Multiplex communications – Data flow congestion prevention or control
Reexamination Certificate
1998-09-30
2004-04-06
Pham, Chi (Department: 2667)
Multiplex communications
Data flow congestion prevention or control
C710S048000, C710S052000, C710S260000, C710S263000
Reexamination Certificate
active
06717910
ABSTRACT:
FIELD OF THE INVENTION
This patent application is related to a method and apparatus for controlling the flow of network data arranged in frames and minimizing congestion, and more particularly, controlling congestion in a network device, such as an HDLC controller, having a FIFO memory at each port.
BACKGROUND OF THE INVENTION
Data networks have become increasingly important in day-to-day activities and business applications. Most of these networks are a packet-switched network, such as the Internet, which uses a Transmission Control Protocol (TCP) and an Internet Protocol (IP), frequently referred to as TCP/IP. The Transmission Control Protocol manages the reliable reception and transmission of network traffic, while the Internet Protocol is responsible for routing to ensure that packets are sent to a correct destination.
In a typical network, a mesh of transmission links are provided, as well as switching nodes and end nodes. End nodes typically ensure that any packet is received and transmitted on the correct outgoing link to reach its destination. The switching nodes are typically referred to as packet switches, or routers, or intermediate systems. The sources and destinations in data traffic (the end nodes) can be referred to as hosts and end systems. These hosts and end systems typically are the personal computers, work stations and other terminals.
To help move information between computers, the open system interconnection (OSI) model has been developed. Each problem of moving information between computers is represented by a layer in the model, and thus, establishes a framework for standards. Two systems communicate only between layers in a protocol stack. However, it is desirable to communicate with a pure layer in the other system, and to achieve such results, information is exchanged by means of protocol data units (PDUs), also known as packets. The PDUs include headers that contain control information, such as addresses, as well as data. At a source, each layer adds its own header, as is well known to those skilled in the art. The seven layers, starting at the physical layer, include: (1) physical; (2) data link; (3) network; (4) transport; (5) session; (6) presentation; and (7) application layers.
The network systems typically use routers that can determine optimum paths, by using routing algorithms. The routers also switch packets arriving at an input port to an output port based on the routing path for each packet. The routing algorithms (or routing protocols) are used to initialize and maintain routing tables that consist of entries that point to a next router to send a packet with a given destination address. Typically, fixed costs are assigned to each link in the network and the cost reflects link bandwidth and/or costs. The least cost paths can be determined by a router after it exchanges network topology and link cost information with other routers.
The two lower layers, the physical and data link layers, are typically governed by a standard for local area networks developed by the IEEE 802 Committee. The data link layer is typically divided into two sublayers, the logical link control (LLC) sublayer, which defines functions such as framing, flow control, error control and addressing. The LLC protocol is a modification of the HDLC protocol. A medium access control (MAC) sublayer controls transmission access to a common medium.
High-level data link control (HDLC) is a communications control procedure for checking the accuracy of data transfer operations between remote devices, in which data is transferred in units known as frames, and in which procedures exist for checking the sequence of frames, and for detecting errors due to bits being lost or inverted during transfer operations. There are also functions which control the set-up and termination of the data link. In HDLC, the bit synchronous data communication across a transmission link is controlled. HDLC is included in the ITU packet-switching interface standard known as X.25.
Programmable HDLC protocol controllers are commonly used in these systems. An HDLC controller is a computer peripheral-interface device which supports the International Standards Organization (ISO) high-level-data-link-control (HDLC). It reduces the central processing unit or microprocessor unit (MPU) software by supporting a frame-level instruction set and by hardware implementation of the low-level tasks associated with frame assembly-disassembly and data integrity.
Most communication protocols are bit-oriented, code-dependent, and ideal for full duplex communication. Some common applications include terminal-to-terminal, terminal-to-MPU, MPU-to-MPU, satellite communication, packet switching, and other high-speed data links.
A communication controller relieves a central MPU of many of the tasks associated with constructing and receiving frames. A frame (sometimes referred to as a packet) is a single communication element which can be used for both link-control and data-transfer purposes.
Most controllers include a direct memory access (DMA) device or function which provides access to an external shared memory resource. The controller allows either DMA or non-DMA data transfers. The controller accepts a command from the MPU, executes the command, and provides an interrupt and result back to the MPU.
In a network, such as Ethernet, an HDLC controller or similar device has a communications processor and firmware, which control a corresponding receiver of a port, where data is incoming or outgoing. Typically, the port includes a receive FIFO memory and a transmit FIFO memory. Incoming frames are received into the receive FIFO memory. At this time, a bus would be requested and the frames transferred along the bus. However, often bus latency occurs corresponding to the delay between the time the bus is requested and the time the bus is actually obtained to transfer data and frames. Other peripheral circuits, such as a tape reader or CD ROM, could be used in the system, such as with a personal computer, and inherently cause greater latency.
The receive FIFO memories have a finite size. At high speeds, such as T2 and T3 type frequencies, there could be much congestion causing an overflow. This congestion will affect any packets and frames coming down the line and, thus, it is advantageous if the frames could be saved before a major data catastrophe occurs. Also, instead of a single downstream node with a loss frame problem, a situation could rapidly develop where many downstream nodes are forced to reclock the transmit windows, easily exacerbating the problem.
It is also desirable not to wait a great period of time to generate any interrupts, such as when a series of end-of-frames are received and frames are discarded. Many of the frame transmission speeds are in milliseconds and in an Ethernet application, it is possible to fill a 120-word FIFO (512 byte in some preferred applications) in a matter of milliseconds. Although upper level software could retransmit any frames that are discarded, this would create greater congestion and take greater bandwidth. This could all create greater problems.
SUMMARY OF THE INVENTION
It is therefore an object of the present invention to reduce congestion in a port receiver, such as with the receive FIFO memory of a network device, e.g., an HDLC controller, and reduce the chance of dropped frames.
In accordance with the present invention, a status error indicator is now generated within a received FIFO memory of a network device, which is indicative of a frame overflow within the FIFO memory. This status error indicator can be read by a communications processor and an early congestion interrupt can be generated to a host processor indicative that a frame overflow has occurred within the receive FIFO memory. The incoming frame can be discarded and the services of received frames can be enhanced within the FIFO memory by one of either increasing the number of words of a direct memory access (DMA) unit burst size or modifying the time-slice or other active processes that are sharing the system.
In accorda
Guritz Elmer H.
Kasper Christian D.
Boakye Alexander O.
Jorgenson Lisa K.
Pham Chi
Regan Christopher F.
STMicroelectronics Inc.
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