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tailscale/cmd/containerboot/services.go

572 lines
20 KiB
Go

cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
// Copyright (c) Tailscale Inc & AUTHORS
// SPDX-License-Identifier: BSD-3-Clause
//go:build linux
package main
import (
"context"
"encoding/json"
"errors"
"fmt"
"log"
"net/netip"
"os"
"path/filepath"
"reflect"
"strings"
"time"
"github.com/fsnotify/fsnotify"
"tailscale.com/ipn"
"tailscale.com/kube/egressservices"
"tailscale.com/kube/kubeclient"
"tailscale.com/tailcfg"
"tailscale.com/util/linuxfw"
"tailscale.com/util/mak"
)
const tailscaleTunInterface = "tailscale0"
// This file contains functionality to run containerboot as a proxy that can
// route cluster traffic to one or more tailnet targets, based on portmapping
// rules read from a configfile. Currently (9/2024) this is only used for the
// Kubernetes operator egress proxies.
// egressProxy knows how to configure firewall rules to route cluster traffic to
// one or more tailnet services.
type egressProxy struct {
cfgPath string // path to egress service config file
nfr linuxfw.NetfilterRunner // never nil
kc kubeclient.Client // never nil
stateSecret string // name of the kube state Secret
netmapChan chan ipn.Notify // chan to receive netmap updates on
podIPv4 string // never empty string, currently only IPv4 is supported
cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
// tailnetFQDNs is the egress service FQDN to tailnet IP mappings that
// were last used to configure firewall rules for this proxy.
// TODO(irbekrm): target addresses are also stored in the state Secret.
// Evaluate whether we should retrieve them from there and not store in
// memory at all.
targetFQDNs map[string][]netip.Prefix
// used to configure firewall rules.
tailnetAddrs []netip.Prefix
}
// run configures egress proxy firewall rules and ensures that the firewall rules are reconfigured when:
// - the mounted egress config has changed
// - the proxy's tailnet IP addresses have changed
// - tailnet IPs have changed for any backend targets specified by tailnet FQDN
func (ep *egressProxy) run(ctx context.Context, n ipn.Notify) error {
var tickChan <-chan time.Time
var eventChan <-chan fsnotify.Event
// TODO (irbekrm): take a look if this can be pulled into a single func
// shared with serve config loader.
if w, err := fsnotify.NewWatcher(); err != nil {
log.Printf("failed to create fsnotify watcher, timer-only mode: %v", err)
ticker := time.NewTicker(5 * time.Second)
defer ticker.Stop()
tickChan = ticker.C
} else {
defer w.Close()
if err := w.Add(filepath.Dir(ep.cfgPath)); err != nil {
return fmt.Errorf("failed to add fsnotify watch: %w", err)
}
eventChan = w.Events
}
if err := ep.sync(ctx, n); err != nil {
return err
}
for {
var err error
select {
case <-ctx.Done():
return nil
case <-tickChan:
err = ep.sync(ctx, n)
case <-eventChan:
log.Printf("config file change detected, ensuring firewall config is up to date...")
err = ep.sync(ctx, n)
case n = <-ep.netmapChan:
shouldResync := ep.shouldResync(n)
if shouldResync {
log.Printf("netmap change detected, ensuring firewall config is up to date...")
err = ep.sync(ctx, n)
}
}
if err != nil {
return fmt.Errorf("error syncing egress service config: %w", err)
}
}
}
// sync triggers an egress proxy config resync. The resync calculates the diff between config and status to determine if
// any firewall rules need to be updated. Currently using status in state Secret as a reference for what is the current
// firewall configuration is good enough because - the status is keyed by the Pod IP - we crash the Pod on errors such
// as failed firewall update
func (ep *egressProxy) sync(ctx context.Context, n ipn.Notify) error {
cfgs, err := ep.getConfigs()
if err != nil {
return fmt.Errorf("error retrieving egress service configs: %w", err)
}
status, err := ep.getStatus(ctx)
if err != nil {
return fmt.Errorf("error retrieving current egress proxy status: %w", err)
}
newStatus, err := ep.syncEgressConfigs(cfgs, status, n)
if err != nil {
return fmt.Errorf("error syncing egress service configs: %w", err)
}
if !servicesStatusIsEqual(newStatus, status) {
if err := ep.setStatus(ctx, newStatus, n); err != nil {
return fmt.Errorf("error setting egress proxy status: %w", err)
}
}
return nil
}
// addrsHaveChanged returns true if the provided netmap update contains tailnet address change for this proxy node.
// Netmap must not be nil.
func (ep *egressProxy) addrsHaveChanged(n ipn.Notify) bool {
return !reflect.DeepEqual(ep.tailnetAddrs, n.NetMap.SelfNode.Addresses())
}
// syncEgressConfigs adds and deletes firewall rules to match the desired
// configuration. It uses the provided status to determine what is currently
// applied and updates the status after a successful sync.
func (ep *egressProxy) syncEgressConfigs(cfgs *egressservices.Configs, status *egressservices.Status, n ipn.Notify) (*egressservices.Status, error) {
if !(wantsServicesConfigured(cfgs) || hasServicesConfigured(status)) {
return nil, nil
}
// Delete unnecessary services.
if err := ep.deleteUnnecessaryServices(cfgs, status); err != nil {
return nil, fmt.Errorf("error deleting services: %w", err)
}
newStatus := &egressservices.Status{}
if !wantsServicesConfigured(cfgs) {
return newStatus, nil
}
// Add new services, update rules for any that have changed.
rulesPerSvcToAdd := make(map[string][]rule, 0)
rulesPerSvcToDelete := make(map[string][]rule, 0)
for svcName, cfg := range *cfgs {
tailnetTargetIPs, err := ep.tailnetTargetIPsForSvc(cfg, n)
if err != nil {
return nil, fmt.Errorf("error determining tailnet target IPs: %w", err)
}
rulesToAdd, rulesToDelete, err := updatesForCfg(svcName, cfg, status, tailnetTargetIPs)
if err != nil {
return nil, fmt.Errorf("error validating service changes: %v", err)
}
log.Printf("syncegressservices: looking at svc %s rulesToAdd %d rulesToDelete %d", svcName, len(rulesToAdd), len(rulesToDelete))
if len(rulesToAdd) != 0 {
mak.Set(&rulesPerSvcToAdd, svcName, rulesToAdd)
}
if len(rulesToDelete) != 0 {
mak.Set(&rulesPerSvcToDelete, svcName, rulesToDelete)
}
if len(rulesToAdd) != 0 || ep.addrsHaveChanged(n) {
// For each tailnet target, set up SNAT from the local tailnet device address of the matching
// family.
for _, t := range tailnetTargetIPs {
var local netip.Addr
for _, pfx := range n.NetMap.SelfNode.Addresses().All() {
if !pfx.IsSingleIP() {
continue
}
if pfx.Addr().Is4() != t.Is4() {
continue
}
local = pfx.Addr()
break
}
if !local.IsValid() {
return nil, fmt.Errorf("no valid local IP: %v", local)
}
if err := ep.nfr.EnsureSNATForDst(local, t); err != nil {
cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
return nil, fmt.Errorf("error setting up SNAT rule: %w", err)
}
}
}
// Update the status. Status will be written back to the state Secret by the caller.
mak.Set(&newStatus.Services, svcName, &egressservices.ServiceStatus{TailnetTargetIPs: tailnetTargetIPs, TailnetTarget: cfg.TailnetTarget, Ports: cfg.Ports})
}
// Actually apply the firewall rules.
if err := ensureRulesAdded(rulesPerSvcToAdd, ep.nfr); err != nil {
return nil, fmt.Errorf("error adding rules: %w", err)
}
if err := ensureRulesDeleted(rulesPerSvcToDelete, ep.nfr); err != nil {
return nil, fmt.Errorf("error deleting rules: %w", err)
}
return newStatus, nil
}
// updatesForCfg calculates any rules that need to be added or deleted for an individucal egress service config.
func updatesForCfg(svcName string, cfg egressservices.Config, status *egressservices.Status, tailnetTargetIPs []netip.Addr) ([]rule, []rule, error) {
rulesToAdd := make([]rule, 0)
rulesToDelete := make([]rule, 0)
currentConfig, ok := lookupCurrentConfig(svcName, status)
// If no rules for service are present yet, add them all.
if !ok {
for _, t := range tailnetTargetIPs {
for ports := range cfg.Ports {
log.Printf("syncegressservices: svc %s adding port %v", svcName, ports)
rulesToAdd = append(rulesToAdd, rule{tailnetPort: ports.TargetPort, containerPort: ports.MatchPort, protocol: ports.Protocol, tailnetIP: t})
}
}
return rulesToAdd, rulesToDelete, nil
}
// If there are no backend targets available, delete any currently configured rules.
if len(tailnetTargetIPs) == 0 {
log.Printf("tailnet target for egress service %s does not have any backend addresses, deleting all rules", svcName)
for _, ip := range currentConfig.TailnetTargetIPs {
for ports := range currentConfig.Ports {
rulesToDelete = append(rulesToAdd, rule{tailnetPort: ports.TargetPort, containerPort: ports.MatchPort, protocol: ports.Protocol, tailnetIP: ip})
}
}
return rulesToAdd, rulesToDelete, nil
}
// If there are rules present for backend targets that no longer match, delete them.
for _, ip := range currentConfig.TailnetTargetIPs {
var found bool
for _, wantsIP := range tailnetTargetIPs {
if reflect.DeepEqual(ip, wantsIP) {
found = true
break
}
}
if !found {
for ports := range currentConfig.Ports {
rulesToDelete = append(rulesToDelete, rule{tailnetPort: ports.TargetPort, containerPort: ports.MatchPort, protocol: ports.Protocol, tailnetIP: ip})
}
}
}
// Sync rules for the currently wanted backend targets.
for _, ip := range tailnetTargetIPs {
// If the backend target is not yet present in status, add all rules.
var found bool
for _, gotIP := range currentConfig.TailnetTargetIPs {
if reflect.DeepEqual(ip, gotIP) {
found = true
break
}
}
if !found {
for ports := range cfg.Ports {
rulesToAdd = append(rulesToAdd, rule{tailnetPort: ports.TargetPort, containerPort: ports.MatchPort, protocol: ports.Protocol, tailnetIP: ip})
}
continue
}
// If the backend target is present in status, check that the
// currently applied rules are up to date.
// Delete any current portmappings that are no longer present in config.
for port := range currentConfig.Ports {
if _, ok := cfg.Ports[port]; ok {
continue
}
rulesToDelete = append(rulesToDelete, rule{tailnetPort: port.TargetPort, containerPort: port.MatchPort, protocol: port.Protocol, tailnetIP: ip})
}
// Add any new portmappings.
for port := range cfg.Ports {
if _, ok := currentConfig.Ports[port]; ok {
continue
}
rulesToAdd = append(rulesToAdd, rule{tailnetPort: port.TargetPort, containerPort: port.MatchPort, protocol: port.Protocol, tailnetIP: ip})
}
}
return rulesToAdd, rulesToDelete, nil
}
// deleteUnneccessaryServices ensure that any services found on status, but not
// present in config are deleted.
func (ep *egressProxy) deleteUnnecessaryServices(cfgs *egressservices.Configs, status *egressservices.Status) error {
if !hasServicesConfigured(status) {
return nil
}
if !wantsServicesConfigured(cfgs) {
for svcName, svc := range status.Services {
log.Printf("service %s is no longer required, deleting", svcName)
if err := ensureServiceDeleted(svcName, svc, ep.nfr); err != nil {
return fmt.Errorf("error deleting service %s: %w", svcName, err)
}
}
return nil
}
for svcName, svc := range status.Services {
if _, ok := (*cfgs)[svcName]; !ok {
log.Printf("service %s is no longer required, deleting", svcName)
if err := ensureServiceDeleted(svcName, svc, ep.nfr); err != nil {
return fmt.Errorf("error deleting service %s: %w", svcName, err)
}
// TODO (irbekrm): also delete the SNAT rule here
}
}
return nil
}
// getConfigs gets the mounted egress service configuration.
func (ep *egressProxy) getConfigs() (*egressservices.Configs, error) {
j, err := os.ReadFile(ep.cfgPath)
if os.IsNotExist(err) {
return nil, nil
}
if err != nil {
return nil, err
}
if len(j) == 0 || string(j) == "" {
return nil, nil
}
cfg := &egressservices.Configs{}
if err := json.Unmarshal(j, &cfg); err != nil {
return nil, err
}
return cfg, nil
}
// getStatus gets the current status of the configured firewall. The current
// status is stored in state Secret. Returns nil status if no status that
// applies to the current proxy Pod was found. Uses the Pod IP to determine if a
// status found in the state Secret applies to this proxy Pod.
func (ep *egressProxy) getStatus(ctx context.Context) (*egressservices.Status, error) {
secret, err := ep.kc.GetSecret(ctx, ep.stateSecret)
if err != nil {
return nil, fmt.Errorf("error retrieving state secret: %w", err)
}
status := &egressservices.Status{}
raw, ok := secret.Data[egressservices.KeyEgressServices]
if !ok {
return nil, nil
}
if err := json.Unmarshal([]byte(raw), status); err != nil {
return nil, fmt.Errorf("error unmarshalling previous config: %w", err)
}
if reflect.DeepEqual(status.PodIPv4, ep.podIPv4) {
cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
return status, nil
}
return nil, nil
}
// setStatus writes egress proxy's currently configured firewall to the state
// Secret and updates proxy's tailnet addresses.
func (ep *egressProxy) setStatus(ctx context.Context, status *egressservices.Status, n ipn.Notify) error {
// Pod IP is used to determine if a stored status applies to THIS proxy Pod.
if status == nil {
status = &egressservices.Status{}
}
status.PodIPv4 = ep.podIPv4
cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
secret, err := ep.kc.GetSecret(ctx, ep.stateSecret)
if err != nil {
return fmt.Errorf("error retrieving state Secret: %w", err)
}
bs, err := json.Marshal(status)
if err != nil {
return fmt.Errorf("error marshalling service config: %w", err)
}
secret.Data[egressservices.KeyEgressServices] = bs
patch := kubeclient.JSONPatch{
Op: "replace",
Path: fmt.Sprintf("/data/%s", egressservices.KeyEgressServices),
Value: bs,
}
if err := ep.kc.JSONPatchSecret(ctx, ep.stateSecret, []kubeclient.JSONPatch{patch}); err != nil {
return fmt.Errorf("error patching state Secret: %w", err)
}
ep.tailnetAddrs = n.NetMap.SelfNode.Addresses().AsSlice()
return nil
}
// tailnetTargetIPsForSvc returns the tailnet IPs to which traffic for this
// egress service should be proxied. The egress service can be configured by IP
// or by FQDN. If it's configured by IP, just return that. If it's configured by
// FQDN, resolve the FQDN and return the resolved IPs. It checks if the
// netfilter runner supports IPv6 NAT and skips any IPv6 addresses if it
// doesn't.
cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
func (ep *egressProxy) tailnetTargetIPsForSvc(svc egressservices.Config, n ipn.Notify) (addrs []netip.Addr, err error) {
if svc.TailnetTarget.IP != "" {
addr, err := netip.ParseAddr(svc.TailnetTarget.IP)
if err != nil {
return nil, fmt.Errorf("error parsing tailnet target IP: %w", err)
}
if addr.Is6() && !ep.nfr.HasIPV6NAT() {
log.Printf("tailnet target is an IPv6 address, but this host does not support IPv6 in the chosen firewall mode. This will probably not work.")
return addrs, nil
}
cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
return []netip.Addr{addr}, nil
}
if svc.TailnetTarget.FQDN == "" {
return nil, errors.New("unexpected egress service config- neither tailnet target IP nor FQDN is set")
}
if n.NetMap == nil {
log.Printf("netmap is not available, unable to determine backend addresses for %s", svc.TailnetTarget.FQDN)
return addrs, nil
}
var (
node tailcfg.NodeView
nodeFound bool
)
for _, nn := range n.NetMap.Peers {
if equalFQDNs(nn.Name(), svc.TailnetTarget.FQDN) {
node = nn
nodeFound = true
break
}
}
if nodeFound {
for _, addr := range node.Addresses().AsSlice() {
if addr.Addr().Is6() && !ep.nfr.HasIPV6NAT() {
log.Printf("tailnet target %v is an IPv6 address, but this host does not support IPv6 in the chosen firewall mode, skipping.", addr.Addr().String())
continue
}
cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
addrs = append(addrs, addr.Addr())
}
// Egress target endpoints configured via FQDN are stored, so
// that we can determine if a netmap update should trigger a
// resync.
mak.Set(&ep.targetFQDNs, svc.TailnetTarget.FQDN, node.Addresses().AsSlice())
}
return addrs, nil
}
// shouldResync parses netmap update and returns true if the update contains
// changes for which the egress proxy's firewall should be reconfigured.
func (ep *egressProxy) shouldResync(n ipn.Notify) bool {
if n.NetMap == nil {
return false
}
// If proxy's tailnet addresses have changed, resync.
if !reflect.DeepEqual(n.NetMap.SelfNode.Addresses().AsSlice(), ep.tailnetAddrs) {
log.Printf("node addresses have changed, trigger egress config resync")
ep.tailnetAddrs = n.NetMap.SelfNode.Addresses().AsSlice()
return true
}
// If the IPs for any of the egress services configured via FQDN have
// changed, resync.
for fqdn, ips := range ep.targetFQDNs {
for _, nn := range n.NetMap.Peers {
if equalFQDNs(nn.Name(), fqdn) {
if !reflect.DeepEqual(ips, nn.Addresses().AsSlice()) {
log.Printf("backend addresses for egress target %q have changed old IPs %v, new IPs %v trigger egress config resync", nn.Name(), ips, nn.Addresses().AsSlice())
}
return true
}
}
}
return false
}
// ensureServiceDeleted ensures that any rules for an egress service are removed
// from the firewall configuration.
func ensureServiceDeleted(svcName string, svc *egressservices.ServiceStatus, nfr linuxfw.NetfilterRunner) error {
// Note that the portmap is needed for iptables based firewall only.
// Nftables group rules for a service in a chain, so there is no need to
// specify individual portmapping based rules.
pms := make([]linuxfw.PortMap, 0)
for pm := range svc.Ports {
pms = append(pms, linuxfw.PortMap{MatchPort: pm.MatchPort, TargetPort: pm.TargetPort, Protocol: pm.Protocol})
}
if err := nfr.DeleteSvc(svcName, tailscaleTunInterface, svc.TailnetTargetIPs, pms); err != nil {
return fmt.Errorf("error deleting service %s: %w", svcName, err)
}
return nil
}
// ensureRulesAdded ensures that all portmapping rules are added to the firewall
// configuration. For any rules that already exist, calling this function is a
// no-op. In case of nftables, a service consists of one or two (one per IP
// family) chains that conain the portmapping rules for the service and the
// chains as needed when this function is called.
func ensureRulesAdded(rulesPerSvc map[string][]rule, nfr linuxfw.NetfilterRunner) error {
for svc, rules := range rulesPerSvc {
for _, rule := range rules {
log.Printf("ensureRulesAdded svc %s tailnetTarget %s container port %d tailnet port %d protocol %s", svc, rule.tailnetIP, rule.containerPort, rule.tailnetPort, rule.protocol)
if err := nfr.EnsurePortMapRuleForSvc(svc, tailscaleTunInterface, rule.tailnetIP, linuxfw.PortMap{MatchPort: rule.containerPort, TargetPort: rule.tailnetPort, Protocol: rule.protocol}); err != nil {
return fmt.Errorf("error ensuring rule: %w", err)
}
}
}
return nil
}
// ensureRulesDeleted ensures that the given rules are deleted from the firewall
// configuration. For any rules that do not exist, calling this funcion is a
// no-op.
func ensureRulesDeleted(rulesPerSvc map[string][]rule, nfr linuxfw.NetfilterRunner) error {
for svc, rules := range rulesPerSvc {
for _, rule := range rules {
log.Printf("ensureRulesDeleted svc %s tailnetTarget %s container port %d tailnet port %d protocol %s", svc, rule.tailnetIP, rule.containerPort, rule.tailnetPort, rule.protocol)
if err := nfr.DeletePortMapRuleForSvc(svc, tailscaleTunInterface, rule.tailnetIP, linuxfw.PortMap{MatchPort: rule.containerPort, TargetPort: rule.tailnetPort, Protocol: rule.protocol}); err != nil {
return fmt.Errorf("error deleting rule: %w", err)
}
}
}
return nil
}
func lookupCurrentConfig(svcName string, status *egressservices.Status) (*egressservices.ServiceStatus, bool) {
if status == nil || len(status.Services) == 0 {
return nil, false
}
c, ok := status.Services[svcName]
return c, ok
}
func equalFQDNs(s, s1 string) bool {
s, _ = strings.CutSuffix(s, ".")
s1, _ = strings.CutSuffix(s1, ".")
return strings.EqualFold(s, s1)
}
// rule contains configuration for an egress proxy firewall rule.
type rule struct {
containerPort uint16 // port to match incoming traffic
tailnetPort uint16 // tailnet service port
tailnetIP netip.Addr // tailnet service IP
protocol string
}
func wantsServicesConfigured(cfgs *egressservices.Configs) bool {
return cfgs != nil && len(*cfgs) != 0
}
func hasServicesConfigured(status *egressservices.Status) bool {
return status != nil && len(status.Services) != 0
}
func servicesStatusIsEqual(st, st1 *egressservices.Status) bool {
if st == nil && st1 == nil {
return true
}
if st == nil || st1 == nil {
return false
}
st.PodIPv4 = ""
st1.PodIPv4 = ""
cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets (#13531) * cmd/containerboot,kube,util/linuxfw: configure kube egress proxies to route to 1+ tailnet targets This commit is first part of the work to allow running multiple replicas of the Kubernetes operator egress proxies per tailnet service + to allow exposing multiple tailnet services via each proxy replica. This expands the existing iptables/nftables-based proxy configuration mechanism. A proxy can now be configured to route to one or more tailnet targets via a (mounted) config file that, for each tailnet target, specifies: - the target's tailnet IP or FQDN - mappings of container ports to which cluster workloads will send traffic to tailnet target ports where the traffic should be forwarded. Example configfile contents: { "some-svc": {"tailnetTarget":{"fqdn":"foo.tailnetxyz.ts.net","ports"{"tcp:4006:80":{"protocol":"tcp","matchPort":4006,"targetPort":80},"tcp:4007:443":{"protocol":"tcp","matchPort":4007,"targetPort":443}}}} } A proxy that is configured with this config file will configure firewall rules to route cluster traffic to the tailnet targets. It will then watch the config file for updates as well as monitor relevant netmap updates and reconfigure firewall as needed. This adds a bunch of new iptables/nftables functionality to make it easier to dynamically update the firewall rules without needing to restart the proxy Pod as well as to make it easier to debug/understand the rules: - for iptables, each portmapping is a DNAT rule with a comment pointing at the 'service',i.e: -A PREROUTING ! -i tailscale0 -p tcp -m tcp --dport 4006 -m comment --comment "some-svc:tcp:4006 -> tcp:80" -j DNAT --to-destination 100.64.1.18:80 Additionally there is a SNAT rule for each tailnet target, to mask the source address. - for nftables, a separate prerouting chain is created for each tailnet target and all the portmapping rules are placed in that chain. This makes it easier to look up rules and delete services when no longer needed. (nftables allows hooking a custom chain to a prerouting hook, so no extra work is needed to ensure that the rules in the service chains are evaluated). The next steps will be to get the Kubernetes Operator to generate the configfile and ensure it is mounted to the relevant proxy nodes. Updates tailscale/tailscale#13406 Signed-off-by: Irbe Krumina <irbe@tailscale.com>
1 month ago
return reflect.DeepEqual(*st, *st1)
}