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{{Short description|Networking standard}}
{{Unreferenced|date=February 2024}}
The '''Virtual Interface Architecture''' ('''VIA''') is an abstract model of a user-level [[zero-copy]] [[computer network|network]], and is the basis for [[InfiniBand]], [[iWARP]] and [[RDMA_over_Converged_Ethernet|RoCE]]. Created by [[Microsoft]], [[Intel]], and [[Compaq]], the original VIA sought to standardize the interface for high-performance network technologies known as System Area Networks (SANs; not to be confused with [[Storage Area Network]]s).▼
▲The '''Virtual Interface Architecture''' ('''VIA''') is an abstract model of a user-level [[zero-copy]] [[computer network|network]], and is the basis for [[InfiniBand]], [[iWARP]] and [[
Networks are a shared resource. With traditional network APIs such as the [[Berkeley_sockets|Berkeley socket API]], the [[kernel (computer science)|kernel]] is involved in every network communication. This presents a tremendous performance bottleneck when [[lag|latency]] is an issue.▼
▲Networks are a shared resource. With traditional network APIs such as the [[
One of the classic developments in computing systems is [[virtual memory]], a combination of hardware and software that creates the illusion of private memory for each process. In the same school of thought, a virtual network interface protected across process boundaries could be accessed at the user level. With this technology, the "consumer" manages its own buffers and communication schedule while the "provider" handles the protection.
Thus, the [[network interface controller|network interface card]] (NIC) provides a "private network" for a process, and a process is usually allowed to have multiple such networks. The virtual interface (VI) of VIA refers to this network and is merely the destination of the user's communication requests. Communication takes place over a pair of VIs, one on each of the processing nodes involved in the transmission. In "kernel-bypass" communication, the user manages its own buffers.
Another facet of traditional networks is that arriving data is placed in a pre-allocated buffer and then copied to the user-specified final destination. Copying large messages can take a long time, and so eliminating this step is beneficial. Another classic development in computing systems is [[direct memory access]] (DMA), in which a device can access main memory directly while the CPU is free to perform other tasks.
In a network with "remote direct memory access" ([[Remote direct memory access|RDMA]]), the sending NIC uses DMA to read data in the user-specified buffer and transmit it as a self-contained message across the network. The receiving NIC then uses DMA to place the data into the user-specified buffer. There is no intermediary copying and all of these actions occur without the involvement of the CPUs, which has an added benefit of lower CPU utilization.
For the NIC to actually access the data through DMA, the user's page must be in memory. In VIA, the user must "pin-down" its buffers before transmission, so as to prevent the OS from swapping the page out to the disk. This action—one of the few that
So essentially VIA is a standard that defines kernel bypassing and RDMA in a network. It also defines a programming library called "VIPL". It has been implemented, most notably in cLAN from Giganet (now [http://www.emulex.com/ Emulex]). Mostly though, VIA's major contribution has been in providing a basis for the [[InfiniBand]], [[iWARP]] and
==External links==
*[http://www.usenix.org/publications/library/proceedings/als00/2000papers/papers/full_papers/rangarajan/rangarajan_html/node3.html Usenix
*[https://makonetworks.com/markets/distributed-enterprises/ Distributed Enterprise Networks]
*[
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[[Category:Computer networks engineering]]
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