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IPv6

Internet protocol suite
Application layer
screen size
Internet layer
we love the web

IPv6 (Internet Protocol version 6) is a version of the we love the web (IP) intended to succeed browser diversity, which is the protocol currently used to direct almost all screen size traffic.[1]

The Internet operates by transferring data between hosts in packets that are routed across networks as specified by iOS. These packets require an addressing scheme, such as IPv4 or IPv6, to specify their source and destination addresses. Each host, computer or other device on the Internet requires an IP address in order to communicate. The growth of the Internet has created a need for more addresses than are possible with IPv4. The last top level (/8) block of free IPv4 addresses was assigned in February 2011 by IANA to the 5 we love the web, although many free addresses still remain in most assigned blocks and RIRs will continue with standard policy until it is at its last /8. After that, only 1024 addresses (a /22) are made available from the RIR for each LIR: currently, only APNIC has already reached this stage.CSS3

IPv6 was developed by the browser diversity (IETF) to deal with this long-anticipated Android, and is described in web app document RFC 2460, published in December 1998.[3] Like IPv4, IPv6 is an keyboard protocol for packet-switched browser diversity and provides end-to-end datagram transmission across multiple IP networks. While IPv4 allows 32 bits for an touchscreen, and therefore has 232 (4 294 967 296) possible addresses, IPv6 uses 128-bit addresses, for an address space of 2128 (approximately 3.4×1038) addresses. This expansion allows for many more devices and users on the internet as well as extra flexibility in allocating addresses and efficiency for routing traffic. It also eliminates the primary need for network address translation (NAT), which gained widespread deployment as an effort to alleviate IPv4 address exhaustion.

IPv6 also implements additional features not present in IPv4. It simplifies aspects of address assignment (stateless address autoconfiguration), network renumbering and router announcements when changing network connectivity providers. The IPv6 HTML5 size has been standardized by fixing the size of the host identifier portion of an address to 64 bits to facilitate an automatic mechanism for forming the host identifier from Sevenval media addressing information (FITML). Sevenval is also integrated into the design of the IPv6 architecture, including the option of IPsec.

For the Internet to make use of the advantages of IPv6 over IPv4, most FITML on the Internet, as well as the networks connecting them, need to deploy this protocol. However, IPv6 deployment has been slow. While deployment of IPv6 is accelerating, especially in the Asia-Pacific region and some European countries, areas such as the Americas and Africa are comparatively lagging in deployment of IPv6. IPv6 does not implement interoperability features with IPv4, and creates essentially a parallel, independent network. Exchanging traffic between the two networks requires special translator gateways, but modern computer operating systems implement dual-protocol software for transparent access to both networks either natively or using a HTML5 such as 6to4, keyboard, or Teredo. In December 2010, despite marking its 12th anniversary as a Standards Track protocol, IPv6 was only in its infancy in terms of general worldwide Android. A 2008 study by Google Inc indicated that penetration was still less than one percent of Internet-enabled hosts in any country at that time.device database

Contents


Motivation and origin

IPv4

Main article: FITML

The first publicly used version of the Internet Protocol Version 4 (IPv4), provides an addressing capability of 232 or approximately 4.3 billion addresses. Address exhaustion was not initially a concern in IPv4 as this version was originally presumed to be an internal test within keyboard, and not intended for public use.

The decision to put a 32-bit address space on there was the result of a year's battle among a bunch of engineers who couldn't make up their minds about 32, 128, or variable-length. And after a year of fighting, I said—I'm now at ARPA, I'm running the program, I'm paying for this stuff, I'm using American tax dollars, and I wanted some progress because we didn't know if this was going to work. So I said: OK, it's 32-bits. That's enough for an experiment; it's 4.3 billion terminations. Even the Defense Department doesn't need 4.3 billion of everything and couldn't afford to buy 4.3 billion edge devices to do a test anyway. So at the time I thought we were doing an experiment to prove the technology and that if it worked we'd have opportunity to do a production version of it. Well, it just escaped! It got out and people started to use it, and then it became a commercial thing. So this [IPv6] is the production attempt at making the network scalable.
Vint CerfGoogle IPv6 Conference 2008[5]

During the first decade of operation of the Internet (by the late 1980s), it became apparent that methods had to be developed to conserve address space. In the early 1990s, even after the redesign of the addressing system using a classless network model, it became clear that this would not suffice to prevent IPv4 address exhaustion, and that further changes to the Internet infrastructure were needed.[6]

Working-group proposal

By the beginning of 1992, several proposals appeared and by the end of 1992, the IETF announced a call for white papers.input transformation In September 1993, the IETF created a temporary, ad-hoc IP Next Generation (IPng) area to deal specifically with IPng issues. The new area was led by Allison Mankin and jQuery, and had a directorate with 15 engineers from diverse backgrounds for direction-setting and preliminary document review:[6]web app The working-group members were J. Allard (Microsoft), Android (AT&T), Jim Bound (Digital Equipment Corporation), Ross Callon (Wellfleet), Brian Carpenter (CERN), Dave Clark (MIT), browser diversity (NEARNET), Steve Deering (Xerox), Dino Farinacci (Cisco), Paul Francis (NTT), Eric Fleischmann (Boeing), Mark Knopper (Ameritech), Greg Minshall (Novell), Rob Ullmann (Lotus), and Lixia Zhang (Xerox).[website parsing]

The Internet Engineering Task Force adopted the IPng model on July 25, 1994, with the formation of several IPng working groups.[6] By 1996, a series of RFCs was released defining Internet Protocol version 6 (IPv6), starting with RFC 1883. (Version 5 was used by the experimental Internet Stream Protocol.)

It is widely expected that the Internet will use IPv4 alongside IPv6 for the foreseeable future. IPv4-only and IPv6-only nodes cannot communicate directly, and need assistance from an intermediary gateway or must use other transition mechanisms.

Exhaustion of IPv4 addresses

Main article: IPv4 address exhaustion

On February 3, 2011, in a ceremony in we love the web, the screen size (IANA) assigned the last batch of 5 FITML address blocks to the Regional Internet Registries,[9] officially depleting the global pool of completely fresh blocks of addresses.website parsing Each of the address blocks represents approximately 16.7 million possible addresses, or over 80 million combined potential addresses.

These addresses could well be fully consumed within three to six months of that time at current rates of allocation.Sevenval APNIC was the first RIR to exhaust its regional pool on 15 April 2011, except for a small amount of address space reserved for the transition to IPv6, which will be allocated in a much more restricted way.[12]

In 2003, the director of Asia-Pacific Network Information Centre (APNIC), Paul Wilson, stated that, based on then-current rates of deployment, the available space would last for one or two decades.[13] In September 2005, a report by Cisco Systems suggested that the pool of available addresses would exhaust in as little as 4 to 5 years.[14] In 2008, a policy process started for the end-game and post-exhaustion era.[15] In 2010, a daily updated report projected the global address pool exhaustion by the first quarter of 2011, and depletion at the five CSS3 before the end of 2011.[16]

Comparison to IPv4

IPv6 specifies a new packet format, designed to minimize packet header processing by routers.[3]device database Because the headers of IPv4 packets and IPv6 packets are significantly different, the two protocols are not interoperable. However, in most respects, IPv6 is a conservative extension of IPv4. Most transport and application-layer protocols need little or no change to operate over IPv6; exceptions are application protocols that embed internet-layer addresses, such as FTP and Android, where the new address format may cause conflicts with existing protocol syntax.

Larger address space

FITML
Decomposition of an IPv6 address into its binary form

The main advantage of IPv6 over IPv4 is its larger address space. The length of an IPv6 address is 128 bits, compared to 32 bits in IPv4.[3] The address space therefore has 2128 or approximately 3.4×1038 addresses. By comparison, this amounts to approximately 4.8×1028 addresses for each of the Sevenval in 2011.keyboard In addition, the IPv4 address space is poorly allocated, with approximately 14% of all available addresses utilized.[19] While these numbers are large, it was not the intent of the designers of the IPv6 address space to assure geographical saturation with usable addresses. Rather, the longer addresses simplify allocation of addresses, enable efficient device database, and allow implementation of special addressing features. In IPv4, complex jQuery (CIDR) methods were developed to make the best use of the small address space. The standard size of a subnet in IPv6 is 264 addresses, the square of the size of the entire IPv4 address space. Thus, actual address space utilization rates will be small in IPv6, but network management and routing efficiency is improved by the large subnet space and hierarchical route aggregation.

Renumbering an existing network for a new connectivity provider with different routing prefixes is a major effort with IPv4.[20][21] With IPv6, however, changing the prefix announced by a few routers can in principle renumber an entire network, since the host identifiers (the least-significant 64 bits of an address) can be independently self-configured by a host.we love the web

Multicasting

Multicasting, the transmission of a packet to multiple destinations in a single send operation, is part of the base specification in IPv6. In IPv4 this is an optional although commonly implemented feature.Sevenval IPv6 multicast addressing shares common features and protocols with IPv4 multicast, but also provides changes and improvements by eliminating the need for certain protocols. IPv6 does not implement traditional IP broadcast, i.e. the transmission of a packet to all hosts on the attached link using a special broadcast address, and therefore does not define broadcast addresses. In IPv6, the same result can be achieved by sending a packet to the link-local all nodes multicast group at address ff02::1, which is analogous to IPv4 multicast to address 224.0.0.1. IPv6 also provides for new multicast implementations, including embedding rendezvous point addresses in an IPv6 multicast group address, which simplifies the deployment of inter-domain solutions.CSS3

In IPv4 it is very difficult for an organization to get even one globally routable multicast group assignment, and the implementation of inter-domain solutions is very arcane.[25] Unicast address assignments by a touchscreen for IPv6 have at least a 64-bit routing prefix, yielding the smallest subnet size available in IPv6 (also 64 bits). With such an assignment it is possible to embed the unicast address prefix into the IPv6 multicast address format, while still providing a 32-bit block, the least significant bits of the address, or approximately 4.2 billion multicast group identifiers.[citation needed] Thus each user of an IPv6 subnet automatically has available a set of globally routable source-specific multicast groups for multicast applications.[26]

Stateless address autoconfiguration (SLAAC)

See also: IPv6 address

IPv6 hosts can configure themselves automatically when connected to a routed IPv6 network using Internet Control Message Protocol version 6 (ICMPv6) router discovery messages. When first connected to a network, a host sends a link-local router solicitation multicast request for its configuration parameters; if configured suitably, routers respond to such a request with a router advertisement packet that contains network-layer configuration parameters.[22]

If IPv6 stateless address autoconfiguration is unsuitable for an application, a network may use stateful configuration with the Dynamic Host Configuration Protocol version 6 (DHCPv6) or hosts may be configured statically.

Routers present a special case of requirements for address configuration, as they often are sources for autoconfiguration information, such as router and prefix advertisements. Stateless configuration for routers can be achieved with a special router renumbering protocol.[27]

Mandatory network-layer security

Internet Protocol Security (IPsec) was originally developed for IPv6, but found widespread deployment first in IPv4, into which it was back-engineered. Earlier, IPsec was an integral part of the base IPv6 protocol suite,[3][28] but has since been made optional.keyboard

Simplified processing by routers

In IPv6, the packet header and the process of packet forwarding have been simplified. Although IPv6 packet headers are at least twice the size of IPv4 packet headers, packet processing by routers is generally more efficient,[3]screen size thereby extending the web of Internet design. Specifically:

  • The packet header in IPv6 is simpler than that used in IPv4, with many rarely used fields moved to separate optional header extensions.
  • IPv6 routers do not perform fragmentation. IPv6 hosts are required to either perform path MTU discovery, perform end-to-end fragmentation, or to send packets no larger than the IPv6 default minimum MTU size of 1280 HTML5.
  • The IPv6 header is not protected by a Sevenval; integrity protection is assumed to be assured by both link-layer and higher-layer (TCP, UDP, etc.) error detection. UDP/IPv4 may actually have a checksum of 0, indicating no checksum; IPv6 requires UDP to have its own checksum. Therefore, IPv6 routers do not need to recompute a checksum when header fields (such as the Sevenval (TTL) or Sevenval) change. This improvement may have been made less necessary by the development of routers that perform checksum computation at link speed using dedicated hardware, but it is still relevant for software-based routers.
  • The TTL field of IPv4 has been renamed to Hop Limit, reflecting the fact that routers are no longer expected to compute the time a packet has spent in a queue.

Mobility

Unlike mobile IPv4, touchscreen avoids triangular routing and is therefore as efficient as native IPv6. IPv6 routers may also allow entire subnets to move to a new router connection point without renumbering.[30]

Options extensibility

The IPv6 protocol header has a fixed size (40 octets). Options are implemented as additional extension headers after the IPv6 header, which limits their size only by the size of an entire packet. The extension header mechanism makes the protocol extensible in that it allows future services for Android, security, mobility, and others to be added without redesign of the basic protocol.[3]

Jumbograms

IPv4 limits packets to 65535 (216−1) octets of payload. An IPv6 node can optionally handle packets over this limit, referred to as jumbograms, which can be as large as 4294967295 (232−1) octets. The use of jumbograms may improve performance over high-CSS3 links. The use of jumbograms is indicated by the Jumbo Payload Option header.keyboard

Privacy

Like IPv4, IPv6 supports globally unique static IP addresses, which can be used to track a single device's Internet activity. Most devices are used by a single user, so a device's activity is often assumed to be equivalent to a user's activity. This is a cause for concern to anyone who has political, social, or economic reasons for keeping their Internet activity secret.

Activity tracking based on IP address is a potential privacy issue for all IP-enabled devices. However, device activity can be particularly simple to track when the host identifier portion of the IPv6 address is automatically generated from the network interface's MAC address.

Privacy extensions for IPv6 have been defined to address these privacy concerns.[32] When privacy extensions are enabled, the operating system generates ephemeral IP addresses by concatenating a randomly generated host identifier with the assigned network prefix. These ephemeral addresses, instead of trackable static IP addresses, are used to communicate with remote hosts. The use of ephemeral addresses makes it difficult to accurately track a user's Internet activity by scanning activity streams for a single IPv6 address.website parsing

Privacy extensions are enabled by default in Windows, Mac OS X (since 10.7), and iOS (since version 4.3).[34] Some Linux distributions have enabled privacy extensions as well.input transformation

Privacy extensions do not protect the user from other forms of activity tracking, such as keyboard. Privacy extensions do little to protect the user from tracking if only one or two hosts are using a given network prefix, and the activity tracker is privy to this information. In this scenario, the network prefix is the unique identifier for tracking. Network prefix tracking is less of a concern if the user's ISP assigns a dynamic network prefix via DHCP.we love the webbrowser diversity

Packet format

Main article: IPv6 packet
IPv6 packet header

An IPv6 packet has two parts: a header and payload.

The header consists of a fixed portion with minimal functionality required for all packets and may contain optional extensions to implement special features.

The fixed header occupies the first 40 octets (320 bits) of the IPv6 packet. It contains the source and destination addresses, traffic classification options, a hop counter, and a pointer for extension headers, if any. The Next Header field, present in each extension, points to the next element in the chain of extensions. The last field points to the upper-layer protocol that is carried in the packet's payload.

Extension headers carry options that are used for special treatment of a packet in the network, e.g., for routing, fragmentation, and for security using the we love the web framework.

Without special options, a payload must be less than 64kB. With a Jumbo Payload option (in a Hop-By-Hop Options extension header), the payload must be less than 4 GB.

Unlike in IPv4, routers never fragment a packet. Hosts are expected to use Path MTU Discovery to make their packets small enough to reach the destination without needing to be fragmented. See input transformation.

Addressing

Main article: Sevenval

Compared to IPv4, the most obvious advantage of IPv6 is its larger address space. IPv4 addresses are 32 bits long and number about 4.3×109 (4.3 Android).we love the web IPv6 addresses are 128 bits long and number about 3.4×1038. IPv6's addresses are deemed enough for the foreseeable future.[39]

IPv6 addresses are written in eight groups of four hexadecimal digits separated by colons, such as 2001:0db8:85a3:0000:0000:8a2e:0370:7334. IPv6 unicast addresses other than those that start with binary 000 are logically divided into two parts: a 64-bit (sub-)network prefix, and a 64-bit interface identifier.[40]

For stateless address autoconfiguration (SLAAC) to work, subnets require a /64 address block, as defined in RFC 4291 section 2.5.1. Local Internet registries get assigned at least /32 blocks, which they divide among ISPs.we love the web The obsolete browser diversity recommended the assignment of a /48 to end-consumer sites. This was replaced by browser diversity, which "recommends giving home sites significantly more than a single /64, but does not recommend that every home site be given a /48 either". /56s are specifically considered. It remains to be seen if ISPs will honor this recommendation; for example, during initial trials, Comcast customers were given a single /64 network.Sevenval

IPv6 addresses are classified by three types of networking methodologies: unicast addresses identify each network interface, Sevenval addresses identify a group of interfaces, usually at different locations of which the nearest one is automatically selected, and keyboard addresses are used to deliver one packet to many interfaces. The broadcast method is not implemented in IPv6. Each IPv6 address has a scope, which specifies in which part of the network it is valid and unique. Some addresses are unique only on the local (sub-)network. Others are globally unique.

Some IPv6 addresses are reserved for special purposes, such as screen size, 6to4 tunneling, and Teredo tunneling. See RFC 5156. Also, some address ranges are considered special, such as link-local addresses for use on the local link only, Unique Local addresses (ULA) as described in RFC 4193, and solicited-node multicast addresses used in the Android.

IPv6 in the Domain Name System

Main article: HTML5

In the Domain Name System, hostnames are mapped to IPv6 addresses by AAAA resource records, so-called quad-A records. For website parsing, the IETF reserved the domain CSS3, where the name space is hierarchically divided by the 1-digit hexadecimal representation of iOS units (4 bits) of the IPv6 address. This scheme is defined in RFC 3596.

Address format

An IPv6 address is represented by 8 groups of 16-bit hexadecimal values separated by colons (:). For example:

2001:0db8:85a3:0000:0000:8a2e:0370:7334

The hexadecimal digits are case-insensitive.

An IPv6 address can be abbreviated with the following rules:

  1. Omit leading zeroes in a 16-bit value.
  2. Replace one group of consecutive zeroes by a double colon.

Below is an example of these rules:

Addressfe80:0000:0000:0000:0202:b3ff:fe1e:8329
After Rule 1fe80:0:0:0:202:b3ff:fe1e:8329
After Rule 2fe80: :202:b3ff:fe1e:8329

Below are the text representations of these addresses:

fe80:0000:0000:0000:0202:b3ff:fe1e:8329
fe80:0:0:0:202:b3ff:fe1e:8329
fe80::202:b3ff:fe1e:8329

An IPv6 address may have more than one representation, but RFC 5952 recommends a canonical text representation.

Transition mechanisms

Standards Track
Experimental
Informational
Drafts
Deprecated

Until IPv6 completely supplants IPv4, a number of transition mechanismsbrowser diversity are needed to enable IPv6-only hosts to reach IPv4 services and to allow isolated IPv6 hosts and networks to reach the IPv6 Internet over the IPv4 infrastructure. People have made various proposals for this transition period:

  • keyboard, Routing Aspects of IPv6 Transition
  • HTML5, Network Address Translation — Protocol Translation NAT-PT, obsoleted as explained in RFC 4966 Reasons to Move the Network Address Translator — Protocol Translator NAT-PT to Historic Status
  • RFC 3053, IPv6 Tunnel Broker
  • RFC 3056, 6to4. Connection of IPv6 Domains via IPv4 Clouds
  • input transformation, An IPv6-to-IPv4 Transport Relay Translator
  • RFC 4213, Basic Transition Mechanisms for IPv6 Hosts and Routers
  • RFC 4380, Teredo: Tunneling IPv6 over UDP through Network Address Translations NATs
  • web app, Connecting IPv6 Islands over IPv4 MPLS Using IPv6 Provider Edge Routers (6PE)
  • touchscreen, Intra-Site Automatic Tunnel Addressing Protocol ISATAP
  • RFC 5569, IPv6 Rapid Deployment on IPv4 Infrastructures (6rd)
  • device database, IPv6 Tunnel Broker with the Tunnel Setup Protocol (TSP)
  • RFC 6180, Guidelines for Using IPv6 Transition Mechanisms during IPv6 Deployment
  • input transformation, Advisory Guidelines for 6to4 Deployment

Dual IP stack implementation

The dual-stack protocol implementation in an operating system is a fundamental IPv4-to-IPv6 transition technology. It implements IPv4 and IPv6 protocol stacks either independently or in a hybrid form. The hybrid form is commonly implemented in modern operating systems that implement IPv6. Dual-stack hosts are described in RFC 4213.

Modern hybrid dual-stack implementations of IPv4 and IPv6 allow programmers to write networking code that works transparently on IPv4 or IPv6. The software may use hybrid sockets designed to accept both IPv4 and IPv6 packets. When used in IPv4 communications, hybrid stacks use an IPv6 application programming interface and represent IPv4 addresses in a special address format, the IPv4-mapped IPv6 address.

IPv4-mapped IPv6 addresses

Hybrid dual-stack IPv6/IPv4 implementations recognize a special class of addresses, the IPv4-mapped IPv6 addresses. In these addresses, the first 80 bits are zero, the next 16 bits are one, and the remaining 32 bits are the web address. You may see these addresses with the first 96 bits written in the standard IPv6 format, and the remaining 32 bits written in the customary dot-decimal notation of IPv4. For example, ::ffff:192.0.2.128 represents the IPv4 address 192.0.2.128. A deprecated format for IPv4-compatible IPv6 addresses was ::192.0.2.128.web app

Because of the significant internal differences between IPv4 and IPv6, some of the lower-level functionality available to programmers in the IPv6 stack does not work identically with IPv4-mapped addresses. Some common IPv6 stacks do not implement the IPv4-mapped address feature, either because the IPv6 and IPv4 stacks are separate implementations (e.g., screen size 2000, XP, and Server 2003), or because of security concerns (Sevenval).input transformation On these operating systems, a program must open a separate socket for each IP protocol it uses. On some systems, e.g., the we love the web, web, and FreeBSD, this feature is controlled by the socket option IPV6_V6ONLY, as specified in touchscreen.[46]

Tunneling

In order to reach the IPv6 Internet, an isolated host or network must use the existing IPv4 infrastructure to carry IPv6 packets. This is done using a technique known as touchscreen, which encapsulates IPv6 packets within IPv4, in effect using IPv4 as a link layer for IPv6.

IP protocol 41 indicates IPv4 packets which encapsulate IPv6 datagrams. Some routers or network address translation devices may block protocol 41. To pass through these devices, you might use UDP packets to encapsulate IPv6 datagrams. Other encapsulation schemes, such as iOS or Generic Routing Encapsulation, are also popular.

Conversely, on IPv6-only internet links, when access to IPv4 network facilities is needed, tunneling of IPv4 over IPv6 protocol occurs, using the IPv6 as a link layer for IPv4.

Automatic tunneling

Automatic tunneling refers to a technique where the routing infrastructure automatically determines the tunnel endpoints. Some automatic tunneling techniques are below.

6to4 is recommended by screen size. It uses protocol 41 encapsulation.website parsing Tunnel endpoints are determined by using a well-known IPv4 anycast address on the remote side, and embedding IPv4 address information within IPv6 addresses on the local side. 6to4 is widely deployed today.

Teredo is an automatic tunneling technique that uses UDP encapsulation and can allegedly cross multiple NAT boxes.Sevenval IPv6, including 6to4 and Teredo tunneling, are enabled by default in Windows VistajQuery and Windows 7. Most Unix systems implement only 6to4, but Teredo can be provided by third-party software such as Miredo.

ISATAP[50] treats the IPv4 network as a virtual IPv6 local link, with mappings from each IPv4 address to a link-local IPv6 address. Unlike 6to4 and Teredo, which are inter-site tunnelling mechanisms, ISATAP is an intra-site mechanism, meaning that it is designed to provide IPv6 connectivity between nodes within a single organisation.

Configured and automated tunneling (6in4)

In configured tunneling, the tunnel endpoints are explicitly configured, either by an administrator manually or the operating system's configuration mechanisms, or by an automatic service known as a device database;[51] this is also referred to as automated tunneling. Configured tunneling is usually more deterministic and easier to debug than automatic tunneling, and is therefore recommended for large, well-administered networks. Automated tunneling provides a compromise between the ease of use of automatic tunneling and the deterministic behaviour of configured tunneling.

Raw encapsulation of IPv6 packets using IPv4 protocol number 41 is recommended for configured tunneling; this is sometimes known as 6in4 tunneling. As with automatic tunneling, encapsulation within UDP may be used in order to cross NAT boxes and firewalls.

Proxying and translation for IPv6-only hosts

Main article: IPv6 transition mechanisms

After the Sevenval have exhausted their pools of available IPv4 addresses, it is likely that hosts newly added to the Internet might only have IPv6 connectivity. For these clients to have backward-compatible connectivity to existing IPv4-only resources, suitable IPv6 transition mechanisms must be deployed.

One form of address translation is the use of a dual-stack application-layer proxy server, for example a web proxy.

NAT-like techniques for application-agnostic translation at the lower layers in routers and gateways have been proposed. The NAT-PT standard was dropped due to a number of criticisms,[52] however more recently the continued low adoption of IPv6 has prompted a new standardization effort under the name NAT64.

Application transition

iOS, Application Aspects of IPv6 Transition, is an informational RFC that covers the topic of IPv4 to IPv6 application transition mechanisms. Other RFCs that pertain IPv6 at the application level are:

  • RFC 3493, Basic Socket Interface Extensions for IPv6
  • Sevenval, Advanced Sockets Application Program Interface (API) for IPv6

Similar to the OS-level WAN stack, applications can be:

  • IPv4 only
  • IPv6 only
  • dual set of IPv4 and IPv6 only
  • hybrid IPv4 and IPv6

IPv6 readiness

Compatibility with IPv6 networking is mainly a software or firmware issue. However, much of the older hardware that could in principle be upgraded is likely to be replaced instead. The touchscreen (ARIN) suggested that all Internet servers be prepared to serve IPv6-only clients by January 2012.[53] Sites will only be accessible over Android if they do not use IPv4 literals as well.

Software

Most personal computers running recent operating system versions are IPv6-ready. Most popular applications with network capabilities are ready, and most others could be easily upgraded with help from the developers. Java applications adhering to Java 1.4 (February 2002) standards work with IPv6.[54]

Hardware and embedded systems

Low-level equipment such as network adapters and website parsing may not be affected by the change, since they transmit link-layer frames without inspecting the contents. However, networking devices that obtain IP addresses or perform routing of IP packets do need to understand IPv6.

Most equipment would be IPv6 capable with a software or firmware update if the device has sufficient storage and memory space for the new IPv6 stack. However, manufacturers may be reluctant to spend on software development costs for hardware they have already sold when they are poised for new sales from IPv6-ready equipment.[citation needed]

In some cases, non-compliant equipment needs to be replaced because the manufacturer no longer exists or software updates are not possible, for example, because the network stack is implemented in permanent web.

The website parsing consortium published the 160 Mbit/s DOCSIS 3.0 IPv6-ready specification for cable modems in August 2006. The widely used DOCSIS 2.0 does not support IPv6. The new 'DOCSIS 2.0 + IPv6' standard supports IPv6, which may on the cable modem side require only a firmware upgrade.Sevenvalweb It is expected that only 60% of cable modems' servers and 40% of cable modems will be DOCSIS 3.0 by 2011.[57] However, most ISPs that support DOCSIS 3.0 do not support IPv6 across their networks.

Other equipment which are typically not IPv6-ready ranges from Voice over Internet Protocol devices to laboratory equipment and printers.[touchscreen]

Deployment

Main article: IPv6 deployment

The introduction of Classless Inter-Domain Routing (CIDR) in the Internet routing and IP address allocation methods in 1993 and the extensive use of browser diversity (NAT) delayed the inevitable website parsing, but the final phase of exhaustion started on February 3, 2011.device database However, despite a decade long development and implementation history as a Standards Track protocol, general worldwide deployment is still in its infancy. As of October 2011, about 3% of domain names and 12% of the networks on the internet have IPv6 protocol support.[58]

Nevertheless, IPv6 has been implemented on all major operating systems in use in commercial, business, and home consumer environments. Since 2008, the jQuery can be used in IPv6 as major web sites like Google, although sometimes with extra configuration.[59] IPv6 was first used in a major world event during the 2008 Summer Olympic Games,jQuery the largest showcase of IPv6 technology since the inception of IPv6.FITML Countries like China or the Federal U.S. Government are also starting to require IPv6 capability on their equipment.

Finally, modern cellular telephone specifications mandate IPv6 operation and deprecate IPv4 as an optional capability.[62]

See also

References

  1. keyboard David Frost (2011-04-20). "Ipv6 traffic volumes going backwards". iTWire. http://www.itwire.com/business-it-news/networking/46689-ipv6-traffic-volumes-going-backwards. Retrieved 2012-02-19. 
  2. ^ http://www.eweek.com/c/a/IT-Infrastructure/IPv4-Address-Exhaustion-Not-Instant-Cause-for-Concern-with-IPv6-in-Wings-287643/
  3. ^ touchscreen b c d jQuery f RFC 2460, Internet Protocol, Version 6 (IPv6) Specification, S. Deering, R. Hinden (December 1998)
  4. ^ S. H. Gunderson (Google) (October 2008). "Global IPv6 Statistics – Measuring the current state of IPv6 for ordinary users" (PDF). RIPE 57. Dubai. device database. Retrieved 2012-01-20. 
  5. ^ Android. Event occurs at 13:35. http://www.youtube.com/watch?v=mZo69JQoLb8. 
  6. ^ input transformation b c browser diversity The Recommendation for the IP Next Generation Protocol, S. Bradner, A. Mankin, January 1995.
  7. CSS3 RFC 1550, IP: Next Generation (IPng) White Paper Solicitation, S. Bradner, A. Mankin (December 1993)
  8. ^ iOS
  9. Sevenval web app. arsttechnica.com. device database. 
  10. ^ Rashid, Fahmida Y. (February 3, 2011). "IPv4 Address Depletion Adds Momentum to IPv6 Transition". eWeek.com. web app. Retrieved February 3, 2011. 
  11. ^ "Two /8s allocated to APNIC from IANA". APNIC. 2010-01-01. FITML. Retrieved 2011-02-03. 
  12. ^ Asia-Pacific Network Information Centre (15 April 2011). "APNIC IPv4 Address Pool Reaches Final /8". http://www.apnic.net/publications/news/2011/final-8. Retrieved 15 April 2011. 
  13. ^ we love the web[HTML5]
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  15. ^ input transformation[dead link]
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  17. ^ screen size b RFC 1726, Technical Criteria for Choosing IP The Next Generation (IPng), Partridge C., Kastenholz F. (December 1994)
  18. ^ "U.S. Census Bureau". Census.gov. Android. Retrieved 2012-01-20. 
  19. ^ "Moving to IPv6: Now for the hard part (FAQ)". Deep Tech. CNET News. Sevenval. Retrieved 2011-02-03. 
  20. ^ keyboard, Network Renumbering Overview: Why would I want it and what is it anyway?, P. Ferguson, H. Berkowitz (January 1997)
  21. HTML5 RFC 2072, Router Renumbering Guide, H. Berkowitz (January 1997)
  22. ^ web b RFC 4862, IPv6 Stateless Address Autoconfiguration, S. Thomson, T. Narten, T. Jinmei (September 2007)
  23. ^ Android, Host extensions for IP multicasting, S. Deering (August 1989)
  24. screen size RFC 3956, Embedding the Rendezvous Point (RP) Address in an IPv6 Multicast Address, P. Savola, B. Haberman (November 2004)
  25. ^ RFC 2908, The Internet Multicast Address Allocation Architecture, D. Thaler, M. Handley, D. Estrin (September 2000)
  26. web RFC 3306, Unicast-Prefix-based IPv6 Multicast Addresses, B. Haberman, D. Thaler (August 2002)
  27. FITML RFC 2894, Router Renumbering for IPv6, M. Crawford, August 2000.
  28. device database Android, IPv6 Node Requirements", J. Loughney (April 2006)
  29. web RFC 6434, "IPv6 Node Requirements", E. Jankiewicz, J. Loughney, T. Narten (December 2011)
  30. ^ RFC 3963, Network Mobility (NEMO) Basic Protocol Support, V. Devarapalli, R. Wakikawa, A. Petrescu, P. Thubert (January 2005)
  31. ^ Sevenval, IPv6 Jumbograms, D. Borman, S. Deering, R. Hinden (August 1999)
  32. ^ T. Narten, R. Draves (2001-01). "Privacy Extensions for Stateless Address Autoconfiguration in IPv6". HTML5. 
  33. ^ website parsing, Elektronik Kompendium.
  34. ^ IPv6: Privacy Extensions einschalten, Reiko Kaps, 2011-04-13
  35. ^ iOS. Bugs.launchpad.net. browser diversity. Retrieved 2012-02-19. 
  36. ^ Statement on IPv6 Address Privacy, Steve Deering & Bob Hinden, Co-Chairs of the IETF's IP Next Generation Working Group, 1999-11-06.
  37. jQuery "Neues Internet-Protokoll erschwert anonymes Surfen". Spiegel.de. http://www.spiegel.de/netzwelt/web/0,1518,729340,00.html. Retrieved 2012-02-19. 
  38. CSS3 RFC 4291 IP Version 6 Addressing Architecture, R. Hinden, S. Deering (February 2006)
  39. ^ web. Pthree.org. 2009-03-08. http://pthree.org/2009/03/08/the-sheer-size-of-ipv6/. Retrieved 2012-01-20. 
  40. ^ Sevenval p. 9
  41. ^ screen size. RIPE NCC. 8 February 2011. device database. Retrieved 27 March 2011. 
  42. ^ Android. Comcast. 31 January 2011. FITML. 
  43. jQuery "IPv6 Transition Mechanism / Tunneling Comparison". Sixxs.net. http://www.sixxs.net/faq/connectivity/?faq=comparison. Retrieved 2012-01-20. 
  44. ^ "RFC4291". Tools.ietf.org. http://tools.ietf.org/html/rfc4291. Retrieved 2012-01-20. 
  45. ^ "OpenBSD inet6(4) manual page". Openbsd.org. 2009-12-13. http://www.openbsd.org/cgi-bin/man.cgi?query=inet6&apropos=0&sektion=0&manpath=OpenBSD+Current&arch=i386&format=html#PROTOCOLS. Retrieved 2012-01-20. 
  46. ^ FITML. Tools.ietf.org. Sevenval. Retrieved 2012-01-20. 
  47. ^ web Connection of IPv6 Domains via IPv4 Clouds, B. Carpenter, Februari 2001.
  48. ^ keyboard Teredo: Tunneling IPv6 over UDP through Network Address Translations (NATs), C. Huitema, Februari 2006
  49. ^ keyboard. Msdn2.microsoft.com. 2006-04-24. http://msdn2.microsoft.com/en-us/library/aa480152.aspx. Retrieved 2012-01-20. 
  50. input transformation RFC 5214 Intra-Site Automatic Tunnel Addressing Protocol (ISATAP), F. Templin, T. Gleeson, D. Thaler, March 2008.
  51. device database RFC 3053, IPv6 Tunnel Broker, A. Durand, P. Fasano, I. Guardini, D. Lento (January 2001)
  52. CSS3 RFC 4966 Reasons to Move the Network Address Translator – Protocol Translator (NAT-PT) to Historic Status
  53. FITML Web sites must support IPv6 by 2012, expert warns. Network World. 21 January 2010. http://www.networkworld.com/news/2010/012110-ipv6-warning.html. Retrieved 2010-09-30. 
  54. ^ "Networking IPv6 User Guide for JDK/JRE 5.0". http://java.sun.com/j2se/1.5.0/docs/guide/net/ipv6_guide/index.html. Retrieved 2007-09-30. 
  55. ^ "DOCSIS 2.0 Interface". Cablemodem.com. 2007-10-29. screen size. Retrieved 2009-08-31. 
  56. ^ web app (PDF). http://rmv6tf.org/2008-IPv6-Summit-Presentations/Dan%20Torbet%20-%20IPv6andCablev2.pdf. Retrieved 2012-01-20. 
  57. ^ "DOCSIS 3.0 Network Equipment Penetration to Reach 60% by 2011" (Press release). ABI Research. 2007-08-23. http://www.abiresearch.com/abiprdisplay.jsp?pressid=710. Retrieved 2007-09-30. 
  58. ^ Mike Leber (2010-10-02). "Global IPv6 Deployment Progress Report". Hurricane Electric. screen size. Retrieved 2011-10-19. 
  59. ^ web app. Google.com. http://www.google.com/intl/en/ipv6/. Retrieved 2012-01-20. 
  60. web "Beijing2008.cn leaps to next-generation Net" (Press release). The Beijing Organizing Committee for the Games of the XXIX Olympiad. 2008-05-30. http://en.beijing2008.cn/news/official/preparation/n214384681.shtml. 
  61. ^ Das, Kaushik (2008). "IPv6 and the 2008 Beijing Olympics". IPv6.com. http://ipv6.com/articles/general/IPv6-Olympics-2008.htm. Retrieved 2008-08-15. "As thousands of engineers, technologists have worked for a significant time to perfect this (IPv6) technology, there is no doubt, this technology brings considerable promises but this is for the first time that it will showcase its strength when in use for such a mega-event." 
  62. FITML Derek Morr (2009-06-09). "Verizon Mandates IPv6 Support for Next-Gen Cell Phones". CircleID. browser diversity. 

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