moby/libnetwork/service_linux.go
Chris Telfer 7d7412f957 Gracefully remove LB endpoints from services
This patch attempts to allow endpoints to complete servicing connections
while being removed from a service.  The change adds a flag to the
endpoint.deleteServiceInfoFromCluster() method to indicate whether this
removal should fully remove connectivity through the load balancer
to the endpoint or should just disable directing further connections to
the endpoint.  If the flag is 'false', then the load balancer assigns
a weight of 0 to the endpoint but does not remove it as a linux load
balancing destination.  It does remove the endpoint as a docker load
balancing endpoint but tracks it in a special map of "disabled-but-not-
destroyed" load balancing endpoints.  This allows traffic to continue
flowing, at least under Linux.  If the flag is 'true', then the code
removes the endpoint entirely as a load balancing destination.

The sandbox.DisableService() method invokes deleteServiceInfoFromCluster()
with the flag sent to 'false', while the endpoint.sbLeave() method invokes
it with the flag set to 'true' to complete the removal on endpoint
finalization.  Renaming the endpoint invokes deleteServiceInfoFromCluster()
with the flag set to 'true' because renaming attempts to completely
remove and then re-add each endpoint service entry.

The controller.rmServiceBinding() method, which carries out the operation,
similarly gets a new flag for whether to fully remove the endpoint.  If
the flag is false, it does the job of moving the endpoint from the
load balancing set to the 'disabled' set.  It then removes or
de-weights the entry in the OS load balancing table via
network.rmLBBackend().  It removes the service entirely via said method
ONLY IF there are no more live or disabled load balancing endpoints.
Similarly network.addLBBackend() requires slight tweaking to properly
manage the disabled set.

Finally, this change requires propagating the status of disabled
service endpoints via the networkDB.  Accordingly, the patch includes
both code to generate and handle service update messages.  It also
augments the service structure with a ServiceDisabled boolean to convey
whether an endpoint should ultimately be removed or just disabled.
This, naturally, required a rebuild of the protocol buffer code as well.

Signed-off-by: Chris Telfer <ctelfer@docker.com>
2018-03-16 15:19:49 -04:00

796 lines
23 KiB
Go

package libnetwork
import (
"fmt"
"io"
"io/ioutil"
"net"
"os"
"os/exec"
"path/filepath"
"runtime"
"strconv"
"strings"
"sync"
"syscall"
"github.com/docker/docker/pkg/reexec"
"github.com/docker/libnetwork/iptables"
"github.com/docker/libnetwork/ipvs"
"github.com/docker/libnetwork/ns"
"github.com/gogo/protobuf/proto"
"github.com/ishidawataru/sctp"
"github.com/sirupsen/logrus"
"github.com/vishvananda/netlink/nl"
"github.com/vishvananda/netns"
)
func init() {
reexec.Register("fwmarker", fwMarker)
reexec.Register("redirecter", redirecter)
}
// Get all loadbalancers on this network that is currently discovered
// on this node.
func (n *network) connectedLoadbalancers() []*loadBalancer {
c := n.getController()
c.Lock()
serviceBindings := make([]*service, 0, len(c.serviceBindings))
for _, s := range c.serviceBindings {
serviceBindings = append(serviceBindings, s)
}
c.Unlock()
var lbs []*loadBalancer
for _, s := range serviceBindings {
s.Lock()
// Skip the serviceBindings that got deleted
if s.deleted {
s.Unlock()
continue
}
if lb, ok := s.loadBalancers[n.ID()]; ok {
lbs = append(lbs, lb)
}
s.Unlock()
}
return lbs
}
// Populate all loadbalancers on the network that the passed endpoint
// belongs to, into this sandbox.
func (sb *sandbox) populateLoadbalancers(ep *endpoint) {
var gwIP net.IP
// This is an interface less endpoint. Nothing to do.
if ep.Iface() == nil {
return
}
n := ep.getNetwork()
eIP := ep.Iface().Address()
if n.ingress {
if err := addRedirectRules(sb.Key(), eIP, ep.ingressPorts); err != nil {
logrus.Errorf("Failed to add redirect rules for ep %s (%s): %v", ep.Name(), ep.ID()[0:7], err)
}
}
if sb.ingress {
// For the ingress sandbox if this is not gateway
// endpoint do nothing.
if ep != sb.getGatewayEndpoint() {
return
}
// This is the gateway endpoint. Now get the ingress
// network and plumb the loadbalancers.
gwIP = ep.Iface().Address().IP
for _, ep := range sb.getConnectedEndpoints() {
if !ep.endpointInGWNetwork() {
n = ep.getNetwork()
eIP = ep.Iface().Address()
}
}
}
for _, lb := range n.connectedLoadbalancers() {
// Skip if vip is not valid.
if len(lb.vip) == 0 {
continue
}
lb.service.Lock()
for _, be := range lb.backEnds {
if !be.disabled {
sb.addLBBackend(be.ip, lb.vip, lb.fwMark, lb.service.ingressPorts, eIP, gwIP, n.ingress)
}
}
lb.service.Unlock()
}
}
// Add loadbalancer backend to all sandboxes which has a connection to
// this network. If needed add the service as well.
func (n *network) addLBBackend(ip, vip net.IP, lb *loadBalancer, ingressPorts []*PortConfig) {
n.WalkEndpoints(func(e Endpoint) bool {
ep := e.(*endpoint)
if sb, ok := ep.getSandbox(); ok {
if !sb.isEndpointPopulated(ep) {
return false
}
var gwIP net.IP
if ep := sb.getGatewayEndpoint(); ep != nil {
gwIP = ep.Iface().Address().IP
}
sb.addLBBackend(ip, vip, lb.fwMark, ingressPorts, ep.Iface().Address(), gwIP, n.ingress)
}
return false
})
}
// Remove loadbalancer backend from all sandboxes which has a
// connection to this network. If needed remove the service entry as
// well, as specified by the rmService bool.
func (n *network) rmLBBackend(ip, vip net.IP, lb *loadBalancer, ingressPorts []*PortConfig, rmService bool, fullRemove bool) {
n.WalkEndpoints(func(e Endpoint) bool {
ep := e.(*endpoint)
if sb, ok := ep.getSandbox(); ok {
if !sb.isEndpointPopulated(ep) {
return false
}
var gwIP net.IP
if ep := sb.getGatewayEndpoint(); ep != nil {
gwIP = ep.Iface().Address().IP
}
sb.rmLBBackend(ip, vip, lb.fwMark, ingressPorts, ep.Iface().Address(), gwIP, rmService, fullRemove, n.ingress)
}
return false
})
}
// Add loadbalancer backend into one connected sandbox.
func (sb *sandbox) addLBBackend(ip, vip net.IP, fwMark uint32, ingressPorts []*PortConfig, eIP *net.IPNet, gwIP net.IP, isIngressNetwork bool) {
if sb.osSbox == nil {
return
}
if isIngressNetwork && !sb.ingress {
return
}
i, err := ipvs.New(sb.Key())
if err != nil {
logrus.Errorf("Failed to create an ipvs handle for sbox %s (%s,%s) for lb addition: %v", sb.ID()[0:7], sb.ContainerID()[0:7], sb.Key(), err)
return
}
defer i.Close()
s := &ipvs.Service{
AddressFamily: nl.FAMILY_V4,
FWMark: fwMark,
SchedName: ipvs.RoundRobin,
}
if !i.IsServicePresent(s) {
var filteredPorts []*PortConfig
if sb.ingress {
filteredPorts = filterPortConfigs(ingressPorts, false)
if err := programIngress(gwIP, filteredPorts, false); err != nil {
logrus.Errorf("Failed to add ingress: %v", err)
return
}
}
logrus.Debugf("Creating service for vip %s fwMark %d ingressPorts %#v in sbox %s (%s)", vip, fwMark, ingressPorts, sb.ID()[0:7], sb.ContainerID()[0:7])
if err := invokeFWMarker(sb.Key(), vip, fwMark, ingressPorts, eIP, false); err != nil {
logrus.Errorf("Failed to add firewall mark rule in sbox %s (%s): %v", sb.ID()[0:7], sb.ContainerID()[0:7], err)
return
}
if err := i.NewService(s); err != nil && err != syscall.EEXIST {
logrus.Errorf("Failed to create a new service for vip %s fwmark %d in sbox %s (%s): %v", vip, fwMark, sb.ID()[0:7], sb.ContainerID()[0:7], err)
return
}
}
d := &ipvs.Destination{
AddressFamily: nl.FAMILY_V4,
Address: ip,
Weight: 1,
}
// Remove the sched name before using the service to add
// destination.
s.SchedName = ""
if err := i.NewDestination(s, d); err != nil && err != syscall.EEXIST {
logrus.Errorf("Failed to create real server %s for vip %s fwmark %d in sbox %s (%s): %v", ip, vip, fwMark, sb.ID()[0:7], sb.ContainerID()[0:7], err)
}
}
// Remove loadbalancer backend from one connected sandbox.
func (sb *sandbox) rmLBBackend(ip, vip net.IP, fwMark uint32, ingressPorts []*PortConfig, eIP *net.IPNet, gwIP net.IP, rmService bool, fullRemove bool, isIngressNetwork bool) {
if sb.osSbox == nil {
return
}
if isIngressNetwork && !sb.ingress {
return
}
i, err := ipvs.New(sb.Key())
if err != nil {
logrus.Errorf("Failed to create an ipvs handle for sbox %s (%s,%s) for lb removal: %v", sb.ID()[0:7], sb.ContainerID()[0:7], sb.Key(), err)
return
}
defer i.Close()
s := &ipvs.Service{
AddressFamily: nl.FAMILY_V4,
FWMark: fwMark,
}
d := &ipvs.Destination{
AddressFamily: nl.FAMILY_V4,
Address: ip,
Weight: 1,
}
if fullRemove {
if err := i.DelDestination(s, d); err != nil && err != syscall.ENOENT {
logrus.Errorf("Failed to delete real server %s for vip %s fwmark %d in sbox %s (%s): %v", ip, vip, fwMark, sb.ID()[0:7], sb.ContainerID()[0:7], err)
}
} else {
d.Weight = 0
if err := i.UpdateDestination(s, d); err != nil && err != syscall.ENOENT {
logrus.Errorf("Failed to set LB weight of real server %s to 0 for vip %s fwmark %d in sbox %s (%s): %v", ip, vip, fwMark, sb.ID()[0:7], sb.ContainerID()[0:7], err)
}
}
if rmService {
s.SchedName = ipvs.RoundRobin
if err := i.DelService(s); err != nil && err != syscall.ENOENT {
logrus.Errorf("Failed to delete service for vip %s fwmark %d in sbox %s (%s): %v", vip, fwMark, sb.ID()[0:7], sb.ContainerID()[0:7], err)
}
var filteredPorts []*PortConfig
if sb.ingress {
filteredPorts = filterPortConfigs(ingressPorts, true)
if err := programIngress(gwIP, filteredPorts, true); err != nil {
logrus.Errorf("Failed to delete ingress: %v", err)
}
}
if err := invokeFWMarker(sb.Key(), vip, fwMark, ingressPorts, eIP, true); err != nil {
logrus.Errorf("Failed to delete firewall mark rule in sbox %s (%s): %v", sb.ID()[0:7], sb.ContainerID()[0:7], err)
}
}
}
const ingressChain = "DOCKER-INGRESS"
var (
ingressOnce sync.Once
ingressProxyMu sync.Mutex
ingressProxyTbl = make(map[string]io.Closer)
portConfigMu sync.Mutex
portConfigTbl = make(map[PortConfig]int)
)
func filterPortConfigs(ingressPorts []*PortConfig, isDelete bool) []*PortConfig {
portConfigMu.Lock()
iPorts := make([]*PortConfig, 0, len(ingressPorts))
for _, pc := range ingressPorts {
if isDelete {
if cnt, ok := portConfigTbl[*pc]; ok {
// This is the last reference to this
// port config. Delete the port config
// and add it to filtered list to be
// plumbed.
if cnt == 1 {
delete(portConfigTbl, *pc)
iPorts = append(iPorts, pc)
continue
}
portConfigTbl[*pc] = cnt - 1
}
continue
}
if cnt, ok := portConfigTbl[*pc]; ok {
portConfigTbl[*pc] = cnt + 1
continue
}
// We are adding it for the first time. Add it to the
// filter list to be plumbed.
portConfigTbl[*pc] = 1
iPorts = append(iPorts, pc)
}
portConfigMu.Unlock()
return iPorts
}
func programIngress(gwIP net.IP, ingressPorts []*PortConfig, isDelete bool) error {
addDelOpt := "-I"
if isDelete {
addDelOpt = "-D"
}
chainExists := iptables.ExistChain(ingressChain, iptables.Nat)
filterChainExists := iptables.ExistChain(ingressChain, iptables.Filter)
ingressOnce.Do(func() {
// Flush nat table and filter table ingress chain rules during init if it
// exists. It might contain stale rules from previous life.
if chainExists {
if err := iptables.RawCombinedOutput("-t", "nat", "-F", ingressChain); err != nil {
logrus.Errorf("Could not flush nat table ingress chain rules during init: %v", err)
}
}
if filterChainExists {
if err := iptables.RawCombinedOutput("-F", ingressChain); err != nil {
logrus.Errorf("Could not flush filter table ingress chain rules during init: %v", err)
}
}
})
if !isDelete {
if !chainExists {
if err := iptables.RawCombinedOutput("-t", "nat", "-N", ingressChain); err != nil {
return fmt.Errorf("failed to create ingress chain: %v", err)
}
}
if !filterChainExists {
if err := iptables.RawCombinedOutput("-N", ingressChain); err != nil {
return fmt.Errorf("failed to create filter table ingress chain: %v", err)
}
}
if !iptables.Exists(iptables.Nat, ingressChain, "-j", "RETURN") {
if err := iptables.RawCombinedOutput("-t", "nat", "-A", ingressChain, "-j", "RETURN"); err != nil {
return fmt.Errorf("failed to add return rule in nat table ingress chain: %v", err)
}
}
if !iptables.Exists(iptables.Filter, ingressChain, "-j", "RETURN") {
if err := iptables.RawCombinedOutput("-A", ingressChain, "-j", "RETURN"); err != nil {
return fmt.Errorf("failed to add return rule to filter table ingress chain: %v", err)
}
}
for _, chain := range []string{"OUTPUT", "PREROUTING"} {
if !iptables.Exists(iptables.Nat, chain, "-m", "addrtype", "--dst-type", "LOCAL", "-j", ingressChain) {
if err := iptables.RawCombinedOutput("-t", "nat", "-I", chain, "-m", "addrtype", "--dst-type", "LOCAL", "-j", ingressChain); err != nil {
return fmt.Errorf("failed to add jump rule in %s to ingress chain: %v", chain, err)
}
}
}
if !iptables.Exists(iptables.Filter, "FORWARD", "-j", ingressChain) {
if err := iptables.RawCombinedOutput("-I", "FORWARD", "-j", ingressChain); err != nil {
return fmt.Errorf("failed to add jump rule to %s in filter table forward chain: %v", ingressChain, err)
}
arrangeUserFilterRule()
}
oifName, err := findOIFName(gwIP)
if err != nil {
return fmt.Errorf("failed to find gateway bridge interface name for %s: %v", gwIP, err)
}
path := filepath.Join("/proc/sys/net/ipv4/conf", oifName, "route_localnet")
if err := ioutil.WriteFile(path, []byte{'1', '\n'}, 0644); err != nil {
return fmt.Errorf("could not write to %s: %v", path, err)
}
ruleArgs := strings.Fields(fmt.Sprintf("-m addrtype --src-type LOCAL -o %s -j MASQUERADE", oifName))
if !iptables.Exists(iptables.Nat, "POSTROUTING", ruleArgs...) {
if err := iptables.RawCombinedOutput(append([]string{"-t", "nat", "-I", "POSTROUTING"}, ruleArgs...)...); err != nil {
return fmt.Errorf("failed to add ingress localhost POSTROUTING rule for %s: %v", oifName, err)
}
}
}
for _, iPort := range ingressPorts {
if iptables.ExistChain(ingressChain, iptables.Nat) {
rule := strings.Fields(fmt.Sprintf("-t nat %s %s -p %s --dport %d -j DNAT --to-destination %s:%d",
addDelOpt, ingressChain, strings.ToLower(PortConfig_Protocol_name[int32(iPort.Protocol)]), iPort.PublishedPort, gwIP, iPort.PublishedPort))
if err := iptables.RawCombinedOutput(rule...); err != nil {
errStr := fmt.Sprintf("setting up rule failed, %v: %v", rule, err)
if !isDelete {
return fmt.Errorf("%s", errStr)
}
logrus.Infof("%s", errStr)
}
}
// Filter table rules to allow a published service to be accessible in the local node from..
// 1) service tasks attached to other networks
// 2) unmanaged containers on bridge networks
rule := strings.Fields(fmt.Sprintf("%s %s -m state -p %s --sport %d --state ESTABLISHED,RELATED -j ACCEPT",
addDelOpt, ingressChain, strings.ToLower(PortConfig_Protocol_name[int32(iPort.Protocol)]), iPort.PublishedPort))
if err := iptables.RawCombinedOutput(rule...); err != nil {
errStr := fmt.Sprintf("setting up rule failed, %v: %v", rule, err)
if !isDelete {
return fmt.Errorf("%s", errStr)
}
logrus.Warnf("%s", errStr)
}
rule = strings.Fields(fmt.Sprintf("%s %s -p %s --dport %d -j ACCEPT",
addDelOpt, ingressChain, strings.ToLower(PortConfig_Protocol_name[int32(iPort.Protocol)]), iPort.PublishedPort))
if err := iptables.RawCombinedOutput(rule...); err != nil {
errStr := fmt.Sprintf("setting up rule failed, %v: %v", rule, err)
if !isDelete {
return fmt.Errorf("%s", errStr)
}
logrus.Warnf("%s", errStr)
}
if err := plumbProxy(iPort, isDelete); err != nil {
logrus.Warnf("failed to create proxy for port %d: %v", iPort.PublishedPort, err)
}
}
return nil
}
// In the filter table FORWARD chain the first rule should be to jump to
// DOCKER-USER so the user is able to filter packet first.
// The second rule should be jump to INGRESS-CHAIN.
// This chain has the rules to allow access to the published ports for swarm tasks
// from local bridge networks and docker_gwbridge (ie:taks on other swarm netwroks)
func arrangeIngressFilterRule() {
if iptables.ExistChain(ingressChain, iptables.Filter) {
if iptables.Exists(iptables.Filter, "FORWARD", "-j", ingressChain) {
if err := iptables.RawCombinedOutput("-D", "FORWARD", "-j", ingressChain); err != nil {
logrus.Warnf("failed to delete jump rule to ingressChain in filter table: %v", err)
}
}
if err := iptables.RawCombinedOutput("-I", "FORWARD", "-j", ingressChain); err != nil {
logrus.Warnf("failed to add jump rule to ingressChain in filter table: %v", err)
}
}
}
func findOIFName(ip net.IP) (string, error) {
nlh := ns.NlHandle()
routes, err := nlh.RouteGet(ip)
if err != nil {
return "", err
}
if len(routes) == 0 {
return "", fmt.Errorf("no route to %s", ip)
}
// Pick the first route(typically there is only one route). We
// don't support multipath.
link, err := nlh.LinkByIndex(routes[0].LinkIndex)
if err != nil {
return "", err
}
return link.Attrs().Name, nil
}
func plumbProxy(iPort *PortConfig, isDelete bool) error {
var (
err error
l io.Closer
)
portSpec := fmt.Sprintf("%d/%s", iPort.PublishedPort, strings.ToLower(PortConfig_Protocol_name[int32(iPort.Protocol)]))
if isDelete {
ingressProxyMu.Lock()
if listener, ok := ingressProxyTbl[portSpec]; ok {
if listener != nil {
listener.Close()
}
}
ingressProxyMu.Unlock()
return nil
}
switch iPort.Protocol {
case ProtocolTCP:
l, err = net.ListenTCP("tcp", &net.TCPAddr{Port: int(iPort.PublishedPort)})
case ProtocolUDP:
l, err = net.ListenUDP("udp", &net.UDPAddr{Port: int(iPort.PublishedPort)})
case ProtocolSCTP:
l, err = sctp.ListenSCTP("sctp", &sctp.SCTPAddr{Port: int(iPort.PublishedPort)})
default:
err = fmt.Errorf("unknown protocol %v", iPort.Protocol)
}
if err != nil {
return err
}
ingressProxyMu.Lock()
ingressProxyTbl[portSpec] = l
ingressProxyMu.Unlock()
return nil
}
func writePortsToFile(ports []*PortConfig) (string, error) {
f, err := ioutil.TempFile("", "port_configs")
if err != nil {
return "", err
}
defer f.Close()
buf, _ := proto.Marshal(&EndpointRecord{
IngressPorts: ports,
})
n, err := f.Write(buf)
if err != nil {
return "", err
}
if n < len(buf) {
return "", io.ErrShortWrite
}
return f.Name(), nil
}
func readPortsFromFile(fileName string) ([]*PortConfig, error) {
buf, err := ioutil.ReadFile(fileName)
if err != nil {
return nil, err
}
var epRec EndpointRecord
err = proto.Unmarshal(buf, &epRec)
if err != nil {
return nil, err
}
return epRec.IngressPorts, nil
}
// Invoke fwmarker reexec routine to mark vip destined packets with
// the passed firewall mark.
func invokeFWMarker(path string, vip net.IP, fwMark uint32, ingressPorts []*PortConfig, eIP *net.IPNet, isDelete bool) error {
var ingressPortsFile string
if len(ingressPorts) != 0 {
var err error
ingressPortsFile, err = writePortsToFile(ingressPorts)
if err != nil {
return err
}
defer os.Remove(ingressPortsFile)
}
addDelOpt := "-A"
if isDelete {
addDelOpt = "-D"
}
cmd := &exec.Cmd{
Path: reexec.Self(),
Args: append([]string{"fwmarker"}, path, vip.String(), fmt.Sprintf("%d", fwMark), addDelOpt, ingressPortsFile, eIP.String()),
Stdout: os.Stdout,
Stderr: os.Stderr,
}
if err := cmd.Run(); err != nil {
return fmt.Errorf("reexec failed: %v", err)
}
return nil
}
// Firewall marker reexec function.
func fwMarker() {
runtime.LockOSThread()
defer runtime.UnlockOSThread()
if len(os.Args) < 7 {
logrus.Error("invalid number of arguments..")
os.Exit(1)
}
var ingressPorts []*PortConfig
if os.Args[5] != "" {
var err error
ingressPorts, err = readPortsFromFile(os.Args[5])
if err != nil {
logrus.Errorf("Failed reading ingress ports file: %v", err)
os.Exit(6)
}
}
vip := os.Args[2]
fwMark, err := strconv.ParseUint(os.Args[3], 10, 32)
if err != nil {
logrus.Errorf("bad fwmark value(%s) passed: %v", os.Args[3], err)
os.Exit(2)
}
addDelOpt := os.Args[4]
rules := [][]string{}
for _, iPort := range ingressPorts {
rule := strings.Fields(fmt.Sprintf("-t mangle %s PREROUTING -p %s --dport %d -j MARK --set-mark %d",
addDelOpt, strings.ToLower(PortConfig_Protocol_name[int32(iPort.Protocol)]), iPort.PublishedPort, fwMark))
rules = append(rules, rule)
}
ns, err := netns.GetFromPath(os.Args[1])
if err != nil {
logrus.Errorf("failed get network namespace %q: %v", os.Args[1], err)
os.Exit(3)
}
defer ns.Close()
if err := netns.Set(ns); err != nil {
logrus.Errorf("setting into container net ns %v failed, %v", os.Args[1], err)
os.Exit(4)
}
if addDelOpt == "-A" {
eIP, subnet, err := net.ParseCIDR(os.Args[6])
if err != nil {
logrus.Errorf("Failed to parse endpoint IP %s: %v", os.Args[6], err)
os.Exit(9)
}
ruleParams := strings.Fields(fmt.Sprintf("-m ipvs --ipvs -d %s -j SNAT --to-source %s", subnet, eIP))
if !iptables.Exists("nat", "POSTROUTING", ruleParams...) {
rule := append(strings.Fields("-t nat -A POSTROUTING"), ruleParams...)
rules = append(rules, rule)
err := ioutil.WriteFile("/proc/sys/net/ipv4/vs/conntrack", []byte{'1', '\n'}, 0644)
if err != nil {
logrus.Errorf("Failed to write to /proc/sys/net/ipv4/vs/conntrack: %v", err)
os.Exit(8)
}
}
}
rule := strings.Fields(fmt.Sprintf("-t mangle %s OUTPUT -d %s/32 -j MARK --set-mark %d", addDelOpt, vip, fwMark))
rules = append(rules, rule)
rule = strings.Fields(fmt.Sprintf("-t nat %s OUTPUT -p icmp --icmp echo-request -d %s -j DNAT --to 127.0.0.1", addDelOpt, vip))
rules = append(rules, rule)
for _, rule := range rules {
if err := iptables.RawCombinedOutputNative(rule...); err != nil {
logrus.Errorf("setting up rule failed, %v: %v", rule, err)
os.Exit(5)
}
}
}
func addRedirectRules(path string, eIP *net.IPNet, ingressPorts []*PortConfig) error {
var ingressPortsFile string
if len(ingressPorts) != 0 {
var err error
ingressPortsFile, err = writePortsToFile(ingressPorts)
if err != nil {
return err
}
defer os.Remove(ingressPortsFile)
}
cmd := &exec.Cmd{
Path: reexec.Self(),
Args: append([]string{"redirecter"}, path, eIP.String(), ingressPortsFile),
Stdout: os.Stdout,
Stderr: os.Stderr,
}
if err := cmd.Run(); err != nil {
return fmt.Errorf("reexec failed: %v", err)
}
return nil
}
// Redirecter reexec function.
func redirecter() {
runtime.LockOSThread()
defer runtime.UnlockOSThread()
if len(os.Args) < 4 {
logrus.Error("invalid number of arguments..")
os.Exit(1)
}
var ingressPorts []*PortConfig
if os.Args[3] != "" {
var err error
ingressPorts, err = readPortsFromFile(os.Args[3])
if err != nil {
logrus.Errorf("Failed reading ingress ports file: %v", err)
os.Exit(2)
}
}
eIP, _, err := net.ParseCIDR(os.Args[2])
if err != nil {
logrus.Errorf("Failed to parse endpoint IP %s: %v", os.Args[2], err)
os.Exit(3)
}
rules := [][]string{}
for _, iPort := range ingressPorts {
rule := strings.Fields(fmt.Sprintf("-t nat -A PREROUTING -d %s -p %s --dport %d -j REDIRECT --to-port %d",
eIP.String(), strings.ToLower(PortConfig_Protocol_name[int32(iPort.Protocol)]), iPort.PublishedPort, iPort.TargetPort))
rules = append(rules, rule)
// Allow only incoming connections to exposed ports
iRule := strings.Fields(fmt.Sprintf("-I INPUT -d %s -p %s --dport %d -m conntrack --ctstate NEW,ESTABLISHED -j ACCEPT",
eIP.String(), strings.ToLower(PortConfig_Protocol_name[int32(iPort.Protocol)]), iPort.TargetPort))
rules = append(rules, iRule)
// Allow only outgoing connections from exposed ports
oRule := strings.Fields(fmt.Sprintf("-I OUTPUT -s %s -p %s --sport %d -m conntrack --ctstate ESTABLISHED -j ACCEPT",
eIP.String(), strings.ToLower(PortConfig_Protocol_name[int32(iPort.Protocol)]), iPort.TargetPort))
rules = append(rules, oRule)
}
ns, err := netns.GetFromPath(os.Args[1])
if err != nil {
logrus.Errorf("failed get network namespace %q: %v", os.Args[1], err)
os.Exit(4)
}
defer ns.Close()
if err := netns.Set(ns); err != nil {
logrus.Errorf("setting into container net ns %v failed, %v", os.Args[1], err)
os.Exit(5)
}
for _, rule := range rules {
if err := iptables.RawCombinedOutputNative(rule...); err != nil {
logrus.Errorf("setting up rule failed, %v: %v", rule, err)
os.Exit(6)
}
}
if len(ingressPorts) == 0 {
return
}
// Ensure blocking rules for anything else in/to ingress network
for _, rule := range [][]string{
{"-d", eIP.String(), "-p", "sctp", "-j", "DROP"},
{"-d", eIP.String(), "-p", "udp", "-j", "DROP"},
{"-d", eIP.String(), "-p", "tcp", "-j", "DROP"},
} {
if !iptables.ExistsNative(iptables.Filter, "INPUT", rule...) {
if err := iptables.RawCombinedOutputNative(append([]string{"-A", "INPUT"}, rule...)...); err != nil {
logrus.Errorf("setting up rule failed, %v: %v", rule, err)
os.Exit(7)
}
}
rule[0] = "-s"
if !iptables.ExistsNative(iptables.Filter, "OUTPUT", rule...) {
if err := iptables.RawCombinedOutputNative(append([]string{"-A", "OUTPUT"}, rule...)...); err != nil {
logrus.Errorf("setting up rule failed, %v: %v", rule, err)
os.Exit(8)
}
}
}
}