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RFC1433 - Directed ARP

王朝other·作者佚名  2008-05-31
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Network Working Group J. Garrett

Request for Comments: 1433 AT&T Bell Laboratories

J. Hagan

University of Pennsylvania

J. Wong

AT&T Bell Laboratories

March 1993

Directed ARP

Status of this Memo

This memo defines an EXPerimental Protocol for the Internet

community. Discussion and suggestions for improvement are requested.

Please refer to the current edition of the "IAB Official Protocol

Standards" for the standardization state and status of this protocol.

Distribution of this memo is unlimited.

Abstract

A router with an interface to two IP networks via the same link level

interface could observe that the two IP networks share the same link

level network, and could advertise that information to hosts (via

ICMP Redirects) and routers (via dynamic routing protocols).

However, a host or router on only one of the IP networks could not

use that information to communicate directly with hosts and routers

on the other IP network unless it could resolve IP addresses on the

"foreign" IP network to their corresponding link level addresses.

Directed ARP is a dynamic address resolution procedure that enables

hosts and routers to resolve advertised potential next-hop IP

addresses on foreign IP networks to their associated link level

addresses.

Acknowledgments

The authors are indeBTed to Joel Halpern of Network Systems

Corporation and David O'Leary who provided valuable comments and

insight to the authors, as well as ongoing moral support as the

presentation of this material evolved through many drafts. Members

of the IPLPDN working group also provided valuable comments during

presentations and through the IPLPDN mailing list. ChUCk Hedrick of

Rutgers University, Paul Tsuchiya of Bell Communications Research,

and Doris Tillman of AT&T Bell Laboratories provided early insight as

well as comments on early drafts.

1. Terminology

A "link level network" is the upper layer of what is sometimes

referred to (e.g., OSI parlance) as the "subnetwork", i.e., the

layers below IP. The term "link level" is used to avoid potential

confusion with the term "IP sub-network", and to identify addresses

(i.e., "link level address") associated with the network used to

transport IP datagrams.

From the perspective of a host or router, an IP network is "foreign"

if the host or router does not have an address on the IP network.

2. Introduction

Multiple IP networks may be administered on the same link level

network (e.g., on a large public data network). A router with a

single interface on two IP networks could use existing routing update

procedures to advertise that the two IP networks shared the same link

level network. Cost/performance benefits could be achieved if hosts

and routers that were not on the same IP network could use that

advertised information, and exchange packets directly, rather than

through the dual addressed router. But a host or router can not send

packets directly to an IP address without first resolving the IP

address to its link level address.

IP address resolution procedures are established independently for

each IP network. For example, on an SMDS network [1], address

resolution may be achieved using the Address Resolution Protocol

(ARP) [2], with a separate SMDS ARP Request Address (e.g., an SMDS

Multicast Group Address) associated with each IP network. A host or

router that was not configured with the appropriate ARP Request

Address would have no way to learn the ARP Request Address associated

with an IP network, and would not send an ARP Request to the

appropriate ARP Request Address. On an Ethernet network a host or

router might guess that an IP address could be resolved by sending an

ARP Request to the broadcast address. But if the IP network used a

different address resolution procedure (e.g., administered address

resolution tables), the ARP Request might go unanswered.

Directed ARP is a procedure that enables a router advertising that an

IP address is on a shared link level network to also aid in resolving

the IP address to its associated link level address. By removing

address resolution constraints, Directed ARP enables dynamic routing

protocols such as BGP [3] and OSPF [4] to advertise and use routing

information that leads to next-hop addresses on "foreign" IP

networks. In addition, Directed ARP enables routers to advertise

(via ICMP Redirects) next-hop addresses that are "foreign" to hosts,

since the hosts can use Directed ARP to resolve the "foreign" next-

hop addresses.

3. Directed ARP

Directed ARP uses the normal ARP packet format, and is consistent

with ARP procedures, as defined in [1] and [2], and with routers and

hosts that implement those procedures.

3.1 ARP Helper Address

Hosts and routers maintain routing information, logically organized

as a routing table. Each routing table entry associates one or more

destination IP addresses with a next-hop IP address and a physical

interface used to forward a packet to the next-hop IP address. If

the destination IP address is local (i.e., can be reached without the

aid of a router), the next-hop IP address is NULL (or a logical

equivalent, such as the IP address of the associated physical

interface). Otherwise, the next-hop IP address is the address of a

next-hop router.

A host or router that implements Directed ARP procedures associates

an ARP Helper Address with each routing table entry. If the host or

router has been configured to resolve the next-hop IP address to its

associated link level address (or to resolve the destination IP

address, if the next-hop IP address is NULL), the associated ARP

Helper Address is NULL. Otherwise, the ARP Helper Address is the IP

address of the router that provided the routing information

indicating that the next-hop address was on the same link level

network as the associated physical interface. Section 4 provides

detailed examples of the determination of ARP Helper Addresses by

dynamic routing procedures.

3.2 Address Resolution Procedures

To forward an IP packet, a host or router searches its routing table

for an entry that is the best match based on the destination IP

address and perhaps other factors (e.g., Type of Service). The

selected routing table entry includes the IP address of a next-hop

router (which may be NULL), the physical interface through which the

IP packet should be forwarded, an ARP Helper Address (which may be

NULL), and other information. The routing function passes the next-

hop IP address, the physical interface, and the ARP Helper Address to

the address resolution function. The address resolution function

must then resolve the next-hop IP address (or destination IP address

if the next-hop IP address is NULL) to its associated link level

address. The IP packet, the link level address to which the packet

should be forwarded, and the interface through which the packet

should be forwarded are then passed to the link level driver

associated with the physical interface. The link level driver

encapsulates the IP packet in one or more link level frames (i.e.,

may do fragmentation) addressed to the associated link level address,

and forwards the frame(s) through the appropriate physical interface.

The details of the functions performed are described via C pseudo-

code below.

The procedures are organized as two functions, Route() and Resolve(),

corresponding to routing and address resolution. In addition, the

following low level functions are also used:

Get_Route(IP_Add,Other) returns a pointer to the routing table

entry with the destination field that best matches IP_Add. If no

matching entry is found, NULL is returned. Other information such

as Type of Service may be considered in selecting the best route.

Forward(Packet,Link_Level_Add,Phys_Int) fragments Packet (if

needed), and encapsulates Packet in one or more Link Level Frames

addressed to Link_Level_Add, and forwards the frame(s) through

interface, Phys_Int.

Look_Up_Add_Res_Table(IP_Add,Phys_Int) returns a pointer to the

link level address associated with IP_Add in the address

resolution table associated with interface, Phys_Int. If IP_Add

is not found in the address resolution table, NULL is returned.

Local_Add_Res(IP_Add,Phys_Int) returns a pointer to the Link Level

address associated with IP_Add, using address resolution

procedures associated with address, IP_Add, and interface,

Phys_Int. If address resolution is unsuccessful, NULL is

returned. Note that different address resolution procedures may

be used for different IP networks.

Receive_ARP_Response(IP_Add,Phys_Int) returns a pointer to an ARP

Response received through interface, Phys_Int, that resolves

IP_Add. If no ARP response is received, NULL is returned.

Dest_IP_Add(IP_Packet) returns the IP destination address from

IP_Packet.

Next_Hop(Entry) returns the IP address in the next-hop field of

(routing table) Entry.

Interface(Entry) returns the physical interface field of (routing

table) Entry.

ARP_Helper_Add(Entry) returns the IP address in the ARP Helper

Address field of (routing table) Entry.

ARP_Request(IP_Add) returns an ARP Request packet with IP_Add as

the Target IP address.

Source_Link_Level(ARP_Response) returns the link level address of

the sender of ARP_Response.

ROUTE(IP_Packet)

{

Entry = Get_Route(Dest_IP_Add(IP_Packet),Other(IP_Packet));

If (Entry == NULL) /* No matching entry in routing table */

Return; /* Discard IP_Packet */

else

{ /* Resolve next-hop IP address to link level address */

If (Next_Hop(Entry) != NULL) /* Route packet via next-hop router */

Next_IP = Next_Hop(Entry);

else /* Destination is local */

Next_IP = Dest_IP_Add(IP_Packet);

L_L_Add = Resolve(Next_IP,Interface(Entry),ARP_Helper_Add(Entry));

If (L_L_Add != NULL)

Forward(IP_Packet,L_L_Add,Interface(Entry));

else /* Couldn't resolve next-hop IP address */

Return; /* Discard IP_Packet */

Return;

}

}

Figure 1: C Pseudo-Code for the Routing function.

Resolve(IP_Add,Interface,ARP_Help_Add)

{

If ((L_L_Add = Look_Up_Add_Res_Table(IP_Add,Interface)) != NULL)

{ /* Found it in Address Resolution Table */

Return L_L_Add;

}

else

{

If (ARP_Help_Add == NULL)

{ /* Do local Address Resolution Procedure */

Return Local_Add_Res(IP_Add,Interface);

}

else /* ARP_Help_Add != NULL */

{

L_L_ARP_Help_Add = Look_Up_Add_Res_Table(ARP_Help_Add,Interface);

If (L_L_ARP_Help_Add == NULL)

/* Not in Address Resolution Table */

L_L_ARP_Help_Add = Local_Add_Res(ARP_Help_Add,Interface);

If (L_L_ARP_Help_Add == NULL) /* Can't Resolve ARP Helper Add */

Return NULL; /* Address Resolution Failed */

else

{ /* ARP for IP_Add */

Forward(ARP_Request(IP_Add),L_L_ARP_Help_Add,Interface);

ARP_Resp = Receive_ARP_Response(IP_Add,Interface);

If (ARP_Resp == NULL) /* No ARP Response (after persistence) */

Return NULL; /* Address Resolution Failed */

else

Return Source_Link_Level(ARP_Resp);

}

}

}

}

}

Figure 2: C Pseudo-Code for Address Resolution function.

3.3 Forwarding ARP Requests

A host that implements Directed ARP procedures uses normal procedures

to process received ARP Requests. That is, if the Target IP address

is the host's address, the host uses normal procedures to respond to

the ARP Request. If the Target IP address is not the host's address,

the host silently discards the ARP Request.

If the Target IP address of an ARP Request received by a router is

the router's address, the router uses normal procedures to respond to

the ARP Request. But if the Target IP address is not the router's

address, the router may forward the ARP Request back through the same

interface it was received from, addressed to a Link Level Address

that corresponds to an ARP Helper Address in the router's routing

table. The procedures used to process an ARP Request are described

via C pseudo-code below. The function Receive() describes procedures

followed by hosts and routers, and the function Direct() describes

additional procedures followed by routers. In addition, the

following low level functions are also used:

Is_Local_IP_Add(IP_Add,Phys_Int) returns TRUE if Phys_Int has been

assigned IP address, IP_Add. Otherwise, returns FALSE.

Do_ARP_Processing(ARP_Request,Interface) processes ARP_Request

using ARP procedures described in [2].

I_Am_Router returns TRUE if device is a router and False if device

is a host.

Target_IP(ARP_Request) returns the Target IP address from

ARP_Request.

Filter(ARP_Request,Phys_Int) returns TRUE if ARP_Request passes

filtering constraints, and FALSE if filtering constraints are not

passed. See section 3.4.

Forward(Packet,Link_Level_Add,Phys_Int) fragments Packet (if

needed), and encapsulates Packet in one or more Link Level Frames

addressed to Link_Level_Add, and forwards the frame(s) through

interface, Phys_Int.

Look_Up_Next_Hop_Route_Table(IP_Add) returns a pointer to the

routing table entry with the next-hop field that matches IP_Add.

If no matching entry is found, NULL is returned.

Look_Up_Dest_Route_Table(IP_Add) returns a pointer to the routing

table entry with the destination field that best matches IP_Add.

If no matching entry is found, NULL is returned.

Link_Level_ARP_Req_Add(IP_Add,Phys_Int) returns the link level

address to which an ARP Request to resolve IP_Add should be

forwarded. If ARP is not used to perform local address resolution

of IP_Add, NULL is returned.

Local_Add_Res(IP_Add,Phys_Int) returns a pointer to the Link Level

address associated with IP_Add, using address resolution

procedures associated with address, IP_Add, and interface,

Phys_Int. If address resolution is unsuccessful, NULL is

returned. Note that different address resolution procedures may

be used for different IP networks.

Next_Hop(Entry) returns the IP address in the next-hop field of

(routing table) Entry.

Interface(Entry) returns the physical interface field of (routing

table) Entry.

ARP_Helper_Add(Entry) returns the IP address in the ARP Helper

Address field of (routing table) Entry.

Source_Link_Level(ARP_Request) returns the link level address of

the sender of ARP_Request.

Receive(ARP_Request,Interface)

{

If (Is_Local_IP_Add(Target_IP(ARP_Request),Interface))

Do_ARP_Processing(ARP_Request,Interface);

else /* Not my IP Address */

If (I_Am_Router) /* Hosts don't Direct ARP Requests */

If (Filter(ARP_Request,Interface)) /* Passes Filter Test */

/* See Section 3.4 */

Direct(ARP_Request,Interface); /* Directed ARP Procedures */

Return;

}

Figure 3: C Pseudo-Code for Receiving ARP Requests.

Direct(ARP_Request,Phys_Int)

{

Entry = Look_Up_Next_Hop_Route_Table(Target_IP(ARP_Request));

If (Entry == NULL) /* Target_IP Address is not a next-hop */

{ /* in Routing Table */

Entry = Look_Up_Dest_Route_Table(Target_IP(ARP_Request));

If (Entry == NULL) /* Not a destination either */

Return; /* Discard ARP Request */

else

If (Next_Hop(Entry) != NULL) /* Not a next-hop and Not local */

Return; /* Discard ARP Request */

}

If (Interface(Entry) != Phys_Int)

/* Must be same physical interface */

Return; /* Discard ARP Request */

If (ARP_Helper_Add(Entry) != NULL)

{

L_L_ARP_Helper_Add = Resolve(ARP_Helper_Add(Entry),Phys_Int,NULL);

If (L_L_ARP_Helper_Add != NULL)

Forward(ARP_Request,L_L_ARP_Helper_Add,Phys_Int);

/* Forward ARP_Request to ARP Helper Address */

Return;

}

else /* Do local address resolution. */

{

L_L_ARP_Req_Add =

Link_Level_ARP_Req_Add(Target_IP(ARP_Request),Phys_Int);

If (L_L_ARP_Req_Add != NULL)

{ /* Local address resolution procedure is ARP. */

/* Forward ARP_Request. */

Forward(ARP_Request,L_L_ARP_Req_Add,Phys_Int);

Return;

}

else

{ /* Local address resolution procedure is not ARP. */

/* Do "published ARP" on behalf of Target IP Address */

Target_Link_Level =

Local_Add_Res(Target_IP(ARP_Request),Phys_Int);

If (Target_Link_Level != NULL) /* Resolved Address */

{

Forward(ARP_Response,Source_Link_Level(ARP_Request),Phys_Int);

}

Return;

}

}

}

Figure 4: C Pseudo_Code for Directing ARP Requests.

3.4 Filtering Procedures

A router performing Directed ARP procedures must filter the

propagation of ARP Request packets to constrain the scope of

potential "ARP floods" caused by misbehaving routers or hosts, and to

terminate potential ARP loops that may occur during periods of

routing protocol instability or as a result of inappropriate manual

configurations. Specific procedures to filter the propagation of ARP

Request packets are beyond the scope of this document. The following

procedures are suggested as potential implementations that should be

sufficient. Other procedures may be better suited to a particular

implementation.

To control the propagation of an "ARP flood", a router performing

Directed ARP procedures could limit the number of identical ARP

Requests (i.e., same Source IP address and same Target IP address)

that it would forward per small time interval (e.g., no more than one

ARP Request per second). This is consistent with the procedure

suggested in [5] to prevent ARP flooding.

Forwarding of ARP Request packets introduces the possibility of ARP

loops. The procedures used to control the scope of potential ARP

floods may terminate some ARP loops, but additional procedures are

needed if the time required to traverse a loop is longer than the

timer used to control ARP floods. A router could refuse to forward

more than N identical ARP Requests per T minutes, where N and T are

administered numbers. If T and N are chosen so that T/N minutes is

greater than the maximum time required to traverse a loop, such a

filter would terminate the loop. In some cases a host may send more

than one ARP Request with the same Source IP address,Target IP

address pair (i.e., N should be greater than 1). For example, the

first ARP Request might be lost. However, once an ARP Response is

received, a host would normally save the associated information, and

therefore would not generate an identical ARP Request for a period of

time on the order of minutes. Therefore, T may be large enough to

ensure that T/N is much larger than the time to traverse any loop.

In some implementations the link level destination address of a frame

used to transport an ARP Request to a router may be available to the

router's Directed ARP filtering process. An important class of

simple ARP loops will be prevented from starting if a router never

forwards an ARP Request to the same link level address to which the

received ARP Request was addressed. Of course, other procedures such

as the one described in the paragraph above will stop all loops, and

are needed, even if filters are implemented that prevent some loops

from starting.

Host requirements [5] specify that "the packet receive interface

between the IP layer and the link layer MUST include a flag to

indicate whether the incoming packet was addressed to a link-level

broadcast address." An important class of simple ARP floods can be

eliminated if routers never forward ARP Requests that were addressed

to a link-level broadcast address.

4. Use of Directed ARP by Routing

The exchange and use of routing information is constrained by

available address resolution procedures. A host or router can not

use a next-hop IP address learned via dynamic routing procedures if

it is unable to resolve the next-hop IP address to the associated

link level address. Without compatible dynamic address resolution

procedures, a router may not advertise a next-hop address that is not

on the same IP network as the host or router receiving the

advertisement. Directed ARP is a procedure that enables a router

that advertises routing information to make the routing information

useful by also providing assistance in resolving the associated

next-hop IP addresses.

The following subsections describe the use of Directed ARP to expand

the scope of ICMP Redirects [6], distance-vector routing protocols

(e.g., BGP [3]), and link-state routing protocols (e.g., OSPF [4]).

4.1 ICMP Redirect

If a router forwards a packet to a next-hop address that is on the

same link level network as the host that originated the packet, the

router may send an ICMP Redirect to the host. But a host can not use

a next-hop address advertised via an ICMP Redirect unless the host

has a procedure to resolve the advertised next-hop address to its

associated link level address. Directed ARP is a procedure that a

host could use to resolve an advertised next-hop address, even if the

host does not have an address on the same IP network as the

advertised next-hop address.

A host that implements Directed ARP procedures includes an ARP Helper

Address with each routing table entry. The ARP Helper Address

associated with an entry learned via an ICMP Redirect is NULL if the

associated next-hop address matches a routing table entry with a NULL

next-hop and a NULL ARP Helper Address (i.e., the host already knows

how to resolve the next-hop address). Otherwise, the ARP Helper

Address is the IP address of the router that sent the ICMP Redirect.

Note that the router that sent the ICMP Redirect is the current

next-hop to the advertised destination [5]. Therefore, the host

should have an entry in its address resolution table for the new ARP

Helper Address. If the host is unable to resolve the next-hop IP

address advertised in the ICMP Redirect (e.g., because the associated

ARP Helper Address is on a foreign IP network; i.e., was learned via

an old ICMP Redirect, and the address resolution table entry for that

ARP Helper Address timed out), the host must flush the associated

routing table entry. Directed ARP procedures do not recursively use

Directed ARP to resolve an ARP Helper Address.

A router that performs Directed ARP procedures might advertise a

foreign next-hop to a host that does not perform Directed ARP.

Following existing procedures, the host would silently discard the

ICMP Redirect. A router that does not implement Directed ARP should

not advertise a next-hop on a foreign IP network, as specified by

existing procedures. If it did, and the ICMP Redirect was received

by a host that implemented Directed ARP procedures, the host would

send an ARP Request for the foreign IP address to the advertising

router, which would silently discard the ARP Request. When address

resolution fails, the host should flush the associated entry from its

routing table.

For various reasons a host may ignore an ICMP Redirect and may

continue to forward packets to the same router that sent the ICMP

Redirect. For example, a host that does not implement Directed ARP

procedures would silently discard an ICMP Redirect advertising a

next-hop address on a foreign IP network. Routers should implement

constraints to control the number of ICMP Redirects sent to hosts.

For example, a router might limit the number of repeated ICMP

Redirects sent to a host to no more than N ICMP Redirects per T

minutes, where N and T are administered values.

4.2 Distance Vector Routing Protocol

A distance-vector routing protocol provides procedures for a router

to advertise a destination address (e.g., an IP network), an

associated next-hop address, and other information (e.g., associated

metric). But a router can not use an advertised route unless the

router has a procedure to resolve the advertised next-hop address to

its associated link level address. Directed ARP is a procedure that

a router could use to resolve an advertised next-hop address, even if

the router does not have an address on the same IP network as the

advertised next-hop address.

The following procedures assume a router only accepts routing updates

if it knows the IP address of the sender of the update, can resolve

the IP address of the sender to its associated link level address,

and has an interface on the same link level network as the sender.

A router that implements Directed ARP procedures includes an ARP

Helper Address with each routing table entry. The ARP Helper Address

associated with an entry learned via a routing protocol update is

NULL if the associated next-hop address matches a routing table entry

with a NULL next-hop and NULL ARP Helper Address (i.e., the router

already knows how to resolve the next-hop address). Otherwise, the

ARP Helper Address is the IP address of the router that sent the

routing update.

Some distance-vector routing protocols (e.g., BGP [3]) provide syntax

that would permit a router to advertise an address on a foreign IP

network as a next-hop. If a router that implements Directed ARP

procedures advertises a foreign next-hop IP address to a second

router that does not implement Directed ARP procedures, the second

router can not use the advertised foreign next-hop. Depending on the

details of the routing protocol implementation, it might be

appropriate for the first router to also advertise a next-hop that is

not on a foreign IP network (e.g., itself), perhaps at a higher cost.

Or, if the routing relationship is an administered connection (e.g.,

BGP relationships are administered TCP/IP connections), the

administrative procedure could determine whether foreign next-hop IP

addresses should be advertised.

A distance-vector routing protocol could advertise that a destination

is directly reachable by specifying that the router receiving the

advertisement is, itself, the next-hop to the destination. In

addition, the advertised metric for the route might be zero. If the

router did not already have a routing table entry that specified the

advertised destination was local (i.e., NULL next-hop address), the

router could add the new route with NULL next-hop, and the IP address

of the router that sent the update as ARP Helper Address.

4.3 Link State Routing Protocol

A link-state routing protocol provides procedures for routers to

identify links to other entities (e.g., other routers and networks),

determine the state or cost of those links, reliably distribute

link-state information to other routers in the routing domain, and

calculate routes based on link-state information received from other

routers. A router with an interface to two (or more) IP networks via

the same link level interface is connected to those IP networks via a

single link, as described above. If a router could advertise that it

used the same link to connect to two (or more) IP networks, and would

perform Directed ARP procedures, routers on either of the IP networks

could forward packets directly to hosts and routers on both IP

networks, using Directed ARP procedures to resolve addresses on the

foreign IP network. With Directed ARP, the cost of the direct path

to the foreign IP network would be less than the cost of the path

through the router with addresses on both IP networks.

To benefit from Directed ARP procedures, the link-state routing

protocol must include procedures for a router to advertise

connectivity to multiple IP networks via the same link, and the

routing table calculation process must include procedures to

calculate ARP Helper Addresses and procedures to accurately calculate

the reduced cost of the path to a foreign IP network reached directly

via Directed ARP procedures.

The Shortest Path First algorithm for calculating least cost routes

is based on work by Dijkstra [7], and was first used in a routing

protocol by the ARPANET, as described by McQuillan [8]. A router

constructs its routing table by building a shortest path tree, with

itself as root. The process is iterative, starting with no entries

on the shortest path tree, and the router, itself, as the only entry

in a list of candidate vertices. The router then loops on the

following two steps.

1. Remove the entry from the candidate list that is closest to

root, and add it to the shortest path tree.

2. Examine the link state advertisement from the entry added to

the shortest path tree in step 1. For each neighbor (i.e.,

router or IP network to which a link connects)

- If the neighbor is already on the shortest path tree, do

nothing.

- If the neighbor is on the candidate list, recalculate the

distance from root to the neighbor. Also recalculate the

next-hop(s) to the neighbor.

- If the neighbor is not on the candidate list, calculate

the distance from root to the neighbor and the next-hop(s)

from root to the neighbor, and add the neighbor to the

candidate list.

The process terminates when there are no entries on the candidate list.

To take advantage of Directed ARP procedures, the link-state protocol

must provide procedures to advertise that a router Accesses two or more

IP networks via the same link. In addition, the Shortest Path First

calculation is modified to calculate ARP Helper Addresses and recognize

path cost reductions achieved via Directed ARP.

1. If a neighbor under consideration is an IP network, and its

parent (i.e., the entry added to the shortest path tree in step

1, above) has advertised that the neighbor is reached via the

same link as a network that is already on the shortest path

tree, the distance from root and next-hop(s) from root to the

neighbor are the same as the distance and next-hop(s)

associated with the network already on the shortest path tree.

If the ARP Helper Address associated with the network that is

already on the shortest path tree is not NULL, the neighbor

also inherits the ARP Helper Address from the network that is

already on the shortest path tree.

2. If the calculated next-hop to the neighbor is not NULL, the

neighbor inherits the ARP Helper Address from its parent.

Otherwise, except as described in item 1, the ARP Helper

Address is the IP address of the next-hop to the neighbor's

parent. Note that the next-hop to root is NULL.

For each router or IP network on the shortest path tree, the Shortest

Path First algorithm described above must calculate one or more

next-hops that can be used to access the router or IP network. A

router that advertises a link to an IP network must include an IP

address that can be used by other routers on the IP network when

using the router as a next-hop. A router might advertise that it was

connected to two IP networks via the same link by advertising the

same next-hop IP address for access from both IP networks. To

accommodate the address resolution constraints of routers on both IP

networks the router might advertise two IP addresses (one from each

IP network) as next-hop IP addresses for access from both IP

networks.

5. Robustness

Hosts and routers can use Directed ARP to resolve third-party next-

hop addresses; i.e., next-hop addresses learned from a routing

protocol peer or current next-hop router. Undetected failure of a

third party next-hop can result in a routing "black hole". To avoid

"black holes", host requirements [5] specify that a host "...MUST be

able to detect the failure of a 'next-hop' gateway that is listed in

its route cache and to choose an alternate gateway." A host may

receive feedback from protocol layers above IP (e.g., TCP) that

indicates the status of a next-hop router, and may use other

procedures (e.g., ICMP echo) to test the status of a next-hop router.

But the complexity of routing is borne by routers, whose routing

information must be consistent with the information known to their

peers. Routing protocols such as BGP [3], OSPF [4], and others,

require that routers must stand behind routing information that they

advertise. Routers tag routing information with the IP address of

the router that advertised the information. If the information

becomes invalid, the router that advertised the information must

advertise that the old information is no longer valid. If a source

of routing information becomes unavailable, all information received

from that source must be marked as no longer valid. The complexity

of dynamic routing protocols stems from procedures to ensure routers

either receive routing updates sent by a peer, or are able to

determine that they did not receive the updates (e.g., because

connectivity to the peer is no longer available).

Third-party next-hops can also result in "black holes" if the

underlying link layer network connectivity is not transitive. For

example, SMDS filters [9] could be administered to permit

communication between the SMDS addresses of router R1 and router R2,

and between the SMDS addresses of router R2 and router R3, and to

block communication between the SMDS addresses of router R1 and

router R3. Router R2 could advertise router R3 as a next-hop to

router R1, but SMDS filters would prevent direct communication

between router R1 and router R3. Non-symmetric filters might permit

router R3 to send packets to router R1, but block packets sent by

router R1 addressed to router R3.

A host or router could verify link level connectivity with a next-hop

router by sending an ICMP echo to the link level address of the

next-hop router. (Note that the ICMP echo is sent directly to the

link level address of the next-hop router, and is not routed to the

IP address of the next-hop router. If the ICMP echo is routed, it

may follow a path that does not verify link level connectivity.) This

test could be performed before adding the associated routing table

entry, or before the first use of the routing table entry. Detection

of subsequent changes in link level connectivity is a dynamic routing

protocol issue and is beyond the scope of this memo.

References

[1] Piscitello, D., and J. Lawrence, "The Transmission of IP

Datagrams over the SMDS Service", RFC1209, Bell Communications

Research, March 1991.

[2] Plummer, D., "An Ethernet Address Resolution Protocol - or -

Converting Network Protocol Addresses to 48.bit Ethernet Address

for Transmission on Ethernet Hardware", RFC826, Symbolics, Inc.,

November 1982.

[3] Lougheed, K. and Y. Rekhter, "A Border Gateway Protocol 3 (BGP-

3)", RFC1267, cisco Systems and IBM T. J. Watson Research

Center, October 1991.

[4] Moy, J., "OSPF Version 2", RFC1247, Proteon, Inc., July 1991.

[5] Braden, R., editor, "Requirements for Internet Hosts --

Communication Layers", STD 3, RFC1122, USC/Information Sciences

Institute, October 1989.

[6] Postel, J., "Internet Control Message Protocol - DARPA Internet

Program Protocol Specification", STD 5, RFC792, USC/Information

Sciences Institute, September 1981.

[7] Dijkstra, E. W., "A Note on Two Problems in Connection with

Graphs", Numerische Mathematik, Vol. 1, pp. 269-271, 1959.

[8] McQuillan, J. M., I. Richer, and E. C. Rosen, "The New Routing

Algorithm for the ARPANET", IEEE Transactions on Communications,

Vol. COM-28, May 1980.

[9] "Generic System Requirements In Support of Switched Multi-

megabit Data Service", Technical Reference TR-TSV-000772, Bell

Communications Research Technical Reference, Issue 1, May 1991.

Security Considerations

Security issues are not discussed in this memo.

Authors' Addresses

John Garrett

AT&T Bell Laboratories

184 Liberty Corner Road

Warren, N.J. 07060-0906

Phone: (908) 580-4719

EMail: jwg@garage.att.com

John Dotts Hagan

University of Pennsylvania

Suite 221A

3401 Walnut Street

PhilaDelphia, PA 19104-6228

Phone: (215) 898-9192

EMail: Hagan@UPENN.EDU

Jeffrey A. Wong

AT&T Bell Laboratories

184 Liberty Corner Road

Warren, N.J. 07060-0906

Phone: (908) 580-5361

EMail: jwong@garage.att.com

 
 
 
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