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RFC3102 - Realm Specific IP: Framework

王朝other·作者佚名  2008-05-31
窄屏简体版  字體: |||超大  

Network Working Group Editors:

Request for Comments: 3102 M. Borella

Category: EXPerimental CommWorks

J. Lo

Candlestick Networks

Contributors:

D. Grabelsky

CommWorks

G. Montenegro

Sun Microsystems

October 2001

Realm Specific IP: Framework

Status of this Memo

This memo defines an Experimental Protocol for the Internet

community. It does not specify an Internet standard of any kind.

Discussion and suggestions for improvement are requested.

Distribution of this memo is unlimited.

Copyright Notice

Copyright (C) The Internet Society (2001). All Rights Reserved.

IESG Note

The IESG notes that the set of documents describing the RSIP

technology imply significant host and gateway changes for a complete

implementation. In addition, the floating of port numbers can cause

problems for some applications, preventing an RSIP-enabled host from

interoperating transparently with existing applications in some cases

(e.g., IPsec). Finally, there may be significant operational

complexities associated with using RSIP. Some of these and other

complications are outlined in section 6 of RFC3102, as well as in

the Appendices of RFC3104. Accordingly, the costs and benefits of

using RSIP should be carefully weighed against other means of

relieving address shortage.

Abstract

This document examines the general framework of Realm Specific IP

(RSIP). RSIP is intended as a alternative to NAT in which the end-

to-end integrity of packets is maintained. We focus on

implementation issues, deployment scenarios, and interaction with

other layer-three protocols.

Table of Contents

1. IntrodUCtion . . . . . . . . . . . . . . . . . . . . . . . . 2

1.1. Document Scope . . . . . . . . . . . . . . . . . . . . . . 4

1.2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . 4

1.3. Specification of Requirements . . . . . . . . . . . . . . . 5

2. Architecture . . . . . . . . . . . . . . . . . . . . . . . . 6

3. Requirements . . . . . . . . . . . . . . . . . . . . . . . . 7

3.1. Host and Gateway Requirements . . . . . . . . . . . . . . . 7

3.2. Processing of Demultiplexing Fields . . . . . . . . . . . . 8

3.3. RSIP Protocol Requirements and Recommendations . . . . . . 9

3.4. Interaction with DNS . . . . . . . . . . . . . . . . . . . 10

3.5. Locating RSIP Gateways . . . . . . . . . . . . . . . . . . 11

3.6. Implementation Considerations . . . . . . . . . . . . . . . 11

4. Deployment . . . . . . . . . . . . . . . . . . . . . . . . . 12

4.1. Possible Deployment Scenarios . . . . . . . . . . . . . . . 12

4.2. Cascaded RSIP and NAT . . . . . . . . . . . . . . . . . . . 14

5. Interaction with Layer-Three Protocols . . . . . . . . . . . 17

5.1. IPSEC . . . . . . . . . . . . . . . . . . . . . . . . . . . 17

5.2. Mobile IP . . . . . . . . . . . . . . . . . . . . . . . . . 18

5.3. Differentiated and Integrated Services . . . . . . . . . . 18

5.4. IP Multicast . . . . . . . . . . . . . . . . . . . . . . . 21

6. RSIP Complications . . . . . . . . . . . . . . . . . . . . . 23

6.1. Unnecessary TCP TIME_WAIT . . . . . . . . . . . . . . . . . 23

6.2. ICMP State in RSIP Gateway . . . . . . . . . . . . . . . . 23

6.3. Fragmentation and IP Identification Field Collision . . . . 24

6.4. Application Servers on RSAP-IP Hosts . . . . . . . . . . . 24

6.5. Determining Locality of Destinations from an RSIP Host. . . 25

6.6. Implementing RSIP Host Deallocation . . . . . . . . . . . . 26

6.7. Multi-Party Applications . . . . . . . . . . . . . . . . . 26

6.8. Scalability . . . . . . . . . . . . . . . . . . . . . . . . 27

7. Security Considerations . . . . . . . . . . . . . . . . . . . 27

8. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 27

9. References . . . . . . . . . . . . . . . . . . . . . . . . . 28

10. Authors' Addresses . . . . . . . . . . . . . . . . . . . . . 29

11. Full Copyright Statement . . . . . . . . . . . . . . . . . . 30

1. Introduction

Network Address Translation (NAT) has become a popular mechanism of

enabling the separation of addressing spaces. A NAT router must

examine and change the network layer, and possibly the transport

layer, header of each packet crossing the addressing domains that the

NAT router is connecting. This causes the mechanism of NAT to

violate the end-to-end nature of the Internet connectivity, and

disrupts protocols requiring or enforcing end-to-end integrity of

packets.

While NAT does not require a host to be aware of its presence, it

requires the presence of an application layer gateway (ALG) within

the NAT router for each application that embeds addressing

information within the packet payload. For example, most NATs ship

with an ALG for FTP, which transmits IP addresses and port numbers on

its control channel. RSIP (Realm Specific IP) provides an

alternative to remedy these limitations.

RSIP is based on the concept of granting a host from one addressing

realm a presence in another addressing realm by allowing it to use

resources (e.g., addresses and other routing parameters) from the

second addressing realm. An RSIP gateway replaces the NAT router,

and RSIP-aware hosts on the private network are referred to as RSIP

hosts. RSIP requires ability of the RSIP gateway to grant such

resources to RSIP hosts. ALGs are not required on the RSIP gateway

for communications between an RSIP host and a host in a different

addressing realm.

RSIP can be viewed as a "fix", of sorts, to NAT. It may ameliorate

some IP address shortage problems in some scenarios without some of

the limitations of NAT. However, it is not a long-term solution to

the IP address shortage problem. RSIP allows a degree of address

realm transparency to be achieve between two differently-scoped, or

completely different addressing realms. This makes it a useful

architecture for enabling end-to-end packet transparency between

addressing realms. RSIP is expected to be deployed on privately

addresses IPv4 networks and used to grant Access to publically

addressed IPv4 networks. However, in place of the private IPv4

network, there may be an IPv6 network, or a non-IP network. Thus,

RSIP allows IP connectivity to a host with an IP stack and IP

applications but no native IP access. As such, RSIP can be used, in

conjunction with DNS and tunneling, to bridge IPv4 and IPv6 networks,

such that dual-stack hosts can communicate with local or remote IPv4

or IPv6 hosts.

It is important to note that, as it is defined here, RSIP does NOT

require modification of applications. All RSIP-related modifications

to an RSIP host can occur at layers 3 and 4. However, while RSIP

does allow end-to-end packet transparency, it may not be transparent

to all applications. More details can be found in the section "RSIP

complications", below.

1.1. Document Scope

This document provides a framework for RSIP by focusing on four

particular areas:

- Requirements of an RSIP host and RSIP gateway.

- Likely initial deployment scenarios.

- Interaction with other layer-three protocols.

- Complications that RSIP may introduce.

The interaction sections will be at an overview level. Detailed

modifications that would need to be made to RSIP and/or the

interacting protocol are left for separate documents to discuss in

detail.

Beyond the scope of this document is discussion of RSIP in large,

multiple-gateway networks, or in environments where RSIP state would

need to be distributed and maintained across multiple redundant

entities.

Discussion of RSIP solutions that do not use some form of tunnel

between the RSIP host and RSIP gateway are also not considered in

this document.

This document focuses on scenarios that allow privately-addressed

IPv4 hosts or IPv6 hosts access to publically-addressed IPv4

networks.

1.2. Terminology

Private Realm

A routing realm that uses private IP addresses from the ranges

(10.0.0.0/8, 172.16.0.0/12, 192.168.0.0/16) specified in

[RFC1918], or addresses that are non-routable from the Internet.

Public Realm

A routing realm with globally unique network addresses.

RSIP Host

A host within an addressing realm that uses RSIP to acquire

addressing parameters from another addressing realm via an RSIP

gateway.

RSIP Gateway

A router or gateway situated on the boundary between two

addressing realms that is assigned one or more IP addresses in at

least one of the realms. An RSIP gateway is responsible for

parameter management and assignment from one realm to RSIP hosts

in the other realm. An RSIP gateway may act as a normal NAT

router for hosts within the a realm that are not RSIP enabled.

RSIP Client

An application program that performs the client portion of the

RSIP client/server protocol. An RSIP client application MUST

exist on all RSIP hosts, and MAY exist on RSIP gateways.

RSIP Server

An application program that performs the server portion of the

RSIP client/server protocol. An RSIP server application MUST

exist on all RSIP gateways.

RSA-IP: Realm Specific Address IP

An RSIP method in which each RSIP host is allocated a unique IP

address from the public realm.

RSAP-IP: Realm Specific Address and Port IP

An RSIP method in which each RSIP host is allocated an IP address

(possibly shared with other RSIP hosts) and some number of per-

address unique ports from the public realm.

Demultiplexing Fields

Any set of packet header or payload fields that an RSIP gateway

uses to route an incoming packet to an RSIP host.

All other terminology found in this document is consistent with that

of [RFC2663].

1.3. Specification of Requirements

The keyWords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",

"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this

documents are to be interpreted as described in [RFC2119].

2. Architecture

In a typical scenario where RSIP is deployed, there are some number

of hosts within one addressing realm connected to another addressing

realm by an RSIP gateway. This model is diagrammatically represented

as follows:

RSIP Host RSIP Gateway Host

Xa Na Nb Yb

[X]------( Addr sp. A )----[N]-----( Addr sp. B )-------[Y]

( Network ) ( Network )

Hosts X and Y belong to different addressing realms A and B,

respectively, and N is an RSIP gateway (which may also perform NAT

functions). N has two interfaces: Na on address space A, and Nb on

address space B. N may have a pool of addresses in address space B

which it can assign to or lend to X and other hosts in address space

A. These addresses are not shown above, but they can be denoted as

Nb1, Nb2, Nb3 and so on.

As is often the case, the hosts within address space A are likely to

use private addresses while the RSIP gateway is multi-homed with one

or more private addresses from address space A in addition to its

public addresses from address space B. Thus, we typically refer to

the realm in which the RSIP host resides as "private" and the realm

from which the RSIP host borrows addressing parameters as the

"public" realm. However, these realms may both be public or private

- our notation is for convenience. In fact, address space A may be

an IPv6 realm or a non-IP address space.

Host X, wishing to establish an end-to-end connection to a network

entity Y situated within address space B, first negotiates and

oBTains assignment of the resources (e.g., addresses and other

routing parameters of address space B) from the RSIP gateway. Upon

assignment of these parameters, the RSIP gateway creates a mapping,

referred as a "bind", of X's addressing information and the assigned

resources. This binding enables the RSIP gateway to correctly de-

multiplex and forward inbound traffic generated by Y for X. If

permitted by the RSIP gateway, X may create multiple such bindings on

the same RSIP gateway, or across several RSIP gateways. A lease time

SHOULD be associated with each bind.

Using the public parameters assigned by the RSIP gateway, RSIP hosts

tunnel data packets across address space A to the RSIP gateway. The

RSIP gateway acts as the end point of such tunnels, stripping off the

outer headers and routing the inner packets onto the public realm.

As mentioned above, an RSIP gateway maintains a mapping of the

assigned public parameters as demultiplexing fields for uniquely

mapping them to RSIP host private addresses. When a packet from the

public realm arrives at the RSIP gateway and it matches a given set

of demultiplexing fields, then the RSIP gateway will tunnel it to the

appropriate RSIP host. The tunnel headers of outbound packets from X

to Y, given that X has been assigned Nb, are as follows:

+---------+---------+---------+

X -> Na Nb -> Y payload

+---------+---------+---------+

There are two basic flavors of RSIP: RSA-IP and RSAP-IP. RSIP hosts

and gateways MAY support RSA-IP, RSAP-IP, or both.

When using RSA-IP, an RSIP gateway maintains a pool of IP addresses

to be leased by RSIP hosts. Upon host request, the RSIP gateway

allocates an IP address to the host. Once an address is allocated to

a particular host, only that host may use the address until the

address is returned to the pool. Hosts MAY NOT use addresses that

have not been specifically assigned to them. The hosts may use any

TCP/UDP port in combination with their assigned address. Hosts may

also run gateway applications at any port and these applications will

be available to the public network without assistance from the RSIP

gateway. A host MAY lease more than one address from the same or

different RSIP gateways. The demultiplexing fields of an RSA-IP

session MUST include the IP address leased to the host.

When using RSAP-IP, an RSIP gateway maintains a pool of IP addresses

as well as pools of port numbers per address. RSIP hosts lease an IP

address and one or more ports to use with it. Once an address / port

tuple has been allocated to a particular host, only that host may use

the tuple until it is returned to the pool(s). Hosts MAY NOT use

address / port combinations that have not been specifically assigned

to them. Hosts may run gateway applications bound to an allocated

tuple, but their applications will not be available to the public

network unless the RSIP gateway has agreed to route all traffic

destined to the tuple to the host. A host MAY lease more than one

tuple from the same or different RSIP gateways. The demultiplexing

fields of an RSAP-IP session MUST include the tuple(s) leased to the

host.

3. Requirements

3.1. Host and Gateway Requirements

An RSIP host MUST be able to maintain one or more virtual interfaces

for the IP address(es) that it leases from an RSIP gateway. The host

MUST also support tunneling and be able to serve as an end-point for

one or more tunnels to RSIP gateways. An RSIP host MUST NOT respond

to ARPs for a public realm address that it leases.

An RSIP host supporting RSAP-IP MUST be able to maintain a set of one

or more ports assigned by an RSIP gateway from which choose ephemeral

source ports. If the host's pool does not have any free ports and

the host needs to open a new communication session with a public

host, it MUST be able to dynamically request one or more additional

ports via its RSIP mechanism.

An RSIP gateway is a multi-homed host that routes packets between two

or more realms. Often, an RSIP gateway is a boundary router between

two or more administrative domains. It MUST also support tunneling

and be able to serve as an end-point for tunnels to RSIP hosts. The

RSIP gateway MAY be a policy enforcement point, which in turn may

require it to perform firewall and packet filtering duties in

addition to RSIP. The RSIP gateway MUST reassemble all incoming

packet fragments from the public network in order to be able to route

and tunnel them to the proper host. As is necessary for fragment

reassembly, an RSIP gateway MUST timeout fragments that are never

fully reassembled.

An RSIP gateway MAY include NAT functionality so that hosts on the

private network that are not RSIP-enabled can still communicate with

the public network. An RSIP gateway MUST manage all resources that

are assigned to RSIP hosts. This management MAY be done according to

local policy.

3.2. Processing of Demultiplexing Fields

Each active RSIP host must have a unique set of demultiplexing fields

assigned to it so that an RSIP gateway can route incoming packets

appropriately. Depending on the type of mapping used by the RSIP

gateway, demultiplexing fields have been defined to be one or more of

the following:

- destination IP address

- IP protocol

- destination TCP or UDP port

- IPSEC SPI present in ESP or AH header (see [RFC3104])

- others

Note that these fields may be augmented by source IP address and

source TCP or UDP port.

Demultiplexing of incoming traffic can be based on a decision tree.

The process begins with the examination of the IP header of the

incoming packet, and proceeds to subsequent headers and then the

payload.

- In the case where a public IP address is assigned for each

host, a unique public IP address is mapped to each RSIP host.

- If the same IP address is used for more than one RSIP host,

then subsequent headers must have at least one field that will

be assigned a unique value per host so that it is usable as a

demultiplexing field. The IP protocol field SHOULD be used to

determine what in the subsequent headers these demultiplexing

fields ought to be.

- If the subsequent header is TCP or UDP, then destination port

number can be used. However, if the TCP/UDP port number is the

same for more than one RSIP host, the payload section of the

packet must contain a demultiplexing field that is guaranteed

to be different for each RSIP host. Typically this requires

negotiation of said fields between the RSIP host and gateway so

that the RSIP gateway can guarantee that the fields are unique

per-host

- If the subsequent header is anything other than TCP or UDP,

there must exist other fields within the IP payload usable as

demultiplexing fields. In other words, these fields must be

able to be set such that they are guaranteed to be unique per-

host. Typically this requires negotiation of said fields

between the RSIP host and gateway so that the RSIP gateway can

guarantee that the fields are unique per-host.

It is desirable for all demultiplexing fields to occur in well-known

fixed locations so that an RSIP gateway can mask out and examine the

appropriate fields on incoming packets. Demultiplexing fields that

are encrypted MUST NOT be used for routing.

3.3. RSIP Protocol Requirements and Recommendations

RSIP gateways and hosts MUST be able to negotiate IP addresses when

using RSA-IP, IP address / port tuples when using RSAP-IP, and

possibly other demultiplexing fields for use in other modes.

In this section we discuss the requirements and implementation issues

of an RSIP negotiation protocol.

For each required demultiplexing field, an RSIP protocol MUST, at the

very least, allow for:

- RSIP hosts to request assignments of demultiplexing fields

- RSIP gateways to assign demultiplexing fields with an

associated lease time

- RSIP gateways to reclaim assigned demultiplexing fields

Additionally, it is desirable, though not mandatory, for an RSIP

protocol to negotiate an RSIP method (RSA-IP or RSAP-IP) and the type

of tunnel to be used across the private network. The protocol SHOULD

be extensible and facilitate vendor-specific extensions.

If an RSIP negotiation protocol is implemented at the application

layer, a choice of transport protocol MUST be made. RSIP hosts and

gateways may communicate via TCP or UDP. TCP support is required in

all RSIP gateways, while UDP support is optional. In RSIP hosts,

TCP, UDP, or both may be supported. However, once an RSIP host and

gateway have begun communicating using either TCP or UDP, they MAY

NOT switch to the other transport protocol. For RSIP implementations

and deployments considered in this document, TCP is the recommended

transport protocol, because TCP is known to be robust across a wide

range of physical media types and traffic loads.

It is recommended that all communication between an RSIP host and

gateway be authenticated. Authentication, in the form of a message

hash appended to the end of each RSIP protocol packet, can serve to

authenticate the RSIP host and gateway to one another, provide

message integrity, and (with an anti-replay counter) avoid replay

attacks. In order for authentication to be supported, each RSIP host

and the RSIP gateway MUST either share a secret key (distributed, for

example, by Kerberos) or have a private/public key pair. In the

latter case, an entity's public key can be computed over each message

and a hash function applied to the result to form the message hash.

3.4. Interaction with DNS

An RSIP-enabled network has three uses for DNS: (1) public DNS

services to map its static public IP addresses (i.e., the public

address of the RSIP gateway) and for lookups of public hosts, (2)

private DNS services for use only on the private network, and (3)

dynamic DNS services for RSIP hosts.

With respect to (1), public DNS information MUST be propagated onto

the private network. With respect to (2), private DNS information

MUST NOT be propagated into the public network.

With respect to (3), an RSIP-enabled network MAY allow for RSIP hosts

with FQDNs to have their A and PTR records updated in the public DNS.

These updates are based on address assignment facilitated by RSIP,

and should be performed in a fashion similar to DHCP updates to

dynamic DNS [DHCP-DNS]. In particular, RSIP hosts should be allowed

to update their A records but not PTR records, while RSIP gateways

can update both. In order for the RSIP gateway to update DNS records

on behalf on an RSIP host, the host must provide the gateway with its

FQDN.

Note that when using RSA-IP, the interaction with DNS is completely

analogous to that of DHCP because the RSIP host "owns" an IP address

for a period of time. In the case of RSAP-IP, the claim that an RSIP

host has to an address is only with respect to the port(s) that it

has leased along with an address. Thus, two or more RSIP hosts'

FQDNs may map to the same IP address. However, a public host may

expect that all of the applications running at a particular address

are owned by the same logical host, which would not be the case. It

is recommended that RSAP-IP and dynamic DNS be integrated with some

caution, if at all.

3.5. Locating RSIP Gateways

When an RSIP host initializes, it requires (among other things) two

critical pieces of information. One is a local (private) IP address

to use as its own, and the other is the private IP address of an RSIP

gateway. This information can be statically configured or

dynamically assigned.

In the dynamic case, the host's private address is typically supplied

by DHCP. A DHCP option could provide the IP address of an RSIP

gateway in DHCPOFFER messages. Thus, the host's startup procedure

would be as follows: (1) perform DHCP, (2) if an RSIP gateway option

is present in the DHCPOFFER, record the IP address therein as the

RSIP gateway.

Alternatively, the RSIP gateway can be discovered via SLP (Service

Location Protocol) as specified in [SLP-RSIP]. The SLP template

defined allows for RSIP service provisioning and load balancing.

3.6. Implementation Considerations

RSIP can be accomplished by any one of a wide range of implementation

schemes. For example, it can be built into an existing configuration

protocol such as DHCP or SOCKS, or it can exist as a separate

protocol. This section discusses implementation issues of RSIP in

general, regardless of how the RSIP mechanism is implemented.

Note that on a host, RSIP is associated with a TCP/IP stack

implementation. Modifications to IP tunneling and routing code, as

well as driver interfaces may need to be made to support RSA-IP.

Support for RSAP-IP requires modifications to ephemeral port

selection code as well. If a host has multiple TCP/IP stacks or

TCP/IP stacks and other communication stacks, RSIP will only operate

on the packets / sessions that are associated with the TCP/IP

stack(s) that use RSIP. RSIP is not application specific, and if it

is implemented in a stack, it will operate beneath all applications

that use the stack.

4. Deployment

When RSIP is deployed in certain scenarios, the network

characteristics of these scenarios will determine the scope of the

RSIP solution, and therefore impact the requirements of RSIP. In

this section, we examine deployment scenarios, and the impact that

RSIP may have on existing networks.

4.1. Possible Deployment Scenarios

In this section we discuss a number of potential RSIP deployment

scenarios. The selection below are not comprehensive and other

scenarios may emerge.

4.1.1. Small / Medium Enterprise

Up to several hundred hosts will reside behind an RSIP-enabled

router. It is likely that there will be only one gateway to the

public network and therefore only one RSIP gateway. This RSIP

gateway may control only one, or perhaps several, public IP

addresses. The RSIP gateway may also perform firewall functions, as

well as routing inbound traffic to particular destination ports on to

a small number of dedicated gateways on the private network.

4.1.2. Residential Networks

This category includes both networking within just one residence, as

well as within multiple-dwelling units. At most several hundred

hosts will share the gateway's resources. In particular, many of

these devices may be thin hosts or so-called "network appliances" and

therefore not require access to the public Internet frequently. The

RSIP gateway is likely to be implemented as part of a residential

firewall, and it may be called upon to route traffic to particular

destination ports on to a small number of dedicated gateways on the

private network. It is likely that only one gateway to the public

network will be present and that this gateway's RSIP gateway will

control only one IP address. Support for secure end-to-end VPN

access to corporate intranets will be important.

4.1.3. Hospitality Networks

A hospitality network is a general type of "hosting" network that a

traveler will use for a short period of time (a few minutes or a few

hours). Examples scenarios include hotels, conference centers and

airports and train stations. At most several hundred hosts will

share the gateway's resources. The RSIP gateway may be implemented

as part of a firewall, and it will probably not be used to route

traffic to particular destination ports on to dedicated gateways on

the private network. It is likely that only one gateway to the

public network will be present and that this gateway's RSIP gateway

will control only one IP address. Support for secure end-to-end VPN

access to corporate intranets will be important.

4.1.4. Dialup Remote Access

RSIP gateways may be placed in dialup remote access concentrators in

order to multiplex IP addresses across dialup users. At most several

hundred hosts will share the gateway's resources. The RSIP gateway

may or may not be implemented as part of a firewall, and it will

probably not be used to route traffic to particular destination ports

on to dedicated gateways on the private network. Only one gateway to

the public network will be present (the remote access concentrator

itself) and that this gateway's RSIP gateway will control a small

number of IP addresses. Support for secure end-to-end VPN access to

corporate intranets will be important.

4.1.5. Wireless Remote Access Networks

Wireless remote access will become very prevalent as more PDA and IP

/ cellular devices are deployed. In these scenarios, hosts may be

changing physical location very rapidly - therefore Mobile IP will

play a role. Hosts typically will register with an RSIP gateway for

a short period of time. At most several hundred hosts will share the

gateway's resources. The RSIP gateway may be implemented as part of

a firewall, and it will probably not be used to route traffic to

particular destination ports on to dedicated gateways on the private

network. It is likely that only one gateway to the public network

will be present and that this gateway's RSIP gateway will control a

small number of IP addresses. Support for secure end-to-end VPN

access to corporate intranets will be important.

4.2. Cascaded RSIP and NAT

It is possible for RSIP to allow for cascading of RSIP gateways as

well as cascading of RSIP gateways with NAT boxes. For example,

consider an ISP that uses RSIP for address sharing amongst its

customers. It might assign resources (e.g., IP addresses and ports)

to a particular customer. This customer may use RSIP to further

subdivide the port ranges and address(es) amongst individual end

hosts. No matter how many levels of RSIP assignment exists, RSIP

MUST only assign public IP addresses.

Note that some of the architectures discussed below may not be useful

or desirable. The goal of this section is to explore the

interactions between NAT and RSIP as RSIP is incrementally deployed

on systems that already support NAT.

4.2.1. RSIP Behind RSIP

A reference architecture is depicted below.

+-----------+

RSIP

gateway +---- 10.0.0.0/8

B

+-----+-----+

10.0.1.0/24

+-----------+ (149.112.240.0/25)

149.112.240.0/24 RSIP +--+

----------------+ gateway

A +--+

+-----------+ 10.0.2.0/24

(149.112.240.128/25)

+-----+-----+

RSIP

gateway +---- 10.0.0.0/8

C

+-----------+

RSIP gateway A is in charge of the IP addresses of subnet

149.112.240.0/24. It distributes these addresses to RSIP hosts and

RSIP gateways. In the given configuration, it distributes addresses

149.112.240.0 - 149.112.240.127 to RSIP gateway B, and addresses

149.112.240.128 - 149.112.240.254 to RSIP gateway C. Note that the

subnet broadcast address, 149.112.240.255, must remain unclaimed, so

that broadcast packets can be distributed to arbitrary hosts behind

RSIP gateway A. Also, the subnets between RSIP gateway A and RSIP

gateways B and C will use private addresses.

Due to the tree-like fashion in which addresses will be cascaded, we

will refer to RSIP gateways A as the 'parent' of RSIP gateways B and

C, and RSIP gateways B and C as 'children' of RSIP gateways A. An

arbitrary number of levels of children may exist under a parent RSIP

gateway.

A parent RSIP gateway will not necessarily be aware that the

address(es) and port blocks that it distributes to a child RSIP

gateway will be further distributed. Thus, the RSIP hosts MUST

tunnel their outgoing packets to the nearest RSIP gateway. This

gateway will then verify that the sending host has used the proper

address and port block, and then tunnel the packet on to its parent

RSIP gateway.

For example, in the context of the diagram above, host 10.0.0.1,

behind RSIP gateway C will use its assigned external IP address (say,

149.112.240.130) and tunnel its packets over the 10.0.0.0/8 subnet to

RSIP gateway C. RSIP gateway C strips off the outer IP header.

After verifying that the source public IP address and source port

number is valid, RSIP gateway C will tunnel the packets over the

10.0.2.0/8 subnet to RSIP gateway A. RSIP gateway A strips off the

outer IP header. After verifying that the source public IP address

and source port number is valid, RSIP gateway A transmits the packet

on the public network.

While it may be more efficient in terms of computation to have a RSIP

host tunnel directly to the overall parent of an RSIP gateway tree,

this would introduce significant state and administrative

difficulties.

A RSIP gateway that is a child MUST take into consideration the

parameter assignment constraints that it inherits from its parent

when it assigns parameters to its children. For example, if a child

RSIP gateway is given a lease time of 3600 seconds on an IP address,

it MUST compare the current time to the lease time and the time that

the lease was assigned to compute the maximum allowable lease time on

the address if it is to assign the address to a RSIP host or child

RSIP gateway.

4.2.2. NAT Behind RSIP

+--------+ +--------+

NAT w/ RSIP

hosts ------+ RSIP +------+ gate- +----- public network

host way

+--------+ +--------+

In this architecture, an RSIP gateway is between a NAT box and the

public network. The NAT is also equipped with an RSIP host. The NAT

dynamically requests resources from the RSIP gateway as the hosts

establish sessions to the public network. The hosts are not aware of

the RSIP manipulation. This configuration does not enable the hosts

to have end-to-end transparency and thus the NAT still requires ALGs

and the architecture cannot support IPSEC.

4.2.3. RSIP Behind NAT

+--------+ +--------+

RSIP RSIP

hosts ------+ gate- +------+ NAT +----- public network

way

+--------+ +--------+

In this architecture, the RSIP hosts and gateway reside behind a NAT.

This configuration does not enable the hosts to have end-to-end

transparency and thus the NAT still requires ALGs and the

architecture cannot support IPSEC. The hosts may have transparency

if there is another gateway to the public network besides the NAT

box, and this gateway supports cascaded RSIP behind RSIP.

4.2.4. RSIP Through NAT

+--------+ +--------+

RSIP RSIP

hosts ------+ NAT +------+ gate- +----- public network

way

+--------+ +--------+

In this architecture, the RSIP hosts are separated from the RSIP

gateway by a NAT. RSIP signaling may be able to pass through the NAT

if an RSIP ALG is installed. The RSIP data flow, however, will have

its outer IP address translated by the NAT. The NAT must not

translate the port numbers in order for RSIP to work properly.

Therefore, only traditional NAT will make sense in this context.

5. Interaction with Layer-Three Protocols

Since RSIP affects layer-three objects, it has an impact on other

layer three protocols. In this section, we outline the impact of

RSIP on these protocols, and in each case, how RSIP, the protocol, or

both, can be extended to support interaction.

Each of these sections is an overview and not a complete technical

specification. If a full technical specification of how RSIP

interacts with a layer-three protocol is necessary, a separate

document will contain it.

5.1. IPSEC

RSIP is a mechanism for allowing end-to-end IPSEC with sharing of IP

addresses. Full specification of RSIP/IPSEC details are in [RSIP-

IPSEC]. This section provides a brief summary. Since IPSEC may

encrypt TCP/UDP port numbers, these objects cannot be used as

demultiplexing fields. However, IPSEC inserts an AH or ESP header

following the IP header in all IPSEC-protected packets (packets that

are transmitted on an IPSEC Security Association (SA)). These

headers contain a 32-bit Security Parameter Index (SPI) field, the

value of which is determined by the receiving side. The SPI field is

always in the clear. Thus, during SA negotiation, an RSIP host can

instruct their public peer to use a particular SPI value. This SPI

value, along with the assigned IP address, can be used by an RSIP

gateway to uniquely identify and route packets to an RSIP host. In

order to guarantee that RSIP hosts use SPIs that are unique per

address, it is necessary for the RSIP gateway to allocate unique SPIs

to hosts along with their address/port tuple.

IPSEC SA negotiation takes place using the Internet Key Exchange

(IKE) protocol. IKE is designated to use port 500 on at least the

destination side. Some host IKE implementations will use source port

500 as well, but this behavior is not mandatory. If two or more RSIP

hosts are running IKE at source port 500, they MUST use different

initiator cookies (the first eight bytes of the IKE payload) per

assigned IP address. The RSIP gateway will be able to route incoming

IKE packets to the proper host based on initiator cookie value.

Initiator cookies can be negotiated, like ports and SPIs. However,

since the likelihood of two hosts assigned the same IP address

attempting to simultaneously use the same initiator cookie is very

small, the RSIP gateway can guarantee cookie uniqueness by dropping

IKE packets with a cookie value that is already in use.

5.2. Mobile IP

Mobile IP allows a mobile host to maintain an IP address as it moves

from network to network. For Mobile IP foreign networks that use

private IP addresses, RSIP may be applicable. In particular, RSIP

would allow a mobile host to bind to a local private address, while

maintaining a global home address and a global care-of address. The

global care-of address could, in principle, be shared with other

mobile nodes.

The exact behavior of Mobile IP with respect to private IP addresses

has not be settled. Until it is, a proposal to adapt RSIP to such a

scenario is premature. Also, such an adaptation may be considerably

complex. Thus, integration of RSIP and Mobile IP is a topic of

ongoing consideration.

5.3. Differentiated and Integrated Services

To attain the capability of providing quality of service between two

communicating hosts in different realms, it is important to consider

the interaction of RSIP with different quality of service

provisioning models and mechanisms. In the section, RSIP interaction

with the integrated service and differentiated service frameworks is

discussed.

5.3.1. Differentiated Services

The differentiated services architecture defined in [RFC2475] allows

networks to support multiple levels of best-effort service through

the use of "markings" of the IP Type-of-Service (now DS) byte. Each

value of the DS byte is termed a differentiated services code point

(DSCP) and represents a particular per-hop behavior. This behavior

may not be the same in all administrative domains. No explicit

signaling is necessary to support differentiated services.

For outbound packets from an edge network, DSCP marking is typically

performed and/or enforced on a boundary router. The marked packet is

then forwarded onto the public network. In an RSIP-enabled network,

a natural place for DSCP marking is the RSIP gateway. In the case of

RSAP-IP, the RSIP gateway can apply its micro-flow (address/port

tuple) knowledge of RSIP assignments in order to provide different

service levels to different RSIP host. For RSA-IP, the RSIP gateway

will not necessarily have knowledge of micro-flows, so it must rely

on markings made by the RSIP hosts (if any) or apply a default policy

to the packets.

When differentiated services is to be performed between RSIP hosts

and gateways, it must be done over the tunnel between these entities.

Differentiated services over a tunnel is considered in detail in

[DS-TUNN], the key points that need to be addressed here are the

behaviors of tunnel ingress and egress for both incoming and going

packets.

For incoming packets arriving at an RSIP gateway tunnel ingress, the

RSIP gateway may either copy the DSCP from the inner header to the

outer header, leave the inner header DSCP untouched, but place a

different DSCP in the outer header, or change the inner header DSCP

while applying either the same or a different DSCP to the outer

header.

For incoming packets arriving at an RSIP host tunnel egress, behavior

with respect to the DSCP is not necessarily important if the RSIP

host not only terminates the tunnel, but consumes the packet as well.

If this is not the case, as per some cascaded RSIP scenarios, the

RSIP host must apply local policy to determine whether to leave the

inner header DSCP as is, overwrite it with the outer header DSCP, or

overwrite it with a different value.

For outgoing packets arriving at an RSIP host tunnel ingress, the

host may either copy the DSCP from the inner header to the outer

header, leave the inner header DSCP untouched, but place a different

DSCP in the outer header, or change the inner header DSCP while

applying either the same or a different DSCP to the outer header.

For outgoing packets arriving at an RSIP gateway tunnel egress, the

RSIP gateway must apply local policy to determine whether to leave

the inner header DSCP as is, overwrite it with the outer header DSCP,

or overwrite it with a different value.

It is reasonable to assume that in most cases, the diffserv policy

applicable on a site will be the same for RSIP and non-RSIP hosts.

For this reason, a likely policy is that the DSCP will always be

copied between the outer and inner headers in all of the above cases.

However, implementations should allow for the more general case.

5.3.2. Integrated Services

The integrated services model as defined by [RFC2205] requires

signalling using RSVP to setup a resource reservation in intermediate

nodes between the communicating endpoints. In the most common

scenario in which RSIP is deployed, receivers located within the

private realm initiate communication sessions with senders located

within the public realm. In this section, we discuss the interaction

of RSIP architecture and RSVP in such a scenario. The less common

case of having senders within the private realm and receivers within

the public realm is not discussed although concepts mentioned here

may be applicable.

With senders in the public realm, RSVP PATH messages flow downstream

from sender to receiver, inbound with respect to the RSIP gateway,

while RSVP RESV messages flow in the opposite direction. Since RSIP

uses tunneling between the RSIP host and gateway within the private

realm, how the RSVP messages are handled within the RSIP tunnel

depends on situations elaborated in [RFC2746].

Following the terminology of [RFC2476], if Type 1 tunnels exist

between the RSIP host and gateway, all intermediate nodes inclusive

of the RSIP gateway will be treated as a non-RSVP aware cloud without

QoS reserved on these nodes. The tunnel will be viewed as a single

(logical) link on the path between the source and destination. End-

to-end RSVP messages will be forwarded through the tunnel

encapsulated in the same way as normal IP packets. We see this as

the most common and applicable deployment scenario.

However, should Type 2 or 3 tunnels be deployed between the tunneling

endpoints , end-to-end RSVP session has to be statically mapped (Type

2) or dynamically mapped (Type 3) into the tunnel sessions. While

the end-to-end RSVP messages will be forwarded through the tunnel

encapsulated in the same way as normal IP packets, a tunnel session

is established between the tunnel endpoints to ensure QoS reservation

within the tunnel for the end-to-end session. Data traffic needing

special QoS assurance will be encapsulated in a UDP/IP header while

normal traffic will be encapsulated using the normal IP-IP

encapsulation. In the type 2 deployment scenario where all data

traffic flowing to the RSIP host receiver are given QoS treatment,

UDP/IP encapsulation will be rendered in the RSIP gateway for all

data flows. The tunnel between the RSIP host and gateway could be

seen as a "hard pipe". Traffic exceeding the QoS guarantee of the

"hard pipe" would fall back to the best effort IP-IP tunneling.

In the type 2 deployment scenario where data traffic could be

selectively channeled into the UDP/IP or normal IP-IP tunnel, or for

type 3 deployment where end-to-end sessions could be dynamically

mapped into tunnel sessions, integration with the RSIP model could be

complicated and tricky. (Note that these are the cases where the

tunnel link could be seen as a expandable soft pipe.) Two main

issues are worth considering.

- For RSIP gateway implementations that does encapsulation of the

incoming stream before passing to the IP layer for forwarding,

the RSVP daemon has to be explicitly signaled upon reception of

incoming RSVP PATH messages. The RSIP implementation has to

recognize RSVP PATH messages and pass them to the RSVP daemon

instead of doing the default tunneling. Handling of other RSVP

messages would be as described in [RFC2746].

- RSIP enables an RSIP host to have a temporary presence at the

RSIP gateway by assuming one of the RSIP gateway's global

interfaces. As a result, the RSVP PATH messages would be

addressed to the RSIP gateway. Also, the RSVP SESSION object

within an incoming RSVP PATH would carry the global destination

address, destination port (and protocol) tuples that were

leased by the RSIP gateway to the RSIP host. Hence the realm

unaware RSVP daemon running on the RSIP gateway has to be

presented with a translated version of the RSVP messages.

Other approaches are possible, for example making the RSVP

daemon realm aware.

A simple mechanism would be to have the RSIP module handle the

necessary RSVP message translation. For an incoming RSVP signalling

flow, the RSIP module does a packet translation of the IP header and

RSVP SESSION object before handling the packet over to RSVP. The

global address leased to the host is translated to the true private

address of the host. (Note that this mechanism works with both RSA-

IP and RSAP-IP.) The RSIP module also has to do an opposite

translation from private to global parameter (plus tunneling) for

end-to-end PATH messages generated by the RSVP daemon towards the

RSIP host receiver. A translation on the SESSION object also has to

be done for RSVP outbound control messages. Once the RSVP daemon

gets the message, it maps them to an appropriate tunnel sessions.

Encapsulation of the inbound data traffic needing QoS treatment would

be done using UDP-IP encapsulation designated by the tunnel session.

For this reason, the RSIP module has to be aware of the UDP-IP

encapsulation to use for a particular end-to-end session.

Classification and scheduling of the QoS guaranteed end-to-end flow

on the output interface of the RSIP gateway would be based on the

UDP/IP encapsulation. Mapping between the tunnel session and end-

to-end session could continue to use the mechanisms proposed in

[RFC2746]. Although [RFC2746] proposes a number of approaches for

this purpose, we propose using the SESSION_ASSOC object introduced

because of its simplicity.

5.4. IP Multicast

The amount of specific RSIP/multicast support that is required in

RSIP hosts and gateways is dependent on the scope of multicasting in

the RSIP-enabled network, and the roles that the RSIP hosts will

play. In this section, we discuss RSIP and multicast interactions in

a number of scenarios.

Note that in all cases, the RSIP gateway MUST be multicast aware

because it is on an administrative boundary between two domains that

will not be sharing their all of their routing information. The RSIP

gateway MUST NOT allow private IP addresses to be propagated on the

public network as part of any multicast message or as part of a

routing table.

5.4.1. Receiving-Only Private Hosts, No Multicast Routing on

Private Network

In this scenario, private hosts will not source multicast traffic,

but they may join multicast groups as recipients. In the private

network, there are no multicast-aware routers, except for the RSIP

gateway.

Private hosts may join and leave multicast groups by sending the

appropriate IGMP messages to an RSIP gateway (there may be IGMP proxy

routers between RSIP hosts and gateways). The RSIP gateway will

coalesce these requests and perform the appropriate actions, whether

they be to perform a multicast WAN routing protocol, such as PIM, or

to proxy the IGMP messages to a WAN multicast router. In other

words, if one or more private hosts request to join a multicast

group, the RSIP gateway MUST join in their stead, using one of its

own public IP addresses.

Note that private hosts do not need to acquire demultiplexing fields

and use RSIP to receive multicasts. They may receive all multicasts

using their private addresses, and by private address is how the RSIP

gateway will keep track of their group membership.

5.4.2. Sending and Receiving Private Hosts, No Multicast Routing

on Private Network

This scenarios operates identically to the previous scenario, except

that when a private host becomes a multicast source, it MUST use RSIP

and acquire a public IP address (note that it will still receive on

its private address). A private host sending a multicast will use a

public source address and tunnel the packets to the RSIP gateway.

The RSIP gateway will then perform typical RSIP functionality, and

route the resulting packets onto the public network, as well as back

to the private network, if there are any listeners on the private

network.

If there is more than one sender on the private network, then, to the

public network it will seem as if all of these senders share the same

IP address. If a downstream multicasting protocol identifies sources

based on IP address alone and not port numbers, then it is possible

that these protocols will not be able to distinguish between the

senders.

6. RSIP Complications

In this section we document the know complications that RSIP may

cause. While none of these complications should be considered "show

stoppers" for the majority of applications, they may cause unexpected

or undefined behavior. Where it is appropriate, we discuss potential

remedial procedures that may reduce or eliminate the deleterious

impact of a complication.

6.1. Unnecessary TCP TIME_WAIT

When TCP disconnects a socket, it enters the TCP TIME_WAIT state for

a period of time. While it is in this state it will refuse to accept

new connections using the same socket (i.e., the same source

address/port and destination address/port). Consider the case in

which an RSIP host (using RSAP-IP) is leased an address/port tuple

and uses this tuple to contact a public address/port tuple. Suppose

that the host terminates the session with the public tuple and

immediately returns its leased tuple to the RSIP gateway. If the

RSIP gateway immediately allocates this tuple to another RSIP host

(or to the same host), and this second host uses the tuple to contact

the same public tuple while the socket is still in the TIME_WAIT

phase, then the host's connection may be rejected by the public host.

In order to mitigate this problem, it is recommended that RSIP

gateways hold recently deallocated tuples for at least two minutes,

which is the greatest duration of TIME_WAIT that is commonly

implemented. In situations where port space is scarce, the RSIP

gateway MAY choose to allocate ports in a FIFO fashion from the pool

of recently deallocated ports.

6.2. ICMP State in RSIP Gateway

Like NAT, RSIP gateways providing RSAP-IP must process ICMP responses

from the public network in order to determine the RSIP host (if any)

that is the proper recipient. We distinguish between ICMP error

packets, which are transmitted in response to an error with an

associated IP packet, and ICMP response packets, which are

transmitted in response to an ICMP request packet.

ICMP request packets originating on the private network will

typically consist of echo request, timestamp request and address mask

request. These packets and their responses can be identified by the

tuple of source IP address, ICMP identifier, ICMP sequence number,

and destination IP address. An RSIP host sending an ICMP request

packet tunnels it to the RSIP gateway, just as it does TCP and UDP

packets. The RSIP gateway must use this tuple to map incoming ICMP

responses to the private address of the appropriate RSIP host. Once

it has done so, it will tunnel the ICMP response to the host. Note

that it is possible for two RSIP hosts to use the same values for the

tuples listed above, and thus create an ambiguity. However, this

occurrence is likely to be quite rare, and is not addressed further

in this document.

Incoming ICMP error response messages can be forwarded to the

appropriate RSIP host by examining the IP header and port numbers

embedded within the ICMP packet. If these fields are not present,

the packet should be silently discarded.

Occasionally, an RSIP host will have to send an ICMP response (e.g.,

port unreachable). These responses are tunneled to the RSIP gateway,

as is done for TCP and UDP packets. All ICMP requests (e.g., echo

request) arriving at the RSIP gateway MUST be processed by the RSIP

gateway and MUST NOT be forwarded to an RSIP host.

6.3. Fragmentation and IP Identification Field Collision

If two or more RSIP hosts on the same private network transmit

outbound packets that get fragmented to the same public gateway, the

public gateway may experience a reassembly ambiguity if the IP header

ID fields of these packets are identical.

For TCP packets, a reasonably small MTU can be set so that

fragmentation is guaranteed not to happen, or the likelihood or

fragmentation is extremely small. If path MTU discovery works

properly, the problem is mitigated. For UDP, applications control

the size of packets, and the RSIP host stack may have to fragment UDP

packets that exceed the local MTU. These packets may be fragmented

by an intermediate router as well.

The only completely robust solution to this problem is to assign all

RSIP hosts that are sharing the same public IP address disjoint

blocks of numbers to use in their IP identification fields. However,

whether this modification is worth the effort of implementing is

currently unknown.

6.4. Application Servers on RSAP-IP Hosts

RSAP-IP hosts are limited by the same constraints as NAT with respect

to hosting servers that use a well-known port. Since destination

port numbers are used as routing information to uniquely identify an

RSAP-IP host, typically no two RSAP-IP hosts sharing the same public

IP address can simultaneously operate publically-available gateways

on the same port. For protocols that operate on well-known ports,

this implies that only one public gateway per RSAP-IP IP address /

port tuple is used simultaneously. However, more than one gateway

per RSAP-IP IP address / port tuple may be used simultaneously if and

only if there is a demultiplexing field within the payload of all

packets that will uniquely determine the identity of the RSAP-IP

host, and this field is known by the RSIP gateway.

In order for an RSAP-IP host to operate a publically-available

gateway, the host must inform the RSIP gateway that it wishes to

receive all traffic destined to that port number, per its IP address.

Such a request MUST be denied if the port in question is already in

use by another host.

In general, contacting devices behind an RSIP gateway may be

difficult. A potential solution to the general problem would be an

architecture that allows an application on an RSIP host to register a

public IP address / port pair in a public database. Simultaneously,

the RSIP gateway would initiate a mapping from this address / port

tuple to the RSIP host. A peer application would then be required to

contact the database to determine the proper address / port at which

to contact the RSIP host's application.

6.5. Determining Locality of Destinations from an RSIP Host

In general, an RSIP host must know, for a particular IP address,

whether it should address the packet for local delivery on the

private network, or if it has to use an RSIP interface to tunnel to

an RSIP gateway (assuming that it has such an interface available).

If the RSIP hosts are all on a single subnet, one hop from an RSIP

gateway, then examination of the local network and subnet mask will

provide the appropriate information. However, this is not always the

case.

An alternative that will work in general for statically addressed

private networks is to store a list of the network and subnet masks

of every private subnet at the RSIP gateway. RSIP hosts may query

the gateway with a particular target IP address, or for the entire

list.

If the subnets on the local side of the network are changing more

rapidly than the lifetime of a typical RSIP session, the RSIP host

may have to query the location of every destination that it tries to

communicate with.

If an RSIP host transmits a packet addressed to a public host without

using RSIP, then the RSIP gateway will apply NAT to the packet (if it

supports NAT) or it may discard the packet and respond with and

appropriate ICMP message.

A robust solution to this problem has proven difficult to develop.

Currently, it is not known how severe this problem is. It is likely

that it will be more severe on networks where the routing information

is changing rapidly that on networks with relatively static routes.

6.6. Implementing RSIP Host Deallocation

An RSIP host MAY free resources that it has determined it no longer

requires. For example, on an RSAP-IP subnet with a limited number of

public IP addresses, port numbers may become scarce. Thus, if RSIP

hosts are able to dynamically deallocate ports that they no longer

need, more hosts can be supported.

However, this functionality may require significant modifications to

a vanilla TCP/IP stack in order to implement properly. The RSIP host

must be able to determine which TCP or UDP sessions are using RSIP

resources. If those resources are unused for a period of time, then

the RSIP host may deallocate them. When an open socket's resources

are deallocated, it will cause some associated applications to fail.

An analogous case would be TCP and UDP sessions that must terminate

when an interface that they are using loses connectivity.

On the other hand, this issue can be considered a resource allocation

problem. It is not recommended that a large number (hundreds) of

hosts share the same IP address, for performance purposes. Even if,

say, 100 hosts each are allocated 100 ports, the total number of

ports in use by RSIP would be still less than one-sixth the total

port space for an IP address. If more hosts or more ports are

needed, more IP addresses should be used. Thus, it is reasonable,

that in many cases, RSIP hosts will not have to deallocate ports for

the lifetime of their activity.

Since RSIP demultiplexing fields are leased to hosts, an

appropriately chosen lease time can alleviate some port space

scarcity issues.

6.7. Multi-Party Applications

Multi-party applications are defined to have at least one of the

following characteristics:

- A third party sets up sessions or connections between two

hosts.

- Computation is distributed over a number of hosts such that the

individual hosts may communicate with each other directly.

RSIP has a fundamental problem with multi-party applications. If

some of the parties are within the private addressing realm and

others are within the public addressing realm, an RSIP host may not

know when to use private addresses versus public addresses. In

particular, IP addresses may be passed from party to party under the

assumption that they are global endpoint identifiers. This may cause

multi-party applications to fail.

There is currently no known solution to this general problem.

Remedial measures are available, such as forcing all RSIP hosts to

always use public IP addresses, even when communicating only on to

other RSIP hosts. However, this can result in a socket set up

between two RSIP hosts having the same source and destination IP

addresses, which most TCP/IP stacks will consider as intra-host

communication.

6.8. Scalability

The scalability of RSIP is currently not well understood. While it

is conceivable that a single RSIP gateway could support hundreds of

RSIP hosts, scalability depends on the specific deployment scenario

and applications used. In particular, three major constraints on

scalability will be (1) RSIP gateway processing requirements, (2)

RSIP gateway memory requirements, and (3) RSIP negotiation protocol

traffic requirements. It is advisable that all RSIP negotiation

protocol implementations attempt to minimize these requirements.

7. Security Considerations

RSIP, in and of itself, does not provide security. It may provide

the illusion of security or privacy by hiding a private address

space, but security can only be ensured by the proper use of security

protocols and cryptographic techniques.

8. Acknowledgements

The authors would like to thank Pyda Srisuresh, Dan Nessett, Gary

Jaszewski, Ajay Bakre, Cyndi Jung, and Rick Cobb for their input.

The IETF NAT working group as a whole has been extremely helpful in

the ongoing development of RSIP.

9. References

[DHCP-DNS] Stapp, M. and Y. Rekhter, "Interaction Between DHCP and

DNS", Work in Progress.

[RFC2983] Black, D., "Differentiated Services and Tunnels", RFC

2983, October 2000.

[RFC3104] Montenegro, G. and M. Borella, "RSIP Support for End-to-

End IPSEC", RFC3104, October 2001.

[RFC3103] Borella, M., Grabelsky, D., Lo, J. and K. Taniguchi,

"Realm Specific IP: Protocol Specification", RFC3103,

October 2001.

[RFC2746] Terzis, A., Krawczyk, J., Wroclawski, J. and L. Zhang,

"RSVP Operation Over IP Tunnels", RFC2746, January 2000.

[RFC1918] Rekhter, Y., Moskowitz, B., Karrenberg, D., de Groot, G.J.

and E. Lear, "Address Allocation for Private Internets",

BCP 5, RFC1918, February 1996.

[RFC2002] Perkins, C., "IP Mobility Support", RFC2002, October

1996.

[RFC2119] Bradner, S., "Key words for use in RFCs to indicate

requirement levels", BCP 14, RFC2119, March 1997.

[RFC2663] Srisuresh, P. and M. Holdrege, "IP Network Address

Translator (NAT) Terminology and Considerations", RFC

2663, August 1999.

[RFC2205] Braden, R., Zhang, L., Berson, S., Herzog, S. and S.

Jamin, "Resource Reservation Protocol (RSVP)", RFC2205,

September 1997.

[RFC2475] Blake, S., Black, D., Carlson, M., Davies, E., Wang, Z.

and W. Weiss, "An Architecture for Differentiated

Services", RFC2475, December 1998.

[RFC3105] Kempf, J. and G. Montenegro, "Finding an RSIP Server with

SLP", RFC3105, October 2001.

10. Authors' Addresses

Michael Borella

CommWorks

3800 Golf Rd.

Rolling Meadows IL 60008

Phone: (847) 262-3083

EMail: mike_borella@commworks.com

Jeffrey Lo

Candlestick Networks, Inc

70 Las Colinas Lane,

San Jose, CA 95119

Phone: (408) 284 4132

EMail: yidarlo@yahoo.com

David Grabelsky

CommWorks

3800 Golf Rd.

Rolling Meadows IL 60008

Phone: (847) 222-2483

EMail: david_grabelsky@commworks.com

Gabriel E. Montenegro

Sun Microsystems

Laboratories, Europe

29, chemin du Vieux Chene

38240 Meylan

FRANCE

Phone: +33 476 18 80 45

EMail: gab@sun.com

11. Full Copyright Statement

Copyright (C) The Internet Society (2001). All Rights Reserved.

This document and translations of it may be copied and furnished to

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or assist in its implementation may be prepared, copied, published

and distributed, in whole or in part, without restriction of any

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included on all such copies and derivative works. However, this

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the copyright notice or references to the Internet Society or other

Internet organizations, except as needed for the purpose of

developing Internet standards in which case the procedures for

copyrights defined in the Internet Standards process must be

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English.

The limited permissions granted above are perpetual and will not be

revoked by the Internet Society or its successors or assigns.

This document and the information contained herein is provided on an

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Acknowledgement

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