcEndpoints.Namespace, Name: svcEndpoints.Name}, Port: portname}
curEndpoints := proxier.endpointsMap[svcPort]
newEndpoints := flattenValidEndpoints(portsToEndpoints[portname])
if len(curEndpoints) != len(newEndpoints) || !slicesEquiv(slice.CopyStrings(curEndpoints), newEndpoints) {
removedEndpoints := getRemovedEndpoints(curEndpoints, newEndpoints)
for _, ep := range removedEndpoints {
staleConnections[endpointServicePair{endpoint: ep, servicePortName: svcPort}] = true
}
glog.V(1).Infof("Setting endpoints for %q to %+v", svcPort, newEndpoints)
proxier.endpointsMap[svcPort] = newEndpoints
}
activeEndpoints[svcPort] = true
}
}
// Remove endpoints missing from the update.
for name := range proxier.endpointsMap {
if !activeEndpoints[name] {
// record endpoints of unactive service to stale connections
for _, ep := range proxier.endpointsMap[name] {
staleConnections[endpointServicePair{endpoint: ep, servicePortName: name}] = true
}
glog.V(2).Infof("Removing endpoints for %q", name)
delete(proxier.endpointsMap, name)
}
}
proxier.syncProxyRules()
proxier.deleteEndpointConnections(staleConnections)
}
// used in OnEndpointsUpdate
type hostPortPair struct {
host string
port int
}
func isValidEndpoint(hpp *hostPortPair) bool {
return hpp.host != "" && hpp.port > 0
}
// Tests whether two slices are equivalent. This sorts both slices in-place.
func slicesEquiv(lhs, rhs []string) bool {
if len(lhs) != len(rhs) {
return false
}
if reflect.DeepEqual(slice.SortStrings(lhs), slice.SortStrings(rhs)) {
return true
}
return false
}
func flattenValidEndpoints(endpoints []hostPortPair) []string {
// Convert Endpoint objects into strings for easier use later.
var result []string
for i := range endpoints {
hpp := &endpoints[i]
if isValidEndpoint(hpp) {
result = append(result, net.JoinHostPort(hpp.host, strconv.Itoa(hpp.port)))
} else {
glog.Warningf("got invalid endpoint: %+v", *hpp)
}
}
return result
}
// portProtoHash takes the ServicePortName and protocol for a service
// returns the associated 16 character hash. This is computed by hashing (sha256)
// then encoding to base32 and truncating to 16 chars. We do this because Iptables
// Chain Names must be <= 28 chars long, and the longer they are the harder they are to read.
func portProtoHash(s proxy.ServicePortName, protocol string) string {
hash := sha256.Sum256([]byte(s.String() + protocol))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return encoded[:16]
}
// servicePortChainName takes the ServicePortName for a service and
// returns the associated iptables chain. This is computed by hashing (sha256)
// then encoding to base32 and truncating with the prefix "KUBE-SVC-".
func servicePortChainName(s proxy.ServicePortName, protocol string) utiliptables.Chain {
return utiliptables.Chain("KUBE-SVC-" + portProtoHash(s, protocol))
}
// serviceFirewallChainName takes the ServicePortName for a service and
// returns the associated iptables chain. This is computed by hashing (sha256)
// then encoding to base32 and truncating with the prefix "KUBE-FW-".
func serviceFirewallChainName(s proxy.ServicePortName, protocol string) utiliptables.Chain {
return utiliptables.Chain("KUBE-FW-" + portProtoHash(s, protocol))
}
// This is the same as servicePortChainName but with the endpoint included.
func servicePortEndpointChainName(s proxy.ServicePortName, protocol string, endpoint string) utiliptables.Chain {
hash := sha256.Sum256([]byte(s.String() + protocol + endpoint))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return utiliptables.Chain("KUBE-SEP-" + encoded[:16])
}
// getRemovedEndpoints returns the endpoint IPs that are missing in the new endpoints
func getRemovedEndpoints(curEndpoints, newEndpoints []string) []string {
return sets.NewString(curEndpoints...).Difference(sets.NewString(newEndpoints...)).List()
}
type endpointServicePair struct {
endpoint string
servicePortName proxy.ServicePortName
}
const noConnectionToDelete = "0 flow entries have been deleted"
// After a UDP endpoint has been removed, we must flush any pending conntrack entries to it, or else we
// risk sending more traffic to it, all of which will be lost (because UDP).
// This assumes the proxier mutex is held
func (proxier *Proxier) deleteEndpointConnections(connectionMap map[endpointServicePair]bool) {
for epSvcPair := range connectionMap {
if svcInfo, ok := proxier.serviceMap[epSvcPair.servicePortName]; ok && svcInfo.protocol == api.ProtocolUDP {
endpointIP := strings.Split(epSvcPair.endpoint, ":")[0]
glog.V(2).Infof("Deleting connection tracking state for service IP %s, endpoint IP %s", svcInfo.clusterIP.String(), endpointIP)
err := proxier.execConntrackTool("-D", "--orig-dst", svcInfo.clusterIP.String(), "--dst-nat", endpointIP, "-p", "udp")
if err != nil && !strings.Contains(err.Error(), noConnectionToDelete) {
// TODO: Better handling for deletion failure. When failure occur, stale udp connection may not get flushed.
// These stale udp connection will keep black hole traffic. Making this a best effort operation for now, since it
// is expensive to baby sit all udp connections to kubernetes services.
glog.Errorf("conntrack return with error: %v", err)
}
}
}
}
// deleteServiceConnection use conntrack-tool to delete UDP connection specified by service ip
func (proxier *Proxier) deleteServiceConnections(svcIPs []string) {
for _, ip := range svcIPs {
glog.V(2).Infof("Deleting connection tracking state for service IP %s", ip)
err := proxier.execConntrackTool("-D", "--orig-dst", ip, "-p", "udp")
if err != nil && !strings.Contains(err.Error(), noConnectionToDelete) {
// TODO: Better handling for deletion failure. When failure occur, stale udp connection may not get flushed.
// These stale udp connection will keep black hole traffic. Making this a best effort operation for now, since it
// is expensive to baby sit all udp connections to kubernetes services.
glog.Errorf("conntrack return with error: %v", err)
}
}
}
//execConntrackTool executes conntrack tool using given parameters
func (proxier *Proxier) execConntrackTool(parameters ...string) error {
conntrackPath, err := proxier.exec.LookPath("conntrack")
if err != nil {
return fmt.Errorf("Error looking for path of conntrack: %v", err)
}
output, err := proxier.exec.Command(conntrackPath, parameters...).CombinedOutput()
if err != nil {
return fmt.Errorf("Conntrack command returned: %q, error message: %s", string(output), err)
}
return nil
}
// This is where all of the iptables-save/restore calls happen.
// The only other iptables rules are those that are setup in iptablesInit()
// assumes proxier.mu is held
func (proxier *Proxier) syncProxyRules() {
start := time.Now()
defer func() {
glog.V(4).Infof("syncProxyRules took %v", time.Since(start))
}()
// don't sync rules till we've received services and endpoints
if !proxier.haveReceivedEndpointsUpdate || !proxier.haveReceivedServiceUpdate {
glog.V(2).Info("Not syncing iptables until Services and Endpoints have been received from master")
return
}
glog.V(3).Infof("Syncing iptables rules")
// Create and link the kube services chain.
{
tablesNeedServicesChain := []utiliptables.Table{utiliptables.TableFilter, utiliptables.TableNAT}
for _, table := range tablesNeedServicesChain {
if _, err := proxier.iptables.EnsureChain(table, kubeServicesChain); err != nil {
glog.Errorf("Failed to ensure that %s chain %s exists: %v", table, kubeServicesChain, err)
return
}
}
tableChainsNeedJumpServices := []struct {
table utiliptables.Table
chain utiliptables.Chain
}{
{utiliptables.TableFilter, utiliptables.ChainOutput},
{utiliptables.TableNAT, utiliptables.ChainOutput},
{utiliptables.TableNAT, utiliptables.ChainPrerouting},
}
comment := "kubernetes service portals"
args := []string{"-m", "comment", "--comment", comment, "-j", string(kubeServicesChain)}
for _, tc := range tableChainsNeedJumpServices {
if _, err := proxier.iptables.EnsureRule(utiliptables.Prepend, tc.table, tc.chain, args...); err != nil {
glog.Errorf("Failed to ensure that %s chain %s jumps to %s: %v", tc.table, tc.chain, kubeServicesChain, err)
return
}
}
}
// Create and link the kube postrouting chain.
{
if _, err := proxier.iptables.EnsureChain(utiliptables.TableNAT, kubePostroutingChain); err != nil {
glog.Errorf("Failed to ensure that %s chain %s exists: %v", utiliptables.TableNAT, kubePostroutingChain, err)
return
}
comment := "kubernetes postrouting rules"
args := []string{"-m", "comment", "--comment", comment, "-j", string(kubePostroutingChain)}
if _, err := proxier.iptables.EnsureRule(utiliptables.Prepend, utiliptables.TableNAT, utiliptables.ChainPostrouting, args...); err != nil {
glog.Errorf("Failed to ensure that %s chain %s jumps to %s: %v", utiliptables.TableNAT, utiliptables.ChainPostrouting, kubePostroutingChain, err)
return
}
}
// Get iptables-save output so we can check for existing chains and rules.
// This will be a map of chain name to chain with rules as stored in iptables-save/iptables-restore
existingFilterChains := make(map[utiliptables.Chain]string)
iptablesSaveRaw, err := proxier.iptables.Save(utiliptables.TableFilter)
if err != nil { // if we failed to get any rules
glog.Errorf("Failed to execute iptables-save, syncing all rules: %v", err)
} else { // otherwise parse the output
existingFilterChains = utiliptables.GetChainLines(utiliptables.TableFilter, iptablesSaveRaw)
}
existingNATChains := make(map[utiliptables.Chain]string)
iptablesSaveRaw, err = proxier.iptables.Save(utiliptables.TableNAT)
if err != nil { // if we failed to get any rules
glog.Errorf("Failed to execute iptables-save, syncing all rules: %v", err)
} else { // otherwise parse the output
existingNATChains = utiliptables.GetChainLines(utiliptables.TableNAT, iptablesSaveRaw)
}
filterChains := bytes.NewBuffer(nil)
filterRules := bytes.NewBuffer(nil)
natChains := bytes.NewBuffer(nil)
natRules := bytes.NewBuffer(nil)
// Write table headers.
writeLine(filterChains, "*filter")
writeLine(natChains, "*nat")
// Make sure we keep stats for the top-level chains, if they existed
// (which most should have because we created them above).
if chain, ok := existingFilterChains[kubeServicesChain]; ok {
writeLine(filterChains, chain)
} else {
writeLine(filterChains, utiliptables.MakeChainLine(kubeServicesChain))
}
if chain, ok := existingNATChains[kubeServicesChain]; ok {
writeLine(natChains, chain)
} else {
writeLine(natChains, utiliptables.MakeChainLine(kubeServicesChain))
}
if chain, ok := existingNATChains[kubeNodePortsChain]; ok {
writeLine(natChains, chain)
} else {
writeLine(natChains, utiliptables.MakeChainLine(kubeNodePortsChain))
}
if chain, ok := existingNATChains[kubePostroutingChain]; ok {
writeLine(natChains, chain)
} else {
writeLine(natChains, utiliptables.MakeChainLine(kubePostroutingChain))
}
if chain, ok := existingNATChains[KubeMarkMasqChain]; ok {
writeLine(natChains, chain)
} else {
writeLine(natChains, utiliptables.MakeChainLine(KubeMarkMasqChain))
}
// Install the kubernetes-specific postrouting rules. We use a whole chain for
// this so that it is easier to flush and change, for example if the mark
// value should ever change.
writeLine(natRules, []string{
"-A", string(kubePostroutingChain),
"-m", "comment", "--comment", `"kubernetes service traffic requiring SNAT"`,
"-m", "mark", "--mark", proxier.masqueradeMark,
"-j", "MASQUERADE",
}...)
// Install the kubernetes-specific masquerade mark rule. We use a whole chain for
// this so that it is easier to flush and change, for example if the mark
// value should ever change.
writeLine(natRules, []string{
"-A", string(KubeMarkMasqChain),
"-j", "MARK", "--set-xmark", proxier.masqueradeMark,
}...)
// Accumulate NAT chains to keep.
activeNATChains := map[utiliptables.Chain]bool{} // use a map as a set
// Accumulate the set of local ports that we will be holding open once this update is complete
replacementPortsMap := map[localPort]closeable{}
// Build rules for each service.
for svcName, svcInfo := range proxier.serviceMap {
protocol := strings.ToLower(string(svcInfo.protocol))
// Create the per-service chain, retaining counters if possible.
svcChain := servicePortChainName(svcName, protocol)
if chain, ok := existingNATChains[svcChain]; ok {
writeLine(natChains, chain)
} else {
writeLine(natChains, utiliptables.MakeChainLine(svcChain))
}
activeNATChains[svcChain] = true
// Capture the clusterIP.
args := []string{
"-A", string(kubeServicesChain),
"-m", "comment", "--comment", fmt.Sprintf(`"%s cluster IP"`, svcName.String()),
"-m", protocol, "-p", protocol,
"-d", fmt.Sprintf("%s/32", svcInfo.clusterIP.String()),
"--dport", fmt.Sprintf("%d", svcInfo.port),
}
if proxier.masqueradeAll {
writeLine(natRules, append(args, "-j", string(KubeMarkMasqChain))...)
}
if len(proxier.clusterCIDR) > 0 {
writeLine(natRules, append(args, "! -s", proxier.clusterCIDR, "-j", string(KubeMarkMasqChain))...)
}
writeLine(natRules, append(args, "-j", string(svcChain))...)
// Capture externalIPs.
for _, externalIP := range svcInfo.externalIPs {
// If the "external" IP happens to be an IP that is local to this
// machine, hold the local port open so no other process can open it
// (because the socket might open but it would never work).
if local, err := isLocalIP(externalIP); err != nil {
glog.Errorf("can't determine if IP is local, assuming not: %v", err)
} else if local {
lp := localPort{
desc: "externalIP for " + svcName.String(),
ip: externalIP,
port: svcInfo.port,
protocol: protocol,
}
if proxier.portsMap[lp] != nil {
glog.V(4).Infof("Port %s was open before and is still needed", lp.String())
replacementPortsMap[lp] = proxier.portsMap[lp]
} else {
socket, err := openLocalPort(&lp)
if err != nil {
glog.Errorf("can't open %s, skipping this externalIP: %v", lp.String(), err)
continue
}
replacementPortsMap[lp] = socket
}
} // We're holding the port, so it's OK to install iptables rules.
args := []string{
"-A", string(kubeServicesChain),
"-m", "comment", "--comment", fmt.Sprintf(`"%s external IP"`, svcName.String()),
"-m", protocol, "-p", protocol,
"-d", fmt.Sprintf("%s/32", externalIP),
"--dport", fmt.Sprintf("%d", svcInfo.port),
}
// We have to SNAT packets to external IPs.
writeLine(natRules, append(args, "-j", string(KubeMarkMasqChain))...)
// Allow traffic for external IPs that does not come from a bridge (i.e. not from a container)
// nor from a local process to be forwarded to the service.
// This rule roughly translates to "all traffic from off-machine".
// This is imperfect in the face of network plugins that might not use a bridge, but we can revisit that later.
externalTrafficOnlyArgs := append(args,
"-m", "physdev", "!", "--physdev-is-in",
"-m", "addrtype", "!", "--src-type", "LOCAL")
writeLine(natRules, append(externalTrafficOnlyArgs, "-j", string(svcChain))...)
dstLocalOnlyArgs := append(args, "-m", "addrtype", "--dst-type", "LOCAL")
// Allow traffic bound for external IPs that happen to be recognized as local IPs to stay local.
// This covers cases like GCE load-balancers which get added to the local routing table.
writeLine(natRules, append(dstLocalOnlyArgs, "-j", string(svcChain))...)
}
// Capture load-balancer ingress.
for _, ingress := range svcInfo.loadBalancerStatus.Ingress {
if ingress.IP != "" {
// create service firewall chain
fwChain := serviceFirewallChainName(svcName, protocol)
if chain, ok := existingNATChains[fwChain]; ok {
writeLine(natChains, chain)
} else {
writeLine(natChains, utiliptables.MakeChainLine(fwChain))
}
activeNATChains[fwChain] = true
// 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.
args := []string{
"-A", string(kubeServicesChain),
"-m", "comment", "--comment", fmt.Sprintf(`"%s loadbalancer IP"`, svcName.String()),
"-m", protocol, "-p", protocol,
"-d", fmt.Sprintf("%s/32", ingress.IP),
"--dport", fmt.Sprintf("%d", svcInfo.port),
}
// jump to service firewall chain
writeLine(natRules, append(args, "-j", string(fwChain))...)
args = []string{
"-A", string(fwChain),
"-m", "comment", "--comment", fmt.Sprintf(`"%s loadbalancer IP"`, svcName.String()),
}
// We have to SNAT packets from external IPs.
writeLine(natRules, append(args, "-j", string(KubeMarkMasqChain))...)
if len(svcInfo.loadBalancerSourceRanges) == 0 {
// allow all sources, so jump directly to KUBE-SVC chain
writeLine(natRules, append(args, "-j", string(svcChain))...)
} else {
// firewall filter based on each source range
allowFromNode := false
for _, src := range svcInfo.loadBalancerSourceRanges {
writeLine(natRules, append(args, "-s", src, "-j", string(svcChain))...)
// ignore error because it has been validated
_, cidr, _ := net.ParseCIDR(src)
if cidr.Contains(proxier.nodeIP) {
allowFromNode = true
}
}
// generally, ip route rule was added to intercept request to loadbalancer vip from the
// loadbalancer's backend hosts. In this case, request will not hit the loadbalancer but loop back directly.
// Need to add the following rule to allow request on host.
if allowFromNode {
writeLine(natRules, append(args, "-s", fmt.Sprintf("%s/32", ingress.IP), "-j", string(svcChain))...)
}
}
// If the packet was able to reach the end of firewall chain, then it did not get DNATed.
// It means the packet cannot go thru the firewall, then mark it for DROP
writeLine(natRules, append(args, "-j", string(KubeMarkDropChain))...)
}
}
// Capture nodeports. If we had more than 2 rules it might be
// worthwhile to make a new per-service chain for nodeport rules, but
// with just 2 rules it ends up being a waste and a cognitive burden.
if svcInfo.nodePort != 0 {
// Hold the local port open so no other process can open it
// (because the socket might open but it would never work).
lp := localPort{
desc: "nodePort for " + svcName.String(),
ip: "",
port: svcInfo.nodePort,
protocol: protocol,
}
if proxier.portsMap[lp] != nil {
glog.V(4).Infof("Port %s was open before and is still needed", lp.String())
replacementPortsMap[lp] = proxier.portsMap[lp]
} else {
socket, err := openLocalPort(&lp)
if err != nil {
glog.Errorf("can't open %s, skipping this nodePort: %v", lp.String(), err)
continue
}
replacementPortsMap[lp] = socket
} // We're holding the port, so it's OK to install iptables rules.
args := []string{
"-A", string(kubeNodePortsChain),
"-m", "comment", "--comment", svcName.String(),
"-m", protocol, "-p", protocol,
"--dport", fmt.Sprintf("%d", svcInfo.nodePort),
}
// Nodeports need SNAT.
writeLine(natRules, append(args, "-j", string(KubeMarkMasqChain))...)
// Jump to the service chain.
writeLine(natRules, append(args, "-j", string(svcChain))...)
}
// If the service has no endpoints then reject packets.
if len(proxier.endpointsMap[svcName]) == 0 {
writeLine(filterRules,
"-A", string(kubeServicesChain),
"-m", "comment", "--comment", fmt.Sprintf(`"%s has no endpoints"`, svcName.String()),
"-m", protocol, "-p", protocol,
"-d", fmt.Sprintf("%s/32", svcInfo.clusterIP.String()),
"--dport", fmt.Sprintf("%d", svcInfo.port),
"-j", "REJECT",
)
continue
}
// Generate the per-endpoint chains. We do this in multiple passes so we
// can group rules together.
endpoints := make([]string, 0)
endpointChains := make([]utiliptables.Chain, 0)
for _, ep := range proxier.endpointsMap[svcName] {
endpoints = append(endpoints, ep)
endpointChain := servicePortEndpointChainName(svcName, protocol, ep)
endpointChains = append(endpointChains, endpointChain)
// Create the endpoint chain, retaining counters if possible.
if chain, ok := existingNATChains[utiliptables.Chain(endpointChain)]; ok {
writeLine(natChains, chain)