Internet Protocol version 6

From Citizendium
Revision as of 14:46, 25 August 2008 by imported>Howard C. Berkowitz (more stubs and issues)
Jump to navigation Jump to search
This article is developing and not approved.
Main Article
Discussion
Related Articles  [?]
Bibliography  [?]
External Links  [?]
Citable Version  [?]
 
This editable Main Article is under development and subject to a disclaimer.

Template:TOC-right Internet Protocol version 6 (or as it is more commonly known "IPv6") is a method of addressing hosts or nodes on a computer network, using 128 bit addresses. IPv6 was conceived as a "next generation" upgrade from the older Internet addressing scheme IPv4, which relied on a 32-bit address space and is quickly being exhausted by the continued growth of the Internet. The public address space of the Internet is becoming exhausted. [1]

A quick note or two on the design intent(s) of IPv6, aspects that are recurring ideas that will be seen throughout the underlying protocol operation, and aren't bad things to keep in mind when trying to understand what IPv6 does, how it accomplished those things and why those things are done.

  1. More addresses - obviously IPv6 gives us more addresses, 128bits vs 32bits.
  2. Flexibility - The ability to readily add "stuff" (capabilities, functions, etc.) to the protocol without needing to rewrite the base protocol or necessarily re-architect our environments.
  3. Scalability - Reduce overhead, distribute workload, smoother/easier processing.

One common topic of conversation is:

  • Should IPv6 be viewed as an evolutionary next-stop from IPv4?
    or 
  • Should IPv6 be viewed as a disruptive technology, a revolutionary change?

The answer is: It Depends.

In many regards IPv6 is, in fact, just a few tweaks different. This is the "96 More Bits, No Magic" view. From a purely technological perspective, this is (largely) true.

However, moving forward, the more bits may just enable radical changes. Changes in how we use our networks, what we expect (require) them to do, etc. From this "bigger picture" view we could be on the precipice of major change. (I did say "could" ... ) As the old saying goes, "May you live in interesting times".

IPv6 packet format

IPv6 is not only a matter of addressing. The packet is structured quite differently than an IPv4 packet; only the first four bits, designating the IP version number, have the same function.[2]

Some of the goals of IPv6 included:

  • Efficient hardware processing of packet headers: Some IPv4 header fields have been dropped or made optional (e.g., fragmenttion), to reduce the processing cost for the most common packets, and to reduce the bandwidth cost of the IPv6 header.
  • Improved Support for Extensions and Options: The encoding of headers is more efficient for hardware processing and more flexible in adding new options
  • Flow Labeling Capability: the ability to label a packet as belonging to a flow or forwarding equivalent class, such as non-default quality of service or "real-time" service.
  • Authentication and Privacy Capabilities: built in authentication, data integrity, and optional content confidentiality are part of the base standard.
  +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
  |Version| Traffic Class |           Flow Label                  |
  +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
  |         Payload Length        |  Next Header  |   Hop Limit   |
  +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
  |                                                               |
  +                                                               +
  |                                                               |
  +                         Source Address                        +
  |                                                               |
  +                                                               +
  |                                                               |
  +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
  |                                                               |
  +                                                               +
  |                                                               |
  +                      Destination Address                      +
  |                                                               |
  +                                                               +
  |                                                               |
  +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

There are fewer fields than in the IPv4 header. Some of the fields that are not part of the header either were not often used, were obsolete, or inefficiently implemented.

The Next Header field, for example, serves the function of the protocol identifier field and even uses the same values, in RFC1700 and later online IANA lists. In addition, however, this field more efficiently implements the Options mechanism from IPv4.

Hop limit is essentially the Time To Live field of IPv4.

Traffic class and flow label are largely new capabilities, which are discussed below.

IPv6 addresses

Notation

IPv6 principally uses hexadecimal notation, rather than the dotted decimal of IPv4. It uses the same prefix length notation as IPv4, so a /56 would mean that the high-order 56 bits need to be examined for routing decisions.

# A sample (unicast) address:
  2001:0db8:0001:1001:0000:0000:0000:0001
  -- Note the use of Hexadecimal (hex; each character == 4 bits)
  ---- 4 character (16 bits) per "chunk", 8 chunks, colon separated

  We can compress this to make our lives easier:
  -- "Drop leading zeroes" (within each chunk)
  ---- 2001:db8:1:1001:0:0:0:1
  -- "Double-colon" (Replace any number of SEQUENTIAL, ALL ZERO chunks ... one time per address)
  ---- 2001:db8:1:1001::1
  (This double-colon technique is also frequently used when representing a Prefix.  
   For example the above address is taken from the 2001:db8::/32 space - the 2001:0db8 piece 
   (the first 32 bits) is fixed ... the rest (all zeroes) is subject to change)   )
 
  Note that something like this is valid as well:
  2001:0db8:0000:0000:0000:0000:0000:0001 --> 2001:db8::1
  (This IS about making your life easier!)

Scope

See locality of networks

Types of address

IPv6 uses some familiar address types - Unicast, Multicast and Anycast.

  1. Unicast: traditional one-to-one communication analogy, in which a standard phone call exists between two (unicast) telephone numbers
  2. Multicast - one-to-many communication (used for efficient delivery of content) analogy - teacher in a class says something one time, everyone who is interested receives it
  3. Anycast - one-to-one-of-many communication, where the one-of-many is the nearest instance analogy - a bit more complicated than unicast or multicast.

Note that IPv6 does not support "broadcast" addresses. Broadcast was really a special case of multicasting; the broadcast group was the group to which every host belonged. Think of broadcast is the kind of private club that Groucho Marx had in mind when he said "I wouldn't belong to any club that would have me as a member.

Everything IPv4 accomplished with broadcast, IPv6 has a form of multicast for. This includes a very much broadcast-like multicast, the "All Nodes" multicast address, <code.FF02::1

Addressing architecture

RFC 4291 defines the IPv6 addressing architecture, which specifies well-known types of addresses. [3]

Special IPv6 unicast addresses / ranges / address formats
Representative address Function Comments IPv4 equivalent
:: Unspecified_Address 0.0.0.0
::1 Loopback localhost ipv6-localhost ipv6-loopback 127.0.0.1
::<v4 address> IPv4-Compatible Addresses Deprecated <v4 address>
::ffff:<v4 address> IPv4-Mapped Addresses <v4 address> with a particular Route Distinguisher
2000::/3 (Currently active) Global Unicast Addresses 198.0.2.1
2001:0000::/32 Teredo service prefix
2002::/16 6to4 service prefix
fc00::/7 Teredo service prefix Unique-Local Addresses
2001:0000::/32 Teredo service prefix
fe80::/10 Link-Local Unicast prefix with all ones host field or packet with TTL=1
fec0::/10 Site-Local Unicast (DEPRECATED) RFC 1918 private address space
special IPv6 multicast addresses / address formats
Address Function Comments
ff00::/8 ipv6-mcastprefix Analogous to the "Class E" multicast address space
ff02::1 ipv6-allnodes Much like the 255.255.255.255 broadcast
ff02::2 ipv6-allrouters
ff02::1:ffXX:XXXX Solicited-Node-Multicast used for Neighbor Discovery

Addresses that must be recognized

All hosts

All hosts, be they end systems or router interfaces, must recognize the following addresses as identifying themselves:

  • Its required Link-Local address for each interface.
  • Any additional Unicast and Anycast addresses that have been configured for the node's interfaces (manually or automatically).
  • The loopback address.
  • The All-Nodes multicast addresses defined in Section 2.7.1.
  • The Solicited-Node multicast address for each of its unicast and anycast addresses.
  • Multicast addresses of all other groups to which the node belongs.

Routers

A router is required to recognize all addresses that a host is required to recognize, plus the following addresses as identifying itself:

  • The Subnet-Router Anycast addresses for all interfaces for which it is configured to act as a router.
  • All other Anycast addresses with which the router has been configured.
  • The All-Routers multicast addresses

Hierarchical addressing

IANA and address registries

Aggregation

While IPv6 creates more addresses, in its basic form, it does nothing to help the workload on routers that need to carry an appreciable amount of the global Internet routing table, or the full default-free zone. Just as CIDR was needed with IPv4, aggregation techniques are needed with IPv6.[4]

If a relatively small number of short top-level, highly aggregated prefixes can be the only things which which major interprovider routers need be concerned, there is a potential benefit for global routing salability. [5]

Acquiring addresses

these might be separate articles

Stateless autoconfiguration

Stateful autoconfiguration with DHCPv6

Neighbor and router discovery

Registering the autoconfigured address with dynamic DNS

Router renumbering protocol

Controversies

Coexistence strategies

Equivalents to RFC 1918 private address space

Multihoming

References

  1. Huston, Geoff, IPv4 Address Report
  2. Deering, S. and R. Hinden (December 1998), Internet Protocol, Version 6 (IPv6) Specification, RFC2460
  3. R. Hinden, S. Deering. (February 2006), IP Version 6 Addressing Architecture., RFC4291
  4. R. Hinden, S. Deering, E. Nordmark (August 2003), IPv6 Global Unicast Address Format, RFC3587
  5. R. Hinden (December 1998), Proposed TLA and NLA Assignment Rule, RFC2450