metropolis/node/core/clusternet/clusternet.go - monogon - Gitiles

 // Package clusternet implements a Cluster Networking mesh service running on all
 // Metropolis nodes.
 //
 // The mesh is based on wireguard and a centralized configuration store in the
 // cluster Curator (in etcd).
 //
 // While the implementation is nearly generic, it currently makes an assumption
 // that it is used only for Kubernetes pod networking. That has a few
 // implications:
 //
 // First, we only have a single real route on the host into the wireguard
 // networking mesh / interface, and that is configured ahead of time in the
 // Service as ClusterNet. All destination addresses that should be carried by the
 // mesh must thus be part of this single route. Otherwise, traffic will be able
 // to flow into the node from other nodes, but will exit through another
 // interface. This is used in practice to allow other host nodes (whose external
 // addresses are outside the cluster network) to access the cluster network.
 //
 // Second, we have two hardcoded/purpose-specific sources of prefixes:
 //  1. Pod networking node prefixes from the kubelet
 //  2. The host's external IP address (as a /32) from the network service.
 package clusternet

 import (
 	"context"
 	"fmt"
 	"net"
 	"net/netip"

 	"github.com/cenkalti/backoff/v4"

 	"source.monogon.dev/metropolis/node/core/localstorage"
 	"source.monogon.dev/metropolis/node/core/network"
 	"source.monogon.dev/metropolis/pkg/event"
 	"source.monogon.dev/metropolis/pkg/supervisor"

 	apb "source.monogon.dev/metropolis/node/core/curator/proto/api"
 	cpb "source.monogon.dev/metropolis/proto/common"
 )

 // Service implements the Cluster Networking Mesh. See package-level docs for
 // more details.
 type Service struct {
 	// Curator is the gRPC client that the service will use to reach the cluster's
 	// Curator, for pushing locally announced prefixes and pulling information about
 	// other nodes.
 	Curator apb.CuratorClient
 	// ClusterNet is the prefix that will be programmed to exit through the wireguard
 	// mesh.
 	ClusterNet net.IPNet
 	// DataDirectory is where the WireGuard key of this node will be stored.
 	DataDirectory *localstorage.DataKubernetesClusterNetworkingDirectory
 	// LocalKubernetesPodNetwork is an event.Value watched for prefixes that should
 	// be announced into the mesh. This is to be Set by the Kubernetes service once
 	// it knows about the local node's IPAM address assignment.
 	LocalKubernetesPodNetwork event.Value[*Prefixes]
 	// Network service used to get the local node's IP address to submit it as a /32.
 	Network event.Value[*network.Status]

 	// wg is the interface to all the low-level interactions with WireGuard (and
 	// kernel routing). If not set, this defaults to a production implementation.
 	// This can be overridden by test to a test implementation instead.
 	wg wireguard
 }

 // Run the Service. This must be used in a supervisor Runnable.
 func (s *Service) Run(ctx context.Context) error {
 	if s.wg == nil {
 		s.wg = &localWireguard{}
 	}
 	if err := s.wg.ensureOnDiskKey(s.DataDirectory); err != nil {
 		return fmt.Errorf("could not ensure wireguard key: %w", err)
 	}
 	if err := s.wg.setup(&s.ClusterNet); err != nil {
 		return fmt.Errorf("could not setup wireguard: %w", err)
 	}

 	supervisor.Logger(ctx).Infof("Wireguard setup complete, starting updaters...")

 	kubeC := make(chan *Prefixes)
 	netC := make(chan *network.Status)
 	if err := supervisor.RunGroup(ctx, map[string]supervisor.Runnable{
 		"source-kubernetes": event.Pipe(s.LocalKubernetesPodNetwork, kubeC),
 		"source-network":    event.Pipe(s.Network, netC),
 		"push": func(ctx context.Context) error {
 			return s.push(ctx, kubeC, netC)
 		},
 	}); err != nil {
 		return err
 	}

 	if err := supervisor.Run(ctx, "pull", s.pull); err != nil {
 		return err
 	}
 	supervisor.Signal(ctx, supervisor.SignalHealthy)
 	<-ctx.Done()
 	return ctx.Err()
 }

 // push is the sub-runnable responsible for letting the Curator know about what
 // prefixes that are originated by this node.
 func (s *Service) push(ctx context.Context, kubeC chan *Prefixes, netC chan *network.Status) error {
 	supervisor.Signal(ctx, supervisor.SignalHealthy)

 	var kubePrefixes *Prefixes
 	var prevKubePrefixes *Prefixes

 	var localAddr net.IP
 	var prevLocalAddr net.IP

 	for {
 		kubeChanged := false
 		localChanged := false

 		select {
 		case <-ctx.Done():
 			return ctx.Err()
 		case kubePrefixes = <-kubeC:
 			if !kubePrefixes.Equal(prevKubePrefixes) {
 				kubeChanged = true
 			}
 		case n := <-netC:
 			localAddr = n.ExternalAddress
 			if !localAddr.Equal(prevLocalAddr) {
 				localChanged = true
 			}
 		}

 		// Ignore spurious updates.
 		if !localChanged && !kubeChanged {
 			continue
 		}

 		// Prepare prefixes to submit to cluster.
 		var prefixes Prefixes

 		// Do we have a local node address? Add it to the prefixes.
 		if len(localAddr) > 0 {
 			addr, ok := netip.AddrFromSlice(localAddr)
 			if ok {
 				prefixes = append(prefixes, netip.PrefixFrom(addr, 32))
 			}
 		}
 		// Do we have any kubelet prefixes? Add them, too.
 		if kubePrefixes != nil {
 			prefixes.Update(kubePrefixes)
 		}

 		supervisor.Logger(ctx).Infof("Submitting prefixes: %s (kube update: %v, local update: %v)", prefixes, kubeChanged, localChanged)

 		err := backoff.Retry(func() error {
 			_, err := s.Curator.UpdateNodeClusterNetworking(ctx, &apb.UpdateNodeClusterNetworkingRequest{
 				Clusternet: &cpb.NodeClusterNetworking{
 					WireguardPubkey: s.wg.key().PublicKey().String(),
 					Prefixes:        prefixes.proto(),
 				},
 			})
 			if err != nil {
 				supervisor.Logger(ctx).Warningf("Could not submit cluster networking update: %v", err)
 			}
 			return err
 		}, backoff.WithContext(backoff.NewExponentialBackOff(), ctx))
 		if err != nil {
 			return fmt.Errorf("couldn't update curator: %w", err)
 		}

 		prevKubePrefixes = kubePrefixes
 		prevLocalAddr = localAddr

 	}
 }

 // pull is the sub-runnable responsible for fetching information about the
 // cluster networking setup/status of other nodes, and programming it as
 // WireGuard peers.
 func (s *Service) pull(ctx context.Context) error {
 	supervisor.Signal(ctx, supervisor.SignalHealthy)

 	srv, err := s.Curator.Watch(ctx, &apb.WatchRequest{
 		Kind: &apb.WatchRequest_NodesInCluster_{
 			NodesInCluster: &apb.WatchRequest_NodesInCluster{},
 		},
 	})
 	if err != nil {
 		return fmt.Errorf("curator watch failed: %w", err)
 	}
 	defer srv.CloseSend()

 	nodes := newNodemap()
 	for {
 		ev, err := srv.Recv()
 		if err != nil {
 			return fmt.Errorf("curator watch recv failed: %w", err)
 		}

 		updated, removed := nodes.update(ctx, ev)

 		for _, n := range removed {
 			supervisor.Logger(ctx).Infof("Node %s removed, unconfiguring", n.id)
 			if err := s.wg.unconfigurePeer(n.copy()); err != nil {
 				// Do nothing and hope whatever caused this will go away at some point.
 				supervisor.Logger(ctx).Errorf("Node %s couldn't be unconfigured: %v", n.id, err)
 			}
 		}
 		var newNodes []*node
 		for _, n := range updated {
 			newNodes = append(newNodes, n.copy())
 			supervisor.Logger(ctx).Infof("Node %s updated: pk %s, address %s, prefixes %v", n.id, n.pubkey, n.address, n.prefixes)
 		}
 		succeeded := 0
 		if err := s.wg.configurePeers(newNodes); err != nil {
 			// If configuring all nodes at once failed, go node-by-node to make sure we've
 			// done as much as possible.
 			supervisor.Logger(ctx).Warningf("Bulk node update call failed, trying node-by-node..: %v", err)
 			for _, n := range newNodes {
 				if err := s.wg.configurePeers([]*node{n}); err != nil {
 					supervisor.Logger(ctx).Errorf("Node %s failed: %v", n.id, err)
 				} else {
 					succeeded += 1
 				}
 			}
 		} else {
 			succeeded = len(newNodes)
 		}

 		if len(newNodes) != 0 {
 			supervisor.Logger(ctx).Infof("Successfully updated %d out of %d nodes", succeeded, len(newNodes))

 			numNodes, numPrefixes := nodes.stats()
 			supervisor.Logger(ctx).Infof("Total: %d nodes, %d prefixes.", numNodes, numPrefixes)
 		}
 	}
 }
	// Package clusternet implements a Cluster Networking mesh service running on all
	// Metropolis nodes.
	//
	// The mesh is based on wireguard and a centralized configuration store in the
	// cluster Curator (in etcd).
	//
	// While the implementation is nearly generic, it currently makes an assumption
	// that it is used only for Kubernetes pod networking. That has a few
	// implications:
	//
	// First, we only have a single real route on the host into the wireguard
	// networking mesh / interface, and that is configured ahead of time in the
	// Service as ClusterNet. All destination addresses that should be carried by the
	// mesh must thus be part of this single route. Otherwise, traffic will be able
	// to flow into the node from other nodes, but will exit through another
	// interface. This is used in practice to allow other host nodes (whose external
	// addresses are outside the cluster network) to access the cluster network.
	//
	// Second, we have two hardcoded/purpose-specific sources of prefixes:
	// 1. Pod networking node prefixes from the kubelet
	// 2. The host's external IP address (as a /32) from the network service.
	package clusternet

	import (
	"context"
	"fmt"
	"net"
	"net/netip"

	"github.com/cenkalti/backoff/v4"

	"source.monogon.dev/metropolis/node/core/localstorage"
	"source.monogon.dev/metropolis/node/core/network"
	"source.monogon.dev/metropolis/pkg/event"
	"source.monogon.dev/metropolis/pkg/supervisor"

	apb "source.monogon.dev/metropolis/node/core/curator/proto/api"
	cpb "source.monogon.dev/metropolis/proto/common"
	)

	// Service implements the Cluster Networking Mesh. See package-level docs for
	// more details.
	type Service struct {
	// Curator is the gRPC client that the service will use to reach the cluster's
	// Curator, for pushing locally announced prefixes and pulling information about
	// other nodes.
	Curator apb.CuratorClient
	// ClusterNet is the prefix that will be programmed to exit through the wireguard
	// mesh.
	ClusterNet net.IPNet
	// DataDirectory is where the WireGuard key of this node will be stored.
	DataDirectory *localstorage.DataKubernetesClusterNetworkingDirectory
	// LocalKubernetesPodNetwork is an event.Value watched for prefixes that should
	// be announced into the mesh. This is to be Set by the Kubernetes service once
	// it knows about the local node's IPAM address assignment.
	LocalKubernetesPodNetwork event.Value[*Prefixes]
	// Network service used to get the local node's IP address to submit it as a /32.
	Network event.Value[*network.Status]

	// wg is the interface to all the low-level interactions with WireGuard (and
	// kernel routing). If not set, this defaults to a production implementation.
	// This can be overridden by test to a test implementation instead.
	wg wireguard
	}

	// Run the Service. This must be used in a supervisor Runnable.
	func (s *Service) Run(ctx context.Context) error {
	if s.wg == nil {
	s.wg = &localWireguard{}
	}
	if err := s.wg.ensureOnDiskKey(s.DataDirectory); err != nil {
	return fmt.Errorf("could not ensure wireguard key: %w", err)
	}
	if err := s.wg.setup(&s.ClusterNet); err != nil {
	return fmt.Errorf("could not setup wireguard: %w", err)
	}

	supervisor.Logger(ctx).Infof("Wireguard setup complete, starting updaters...")

	kubeC := make(chan *Prefixes)
	netC := make(chan *network.Status)
	if err := supervisor.RunGroup(ctx, map[string]supervisor.Runnable{
	"source-kubernetes": event.Pipe(s.LocalKubernetesPodNetwork, kubeC),
	"source-network": event.Pipe(s.Network, netC),
	"push": func(ctx context.Context) error {
	return s.push(ctx, kubeC, netC)
	},
	}); err != nil {
	return err
	}

	if err := supervisor.Run(ctx, "pull", s.pull); err != nil {
	return err
	}
	supervisor.Signal(ctx, supervisor.SignalHealthy)
	<-ctx.Done()
	return ctx.Err()
	}

	// push is the sub-runnable responsible for letting the Curator know about what
	// prefixes that are originated by this node.
	func (s Service) push(ctx context.Context, kubeC chan Prefixes, netC chan *network.Status) error {
	supervisor.Signal(ctx, supervisor.SignalHealthy)

	var kubePrefixes *Prefixes
	var prevKubePrefixes *Prefixes

	var localAddr net.IP
	var prevLocalAddr net.IP

	for {
	kubeChanged := false
	localChanged := false

	select {
	case <-ctx.Done():
	return ctx.Err()
	case kubePrefixes = <-kubeC:
	if !kubePrefixes.Equal(prevKubePrefixes) {
	kubeChanged = true
	}
	case n := <-netC:
	localAddr = n.ExternalAddress
	if !localAddr.Equal(prevLocalAddr) {
	localChanged = true
	}
	}

	// Ignore spurious updates.
	if !localChanged && !kubeChanged {
	continue
	}

	// Prepare prefixes to submit to cluster.
	var prefixes Prefixes

	// Do we have a local node address? Add it to the prefixes.
	if len(localAddr) > 0 {
	addr, ok := netip.AddrFromSlice(localAddr)
	if ok {
	prefixes = append(prefixes, netip.PrefixFrom(addr, 32))
	}
	}
	// Do we have any kubelet prefixes? Add them, too.
	if kubePrefixes != nil {
	prefixes.Update(kubePrefixes)
	}

	supervisor.Logger(ctx).Infof("Submitting prefixes: %s (kube update: %v, local update: %v)", prefixes, kubeChanged, localChanged)

	err := backoff.Retry(func() error {
	_, err := s.Curator.UpdateNodeClusterNetworking(ctx, &apb.UpdateNodeClusterNetworkingRequest{
	Clusternet: &cpb.NodeClusterNetworking{
	WireguardPubkey: s.wg.key().PublicKey().String(),
	Prefixes: prefixes.proto(),
	},
	})
	if err != nil {
	supervisor.Logger(ctx).Warningf("Could not submit cluster networking update: %v", err)
	}
	return err
	}, backoff.WithContext(backoff.NewExponentialBackOff(), ctx))
	if err != nil {
	return fmt.Errorf("couldn't update curator: %w", err)
	}

	prevKubePrefixes = kubePrefixes
	prevLocalAddr = localAddr

	}
	}

	// pull is the sub-runnable responsible for fetching information about the
	// cluster networking setup/status of other nodes, and programming it as
	// WireGuard peers.
	func (s *Service) pull(ctx context.Context) error {
	supervisor.Signal(ctx, supervisor.SignalHealthy)

	srv, err := s.Curator.Watch(ctx, &apb.WatchRequest{
	Kind: &apb.WatchRequest_NodesInCluster_{
	NodesInCluster: &apb.WatchRequest_NodesInCluster{},
	},
	})
	if err != nil {
	return fmt.Errorf("curator watch failed: %w", err)
	}
	defer srv.CloseSend()

	nodes := newNodemap()
	for {
	ev, err := srv.Recv()
	if err != nil {
	return fmt.Errorf("curator watch recv failed: %w", err)
	}

	updated, removed := nodes.update(ctx, ev)

	for _, n := range removed {
	supervisor.Logger(ctx).Infof("Node %s removed, unconfiguring", n.id)
	if err := s.wg.unconfigurePeer(n.copy()); err != nil {
	// Do nothing and hope whatever caused this will go away at some point.
	supervisor.Logger(ctx).Errorf("Node %s couldn't be unconfigured: %v", n.id, err)
	}
	}
	var newNodes []*node
	for _, n := range updated {
	newNodes = append(newNodes, n.copy())
	supervisor.Logger(ctx).Infof("Node %s updated: pk %s, address %s, prefixes %v", n.id, n.pubkey, n.address, n.prefixes)
	}
	succeeded := 0
	if err := s.wg.configurePeers(newNodes); err != nil {
	// If configuring all nodes at once failed, go node-by-node to make sure we've
	// done as much as possible.
	supervisor.Logger(ctx).Warningf("Bulk node update call failed, trying node-by-node..: %v", err)
	for _, n := range newNodes {
	if err := s.wg.configurePeers([]*node{n}); err != nil {
	supervisor.Logger(ctx).Errorf("Node %s failed: %v", n.id, err)
	} else {
	succeeded += 1
	}
	}
	} else {
	succeeded = len(newNodes)
	}

	if len(newNodes) != 0 {
	supervisor.Logger(ctx).Infof("Successfully updated %d out of %d nodes", succeeded, len(newNodes))

	numNodes, numPrefixes := nodes.stats()
	supervisor.Logger(ctx).Infof("Total: %d nodes, %d prefixes.", numNodes, numPrefixes)
	}
	}
	}