k3s/pkg/agent/netpol/policy.go
Derek Nola 73df2d806b
Update embedded kube-router (#3557)
* Update embedded kube-router

Signed-off-by: dereknola <derek.nola@suse.com>
2021-07-07 08:46:10 -07:00

806 lines
32 KiB
Go

// Apache License v2.0 (copyright Cloud Native Labs & Rancher Labs)
// - modified from https://github.com/cloudnativelabs/kube-router/blob/73b1b03b32c5755b240f6c077bb097abe3888314/pkg/controllers/netpol/policy.go
// +build !windows
package netpol
import (
"crypto/sha256"
"encoding/base32"
"errors"
"fmt"
"strconv"
"strings"
"time"
"github.com/rancher/k3s/pkg/agent/netpol/utils"
api "k8s.io/api/core/v1"
networking "k8s.io/api/networking/v1"
v1 "k8s.io/apimachinery/pkg/apis/meta/v1"
"k8s.io/apimachinery/pkg/labels"
"k8s.io/apimachinery/pkg/util/intstr"
listers "k8s.io/client-go/listers/core/v1"
"k8s.io/client-go/tools/cache"
"k8s.io/klog/v2"
)
func (npc *NetworkPolicyController) newNetworkPolicyEventHandler() cache.ResourceEventHandler {
return cache.ResourceEventHandlerFuncs{
AddFunc: func(obj interface{}) {
npc.OnNetworkPolicyUpdate(obj)
},
UpdateFunc: func(oldObj, newObj interface{}) {
npc.OnNetworkPolicyUpdate(newObj)
},
DeleteFunc: func(obj interface{}) {
npc.handleNetworkPolicyDelete(obj)
},
}
}
// OnNetworkPolicyUpdate handles updates to network policy from the kubernetes api server
func (npc *NetworkPolicyController) OnNetworkPolicyUpdate(obj interface{}) {
netpol := obj.(*networking.NetworkPolicy)
klog.V(2).Infof("Received update for network policy: %s/%s", netpol.Namespace, netpol.Name)
npc.RequestFullSync()
}
func (npc *NetworkPolicyController) handleNetworkPolicyDelete(obj interface{}) {
netpol, ok := obj.(*networking.NetworkPolicy)
if !ok {
tombstone, ok := obj.(cache.DeletedFinalStateUnknown)
if !ok {
klog.Errorf("unexpected object type: %v", obj)
return
}
if netpol, ok = tombstone.Obj.(*networking.NetworkPolicy); !ok {
klog.Errorf("unexpected object type: %v", obj)
return
}
}
klog.V(2).Infof("Received network policy: %s/%s delete event", netpol.Namespace, netpol.Name)
npc.RequestFullSync()
}
// Configure iptables rules representing each network policy. All pod's matched by
// network policy spec podselector labels are grouped together in one ipset which
// is used for matching destination ip address. Each ingress rule in the network
// policyspec is evaluated to set of matching pods, which are grouped in to a
// ipset used for source ip addr matching.
func (npc *NetworkPolicyController) syncNetworkPolicyChains(networkPoliciesInfo []networkPolicyInfo, version string) (map[string]bool, map[string]bool, error) {
start := time.Now()
defer func() {
endTime := time.Since(start)
klog.V(2).Infof("Syncing network policy chains took %v", endTime)
}()
klog.V(1).Infof("Attempting to attain ipset mutex lock")
npc.ipsetMutex.Lock()
klog.V(1).Infof("Attained ipset mutex lock, continuing...")
defer func() {
npc.ipsetMutex.Unlock()
klog.V(1).Infof("Returned ipset mutex lock")
}()
ipset, err := utils.NewIPSet(false)
if err != nil {
return nil, nil, err
}
err = ipset.Save()
if err != nil {
return nil, nil, err
}
npc.ipSetHandler = ipset
activePolicyChains := make(map[string]bool)
activePolicyIPSets := make(map[string]bool)
// run through all network policies
for _, policy := range networkPoliciesInfo {
// ensure there is a unique chain per network policy in filter table
policyChainName := networkPolicyChainName(policy.namespace, policy.name, version)
npc.filterTableRules.WriteString(":" + policyChainName + "\n")
activePolicyChains[policyChainName] = true
currnetPodIps := make([]string, 0, len(policy.targetPods))
for ip := range policy.targetPods {
currnetPodIps = append(currnetPodIps, ip)
}
if policy.policyType == "both" || policy.policyType == "ingress" {
// create a ipset for all destination pod ip's matched by the policy spec PodSelector
targetDestPodIPSetName := policyDestinationPodIPSetName(policy.namespace, policy.name)
setEntries := make([][]string, 0)
for _, podIP := range currnetPodIps {
setEntries = append(setEntries, []string{podIP, utils.OptionTimeout, "0"})
}
npc.ipSetHandler.RefreshSet(targetDestPodIPSetName, setEntries, utils.TypeHashIP)
err = npc.processIngressRules(policy, targetDestPodIPSetName, activePolicyIPSets, version)
if err != nil {
return nil, nil, err
}
activePolicyIPSets[targetDestPodIPSetName] = true
}
if policy.policyType == "both" || policy.policyType == "egress" {
// create a ipset for all source pod ip's matched by the policy spec PodSelector
targetSourcePodIPSetName := policySourcePodIPSetName(policy.namespace, policy.name)
setEntries := make([][]string, 0)
for _, podIP := range currnetPodIps {
setEntries = append(setEntries, []string{podIP, utils.OptionTimeout, "0"})
}
npc.ipSetHandler.RefreshSet(targetSourcePodIPSetName, setEntries, utils.TypeHashIP)
err = npc.processEgressRules(policy, targetSourcePodIPSetName, activePolicyIPSets, version)
if err != nil {
return nil, nil, err
}
activePolicyIPSets[targetSourcePodIPSetName] = true
}
}
err = npc.ipSetHandler.Restore()
if err != nil {
return nil, nil, fmt.Errorf("failed to perform ipset restore: %s", err.Error())
}
klog.V(2).Infof("Iptables chains in the filter table are synchronized with the network policies.")
return activePolicyChains, activePolicyIPSets, nil
}
func (npc *NetworkPolicyController) processIngressRules(policy networkPolicyInfo,
targetDestPodIPSetName string, activePolicyIPSets map[string]bool, version string) error {
// From network policy spec: "If field 'Ingress' is empty then this NetworkPolicy does not allow any traffic "
// so no whitelist rules to be added to the network policy
if policy.ingressRules == nil {
return nil
}
policyChainName := networkPolicyChainName(policy.namespace, policy.name, version)
// run through all the ingress rules in the spec and create iptables rules
// in the chain for the network policy
for i, ingressRule := range policy.ingressRules {
if len(ingressRule.srcPods) != 0 {
srcPodIPSetName := policyIndexedSourcePodIPSetName(policy.namespace, policy.name, i)
activePolicyIPSets[srcPodIPSetName] = true
setEntries := make([][]string, 0)
for _, pod := range ingressRule.srcPods {
setEntries = append(setEntries, []string{pod.ip, utils.OptionTimeout, "0"})
}
npc.ipSetHandler.RefreshSet(srcPodIPSetName, setEntries, utils.TypeHashIP)
if len(ingressRule.ports) != 0 {
// case where 'ports' details and 'from' details specified in the ingress rule
// so match on specified source and destination ip's and specified port (if any) and protocol
for _, portProtocol := range ingressRule.ports {
comment := "rule to ACCEPT traffic from source pods to dest pods selected by policy name " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, srcPodIPSetName, targetDestPodIPSetName, portProtocol.protocol, portProtocol.port, portProtocol.endport); err != nil {
return err
}
}
}
if len(ingressRule.namedPorts) != 0 {
for j, endPoints := range ingressRule.namedPorts {
namedPortIPSetName := policyIndexedIngressNamedPortIPSetName(policy.namespace, policy.name, i, j)
activePolicyIPSets[namedPortIPSetName] = true
setEntries := make([][]string, 0)
for _, ip := range endPoints.ips {
setEntries = append(setEntries, []string{ip, utils.OptionTimeout, "0"})
}
npc.ipSetHandler.RefreshSet(namedPortIPSetName, setEntries, utils.TypeHashIP)
comment := "rule to ACCEPT traffic from source pods to dest pods selected by policy name " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, srcPodIPSetName, namedPortIPSetName, endPoints.protocol, endPoints.port, endPoints.endport); err != nil {
return err
}
}
}
if len(ingressRule.ports) == 0 && len(ingressRule.namedPorts) == 0 {
// case where no 'ports' details specified in the ingress rule but 'from' details specified
// so match on specified source and destination ip with all port and protocol
comment := "rule to ACCEPT traffic from source pods to dest pods selected by policy name " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, srcPodIPSetName, targetDestPodIPSetName, "", "", ""); err != nil {
return err
}
}
}
// case where only 'ports' details specified but no 'from' details in the ingress rule
// so match on all sources, with specified port (if any) and protocol
if ingressRule.matchAllSource && !ingressRule.matchAllPorts {
for _, portProtocol := range ingressRule.ports {
comment := "rule to ACCEPT traffic from all sources to dest pods selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, "", targetDestPodIPSetName, portProtocol.protocol, portProtocol.port, portProtocol.endport); err != nil {
return err
}
}
for j, endPoints := range ingressRule.namedPorts {
namedPortIPSetName := policyIndexedIngressNamedPortIPSetName(policy.namespace, policy.name, i, j)
activePolicyIPSets[namedPortIPSetName] = true
setEntries := make([][]string, 0)
for _, ip := range endPoints.ips {
setEntries = append(setEntries, []string{ip, utils.OptionTimeout, "0"})
}
npc.ipSetHandler.RefreshSet(namedPortIPSetName, setEntries, utils.TypeHashIP)
comment := "rule to ACCEPT traffic from all sources to dest pods selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, "", namedPortIPSetName, endPoints.protocol, endPoints.port, endPoints.endport); err != nil {
return err
}
}
}
// case where nether ports nor from details are speified in the ingress rule
// so match on all ports, protocol, source IP's
if ingressRule.matchAllSource && ingressRule.matchAllPorts {
comment := "rule to ACCEPT traffic from all sources to dest pods selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, "", targetDestPodIPSetName, "", "", ""); err != nil {
return err
}
}
if len(ingressRule.srcIPBlocks) != 0 {
srcIPBlockIPSetName := policyIndexedSourceIPBlockIPSetName(policy.namespace, policy.name, i)
activePolicyIPSets[srcIPBlockIPSetName] = true
npc.ipSetHandler.RefreshSet(srcIPBlockIPSetName, ingressRule.srcIPBlocks, utils.TypeHashNet)
if !ingressRule.matchAllPorts {
for _, portProtocol := range ingressRule.ports {
comment := "rule to ACCEPT traffic from specified ipBlocks to dest pods selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, srcIPBlockIPSetName, targetDestPodIPSetName, portProtocol.protocol, portProtocol.port, portProtocol.endport); err != nil {
return err
}
}
for j, endPoints := range ingressRule.namedPorts {
namedPortIPSetName := policyIndexedIngressNamedPortIPSetName(policy.namespace, policy.name, i, j)
activePolicyIPSets[namedPortIPSetName] = true
setEntries := make([][]string, 0)
for _, ip := range endPoints.ips {
setEntries = append(setEntries, []string{ip, utils.OptionTimeout, "0"})
}
npc.ipSetHandler.RefreshSet(namedPortIPSetName, setEntries, utils.TypeHashNet)
comment := "rule to ACCEPT traffic from specified ipBlocks to dest pods selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, srcIPBlockIPSetName, namedPortIPSetName, endPoints.protocol, endPoints.port, endPoints.endport); err != nil {
return err
}
}
}
if ingressRule.matchAllPorts {
comment := "rule to ACCEPT traffic from specified ipBlocks to dest pods selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, srcIPBlockIPSetName, targetDestPodIPSetName, "", "", ""); err != nil {
return err
}
}
}
}
return nil
}
func (npc *NetworkPolicyController) processEgressRules(policy networkPolicyInfo,
targetSourcePodIPSetName string, activePolicyIPSets map[string]bool, version string) error {
// From network policy spec: "If field 'Ingress' is empty then this NetworkPolicy does not allow any traffic "
// so no whitelist rules to be added to the network policy
if policy.egressRules == nil {
return nil
}
policyChainName := networkPolicyChainName(policy.namespace, policy.name, version)
// run through all the egress rules in the spec and create iptables rules
// in the chain for the network policy
for i, egressRule := range policy.egressRules {
if len(egressRule.dstPods) != 0 {
dstPodIPSetName := policyIndexedDestinationPodIPSetName(policy.namespace, policy.name, i)
activePolicyIPSets[dstPodIPSetName] = true
setEntries := make([][]string, 0)
for _, pod := range egressRule.dstPods {
setEntries = append(setEntries, []string{pod.ip, utils.OptionTimeout, "0"})
}
npc.ipSetHandler.RefreshSet(dstPodIPSetName, setEntries, utils.TypeHashIP)
if len(egressRule.ports) != 0 {
// case where 'ports' details and 'from' details specified in the egress rule
// so match on specified source and destination ip's and specified port (if any) and protocol
for _, portProtocol := range egressRule.ports {
comment := "rule to ACCEPT traffic from source pods to dest pods selected by policy name " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, targetSourcePodIPSetName, dstPodIPSetName, portProtocol.protocol, portProtocol.port, portProtocol.endport); err != nil {
return err
}
}
}
if len(egressRule.namedPorts) != 0 {
for j, endPoints := range egressRule.namedPorts {
namedPortIPSetName := policyIndexedEgressNamedPortIPSetName(policy.namespace, policy.name, i, j)
activePolicyIPSets[namedPortIPSetName] = true
setEntries := make([][]string, 0)
for _, ip := range endPoints.ips {
setEntries = append(setEntries, []string{ip, utils.OptionTimeout, "0"})
}
npc.ipSetHandler.RefreshSet(namedPortIPSetName, setEntries, utils.TypeHashIP)
comment := "rule to ACCEPT traffic from source pods to dest pods selected by policy name " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, targetSourcePodIPSetName, namedPortIPSetName, endPoints.protocol, endPoints.port, endPoints.endport); err != nil {
return err
}
}
}
if len(egressRule.ports) == 0 && len(egressRule.namedPorts) == 0 {
// case where no 'ports' details specified in the ingress rule but 'from' details specified
// so match on specified source and destination ip with all port and protocol
comment := "rule to ACCEPT traffic from source pods to dest pods selected by policy name " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, targetSourcePodIPSetName, dstPodIPSetName, "", "", ""); err != nil {
return err
}
}
}
// case where only 'ports' details specified but no 'to' details in the egress rule
// so match on all sources, with specified port (if any) and protocol
if egressRule.matchAllDestinations && !egressRule.matchAllPorts {
for _, portProtocol := range egressRule.ports {
comment := "rule to ACCEPT traffic from source pods to all destinations selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, targetSourcePodIPSetName, "", portProtocol.protocol, portProtocol.port, portProtocol.endport); err != nil {
return err
}
}
for _, portProtocol := range egressRule.namedPorts {
comment := "rule to ACCEPT traffic from source pods to all destinations selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, targetSourcePodIPSetName, "", portProtocol.protocol, portProtocol.port, portProtocol.endport); err != nil {
return err
}
}
}
// case where nether ports nor from details are speified in the egress rule
// so match on all ports, protocol, source IP's
if egressRule.matchAllDestinations && egressRule.matchAllPorts {
comment := "rule to ACCEPT traffic from source pods to all destinations selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, targetSourcePodIPSetName, "", "", "", ""); err != nil {
return err
}
}
if len(egressRule.dstIPBlocks) != 0 {
dstIPBlockIPSetName := policyIndexedDestinationIPBlockIPSetName(policy.namespace, policy.name, i)
activePolicyIPSets[dstIPBlockIPSetName] = true
npc.ipSetHandler.RefreshSet(dstIPBlockIPSetName, egressRule.dstIPBlocks, utils.TypeHashNet)
if !egressRule.matchAllPorts {
for _, portProtocol := range egressRule.ports {
comment := "rule to ACCEPT traffic from source pods to specified ipBlocks selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, targetSourcePodIPSetName, dstIPBlockIPSetName, portProtocol.protocol, portProtocol.port, portProtocol.endport); err != nil {
return err
}
}
}
if egressRule.matchAllPorts {
comment := "rule to ACCEPT traffic from source pods to specified ipBlocks selected by policy name: " +
policy.name + " namespace " + policy.namespace
if err := npc.appendRuleToPolicyChain(policyChainName, comment, targetSourcePodIPSetName, dstIPBlockIPSetName, "", "", ""); err != nil {
return err
}
}
}
}
return nil
}
func (npc *NetworkPolicyController) appendRuleToPolicyChain(policyChainName, comment, srcIPSetName, dstIPSetName, protocol, dPort, endDport string) error {
args := make([]string, 0)
args = append(args, "-A", policyChainName)
if comment != "" {
args = append(args, "-m", "comment", "--comment", "\""+comment+"\"")
}
if srcIPSetName != "" {
args = append(args, "-m", "set", "--match-set", srcIPSetName, "src")
}
if dstIPSetName != "" {
args = append(args, "-m", "set", "--match-set", dstIPSetName, "dst")
}
if protocol != "" {
args = append(args, "-p", protocol)
}
if dPort != "" {
if endDport != "" {
multiport := fmt.Sprintf("%s:%s", dPort, endDport)
args = append(args, "--dport", multiport)
} else {
args = append(args, "--dport", dPort)
}
}
markArgs := append(args, "-j", "MARK", "--set-xmark", "0x10000/0x10000", "\n")
npc.filterTableRules.WriteString(strings.Join(markArgs, " "))
returnArgs := append(args, "-m", "mark", "--mark", "0x10000/0x10000", "-j", "RETURN", "\n")
npc.filterTableRules.WriteString(strings.Join(returnArgs, " "))
return nil
}
func (npc *NetworkPolicyController) buildNetworkPoliciesInfo() ([]networkPolicyInfo, error) {
NetworkPolicies := make([]networkPolicyInfo, 0)
for _, policyObj := range npc.npLister.List() {
policy, ok := policyObj.(*networking.NetworkPolicy)
podSelector, _ := v1.LabelSelectorAsSelector(&policy.Spec.PodSelector)
if !ok {
return nil, fmt.Errorf("failed to convert")
}
newPolicy := networkPolicyInfo{
name: policy.Name,
namespace: policy.Namespace,
podSelector: podSelector,
policyType: "ingress",
}
ingressType, egressType := false, false
for _, policyType := range policy.Spec.PolicyTypes {
if policyType == networking.PolicyTypeIngress {
ingressType = true
}
if policyType == networking.PolicyTypeEgress {
egressType = true
}
}
if ingressType && egressType {
newPolicy.policyType = "both"
} else if egressType {
newPolicy.policyType = "egress"
} else if ingressType {
newPolicy.policyType = "ingress"
}
matchingPods, err := npc.ListPodsByNamespaceAndLabels(policy.Namespace, podSelector)
newPolicy.targetPods = make(map[string]podInfo)
namedPort2IngressEps := make(namedPort2eps)
if err == nil {
for _, matchingPod := range matchingPods {
if !isNetPolActionable(matchingPod) {
continue
}
newPolicy.targetPods[matchingPod.Status.PodIP] = podInfo{ip: matchingPod.Status.PodIP,
name: matchingPod.ObjectMeta.Name,
namespace: matchingPod.ObjectMeta.Namespace,
labels: matchingPod.ObjectMeta.Labels}
npc.grabNamedPortFromPod(matchingPod, &namedPort2IngressEps)
}
}
if policy.Spec.Ingress == nil {
newPolicy.ingressRules = nil
} else {
newPolicy.ingressRules = make([]ingressRule, 0)
}
if policy.Spec.Egress == nil {
newPolicy.egressRules = nil
} else {
newPolicy.egressRules = make([]egressRule, 0)
}
for _, specIngressRule := range policy.Spec.Ingress {
ingressRule := ingressRule{}
ingressRule.srcPods = make([]podInfo, 0)
ingressRule.srcIPBlocks = make([][]string, 0)
// If this field is empty or missing in the spec, this rule matches all sources
if len(specIngressRule.From) == 0 {
ingressRule.matchAllSource = true
} else {
ingressRule.matchAllSource = false
for _, peer := range specIngressRule.From {
if peerPods, err := npc.evalPodPeer(policy, peer); err == nil {
for _, peerPod := range peerPods {
if !isNetPolActionable(peerPod) {
continue
}
ingressRule.srcPods = append(ingressRule.srcPods,
podInfo{ip: peerPod.Status.PodIP,
name: peerPod.ObjectMeta.Name,
namespace: peerPod.ObjectMeta.Namespace,
labels: peerPod.ObjectMeta.Labels})
}
}
ingressRule.srcIPBlocks = append(ingressRule.srcIPBlocks, npc.evalIPBlockPeer(peer)...)
}
}
ingressRule.ports = make([]protocolAndPort, 0)
ingressRule.namedPorts = make([]endPoints, 0)
// If this field is empty or missing in the spec, this rule matches all ports
if len(specIngressRule.Ports) == 0 {
ingressRule.matchAllPorts = true
} else {
ingressRule.matchAllPorts = false
ingressRule.ports, ingressRule.namedPorts = npc.processNetworkPolicyPorts(specIngressRule.Ports, namedPort2IngressEps)
}
newPolicy.ingressRules = append(newPolicy.ingressRules, ingressRule)
}
for _, specEgressRule := range policy.Spec.Egress {
egressRule := egressRule{}
egressRule.dstPods = make([]podInfo, 0)
egressRule.dstIPBlocks = make([][]string, 0)
namedPort2EgressEps := make(namedPort2eps)
// If this field is empty or missing in the spec, this rule matches all sources
if len(specEgressRule.To) == 0 {
egressRule.matchAllDestinations = true
// if rule.To is empty but rule.Ports not, we must try to grab NamedPort from pods that in same namespace,
// so that we can design iptables rule to describe "match all dst but match some named dst-port" egress rule
if policyRulePortsHasNamedPort(specEgressRule.Ports) {
matchingPeerPods, _ := npc.ListPodsByNamespaceAndLabels(policy.Namespace, labels.Everything())
for _, peerPod := range matchingPeerPods {
if !isNetPolActionable(peerPod) {
continue
}
npc.grabNamedPortFromPod(peerPod, &namedPort2EgressEps)
}
}
} else {
egressRule.matchAllDestinations = false
for _, peer := range specEgressRule.To {
if peerPods, err := npc.evalPodPeer(policy, peer); err == nil {
for _, peerPod := range peerPods {
if !isNetPolActionable(peerPod) {
continue
}
egressRule.dstPods = append(egressRule.dstPods,
podInfo{ip: peerPod.Status.PodIP,
name: peerPod.ObjectMeta.Name,
namespace: peerPod.ObjectMeta.Namespace,
labels: peerPod.ObjectMeta.Labels})
npc.grabNamedPortFromPod(peerPod, &namedPort2EgressEps)
}
}
egressRule.dstIPBlocks = append(egressRule.dstIPBlocks, npc.evalIPBlockPeer(peer)...)
}
}
egressRule.ports = make([]protocolAndPort, 0)
egressRule.namedPorts = make([]endPoints, 0)
// If this field is empty or missing in the spec, this rule matches all ports
if len(specEgressRule.Ports) == 0 {
egressRule.matchAllPorts = true
} else {
egressRule.matchAllPorts = false
egressRule.ports, egressRule.namedPorts = npc.processNetworkPolicyPorts(specEgressRule.Ports, namedPort2EgressEps)
}
newPolicy.egressRules = append(newPolicy.egressRules, egressRule)
}
NetworkPolicies = append(NetworkPolicies, newPolicy)
}
return NetworkPolicies, nil
}
func (npc *NetworkPolicyController) evalPodPeer(policy *networking.NetworkPolicy, peer networking.NetworkPolicyPeer) ([]*api.Pod, error) {
var matchingPods []*api.Pod
matchingPods = make([]*api.Pod, 0)
var err error
// spec can have both PodSelector AND NamespaceSelector
if peer.NamespaceSelector != nil {
namespaceSelector, _ := v1.LabelSelectorAsSelector(peer.NamespaceSelector)
namespaces, err := npc.ListNamespaceByLabels(namespaceSelector)
if err != nil {
return nil, errors.New("Failed to build network policies info due to " + err.Error())
}
podSelector := labels.Everything()
if peer.PodSelector != nil {
podSelector, _ = v1.LabelSelectorAsSelector(peer.PodSelector)
}
for _, namespace := range namespaces {
namespacePods, err := npc.ListPodsByNamespaceAndLabels(namespace.Name, podSelector)
if err != nil {
return nil, errors.New("Failed to build network policies info due to " + err.Error())
}
matchingPods = append(matchingPods, namespacePods...)
}
} else if peer.PodSelector != nil {
podSelector, _ := v1.LabelSelectorAsSelector(peer.PodSelector)
matchingPods, err = npc.ListPodsByNamespaceAndLabels(policy.Namespace, podSelector)
}
return matchingPods, err
}
func (npc *NetworkPolicyController) processNetworkPolicyPorts(npPorts []networking.NetworkPolicyPort, namedPort2eps namedPort2eps) (numericPorts []protocolAndPort, namedPorts []endPoints) {
numericPorts, namedPorts = make([]protocolAndPort, 0), make([]endPoints, 0)
for _, npPort := range npPorts {
var protocol string
if npPort.Protocol != nil {
protocol = string(*npPort.Protocol)
}
if npPort.Port == nil {
numericPorts = append(numericPorts, protocolAndPort{port: "", protocol: protocol})
} else if npPort.Port.Type == intstr.Int {
var portproto protocolAndPort
if npPort.EndPort != nil {
if *npPort.EndPort >= npPort.Port.IntVal {
portproto.endport = strconv.Itoa(int(*npPort.EndPort))
}
}
portproto.protocol, portproto.port = protocol, npPort.Port.String()
numericPorts = append(numericPorts, portproto)
} else {
if protocol2eps, ok := namedPort2eps[npPort.Port.String()]; ok {
if numericPort2eps, ok := protocol2eps[protocol]; ok {
for _, eps := range numericPort2eps {
namedPorts = append(namedPorts, *eps)
}
}
}
}
}
return
}
func (npc *NetworkPolicyController) ListPodsByNamespaceAndLabels(namespace string, podSelector labels.Selector) (ret []*api.Pod, err error) {
podLister := listers.NewPodLister(npc.podLister)
allMatchedNameSpacePods, err := podLister.Pods(namespace).List(podSelector)
if err != nil {
return nil, err
}
return allMatchedNameSpacePods, nil
}
func (npc *NetworkPolicyController) ListNamespaceByLabels(namespaceSelector labels.Selector) ([]*api.Namespace, error) {
namespaceLister := listers.NewNamespaceLister(npc.nsLister)
matchedNamespaces, err := namespaceLister.List(namespaceSelector)
if err != nil {
return nil, err
}
return matchedNamespaces, nil
}
func (npc *NetworkPolicyController) evalIPBlockPeer(peer networking.NetworkPolicyPeer) [][]string {
ipBlock := make([][]string, 0)
if peer.PodSelector == nil && peer.NamespaceSelector == nil && peer.IPBlock != nil {
if cidr := peer.IPBlock.CIDR; strings.HasSuffix(cidr, "/0") {
ipBlock = append(ipBlock, []string{"0.0.0.0/1", utils.OptionTimeout, "0"}, []string{"128.0.0.0/1", utils.OptionTimeout, "0"})
} else {
ipBlock = append(ipBlock, []string{cidr, utils.OptionTimeout, "0"})
}
for _, except := range peer.IPBlock.Except {
if strings.HasSuffix(except, "/0") {
ipBlock = append(ipBlock, []string{"0.0.0.0/1", utils.OptionTimeout, "0", utils.OptionNoMatch}, []string{"128.0.0.0/1", utils.OptionTimeout, "0", utils.OptionNoMatch})
} else {
ipBlock = append(ipBlock, []string{except, utils.OptionTimeout, "0", utils.OptionNoMatch})
}
}
}
return ipBlock
}
func (npc *NetworkPolicyController) grabNamedPortFromPod(pod *api.Pod, namedPort2eps *namedPort2eps) {
if pod == nil || namedPort2eps == nil {
return
}
for k := range pod.Spec.Containers {
for _, port := range pod.Spec.Containers[k].Ports {
name := port.Name
protocol := string(port.Protocol)
containerPort := strconv.Itoa(int(port.ContainerPort))
if (*namedPort2eps)[name] == nil {
(*namedPort2eps)[name] = make(protocol2eps)
}
if (*namedPort2eps)[name][protocol] == nil {
(*namedPort2eps)[name][protocol] = make(numericPort2eps)
}
if eps, ok := (*namedPort2eps)[name][protocol][containerPort]; !ok {
(*namedPort2eps)[name][protocol][containerPort] = &endPoints{
ips: []string{pod.Status.PodIP},
protocolAndPort: protocolAndPort{port: containerPort, protocol: protocol},
}
} else {
eps.ips = append(eps.ips, pod.Status.PodIP)
}
}
}
}
func networkPolicyChainName(namespace, policyName string, version string) string {
hash := sha256.Sum256([]byte(namespace + policyName + version))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeNetworkPolicyChainPrefix + encoded[:16]
}
func policySourcePodIPSetName(namespace, policyName string) string {
hash := sha256.Sum256([]byte(namespace + policyName))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeSourceIPSetPrefix + encoded[:16]
}
func policyDestinationPodIPSetName(namespace, policyName string) string {
hash := sha256.Sum256([]byte(namespace + policyName))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeDestinationIPSetPrefix + encoded[:16]
}
func policyIndexedSourcePodIPSetName(namespace, policyName string, ingressRuleNo int) string {
hash := sha256.Sum256([]byte(namespace + policyName + "ingressrule" + strconv.Itoa(ingressRuleNo) + "pod"))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeSourceIPSetPrefix + encoded[:16]
}
func policyIndexedDestinationPodIPSetName(namespace, policyName string, egressRuleNo int) string {
hash := sha256.Sum256([]byte(namespace + policyName + "egressrule" + strconv.Itoa(egressRuleNo) + "pod"))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeDestinationIPSetPrefix + encoded[:16]
}
func policyIndexedSourceIPBlockIPSetName(namespace, policyName string, ingressRuleNo int) string {
hash := sha256.Sum256([]byte(namespace + policyName + "ingressrule" + strconv.Itoa(ingressRuleNo) + "ipblock"))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeSourceIPSetPrefix + encoded[:16]
}
func policyIndexedDestinationIPBlockIPSetName(namespace, policyName string, egressRuleNo int) string {
hash := sha256.Sum256([]byte(namespace + policyName + "egressrule" + strconv.Itoa(egressRuleNo) + "ipblock"))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeDestinationIPSetPrefix + encoded[:16]
}
func policyIndexedIngressNamedPortIPSetName(namespace, policyName string, ingressRuleNo, namedPortNo int) string {
hash := sha256.Sum256([]byte(namespace + policyName + "ingressrule" + strconv.Itoa(ingressRuleNo) + strconv.Itoa(namedPortNo) + "namedport"))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeDestinationIPSetPrefix + encoded[:16]
}
func policyIndexedEgressNamedPortIPSetName(namespace, policyName string, egressRuleNo, namedPortNo int) string {
hash := sha256.Sum256([]byte(namespace + policyName + "egressrule" + strconv.Itoa(egressRuleNo) + strconv.Itoa(namedPortNo) + "namedport"))
encoded := base32.StdEncoding.EncodeToString(hash[:])
return kubeDestinationIPSetPrefix + encoded[:16]
}
func policyRulePortsHasNamedPort(npPorts []networking.NetworkPolicyPort) bool {
for _, npPort := range npPorts {
if npPort.Port != nil && npPort.Port.Type == intstr.String {
return true
}
}
return false
}