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Data flow control switching method From Wikipedia, the free encyclopedia
Wormhole flow control, also called wormhole switching or wormhole routing, is a system of simple flow control in computer networking based on known fixed links. It is a subset of flow control methods called flit-buffer flow control.[1]: Chapter 13.2.1
Switching is a more appropriate term than routing, as "routing" defines the route or path taken to reach the destination.[2][3] The wormhole technique does not dictate the route to the destination but decides when the packet moves forward from a router.
Wormhole switching is widely used in multicomputers because of its low latency and small requirements at the nodes.[3]: 376
Wormhole routing supports very low-latency, high-speed, guaranteed delivery of packets suitable for real-time communication.[4]
In the wormhole flow control, each packet is broken into small pieces called flits (flow control units or flow control digits).
Commonly, the first flits, called the header flits, holds information about this packet's route (for example, the destination address) and sets up the routing behavior for all subsequent flits associated with the packet. The header flits are followed by zero or more body flits which contain the actual payload of data. Some final flits, called the tail flits, perform some bookkeeping to close the connection between the two nodes.
In wormhole switching, each buffer is either idle, or allocated to one packet. A header flit can be forwarded to a buffer if this buffer is idle. This allocates the buffer to the packet. A body or trailer flit can be forwarded to a buffer if this buffer is allocated to its packet and is not full. The last flit frees the buffer. If the header flit is blocked in the network, the buffer fills up, and once full, no more flits can be sent: this effect is called "back-pressure" and can be propagated back to the source.
The name "wormhole" plays on the way packets are sent over the links: the address is so short that it can be translated before the message itself arrives. This allows the router to quickly set up the routing of the actual message and then "bow out" of the rest of the conversation. Since a packet is transmitted flit by flit, it may occupy several flit buffers along its path, creating a worm-like image.
This behaviour is quite similar to cut-through switching,[5] commonly called "virtual cut-through," the major difference being that cut-through flow control allocates buffers and channel bandwidth on a packet level, while wormhole flow control does this on the flit level.
In case of circular dependency, this back-pressure can lead to deadlock.
In most respects, wormhole is very similar to ATM or MPLS forwarding, with the exception that the cell does not have to be queued.
One thing special about wormhole flow control is the implementation of virtual channels:
A virtual channel holds the state needed to coordinate the handling of the flits of a packet over a channel. At a minimum, this state identifies the output channel of the current node for the next hop of the route and the state of the virtual channel (idle, waiting for resources, or active). The virtual channel may also include pointers to the flits of the packet that are buffered on the current node and the number of flit buffers available on the next node.[1]: 237
Consider the 2x2 network of the figure on the right, with 3 packets to be sent: a pink one, made of 4 flits, 'UVWX', from C to D; a blue one, made of 4 flits 'abcd', from A to F; and a green one, made of 4 flits 'ijkl', from E to H. We assume that the routing has been computed, as drawn, and implies a conflict of a buffer, in the bottom-left router. The throughput is of one flit per time unit.
First, consider the pink flow: at time 1, the flit 'U' is sent to the first buffer; at time 2, the flit 'U' goes through the next buffer (assuming the computation of the route takes no time), and the flit 'V' is sent to the first buffer, and so on.
The blue and green flows requires a step by step presentation:
Wormhole techniques are primarily used in multiprocessor systems, notably hypercubes. In a hypercube computer each CPU is attached to several neighbours in a fixed pattern, which reduces the number of hops from one CPU to another. Each CPU is given a number (typically only 8-bit to 16-bit), which is its network address, and packets to CPUs are sent with this number in the header. When the packet arrives at an intermediate router for forwarding, the router examines the header (very quickly), sets up a circuit to the next router, and then bows out of the conversation. This reduces latency (delay) noticeably compared to store-and-forward switching that waits for the whole packet before forwarding. More recently, wormhole flow control has found its way to applications in network-on-chip systems (NOCs), of which multi-core processors are one flavor. Here, many processor cores, or on a lower level, even functional units can be connected in a network on a single IC package. As wire delays and many other non-scalable constraints on linked processing elements become the dominating factor for design, engineers are looking to simplify organized interconnection networks, in which flow control methods play an important role.
An extension of worm-hole flow control is Virtual-Channel flow control, where several virtual channels may be multiplexed across one physical channel. Each unidirectional virtual channel is realized by an independently managed pair of (flit) buffers. Different packets can then share the physical channel on a flit-by-flit basis. Virtual channels were originally introduced to avoid the deadlock problem, but they can be also used to reduce wormhole blocking, improving network latency and throughput. Wormhole blocking occurs when a packet acquires a channel, thus preventing other packets from using the channel and forcing them to stall. Suppose a packet P0 has acquired the channel between two routers. In absence of virtual channels, a packet P1 arriving later would be blocked until the transmission of P0 has been completed. If virtual channels are implemented, the following improvements are possible:
Using virtual channels to reduce wormhole blocking has many similarities to using virtual output queueing to reduce head-of-line blocking.
A mix of source routing and logical routing may be used in the same wormhole-switched packet. The value of the first byte of a Myrinet or SpaceWire packet is the address of the packet. Each SpaceWire switch uses the address to decide how to route the packet.[7]
With source routing, the packet sender chooses how the packet is routed through the switch.
If the first byte of an incoming SpaceWire packet is in the range 1 to 31, it indicates the corresponding port 1 to 31 of the Spacewire switch. The SpaceWire switch then discards that routing character and sends the rest of the packet out that port. This exposes the next byte of the original packet to the next SpaceWire switch. The packet sender may choose to use source routing to explicitly specify the complete path through the network to the final destination in this fashion.[7]
With logical routing, the Spacewire switch itself decides how to route the packet.
If the address (the first byte) of an incoming SpaceWire packet is in the range 32 to 255, the SpaceWire switch uses that value as an index into an internal routing table that indicates which port(s) to send the packet and whether to delete or retain that first byte.[7]
Address 0 is used to communicate directly with the switch, and may be used to set the routing table entries for that switch.[7]
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