Confirm neighbor reachability with TCP ACKs

As per RFC 4861 section 7.3.1, A neighbor is considered reachable if the node has recently received a confirmation that packets sent recently to the neighbor were received by its IP layer. Positive confirmation can be gathered in two ways: hints from upper-layer protocols that indicate a connection is making "forward progress", or receipt of a Neighbor Advertisement message that is a response to a Neighbor Solicitation message. This change adds support for TCP to let the IP/link layers know that a neighbor is reachable. Test: integration_test.TestTCPConfirmNeighborReachability PiperOrigin-RevId: 354222833
author: Ghanan Gowripalan <ghanan@google.com> 2021-01-27 19:06:47 -0800
committer: gVisor bot <gvisor-bot@google.com> 2021-01-27 19:08:51 -0800
commit: b85b23e50d1c264ff4821e182ad89a8ea3d0e0c5 (patch)
tree: 9180366b5d4106e048b41fd1d34a436be6719d0f /pkg/tcpip
parent: 1d22284c13cc040e52c2130386c10d8f84f6bbd6 (diff)
9 files changed, 633 insertions, 162 deletions
diff --git a/pkg/tcpip/stack/neighbor_cache.go b/pkg/tcpip/stack/neighbor_cache.go
index 204196d00..eea32dcf5 100644
--- a/pkg/tcpip/stack/neighbor_cache.go
+++ b/pkg/tcpip/stack/neighbor_cache.go
@@ -297,10 +297,9 @@ func (n *neighborCache) HandleConfirmation(addr tcpip.Address, linkAddr tcpip.Li
 	// no matching entry for the remote address.
 }
 
-// HandleUpperLevelConfirmation implements
-// NUDHandler.HandleUpperLevelConfirmation by following the logic defined in
-// RFC 4861 section 7.3.1.
-func (n *neighborCache) HandleUpperLevelConfirmation(addr tcpip.Address) {
+// handleUpperLevelConfirmation processes a confirmation of reachablity from
+// some protocol that operates at a layer above the IP/link layer.
+func (n *neighborCache) handleUpperLevelConfirmation(addr tcpip.Address) {
 	n.mu.RLock()
 	entry, ok := n.cache[addr]
 	n.mu.RUnlock()
diff --git a/pkg/tcpip/stack/nic.go b/pkg/tcpip/stack/nic.go
index 1bbfe6213..f59416fd3 100644
--- a/pkg/tcpip/stack/nic.go
+++ b/pkg/tcpip/stack/nic.go
@@ -561,6 +561,12 @@ func (n *NIC) removeAddress(addr tcpip.Address) *tcpip.Error {
 	return tcpip.ErrBadLocalAddress
 }
 
+func (n *NIC) confirmReachable(addr tcpip.Address) {
+	if n := n.neigh; n != nil {
+		n.handleUpperLevelConfirmation(addr)
+	}
+}
+
 func (n *NIC) getNeighborLinkAddress(addr, localAddr tcpip.Address, linkRes LinkAddressResolver, onResolve func(LinkResolutionResult)) (tcpip.LinkAddress, <-chan struct{}, *tcpip.Error) {
 	if n.neigh != nil {
 		entry, ch, err := n.neigh.entry(addr, localAddr, linkRes, onResolve)
diff --git a/pkg/tcpip/stack/nud.go b/pkg/tcpip/stack/nud.go
index 12d67409a..77926e289 100644
--- a/pkg/tcpip/stack/nud.go
+++ b/pkg/tcpip/stack/nud.go
@@ -174,10 +174,6 @@ type NUDHandler interface {
 	// HandleConfirmation processes an incoming neighbor confirmation (e.g. ARP
 	// reply or Neighbor Advertisement for ARP or NDP, respectively).
 	HandleConfirmation(addr tcpip.Address, linkAddr tcpip.LinkAddress, flags ReachabilityConfirmationFlags)
-
-	// HandleUpperLevelConfirmation processes an incoming upper-level protocol
-	// (e.g. TCP acknowledgements) reachability confirmation.
-	HandleUpperLevelConfirmation(addr tcpip.Address)
 }
 
 // NUDConfigurations is the NUD configurations for the netstack. This is used
diff --git a/pkg/tcpip/stack/route.go b/pkg/tcpip/stack/route.go
index d9a8554e2..9c8c155fa 100644
--- a/pkg/tcpip/stack/route.go
+++ b/pkg/tcpip/stack/route.go
@@ -354,11 +354,6 @@ func (r *Route) resolvedFields(afterResolve func(ResolvedFieldsResult)) (RouteIn
 		return fields, nil, nil
 	}
 
-	nextAddr := r.NextHop
-	if nextAddr == "" {
-		nextAddr = r.RemoteAddress
-	}
-
 	// If specified, the local address used for link address resolution must be an
 	// address on the outgoing interface.
 	var linkAddressResolutionRequestLocalAddr tcpip.Address
@@ -367,7 +362,7 @@ func (r *Route) resolvedFields(afterResolve func(ResolvedFieldsResult)) (RouteIn
 	}
 
 	afterResolveFields := fields
-	linkAddr, ch, err := r.outgoingNIC.getNeighborLinkAddress(nextAddr, linkAddressResolutionRequestLocalAddr, r.linkRes, func(r LinkResolutionResult) {
+	linkAddr, ch, err := r.outgoingNIC.getNeighborLinkAddress(r.nextHop(), linkAddressResolutionRequestLocalAddr, r.linkRes, func(r LinkResolutionResult) {
 		if afterResolve != nil {
 			if r.Success {
 				afterResolveFields.RemoteLinkAddress = r.LinkAddress
@@ -382,6 +377,13 @@ func (r *Route) resolvedFields(afterResolve func(ResolvedFieldsResult)) (RouteIn
 	return fields, ch, err
 }
 
+func (r *Route) nextHop() tcpip.Address {
+	if len(r.NextHop) == 0 {
+		return r.RemoteAddress
+	}
+	return r.NextHop
+}
+
 // local returns true if the route is a local route.
 func (r *Route) local() bool {
 	return r.Loop == PacketLoop || r.outgoingNIC.IsLoopback()
@@ -519,3 +521,12 @@ func (r *Route) IsOutboundBroadcast() bool {
 	// Only IPv4 has a notion of broadcast.
 	return r.isV4Broadcast(r.RemoteAddress)
 }
+
+// ConfirmReachable informs the network/link layer that the neighbour used for
+// the route is reachable.
+//
+// "Reachable" is defined as having full-duplex communication between the
+// local and remote ends of the route.
+func (r *Route) ConfirmReachable() {
+	r.outgoingNIC.confirmReachable(r.nextHop())
+}
diff --git a/pkg/tcpip/tests/integration/BUILD b/pkg/tcpip/tests/integration/BUILD
index 218b218e7..71695b630 100644
--- a/pkg/tcpip/tests/integration/BUILD
+++ b/pkg/tcpip/tests/integration/BUILD
@@ -17,6 +17,7 @@ go_test(
         "//pkg/tcpip",
         "//pkg/tcpip/buffer",
         "//pkg/tcpip/checker",
+        "//pkg/tcpip/faketime",
         "//pkg/tcpip/header",
         "//pkg/tcpip/link/channel",
         "//pkg/tcpip/link/ethernet",
diff --git a/pkg/tcpip/tests/integration/forward_test.go b/pkg/tcpip/tests/integration/forward_test.go
index aedf1845e..2b5832c62 100644
--- a/pkg/tcpip/tests/integration/forward_test.go
+++ b/pkg/tcpip/tests/integration/forward_test.go
@@ -38,96 +38,207 @@ import (
 var _ stack.NetworkDispatcher = (*endpointWithDestinationCheck)(nil)
 var _ stack.LinkEndpoint = (*endpointWithDestinationCheck)(nil)
 
-// newEthernetEndpoint returns an ethernet link endpoint that wraps an inner
-// link endpoint and checks the destination link address before delivering
-// network packets to the network dispatcher.
-//
-// See ethernet.Endpoint for more details.
-func newEthernetEndpoint(ep stack.LinkEndpoint) *endpointWithDestinationCheck {
-	var e endpointWithDestinationCheck
-	e.Endpoint.Init(ethernet.New(ep), &e)
-	return &e
-}
-
-// endpointWithDestinationCheck is a link endpoint that checks the destination
-// link address before delivering network packets to the network dispatcher.
-type endpointWithDestinationCheck struct {
-	nested.Endpoint
-}
-
-// DeliverNetworkPacket implements stack.NetworkDispatcher.
-func (e *endpointWithDestinationCheck) DeliverNetworkPacket(src, dst tcpip.LinkAddress, proto tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) {
-	if dst == e.Endpoint.LinkAddress() || dst == header.EthernetBroadcastAddress || header.IsMulticastEthernetAddress(dst) {
-		e.Endpoint.DeliverNetworkPacket(src, dst, proto, pkt)
-	}
-}
-
-func TestForwarding(t *testing.T) {
-	const (
-		host1NICID   = 1
-		routerNICID1 = 2
-		routerNICID2 = 3
-		host2NICID   = 4
-
-		listenPort = 8080
-	)
+const (
+	host1NICID   = 1
+	routerNICID1 = 2
+	routerNICID2 = 3
+	host2NICID   = 4
+)
 
-	host1IPv4Addr := tcpip.ProtocolAddress{
+var (
+	host1IPv4Addr = tcpip.ProtocolAddress{
 		Protocol: ipv4.ProtocolNumber,
 		AddressWithPrefix: tcpip.AddressWithPrefix{
 			Address:   tcpip.Address(net.ParseIP("192.168.0.2").To4()),
 			PrefixLen: 24,
 		},
 	}
-	routerNIC1IPv4Addr := tcpip.ProtocolAddress{
+	routerNIC1IPv4Addr = tcpip.ProtocolAddress{
 		Protocol: ipv4.ProtocolNumber,
 		AddressWithPrefix: tcpip.AddressWithPrefix{
 			Address:   tcpip.Address(net.ParseIP("192.168.0.1").To4()),
 			PrefixLen: 24,
 		},
 	}
-	routerNIC2IPv4Addr := tcpip.ProtocolAddress{
+	routerNIC2IPv4Addr = tcpip.ProtocolAddress{
 		Protocol: ipv4.ProtocolNumber,
 		AddressWithPrefix: tcpip.AddressWithPrefix{
 			Address:   tcpip.Address(net.ParseIP("10.0.0.1").To4()),
 			PrefixLen: 8,
 		},
 	}
-	host2IPv4Addr := tcpip.ProtocolAddress{
+	host2IPv4Addr = tcpip.ProtocolAddress{
 		Protocol: ipv4.ProtocolNumber,
 		AddressWithPrefix: tcpip.AddressWithPrefix{
 			Address:   tcpip.Address(net.ParseIP("10.0.0.2").To4()),
 			PrefixLen: 8,
 		},
 	}
-	host1IPv6Addr := tcpip.ProtocolAddress{
+	host1IPv6Addr = tcpip.ProtocolAddress{
 		Protocol: ipv6.ProtocolNumber,
 		AddressWithPrefix: tcpip.AddressWithPrefix{
 			Address:   tcpip.Address(net.ParseIP("a::2").To16()),
 			PrefixLen: 64,
 		},
 	}
-	routerNIC1IPv6Addr := tcpip.ProtocolAddress{
+	routerNIC1IPv6Addr = tcpip.ProtocolAddress{
 		Protocol: ipv6.ProtocolNumber,
 		AddressWithPrefix: tcpip.AddressWithPrefix{
 			Address:   tcpip.Address(net.ParseIP("a::1").To16()),
 			PrefixLen: 64,
 		},
 	}
-	routerNIC2IPv6Addr := tcpip.ProtocolAddress{
+	routerNIC2IPv6Addr = tcpip.ProtocolAddress{
 		Protocol: ipv6.ProtocolNumber,
 		AddressWithPrefix: tcpip.AddressWithPrefix{
 			Address:   tcpip.Address(net.ParseIP("b::1").To16()),
 			PrefixLen: 64,
 		},
 	}
-	host2IPv6Addr := tcpip.ProtocolAddress{
+	host2IPv6Addr = tcpip.ProtocolAddress{
 		Protocol: ipv6.ProtocolNumber,
 		AddressWithPrefix: tcpip.AddressWithPrefix{
 			Address:   tcpip.Address(net.ParseIP("b::2").To16()),
 			PrefixLen: 64,
 		},
 	}
+)
+
+func setupRoutedStacks(t *testing.T, host1Stack, routerStack, host2Stack *stack.Stack) {
+	host1NIC, routerNIC1 := pipe.New(linkAddr1, linkAddr2)
+	routerNIC2, host2NIC := pipe.New(linkAddr3, linkAddr4)
+
+	if err := host1Stack.CreateNIC(host1NICID, newEthernetEndpoint(host1NIC)); err != nil {
+		t.Fatalf("host1Stack.CreateNIC(%d, _): %s", host1NICID, err)
+	}
+	if err := routerStack.CreateNIC(routerNICID1, newEthernetEndpoint(routerNIC1)); err != nil {
+		t.Fatalf("routerStack.CreateNIC(%d, _): %s", routerNICID1, err)
+	}
+	if err := routerStack.CreateNIC(routerNICID2, newEthernetEndpoint(routerNIC2)); err != nil {
+		t.Fatalf("routerStack.CreateNIC(%d, _): %s", routerNICID2, err)
+	}
+	if err := host2Stack.CreateNIC(host2NICID, newEthernetEndpoint(host2NIC)); err != nil {
+		t.Fatalf("host2Stack.CreateNIC(%d, _): %s", host2NICID, err)
+	}
+
+	if err := routerStack.SetForwarding(ipv4.ProtocolNumber, true); err != nil {
+		t.Fatalf("routerStack.SetForwarding(%d): %s", ipv4.ProtocolNumber, err)
+	}
+	if err := routerStack.SetForwarding(ipv6.ProtocolNumber, true); err != nil {
+		t.Fatalf("routerStack.SetForwarding(%d): %s", ipv6.ProtocolNumber, err)
+	}
+
+	if err := host1Stack.AddProtocolAddress(host1NICID, host1IPv4Addr); err != nil {
+		t.Fatalf("host1Stack.AddProtocolAddress(%d, %#v): %s", host1NICID, host1IPv4Addr, err)
+	}
+	if err := routerStack.AddProtocolAddress(routerNICID1, routerNIC1IPv4Addr); err != nil {
+		t.Fatalf("routerStack.AddProtocolAddress(%d, %#v): %s", routerNICID1, routerNIC1IPv4Addr, err)
+	}
+	if err := routerStack.AddProtocolAddress(routerNICID2, routerNIC2IPv4Addr); err != nil {
+		t.Fatalf("routerStack.AddProtocolAddress(%d, %#v): %s", routerNICID2, routerNIC2IPv4Addr, err)
+	}
+	if err := host2Stack.AddProtocolAddress(host2NICID, host2IPv4Addr); err != nil {
+		t.Fatalf("host2Stack.AddProtocolAddress(%d, %#v): %s", host2NICID, host2IPv4Addr, err)
+	}
+	if err := host1Stack.AddProtocolAddress(host1NICID, host1IPv6Addr); err != nil {
+		t.Fatalf("host1Stack.AddProtocolAddress(%d, %#v): %s", host1NICID, host1IPv6Addr, err)
+	}
+	if err := routerStack.AddProtocolAddress(routerNICID1, routerNIC1IPv6Addr); err != nil {
+		t.Fatalf("routerStack.AddProtocolAddress(%d, %#v): %s", routerNICID1, routerNIC1IPv6Addr, err)
+	}
+	if err := routerStack.AddProtocolAddress(routerNICID2, routerNIC2IPv6Addr); err != nil {
+		t.Fatalf("routerStack.AddProtocolAddress(%d, %#v): %s", routerNICID2, routerNIC2IPv6Addr, err)
+	}
+	if err := host2Stack.AddProtocolAddress(host2NICID, host2IPv6Addr); err != nil {
+		t.Fatalf("host2Stack.AddProtocolAddress(%d, %#v): %s", host2NICID, host2IPv6Addr, err)
+	}
+
+	host1Stack.SetRouteTable([]tcpip.Route{
+		{
+			Destination: host1IPv4Addr.AddressWithPrefix.Subnet(),
+			NIC:         host1NICID,
+		},
+		{
+			Destination: host1IPv6Addr.AddressWithPrefix.Subnet(),
+			NIC:         host1NICID,
+		},
+		{
+			Destination: host2IPv4Addr.AddressWithPrefix.Subnet(),
+			Gateway:     routerNIC1IPv4Addr.AddressWithPrefix.Address,
+			NIC:         host1NICID,
+		},
+		{
+			Destination: host2IPv6Addr.AddressWithPrefix.Subnet(),
+			Gateway:     routerNIC1IPv6Addr.AddressWithPrefix.Address,
+			NIC:         host1NICID,
+		},
+	})
+	routerStack.SetRouteTable([]tcpip.Route{
+		{
+			Destination: routerNIC1IPv4Addr.AddressWithPrefix.Subnet(),
+			NIC:         routerNICID1,
+		},
+		{
+			Destination: routerNIC1IPv6Addr.AddressWithPrefix.Subnet(),
+			NIC:         routerNICID1,
+		},
+		{
+			Destination: routerNIC2IPv4Addr.AddressWithPrefix.Subnet(),
+			NIC:         routerNICID2,
+		},
+		{
+			Destination: routerNIC2IPv6Addr.AddressWithPrefix.Subnet(),
+			NIC:         routerNICID2,
+		},
+	})
+	host2Stack.SetRouteTable([]tcpip.Route{
+		{
+			Destination: host2IPv4Addr.AddressWithPrefix.Subnet(),
+			NIC:         host2NICID,
+		},
+		{
+			Destination: host2IPv6Addr.AddressWithPrefix.Subnet(),
+			NIC:         host2NICID,
+		},
+		{
+			Destination: host1IPv4Addr.AddressWithPrefix.Subnet(),
+			Gateway:     routerNIC2IPv4Addr.AddressWithPrefix.Address,
+			NIC:         host2NICID,
+		},
+		{
+			Destination: host1IPv6Addr.AddressWithPrefix.Subnet(),
+			Gateway:     routerNIC2IPv6Addr.AddressWithPrefix.Address,
+			NIC:         host2NICID,
+		},
+	})
+}
+
+// newEthernetEndpoint returns an ethernet link endpoint that wraps an inner
+// link endpoint and checks the destination link address before delivering
+// network packets to the network dispatcher.
+//
+// See ethernet.Endpoint for more details.
+func newEthernetEndpoint(ep stack.LinkEndpoint) *endpointWithDestinationCheck {
+	var e endpointWithDestinationCheck
+	e.Endpoint.Init(ethernet.New(ep), &e)
+	return &e
+}
+
+// endpointWithDestinationCheck is a link endpoint that checks the destination
+// link address before delivering network packets to the network dispatcher.
+type endpointWithDestinationCheck struct {
+	nested.Endpoint
+}
+
+// DeliverNetworkPacket implements stack.NetworkDispatcher.
+func (e *endpointWithDestinationCheck) DeliverNetworkPacket(src, dst tcpip.LinkAddress, proto tcpip.NetworkProtocolNumber, pkt *stack.PacketBuffer) {
+	if dst == e.Endpoint.LinkAddress() || dst == header.EthernetBroadcastAddress || header.IsMulticastEthernetAddress(dst) {
+		e.Endpoint.DeliverNetworkPacket(src, dst, proto, pkt)
+	}
+}
+
+func TestForwarding(t *testing.T) {
+	const listenPort = 8080
 
 	type endpointAndAddresses struct {
 		serverEP         tcpip.Endpoint
@@ -294,113 +405,7 @@ func TestForwarding(t *testing.T) {
 					host1Stack := stack.New(stackOpts)
 					routerStack := stack.New(stackOpts)
 					host2Stack := stack.New(stackOpts)
-
-					host1NIC, routerNIC1 := pipe.New(linkAddr1, linkAddr2)
-					routerNIC2, host2NIC := pipe.New(linkAddr3, linkAddr4)
-
-					if err := host1Stack.CreateNIC(host1NICID, newEthernetEndpoint(host1NIC)); err != nil {
-						t.Fatalf("host1Stack.CreateNIC(%d, _): %s", host1NICID, err)
-					}
-					if err := routerStack.CreateNIC(routerNICID1, newEthernetEndpoint(routerNIC1)); err != nil {
-						t.Fatalf("routerStack.CreateNIC(%d, _): %s", routerNICID1, err)
-					}
-					if err := routerStack.CreateNIC(routerNICID2, newEthernetEndpoint(routerNIC2)); err != nil {
-						t.Fatalf("routerStack.CreateNIC(%d, _): %s", routerNICID2, err)
-					}
-					if err := host2Stack.CreateNIC(host2NICID, newEthernetEndpoint(host2NIC)); err != nil {
-						t.Fatalf("host2Stack.CreateNIC(%d, _): %s", host2NICID, err)
-					}
-
-					if err := routerStack.SetForwarding(ipv4.ProtocolNumber, true); err != nil {
-						t.Fatalf("routerStack.SetForwarding(%d): %s", ipv4.ProtocolNumber, err)
-					}
-					if err := routerStack.SetForwarding(ipv6.ProtocolNumber, true); err != nil {
-						t.Fatalf("routerStack.SetForwarding(%d): %s", ipv6.ProtocolNumber, err)
-					}
-
-					if err := host1Stack.AddProtocolAddress(host1NICID, host1IPv4Addr); err != nil {
-						t.Fatalf("host1Stack.AddProtocolAddress(%d, %#v): %s", host1NICID, host1IPv4Addr, err)
-					}
-					if err := routerStack.AddProtocolAddress(routerNICID1, routerNIC1IPv4Addr); err != nil {
-						t.Fatalf("routerStack.AddProtocolAddress(%d, %#v): %s", routerNICID1, routerNIC1IPv4Addr, err)
-					}
-					if err := routerStack.AddProtocolAddress(routerNICID2, routerNIC2IPv4Addr); err != nil {
-						t.Fatalf("routerStack.AddProtocolAddress(%d, %#v): %s", routerNICID2, routerNIC2IPv4Addr, err)
-					}
-					if err := host2Stack.AddProtocolAddress(host2NICID, host2IPv4Addr); err != nil {
-						t.Fatalf("host2Stack.AddProtocolAddress(%d, %#v): %s", host2NICID, host2IPv4Addr, err)
-					}
-					if err := host1Stack.AddProtocolAddress(host1NICID, host1IPv6Addr); err != nil {
-						t.Fatalf("host1Stack.AddProtocolAddress(%d, %#v): %s", host1NICID, host1IPv6Addr, err)
-					}
-					if err := routerStack.AddProtocolAddress(routerNICID1, routerNIC1IPv6Addr); err != nil {
-						t.Fatalf("routerStack.AddProtocolAddress(%d, %#v): %s", routerNICID1, routerNIC1IPv6Addr, err)
-					}
-					if err := routerStack.AddProtocolAddress(routerNICID2, routerNIC2IPv6Addr); err != nil {
-						t.Fatalf("routerStack.AddProtocolAddress(%d, %#v): %s", routerNICID2, routerNIC2IPv6Addr, err)
-					}
-					if err := host2Stack.AddProtocolAddress(host2NICID, host2IPv6Addr); err != nil {
-						t.Fatalf("host2Stack.AddProtocolAddress(%d, %#v): %s", host2NICID, host2IPv6Addr, err)
-					}
-
-					host1Stack.SetRouteTable([]tcpip.Route{
-						{
-							Destination: host1IPv4Addr.AddressWithPrefix.Subnet(),
-							NIC:         host1NICID,
-						},
-						{
-							Destination: host1IPv6Addr.AddressWithPrefix.Subnet(),
-							NIC:         host1NICID,
-						},
-						{
-							Destination: host2IPv4Addr.AddressWithPrefix.Subnet(),
-							Gateway:     routerNIC1IPv4Addr.AddressWithPrefix.Address,
-							NIC:         host1NICID,
-						},
-						{
-							Destination: host2IPv6Addr.AddressWithPrefix.Subnet(),
-							Gateway:     routerNIC1IPv6Addr.AddressWithPrefix.Address,
-							NIC:         host1NICID,
-						},
-					})
-					routerStack.SetRouteTable([]tcpip.Route{
-						{
-							Destination: routerNIC1IPv4Addr.AddressWithPrefix.Subnet(),
-							NIC:         routerNICID1,
-						},
-						{
-							Destination: routerNIC1IPv6Addr.AddressWithPrefix.Subnet(),
-							NIC:         routerNICID1,
-						},
-						{
-							Destination: routerNIC2IPv4Addr.AddressWithPrefix.Subnet(),
-							NIC:         routerNICID2,
-						},
-						{
-							Destination: routerNIC2IPv6Addr.AddressWithPrefix.Subnet(),
-							NIC:         routerNICID2,
-						},
-					})
-					host2Stack.SetRouteTable([]tcpip.Route{
-						{
-							Destination: host2IPv4Addr.AddressWithPrefix.Subnet(),
-							NIC:         host2NICID,
-						},
-						{
-							Destination: host2IPv6Addr.AddressWithPrefix.Subnet(),
-							NIC:         host2NICID,
-						},
-						{
-							Destination: host1IPv4Addr.AddressWithPrefix.Subnet(),
-							Gateway:     routerNIC2IPv4Addr.AddressWithPrefix.Address,
-							NIC:         host2NICID,
-						},
-						{
-							Destination: host1IPv6Addr.AddressWithPrefix.Subnet(),
-							Gateway:     routerNIC2IPv6Addr.AddressWithPrefix.Address,
-							NIC:         host2NICID,
-						},
-					})
+					setupRoutedStacks(t, host1Stack, routerStack, host2Stack)
 
 					epsAndAddrs := test.epAndAddrs(t, host1Stack, routerStack, host2Stack, subTest.proto)
 					defer epsAndAddrs.serverEP.Close()
diff --git a/pkg/tcpip/tests/integration/link_resolution_test.go b/pkg/tcpip/tests/integration/link_resolution_test.go
index f85164c5b..3c25d1e0c 100644
--- a/pkg/tcpip/tests/integration/link_resolution_test.go
+++ b/pkg/tcpip/tests/integration/link_resolution_test.go
@@ -19,12 +19,14 @@ import (
 	"fmt"
 	"net"
 	"testing"
+	"time"
 
 	"github.com/google/go-cmp/cmp"
 	"github.com/google/go-cmp/cmp/cmpopts"
 	"gvisor.dev/gvisor/pkg/tcpip"
 	"gvisor.dev/gvisor/pkg/tcpip/buffer"
 	"gvisor.dev/gvisor/pkg/tcpip/checker"
+	"gvisor.dev/gvisor/pkg/tcpip/faketime"
 	"gvisor.dev/gvisor/pkg/tcpip/header"
 	"gvisor.dev/gvisor/pkg/tcpip/link/pipe"
 	"gvisor.dev/gvisor/pkg/tcpip/network/arp"
@@ -728,3 +730,435 @@ func TestWritePacketsLinkResolution(t *testing.T) {
 		})
 	}
 }
+
+type eventType int
+
+const (
+	entryAdded eventType = iota
+	entryChanged
+	entryRemoved
+)
+
+func (t eventType) String() string {
+	switch t {
+	case entryAdded:
+		return "add"
+	case entryChanged:
+		return "change"
+	case entryRemoved:
+		return "remove"
+	default:
+		return fmt.Sprintf("unknown (%d)", t)
+	}
+}
+
+type eventInfo struct {
+	eventType eventType
+	nicID     tcpip.NICID
+	entry     stack.NeighborEntry
+}
+
+func (e eventInfo) String() string {
+	return fmt.Sprintf("%s event for NIC #%d, %#v", e.eventType, e.nicID, e.entry)
+}
+
+var _ stack.NUDDispatcher = (*nudDispatcher)(nil)
+
+type nudDispatcher struct {
+	c chan eventInfo
+}
+
+func (d *nudDispatcher) OnNeighborAdded(nicID tcpip.NICID, entry stack.NeighborEntry) {
+	e := eventInfo{
+		eventType: entryAdded,
+		nicID:     nicID,
+		entry:     entry,
+	}
+	d.c <- e
+}
+
+func (d *nudDispatcher) OnNeighborChanged(nicID tcpip.NICID, entry stack.NeighborEntry) {
+	e := eventInfo{
+		eventType: entryChanged,
+		nicID:     nicID,
+		entry:     entry,
+	}
+	d.c <- e
+}
+
+func (d *nudDispatcher) OnNeighborRemoved(nicID tcpip.NICID, entry stack.NeighborEntry) {
+	e := eventInfo{
+		eventType: entryRemoved,
+		nicID:     nicID,
+		entry:     entry,
+	}
+	d.c <- e
+}
+
+func (d *nudDispatcher) waitForEvent(want eventInfo) error {
+	if diff := cmp.Diff(want, <-d.c, cmp.AllowUnexported(eventInfo{}), cmpopts.IgnoreFields(stack.NeighborEntry{}, "UpdatedAtNanos")); diff != "" {
+		return fmt.Errorf("got invalid event (-want +got):\n%s", diff)
+	}
+	return nil
+}
+
+// TestTCPConfirmNeighborReachability tests that TCP informs layers beneath it
+// that the neighbor used for a route is reachable.
+func TestTCPConfirmNeighborReachability(t *testing.T) {
+	tests := []struct {
+		name            string
+		netProto        tcpip.NetworkProtocolNumber
+		remoteAddr      tcpip.Address
+		neighborAddr    tcpip.Address
+		getEndpoints    func(*testing.T, *stack.Stack, *stack.Stack, *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{})
+		isHost1Listener bool
+	}{
+		{
+			name:         "IPv4 active connection through neighbor",
+			netProto:     ipv4.ProtocolNumber,
+			remoteAddr:   host2IPv4Addr.AddressWithPrefix.Address,
+			neighborAddr: routerNIC1IPv4Addr.AddressWithPrefix.Address,
+			getEndpoints: func(t *testing.T, host1Stack, _, host2Stack *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{}) {
+				var listenerWQ waiter.Queue
+				listenerEP, err := host2Stack.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &listenerWQ)
+				if err != nil {
+					t.Fatalf("host2Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv4.ProtocolNumber, err)
+				}
+
+				var clientWQ waiter.Queue
+				clientWE, clientCH := waiter.NewChannelEntry(nil)
+				clientWQ.EventRegister(&clientWE, waiter.EventOut)
+				clientEP, err := host1Stack.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &clientWQ)
+				if err != nil {
+					listenerEP.Close()
+					t.Fatalf("host1Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv4.ProtocolNumber, err)
+				}
+
+				return listenerEP, clientEP, clientCH
+			},
+		},
+		{
+			name:         "IPv6 active connection through neighbor",
+			netProto:     ipv6.ProtocolNumber,
+			remoteAddr:   host2IPv6Addr.AddressWithPrefix.Address,
+			neighborAddr: routerNIC1IPv6Addr.AddressWithPrefix.Address,
+			getEndpoints: func(t *testing.T, host1Stack, _, host2Stack *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{}) {
+				var listenerWQ waiter.Queue
+				listenerEP, err := host2Stack.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &listenerWQ)
+				if err != nil {
+					t.Fatalf("host2Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv6.ProtocolNumber, err)
+				}
+
+				var clientWQ waiter.Queue
+				clientWE, clientCH := waiter.NewChannelEntry(nil)
+				clientWQ.EventRegister(&clientWE, waiter.EventOut)
+				clientEP, err := host1Stack.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &clientWQ)
+				if err != nil {
+					listenerEP.Close()
+					t.Fatalf("host1Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv6.ProtocolNumber, err)
+				}
+
+				return listenerEP, clientEP, clientCH
+			},
+		},
+		{
+			name:         "IPv4 active connection to neighbor",
+			netProto:     ipv4.ProtocolNumber,
+			remoteAddr:   routerNIC1IPv4Addr.AddressWithPrefix.Address,
+			neighborAddr: routerNIC1IPv4Addr.AddressWithPrefix.Address,
+			getEndpoints: func(t *testing.T, host1Stack, routerStack, _ *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{}) {
+				var listenerWQ waiter.Queue
+				listenerEP, err := routerStack.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &listenerWQ)
+				if err != nil {
+					t.Fatalf("routerStack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv4.ProtocolNumber, err)
+				}
+
+				var clientWQ waiter.Queue
+				clientWE, clientCH := waiter.NewChannelEntry(nil)
+				clientWQ.EventRegister(&clientWE, waiter.EventOut)
+				clientEP, err := host1Stack.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &clientWQ)
+				if err != nil {
+					listenerEP.Close()
+					t.Fatalf("host1Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv4.ProtocolNumber, err)
+				}
+
+				return listenerEP, clientEP, clientCH
+			},
+		},
+		{
+			name:         "IPv6 active connection to neighbor",
+			netProto:     ipv6.ProtocolNumber,
+			remoteAddr:   routerNIC1IPv6Addr.AddressWithPrefix.Address,
+			neighborAddr: routerNIC1IPv6Addr.AddressWithPrefix.Address,
+			getEndpoints: func(t *testing.T, host1Stack, routerStack, _ *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{}) {
+				var listenerWQ waiter.Queue
+				listenerEP, err := routerStack.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &listenerWQ)
+				if err != nil {
+					t.Fatalf("routerStack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv6.ProtocolNumber, err)
+				}
+
+				var clientWQ waiter.Queue
+				clientWE, clientCH := waiter.NewChannelEntry(nil)
+				clientWQ.EventRegister(&clientWE, waiter.EventOut)
+				clientEP, err := host1Stack.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &clientWQ)
+				if err != nil {
+					listenerEP.Close()
+					t.Fatalf("host1Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv6.ProtocolNumber, err)
+				}
+
+				return listenerEP, clientEP, clientCH
+			},
+		},
+		{
+			name:         "IPv4 passive connection to neighbor",
+			netProto:     ipv4.ProtocolNumber,
+			remoteAddr:   host1IPv4Addr.AddressWithPrefix.Address,
+			neighborAddr: routerNIC1IPv4Addr.AddressWithPrefix.Address,
+			getEndpoints: func(t *testing.T, host1Stack, routerStack, _ *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{}) {
+				var listenerWQ waiter.Queue
+				listenerEP, err := host1Stack.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &listenerWQ)
+				if err != nil {
+					t.Fatalf("host1Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv4.ProtocolNumber, err)
+				}
+
+				var clientWQ waiter.Queue
+				clientWE, clientCH := waiter.NewChannelEntry(nil)
+				clientWQ.EventRegister(&clientWE, waiter.EventOut)
+				clientEP, err := routerStack.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &clientWQ)
+				if err != nil {
+					listenerEP.Close()
+					t.Fatalf("routerStack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv4.ProtocolNumber, err)
+				}
+
+				return listenerEP, clientEP, clientCH
+			},
+			isHost1Listener: true,
+		},
+		{
+			name:         "IPv6 passive connection to neighbor",
+			netProto:     ipv6.ProtocolNumber,
+			remoteAddr:   host1IPv6Addr.AddressWithPrefix.Address,
+			neighborAddr: routerNIC1IPv6Addr.AddressWithPrefix.Address,
+			getEndpoints: func(t *testing.T, host1Stack, routerStack, _ *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{}) {
+				var listenerWQ waiter.Queue
+				listenerEP, err := host1Stack.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &listenerWQ)
+				if err != nil {
+					t.Fatalf("host1Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv6.ProtocolNumber, err)
+				}
+
+				var clientWQ waiter.Queue
+				clientWE, clientCH := waiter.NewChannelEntry(nil)
+				clientWQ.EventRegister(&clientWE, waiter.EventOut)
+				clientEP, err := routerStack.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &clientWQ)
+				if err != nil {
+					listenerEP.Close()
+					t.Fatalf("routerStack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv6.ProtocolNumber, err)
+				}
+
+				return listenerEP, clientEP, clientCH
+			},
+			isHost1Listener: true,
+		},
+		{
+			name:         "IPv4 passive connection through neighbor",
+			netProto:     ipv4.ProtocolNumber,
+			remoteAddr:   host1IPv4Addr.AddressWithPrefix.Address,
+			neighborAddr: routerNIC1IPv4Addr.AddressWithPrefix.Address,
+			getEndpoints: func(t *testing.T, host1Stack, _, host2Stack *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{}) {
+				var listenerWQ waiter.Queue
+				listenerEP, err := host1Stack.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &listenerWQ)
+				if err != nil {
+					t.Fatalf("host1Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv4.ProtocolNumber, err)
+				}
+
+				var clientWQ waiter.Queue
+				clientWE, clientCH := waiter.NewChannelEntry(nil)
+				clientWQ.EventRegister(&clientWE, waiter.EventOut)
+				clientEP, err := host2Stack.NewEndpoint(tcp.ProtocolNumber, ipv4.ProtocolNumber, &clientWQ)
+				if err != nil {
+					listenerEP.Close()
+					t.Fatalf("host2Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv4.ProtocolNumber, err)
+				}
+
+				return listenerEP, clientEP, clientCH
+			},
+			isHost1Listener: true,
+		},
+		{
+			name:         "IPv6 passive connection through neighbor",
+			netProto:     ipv6.ProtocolNumber,
+			remoteAddr:   host1IPv6Addr.AddressWithPrefix.Address,
+			neighborAddr: routerNIC1IPv6Addr.AddressWithPrefix.Address,
+			getEndpoints: func(t *testing.T, host1Stack, _, host2Stack *stack.Stack) (tcpip.Endpoint, tcpip.Endpoint, <-chan struct{}) {
+				var listenerWQ waiter.Queue
+				listenerEP, err := host1Stack.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &listenerWQ)
+				if err != nil {
+					t.Fatalf("host1Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv6.ProtocolNumber, err)
+				}
+
+				var clientWQ waiter.Queue
+				clientWE, clientCH := waiter.NewChannelEntry(nil)
+				clientWQ.EventRegister(&clientWE, waiter.EventOut)
+				clientEP, err := host2Stack.NewEndpoint(tcp.ProtocolNumber, ipv6.ProtocolNumber, &clientWQ)
+				if err != nil {
+					listenerEP.Close()
+					t.Fatalf("host2Stack.NewEndpoint(%d, %d, _): %s", tcp.ProtocolNumber, ipv6.ProtocolNumber, err)
+				}
+
+				return listenerEP, clientEP, clientCH
+			},
+			isHost1Listener: true,
+		},
+	}
+
+	for _, test := range tests {
+		t.Run(test.name, func(t *testing.T) {
+			clock := faketime.NewManualClock()
+			nudDisp := nudDispatcher{
+				c: make(chan eventInfo, 3),
+			}
+			stackOpts := stack.Options{
+				NetworkProtocols:   []stack.NetworkProtocolFactory{arp.NewProtocol, ipv4.NewProtocol, ipv6.NewProtocol},
+				TransportProtocols: []stack.TransportProtocolFactory{tcp.NewProtocol},
+				Clock:              clock,
+				UseNeighborCache:   true,
+			}
+			host1StackOpts := stackOpts
+			host1StackOpts.NUDDisp = &nudDisp
+
+			host1Stack := stack.New(host1StackOpts)
+			routerStack := stack.New(stackOpts)
+			host2Stack := stack.New(stackOpts)
+			setupRoutedStacks(t, host1Stack, routerStack, host2Stack)
+
+			// Add a reachable dynamic entry to our neighbor table for the remote.
+			{
+				ch := make(chan stack.LinkResolutionResult, 1)
+				if err := host1Stack.GetLinkAddress(host1NICID, test.neighborAddr, "", test.netProto, func(r stack.LinkResolutionResult) {
+					ch <- r
+				}); err != tcpip.ErrWouldBlock {
+					t.Fatalf("got host1Stack.GetLinkAddress(%d, %s, '', %d, _) = %s, want = %s", host1NICID, test.neighborAddr, test.netProto, err, tcpip.ErrWouldBlock)
+				}
+				if diff := cmp.Diff(stack.LinkResolutionResult{LinkAddress: linkAddr2, Success: true}, <-ch); diff != "" {
+					t.Fatalf("link resolution mismatch (-want +got):\n%s", diff)
+				}
+			}
+			if err := nudDisp.waitForEvent(eventInfo{
+				eventType: entryAdded,
+				nicID:     host1NICID,
+				entry:     stack.NeighborEntry{State: stack.Incomplete, Addr: test.neighborAddr},
+			}); err != nil {
+				t.Fatalf("error waiting for initial NUD event: %s", err)
+			}
+			if err := nudDisp.waitForEvent(eventInfo{
+				eventType: entryChanged,
+				nicID:     host1NICID,
+				entry:     stack.NeighborEntry{State: stack.Reachable, Addr: test.neighborAddr, LinkAddr: linkAddr2},
+			}); err != nil {
+				t.Fatalf("error waiting for reachable NUD event: %s", err)
+			}
+
+			// Wait for the remote's neighbor entry to be stale before creating a
+			// TCP connection from host1 to some remote.
+			nudConfigs, err := host1Stack.NUDConfigurations(host1NICID)
+			if err != nil {
+				t.Fatalf("host1Stack.NUDConfigurations(%d): %s", host1NICID, err)
+			}
+			// The maximum reachable time for a neighbor is some maximum random factor
+			// applied to the base reachable time.
+			//
+			// See NUDConfigurations.BaseReachableTime for more information.
+			maxReachableTime := time.Duration(float32(nudConfigs.BaseReachableTime) * nudConfigs.MaxRandomFactor)
+			clock.Advance(maxReachableTime)
+			if err := nudDisp.waitForEvent(eventInfo{
+				eventType: entryChanged,
+				nicID:     host1NICID,
+				entry:     stack.NeighborEntry{State: stack.Stale, Addr: test.neighborAddr, LinkAddr: linkAddr2},
+			}); err != nil {
+				t.Fatalf("error waiting for stale NUD event: %s", err)
+			}
+
+			listenerEP, clientEP, clientCH := test.getEndpoints(t, host1Stack, routerStack, host2Stack)
+			defer listenerEP.Close()
+			defer clientEP.Close()
+			listenerAddr := tcpip.FullAddress{Addr: test.remoteAddr, Port: 1234}
+			if err := listenerEP.Bind(listenerAddr); err != nil {
+				t.Fatalf("listenerEP.Bind(%#v): %s", listenerAddr, err)
+			}
+			if err := listenerEP.Listen(1); err != nil {
+				t.Fatalf("listenerEP.Listen(1): %s", err)
+			}
+			if err := clientEP.Connect(listenerAddr); err != tcpip.ErrConnectStarted {
+				t.Fatalf("got clientEP.Connect(%#v) = %s, want = %s", listenerAddr, err, tcpip.ErrConnectStarted)
+			}
+
+			// Wait for the TCP handshake to complete then make sure the neighbor is
+			// reachable without entering the probe state as TCP should provide NUD
+			// with confirmation that the neighbor is reachable (indicated by a
+			// successful 3-way handshake).
+			<-clientCH
+			if err := nudDisp.waitForEvent(eventInfo{
+				eventType: entryChanged,
+				nicID:     host1NICID,
+				entry:     stack.NeighborEntry{State: stack.Delay, Addr: test.neighborAddr, LinkAddr: linkAddr2},
+			}); err != nil {
+				t.Fatalf("error waiting for delay NUD event: %s", err)
+			}
+			if err := nudDisp.waitForEvent(eventInfo{
+				eventType: entryChanged,
+				nicID:     host1NICID,
+				entry:     stack.NeighborEntry{State: stack.Reachable, Addr: test.neighborAddr, LinkAddr: linkAddr2},
+			}); err != nil {
+				t.Fatalf("error waiting for reachable NUD event: %s", err)
+			}
+
+			// Wait for the neighbor to be stale again then send data to the remote.
+			//
+			// On successful transmission, the neighbor should become reachable
+			// without probing the neighbor as a TCP ACK would be received which is an
+			// indication of the neighbor being reachable.
+			clock.Advance(maxReachableTime)
+			if err := nudDisp.waitForEvent(eventInfo{
+				eventType: entryChanged,
+				nicID:     host1NICID,
+				entry:     stack.NeighborEntry{State: stack.Stale, Addr: test.neighborAddr, LinkAddr: linkAddr2},
+			}); err != nil {
+				t.Fatalf("error waiting for stale NUD event: %s", err)
+			}
+			var r bytes.Reader
+			r.Reset([]byte{0})
+			var wOpts tcpip.WriteOptions
+			if _, err := clientEP.Write(&r, wOpts); err != nil {
+				t.Errorf("clientEP.Write(_, %#v): %s", wOpts, err)
+			}
+			if err := nudDisp.waitForEvent(eventInfo{
+				eventType: entryChanged,
+				nicID:     host1NICID,
+				entry:     stack.NeighborEntry{State: stack.Delay, Addr: test.neighborAddr, LinkAddr: linkAddr2},
+			}); err != nil {
+				t.Fatalf("error waiting for delay NUD event: %s", err)
+			}
+			if test.isHost1Listener {
+				// If host1 is not the client, host1 does not send any data so TCP
+				// has no way to know it is making forward progress. Because of this,
+				// TCP should not mark the route reachable and NUD should go through the
+				// probe state.
+				clock.Advance(nudConfigs.DelayFirstProbeTime)
+				if err := nudDisp.waitForEvent(eventInfo{
+					eventType: entryChanged,
+					nicID:     host1NICID,
+					entry:     stack.NeighborEntry{State: stack.Probe, Addr: test.neighborAddr, LinkAddr: linkAddr2},
+				}); err != nil {
+					t.Fatalf("error waiting for probe NUD event: %s", err)
+				}
+			}
+			if err := nudDisp.waitForEvent(eventInfo{
+				eventType: entryChanged,
+				nicID:     host1NICID,
+				entry:     stack.NeighborEntry{State: stack.Reachable, Addr: test.neighborAddr, LinkAddr: linkAddr2},
+			}); err != nil {
+				t.Fatalf("error waiting for reachable NUD event: %s", err)
+			}
+		})
+	}
+}
diff --git a/pkg/tcpip/transport/tcp/connect.go b/pkg/tcpip/transport/tcp/connect.go
index 62954d7e4..6df4e6525 100644
--- a/pkg/tcpip/transport/tcp/connect.go
+++ b/pkg/tcpip/transport/tcp/connect.go
@@ -1335,6 +1335,14 @@ func (e *endpoint) protocolMainLoop(handshake bool, wakerInitDone chan<- struct{
 		}
 	}
 
+	// Reaching this point means that we successfully completed the 3-way
+	// handshake with our peer.
+	//
+	// Completing the 3-way handshake is an indication that the route is valid
+	// and the remote is reachable as the only way we can complete a handshake
+	// is if our SYN reached the remote and their ACK reached us.
+	e.route.ConfirmReachable()
+
 	drained := e.drainDone != nil
 	if drained {
 		close(e.drainDone)
diff --git a/pkg/tcpip/transport/tcp/snd.go b/pkg/tcpip/transport/tcp/snd.go
index 28ef9f899..027c2a4a8 100644
--- a/pkg/tcpip/transport/tcp/snd.go
+++ b/pkg/tcpip/transport/tcp/snd.go
@@ -1390,6 +1390,17 @@ func (s *sender) handleRcvdSegment(rcvdSeg *segment) {
 		acked := s.sndUna.Size(ack)
 		s.sndUna = ack
 
+		// The remote ACK-ing at least 1 byte is an indication that we have a
+		// full-duplex connection to the remote as the only way we will receive an
+		// ACK is if the remote received data that we previously sent.
+		//
+		// As of writing, linux seems to only confirm a route as reachable when
+		// forward progress is made which is indicated by an ACK that removes data
+		// from the retransmit queue.
+		if acked > 0 {
+			s.ep.route.ConfirmReachable()
+		}
+
 		ackLeft := acked
 		originalOutstanding := s.outstanding
 		for ackLeft > 0 {
author	Ghanan Gowripalan <ghanan@google.com>	2021-01-27 19:06:47 -0800
committer	gVisor bot <gvisor-bot@google.com>	2021-01-27 19:08:51 -0800
commit	b85b23e50d1c264ff4821e182ad89a8ea3d0e0c5 (patch)
tree	9180366b5d4106e048b41fd1d34a436be6719d0f /pkg/tcpip
parent	1d22284c13cc040e52c2130386c10d8f84f6bbd6 (diff)