Content centric networking


In contrast to IP-based, host-oriented, Internet architecture, content centric networking emphasizes content by making it directly addressable and routable. Endpoints communicate based on named data instead of IP addresses. CCN is characterized by the basic exchange of content request messages and content return messages. It is considered an information-centric networking architecture.
The goals of CCN are to provide a more secure, flexible and scalable network thereby addressing the Internet's modern-day requirements for secure content distribution on a massive scale to a diverse set of end devices. CCN embodies a security model that explicitly secures individual pieces of content rather than securing the connection or "pipe". It provides flexibility by using data names instead of host names. Additionally, named and secured content resides in distributed caches automatically populated on demand or selectively pre-populated. When requested by name, CCN delivers named content to the user from the nearest cache, traversing fewer network hops, eliminating redundant requests, and consuming less resources overall.
CCN began as a research project at the Palo Alto Research Center in 2007. The first software release was made available in 2009. CCN is the ancestor of related approaches, including named data networking.
CCN Technology and its open source code base has been acquired by Cisco in February 2017

History

The principles behind information-centric networks were first described in the original 17 rules of Ted Nelson's Project Xanadu in 1979. In 2002, Brent Baccala submitted an Internet Draft differentiating between connection-oriented and data-oriented networking and suggested that the Internet web architecture was rapidly becoming more data oriented. In 2006, the DONA project at UC Berkeley and ICSI proposed an information centric network architecture, which improved TRIAD by incorporating security and persistence as first-class primitives in the architecture. On August 30, 2006, PARC Research Fellow Van Jacobson gave a talk titled "A new way to look at Networking" at Google. The CCN project was officially launched at PARC in 2007. In 2009, PARC announced the CCNx project, publishing the interoperability specifications and an open source implementation on the on September 21, 2009. The original CCN design was described in a paper published at the International Conference on emerging Networking EXperiments and Technologies in December 2009.
Annual CCNx Community meetings were held in 2011, 2012, 2013 and 2015.
The for CCNx 1.0 has been made available for comment and discussion. Work on CCNx happens openly in the IRTF research group.

Specification

The CCNx specification was published in some IETF drafts. The specifications included:
Seamless data integration within an open-run environment was proposed as a major contributing factor in protecting the security of cloud-based analytics and key network encryption. The driving force in adopting these heuristics was twofold: Batch-interrupted data streams remaining confined to an optimal run environment; and secure shared cloud access depending upon integrative analytic processes.

Software

The CCNx software was available on GitHub.

Motivation and benefits

The functional goal of the Internet Protocol as conceived and created in the 1970s was to enable two machines, one comprising resources and the other desiring access to those resources, to have a conversation with each other. The operating principle was to assign addresses to end-points, thereby enabling these end-points to locate and connect with one another.
Since those early days, there have been fundamental changes in the way the Internet is used — from the proliferation of social networking services to viewing and sharing digital content such as videos, photographs, documents, etc. Instead of providing basic connectivity, the Internet has become largely a distribution network with massive amounts of video and web page content flowing from content providers to viewers. Internet users of today are demanding faster, more efficient, and more secure access to content without being concerned with where that content might be located.
Networks are also used in many environments where the traditional TCP/IP communication model doesn't fit. The Internet of Things and sensor networks are environments where the source-destination communication model doesn't always provide the best solution.
CCN was designed to work in many environments from high-speed data centers to resource constrained sensors. CCN aims to be:
Content Object messages are named payloads that are the network-sized chunks of data. Names are a hierarchical series of binary name segments that are assigned to Content Objects by content publishers. Signatures are cryptographic bindings between a name, a payload, and the Key Id of the publisher. This is used for provenance. Interest messages are requests for Content Objects that match the name along with some optional restrictions on that object.
The core protocol operates as follows: Consumers issue a request for content by sending an Interest message with the name of the desired content. The network routes the interest based on the name using longest prefix match. The interest leaves state as it traverses the network. This state is stored in the Pending Interest Table. When a match is found the content is sent back on the reverse path of the Interest, following the PIT state created by the Interest.
Because the content is self identifiable any Content Object can be cached. Interest messages may be matched against caches along the way, not only at the publishers.
Distributed caching within a content-centric network is also possible, requiring multifunctional access parameters across the database. This essentially enables shared network encryption algorithms to employ role-based access limitations to users based on defined authorization levels.

CCNx releases

CCNx 0.x

Interests match Content Objects based on name prefixes. For example, an Interest for /a/b would match a Content Object named /a/b/c/d or /a/b.
Interests include restrictions in the form of selectors. These help the network select which of the possible prefix matches are an actual match. For example, an Interest might exclude certain names, ask for a minimum or maximum number of extra name segments, etc.
Content Objects have an implicit final name component that is equal to the hash of the Content Object. This may be used for matching to a name.
Packet encoding is done using ccnb.
The last version of this branch is 0.8.2 Software is under a GPL license. are also available.

CCNx 1.x

CCNx 1.x differs from CCNx 0.x in the following ways:
Interests match Content Objects on exact names, not name prefixes. Therefore, an Interest for /a/b/ will only match a Content Object with the name /a/b.
Interests can restrict matches on the publisher KeyID or the object's ContentObjectHash.
A nested Type-Length-Value format is used to encode all messages on the wire. Each message is composed of a set of packet headers and a protocol message that includes the name, the content, and information used to cryptographically validate the message – all contained in nested TLVs.
The specification of CCNx 1.0 is available at: http://blogs.parc.com/ccnx/specifications/

Derivative works