JP3557200B2 - ATM communication system - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an ATM communication system.
[0002]
[Prior art]
In recent years, demands for various communications such as image communications and high-speed data communications have increased, and integration of communications networks (B-ISDN) has been desired to provide efficient and flexible communications services. ATM (Asynchronous Transfer Mode) exchange is promising as a realizing method. The ATM switching system is intended to realize a communication service by storing information in a fixed-length packet called a cell irrespective of its attribute and using the cell as a unit of exchange.
[0003]
The CCITT has defined this ATM switching system as a formal next-generation switching system and has decided to formally implement B-ISDN using the ATM switching system. Along with this, public networks and corporate networks are constructed based on the ATM switching system, and it is highly likely that this will fulfill the needs of next-generation multimedia communication and broadband communication.
[0004]
There is a movement to apply this ATM switching system to the field of LAN (local area network). This is to implement a conventional LAN communication system represented by Ethernet by an ATM switching system (hereinafter, also referred to as an ATM communication system), and standardization has already begun in the United States and other countries.
[0005]
When the ATM switching system is applied to a LAN, the following advantages can be considered.
[0006]
(1) Broadband communication can be realized
The communication speed of Ethernet, which can be said to be a substantial standard of the current LAN, is 10 Mbps. Higher speed LANs such as FDDI (100 Mbps) are also appearing, but these are both shared media (a method in which the bandwidth is shared by all terminals). On the other hand, the introduction of the ATM switching system with the standard of 150 Mbps / 620 Mbps is basically a star type configuration, so that the terminal can exclusively use the band and dramatically increase the LAN throughput. May improve.
[0007]
(2) Suitable for multimedia
The current LAN has supported so-called data communication such as file transfer and transaction processing. However, due to the system, it is not possible to support real-time communication typified by audio and video, or even if it is possible, the overhead is very high. And the bandwidth is very small.
[0008]
On the other hand, the ATM switching system integrates real-time / continuous communication such as voice and image with non-continuous communication such as data communication by unified processing by hardware and drastic improvement of network reliability. That is, this is a communication method capable of performing multimedia communication. From this, there is a possibility that introduction of the ATM switching system into the LAN may promote the realization of a multimedia environment in the LAN.
[0009]
(3) Good affinity with public networks.
[0010]
As described above, since the target of realizing broadband communication in the public network is the ATM switching system determined by CCITT, the future public network (public communication network) may be constructed as an ATM network. Extremely high.
[0011]
Apart from this, there has recently been an increasing demand to use the LAN environment in a wider area. This indicates that the same environment as the LAN is made wider, that is, the need for MAN (Metropolitan Area Network) and WAN (Wide Area Network) is increasing. In order to realize this, it is necessary to interconnect terminals or LANs via a public network. Generally, when these terminals or networks are physically separated, they are interconnected via a public network. There is a need.
[0012]
Assuming that an ATM exchange method is used for a public network and a similar communication method is used for a LAN, it is considered that mutual entry of information / packets can be performed at a boundary point only by a simple protocol conversion. It shows high affinity to public networks. From these facts, it is considered that the application of the ATM switching system to the LAN can secure a broadband communication line between a long-distance terminal and a network and a real-time property, which were not possible with the conventional public network. , MAN or WAN.
[0013]
On the other hand, in a conventional LAN environment, for example, Ethernet or the like, when connecting LANs, that is, performing internetworking between LANs, a router is arranged between each LAN. This router performs processing up to layer 3 (network layer) of the OSI protocol layer stack, and its main function is routing processing of datagram communication across LANs. That is, a datagram that spans two LANs is always raised to layer 3 by a router, where the destination network layer address is analyzed, and delivered to the destination LAN according to the analysis result. This router is often called a "gateway" in the computer communication world, but the term "gateway" is defined as an entity that performs processing up to layer 7 in OSI. Since they are different, they will be referred to as routers hereinafter.
[0014]
Among those for realizing the connection between LANs, a “bridge” is also known as similar to a router. This is because the router analyzes the destination network layer address to determine the LAN to be transmitted, whereas the bridge analyzes the data link layer address (MAC address) to determine the LAN to transmit. Specifically, the bridge analyzes the destination MAC address of the received datagram, and if the received MAC address is not addressed to its own LAN, realizes the connection between LANs by transmitting the datagram to the other LAN. It is a function that causes Further, as a similar example, "Bruta" which functions as a router for a predetermined network layer protocol and functions as a bridge for other protocols is known.
[0015]
Workstations (WS) have been commonly used for these routers, bridges and brouters. In other words, the functions of the router, the bridge, and the brouter are realized by the CPU in the WS analyzing the address and transmitting the address to the assigned physical port.
[0016]
[Problems to be solved by the invention]
One feature of the ATM communication system is that high speed is achieved by hardware switching of ATM cells. That is, the ATM network is a "connection-oriented" (hereinafter, also referred to as CO) network, and establishes a virtual connection (Virtual Connection: VC) or a virtual path (Virtual Path: VP) between end-to-end. Packets called cells are delivered end-to-end in such a manner that a VC or VP is label-multiplexed or label-exchanged with its identifier (VCI or VPI).
[0017]
Information (data) delivered between end-to-end is stored in the payload of the ATM cell, and the ATM cell is exchanged / transferred to the destination terminal by hardware switching only without software intervention along the VC / VP. You. The hardware switching is performed by the ATM switch with reference to the VPI / VCI included in the ATM cell header (in some cases, the value of another area of the ATM cell header, for example, PT).
[0018]
When this ATM communication method is applied to the field of LAN, it is considered that communication between terminals in the LAN can be achieved by the above-described communication through ATM-VC / ATM-VP, and the communication between terminals is dramatically improved. High speed and large capacity can be expected.
[0019]
However, when performing communication between LANs (hereinafter referred to as ATM-LAN) to which such an ATM communication system is applied, as described above, a router, a bridge or a brouter located between the LANs compulsorily applies Layer 3 or Layer 3. A termination at 2 is made. It is highly likely that the layer 2 and layer 3 processing after the termination is normally performed by software processing. For this reason, there is a high possibility that communication over a LAN loses remarkably high speed and large capacity compared to communication within the LAN. In a conventional system in which a router, a bridge, a brouter, or the like is provided between LANs to perform communication between LANs, VP / VC across LANs is basically not established. This is because the VP / VC does not perform the layer processing of the ATM layer or more between its end points. This means that a connection-oriented communication line, which is one of the features of the ATM communication system, cannot be set for communication over ATM networks.
[0020]
In contrast to the ATM communication system which is a connection-oriented communication system, a communication system used in conventional data communication is "connectionless" (hereinafter, also referred to as CL). In the connectionless communication method, a connection is not necessarily established between end-to-end, a packet is sent to a network in a form of attaching destination information to a part of the packet, and a node in the network analyzes the destination information and performs a routing process. Then, the packet is transferred to the destination terminal. That is, in connectionless communication, a terminal implements a datagram without performing a connection setting procedure. A packet transmitted to a destination terminal without a connection in this way is called a datagram, and a communication method using this is called a datagram. This is called the transfer method. In other words, connectionless communication is a method of realizing communication in the form of datagram transfer without a terminal performing a connection setup procedure.
[0021]
Most existing data terminals, such as workstations (WS) and personal computers (PC), apply this datagram transfer method in most cases. This is because most conventional LANs support the datagram transfer method, and the software (for example, OS) installed in the data terminal is for datagram transfer. Typical examples thereof include TCP / IP and UDP / IP.
[0022]
In these existing terminals or terminals equipped with an existing protocol, that is, terminals that generate datagrams and send them out to the partner terminal / network via the ATM network, the datagram transfer method is used for communication between the terminals. . Therefore, in order to adapt these terminals to the ATM network, it is necessary to (a) replace the current LAN board, for example, an Ethernet board with an ATM network board (ATM board) in the terminal, or use a terminal adapter (TA). (B) a function of loading a datagram into an ATM cell at some form in the terminal, and (c) a destination terminal indicated by the destination address of the datagram in the network. Improvements such as the provision of a function to deliver items up to the terminal side and the network are required. The term "terminal" here includes a gateway between an existing LAN and an ATM network.
[0023]
As a function for realizing this, a datagram delivery method using a CLSF (connectionless service function) has been conventionally known. The datagram delivery method using the CLSF is realized as follows.
[0024]
A CLSF processing unit is arranged in the ATM network, and all datagrams are collected here. That is, all the datagram terminals and the CLSF processing unit are connected by PVC (permanent VC) (or VC, VP, or PVP), and the terminal converts all the datagrams to be transmitted into ATM cells and puts them on the PVC going to the CLSF processing unit. , To the CLSF processing unit. The CLSF processing unit reproduces the received datagram, analyzes the destination address, selects a PVC connected to the destination address, converts the datagram into an ATM cell, and transmits the datagram again. When there is no PVC connected to the destination address, when a plurality of CLSF processing units exist in the network, it is considered to include the terminal which is the destination address, or the data is transmitted to the next-stage CLSF processing unit predetermined by the routing rule. The gram is again converted into an ATM cell and transmitted.
[0025]
In the CLSF processing unit, it is not always necessary to analyze the destination address after reproducing the datagram, convert the datagram into an ATM cell again, and send the datagram. The first address of the datagram converted into the ATM cell includes the destination address. In this case, a method is used in which the destination address in the first one cell is analyzed, the cell is directly forwarded to the destination terminal, and the second and subsequent cells in which the datagram is converted into ATM cells are sequentially transmitted to the destination terminal. May be.
[0026]
However, in the above-described method using CLSF, all datagrams transmitted from within the network always pass through the CLSF processing unit, and the number of datagrams to be transmitted increases and the number of terminals in the network increases. A higher throughput is required for the CLSF processing unit, and a very high throughput and flexible expandability are required for the CLSF processing unit.
[0027]
Another method of transmitting a datagram to a destination terminal is a method of setting up an ATM connection, for example, a VC to the destination terminal, and placing the ATM cellized datagram on the VC for delivery. However, in this method, it is very problematic to which destination terminal a VC is set. In other words, there are practically innumerable terminals capable of sending datagrams, and since datagrams are generated in bursts, unlike voice information, it is wasteful to use network resources to establish unnecessary connections.
[0028]
Furthermore, when realizing connectionless communication in the conventional ATM network, the ATM connection is always terminated in the CLSF processing unit, and protocol processing higher than the AAL layer, for example, protocol processing for a connectionless service called CLNAP is performed. That is, even when datagram communication is performed between very close terminals, the ATM connection is once terminated in the CLSF processing unit. Further, when datagram communication is performed between distant terminals, the datagram passes through a plurality of CLSF processing units, and each CLSF processing unit performs protocol processing on the AAL layer or higher.
[0029]
Generally, protocol processing such as CLNAP higher than the AAL layer is performed by software processing (the processing below the AAL layer is generally performed by hardware processing), and the processing speed is slow. Further, the CLSF processing unit performs not only communication between terminals belonging to the network supported by the CLSF processing unit but also communication with terminals in the network supported by other CLSF processing units. For example, it is necessary to analyze network layer address information), and the load of the datagram transfer process is concentrated on the CLSF processing unit. For these reasons, the conventional ATM communication system has a problem that it is difficult to realize high-speed communication in connectionless communication (datagram delivery) between terminals.
[0030]
An object of the present invention is to provide an ATM communication system capable of realizing communication between ATM networks without sacrificing high speed, large capacity, and connection orientation.
[0031]
It is another object of the present invention to provide an ATM communication system capable of efficiently performing datagram delivery using an ATM network.
[0032]
Still another object of the present invention is to provide an ATM communication system capable of performing connectionless communication between terminals connected to an ATM network, that is, high-speed datagram delivery.
[0033]
[Means for Solving the Problems]
In order to solve the above problems, an ATM communication system according to the present invention is configured as follows.
[0034]
(1) A plurality of ATM networks operated in the asynchronous transfer mode, a plurality of terminals respectively accommodated in the plurality of ATM networks, and internetworking provided between the plurality of ATM networks and between the ATM networks And an inter-network connecting device that performs at least some of packets transmitted from one ATM network connected to the inter-network connecting device to another ATM network. An ATM communication system characterized in that at least one of ATM layer processing and at least one of ATM cell switching and ATM cell switching is performed in ATM layer processing without performing processing at or above the ATM adaptation layer.
[0035]
The network connection device preferably has ATM cell header conversion means.
[0036]
The network connection device preferably has CLSF (connectionless service function) processing means. The CLSF processing unit performs a network layer process (analysis of network layer address, routing process, and the like) on at least a datagram spanning the internetwork connecting device.
[0037]
Further, an address resolution protocol for datagram distribution developed in an ATM network (when a network layer address of a datagram destination is known and a physical address to which the datagram is to be transmitted is unknown, a network layer address Protocol for acquiring a physical address from the ATM network), resolution of an address located outside the ATM network may be performed by notifying a VPI / VCI connected to a CLSF processing unit in the network connection device. .
[0038]
(2) A plurality of ATM networks operated in the asynchronous transfer mode, a plurality of terminals respectively accommodated in the plurality of ATM networks, and internetworking provided between the plurality of ATM networks and between the ATM networks And an inter-network connection device that performs connection-less service processing means.
[0039]
The connectionless service processing means performs at least a network layer process on a datagram delivered over the inter-network connecting device having the connectionless service processing means, and the delivery of the datagram across three or more ATM networks is performed by the connectionless service processing means. Relaying between connectionless service processing means may be performed.
[0040]
When there are a plurality of these network connection devices, the CLSF processing means in the network connection devices may be connected by a permanent connection.
[0041]
Further, the connection that connects the CLSF processing units in the network connection device may be a connection that is not managed by the bandwidth management entity.
[0042]
In addition, the network connection apparatus may include a call / connection processing unit (a part having a function of setting, disconnecting, changing, and managing the call and / or the connection).
[0043]
Also, the call / connection processing means in the network connection device may perform at least a process for a call / connection across the network connection device.
[0044]
Also, regarding an address resolution protocol for detecting a call process associated with a call / connection setup / change / disconnection process deployed in the ATM network, the call / connection to be processed is located outside the ATM network. The address resolution in the case where the address resolution is between the two addresses may be performed using the VPI / VCI addressed to the call processing unit in the network connection device.
[0045]
The call / connection processing means in the ATM network relays the call / connection processing to the call processing in the inter-network connecting device when the target call / connection is not closed within the ATM network. Is also good.
[0046]
(3) A plurality of ATM networks operated in the asynchronous transfer mode, a plurality of terminals respectively accommodated in the plurality of ATM networks, and internetworking provided between the plurality of ATM networks and between the ATM networks And an inter-network connection device that performs call processing. The inter-network connection device has call processing means, and the call processing means performs at least call / connection processing across the inter-network connection device having the call processing means.
[0047]
In this call processing means, processing of a call / connection over three or more ATM networks may be performed by relaying between the call processing means.
[0048]
The call processing means in the network connection device may be connected by a permanent connection.
[0049]
(4) A plurality of ATM-LANs operated in the asynchronous transfer mode, a plurality of terminals respectively accommodated in the plurality of ATM-LANs, and at least one datagram server provided in the plurality of ATM-LANs as a whole Connection setting means for setting an end-to-end ATM connection between the plurality of terminals accommodated in the same ATM-LAN; Datagram delivery means is provided through the ATM connection set by the connection setting means, and datagram delivery means is provided through the datagram server for datagram delivery between the plurality of terminals in the different ATM-LAN. An ATM communication system, characterized in that:
[0050]
Here, the datagram server performs the following processing. The datagram (connectionless packet) converted into an ATM cell is terminated once. However, it is not necessary to reassemble the datagram. That is, it is not always necessary to perform the network layer termination, and the termination may be performed in the CL layer being discussed in CCITT. Then, after referring to the network layer address once, an appropriate ATM connection (VP / VC connected to the node having the network layer address or VP connected to the CLSF processing means considered to have a function of delivering the network layer address) is performed. / VC).
[0051]
The terminal may set up an end-to-end ATM connection with another terminal or perform address resolution when the terminal itself starts up or boots.
[0052]
Further, the terminal may set up an end-to-end ATM connection with another terminal or perform an address resolution when the terminal itself logs in.
[0053]
In the datagram delivery method, if an ATM connection cannot be established between terminals in the same ATM-LAN, or if address resolution cannot be performed, the terminal transmits a datagram to be transmitted. The data may be transferred to a gram server or may be broadcast in the ATM-LAN.
[0054]
(5) A plurality of ATM networks operated in the asynchronous transfer mode, a plurality of terminals accommodated in the plurality of ATM networks, and a plurality of datagram servers provided at least one in the plurality of ATM networks as a whole. And an internetworking device provided between the plurality of ATM networks to perform internetworking between the ATM networks, wherein the internetworking device has an address from the ATM network connected to the internetworking device. In response to an ARP request for requesting a resolution, a reply of an ATM address of an ATM connection connected to the interworking device when the target node of the address resolution does not exist in the ATM network connected to the interworking device. Response means for making an ARP response to the ARP request, and an ATM returned by the ARP response from the response means. And a connection connection means for connecting a first ATM connection indicated by an address and a second ATM connection set between the network connection device and the datagram server. An ATM communication system wherein a datagram server and a datagram server are directly connected by an ATM connection.
[0055]
(6) A plurality of ATM networks operated in the asynchronous transfer mode, a plurality of terminals respectively accommodated in the plurality of ATM networks, and a plurality of datagram servers provided at least one in the plurality of ATM networks as a whole. , An interworking device provided between the plurality of ATM networks and performing internetworking between the ATM networks, wherein the interworking device is provided with a routing protocol terminating means and an interworking device. Notification means for notifying routing information to an ARP server for performing address resolution when receiving an ARP request for requesting address resolution from a connected first ATM network; The information passed through is returned by an address resolution response from the address resolution server. Transmission connection means for connecting a first ATM connection indicated by the designated ATM address and a second ATM connection set between the network connection device and the datagram server. An ATM communication system wherein a terminal and the datagram server are directly connected by an ATM connection.
[0056]
(7) Here, the connection connection means in (5) or (6) is, for example, the connection between the first ATM connection and the second ATM connection by at least one of an ATM cell header conversion means and an ATM cell switching means. Configured to do so.
[0057]
In this case, the number of datagram servers can be increased or decreased or changed by setting at least one of the ATM cell header conversion means and the ATM cell switching means.
[0058]
(8) An ATM network operated in the asynchronous transfer mode, and a plurality of terminals accommodated in the ATM network, wherein the terminals serve as ATM communication substrates from ATM cells from the ATM network to the terminals. ARP request cell extracting means for extracting an ARP request cell for requesting the obtained address resolution, and for responding to the address resolution request based on the ARP request cell extracted by the ARP request cell. ARP response cell generating means for generating an ARP response cell, and multiplexing means for multiplexing the ARP response cell generated by the ARP response cell generating means with an ATM cell stream transmitted from the terminal device. An ATM communication system characterized by the above-mentioned.
[0059]
The operation of the ATM communication system according to the present invention will be described below.
[0060]
(1) In a conventional ATM communication system, a packet input by an inter-network connecting device is processed by being raised to an upper layer (a data link layer, a network layer, or a higher layer). According to the invention, a part of a packet transmitted from one ATM network connected to the network connection device to another ATM network connected to the network connection device is not subjected to AAL or higher processing. At least with reference to the ATM cell header and / or switching of the ATM cell. As a result, an ATM connection (VP, VC) that spans the network connection device can be generated without terminating the connection in the network connection device. Since this ATM connection passes through the inter-network connecting device only by the ATM layer processing without being terminated in the upper layer, it is possible to speed up data and transfer a large amount of data across each network.
[0061]
In an ATM network, the range covered by the physical address system can be determined as one closed network (ATM-LAN). That is, it can be determined that the range of the entity that determines the value of VPI / VCI, which is the physical address system in the ATM network, is one ATM-LAN. One or more entities that determine the value of the VPI / VCI exist in the ATM-LAN, and they operate in cooperation. Thus, in an inter-network connecting device that connects ATM-LANs having independent VPI / VCI systems, these address systems are converted, that is, the VPI / VCI address system on one side is converted from the VPI / VCI address system on the other side. A mechanism for translating addresses to is required. By having the ATM cell header conversion means in the network connection device, it is possible to refer to the ATM cell header value including the VPI / VCI value, and it is possible to change the address system by the conversion means. .
[0062]
(2) In the present invention, by providing the CLSF processing means in the network connection device, datagrams distributed over the network connection devices can be processed (terminated) here. When a datagram is delivered using the CLSF processing means, the ATM connection is once terminated by the CLSF processing means, and the datagram converted into an ATM cell is once raised to an upper layer (network layer or CL layer) processing. That is, the network layer address or the CL layer address is referred to. In this case, reassembly of the datagram is not necessary. Thereafter, an ATM connection leading to the referred address is selected, and the datagram is transmitted through the ATM connection.
[0063]
By arranging the CLSF processing means in the network connection device in this way, datagrams distributed over networks are terminated at the ATM connection here. Can be directly accessed from the ATM network connected to the CLSF processing means. This access can be made without using an ATM connection that spans a plurality of networks. (2) Datagram delivery over an ATM network connected to the network connection device is processed here. Thus, the conversion of the address system (VPI / VCI value) in each ATM network can be performed intensively here. (3) Routing information (network layer address, CL) connected to the network connection device This eliminates the need for exchanging layer addresses and VPI / VCI values) between networks.
[0064]
In an ATM network (ATM-LAN) connected to the network connection device, a terminal desiring datagram delivery performs address resolution for detecting where to send the datagram. If the transmission address of the gram is addressed to an address located outside the ATM-LAN, for example, the CLSF processing means itself or an ARP server described later notifies the VPI / VCI connected to the CLSF processing means in the network connection device. Thus, datagram delivery outside the network can be performed in a unified manner.
[0065]
The above configuration can be applied not only to an inter-network connection device between ATM networks but also to an inter-network connection device between an ATM network and a network operated by another system (for example, Ethernet system).
[0066]
Also, when datagram delivery spans three or more networks, this is performed by relaying between CLSF means arranged in the network connection device, thereby enabling data to be delivered outside the own ATM-LAN. The method for sending a gram to the CLSF processing means disposed in the network connection apparatus, and the datagram destination to be managed by the CLSF processing means is the same except for the other CLSF processing means. Can maintain the method of using only terminals / nodes in the network connected to the network, and can achieve efficient CLSF operation.
[0067]
Here, the connection between the CLSF processing means is made by a permanent connection, specifically, a PVP (permanent VP) or a PVC (permanent VC), so that a connection setting overhead generated every time a datagram is transferred between the CLSF processing means. It is possible to reduce the number of datagrams and to distribute datagrams across three or more networks through the permanent connection. Therefore, it is necessary to monitor the traffic used for datagram distribution. It can be easier to do.
[0068]
(3) Also, datagram delivery is usually performed over an unreliable connection. That is, it can be considered that the transmission is performed on the assumption that the transmitted datagram may be lost in the middle, or that the delay time until the transmitted datagram reaches the transmission destination cannot be predicted. For this reason, the connection that connects the CLSF processing means is also excluded from the management of the band management entity, that is, the connection is not subject to connection control for band management when setting the connection, and the connection having a low cell delivery priority is set. It can be. As a result, a strategy is taken to preferentially pass cells of a connection target connection (high-priority connection), but datagram delivery is appropriate in nature.
[0069]
Further, by providing the call / connection processing means in the network connection device, the processing (setting, disconnection, change, management, etc.) of the ATM connection across the network connection devices can be processed (terminated) here. . As a result, (1) the processing of the ATM connection over the inter-network connecting device requires information in both connected networks. By arranging the call / connection processing means in the inter-network connection device located between the respective networks and capable of knowing information in the respective networks, the efficiency of the processing of the ATM connection over the inter-network connection device is improved. Can be done (2) It is possible to access the call / connection processing means from each network connected to the network connection device. This access can be performed without using an ATM connection that spans a plurality of networks. (3) The call / connection processing means in the network connection device can specialize in processing of an ATM connection across the network connection device. (4) For an ATM connection spanning between networks, it is necessary for the network connection device to convert each ATM address system (VPI / VCI system). By providing the call / connection processing means in the network connection device, elements indispensable for the conversion of the address system, such as the setting means of the conversion table of the VPI / VCI system, can be included in the call / connection processing means. Advantages such as being able to be tightly coupled to the processing means can be enjoyed.
[0070]
Further, in an ATM network (ATM-LAN) connected to the above network connection device, where should a terminal that wants a call / connection processing request (setting, disconnection, change request, etc.) send the processing request? At the time of address resolution for detecting whether or not the connection destination address of the call / connection is an address located outside the ATM-LAN, the VPI connected to the call / connection processing means in the inter-network connection device is used. By notifying / VCI, call / connection processing with the outside of the network can be uniformly performed.
[0071]
Also, when a call / connection processing means is provided in the ATM-LAN and the processing for the requested call / connection is closed in the ATM-LAN, the call / connection in the ATM-LAN is performed. The processing is performed in the processing means, and if the processing is a processing request with an entity outside the ATM-LAN, the call / connection processing in the inter-network connection device which manages the processing of the call / connection with the outside of the ATM-LAN. By relaying the processing to the means, processing relating to a call / connection with the outside of the network can be uniformly performed.
[0072]
The above configuration can be applied not only to an inter-network connection device between ATM networks but also to an inter-network connection device between an ATM network and a network operated by another system (for example, Ethernet system).
[0073]
When the above-mentioned call / connection processing spans three or more networks, this is performed by relaying between the call / connection processing means arranged in the network connection apparatus, so that the outside of the own ATM-LAN is performed. The ATM connection of (1) is sent to the call / connection processing means arranged in the network connection device, and the entity (terminal, node, etc.) managed by the call / connection processing means is another call / connection. It is possible to maintain a method in which only the terminals / nodes in the network connected to the inter-network connecting device are excluded except for the processing means, and it is possible to efficiently operate the call / connection processing.
[0074]
Further, by making the connection between the call / connection processing means by a permanent connection (PVP or PVC), it is possible to reduce the connection setting overhead generated every time processing information is transferred between the call / connection processing means, The processing of a call / connection across three or more networks can be always performed by relaying between call / connection processing means in the network connection apparatus via the permanent connection. Also, it is possible to easily monitor traffic used for call / connection processing.
[0075]
(4) As described above, unlike the wide area network environment, the application program is considered to require a sufficiently small latency and a short call setup time for the LAN in the LAN environment. Since the datagram does not require call setup, the latter requirement can be satisfied. However, when a datagram server is used in an ATM environment, the residence time of the datagram in the datagram server generally becomes a problem. , Small latency cannot be secured. An environment that particularly requires a small latency is considered to be an application in the LAN (a propagation delay is inevitable due to the physical distance in a WAN environment), so that a terminal in the ATM-LAN is connected to another in the same ATM-LAN. By providing an ATM connection end-to-end with the terminal and performing datagram distribution, both of the above requirements can be satisfied. In addition, since the traffic of datagrams in a LAN is generally considered to greatly exceed the traffic of datagrams across LANs, the exchange of completed datagrams in a LAN is performed via a datagram server. Doing so directly can also prevent the datagram server from requiring excessive throughput. In this case, datagrams distributed over a plurality of networks may be delivered through a datagram server having datagram delivery means.
[0076]
Further, when a datagram to be transmitted is generated, the terminal device transmitting the datagram waits for the datagram on an ATM communication board or an arbitrary memory, and performs an ATM connection setting or address resolution. After a physical address (an ATM cell header value such as a VPI / VCI value in the case of an ATM network) is determined, a datagram is taken out from the ATM communication substrate or an arbitrary memory, and is converted into an ATM cell, and the physical address is obtained. It is not always necessary to add and send. This is because the datagram is kept in a waiting state during the above-mentioned ARP, so that it is useless from the viewpoint of transmitting the datagram. It is considered that efficient datagram delivery can be performed by setting up an ATM connection or performing address resolution in advance for a destination terminal that may transmit a datagram. The setting of the end-to-end ATM connection or the address resolution may be performed at the time of starting (booting) or logging in the terminal device.
[0077]
When an ATM connection between terminals in the same ATM-LAN cannot be established or address resolution cannot be performed, the terminal transfers a datagram to be transmitted to a datagram server. , Communication by datagram can be enabled. This is because it is generally considered that the datagram server has an ability to deliver the datagram to the destination terminal of the datagram (because the datagram server is connected to the node / IWU / Since the datagram delivery into the same ATM-LAN does not have an end-to-end ATM connection, or the datagram sending terminal recognizes the ATM connection, since the terminal recognizes the existence of all network layer addresses of the terminal. Even if it is not possible, it becomes possible with the datagram server.
[0078]
If an ATM connection cannot be established between terminals in the same ATM-LAN, or if address resolution cannot be performed, the terminal broadcasts a datagram to be transmitted in the ATM-LAN. For example, information to be broadcast can be transmitted because all terminals in the ATM-LAN are receiving and analyzing the information.
[0079]
(5) Next, an inter-network connection device according to the present invention will be described. In general, an inter-network connection device has information on a network connected to the device (such as how a network layer address or other node having an address is arranged, how to perform routing, and the like). Information; routing information), it is located in a position where it can directly collect routing information, so it can be used in both the main operating point of the routing protocol (exchange of routing information in the backbone network) and in the point of concentration of routing information in the branch network. ). A conventional existing network connection device (commonly called a router in a LAN) analyzes the meaning of "the end point of the routing protocol" and the network layer address of the datagram input to the network connection device. However, it has two functions in the sense that "routing of the input datagram" is performed based on the routing information obtained through the routing protocol or the like. In the ATM network, on the other hand, the latter function, that is, a function of analyzing a network layer address of an input datagram and performing routing of the datagram based on routing information obtained through the above-described routing protocol or the like. Is a function of the datagram server and generally requires high cost and complex equipment. In addition, providing a large number of datagram servers as described above, although the total amount of datagrams actually communicated is not so large, is considered to waste communication resources.
[0080]
(6) Therefore, when the routing protocol terminating means and the datagram service processing means are separated as in the present invention, and the ATM address resulting from the address resolution is required (the node of the address resolution is end-to-end). If the connection is not made by the end ATM connection, that is, if it is not in the same ATM-LAN), it is possible to use an ATM address leading to the datagram server without using more datagram servers than necessary. Datagram services can be provided at an appropriate cost and scale.
[0081]
(7) In the above network connection device, an ATM connection indicated by the ATM address returned in the ARP response and connected to the network connection device, and an ATM connecting the data connection server to the datagram server from the network connection device. The connection with the connection is made by setting the ATM cell header conversion means and / or the ATM cell switching means in the network connection device, so that the datagram transmitting terminal and the datagram server are directly connected by the ATM connection, that is, the ATM connection. They can be combined only by layer processing.
[0082]
In an ATM network for transferring datagrams between an arbitrary terminal and a datagram server in the manner described above, in the case of increasing or decreasing or changing the number of datagram servers, the ATM cell header conversion means in the network connection device is used. And / or by changing the setting of the ATM cell switching means, the setting change at the time of adding / decreasing the datagram server or at the time of changing can be made only by a simple table change in the network connection device, and It can be easily done in a very short time.
[0083]
(8) By using a terminal (ATM communication board) as in the present invention, generally, cells transmitted from a broadcast channel (arbitrary transmitting terminal to all nodes / IWUs / terminals belonging to the ATM-LAN) ARP request cells (address resolution request cells) considered to be performed via an ATM connection that can broadcast the ARP request cells (address resolution request cells) can be promptly handled by a higher-level processing device (such as a CPU) inside the terminal device. It can be performed without consuming processing time.
[0084]
In addition, as described above, the entire network of the ATM communication system is configured by a plurality of ATM networks, that is, divided into subnets, so that the separation between the address analysis protocol and the routing protocol is clarified, and the network can be flexibly expanded. Can be.
[0085]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the invention will be described with reference to the drawings.
[0086]
(1st Embodiment)
FIG. 1 shows an ATM network according to the first embodiment. As shown in FIG. 1, the ATM network according to the present embodiment includes a first ATM-LAN 11, a second ATM-LAN 12, and an inter-network connection device (hereinafter, also referred to as IWU) 13.
[0087]
Each of the first ATM-LAN 11 and the second ATM-LAN 12 is a local area network operated by the ATM method. Within each ATM-LAN, the address scheme is independent. That is, the VPI / VCI value used inside each ATM-LAN has the authority to be determined by the VPI / VCI value determination function existing inside the ATM-LAN, and this authority is independent in each ATM-LAN. is there. The terminal device and the node in the ATM-LAN store the information in the ATM cell if the information to be transmitted exists (whether the destination is in the ATM-LAN or not), An appropriate ATM cell header is added, and the packet is transmitted into the ATM-LAN.
[0088]
FIG. 2 shows a diagram of the internal structure of the network connection device 13. The network connection device 13 includes an add / drop processor 21, a multiplexer / demultiplexer (hereinafter, referred to as MUX / DEMUX) 22, a CLSF processor 23, a call processor 24, an IWU manager 25, and an ATM cell header converter 26. Become. The network connection device 13 is located between two ATM-LANs and has a function of managing internetworking (connection between LANs) of the two ATM-LANs.
[0089]
The add / drop processing unit 21 refers to the header portion of the input ATM cell, and if the cell has an appropriate header value (that is, the cell is terminated in the internetwork connection device 13). If it is a cell to be performed, a process of dropping the cell to the DEMUX 22 and a process of inserting (adding) a cell from the MUX 22 into the cell transmission path are performed. Here, the add / drop processing unit 21 has a function of dropping cells from both the left and right on the cell transmission path, and a function of inserting cells into the cell transmission path in either the left or right direction.
[0090]
In the add / drop processing unit 21, information on which cell is to be inserted on the cell transmission path in the left or right direction is specified by a CLSF processing unit 23, a call processing unit 24, and an IWU management unit 25, which will be described later. And That is, for example, the inserted cell is passed to the add / drop processing unit 21 together with a value such as 0 when inserted into the cell transmission line in the left direction and 1 in the right direction. Decide the direction. The cell may be inserted at a location where an empty cell passes over a cell slot on a cell transmission line, replacing the empty cell.
[0091]
In addition, when a cell is dropped from the add / drop processing unit 21 to the MUX / DEMUX 22 side, a drop table as shown in FIG. 3 is referred to. This drop table is provided in each of the cell transmission lines in both the left and right directions, and the cell drop destination (the CLSF processing unit 23, the call processing unit 24, or the IWU management unit 25) is determined according to the value of this table. As shown in FIG. 3, the drop table has a cell header value as an entry, and a value indicating a drop destination is referred to. As the value indicating the drop destination, for example, 1 is assigned to the CLSF processor 23, 2 is assigned to the call processor 24, 3 is assigned to the IWU manager 25, and so on. The cell to be dropped by the add / drop processing unit 21 is a value indicating this drop destination and a value indicating whether the cell is a drop cell from the left or right cell transmission line (for example, 0 if from the left direction, 0 if right). 1) and the like to the MUX / DEMUX 22 side. The information on the drop table is initialized, added, changed, and the like by the IWU management unit 25 described later.
[0092]
The MUX / DEMUX 22 refers to the information sent in parallel with the cell (drop cell) sent from the add / drop processing unit and connects to any module connected to the lower part (in this embodiment, the CLSF processing unit 23, A function (DEMUX function) to be transmitted to the call processing unit 24 and the IWU management unit 25) and a cell (add cell, inserted cell) to be inserted into a cell transmission path transmitted from a module group connected to the lower part are multiplexed. A function (MUX function) is provided to the drop processing unit 21 for passing information along with which direction to insert.
[0093]
The CLSF processing unit 23 performs processing of a connectionless service function (Connection Less Service Function). As described later in detail, the CLSF processing unit 23 once terminates a datagram (connectionless packet) delivered across the network connection device 13 (note that it is not always necessary to reassemble the datagram). That is, it is not always necessary to terminate the network layer, and it is also possible to terminate at the CL layer discussed in CCITT.) After referring to the network layer address once, the appropriate ATM connection (the network layer address VP / VC connected to a terminal / node having the above or a VP / VC connected to a CLSF processing unit which is considered to have a function of delivering the network layer address. It should be noted that the ATM connection for datagram delivery is once terminated in the CLSF processing unit 23.
[0094]
The call processing unit 24 basically has a function of performing setting, disconnection, change, management, and the like of an ATM connection across the network connection device 13. Further, it may have a function of managing the band on the ATM transmission line in the ATM connection or the network connection device. Details will be described later.
[0095]
The IWU management unit 25 has a function of managing and controlling the network connection device 13.
[0096]
The header conversion unit 26 has a function of referring to the header value of the cell (from both the left and right directions) and, if the header value is an appropriate value, rewriting this to another header value. The header conversion unit 26 basically has a function of referring to a cell header value (input cell header value) and rewriting the cell header value to a certain cell header value (output cell header value). Has a correspondence table inside. The initialization, addition, and change of the correspondence table are performed by the IWU management unit 25. This correspondence table matches the drop table of FIG. 3 in that the entry value is the input cell header value, so that the table can be easily integrated with the drop table.
[0097]
Each module in the network connection device 13 is assumed to be connected to a bus (not shown), and control such as a change in the set value of each module from the IWU management unit 25 is performed through this bus. I do.
[0098]
Instead of exchanging information between the modules through the bus as described above, the information may be put on ATM cells and the cells may be exchanged between the modules.
[0099]
In the present embodiment, various processes (CLSF process, call process, etc.) on the cell transmission path in both the left and right directions are performed by the same module on the left and right sides, but it is also possible to perform these processes on the left and right directions separately. .
[0100]
Further, in the present embodiment, various processes in the IWU are performed separately (that is, the CLSF processing unit is performed by the CLSF processing module, and the call processing is performed by the call processing module. ), All or some of these processes can be performed by the same CPU / MPU.
[0101]
In addition, although the case where there is only one header conversion unit 26 in the network connection apparatus of FIG. 2 of the present embodiment, before and after the add / drop, Alternatively, a header conversion unit is provided afterward, each of which performs header conversion of an ATM cell of a one-way cell flow (FIG. 38), or an add / drop processing unit before and after the header conversion unit as shown in FIG. It is also conceivable to provide a method of adding and dropping ATM cells in a unidirectional cell flow. By doing so, the functions of the network connection device 13 can be symmetrically viewed from both the left and right directions.
[0102]
Next, FIG. 4 shows an embodiment of a node / terminal configuration inside the first ATM-LAN 11 and the second ATM-LAN 12. As described above, the first ATM-LAN 11 includes three switch nodes 41, 42, and 43 and terminals 4A, 4B, 4C, and 4D connected thereto. The second ATM-LAN 12 is composed of two switch nodes 44 and 45 and terminals 4E, 4F and 4G connected thereto.
[0103]
In the switch node, an ATM switch is mounted, and connection between the switch nodes, connection with an inter-network connecting device, and connection with a terminal device can be performed. In this case, a star type (or a tree type) configuration is used. Will be taken. It is assumed that various values such as 10M, 20M, 155M, and 622M can be selected for the interface speed between these switch nodes and the terminal device / switch node / inter-network connection device.
[0104]
Next, FIG. 5 shows an embodiment of an ATM connection connection state between terminals in both ATM-LANs and a CLSF processing unit in the network connection device 13. Here, for simplicity, wiring between terminals and switch nodes and between switch nodes and networks are omitted. Other components such as a call processing unit and a header conversion unit in the network connection apparatus are also omitted in the figure.
[0105]
As described above, each terminal device and the CLSF processing unit 23 in the network connection device 13 are connected by the ATM connection. This ATM connection may be a VP or a VC. This ATM connection is a connection that is not subject to band management. That is, when physically establishing an ATM connection between the terminal device and the CLSF processing unit 23 in the inter-network connecting device 13, the band is not reserved (that is, the band management for the band management is performed in the call admission control). (Without going through an evaluation function). An ATM connection that does not perform such band management is considered to have a lower priority than an ATM connection that performs band management. That is, with respect to parameters such as the cell delivery delay and the cell discard rate, an ATM connection that does not perform band management shows a bad value as compared with an ATM connection that performs band management. The ATM connection between the terminal device and the CLSF processing unit is used for datagram delivery, but the delivery of datagrams originally requires a large delay time and unreliable physical connection. Therefore, it is appropriate to use such an ATM connection.
[0106]
As described above, in the present embodiment, the ATM connection in the ATM-LAN (and, in some cases, the ATM connection extending between the ATM-LAN) includes an ATM connection for performing bandwidth management and an ATM connection for not performing bandwidth management. There is. An ATM connection that performs bandwidth management is a connection that can perform communication while maintaining a certain communication quality (QOS) (a connection that can expect a cell loss rate of a certain level or more and a delay time of a certain level or less), and does not perform bandwidth management. The ATM connection is a connection without any guarantee in the communication quality (there is no restriction on the cell discard rate and the delay time).
[0107]
An ATM connection that performs bandwidth management is considered a high-priority connection, and an ATM connection that does not perform bandwidth management is considered a low-priority connection. For example, only when there is no cell belonging to a high-priority connection, a low-priority connection is considered. This can be realized by performing priority control such as permitting passage of cells belonging to the connection.
[0108]
Regarding the ATM connection for performing the bandwidth management, the setting is permitted only when the cell transmission path through which the connection passes and the communication resources in the switching node are secured, but the bandwidth management is not performed. Since the ATM connection is not subject to the band management, the call / connection admission control is unconditionally accepted as long as the number is equal to or less than the maximum number of receptions (of each connection management entity).
[0109]
It should be noted that the ATM connection between the terminal device and the CLSF processing unit 23 in the network connection device 13 does not extend over the network connection device, that is, does not extend over the ATM-LAN. When setting up an ATM connection across an ATM-LAN, generally, negotiation between the two ATM-LANs, address conversion, protocol conversion, etc. are generally required as described later, and CLSF processing is performed in the network connection device. By providing the unit, it is not necessary to provide such an ATM connection across the ATM-LAN for datagram delivery.
[0110]
By the way, the terminal device delivers the datagram via the network connection device 13, that is, the datagram outside the own ATM-LAN, via the CLSF processing unit 23 in the network connection device 13. That is, although the datagram converted into the ATM cell is sent to the CLSF processing unit 23, there are several approaches until the terminal device knows that the datagram should be sent to the CLSF processing unit 23. The method is conceivable.
[0111]
The terminal device assigns an ATM address (that is, which VPI / VCI value) to the datagram from a destination address of the datagram to be sent (a network layer address or a mail address including a domain name may be used). You have to resolve it to send it. In this manner, the operation of resolving the VPI / VCI value to be added to the datagram / ATM cell transmitted from the destination address is performed in accordance with the customary method of the LAN, and the ARP (Address Resolution Protocol) and I will call it.
[0112]
There are several methods for implementing this ARP as follows.
[0113]
(Method 1): When VPI / VCI addressed to the CLSF processing unit has been allocated in advance.
[0114]
In this case, the ATM address (VPI / VCI) of the CLSF processing unit is previously uniquely assigned to the LAN, and the datagram may be sent unconditionally with the VPI / VCI attached.
[0115]
In such a system, the terminal cannot distinguish between datagram delivery to its own ATM-LAN and datagram delivery to another LAN via the network connection device. It is necessary that the CLSF processing unit 23 also has a datagram delivery function closed within the ATM-LAN. As shown in FIG. 6, a separate CLSF processing unit is provided in the ATM-LAN, and for datagram delivery across the network connection device, the datagram is relayed to the CLSF processing unit in the network connection device. The datagram delivery system of the format to be ingested is included in the present method (the VPI / VCI for the CLSF processing unit in the ATM-LAN is determined in advance). (Method 2): Method using ARP server
An ARP server exists in the ATM-LAN (not shown), and the terminal device asks the ARP server which VPI / VCI should be used to send the datagram of the destination address. It is a way to go.
[0116]
The ARP server has a table inside, and this table corresponds to the destination address and the VPI / VCI value. The ARP server that has received the inquiry analyzes the VPI / VCI value corresponding to the destination address with reference to an internal table, and returns the analysis result (VPI / VCI value) to the terminal device of the inquiry source. At this time, if an ATM connection is not established between the two terminal devices / nodes, the fact may be notified, or the ARP server sets up an ATM connection between the two terminal / nodes, and then sets the ATM connection. The VPI / VCI value of the ATM connection may be returned. ARP is performed in this manner.
[0117]
Here, it is conceivable that the terminal device knows the ATM address of the ARP server (the VPI / VCI value addressed to the ARP server from the terminal device) or not.
[0118]
If it is known, there is no problem if an inquiry is made using the VPI / VCI value.
[0119]
If the user does not know, the ARP server performs the resolution (ARP) of the ATM address of the ARP server itself, or broadcasts the inquiry in the own ATM-LAN using a broadcast channel, and the ARP server transmits the broadcast inquiry to the ARP server. This inquiry may be considered as a method of recognizing that it is an inquiry to oneself and performing subsequent processing. When this broadcast channel is used, its own address (network layer address, mail address if necessary, ATM address VPI / VCI value, server name (ARP server), physical address assigned to the communication board) Etc.), destination address (network layer address of the entity that wants to receive the broadcast cell, mail address, ATM address, server name, function name, etc., if necessary), broadcast cell type (what kind of broadcast cell ) Must be included at least (Fig. 7). In addition, the own address (source address) and the destination address (reception side address) include an area indicating “address of protocol” (for example, IP address, E.164 address, etc.). May be. In addition, when the same transmission source makes a plurality of requests to the same destination at the same time, a random number, a discriminating number, and the like are included in the cell in order to indicate to which request the response is. May be added.
[0120]
When this broadcast cell is used for ARP, the address (network layer address, mail address if necessary, etc.) of the terminal device / node which is the target of the address resolution is added to the other information field of FIG. 7, for example. At least information may be included. In this case, the receiver address in the broadcast cell format may be undefined (for example, all 1s). The reason why the receiving side address is not fixed is that the receiving side address in the broadcast cell is the address of the receiving target terminal of the broadcast cell. This is because, when a broadcast cell is used for ARP, it is not considered that the terminal device targeted for address resolution always responds to the ARP, that is, it is not considered to receive and process the cell performing the ARP. .
[0121]
When performing the broadcast, for example, VPI = all 1 is used. VCI may be all 1s, or the value of VCI may include broadcast cell type information.
[0122]
As an example of performing ARP using broadcast, for example, an appropriate ARP server that has received a broadcast cell (ARP cell) knows that this is a datagram transmission request ARP by referring to the broadcast cell type. The ARP request recognizes that the ARP request is to be processed through the CLSF processing unit in the network connection device by referring to the address targeted for address resolution, and transmits the request to the CLSF processing unit in the network connection device. In response to the ATM address (VPI / VCI value). FIG. 8 shows an example of the format of a broadcast cell when such ARP is performed using a broadcast cell.
[0123]
Even when an address resolution request is made to the ARP server (through an end-to-end ATM connection) without using a broadcast, it is needless to say that the query needs to include the target address of the address resolution.
[0124]
When the ARP server recognizes that the transmission destination of the datagram is the destination of the inter-network connecting device (that is, outside the own ATM-LAN), the ARP server outputs a CLSF processing unit in the inter-network connecting device as a resolution result. To the ATM address (VPI / VCI value).
[0125]
In order to recognize that [the transmission destination of the datagram is beyond the network connection device], for example, using a subnet mask or the like, it is determined whether or not the destination address of the datagram has a sub-address of the own ATM-LAN. There is a method of checking whether or not.
[0126]
Several methods are also conceivable when the ARP server returns the analysis result to the inquiry source.
[0127]
First, there is a method of returning the inquiry result using a broadcast channel. In this case, the response to the ARP is entered in the broadcast cell type shown in FIG. 8, and the ATM address (VPI / VCI) as the address resolution result replaces or continues to be the address resolution target address. .
[0128]
Although the details will be described later, the method proposed in the previously filed Japanese Patent Application No. 5-1267 (herein, this is called a VP routing method), that is, one VPI is allocated to each terminal / node, ARP is performed as a “datagram transmission request ARP” in this ARP, except that the routing in the LAN is performed using the VPI.
[0129]
That is, the ARP does not always return the "datagram transmission request ARP" (the VPI / VCI of the ATM connection directly connected to the destination end-to-end. For example, the VPI / VCI of the ATM connection to the CLSF processing unit). Note that there is a possibility that the VCI value will be resolved) and that "connection connection request ARP" (the VPI / VCI of the ATM connection directly connected end-to-end with the partner is returned). It is. .
[0130]
(Method 3) Method via call processing server
This is a method in which a terminal device that wants ARP requests a call processing server (not shown) existing in the ATM-LAN to set up an ATM connection with the CLSF processing unit. When the call processing server recognizes that the delivery destination of the datagram is beyond the network connection device, the call processing server may establish an ATM connection with the CLSF processing unit in the network connection device.
[0131]
(Method 4) Direct ARP between terminal / node
In a system in which one VPI is allocated to each terminal / node in the ATM-LAN, and routing in the ATM-LAN is performed using the VPI (VP routing system), the ARP transmits data without any server. This can be directly performed between the terminal on the transmission side of the gram and the CLSF processing unit 23 in the network connection device 13. That is, the terminal device issues an ARP request using the broadcast channel.
[0132]
The contents of the request cell are as shown in FIG. The source address is the address of the terminal device itself (VPI value or VPI / VCI value may be used), the receiving address is the address of the other party or undefined, and the ARP destination address is the address of the other party. In this case, since there are two areas where the destination address is located and it is considered redundant, the format of the ARP cell (broadcast cell) for direct ARP can be simplified as shown in FIG. It is possible.
[0133]
Upon receiving this, the inter-network connection device 13 (if necessary, the CLSF processing unit 23 of the inter-network connection device 13 may be replaced with a broadcast cell type in a drop table. If it is determined that the datagram is a datagram delivered over the own network connection device, the ATM address addressed to itself is resolved to the resolution of the address. Therefore, the resolution result is returned to the inquiry source terminal device with the VPI of the inter-network connection device 13 and the required VCI value. This is because the inquiring terminal transmits the cell with the VPI / VCI value added thereto, so that the cell reaches the inter-network connecting device by the VPI value and is dropped to the CLSF processing unit by the VCI value. become. When returning the resolution result, a broadcast channel may be used, or this may be performed via a VP addressed to the inquiry source terminal device.
[0134]
Note that ATM-LAN does not necessarily need to apply VPI routing, and ARP can be directly applied in a general case where the receiving terminal knows the ATM address of the ATM connection with the transmitting terminal. .
[0135]
As described above, the ARP for the delivery of the datagram across the network connection device is performed, and the terminal device that sends the datagram thereafter converts the datagram into an ATM cell, and then transmits the datagram to the destination of the network. In the case where the destination is over the inter-connecting device, the ATM address (VPI / VCI) previously resolved is used and transmitted to the CLSF processing unit in the inter-connecting device. For an address once resolved, it will be used hereinafter. The CLSF processing unit in the inter-network connection device terminates this once in the network layer or the CL layer, analyzes the destination address, and (after converting it into an ATM cell again if necessary) to the ATM connected to the destination. The connection will be appropriately selected and the datagram will be delivered through this.
[0136]
Thus, by arranging the CLSF processing unit in the network connection device,
(1) The CLSF processing unit can be directly accessed from the network connected to the network connection device. This access can be performed without using an ATM connection that spans a plurality of networks.
(2) For datagram delivery across ATM networks connected to the network connection device, processing is performed here, so that conversion of the address system (VPI / VCI value) in each network is centralized here. It can be carried out.
(3) Routing information (for example, network layer address, relation information between CL layer address and VPI / VCI value and existence information) relating to the ATM network connected to the internetwork connecting device is sent to the internetworking device / CLSF processing unit. Since termination / centralized management is possible, there is no need to exchange data between networks.
Such advantages as can be enjoyed.
[0137]
Note that the ARP method (method 1 to method 4) described in the present embodiment does not necessarily require the CLSF processing unit to be present in the IWU, and may have a configuration in which the CLSF processing unit is present at an arbitrary position in the network.
[0138]
Further, as described in detail in (Method 2), the "datagram transmission request ARP" (the VPI / VCI of the ATM connection directly connected to the destination end-to-end is not always returned to the ARP). For example, the VPI / VCI value of the ATM connection to the CLSF processing unit may be resolved, and the “connection connection request ARP” (the VPI / VCI of the ATM connection directly connected end-to-end with the partner) is returned. It should be noted that they can be mainly classified.
[0139]
Next, FIG. 9 shows an embodiment of an ATM connection connection state between terminals in both ATM-LANs and a call processing unit 24 in the network connection device 13. Here, for the sake of simplicity, wiring between terminals and switch nodes and between switch nodes and networks are omitted. Other components such as a CLSF processing unit and a header conversion unit in the network connection device are also omitted in the figure. Call processing units 91 and 92 are added to both ATM-LANs.
[0140]
As described above, each terminal device and the call processing unit 24 in the network connection device 13 are connected by the ATM connection. This ATM connection may be a VP or a VC. It should be noted that the ATM connection between the terminal device and the call processing unit 24 in the network connection device 13 also crosses the network connection device, that is, does not cross the ATM-LAN, like the CLSF processing unit. is necessary. This ATM connection is a connection for signaling.
[0141]
In this case, it should be noted that only the call processing unit in the network connection device needs to have the configuration information of both ATM-LANs.
[0142]
If a terminal / node in the ATM-LAN wants to establish an ATM connection over the network connection device 13, the call processing unit 24 will be used. The correspondence is slightly different depending on whether the ATM connection over the device 13 is a connection for performing bandwidth management or a simple connection connection requiring no bandwidth management. The description will be given below in order.
[0143]
First, a description will be given of a case where only a simple connection connection (band management is unnecessary) is required.
[0144]
(Method 1) A case where a terminal issues a connection connection request to a call processing unit in an internetwork connecting apparatus.
[0145]
In this case, a “connection setting request ARP” is performed. As described above, the "connection setting request ARP" corresponds to the general signaling discussed in CCITT because the VPI / VCI of the ATM connection directly connected to the partner is resolved.
[0146]
First, a terminal device / node (referred to as a transmitting terminal) that wants to establish an ATM connection across the network connection device issues a connection connection request to the call processing unit 24 in the network connection device 13.
[0147]
At this time, if the transmitting terminal does not know to which call processing unit the connection connection request should be issued, or if a signaling channel of which ATM address (VPI / VCI) is used, a connection setting request across networks can be issued. There is a case where you do not know what. In this case, a "call processing request ARP" for asking which call processing unit should issue a connection connection request is used. That is, although the details follow the case of the CLSF processing unit, the “call processing request ARP” is issued with the destination address of the receiving terminal as an address resolution target address. When transmitting the "call processing request ARP" through the broadcast channel, the fact is written in the area of the broadcast cell type of the broadcast cell format. On the other hand, if the destination address is on the other side via the network connection device, the ATM address (VPI / VCI) to the call processing unit 24 in the network connection device 13 is returned. . This reply may be made, for example, by the network connection device or by the ARP server. Upon receiving this, the transmitting terminal again issues a connection connection request (connection setting request ARP) to the call processing unit 24 in the network connection device 13.
[0148]
It is to be noted that a method of directly broadcasting the “connection setting request ARP” through the broadcast channel without issuing the “call processing request ARP” may be considered.
[0149]
In this way, the call processing unit 24 in the inter-network connection device 13 that has received the connection connection request, in each ATM-LAN, between the transmission-side terminal and the inter-network connection device and between the inter-network connection device and the reception-side terminal. By establishing an ATM connection between the two and further setting the header conversion unit 26 appropriately, the two ATM connections are connected, and finally an ATM connection between the two terminals is established. Here, when establishing an ATM connection in each ATM-LAN, the call processing units 91 and 92 in both ATM-LANs may be used.
[0150]
(Method 2) A method in which the network connecting device relays ARP.
In this method, when the transmitting terminal device issues a “connection setting request ARP”, the network connection device that has received the “connection setting request ARP” relays the connection setting request ARP. That is, the transmitting side terminal device indicates the address of the receiving side terminal (network layer address, mail address, or the like) and the fact that the connection setting request has been made (for example, when this ARP is performed by broadcast, the broadcast cell type indicates this). ARP is performed (connection setting request). Upon receiving this, the call processing unit in the inter-network connecting device recognizes that the connection setting request ARP is a connection setting request ARP that spans the inter-network connecting device, and passes the ARP over the inter-network connecting device. Relay to the next ATM-LAN. This is performed, for example, by transmitting (relaying) an ARP request cell for making the ARP request to the next ATM-LAN. Also, in parallel with or before or after the ARP relaying, an ATM connection between the transmitting terminal and the network connection device is set / established.
[0151]
During this time, it may be notified to the transmitting terminal that ARP is currently being performed.
[0152]
When the ARP is completed, that is, when the ATM connection between the network connection device and the receiving terminal is established, the ATM connection (the ATM connection between the network connection device and the receiving terminal) and the transmitting terminal device And the ATM connection established between the network connection devices. In this case, this can be performed by appropriately setting the header conversion unit in the network connection device. In this way, for an ATM connection connected end-to-end between the transmitting terminal and the receiving terminal, the connection connection is completed by notifying the transmitting terminal device of the VPI / VCI value of the ATM connection. .
[0153]
When an ATM connection is established by ARP relaying in this way, a special call processing unit is not required in the network-to-network connection device, and it is sufficient to simply provide the ARP relaying function. is necessary. Therefore, this method 2 can be considered to be a special case of the method 1 above.
[0154]
Next, as a specific example of the method 2, an example of a flow of a connection setting request across an inter-network connecting device when the VP routing method is used in both ATM-LANs will be outlined.
[0155]
For example, an example is shown in which a terminal A of a first ATM-LAN requests setting of an ATM connection (end-to-end ATM connection) with a terminal B of a second ATM-LAN.
[0156]
The terminal A of the first ATM-LAN specifies the address of the terminal B (for example, a network layer address) as an address for address resolution, and sends out a connection setting request ARP. Upon receiving this, the interworking apparatus identifies, for example, in the call processing unit that the terminal B targeted for the address resolution of the connection setting request ARP exists in the second ATM-LAN, or The second ATM-LAN, which is the ARP destination specified in the above, is selected, and the connection setting request ARP is relayed to the second ATM-LAN (that is, the connection setting request is sent to the second ATM-LAN). Send ARP). At this time, the source address of the ARP cell may be rewritten and used as the address of the call processing unit in the network connection device.
[0157]
In parallel or before or after this, the call processing unit of the network connection device secures an ATM connection between the transmitting terminal A and the network connection device. Specifically, in the first ATM-LAN side, the VCI value (VPI value = # P) allocated to itself (inter-network connection device) is appropriately selected from unused VCI values (VPI value = # P). The selected VCI value = # Q), which is defined as an ATM connection between the transmitting terminal A and the network connection device. It should be noted that, during this time, no setting has been made to (the routing table of) the switch node in the first ATM-LAN.
[0158]
In the second ATM-LAN, an ATM connection between the receiving terminal B and the network connection device is established or address-resolved by ARP (that is, an ATM address from the network connection device to the receiving terminal B is transmitted). An ATM connection value is obtained, and the ATM address value is VPI value = # R, VCI value = # S), and an ATM connection between the network connection device and the receiving terminal B is determined.
[0159]
The call processing unit in the network connection device appropriately converts the ATM connection between the transmitting terminal A and the network connection device and the ATM connection between the network connection device and the reception terminal B into a table in the header conversion function. That is, by defining the header conversion of (VPI, VCI) = (# P, #Q) and (VPI, VCI) = (# R, #S), both ATM connections are combined and transmitted. An end-to-end ATM connection between the terminal A and the terminal B is established.
[0160]
Here, it should be noted that the call processing unit in the network connection device performs ARP relaying and only sets up a table in the network connection device. That is, it is not always assumed that a special call processing unit exists in both ATM-LANs.
[0161]
With respect to the end-to-end ATM connection established in this way, the call processing unit of the interworking apparatus sends (VPI, VCI) = (# P, #Q) as the resolution result as an ARP response. Will be returned. If the transmitting terminal A transmits a cell at the ATM address of (VPI, VCI) = (# P, #Q), the cell does not receive an AAL or more termination on the way, and the receiving terminal B and the ATM layer The end-to-end communication can be performed only by the processing, and the end-to-end ATM connection is established.
[0162]
The information of the attribute of the communication to be connected (such as UPC parameters and QOS) may be added to the information section of the cell of the connection connection request ARP.
[0163]
The above is the flow up to establishing an ATM connection from the transmitting terminal to the receiving terminal. Of course, in parallel with this, an ATM connection from the receiving terminal to the transmitting terminal is also established, and two-way communication is possible. It is also possible to easily do. In this case, the VCI value to be used in the reverse ATM connection (for example, from the inter-network connection device to the transmitting terminal A or from the receiving terminal B to the inter-network connection device) is added to the connection setting request ARP. (This VCI value is used for the reverse ATM connection).
[0164]
Although the description has been made on the assumption that the call processing units 91 and 92 exist in the first and second ATM-LANs, it is not always necessary that one or more call processing units exist in the ATM-LAN. , A call processing unit using a call processing unit in an IWU or another ATM-LAN is also conceivable.
[0165]
Next, a description will be given of a case where bandwidth management is performed for an ATM connection straddling the network connection device, that is, a case where an appropriate QOS is obtained for the ATM connection.
[0166]
In the case of the above (method 1), when setting up an ATM connection in each ATM-LAN, an entity (in the call processing unit) that performs the bandwidth management and the bandwidth management of the ATM transmission line in the network connection device. ) Manages the bandwidth in the inter-network connecting device, the band management units of the ATM connections in both ATM-LANs (may be in the call processing units 91 and 92), and the inter-network connecting device. Only when all of the band management units within the ATM switch determine that the ATM connection can be established, the ATM connections are connected by appropriately defining a header conversion function in the inter-network connection device. It should be established.
[0167]
In the case of the above (method 2), after or when an ATM connection spanning the inter-network connecting device is established, the band management units in both ATM-LANs and the inter-network connecting device perform management of the band management of the ATM connection. The validity is inquired, and if permitted, the use of the ATM connection via the bandwidth management (that is, maintaining a certain or more QOS) is permitted. Here, if the band management unit does not permit the use of the ATM connection that maintains the QOS of a certain level or more, the transmission side terminal (if necessary, also notifies the reception side terminal that the band management could not be secured. ). In this case, it should be noted that an ATM connection without bandwidth management has been established. Here, if the terminal side does not mind the connection without the bandwidth management, the terminal starts communication with the ATM connection. If it is determined that the communication is not possible with the ATM connection without the bandwidth management, The communication is abandoned. At that time, the ATM connection disconnection request may be issued.
[0168]
The above-described processes are not limited to connection setting requests, but are performed in substantially the same manner when connection setting / disconnection / change requests are made.
[0169]
By providing the call processing function in the network connection device, the following advantages can be enjoyed.
[0170]
(1) The processing of an ATM connection across an inter-network connecting device requires information in both connected networks. By arranging a call / connection processing unit in an inter-network connecting device located between each network and capable of knowing information in each of the networks, the efficiency of processing ATM connections across the inter-network connecting devices is improved. Can be done
[0171]
(2) Each of the networks connected to the inter-network connecting device can access the call / connection processing unit. This access can be made without using an ATM connection that spans a plurality of networks.
[0172]
(3) The call / connection processing unit in the network connection device can specialize in processing of an ATM connection across the network connection device.
[0173]
(4) For an ATM connection spanning between networks, it is necessary for the network connection device to convert each ATM address system (VPI / VCI system). By providing the call / connection processing unit in the network connection device, elements indispensable for the conversion of the address system, such as the setting unit of the conversion table of the VPI / VCI system, are included in the call / connection processing unit, and the same processing is performed. It becomes possible to couple tightly with the part.
[0174]
It should be noted that the call processing method described in the present embodiment does not necessarily require that the call processing unit be present in the IWU, and a configuration in which the call processing unit exists at an arbitrary position in the network can be considered. However, in this case, since the call processing unit needs to set a table in the IWU, it is desired that an ATM connection directly connected to the IWU exists.
[0175]
Next, FIG. 10 shows another embodiment of the connection state of the ATM connection between the terminals in both ATM-LANs and the call processing unit 24 in the network connection device 13. In the present embodiment, the call processing units 101 and 102 in each ATM-LAN and the call processing unit 24 in the network connection device 13 are connected by an ATM connection. This ATM connection may be a VP or a VC.
[0176]
In this case, an ATM connection connection request that crosses the network connection device 13 is first terminated in the call processing units 101 and 102 in the ATM-LAN, and the ATM connection requested here crosses the network connection device. Is recognized by the call processing units 101 and 102, the call processing is relayed to the call processing unit 24 in the network connection device 13, and the call processing in the network connection device 13 is further performed. The call is relayed from the unit 24 to the call processing unit in the ATM-LAN on the opposite side. In this process, the ATM connections in both ATM-LANs are established by the call processing units in the respective ATM-LANs, and the two ATM connections are connected by appropriately setting the header conversion unit in the network connection device. As a result, an ATM connection across the network connection device is established.
[0177]
Here, in the call processing system of the form as shown in FIG. 10, a connection setting request from a terminal in the ATM-LAN is transmitted to the inter-network connection device regardless of whether it is closed in the ATM-LAN. This is a method that is always output to the call processing units 101 and 102 in the ATM-LAN, regardless of whether it is over. In this system, the ATM connection between the call processing unit in the ATM-LAN and the call processing unit 24 in the network connection device 13 is also used in the CLSF processing unit or the network connection device as in the previous embodiment. It should be noted that it does not span ATM-LAN.
[0178]
Further, by arranging the call processing units in such a manner, only the configuration information in the own ATM-LAN may be arranged in the call processing units 101 and 102 in the ATM-LAN. It should be noted that the configuration information on the LAN only needs to be contained in the call processing unit in the network connection device. Here, the call processing units 101 and 102 in the ATM-LAN may relay to the call processing unit in the inter-network connection device when the arrived ATM connection setting request is not closed to the own ATM-LAN. It is also possible to make a rule with
[0179]
Next, FIG. 11 shows an example in which no call processing unit exists in the network connection apparatus. The setting of the ATM connection over a plurality of ATM-LANs in such a form is performed by cooperative distribution between the call processing unit 11A in the first ATM-LAN 111 and the call processing unit 11B in the second ATM-LAN 112. Will be done. That is, for example, a request for setting up an ATM connection over a plurality of ATM-LANs from a terminal in the first ATM-LAN is first passed to the call processing unit 11A in the first ATM-LAN, and the call processing unit 11A recognizes that the request spans a plurality of ATM-LANs, relays the request to a call processing unit 11B in a second ATM-LAN 112, and thereafter, the plurality of call processing units The ATM connection is established by cooperative distribution. Here, it should be noted that establishment of the ATM connection in the network connection device, that is, setting of the header conversion unit in the network connection device is also responsible for one of the call processing units. Also, the two call processing units are connected by, for example, a permanent ATM connection (either VP or VC), but note that the ATM connection connecting the call processing units spans both ATM-LANs. is necessary. In this case, all the call processing units basically need to have information on the configuration of the adjacent ATM-LAN inside.
[0180]
As described in detail above (except for the example in FIG. 11), the cells of the C plane relating to the connection spanning a plurality of networks are basically call processing units for LAN-to-LAN connection (in the present embodiment, the network connection device). In the call processing unit). Here, it is also possible to adopt a configuration in which the cells of the M plane are terminated in the network connection device. In this case, the network management unit is arranged in the network connection device. The network management unit disposed in the network connection apparatus can collectively manage, hold, or easily prepare the management information of the ATM-LAN ahead of the network management unit. It is possible to greatly reduce the addition when exchanging or acquiring network management information when the LAN is configured in a hierarchical manner (it can be terminated before and after the network connection device).
[0181]
When the network connection device is located between ATM-LANs of other vendors, a protocol conversion unit (that is, a conversion unit of an ATM-LAN protocol for each vendor) may be included therein. .
[0182]
A so-called broadcast channel broadcast in the ATM-LAN is basically terminated in the network connection device. This can be easily realized by deciding that a certain broadcast cell is not transmitted to the next ATM-LAN but discarded in the header conversion unit in the header conversion unit in the network connection device. It is.
[0183]
Assuming that VPI = all 1 is a broadcast cell and the attribute of the broadcast cell is determined by the value of the VCI, a certain broadcast cell, that is, a broadcast cell having a certain VCI value is set in the header conversion unit. The broadcast cell is discarded and another broadcast cell (broadcast cell cell having another certain VCI value) is transmitted to the next broadcast channel of the LAN after subjecting the broadcast cell to header conversion as necessary. It is also possible to easily perform relaying. Also, the cells received via the broadcast channel can be easily broadcast via the broadcast channel in the next ATM-LAN by appropriately setting the header conversion unit. A diagram summarizing these is shown in FIG.
[0184]
(Second embodiment)
Next, FIG. 13 shows an ATM network according to a second embodiment of the present invention. As shown in FIG. 1, the ATM network according to the present embodiment includes a first ATM-LAN 131, a second ATM-LAN 132, a third ATM-LAN 133, and an inter-network connection device (IWU) 134.
[0185]
The first ATM-LAN 131, the second ATM-LAN 132, and the third ATM-LAN 133 are local area networks operated by the ATM system, respectively, as in the first embodiment. The address system is independent in each ATM-LAN. If there is information to be transmitted, the terminal device or node in the ATM-LAN stores the information in an ATM cell regardless of whether the transmission destination is in the ATM-LAN or not. An ATM cell header to be added is sent to the ATM-LAN.
[0186]
FIG. 14 shows a diagram of the internal structure of the network connection device 134. As described above, the network connection device 134 includes the ATM switch 141, the CLSF processing unit 142, the call processing unit 143, the IWU management unit 144, the input processing units 14A, 14B,..., And the output processing units 14X, 14Y,.
[0187]
The network connection device 134 is located between two or more ATM-LANs and has a function of managing internetworking (LAN connection) of the plurality of ATM-LANs.
[0188]
The input processing units 14A,... Analyze the input ATM cells for header values (for example, VPI / VCI values) (and, if necessary, convert them), and perform cell routing in the ATM switch. Has the function of adding a new routing tag to the input cell.
[0189]
The ATM switch 141 is an ATM switch having N inputs and M outputs (N and M are positive numbers, for example, N = M = 8). The cell is routed according to the routing tag assigned to the cell. A broadcast function and a multicast function may be provided inside.
[0190]
The output processing units 14X,... Have a function of deleting a routing tag from ATM cells arriving via an ATM switch, and a function of converting a value of an ATM cell header if necessary.
[0191]
The conversion function of the ATM cell header is a function necessary for either the input processing unit or the output processing unit. The input processing unit and the output processing unit are in charge of connection with a switch node in a LAN adjacent to the terminal unit, a terminal device, or another network connection device if necessary.
[0192]
The function of the CLSF processing unit 142 is a connectionless service function (Connection Less Service Function). This function basically conforms to the CLSF processing unit 23 of the first embodiment, and a detailed description thereof will be omitted.
[0193]
The call processing unit 143 basically has a function of performing setting, disconnection, change, management, and the like of the ATM connection across the main network connection device 134, and basically has a function of performing the call processing unit 24 of the first embodiment. The function is the same. Therefore, detailed description is omitted.
[0194]
The IWU management unit 144 has a function of managing and controlling the main network connection device 134. It is assumed that each module in the network connection device 134 is connected to a bus (not shown), and control such as a change of a set value of each module from the IWU management unit 144 is performed through this bus. I do.
[0195]
Instead of exchanging information between the modules through the bus as described above, the information may be put on ATM cells and the cells may be exchanged between the modules.
[0196]
Further, in the present embodiment, various processes in the IWU are performed separately (that is, the CLSF processing unit performs processing in the CLSF processing module, and the call processing performs processing in the call processing module). All or some of these processes can be performed by the same CPU / MPU.
[0197]
Next, FIG. 15 shows an embodiment of a node / terminal configuration inside the first ATM-LAN 131, the second ATM-LAN 132, and the third ATM-LAN 133. The first ATM-LAN 131 includes three switch nodes 151, 152, and 153 and terminals 15A, 15B, 15C, and 15D connected thereto. The second ATM-LAN 132 includes two switch nodes 154 and 155 and terminals 15E, 15F and 15G connected thereto. The third ATM-LAN 133 is composed of two switch nodes 156 and 157 and terminals 15H, 15I and 15J connected thereto. The function of the switch node is the same as in the first embodiment.
[0198]
Next, FIG. 16 shows an embodiment of an ATM connection connection state between a terminal in each ATM-LAN and a CLSF processing unit in the network connection device 134. Here, for the sake of simplicity, wiring between terminals and switch nodes and between switch nodes and networks are omitted. Further, other components such as a call processing unit and a header conversion unit in the network connection device and a switch node in the ATM-LAN are also omitted in the figure.
[0199]
As described above, each terminal device and the CLSF processing unit 142 in the network connection device 134 are connected by an ATM connection (VP or VC). This ATM connection is a connection that is not subject to band management, as in the first embodiment. The ATM connection between the terminal device and the CLSF processing unit 142 in the network connection device 134, as in the first embodiment, does not cross the network connection device, that is, does not cross the ATM-LAN. You need to be careful.
[0200]
When the terminal device wants to deliver a datagram via the network connection device 134, that is, outside the ATM-LAN, this is performed in a process substantially similar to that of the first embodiment. The following is a brief description.
[0201]
Datagram delivery across the network connection device 134 is delivered via the CLSF processing unit 142 in the network connection device 134. That is, the datagram converted into an ATM cell is sent to the CLSF processing unit 142. Here, the approach (ARP) until the terminal device knows that the terminal / node in the ATM-LAN should send the datagram to the CLSF processing unit 142 is the same as in the first embodiment. Therefore, the details are omitted. As in the first embodiment, ARP for datagram delivery across the network connection device is performed, and a terminal device that sends out the datagram thereafter converts the datagram into an ATM cell and then converts the datagram into an ATM cell. If the destination is a destination that crosses the network connection device, it uses the previously resolved ATM address (VPI / VCI) to send it to the CLSF processing unit in the network connection device. The CLSF processing unit in the inter-network connection device terminates this once in the network layer or the CL layer, analyzes the destination address, and (after converting it into an ATM cell again if necessary) to the ATM connected to the destination. The connection will be appropriately selected and the datagram will be delivered through this.
[0202]
Here, even with this method, the same advantages as the advantages of the CLSF processing unit in the network connection device in the first embodiment can be enjoyed.
[0203]
Next, FIG. 17 shows an embodiment of an ATM connection connection state between a terminal in each ATM-LAN and a call processing unit 143 in the network connection device 134. Here, for the sake of simplicity, wiring between terminals and switch nodes and between switch nodes and networks are omitted. Other components such as a CLSF processing unit processing unit and a header conversion unit in the network connection apparatus are also omitted in the figure. In addition, call processing units 171, 172, and 173 are added to both ATM-LANs.
[0204]
As described above, each terminal device and the call processing unit 143 in the network connection device 134 are connected by the ATM connection (VP or VC). It should be noted that the ATM connection between the terminal device and the call processing unit 143 in the inter-network connection device 134 also spans the inter-network connection device as in the case of the CLSF processing unit, that is, does not span the ATM-LAN. is necessary.
[0205]
Also, in this case, it should be noted that only the call processing unit in the network connection device needs to have all the configuration information of each ATM-LAN.
[0206]
When a terminal device / node in the ATM-LAN wants to establish an ATM connection across the network connection device 134, the call processing unit 143 is used. Basically, it is the same as the first embodiment, but there are some differences, so that a brief description will be given.
[0207]
First, a description will be given of a case where only a simple connection is required.
[0208]
(Method 1): When the terminal issues a connection connection request to the call processing unit in the network connection device.
[0209]
This case conforms to the first embodiment. Therefore, detailed description is omitted.
[0210]
(Method 2): A method in which the network connection device relays ARP.
[0211]
In this method, similarly to the first embodiment, when the transmitting side terminal device issues a “connection setting request ARP”, the network connection device that has received this relays the ARP. Analyzes which ATM-LAN belongs to a plurality of ATM-LANs connected to the network connection device 134, and then relays ARP only for the ATM-LAN. Different from the embodiment. That is, the call processing unit refers to an internal database (correspondence table between a connected LAN and a network address or a domain name, etc.) (resolution at a network level). Resolution will be applied at the terminal / node level.
[0212]
Of course, ARP may be relayed for all ATM-LANs connected to the network connection device without performing network-level resolution in the network connection device, or ATM connected to the network connection device. Until ARP is sequentially performed on the LAN, ARP may be performed before entering (for example, in ascending order of switch port numbers).
[0213]
Note that when bandwidth management is performed for an ATM connection that straddles the network connection device, that is, when an appropriate QOS is obtained for the ATM connection, the detailed description is omitted because it conforms to the first embodiment.
[0214]
The above-described processes are not limited to connection setting requests, but are performed in substantially the same manner when connection setting / disconnection / change requests are made.
[0215]
Here, even with this method, the advantage of the call processing unit in the network connection device in the first embodiment can be enjoyed.
[0216]
Further, the call processing unit 143 is not necessarily located in the IWU 134 but may be located at an arbitrary position in the network.
[0217]
Next, FIG. 18 shows another embodiment of the connection state of the ATM connection between the terminal in each ATM-LAN and the call processing unit 143 in the network connection device 134. The call processing units 181, 182, and 183 in each ATM-LAN and the call processing unit 143 in the network connection device 134 are connected by an ATM connection (VP or VC). Also in this case, similarly to FIG. 10 of the first embodiment, an ATM connection connection request that straddles the inter-network connecting device 134 is first terminated in the call processing units 181, 182, and 183 in the ATM-LAN. When the call processing units 181, 182, and 183 recognize that the requested ATM connection spans the network connection device, the call processing unit communicates with the call processing unit 143 in the network connection device 134. The call processing unit 143 in the network connection device 134 determines which ATM-LAN is connected to the terminal / node in the connection processing, and based on the determination result, Are relayed to the corresponding ATM-LAN call processing unit. In this process, the ATM connection in each ATM-LAN is established by the call processing unit in each ATM-LAN, and the input processing unit in the network connection device or the header conversion unit in the output processing unit is appropriately set. By doing so, both ATM connections are connected, and as a result, an ATM connection across the network connection device is established.
[0218]
When the call processing unit 143 in the network connection device 134 relays the arrived connection connection request across the network connection device to the call processing unit in the ATM-LAN, as described above, The call processing unit in the device does not analyze which ATM-LAN call processing unit relays the call, but (if necessary, the call processing unit in the ATM-LAN in which the connection setting request is issued). It is also possible to adopt a method of broadcasting the call processing units in all connected ATM-LANs (excluding the call processing units) or a method of sequentially sending inquiries to them.
[0219]
Here, similarly to the first embodiment, in the call processing system of the form shown in FIG. 18, a connection setting request from a terminal in the ATM-LAN is a request that is closed in the own ATM-LAN. Regardless of whether it is a network connection device or a network connection device, this method is always output to the call processing units 181, 182, and 183 in the ATM-LAN. In this system, the ATM connection between the call processing unit in the ATM-LAN and the call processing unit 143 in the network connection device 134 is also used in the CLSF processing unit or the network connection device as in the previous embodiment. It should be noted that it does not span ATM-LAN.
[0220]
Further, by arranging the call processing units in this manner, only the configuration information in the own ATM-LAN may be arranged in the call processing units 181, 182, and 183 in the ATM-LAN. It should be noted that the configuration information on the ATM-LAN only needs to be contained in the call processing unit in the network connection device. Here, the call processing units 181, 182, and 183 in the ATM-LAN relay to the call processing unit in the inter-network connection device when the arrived ATM connection setting request is not closed to the own ATM-LAN. It is also possible to make a rule that it is good.
[0221]
Next, FIG. 19 shows an example in which no call processing unit exists in the network connection device. Also in this case, similarly to the first embodiment, the setting of the ATM connection over a plurality of ATM-LANs in such a mode is performed by the call processing unit 19A in the first ATM-LAN 191 and the second ATM-LAN. This is performed by cooperative distribution between the call processing unit 19B in the LAN 192 and the call processing unit 19C in the third ATM-LAN 193. That is, for example, a request for setting up an ATM connection that spans a plurality of ATM-LANs from a terminal in the first ATM-LAN to a terminal in the second ATM-LAN is first made in the first ATM-LAN. The request is first passed to the call processing unit 19A. The call processing unit 19A recognizes that the request extends over a plurality of ATM-LANs, and sends the request to the call processing unit 19B in the second ATM-LAN 192. Relaying is performed, and thereafter, the plurality of call processing units cooperate and distribute to establish an ATM connection. Here, it should be noted that establishment of the ATM connection in the network connection device, that is, setting of the header conversion unit in the network connection device is also responsible for any of the call processing units. Each call processing unit is connected by, for example, a permanent ATM connection (either VP or VC). However, the ATM connection connecting these call processing units spans both ATM-LANs. Caution must be taken. In this case, all of the call processing units basically need to have information on the configuration of the adjacent ATM-LAN inside. Further, in a situation where a plurality of ATM-LANs hang from one network connection device, it is necessary to basically form a permanent connection between the call processing units in each ATM-LAN in a mesh form.
[0222]
As described in detail above, in the second embodiment, as in the first embodiment (except for the example in FIG. 19), the cells of the C plane relating to the connection that spans a plurality of networks are basically LAN LANs. The connection is terminated at a call processing unit for connection (a call processing unit in the network connection device in the present embodiment). Also, as in the first embodiment, the M-plane cell can be terminated in the network connection device. When the network connection device is located between ATM-LANs of other vendors, a protocol conversion unit (that is, a conversion unit of an ATM-LAN protocol for each vendor) may be included therein. . Also, the broadcast channel in the ATM-LAN is basically terminated in this inter-network connecting device as in the first embodiment.
[0223]
(Third embodiment)
Next, FIG. 20 shows an example of a configuration method of a large-scale ATM network as a third embodiment. This large-scale ATM network includes an ATM backbone network 201, a first ATM-LAN 202, a second ATM-LAN 203, a third ATM-LAN 204, an ATM backbone network, and a network connection device between each ATM-LAN. 20A, 20B and 20C. These ATM-LANs can have a hierarchical network structure via the ATM backbone network 201.
[0224]
The ATM backbone network 201 is a network for connecting between ATM-LANs and interfacing with a public network (not shown). The internal architecture is not particularly limited, but it is a highly flexible, scalable, and highly reliable network that can adopt various architectures such as ring / star / bus / tree / mixture. ATM-LANs 202, 203 and 204 are the same as in the first and second embodiments.
[0225]
The network connection devices 20A, 20B, and 20C are almost the same as the network connection device 13 in FIG. 2 except that they manage internetworking between the ATM backbone network and the ATM-LAN. In order to ensure its reliability, the traffic management is stricter than that of the ATM-LAN. Therefore, the policing mechanism is attached to the output interface to the backbone network side of the network connection equipment, and the specified traffic conditions are complied with. It is supposed to. Another major difference from the interworking apparatus 13 of FIG. 2 is that a protocol conversion mechanism between the ATM-LAN and the ATM backbone network is provided.
[0226]
Here, for example, the ATM backbone network is a network that is managed by the management department of the entire company or university, or the management department of the entire business establishment, whereas the ATM-LAN is a department, section, or laboratory unit of the company or university. LAN to be laid. Compared with the current situation, it can be considered that the ATM backbone network corresponds to the current telephone network (PBX network), and the ATM-LAN corresponds to the current computer communication LAN. The large-scale network according to the present embodiment is considered to be a network in which a telephone network and a computer network are integrated by an ATM system as a hierarchical network. Further, it may be assumed that the ATM backbone network is a network that is deployed on a nationwide scale via a dedicated line of a public network.
[0227]
FIG. 21 shows the internal structure of the ATM-LAN in this large-scale network. The first ATM-LAN 202 includes three switch nodes 211, 212, and 213 and terminals 21A, 21B, 21C, and 21D connected thereto. The second ATM-LAN 203 is composed of two switch nodes 214 and 215 and terminals 21E, 21F and 21G connected thereto. The third ATM-LAN 204 includes two switch nodes 216 and 217 and terminals 21H, 21I, and 21J connected thereto. The function of the switch node is the same as in the first embodiment.
[0228]
Next, details of a datagram delivery method in the ATM-LAN in the large-scale network according to the present embodiment will be described. Since the datagram delivery method is the same for each of the first to third ATM-LANs 202 to 204, the first ATM-LAN 202 will be representatively described as an example.
[0229]
In the first ATM-LAN 202, a unique VPI value is assigned to every node, IWU, and terminal device in the first ATM-LAN by LAN. That is, if a cell originating from any other node / IWU / terminal has the VPI value in the VPI field of its ATM cell header, the cell is always routed to the corresponding node / IWU / terminal. You. Here, it should be noted that a unique VPI value is assigned to the switch node and the network connection device in the LAN.
[0230]
For example, when one VPI value is assigned to each node / IWU / terminal as shown in FIG. 22, “VPI value = # A” is set, and the cell transmitted from any terminal / node is set to the VCI value. Is always routed to the terminal 21A, that is, delivered. In addition, a routing table of a switch node in the ATM-LAN is set so that cells are routed in this way.
[0231]
By setting in this way, the nodes / IWUs / terminals belonging to the ATM-LAN are equivalent to the mesh connection (end-to-end) between the nodes / IWU / terminal. That is, when performing communication (when transmitting a cell) from an arbitrary terminal / IWU / node (called a transmitting terminal) to an arbitrary terminal / IWU / node (called a receiving terminal), Using the assigned VPI value (ATM cell header value), the cell is routed to the receiving terminal. This means that an ATM connection from an arbitrary transmitting terminal to an arbitrary receiving terminal is set up in a mesh form (although there is no guarantee of QOS) (VP routing method).
[0232]
Note that the format of the ATM cell header in the ATM-LAN according to the present embodiment conforms to the format of a UNI (user / network interface) cell in the CCITT recommendation. Since the VPI value is assigned to the constituent elements (nodes / IWUs / terminals) of the ATM-LAN so as to be unique in the ATM-LAN, the total number of nodes / IWUs / terminals in the ATM-LAN is calculated. The upper limit is limited to 256. This is because the VPI area has only 8 bits. In the present embodiment, as described later, the upper limit of the total number of nodes / IWUs / terminals in the ATM-LAN is even smaller.
[0233]
Here, a switch is set to perform the VP routing method in the switch node. That is, if an appropriate VP is set in the ATM cell header and the cell is transmitted, the cell is routed to the intended receiving terminal. Despite this, the transmitting terminal may not recognize the ATM address (VPI value) of the receiving terminal. In this case, it is assumed that the transmitting terminal has recognized the network layer address of the intended receiving terminal (or may be the physical address value of the communication board, etc.).
[0234]
Such a situation occurs when, in an existing LAN (eg, Ethernet), the network address (eg, IP address) of the receiving terminal is known but the physical address (MAC address, eg, Ethernet address) is not known. Corresponding. In such an existing LAN, in such a case, a protocol (address resolution protocol, ARP) for resolving a physical address from a network layer address is operated.
[0235]
Similarly, in the ATM-LAN of the present embodiment, ARP is performed to obtain (resolve) an ATM address (VPI value) connected to the receiving terminal from the network layer address of the receiving terminal. Is expressed as
[0236]
Hereinafter, an ARP method when the receiving terminal is in the same ATM-LAN as the transmitting terminal will be described. First, the following two methods can be considered as this method.
[0237]
(Method 1): Direct ARP between sender terminal and receiver terminal
The transmitting terminal knows the network layer address (eg, IP address or E.164 address) of the receiving terminal, but this address corresponds to any ATM address (specifically, VPI / VCI value). I don't know. In this case, the transmitting terminal performs ARP through a broadcast channel defined in the ATM-LAN in advance. Although details will be described later, there are several types of ARPs, and this ARP is a “datagram transmission request ARP” therein.
[0238]
Here, the broadcast channel is an ATM connection that can broadcast a transmitted cell from any transmitting terminal to all nodes / IWUs / terminals belonging to the ATM-LAN. For example, when a cell with “VPI value = all 1” is transmitted, the cell is recognized by the network as a broadcast cell (broadcast cell), and the cell is transmitted to all nodes / IWUs / terminals belonging to the ATM-LAN. Will be delivered to Here, the cell transmitted as the broadcast cell may or may not be delivered to the terminal that transmitted the cell.
[0239]
FIG. 23 shows an example of the format of a cell that performs a datagram transmission request ARP. As described above, the datagram transmission request ARP cell includes at least the transmission source address (Source Address), the destination address (Destination Address), the broadcast cell type, and the ARP type. The source address includes the network layer address type, the network layer address of the transmitting terminal, and the VPI value assigned to the transmitting terminal in the ATM-LAN.
[0240]
Here, the network layer address type is an area for indicating which network layer address (which network layer protocol address) the network layer address of the transmitting terminal subsequently included in this area is. is there. For example, as shown in FIG. 24, a method of identifying by LLC + (SNAP (SubNetwork Attachment Point) or NLPID (Network Layer Protocol ID)) can be considered. Further, as this network layer address type, the same type as the protocol type of PPP (Point to Point Protocol) of Internet Request for Comments (RFC) 1134 may be used.
[0241]
Also, by using the VPI value assigned to the transmitting terminal, cells can be delivered from all nodes / IWUs / terminals belonging to the ATM-LAN to the "transmitting terminal" (VP routing method). As described above. That is, this value indicates its own ATM address in the ATM-LAN.
[0242]
The destination address includes the network layer address type and the network layer address of the receiving terminal. The network layer address type and the network layer address of the receiving terminal are the same as the relationship between the same type of source address and the same address, and therefore, the details are omitted.
[0243]
The broadcast cell type is a field indicating what meaning the broadcast cell has. Specific "meaning of the broadcast cell" includes, for example, "datagram transmission request ARP", "connection connection request ARP" (meaning will be described later), "broadcast" (all nodes / IWUs / terminals in the ATM-LAN). (E.g., routing information, etc.), and all the nodes / IWUs / terminals basically receive and process the information. As a 6-bit coding method for identifying a broadcast cell type, for example, “000000; datagram transmission request ARP”, “000001; connection connection request ARP”, “0000010; broadcast”, and the like can be used.
[0244]
The ARP type indicates whether the ARP is an “ARP request” when the broadcast cell is an ARP (“datagram transmission request ARP” or “connection setting request ARP”) (for example, ARP type value = 0). , “ARP response” (same = 1)).
[0245]
As a 2-bit coding method for identifying the ARP type, for example, "00; ARP request", "01; ARP response", "10; RARP request", "11; RARP response" and the like can be used. Here, "ARP request" in ARP is the type of ARP cell used when inquiring the ATM address (VPI value, etc.) of the other party, and "ARP response" is the ATM address as a response to the "ARP request". Is the type of ARP cell that returns.
[0246]
Note that an error correction code such as parity or CRC may be added to the ARP cell. This error correction code is desirably inserted at the end of the cell in order to facilitate pipeline processing of the cell.
[0247]
It is desirable that the present ARP cell be completed in one cell without extending to a plurality of cells. This is because, when the ARP cell extends over a plurality of cells, reassembly of the information over the plurality of cells is required, which causes the processing to be complicated. That is, when a certain information packet is converted into an ATM cell and transferred through a broadcast channel, the receiving terminal first recognizes that the broadcast cell is addressed to itself by referring to the destination address included in the cell, and The source is determined by referring to the source address, and the cell is reassembled for each source address to obtain an information packet. Therefore, when the broadcast cell is multiplexed and received from a plurality of transmitting terminals, the receiving terminal individually reassembles the information packet for each pair of the destination address and the source address. You need a function to do it. This means that a large cost is required for realizing the analysis and processing functions of the broadcast cell, especially for the hardware. On the other hand, if the broadcast cell is completed in one cell, reassembly is not required, and the processing for each cell can be performed sequentially, which is easy to realize. This is a situation common not only to ARP cells but also to all broadcast cells.
[0248]
When the transmitting terminal performs ARP, the transmitting terminal transmits the broadcast cell to the ATM-LAN using a "datagram transmission request ARP (ARP request)". At this time, the meaningless data is contained in the field of the ATM address of the destination address. The protocol may be defined in this way. All nodes / IWUs / terminals belonging to the ATM-LAN receive the broadcast cell, identify the broadcast cell type, identify that the broadcast cell is a "datagram transmission request ARP (ARP request)", Further, it determines whether or not this is an ARP addressed to itself (whether or not its own address is included in the destination address of the ARP cell). If the cell is a "datagram transmission request ARP (ARP request)" addressed to itself, the transmission side terminal requesting the ARP is notified of its own ATM address (the VPI assigned to itself). ), A response cell (ARP response) including its own ATM address (VPI value) is transmitted. This reply may be made using a broadcast channel from the receiving terminal, but in the present embodiment, in consideration of the communication resources of the network, the transmission included in the “datagram transmission request ARP (ARP request)” cell is considered. The response is performed by using the ATM address (VPI value) of the side terminal as the ATM address (VPI value) of the reply cell (ARP response cell). In these cases, the address of the transmitting terminal (the terminal that has responded to the ARP), the address of the receiving terminal (the terminal that has performed the ARP inquiry), the broadcast cell type (using the broadcast cell, When replying), the ARP type is entered. In this way, compared to the ARP inquiry (ARP request), the source address and the receiving address are exchanged.
[0249]
Here, when the ARP response is performed without using the broadcast channel, that is, the ARP response is transmitted to the transmitting terminal that has inquired about the ARP by a point-to-point ATM connection (VP using the VPI value of the transmitting terminal). A description will be given of a case in which the connection is performed using an ATM connection based on a routing method.
[0250]
A VCI value to be used when replying to (the ARP of) the broadcast channel, such as an ARP response, is determined in advance such as “VCI value = 0”. It is assumed that the payload (48 octets) of the cell having the “VCI value = 0” has the same format as the broadcast cell (see FIG. 25). By doing so, since information such as the broadcast cell type, the ARP type, the source address, and the destination address is included in the payload, the "transmitting terminal (the terminal that made the ARP request)" Can be recognized as "this is an ARP response to the ARP request issued by itself."
[0251]
FIG. 26 summarizes the flow of ARP between the nodes / IWUs / terminals in the ATM-LAN as described above. As shown in this figure, the node / IWU / terminal that has received the ARP request not addressed to itself may discard the cell (ARP request cell).
[0252]
The other terminals may sequentially update and learn the address table (correspondence table between the L3 address and the VPI) in the own terminal with reference to these ARP cells which are not necessarily related to the own terminal.
[0253]
(Method 2): When using ARP server
Even if at least one server (ARP server) that manages and recognizes the correspondence between the network layer address in the ATM-LAN and the ATM address (VPI value) exists in the ATM-LAN, or does not exist, When all the nodes / IWUs / terminals belonging to the ATM-LAN recognize the access method to the ARP server, any terminal can perform resolution from the network layer address to the ATM address (VPI). Is a method of making an inquiry to the ARP server. However, the ARP server is not shown in FIG.
[0254]
The transmitting terminal that makes the ARP request sets the ARP request cell through the broadcast channel or sets the VPI value addressed to the ARP server in the ATM cell header (at this time, for example, VCI = 0, the reason being the same as (method 1)). , And sends the ARP request cell to the ARP server.
[0255]
However, when the ATM address (VPI value) of the ARP server is unknown, it is necessary to take care that this address must be resolved. Here, when performing the resolution of the address of the ARP server, the address resolution from the network layer address of the ARP server to the ATM address may be performed through a broadcast channel, or the network layer address of the ARP server may be unknown. In this case, the ARP server may autonomously recognize that the type of the broadcast cell is the ARP request cell, and respond to this. This may be performed using a process server or the like.
[0256]
The ATM address of the ARP server may be determined in advance by default (uniquely determined by the ATM-LAN).
[0257]
The ARP server that has received the ARP request (datagram transmission request ARP) in this way, if the resolution destination of the ARP request is a node / IWU / terminal in the ATM-LAN, the resolution destination Is returned as an ARP response. This ARP response may be made through a broadcast channel, as in (Method 1), or may be made using a point-to-point ATM connection to the transmitting terminal that made the ARP request.
[0258]
As described above, the ARP server is not limited to one in one ATM-LAN, but may be plural in the same ATM-LAN, or one in a plurality of ATM-LANs. There may be a configuration in which there is only one, and access from the plurality of ATM-LANs is possible.
[0259]
The above embodiment is the address resolution method in the case where the receiving terminal exists in the same ATM-LAN as the transmitting terminal. Therefore, an address resolution method when the receiving terminal is in an ATM-LAN different from the transmitting terminal will be described.
[0260]
Basically, in the ATM network according to the embodiments described above, datagram delivery over a plurality of ATM-LANs, that is, datagram delivered over an internetwork unit (IWU), is performed by a CLSF processing unit. The ATM connection is terminated once, and the datagram is subjected to the processing of the network layer address (network layer processing or CL layer processing).
[0261]
Therefore, if the address resolution destination (the receiving terminal having the network layer address) belongs to a different ATM-LAN as viewed from the transmitting terminal, if it is a “datagram transmission request ARP”, The address resolution result in the ARP response to the ARP request needs to be the VPI / VCI value of the ATM connection to the CLSF processing unit in the network connection device, that is, the ATM address.
[0262]
Here, the distinction between the “datagram transmission request ARP” and the “connection connection request ARP” will be described. In the “datagram transmission request ARP”, when there is a datagram to be transmitted (in the form of an ATM cell) (when only the network layer address of the datagram to be transmitted is known and the ATM address is unknown), “ARP Request this resolution as "request". On the other hand, a "datagram transmission request ARP" replies as a resolution result which ATM address is used to deliver the datagram to a desired receiving terminal. Here, the delivery destination delivered with the ATM address value returned as the resolution result is not necessarily the receiving terminal. For example, this case corresponds to a case where a destination delivered by the ATM address value is a CLSF processing unit.
[0263]
On the other hand, the “connection setting request ARP” is an ARP that requests an ATM connection directly connected to a receiving terminal as an address resolution result. That is, whether or not the receiving terminal is in the same ATM-LAN as the transmitting terminal, if the ATM address value as the resolution result is used, the ATM connection indicated by the ATM address is halfway (for example, IWU or CLSF). ARP requesting a state in which the receiving terminal is connected to the receiving terminal via an end-to-end ATM connection without being terminated by a processing unit. Such ARP is similar to the connection setup method defined by the signaling procedure discussed in CCITT. However, in this connection setting, in the present embodiment, overhead such as bandwidth management (securing a bandwidth) is not necessarily required, and setting of an end-to-end ATM connection is simply performed (table setting in a switch node is performed. It should be noted that the use of the ATM address only guarantees that end-to-end communication can be performed through the ATM connection, and does not necessarily guarantee QOS or the like. is there. If this ARP (connection setting request ARP) is used, an ATM connection coupled end-to-end can be obtained, so that QOS (Quality Of Service) and negotiation of communication attributes are performed between both terminals without passing through a call setting server or the like. And so on.
[0264]
Next, an address resolution method (“datagram transmission request ARP”) when the receiving terminal is in an ATM-LAN different from the transmitting terminal will be specifically described. Also in this case, the following two methods can be considered.
[0265]
(Method I): Direct ARP of transmitting terminal-CLSF processing unit in IWU
Basically, it conforms to (method 1) where the receiving terminal is in the same ATM-LAN as the transmitting terminal. That is, if the network layer address of the receiving terminal (or the physical address of the communication board, etc.) is known, but it is not known which ATM address corresponds to the address, the transmitting terminal preliminarily checks the ATM-address. This is a method for performing ARP through a broadcast channel defined in a LAN.
[0266]
The difference from the above (method 1) is that the receiving terminal that performs the ARP (datagram transmission request ARP) belongs to a different ATM-LAN from the transmitting terminal (the same applies to the inter-network connection device. Otherwise, if the datagram cannot be delivered), the interworking device returns an ARP response.
[0267]
The network connecting device grasps the network layer addresses of all nodes / IWUs / terminals in the ATM-LAN to which the transmitting terminal belongs, and determines that the receiving address included in the ARP request does not exist in the ATM-LAN. It is possible to recognize. In this case, the inter-network connection device may respond to its own ATM address value (VPI value) as an ARP response as a default router.
[0268]
Further, the ARP response may be made after confirming the existence of the receiving terminal having the receiving address included in the ARP request on the opposite side straddling the network connection device.
[0269]
In addition, some routing protocol may operate between the IWUs or between the CLSF processing units, exchange routing information, and make an ARP response based on the routing information.
[0270]
Other points are almost the same as (method 1) when the receiving terminal is in the same ATM-LAN as the transmitting terminal. In this case, if the received broadcast cell is a datagram transmission request ARP, the add / drop function in the internetwork connecting apparatus can process the datagram transmission request ARP by using an internal ARP processing unit (in this embodiment, an LSF processing unit). ) Needs to be dropped. For example, if the received broadcast cell is a “connection setting request ARP”, it is dropped to the internal call processing unit.
[0271]
Further, the CLSF processing unit grasps the network layer address of the node / IWU / terminal belonging to each ATM-LAN connected to the network connection device as described above, and the receiving address included in the ARP request issues the ARP request. It is necessary to analyze whether or not the terminal is in the same ATM-LAN as the transmitting terminal, and if not, generate an ARP response and send an ARP response cell to the transmitting terminal.
[0272]
Further, a method of considering whether the request is addressed to the own subnet using a subnet mask or the like may be considered.
[0273]
Thus, the present CLSF processing unit has a datagram relaying function, an address resolution function, and a routing information processing function. Note that an address resolution function and / or a processing function of routing information may be provided separately from the CLSF processing unit.
[0274]
(Method II): When using an ARP server
Basically, it conforms to (method 2) when the receiving terminal is in the same ATM-LAN as the transmitting terminal. That is, there is a server (ARP server) that manages and recognizes the correspondence between the network layer address in the ATM-LAN and the ATM address (VPI value), and performs the resolution from the network layer address to the ATM address (VPI). In order to perform the solution, an inquiry is made to the ARP server.
[0275]
The difference from the above (method 2) is that the receiving terminal that performs the ARP (datagram transmission request ARP) belongs to a different ATM-LAN from the transmitting terminal, that is, the network connection device. If the datagram cannot be delivered without spanning over, the ATM address to (the CLSF processing unit of) the network connection device is returned as an ARP response.
[0276]
For this reason, the ARP server has a table (correspondence table of network layer addresses and ATM addresses (VPI values, see FIG. 27) for each ATM-LAN, and the node / IWU in the target ATM-LAN. In addition to the network layer address of the / terminal, the ATM address of the network connection device is described. In this way, as the ARP response to the receiving terminal belonging to the ATM-LAN different from the transmitting terminal, the network connection device (the CLSF processing unit therein) is selected.
[0277]
The setting of the table in the ARP server may be manually performed manually. Further, the table setting may be automatically performed in such a manner that the ARP server obtains information on the routing by an appropriate routing protocol.
[0278]
The other points are almost the same as (method 2) when the receiving terminal is in the same ATM-LAN as the transmitting terminal.
[0279]
In the above (method 2) and (method II), if the ATM-LAN is a network that is not routed by the "VP routing method", the network is a form in which an ATM connection is established by, for example, a call processing server. In this case, the ARP server that has received the ARP request transmits a call processing server (not shown in the figure) between the transmitting terminal that has issued the ARP request and the receiving terminal that has been requested by the ARP request. An ATM connection using a server that performs setting, disconnection, change, management, etc. (end-to-end within the ATM-LAN, and between the CLSF processing units in the network connection device outside the ATM-LAN) Set and notify the ATM cell header value such as the VPI / VCI value of the ATM connection to the transmitting terminal and, if necessary, the receiving terminal. Method may be used that.
[0280]
Further, in the above (method 2) and (method II), even if the ARP server has a function of authentication (permission of connection setting, etc.), that is, a function of performing address resolution only for a specific terminal. good.
[0281]
As described above (method I) or (method II), the processing for the ARP request related to the transmission of datagrams over a plurality of ATM-LANs is performed. (Address resolution protocol for datagrams)
If the ARP fails in any way, the broadcast cell type is set to “broadcast” through the broadcast channel, and the destination network layer address is written in the destination address field. Communication can be performed.
[0282]
If the ARP fails, the datagram to be transmitted to the CLSF processing unit processing unit inside (or inside or outside) the internetwork connecting device can be transmitted. It should be noted that by delivering datagrams to the CLSF processing unit (from recognizing the existence of all network layer addresses of the terminal), datagram delivery within the same ATM-LAN becomes possible. is there.
[0283]
Next, a rule for attaching an ATM cell header for datagram delivery in the present embodiment will be described.
[0284]
Since ATM cells in the ATM-LAN according to the present embodiment are UNI cells according to the CCITT recommendation, VPI values from 0 to 255 and VCI values from 0 to 65535 can be used.
[0285]
As described above, at least one VPI value is assigned to each node / IWU / terminal in the ATM-LAN, and an appropriate VPI value is assigned from any transmitting terminal. Is added to the ATM cell header and transmitted, the packet is routed to the corresponding receiving terminal (the receiving terminal given the VPI value) (VP routing method). In the present embodiment, considering the existence of a VPI value having a special meaning (for example, for meta-signaling, network management, emergency, etc.), the VPI value assigned to each node / IWU / terminal in the ATM-LAN is , 16 to 254. That is, the total number of nodes / IWUs / terminals that can exist in the same ATM-LAN is up to 239 in the present embodiment. An exception to this VPI value assignment method is “VPI = all 1 (255)”. In the case of this VPI value, an ATM cell having the VPI value is broadcast as a broadcast channel in the ATM-LAN. You.
[0286]
It should be noted that the reserved VPI value (VCI value) may have the same meaning as the reserved VPI value (VCI value) in B-ISDN under discussion at CCITT.
[0287]
Next, an example of a rule for attaching a VCI in the present embodiment will be described. As described above, “VCI = 0” is used for the response of the broadcast cell. As in the case of the VPI, reserved bits are set for "VCI = 1 to 15". If "VCI = 16-254", this shall be used for datagram delivery. That is, when an arbitrary transmitting terminal transmits a datagram, a cell having a value of “VCI = 16 to 254” is used together with a destination address (destination VPI). At this time, it is assumed that the VPI value assigned to the user is entered as the VCI value. That is, when a node / IWU / terminal to which "VPI value = # X" is assigned transmits a datagram, the VPI area of the ATM cell header obtained by converting the datagram into an ATM cell is the datagram. (The resolution result of the datagram transmission request ARP) and the VPI value assigned to itself (that is, “VCI value = own VPI value”). Send out.
[0288]
The node / IWU / terminal that has received this cell recognizes that the cell has been delivered to itself based on the VPI value, and since the VCI value is “16 ≦ VCI value ≦ 254”, the datagram is Can be recognized. In order to determine the transmission source, the receiving terminal must use a different transmission terminal unless the ID that can determine the transmission source is in a layer higher than the ATM layer such as AAL type 3/4 for each cell. Or a datagram sent from the CLSF processing unit or the like must have a different ATM cell header. This is made possible by using the ATM cell header value assignment method as in the present embodiment.
[0289]
Further, when the inter-network connecting device receives a cell whose VPI value is addressed to itself and has a VCI value of 16 to 254, the cell crosses the inter-network connecting device or the inter-network connecting device. The cell can be recognized as a datagram to be delivered and the cell can be routed to an internal CLSF processor.
[0290]
As described above, when the VCI value is 16 to 254, the receiving terminal can recognize that the cell is a datagram, and further, this is obtained by attaching the corresponding VCI value to each source terminal. Datagram reassembly is also performed for an AAL (ATM Adaptation Layer) mode in which packets from the same source ATM-SAP, such as AAL type 5, must be sent consecutively because the gram is transferred. It is necessary to pay attention to the fact that it can be used (a different VPI / VCI value is provided for each transmitting terminal). That is, datagram delivery can be performed without negotiation on the VCI value used between the transmitting terminal and the receiving terminal.
[0291]
Note that the VCI value = 256 to 65535 can be appropriately used by, for example, negotiating how to use it between end and end.
[0292]
Next, the timing of performing the datagram transmission request ARP will be described. It is not always necessary to perform the datagram transmission request ARP when the datagram falls from the OS (operating system) in the ATM board (ATM communication board). That is, when a datagram to be transmitted is generated, the datagram is made to wait on an ATM board or an arbitrary memory, a datagram transmission request ARP is performed, an address resolution is performed, and an ATM address is found. It is not always necessary to take out a datagram from the ATM board or an arbitrary memory, convert the datagram into an ATM cell, add a resolved ATM address, and transmit the ATM cell. This is because the datagram is kept waiting while the ARP is being performed, which is a wasteful time from the viewpoint of transmitting the datagram. For a destination terminal that may transmit a datagram, it is considered that efficient datagram delivery can be performed by performing address resolution in advance.
[0293]
The timing at which the datagram transmission request ARP is performed is as follows when the node / IWU / terminal is booted (a network layer address at which the datagram transmission request ARP is to be performed is specified in the boot program, and for each of the network layer addresses, for example, A datagram transmission request ARP is performed by batch processing or the like).
[0294]
In addition, at the time of user login of the node / IWU / terminal (login program, that is, a program started at the time of login, a network layer address to which a datagram transmission request ARP is to be performed is specified. For example, a datagram transmission request ARP is performed by batch processing or the like).
[0295]
For example, in the former method, an address of an ATM connection for a datagram with an indispensable partner (for example, a NIS server, a file server, a network management server, a network server, etc.) for an arbitrary node / IWU / terminal is resolved, In the latter method, applications such as resolution of an address of an ATM connection for datagram between each user and a partner with which the user frequently performs datagram communication can be considered.
[0296]
Here, the address resolution of the ATM connection at the time of boot or login as described above is not limited to the datagram, that is, not limited to the datagram delivery request ARP, but may be performed for the connection setting request ARP. Caution must be taken.
[0297]
Further, in the present embodiment, the setting of the switch node (setting of the routing table for the VP routing) has been completed before performing the ARP from the description that “ARP is performed at the time of booting or logging in”. Presupposes that if an ATM cell is transmitted with an appropriate ATM address (VPI value), the cell can be transmitted to a desired destination terminal. For example, at the time of booting the terminal / IWU / node, the setting of the switch node is performed first, and then the ARP is performed.
[0298]
However, when the setting of the switch node (setting of the routing table for the VP routing) is not completed in advance, and the setting of the ATM connection using a call setting server or the like at the time of booting or logging in is performed. It should be noted that there is also a possibility.
[0299]
It should be noted that, as will be described later, when an ATM connection is set in advance at the time of booting, at the time of login, or the like, communication resources are not particularly limited. That is, the ATM connection established at the above stage is merely an ATM connection set in a table in the switch node without going through connection admission control and the like. It can be considered as a low-grade connection and does not overwhelm communication resources.
[0300]
The reason will be described below. In the present embodiment, the ATM connection in the ATM-LAN (including the ATM connection that extends between the ATM-LAN in some cases) includes an ATM connection that performs bandwidth management and an ATM connection that does not perform bandwidth management. . An ATM connection that performs bandwidth management is a connection that can perform communication while maintaining a certain communication quality (QOS) (a connection that can expect a cell loss rate of a certain level or more and a delay time of a certain level or less), and does not perform bandwidth management. The ATM connection is a connection without any guarantee in the communication quality (there is no restriction on the cell discard rate and the delay time). An ATM connection that performs bandwidth management is considered a high-priority connection, and an ATM connection that does not perform bandwidth management is considered a low-priority connection. For example, only when there is no cell belonging to a high-priority connection, a low-priority connection is considered. This can be realized by performing priority control such as permitting passage of cells belonging to the connection. Regarding the ATM connection for performing the bandwidth management, the setting is permitted only when the cell transmission path through which the connection passes and the communication resources in the switching node are secured, but the bandwidth management is not performed. Since the ATM connection is not subject to the band management, the call / connection admission control is unconditionally accepted as long as the number is equal to or less than the maximum number of receptions of each connection management entity. The maximum number of receptions is defined, for example, by the capacity of a table in the switch node. For the ATM connection for performing the bandwidth management, a "bandwidth management server" is particularly provided (not shown), which is an evaluation function for the centralized management of the communication resources in the ATM-LAN and the admission control. , Etc. are performed. Only the ATM connection authorized by the bandwidth management server can be used as an ATM connection for performing bandwidth management.
[0301]
Next, FIG. 28 shows an embodiment of an ATM connection connection state between CLSF processing units in an inter-network connection device in an ATM backbone network. Here, for the sake of simplicity, each physical wiring and the like are omitted. In addition, other functions such as a call processing function and a header conversion function in the inter-network connecting device, a switch node in the ATM-LAN, and a component in the ATM backbone network are omitted in the figure (actually, these are omitted). An ATM connection may be established from the switch node in the ATM-LAN to the CLSF processing unit in the network connection device.
[0302]
Thus, in the ATM backbone network, the CLSF processing units in the inter-network connecting device are connected by, for example, a permanent connection (VP or VC). This permanent connection is also a connection that is not subject to band management. Datagrams that cross the ATM backbone network (or to terminals / nodes existing in the ATM backbone network) are relayed by these CLSF processing units. That is, the CLSF processing unit in the network connection apparatus terminates this once in the network layer or the CL layer, analyzes the destination address, and (if necessary, converts it into an ATM cell again) to the destination. The connected ATM connection is appropriately selected and the datagram is delivered through this. As shown in FIG. 28, since the CLSF processing units in the network connection apparatus are connected by permanent ATM connections, the CLSF processing units transmit the datagrams (ATM cells) through these permanent ATM connections. Is relayed to the CLSF processing unit in the next interworking apparatus.
[0303]
By arranging the CLSF processing unit in the inter-network connecting device as described above and distributing datagrams across networks via the CLSF processing unit in the inter-network connecting device, the following is achieved. You can enjoy the benefits.
[0304]
(1) The CLSF processing unit can be directly accessed from the network connected to the network connection device. This access can be performed without using an ATM connection that spans a plurality of networks.
[0305]
(2) For datagram delivery across ATM networks connected to the network connection device, processing is performed here, so that conversion of the address system (VPI / VCI value) in each network is centralized here. It can be carried out.
[0306]
(3) Routing information (information on a network layer address, a CL layer address, information on the relationship between the address and the VPI / VCI value, etc.) relating to the network connected to the network connection device is usually transmitted to the network connection device. Because the CLSF processing unit that performs analysis and processing of datagrams using the routing information is disposed in the interworking apparatus because it is terminated and exchanged, the routing protocol and the routing between the CLSF processing unit can be closely related. This is appropriate because the table can be shared.
[0307]
However, of the functions of the CLSF processing unit, after terminating a datagram (connectionless packet) and once referring to a network layer address, an appropriate ATM connection (VP / VC connected to a terminal / node having the network layer address, Alternatively, the function of sending to the VP / VC connected to the CLSF processing unit which is considered to have a function of delivering to the network layer address requires a large device as a function in the network, and the function of the CLSF processing unit is more than necessary. Is considered to lead to an increase in cost (over-spec). Therefore, in a large-scale ATM network as shown in FIG. 28, a CLSF processing unit is provided for each inter-network connecting device or for each ATM-LAN, between the respective ATM-LANs, or between the ATM backbone network and the external. This is considered to be the final form when the datagram communication volume with the network becomes sufficiently large.
[0308]
Therefore, an example of the development of the method of arranging the CLSF processing units in the large-scale ATM network will be described below. As described above, the arrangement of the CLSF processing unit in each network connection device as shown in FIG. 28 is considered to be the final form of this development. Hereinafter, the development of the method of arranging the CLSF processing units will be described in three phases.
[0309]
FIG. 29 shows a diagram at the time of initial introduction as phase 1. Thus, only one CLSF processing unit is provided in the ATM backbone network. Note that the CLSF processing unit may be located in any one of the inter-network connection devices or in any ATM-LAN. It is assumed that the CLSF processing unit has a sufficient throughput to process datagrams belonging to the large-scale ATM network (between networks) during the phase 1. Here, it should be noted that datagram communication between terminals in the ATM-LAN may be performed by an end-to-end ATM connection as described above.
[0310]
In this embodiment, the CLSF processing unit does not exist in every network connection device. However, in the network connection device, a routing protocol termination processing unit (hereinafter, referred to as a routing processing unit) operating in the large-scale ATM network. The network connection device in this phase 1 is the same as the CLSF processing unit in FIG. It should be noted that a routing processing unit is provided instead, or a routing processing unit is provided instead of the CLSF processing unit and the call processing unit in FIG. 2).
[0311]
Usually, the network connection device is in a position to obtain routing information about a network connected to the network connection device (or another network located further ahead of a network directly connected to the network connection device). For this reason, a routing protocol in a large-scale network may be operating in such a manner that routing information is exchanged between the network connecting devices. In this large-scale ATM network as well, the above-described routing protocol works, and each inter-network connecting device collects or exchanges routing information. In the present embodiment, the routing processing unit terminates the routing protocol.
[0312]
Of these, the exchange of routing information or the exchange of location information (where the terminal having an address is located) (operation of the routing protocol) may be performed by the delivery of datagrams between the internetwork connecting devices. An ATM connection for exchanging routing information may be provided between the network connecting devices, and if necessary, an ATM connection may be separately provided for each routing protocol to exchange routing / position information. In this way, the network connection device can obtain information on routing and position.
[0313]
In this phase 1, since the CLSF processing unit does not exist in the network connection apparatus, the address resolution method when the receiving terminal is in an ATM-LAN different from the transmitting terminal has been described above ( The results are slightly different from those of the methods I) and II. An embodiment will be described below.
[0314]
(Method I ′): Direct ARP between the transmitting terminal and the routing function in the IWU
Basically, it conforms to (Method I) except that it is the routing function in the network connection device that returns a response to the ARP request from the transmitting terminal.
[0315]
Since the routing processing unit in the network connection device has the routing information on the network to which the transmitting terminal belongs, it can determine whether the ARP request is closed to the ATM-LAN. . Therefore, if the ARP request is not closed within the ATM-LAN, that is, if it is recognized that the address to be address-resolved does not exist in the ATM-LAN to which the transmitting terminal belongs, the routing function is activated. Perform an ARP response. Here, as the ARP response, the VPI value assigned to the own network connection device is returned as in the case of the above (Method I). Therefore, from the viewpoint of the transmission side terminal, it cannot be determined whether or not the CLSF processing unit is located in the inter-network connecting device (hence, in the own ATM-LAN).
[0316]
(Method II '): When using an ARP server
According to (Method II). However, the ARP server may receive information on routing from a routing processing unit in the network connection device.
[0317]
However, in either of the methods (method I ') and (method II'), since the CLSF processing unit does not exist in the network connection apparatus, the routing processing unit converts the transmitted datagram into the CLSF data. It must be transferred to the processing unit. Hereinafter, this embodiment will be described.
[0318]
This is a method performed by appropriately setting the header conversion function in the network connection device. That is, when a datagram (actually, this is converted into an ATM cell) is sent to the internetworking apparatus (as described above, this is the VPI value assigned to its own internetworking apparatus and 8). Can be determined by the arrival of an ATM cell having a VCI value of .about.254), which is converted into an appropriate header (described later) using a header conversion table, and without termination by the network layer or CL layer, The cell is transferred to the CLSF processing unit only by the ATM processing. The setting of the header conversion table (header conversion unit) may be performed when ARP is performed for the first time, or may be performed in advance.
[0319]
In this case, since the CLSF processing unit needs to uniquely identify the transmitting terminal for each of the received cells ("identification" here means which terminal the transmitting terminal is, for example, a network layer address). Etc., but not "meaning that cells originating from different terminals (cells belonging to different connectionless packets)", and different ATM cell headers for each transmitting terminal. Note that it is necessary to assign a value.
[0320]
In the following, an example of an ATM cell header value assignment method that can uniquely identify a transmitting terminal in the CLSF processing unit will be described with reference to an example in which the "VP routing method" is applied to an ATM backbone network. .
[0321]
Also in the ATM backbone network, since the "VP routing method" is performed, at least one VPI value is assigned to the CLSF processing unit in the ATM backbone network, and the datagram ( The VPI value is assigned to the ATM cell (registered in the header conversion function). Therefore, the CLSF processing unit identifies the transmitting terminal based on the VCI value.
[0322]
As the VCI value, for example, as shown in FIG. 30, the first eight digits of the VCI value are the VPI value in the ATM-LAN of the transmitting terminal, and the last eight digits are the ATM backbone assigned to the network connection device. It is assumed that the VPI value on the network side is used. By doing so, the CLSF processing unit can uniquely identify the transmitting terminal from the ATM cell header of the received cell (since different VCI values are always used if the transmitting terminal is different). By registering such a VCI value in the header conversion function, the network connection device can transfer the datagram delivered across the network connection device to the CLSF processing unit using only the ATM layer processing. It becomes. By adopting such a method, the CLSF processing unit can support up to 64k (= 2 to the 16th) terminals.
[0323]
This rule can be applied not only to a two-layer network as in the present embodiment but also to a multi-layer network by appropriately devising the VCI field hierarchy.
[0324]
Here, in the ATM-LAN, since there is a possibility that the datagram destined for the network connection device itself is transferred to the CLSF processing unit in the above-described rules, the network connection device has a plurality of VPI values, for example, Given two of #X and #Y, when the resolution of the address of the internetwork connection apparatus itself is obtained by ARP, "VPI value = # X", and a receiving terminal that straddles the internetwork connection apparatus When the address resolution is obtained, “VPI value = # Y” is answered as an ARP response, and when “VPI value = # X”, the datagram is taken into the connection device between own networks. When "VPI value = # Y", it is determined that the datagram is not a datagram addressed to the own network connection device, the header is converted by the header conversion function, and the cell is transferred to the CLSF processing unit. How to It is also possible.
[0325]
On the other hand, when a cell is received from the CLSF processing unit, it should be noted that the datagram may be transmitted to a terminal in the ATM-LAN after performing the reverse of the above processing.
[0326]
A specific example of the above exchange is summarized in FIG. Descriptions of switch nodes and the like are omitted. The ATM-LAN 311 and the ATM backbone network 312 are operated by the VP routing method, and the terminals 31A, 31B, 31C and the network connection device 31P in the ATM-LAN 311 are #A, #B, #C, #P, respectively. A VPI value has been assigned. VPI values #X and #Y are assigned to the CLSF processing unit 31X and the network connection device in the ATM backbone network 312, respectively.
[0327]
The terminal in the ATM-LAN 311 sends out a datagram (transformed into an ATM cell) delivered across the internetwork connecting device 31P with "VPI value = # P" as shown in the figure. As described above, the VCI value includes the VPI value assigned to itself and is transmitted (for example, “VCI value = # A” in the terminal 31A).
[0328]
The header conversion table (the side from the ATM-LAN 311 to the ATM backbone network) in the network connection device 31C is set as shown in the figure, and the datagram (which is obtained by converting the datagram into an ATM cell) is automatically converted to an ATM layer. It can be transferred to the CLSF processing unit only by processing.
[0329]
For example, since the above datagram goes to the CLSF processing unit, the VPI value is rewritten to #X, and the VCI value is
(1) For the last eight digits of the VCI value, the CLSF processing unit that has received the datagram (the ATM cell of the datagram) determines which network connection device the datagram has been transferred from. Therefore, the VPI value (= # Y in this case) of the network connection device is entered.
(2) The first eight digits of the VCI value contain the VPI value (= # A in this case) of the transmitting terminal in order to identify the transmitting terminal for each inter-network connecting device.
It is operated as follows.
[0330]
In this example, a cell reaching the CLSF processing unit has a VCI value other than 16 to 254 despite being a datagram, but basically only a datagram is transferred to the CLSF processing unit. Therefore, this is appropriate as an ATM cell header value assignment rule for the CLSF processing unit (that is, in this example, the CLSF processing unit in the ATM backbone network assigns a VCI value different from the VCI value assignment rule in the ATM-LAN). You are doing that). Note that a datagram directed to the CLSF processing unit itself can be recognized as "a datagram addressed to itself when the first eight digits of the VCI value are 0".
[0331]
On the other hand, in the datagram (which is converted into an ATM cell) from the CLSF processing unit to the network connection device, the VPI value is the VPI value of the network connection device (in this case, = # Y), and the VCI value is , The lower eight digits contain the VPI value assigned to the CLSF processing unit (= # X in this case), and the upper eight digits represent the VPI value of the receiving terminal (if the receiving terminal is the terminal 31B, #B).
[0332]
As for the header conversion unit (on the side from the ATM backbone network 312 to the ATM-LAN 311) in the network connection device, as shown in the figure, the ATM cell header value sent from the CLSF processing unit side, that is, the lower eight digits of the VCI value is used. By referring to this, it recognizes that this is a datagram sent from the CLSF processing unit, refers to the first eight digits of the VCI value, and uses this value as the VPI value of the cell transmitted to the receiving terminal. Here, as described above, the VPI value assigned in the ATM-LAN 311 is entered as the VCI value of the cell transmitted to the receiving terminal.
[0333]
If the ATM backbone network 312 does not include more than 200 inter-network connection devices (or ATM-LANs), the lower eight digits of the VCI value are further hierarchized into, for example, four digits and four digits, and the network is hierarchized. It is also possible to take a multi-stage configuration of the interconnection device.
[0334]
In this embodiment, the number of ATM-LANs connected to the network connection device is one. However, when the number of ATM-LANs connected to the network connection device is plural, the ATM One VPI value may be assigned to each ATM-LAN. In this case, in the ATM backbone network, the network connection device has a plurality of VPI values. If a plurality of VPI values (equal to the number of ATM-LANs connected to the interworking device) cannot be assigned to the interworking device, the CLSF processing unit and the header conversion unit of the interworking device may be unable to allocate a VPI value. Since it is necessary to determine which datagram (transformed into ATM cells) should be distributed to which terminal of which ATM-LAN, it is necessary to negotiate a logical allocation method of VCI values.
[0335]
Next, FIG. 32 shows a case where a CLSF processing unit is added as a phase 2. Thus, a plurality of CLSF processing units are provided in the ATM backbone network. Some of the CLSF processing units may be located in any of the inter-network connection devices or in any ATM-LAN. In such a case, for example, it is considered that the communication amount of datagrams in the present network increases, the throughput of the CLSF processing unit installed in phase 1 becomes insufficient, and the CLSF processing unit is added.
[0336]
It should be noted that also in this embodiment, the routing processing unit exists in the network connection device. In this phase 2, the address resolution method when the receiving terminal is in an ATM-LAN different from the transmitting terminal is the same as in phase 1. However, since the CLSF processing unit has been added, in the header conversion function in some of the inter-network connecting devices, the transfer destination of the datagram (in the form of an ATM cell) is changed in order to change the transfer destination of the datagram (the ATM cell is converted) to the additional CLSF processing unit. The header rewriting table is rewritten so as to be converted into an ATM connection header (ATM cell header) connected to the section. It should be noted that the CLSF processing unit can be added (deleted or changed in some cases) only by this rewriting, so that the CLSF processing unit can be added or removed very easily.
[0337]
In this case, it is not necessary for the transmission side terminal (reception side terminal) in the ATM-LAN to recognize any change in the inter-network connection device (such as a change in the setting of the header rewriting table) due to the addition of the CLSF processing unit. You need to be careful. The transmitting terminal can perform communication using the address resolution and the datagram in exactly the same manner as in phase 1. This is the same not only in phase 2 but also in phase 3 described later. By repeatedly performing the addition (or note that the CLSF processing unit may be switched or changed) as in the phase 2, the CLSF processing unit is arranged in all inter-network connection devices as shown in FIG. (Phase 3). Here, when a CLSF processing unit is added in the network connection device, a CLSF processing unit may be added instead of the routing processing unit, or the CLSF processing unit may be provided in a state where the routing processing unit is arranged. The part may be added. This is done only by changing the settings of the header conversion table (header conversion unit) and the add / drop processing unit (if the distribution of cells in the network connection apparatus is performed by the ATM switch function, the switching function). It should be noted that the number of CLSF processing units can be increased and decreased very easily.
[0338]
Here, it should be noted that the ATM connection between the network connection device and the CLSF processing unit and the ATM connection between the CLSF processing unit and each terminal may be an ATM connection that does not perform band management.
[0339]
Next, returning to FIG. 28, the “ARP between CLSF processing units” will be described. In FIG. 28, when the CLSF processing unit delivers a datagram, which PVC / PVC of the permanent ATM connection (PVC, PVP) to the CLSF processing unit in the inter-network connection device set up in the ATM backbone network. There are times when it is necessary to make a selection as to whether to send to PVP. That is, the destination address of the analyzed datagram (which may be a network layer address or a mail address) is stored in a table inside the CLSF processing unit (in the case of this destination address, an instruction to send the datagram to this PVC / PVP is written. If the datagram has not been registered in the table, resolution is performed on which PVC / PVP the datagram should be sent from the destination address. This is referred to herein as “CLSF processing unit ARP”. There are several methods for performing the “ARP between CLSF processing units” as follows.
[0340]
(Method 1): Method using ARP server
This is a method similar to (method 2) of ARP for datagram delivery in the ATM-LAN of the first embodiment. An ARP server is placed in the ATM backbone network (not shown). This ARP server has a table inside, and this table corresponds to the destination address and the VPI / VCI value. This VPI / VCI value is stored in a PVC / CLSF processing unit in another network connection device (in some cases, a CLSF processing unit in an ATM backbone network, which is responsible for a terminal device in the ATM backbone network). It is the VCI / VPI value of PVP. FIG. 33 shows one embodiment of the outline of the table. As described above, there are as many tables as the number of CLSF processing units, and each table corresponds to an inquiry from one CLSF processing unit. The ARP server having received the inquiry analyzes the VPI / VCI value corresponding to the destination address with reference to the table, and returns the analysis result (VPI / VCI value) to the CLSF processing unit of the inquiry source.
[0341]
Here, in a system in which the ATM backbone network assigns one VPI to a terminal / node inside the ATM backbone network and performs routing of cells in the ATM backbone network using the VPI, the VPI value to be assigned by the destination address is uniquely determined. Since the determination is made, there is no need to prepare a table for each destination address, and only one table need be prepared, so that a large amount of tables can be reduced. In this case, when sending a datagram or ARP, for example, the first eight digits of the VCI value are all 0 (this is used as a datagram delivery mark. That is, in the network connection device, the first eight digits of the VCI value are set). The cells of all 0 are transferred to the CLSF processing unit), and the lower 8 digits are filled with the VPI value of the interworking apparatus to which the source CLSF processing unit belongs, and the CLSF processing unit that has received this transmits the cell. The origin can be known, and the datagram delivery processing can be continued. When returning the ARP, if the VPI of the transmission source CLSF processing unit included in the VCI area is used, the ARP reply can be performed without using the broadcast. If the CLSF processing unit does not need to know the transmission source CLSF processing unit, the operation of putting the VPI of the interworking apparatus to which the transmission source CLSF processing unit belongs into the last eight digits can be omitted.
[0342]
The other points are almost the same as the method (method 2) described for the ARP to the CLSF processing unit in the ATM-LAN in the first embodiment.
[0343]
(Method 2): Direct ARP between CLSF processing units in ATM backbone network
This is a method in which ARP is performed directly in the ATM backbone network to another CLSF processing unit in the inter-network connection device or in the ATM backbone network. That is, the CLSF processing unit on the side that performs ARP (that is, the side that asks for the VPI / VCI value) broadcasts an ARP request to other CLSF processing units, or a method similar to the broadcast (for example, listening in turn). This is a method in which the corresponding CLSF processing unit notifies the VPI / VCI value addressed to itself by responding to this.
[0344]
This is because one VPI is allocated to each node / inter-network connection device in the ATM backbone network, and in a system in which routing in the backbone network is performed using the VPI (VP routing system), the VPI value of the own device and an appropriate VPI are used. This can be done by notifying a proper VCI value.
[0345]
When the CLSF processing unit that has received the ARP determines that this is the destination address to be in charge of itself, the VSF of the PVC / PVP connected between the own CLSF processing unit and the transmission source CLSF processing unit This can also be performed by notifying the / VCI value, and it is not always necessary to use the VP routing method.
[0346]
(Method 3): A method in which a table regarding all addresses is given to each CLSF processing unit in advance without using ARP.
If the overall network scale is not so large, a table for all addresses can be given to each CLSF processing unit in advance. The loading of this table may be performed, for example, when the CLSF processing unit is started.
[0347]
In this case, for a destination address not in the table, a transfer destination CLSF processing unit is determined by default, and the destination CLSF processing unit may be transferred to this destination. This default transfer destination CLSF processing unit has all the complete tables. It is also possible to adopt a configuration method such as
[0348]
After such “ARP between CLSF processing units”, the datagram is transferred (relayed) to the CLSF processing unit indicated by VPI / VCI, which is the result of the ARP, and is transmitted to the CLSF processing unit. Is again analyzed for the destination address and relayed to the ATM connection connected to the appropriate destination. The set of the destination address and the VPI / VCI value resolved by the “ARP between the CLSF processing units” may be stored in a table in the CLSF processing unit thereafter.
[0349]
With regard to the ATM backbone network, sufficient consideration must be given to addressing in order to realize efficient routing. For example, in order to facilitate the creation of a subnet mask, a network address having a large value is assigned to a physically close LAN or a LAN connected to a switch node in the same network connection device / ATM backbone network. It is.
[0350]
Also in this method, the advantage of the CLSF processing unit in the network connection device in the first and second embodiments can be enjoyed.
[0351]
Next, FIG. 34 shows the state of the ATM connection between the call processing unit in the network connection device and the terminal in the ATM-LAN, and the state of the ATM connection connection between the call processing units in the network connection device in the ATM backbone network. 1 illustrates one embodiment. Here, each physical wiring is omitted for simplicity. Further, other components such as a CLSF processing unit and a header conversion unit in the network connection device, a switch node in the ATM-LAN, and a component in the ATM backbone network are also omitted in the figure. Actually, the ATM connection may be established from the switch node in the ATM-LAN to the call processing unit in the network connection device.
[0352]
As described above, each terminal device in the ATM-LAN is connected to the call processing unit in the network connection device by an ATM connection (VP or VC). It should be noted that the ATM connection between the terminal device in the ATM-LAN and the call processing unit in the network connection device is not a connection over the network connection device as in the first and second embodiments. is necessary.
[0353]
In the ATM backbone network, the call processing units in the inter-network connecting device are connected by, for example, a permanent connection (VP or VC). It should be noted that this permanent connection is also an ATM connection closed in the ATM backbone network, and is not a connection that spans an inter-network connecting device.
[0354]
Further, by making the connection between the call processing units by a permanent ATM connection, it is possible to reduce the connection setup overhead generated every time processing information is transferred between the call processing units, and to make a call that crosses three or more networks. The / connection process can be always performed by relaying between the call processing units in the network connection device via the permanent ATM connection. Also, it is possible to easily monitor traffic used for call / connection processing.
[0355]
Hereinafter, when setting up an ATM connection from a terminal / node in the ATM-LAN (hereinafter, referred to as a transmitting terminal) to a terminal / node in another ATM-LAN (hereinafter, referred to as a receiving terminal). The process will be described.
[0356]
If a terminal device / node in the ATM-LAN wants to establish an ATM connection across the network connection device and the ATM backbone network, the call processing unit in the network connection device is used. Basically, it is the same as the first and second embodiments, but there are some differences.
[0357]
First, a description will be given of a case where only a simple connection connection (bandwidth management is unnecessary) is required.
[0358]
First, the point that a terminal / node (referred to as a transmitting terminal) in an ATM-LAN that issues an ATM connection setting request acts on a call processing unit in an inter-network connecting device is substantially the same as the first and second embodiments. Done in the process. Detailed description is omitted.
[0359]
Next, the call processing unit in the inter-network connecting device that has received the request searches the inter-network connecting device for the target address of the “connection setting request ARP”, and searches the network. The ARP is relayed to a call processing unit in the interconnection device. As shown in FIG. 34, since the call processing units in the network connection apparatus are connected by permanent ATM connections, the call processing units receive the connection setting request via these permanent ATM connections. Relaying is performed to the call processing unit in the network connection device.
[0360]
Here, to which PVC / PVP should be sent out of the permanent ATM connections (PVC, PVP) of the call processing unit in the inter-network connecting device which is set up in the ATM backbone network. Sometimes you need to do. In other words, the destination address of the analyzed connection connection request (which may be a network layer address or a mail address) is stored in a table inside the call processing unit (in the case of this destination address, it is sent to this PVC / PVP, and this call processing unit If the connection request is not registered in the table in which the instruction to perform the relaying is written), resolution is performed to which PVC / PVP the connection request should be transmitted from the destination address. This is referred to herein as "inter-call processing ARP".
[0361]
There are several methods for performing the “ARP between call processing units” as follows.
[0362]
(Method 1): Method using ARP server
This is almost the same as the case of the ARP server in the CLSF processing unit in FIG. 28, except that the VPI / VCI value in the table inside the ARP server is different from the call processing unit (in some cases, Call processing unit in the ATM backbone network, which is responsible for the terminal device in the ATM backbone network), which is the VCI / VPI value of PVC / PVP. This table can be easily shared with the table used in the CLSF processing unit.
[0363]
(Method 2): A method of performing ARP directly between call processing units in an ATM backbone network
In this method, ARP is performed directly in the ATM backbone network to other call processing units in the inter-network connection device or in the ATM backbone network. Since it can be realized by a method substantially similar to (method 2) in the CLSF processing unit shown in FIG. 28, the details are omitted.
[0364]
(Method 3): A method in which a table regarding all addresses is given to each call processing unit in advance without using ARP.
As in the case of the CLSF processing unit, when the overall network scale is not so large, a table relating to all addresses can be given to each call processing unit in advance. The loading of this table may be performed, for example, when the call processing unit is started. Further, the table can be easily shared with the CLSF processing unit. Details are almost the same as those in the case of the CLSF processing unit, and thus description thereof is omitted.
[0365]
In this case, for a destination address that is not in the table, a transfer destination call processing unit may be determined by default and transferred to this destination. The default transfer destination call processing unit may adopt a configuration method such as having all the complete tables.
[0366]
After such “ARP between call processing units”, the connection setting request is transferred (relayed) to the call processing unit indicated by VPI / VCI, which is the result of this ARP, and delivered to the call processing unit. In the connection setting request, the destination address is analyzed again, and the same operation as that of the call processing unit in charge of the receiving terminal in the first and second embodiments is performed. The set of the destination address and the VPI / VCI value resolved by the “ARP between call processing units” is thereafter stored in a table in the call processing unit.
[0367]
The above-described processes are not limited to connection setting requests, but are performed in substantially the same manner when connection setting / disconnection / change requests are made.
[0368]
Note that a permanent ATM connection is not established between the call processing units in the network connection device, and a permanent ATM connection / ATM connection is established between the call processing units each time a connection setup / disconnection / change request is made. , ARP can be exercised throughout the ATM backbone network.
[0369]
Also, when performing bandwidth management for the ATM connection over the ATM backbone network, that is, when obtaining an appropriate QOS for the ATM connection, the first and second embodiments are followed. Omitted.
[0370]
Also in this method, the advantages of the call processing unit in the network connection device in the first and second embodiments can be enjoyed.
[0371]
It should be noted that in the case of the call processing unit, similarly to the case of the CLSF, the call processing unit can be gradually increased / decreased / changed as shown in FIGS. 29, 32, and 28. In the same manner, such a change can be dealt with only by a simple change of the table in the IWU. It should be noted that this is not limited to the CLSF and the call processing unit, but is generally applicable to any server.
[0372]
Next, FIG. 35 shows another embodiment of the method of arranging the call processing units in the large-scale network. In the example of FIG. 35, a call processing unit 351 is arranged in the ATM backbone network. The number of call processing units in the ATM backbone network is not necessarily one, and may be distributed and arranged (either load distribution or function distribution). When the call processing unit in the network connection apparatus desires an ATM connection across the ATM backbone network, the call processing unit 351 relays the connection connection request. Here, as shown in FIG. 35, the call processing unit in the network connection device and the call processing unit 351 in the ATM backbone network are connected by a permanent ATM connection. It should be noted that this permanent ATM connection is not a connection over an inter-network connection device, but is closed within an ATM backbone network. The call processing unit 351 collectively performs setting, disconnection, management, and the like of the ATM connection in the ATM backbone network. The call processing unit 351 sets / connects the ATM connection that traverses the ATM backbone network between the inter-network connecting devices. Disconnect / change. The call processing unit in the inter-network connecting device couples the ATM connection in the ATM-LAN with the ATM connection between the ATM backbone networks by appropriately setting a header conversion unit, and controls the ATM connection across the ATM backbone network. I do.
[0373]
A similar operation is used when controlling an ATM connection between a terminal / node in the ATM-LAN and a terminal / node in the ATM backbone network.
[0374]
Also, by arranging the call processing units in such a manner, it should be noted that only the call processing unit 351 in the ATM backbone network needs to hold the configuration information relating to the ATM-LAN connected to the ATM backbone network. is necessary. Here, it can be said that the call processing unit in the network connection device has a multiplexing function to the call processing unit 351 in the ATM backbone network.
[0375]
Now, when performing ARP (address resolution from network layer address to ATM address = VPI value) as described above, where the entity performing the ARP is located on the transmitting terminal (node / IWU / terminal). Regarding whether to do so, there are several cases. Hereinafter, each case will be described. Here, the term “ATM board” is used, which is a communication expansion board of a terminal device that performs communication using the ATM communication system, and is a board (substrate) having an ATM interface and a terminal internal bus interface.
[0376]
First, the ARP request will be described.
[0377]
(Case 1): When the ATM board autonomously makes an ARP request.
[0378]
In this case, a datagram to be transferred is received from a host (for example, OS) via the terminal internal bus interface. This datagram is a network layer datagram (for example, an IP datagram). Therefore, the network layer address of the transfer destination is notified to the ATM board from the upper level (in a form stored in an appropriate area of the network layer datagram).
[0379]
At the same time, information on a MAC address different from that of the ATM system may be transferred to the ATM board. This is considered when the ATM board is used as a communication board without making any changes to the settings of the OS or the device driver in place of the Ethernet board of the existing terminal (for example, UNIX / TCP / IP + Ethernet). Is a situation. That is, in the above example, the OS does not recognize that the communication board is an ATM board, but recognizes that the communication board is an Ethernet board.
[0380]
In this example, since the function of the ARP request is provided in the ATM board, the network layer address and the ATM address (the ATM cell header value including the VPI value in the present embodiment and the VPI / VCI value in the general case) are used. ) Exists on the ATM board. If the resolution of the ATM address has not been completed for the destination address of the datagram received from the host, the ATM board autonomously makes an ARP request.
[0381]
The ARP may be such that a processor or the like mounted on the ATM board generates the ARP request cell in software / firmware, or may be generated by dedicated hardware on the ATM board. The generated ARP request cell is transmitted to the ATM-LAN in the manner described above. During the ARP, the datagram waits in the memory on the ATM board. During this time, the ATM board may be performing processing relating to the datagram sent from the host following the datagram, or converting the datagram into an ATM cell.
[0382]
When the ARP response is returned, the ATM address (VPI value) described in the response is used as an ATM cell header, an ATM cell header is generated according to the above rule, and the datagram (transformed into an ATM cell) is converted to an ATM-LAN. Send to.
[0383]
At the same time, the ATM address subjected to the address resolution is registered in the ARP table in the ATM board. By this registration, the datagram to the next same destination can be converted from the network layer address to the ATM address without performing the address resolution.
[0384]
The conversion from the network layer address to the ATM address may be performed by a processor or the like mounted on the ATM board in terms of software / firmware, or by dedicated hardware on the ATM board. good.
[0385]
The conversion table between the network layer address and the ATM address registered in the ARP table may be deleted if it is not used for a certain period of time. This is a method that can be applied when deciding data to be deleted when there is a limit to the size of the ARP table and there is data to be newly registered.
[0386]
(Case 2): When an ARP request program is running as an OS program in the terminal or a device driver.
[0387]
In this case, it is the program in the terminal that makes the ARP request. The activation of this ARP
(1) When there is a correspondence table between a network layer address and an ATM address in the ATM board, and the ATM board which needs an ARP request due to the appearance of a network layer address that does not exist in the correspondence table starts the ARP program.
(2) There is a correspondence table between the network layer address and the ATM address on the OS or device driver side, and the appearance of the network layer address that does not exist in the correspondence table allows the OS or device driver to autonomously recognize the necessity of the ARP request, When starting the OS ARP request processing program or the device driver ARP request processing program
There are two cases. In the case of (2), a correspondence table between the network layer address and the ATM address may exist in the ATM board.
[0388]
There are several cases for the operation of the ARP processing program,
(A) The ARP request processing program autonomously generates an ARP request cell or “payload of the cell (that is, content that indicates that it is an ARP request) + information that informs the ATM board that the information is ARP”. Then, it notifies the ATM board. The ATM board sends the above information as an ARP to the ATM-LAN. That is, the ARP processing program has the ability to generate ARP information.
(B) The ARP request processing program issues an instruction to the ATM board that "perform an ARP request for the network layer address". The ATM board generates an ARP request cell and sends it out to the ATM-LAN.
[0389]
There are two cases.
[0390]
Furthermore, there are several cases where the ATM board can respond to the ARP response,
(I) On the ATM board, there is a correspondence table between the network layer address and the ATM address in the ATM board, and the ATM address of the resolution result is registered in the correspondence table.
(Ii) There is a correspondence table between the network layer address and the ATM address on the OS or device driver side, and the ATM address of the resolution result is registered in the correspondence table.
(Iii) Both the ATM board and the OS or device driver have a correspondence table between the network layer address and the ATM address in the ATM board, and register the ATM address of the resolution result in both correspondence tables.
There are three cases.
[0391]
Here, in (iii), the correspondence table on the ATM board may be a cache of the correspondence table of the OS or the device driver. That is, only a part of the data in the correspondence table held by the OS or the device driver is described. Various methods such as a FIFO method and a round robin method can be considered as a selection method of how to describe a part.
[0392]
Next, the ARP response will be described.
[0393]
(Case A): When the ATM board autonomously makes an ARP response.
[0394]
This is a case where the ATM board which has received the ARP request from the ATM interface side autonomously detects the ARP request addressed to itself and makes an ARP response to the ARP request addressed to itself.
[0395]
FIG. 36 shows an example of an ATM board that performs such processing. This ATM board includes an ATM interface 361, an ARP filter unit 362, an ARP processing unit 363, an insertion unit 364, and a bus interface unit 365. The ATM interface 361 has a function of interfacing the ATM board with the ATM-LAN.
[0396]
The ARP filter unit 362 has a function of extracting an ARP cell from the cells flowing on the input transmission line and dropping the ARP cell to the ARP processing unit 363. Further, a function of inserting an empty cell into a cell slot that has become empty after dropping may be further provided.
[0397]
The ARP processing unit 363 analyzes the ARP cell sent from the ARP filter unit 362 and checks whether the ARP cell is an ARP cell addressed to itself by analyzing a destination address. In this case, it has a function of discarding the cell, generating an ARP response cell if the cell is an ARP cell addressed to itself, and transmitting the ARP response cell to the insertion unit 364. The processing of the ARP processing unit may be performed by hardware logic, or may be processed by software or firmware by a processor or the like.
[0398]
The insertion unit 364 appropriately multiplexes the ARP response cell transmitted from the ARP processing unit 363 and the cell transmitted from the bus interface unit 365, and the ATM-LAN side has a function of transmitting the cell.
[0399]
The bus interface unit 365 has a function of interfacing the ATM board with the bus inside the terminal.
[0400]
Here, in FIG. 36, only representative ATM cell transfer paths are indicated by arrows. Actually, the host CPU or the like accesses each other via the terminal internal bus with each module, for example, notifies the ARP processing unit of the network layer address of the terminal device, exchanges error notification, etc. There is a control line for realizing the above function.
[0401]
The ARP request cell arriving at the ATM board is dropped by the ARP filter section 362 to the ARP processing section 363 side. If the ARP cell is addressed to itself (for the terminal on which the ATM board is mounted), the ARP processing section 363 , An ARP response cell is generated and transmitted to the ATM-LAN side via the insertion unit 364. At this time, if there is a correspondence table between the network layer address and the ATM address in the ATM board, the information (specifically, the transmission source address) included in the ARP request cell is used and transmitted to the correspondence table. Information included in the original address (corresponding information between the network layer address of the transmission source terminal and the ATM address) may be registered.
[0402]
If a correspondence table between the network layer address and the ATM address exists in the OS or the device driver, the OS (registering information on the correspondence between the network layer address of the transmission source terminal and the ATM address) is registered. Alternatively, the information may be notified to the device driver side.
[0403]
As can be understood from the above description, the ARP request and the response are both performed by the ATM board or software (that is, by the OS or the device driver), and the "ARP request is performed by the software (that is, the OS It is also necessary to note that the device driver may perform the ARP response by the ATM board.
[0404]
(Case B): When the OS program or device driver in the terminal makes an ARP response.
[0405]
In this case, it is the program in the terminal that makes the ARP response. The activation of this ARP response program
(1) When the ATM board recognizes the arrival of the ARP request cell addressed to itself and notifies the OS or the device driver side.
(2) The ATM board transfers the ARP request cell and other cells to the OS or the device driver without distinction, and the OS or the device driver recognizes the arrival of the ARP request cell addressed to itself, and When starting the ARP response processing program or the ARP response processing device driver.
There are two possibilities.
[0406]
There are several cases of the operation of the ARP response processing program,
(A) The ARP response processing program autonomously generates an ARP response cell or “payload of the cell (that is, the content of the ARP response) + information that informs the ATM board that the information is an ARP response”, Notify the board. The ATM board sends the information as an ARP response cell to the ATM-LAN. That is, the ARP processing program has the ability to generate ARP response information.
(B) The ARP response processing program issues an instruction to the ATM board that "perform an ARP response for the network layer address (and ATM address)". The ATM board generates an ARP response cell and sends it out to the ATM-LAN.
[0407]
In the third embodiment, the "VP routing method" is used as an example of the cell routing and addressing method in the ATM-LAN or the ATM backbone network. It should be noted that the application is not limited to the VP routing system, but can be applied to a general ATM communication system.
[0408]
For example, instead of the "VP routing method", a processing unit such as a call processing server sets an end-end ATM connection every time a connection connection request is made (the ATM cell header may be rewritten during cell transfer). ATM-LAN or ATM backbone network of a method for performing end-to-end communication (hereinafter also referred to as a call processing server method), or "ATM-LAN is operated by a VP routing method, and the ATM backbone network is a call system. A large-scale ATM network operated by a processing server system, and conversely, a large-scale ATM network operated by a VP routing system for an ATM backbone network and a call processing server system for an ATM-LAN. VP routing method in some ATM-LANs, call processing in some ATM-LANs As such over bus system, even in an ATM network in which various schemes are mixed, various methods of the present invention are possible easily applied.
[0409]
In the present embodiment, the datagram delivery method in the ATM-LAN or the ATM backbone network has been described. However, the present invention is not limited to the ATM-LAN or the ATM backbone network. It should be noted that the present invention can be easily applied to a LAN or a subnetted ATM backbone network.
[0410]
Further, the inter-network connection devices in the first, second, and third embodiments described above can be considered to belong to any ATM-LAN or ATM backbone network. It is also possible to consider that the network connection device belongs to all connected networks.
[0411]
Further, the network connection device in the embodiments described so far may be a form in which an extension unit / extension board is added to a computer (workstation or the like), or may have a structure integrated with the computer. . In this case, the CLSF processing unit, the call processing unit, and the IWU management unit may be configured to be realized by the CPU of the computer.
[0412]
(Fourth embodiment)
Next, an embodiment relating to datagram communication within a sub-network will be described. Here, the case of a general ATM network, Ezaki, Tsuda, and Natsahori: "Method for Realizing Data Transfer in ATM-LAN", as described in IEICE (Information Network Research Group, March, 1993) Various VPI routing methods will be described.
[0413]
(Embodiment 4-1) A case where datagram communication inside a sub-network is applied to a general ATM network.
[0414]
FIG. 40 shows an embodiment of the present invention. When a datagram transmission request is issued to the terminal (TE) 411, the terminal 411 uses the ATM connection 41A to send an address resolution server (hereinafter referred to as ARS) 413 to the target. Request to acquire an ATM address (AR request) in order to transfer a datagram to this terminal. This address acquisition request is always made when a datagram transfer request occurs, or only when there is no address information of the destination terminal in the address resolution table stored in the terminal 411 (see FIG. 42). is there. In the latter method, if the address already exists in the AR table, there is no need to execute the AR request and AR response procedures.
[0415]
The ARS 413 notifies the terminal 411 of the VCI / VPI information (VCI / VPI information to be added by the terminal 411), which is the identifier of the ATM connection for transferring the datagram to the destination terminal 412, using the ATM connection 41B (AR Response). The terminal 411 that has received the AR response adds the notified VCI / VPI and inputs the datagram to the network. The datagram is delivered directly to the terminal 412 through the ATM connection 41C. In the case of this embodiment, it is necessary that an ATM connection be set up between all terminals in the sub-network in a full mesh state.
[0416]
FIG. 42 is a flowchart illustrating an example of a protocol executed by the transmitting terminal (the terminal 411 in this example). This is an example of a case where the transmitting terminal can cache the destination address information. In step 432, a cache table for address resolution in the terminal is searched. If there is no information on the destination terminal 412 in the cache entry, an AR response is sent to the ARS 413.
[0417]
FIG. 41 shows data exchange between the terminals 411 and 412 and the ARS 413. This is an example in the case where the address resolution cache entry of the terminal 411 has no information of the destination terminal 412. The AR request 41A and the AR response 41B can be realized by a point-to-point ATM connection, but can also be realized by using a broadcast channel.
[0418]
FIG. 43 shows another embodiment. The CLSF 414 executes the actual datagram transfer. When a datagram transfer request is generated in the terminal 411, the terminal 411 performs resolution of ATM connection information for transferring the datagram to the target terminal 412. When the terminal 411 does not have the ATM connection information for transferring the datagram to the destination terminal 412, that is, when there is no entry in the cache table, the address resolution is performed using the ATM connection 41A (AR request). ).
[0419]
When the destination terminal is a terminal in the own sub-network, the ARS 413 replies to the terminal 411 with ATM layer address information for the terminal 411 to transfer a datagram to the CLSF 414 (AR response). An embodiment in which a terminal to which a datagram is to be transferred belongs to a network other than the own subnetwork will be described in the next subsection and thereafter.
[0420]
The terminal 411 that has completed the address resolution adds an appropriate VCI / VPI (a cache table or VCI / VPI information acquired by an AR response) to a cell for transferring a datagram and inputs the cell to the network. The VCI / VPI is an identifier of the ATM connection 441, and the cell is transferred on the ATM connection 441 and reaches the CLSF 414. The CLSF 414 analyzes the address information of the received datagram, adds a VCI / VPI for transferring the datagram to the destination terminal 412, and inputs the cell to the network. The inserted cell reaches the terminal 412 using the ATM connection 442. In the case of the present embodiment, a star-shaped ATM connection needs to be set between the CSLF 414 and each terminal. Note that the AR request and the AR response can be made using a broadcast channel instead of a point-to-point ATM connection.
[0421]
The address resolution procedure performed by the ARS 413 may be performed by searching for address space information (address mask) of the network. As described below, the ARS 413 only needs to analyze which network address space the terminal exists in the external network. The ARS 413 does not necessarily include VCI / VPI information for directly accessing the destination terminal via the ATM connection. There is no need for resolution.
[0422]
FIG. 44 shows a procedure for data transfer. Here, as for the transfer of datagrams from the terminal 411 to the CLSF 414, the case where the entire datagram is once taken into the CLSF 414 and then transferred collectively to the terminal 412 is shown. It is also possible to do it.
[0423]
(Embodiment 4-2) A case where VPI routing is applied to datagram communication inside a subnetwork.
[0424]
It is assumed that a VPI is assigned to each network element as shown in FIG. Each terminal / server is equivalent to setting up a multipoint-to-point ATM connection from every UNI point in the subnetwork. That is, when the terminal puts a cell with the VPI of the destination terminal into the network, the cell is transferred to the target UNI point. For example, to transfer a cell to ARS 413, VPI₄₁₃May be added.
[0425]
The method described with reference to FIG. 40 uses the connections 46A, 46B, and 46C. The terminal 411 is a VPI₄₁₃Is transferred to the ARS 413 with the VPI information as the VPI information. At this time, the ARS 413 can recognize that the received cell is a cell transmitted from the terminal 411, using the VCI information or the identifier of the upper layer. For example, in the VCI field, the VPI₄₁₁By writing, the ARS 413 can recognize that the received cell is from the terminal 411 by referring to the ATM header. Also, the VCI information can be an identification number that explicitly indicates that the cell is an AR request cell for datagram communication.
[0426]
The ARS 413 that has performed the address resolution of the terminal 412 stores VPI = VPI in the AR response cell.₄₁₁Is written to the terminal 411 to the network. Similarly to the ARS 413, the terminal 411 uses at least one of the VCI information and the header information of the upper layer to recognize that the received cell is an AR response. In the AR response cell, VPI which is access address information of the terminal 412 is included.₄₁₂Is written at least.
[0427]
The identification information for identifying that the cell for datagram transfer received by the terminal 412 has been transferred from the terminal 411 is VCI information or header information of an upper layer. It is also possible to notify the terminal 411 as information written in the response. The easiest way to identify the source and the cell type by the receiver is to use the above-mentioned procedure to set the VCI field information to 8 bits for the source VPI information and the last 8 bits for the cell type. The method of showing is possible.
[0428]
As a coding method of the VCI field (16 bits) of the cell to be transferred to the terminal 411 and the terminal 412, the following method is available.
[0429]
Example 1: 8 bits are the access address of the terminal (the same number as the VPI number), and the remaining 8 bits are identification numbers indicating that connectionless communication is performed.
Example 2: 8 bits are access address of own terminal, and remaining 8 bits are identification number of own network. However, at this time, each terminal needs to acquire the VPI for connectionless communication separately from the VPI for connection-oriented communication (a different VPI is used for CL and CO).
[0430]
Example 3: 16 bits are set when the terminal is booted. It is also possible for the receiving terminal to make an appropriate assignment.
[0431]
The method described with reference to FIG. 43 uses the connections 46A, 46B, 46D, and 46E. The terminal 411 is a VPI₄₁₃Is transferred to the ARS 413 with the VPI information as the VPI information. The ARS 413 that has performed the address resolution of the terminal 412 stores VPI = VPI in the AR response cell.₄₁₄Is written, and the cell (AR response) is input to the network. The AR response cell includes VPI, which is access address information of CLSF414.₄₁₄Is written at least. The information for identifying that the cell for datagram transfer received by the CLSF 414 has been transferred from the terminal 411 is VCI information or header information of an upper layer, and the ARS 413 stores this identification information in the AR response. May be notified to the terminal 411 as information written in the terminal 411. The CLS 414 analyzes the address information of the received cell, and transmits VPI = VPI to transfer the datagram cell to the terminal 412.₄₁₂Is added to the cell to put the cell into the network. The cell is transferred to the terminal 412 through the ATM connection 46E.
[0432]
Five specific examples in the present embodiment are shown below.
[0433]
(1) The CLSF 414 performs resolution of the access address of the receiving terminal. The CLSF 414 analyzes the address of the destination terminal based on the network layer address written in the received datagram (or an address of another layer is also possible). At this time, the datagram is once reassembled by the CLSF 414.
[0434]
(2) The CLSF 414 performs resolution of the access address of the receiving terminal. The CLSF 414 analyzes the address of the destination terminal based on the network layer address written in the received datagram (or an address of another layer is also possible). At this time, the datagram is not once reassembled by the CLSF 414, and the cells are relayed by pipeline processing. That is, the address information written in the first cell of the datagram is analyzed to analyze the access address of the destination terminal, and the cells subsequent to the first cell are rewritten to VPI / VCI based on the VCI information and transmitted to the destination terminal. Relaying. The CLSF 414 needs to assign a different VCI for each datagram.
[0435]
(3) The transmitting terminal resolves the access address of the destination terminal and writes this in the payload of the first cell. Upon receiving the first cell, the CLSF 414 reads the information of the payload section of the first cell and uses this to transfer the cell to the destination terminal. At this time, the datagram is once reassembled by the CLSF 414.
[0436]
(4) The transmitting terminal resolves the access address of the destination terminal and writes this in the payload of the first cell. Upon receiving the head cell, the CLSF 414 reads the information of the payload part of the head cell, and uses this to transfer the cell to the destination terminal. At this time, the datagram is not once reassembled by the CLSF 414, and the cells are relayed by pipeline processing. In other words, the access address of the destination terminal is analyzed by analyzing the address information written in the first cell of the datagram, and the cells subsequent to the first cell are rewritten with VPI / VCI based on the VCI information to change the destination terminal. Relaying to The CLSF 414 needs to assign a different VCI for each datagram.
[0437]
(5) The transmitting terminal resolves the access address of the destination terminal, and transfers this to the CLSF 414 using the VCI field. That is, for example, 8 bits of the VCI are set as the access address of the destination terminal, and the remaining 8 bits are set as the access address of the source terminal. The CLSF 414 copies the address of the destination terminal in the VCI field and relays the cell to the destination terminal. The relaying includes a method of once reassembling a datagram and a method of relaying cells in a pipeline.
[0438]
(Fifth embodiment)
Next, as an embodiment relating to datagram transfer to an external network, a case where a two-layer network is used will be described.
[0439]
(Embodiment 5-1) Case of Using General ATM Network—Part 1
[0440]
FIG. 46 shows a schematic diagram of the network architecture of the present embodiment. This network is composed of a two-layer network. Each of the networks 471 to 475 is internetworked via an IWU (Internetworking Unit) 476 to 479. The network 471 and the public network 475 are connected via the IWU 479. The IWUs 476 to 479 can realize the relaying of the ATM cell without terminating the ATM connection. That is, it has a function of converting the VCI / VPI of the received cell into the VCI / VPI assigned to the corresponding ATM connection in the adjacent network.
[0441]
FIGS. 47 and 51 show the setting of the ATM connection related to the address resolution. Each of the ARSs 481 to 484 manages at least address information of terminals or networks accommodated in the networks 471 to 474 to which each ARS belongs. FIG. 48 shows the settings of the ATM connections 496, 497, 498, and 49B required to transfer a datagram from the network 472 to the other networks 471, 473, 474, and 475. An ATM connection (one-way ATM connection) from the IWU 476 to the CLSF 491, 493, 494 is set. Further, an ATM connection 49B (a bidirectional ATM connection is normally defined) to the CLSF in the public network 475 is set. Note that the same connection is set for other sub-networks. The location where the CLSF and ARS are located can also be located at the location of the IWU. Further, it is possible that the CLSF and the ARS exist at the same position.
[0442]
A cell (connectionless communication cell) to be transferred from the public network 475 to a terminal existing in the network under discussion here is a connectionless communication (ATM connection) with the public network once existing in the network 471. There is a terminating server. As viewed from the public network 475, this server is defined as an access point for connectionless communication. This server terminates the ATM connection and forwards the datagram to the destination terminal. The method of transferring datagrams from the server is realized in the same manner as the transfer of datagrams from each terminal to another terminal.
[0443]
The protocol of the terminal in this embodiment, that is, the procedure for the terminal to transmit a connectionless communication datagram to the target terminal is as follows.
[0444]
(1) The terminal issues an address resolution request (AR request). This is performed when the terminal cannot resolve the address with its own capability, for example, when there is no entry in the address resolution cache table, or always.
[0445]
(2) The terminal acquires, from the address resolution server, VCI / VPI information which is an identifier of an ATM connection prepared for accessing the corresponding terminal.
[0446]
(3) The terminal attaches the obtained VCI / VPI and inserts a cell into the network, thereby completing the datagram transfer.
[0447]
It should be noted that the terminal does not need to perform the connection setting procedure defined in the ATM network when transferring the datagram.
[0448]
In the present embodiment, there are two types of protocols of the address resolution server, “backbone ARS-led” and “front-end ARS manual”, which are respectively as follows.
[0449]
(I) Backbone ARS initiative
A star-like ATM connection (bidirectional communication channel) is formed between the ARS 482 to 484 existing in each of the networks 472 to 474 and the ARS 481 existing in the network 471. For example, in order for the terminal 47A to acquire the VCI / VPI to transfer the datagram to the terminal 47D, the terminal 47A transmits the address resolution request cell having the address information of the terminal 47D to the ARS 482, which is the ARS of its own network 472. To transfer. The ARS 482 that has received the request cell analyzes that the address of the target terminal written in the received cell is not the own network 472, and uses the ATM connection 485 that has already been set to the ARS 481 existing in the network 471. Relays address resolution request cells. As another method, it is possible that the ARS 482 caches the network address information of the external network already acquired in the past through the ATM connection 485 and the VCI / VPI information for transferring the cell to each corresponding CLSF.
[0450]
The ARS 481 uses VCI / VPI information (VCI / VPI) for transferring the datagram to the CLSF (existing in the network 474) to which the datagram is to be transferred from the address information of the destination terminal 47D held by the received cell. The VCI / VPI information is transferred to the ARS 482. The ARS 482 that has received the VCI / VPI information returns (AR response) VCI / VPI information to be used by the terminal 47A based on the VCI / VPI information.
[0451]
Address resolution in the ARS 481 is performed as follows. The ARS 481 has the address information (address space information) of the terminal accommodated in the own network 471 and the information of the address space of the sub-networks 472 to 474. The ARS 481 compares the address written in the received address resolution request cell with the address space information of each subnetwork, and analyzes the corresponding destination network. Here, it should be noted that the ARS does not always need to analyze up to the host address of the destination address, but only analyzes up to the network address, when performing the comparison.
[0452]
Note that there are the following two methods for identifying a datagram intended for the public network 475.
[0453]
(A) Indicates whether the address information written in the address resolution cell is a datagram for the public network 475 or a datagram not for the public network. In other words, the terminal knows whether it is for the public network or not at the time of the address resolution request, and the terminal resolves the address resolution in a way that can explicitly identify whether the ARS is for the public or not. Transfer the cell to the ARS. When the address information is not the address for the public network 475 and the address does not exist in the address entry of the ARS 481, information indicating that the address does not exist is sent to the ARS 482.
[0454]
(B) When the address of the received address resolution request cell does not exist in the address entry of the ARS 481, it is determined that the address belongs to the public network 475.
[0455]
As described above, the ARS 481 has the address and address space information of the terminals belonging to the network 471 and the sub-networks 472, 473, and 474, and performs address resolution.
[0456]
FIGS. 49 and 50 show views of the sub-network space in this embodiment from the viewpoint of the ARS. FIG. 49 is an address space view of an adjacent network as viewed from the ARS 481. FIG. 50 is an address space view of the adjacent network viewed from the ARS 482. From the ARS 482, the network 511 connected by the IWU 476 is not initially visible as a plurality of sub-networks. The address space of each subnetwork is resolved from the ARS 482 only after exchanging information with the ARS 481.
[0457]
The address information (ATM layer address information) that the ARS 482 receives from the ARS 481 is the identifier (VCI / VPI information) of the ATM connection from the IWU 476 to the CLSF existing on the target subnet, and in some cases, also includes the identification information of the upper layer. Information). For example, when transferring a datagram from the terminal 47A to the terminal 47D, the identifier of the ATM connection 495, 497 for accessing the CLSF 494 is notified (AR response), and when transferring the datagram to the terminal 47F, the CLSF 491 is accessed. Of the ATM connection 495, 496 for the communication. The ARS 482 notifies the terminal 47A of VCI / VPI information from the VCI / VPI information received from the ARS 481 such that the ATM connection is normally relayed by the IWU 476. The VCI / VPI number notified to terminal 47A is rewritten by IWU 476 to another VCI / VPI.
[0458]
(Ii) Front-end ARS-led
A star ATM connection shown in FIG. 47 or a mesh ATM connection shown in FIG. 51 is formed between the ARS 482 to 484 existing in each of the networks 472 to 474 and the ARS 481 existing in the network 471. Each ARS acquires the address space information and the ATM connection information (VCI / VPI) of the external subnetwork as viewed from its own subnetwork, using the ATM connection defined in FIG. 47 or 51, respectively. FIG. 47 shows a configuration in which the ARS 481 is like a master ARS, and FIG. 51 shows a distributed configuration in which each ARS operates independently. If the network does not have three or more layers, it is more appropriate to use the backbone network as the master as shown in FIG.
[0459]
On the other hand, when there is no limitation on the network hierarchy, which of the forms of FIGS. 47 and 51 is selected depends on the form or management form of the network and the number of sub-networks existing in the network. For example, in order for the terminal 47A to acquire the VCI / VPI to transfer the datagram to the terminal 47D, the terminal 47A transmits an address resolution request cell having the address information of the terminal 47D to the ARS 482, which is the ARS of its own network 472. Forward. The ARS 482 that has received the request cell analyzes that the address of the destination terminal written in the received cell is the network 474, and sends the datagram to the CLSF (existing in the network 474) to which the datagram is to be forwarded. Is transmitted to the terminal 47A (AR response) for transferring the VCI / VPI information (VCI / VPI information will be described later).
[0460]
Address resolution in the ARS 482 is performed as follows. The ARS 482 has address information (address space information) of the terminal accommodated in the own network 472 and information on the address space of the sub-networks 471, 473, and 474. The ARS 482 compares the address written in the received address resolution request cell with the address space information of each subnetwork, and analyzes the corresponding transfer destination network. Here, it should be noted that the ARS does not always need to analyze up to the host address of the destination address, but only analyzes up to the network address, when performing the comparison.
[0461]
Note that there are the following two methods for identifying a datagram intended for the public network 475.
[0462]
(A) Indicates whether the address information written in the address resolution cell is a datagram intended for the public network 475 or a datagram not intended for the public network. In other words, the terminal knows whether it is for the public network or not at the time of the address resolution request, and the terminal resolves the address resolution in a way that can explicitly identify whether the ARS is for the public or not. Transfer the cell to the ARS. When the address information is not the address for the public network 475 and the address does not exist in the address entry of the ARS 482, it is determined that the address does not exist.
[0463]
(B) When the address of the received address resolution request cell does not exist in the address entry of the ARS 482, it is determined that the address belongs to the public network 475.
[0464]
As described above, the ARS 482 has the address and address space information of the terminals belonging to the network 472 and the sub-networks 471, 473, and 474, and performs address resolution.
[0465]
FIGS. 52 and 53 show views of the sub-network space in the present embodiment from the standpoint of ARS. FIG. 52 is an address space view of the adjacent network as viewed from the ARS 482, and FIG. 53 is an address space view of the adjacent network as viewed from the ARS 481. From each ARS, the address space of all sub-networks is resolved.
[0466]
The address information (ATM layer) that the ARS 482 receives from another ARS is the identifier of the ATM connection from the IWU 476 to the CLSF existing in the target subnet (VCI / VPI information, and may also include upper layer identification information). Information. For example, when transferring a datagram from the terminal 47A to the terminal 47D, the identifier of the ATM connection 495, 497 for accessing the CLSF 494 is notified (AR response), and when transferring the datagram to the terminal 47F, the CLSF 491 is accessed. Of the ATM connection 495, 496 for the communication. The ARS 482 notifies the terminal 47A of VCI / VPI information from the VCI / VPI information received from another ARS such that the ATM connection is normally relayed by the IWU 476. The VCI / VPI number notified to terminal 47A is rewritten by IWU 476 to another VCI / VPI.
[0467]
Between the ARSs, not only an exchange protocol for address space information of each sub-network but also a routing protocol for datagram communication (connectionless communication) between the sub-networks operates. Specifically, it performs setting management of the ATM connection between the IWU and the CLSF as shown in FIG. The individual ATM connections are separated by the IWU (closed inside the sub-network), and another ATM connection server process and a routing server process control ATM connection routing and ATM connection management (for example, VCI / VPI management). ), The ARS exchanges control messages with these servers and the IWU, and manages ATM connections necessary for connectionless communication.
[0468]
FIG. 54 shows an example of a VCI / VPI rewrite table that the IWU 476 should have. In the figure, VCI / VPI added for transferring a cell to the same CLSF need not necessarily be different numbers. That is, by combining with not only the VCI / VPI information but also the identifier information in the upper layer data unit, it is possible to identify which datagram the cell received by the destination CLSF belongs to. Similarly, the VCI / VPI added to the cell transferred from the same terminal need not always have a different number.
[0469]
Also, due to congestion or failure in the sub-network, it may be necessary to use an ATM connection having a different path from the ATM connection used in the normal state. In this case, a routing control process (a control process for address management may be another process) for managing and controlling VCI / VPI and routing table information set in a table of each switch is performed at a UNI point ( The VCI / VPI number shown to the user interface point) is controlled so that the same number can be maintained even when the route in the subnetwork changes.
[0470]
Next, even when access points of various servers (for example, CLSF) move, rebooting may be performed so that the connection identification numbers (VCI / VPI) seen from each access point are the same. In addition, a request message (new access information if necessary) for discarding information for old access from the cache table is transferred to the relevant access point upon reboot. In the latter case, the IWU needs to change the entry information in the table as shown in FIG. 54 (using the information in the transferred message or executing a protocol for acquiring new information). ).
[0471]
Next, routing to the destination terminal in the present embodiment will be described. The final datagram delivery to each terminal is performed only for the network to which each CLSF belongs (see FIG. 48). That is, for example, the CLSF 491 delivers datagrams to terminals belonging to the network 471 (the networks 472, 473, 474, and 475 do not provide service). Similarly, the CLSF 494 distributes datagrams only to terminals within the network 494. If the network address of the datagram received by each CLSF does not exist in the address entry of the CLSF, or if the address of the received datagram is not an element of the network address space of the network, the datagram is incorrect. Is determined to have been delivered. Actions on erroneous datagram delivery are not discussed here. That is, each CLSF need only have the address information of the terminal of the network to which it belongs. When the address of the received datagram exists in the own network, an appropriate ATM connection is selected and the datagram is relayed.
[0472]
FIG. 55 shows an example of protocol processing when a datagram is transferred from the terminal 47A to the terminal 47D. The ATM connection is temporarily terminated by CLSF494. That is, the OSI layer 3 protocol is terminated by CLSF494. The layer 3 protocol processing is performed by the CLSF 494, and the data unit is transferred to the terminal 47D using the ATM connection. As described above, when transferring a datagram to a terminal other than the own subnetwork, datagram delivery is realized end-to-end at the end of only one ATM connection.
[0473]
(Embodiment 5-1-1)
Next, a more specific embodiment will be described.
[0474]
56 and 57, an embodiment in which a datagram is transferred from the terminal 47A to the terminal 47D will be briefly described. FIG. 56 shows an embodiment based on the management views shown in FIGS. 50 and 49, and FIG. 57 shows an embodiment based on the management views shown in FIGS.
[0475]
The address resolution in the present embodiment is performed as follows.
[0476]
If the terminal 47A does not have the ATM layer address information for transferring the datagram to the terminal 47D when transferring the datagram to the terminal 47D, the terminal 47A sends to the ARS 482 an address resolution having the address information of the terminal 47D. The request cell is transferred using the ATM connection 571, 581. However, the ATM connections 571 and 581 can be realized by a point-to-point connection or a broadcast connection. The ARS 482 that has received the address resolution request cell transmits the address resolution request cell via the ATM connection 572 to the ARS 481 in the example of FIG. Transfer to As a procedure from when the ARS 482 receives the address resolution request cell to when the ARS 481 transfers the request cell to the ARS 481, the following method can be considered.
[0477]
(1) When the ARS handles all the responses to the address resolution request cells generated in the network, the ARS first screens the address resolution request cells. That is, it verifies whether the address in the received cell is an element of the address space of the own network using a network mask or the like. If the address is in the own network, the address table is searched and the ATM layer address information of the corresponding terminal is returned. On the other hand, when the address is other than that of the own network, the request cell is transferred to a preset upper ARS, in this example, ARS481.
[0478]
(2) The ARS responds only to a request that sends a datagram to a terminal that is not in the network, that is, belongs to another subnetwork, and a response to a resolution request to a terminal in its own network is The case where each terminal to be transferred replies is different depending on whether a broadcast channel is used for address resolution or a point-to-point connection. When a broadcast channel is used, after screening an address, a request cell is fetched, and the request cell is transferred to an upper ARS. On the other hand, when a point-to-point connection is used, cells can be transferred unconditionally to an upper ARS, in this example, the ARS 481 in this example.
[0479]
In the example of FIG. 56, the ARS 481 that has received the address resolution request cell checks whether or not the address held by the own network and the address of the request cell exist in the address space. If there is no address corresponding to the address entry, it is determined that the address is for the public network. In the example, since the destination is the terminal 47D, the ARS 471 can recognize that the address of the requested cell exists in the address space of the network 474 (that is, the address space information of the network 474 can be used). The ARS 481 that has analyzed the address of the terminal 47D responds to the ARS 482 with VCI / VPI information (VCI / VPI information as viewed from the IWU 476) of the ATM connection from the IWU 476 to the CLSF 494.
[0480]
The ARS 482 returns a VCI / VPI, which is identification information of the ATM connection to be relayed to the ATM connection through the CLSF 494 in the IWU 476. By using the VCI / VPI, the terminal 47A can directly deliver a datagram to the CLSF494. In the example of FIG. 57 in which the ARS 482 can autonomously perform address resolution, in response to an address resolution request given through the ATM connection 581, the resolution information (AR response) is directly sent to the terminal 47A. Via the ATM connection 582.
[0481]
Datagram transfer in the present embodiment is performed as follows.
[0482]
The terminal 47A transfers the cell (having datagram information) to the CLS 494 using the ATM connection 575,583. The IWUs 476 and 478 relay the ATM connection by rewriting the received VCI / VPI information of the cell. Since this processing is performed as processing of the ATM layer without being raised to the upper layer, the ATM connections 575 and 583 via the IWUs 476 and 478 can be regarded as one ATM connection without an ATM termination point.
[0483]
At the CLSF 494, which is the terminal point of the ATM connections 575 and 583, the processing of the network layer is performed. The CLSF 494 analyzes the network address, relays the datagram to the ATM connection 576, 584, and transfers the datagram to the terminal 47D.
[0484]
As described above, there are two ATM connections, the terminal 47A to the CLSF 494 and the CLSF 494 to the terminal 47D, and are terminated only once.
[0485]
(Embodiment 5-2) Case where VPI routing ATM network is used—Part 1
[0486]
First, an ATM layer address assignment method according to the present embodiment will be described. When performing VPI routing, the VPI field indicates the destination UNI (described as VPI-F). The coding method of the VCI field needs to be defined as follows. Here, the coding of the VCI field under discussion relates to the transfer of cells related to connectionless communication, and the coding here is not necessarily applied to other applications (such as connection-oriented connections). No need to use. That is, generally, the coding method of the VCI field can be performed by negotiation between the receiving terminal and the transmitting terminal. The 16-bit VCI field is defined to be composed of two 8-bit subfields, and these are described as VCI-F1 and VCI-F2.
[0487]
In this embodiment, the ATM connection is set as follows. The setting of the ATM connection related to the address resolution shown in FIGS. Each of the ARSs 481 to 484 manages at least address information of terminals or networks accommodated in the networks 471 to 474 to which each ARS belongs.
[0488]
FIG. 58 shows a case where the ARS 481 shown in FIG. 48 takes the initiative (becomes a route) to manage the address information of each sub-network. The VCI / VPI information is rewritten by the IWU and relaying of the ATM connection is performed. For example, an ATM connection from the ARS 482 to the ARS 481 is formed from the connections 591 and 592. The VPI-F of the connection 591 is a VPI that is an access address of the IWU 476._476-2And VCI-F1 is VPI which is an access address of ARS482.₄₈₂It is. The VCI-F2 can be any value in principle, but the IWU 476 can identify from the information inside the VCI-F2 that the receiving cell is to be relayed to the connection 592. Is coded as On the other hand, the VPI-F of the connection 592 is a VPI which is an access address of the ARS 481.₄₈₁VCI-F1 is VPI which is an access address of IWU 476._476-1It is. Note that VCI-F2 can be set to any value in principle for both connections. Also, VPI_476-1Is the access address (VPI) of the IWU 476 for the network 471,_476-2Is the access address (VPI) of the IWU 476 for the network 472.
[0489]
The IWU 476 analyzes VCI / VPI information to be written to the cell of the connection 592 from the set of the received VCI-F2 and VCI-F1 information of the cell. Therefore, the IWU 476 has a VCI field (16 bits) as a table entry, and as a result, has a function of analyzing VCI / VPI information. The VPI-F of the cell of the connection 592 is analyzed by a combination of the VCI-F1 and the VCI-F2. VCI-F1 has VPI_476-1Is written. The VCI-F2 is coded as an identifier of an ATM connection between the ARS 482 and the ARS 481. The value of VCI-F2 is determined when an ATM connection (connections 591 and 592) is set. The assignment of the VCI-F2 may be a process of managing the VCI-F2 in the sub-network (networks 471 and 472), or the value of the VCI-F2 is managed by the terminal (ARS481 and IWU476). It can be a process.
[0490]
59 and 60 will be described. This is a case where each ARS shown in FIG. 51 independently manages address information of each subnetwork. For example, an ATM connection 617 from the ARS 482 to the ARS 484 is formed from the connections 6021, 6041, and 6061. The VPI-F of the connection 6021 is a VPI 476-2 which is an access address of the IWU 476, and the VCI-F1 is a VPI-VPI which is an access address of the ARS 482.₄₈₂It is. The connection of the VCI-F2 is identified by a combination of VCI-F1 and VCI-F2 which are identification numbers assigned to the connection 6021. The VPI-F of the connection 6061 is a VPI that is an access address of the IWU 478._478-1VCI-F1 is VPI which is an access address of IWU 476._476-1It is. VCI-F2 is a value set when the connection 6061 is set. The VPI-F of the connection 6041 is a VPI which is an access address of the ARS484.₄₈₄And VCI-F1 is VPI which is an access address of IWU478._478-1It is. VCI-F2 is a value set when the connection 6041 is set.
[0490]
For example, the IWU 478 analyzes VCI / VPI information to be written to the cell of the connection 6041 from a set of received VCI-F2 and VCI-F1 information of the cell. The IWU 478 has a VCI field (16 bits) as a table entry, and has a function of analyzing VCI / VPI information as a result.
[0492]
The VPI-F of the cell of the connection 6041 is analyzed by a combination of the VCI-F1 and the VCI-F2. VCI-F1 has VPI_478-1Is written. The VCI-F2 is coded as an identifier of an ATM connection between the ARS 482 and the ARS 481 (analyzed from VCI field information). The value of VCI-F2 is determined when an ATM connection (connections 6021, 6041, 6061) is set. The assignment of the VCI-F2 may be a process of managing the VCI-F2 in the sub-network (networks 471, 472, 474), or the terminal (ARS481, IWU476, ARS484) may change the value of the VCI-F2. It may be a managed process.
[0493]
According to the method of setting the VCI / VPI field as described above, even when the ARS transfers information spanning a plurality of cells to another ARS, the data can be reassembled without any problem on the receiving side. It is necessary to use an upper layer identification field for data identification such as from which terminal the data is transferred or data related to an address resolution protocol.
[0494]
FIG. 61 shows the setting of an ATM connection required to transfer a datagram from the terminal 47A to the terminal 47F, the public network 475, and the terminal 47D. The two methods are described below.
[0495]
(1) First, the transfer of a datagram from the terminal 47A to the terminal 47F will be described. In this case, it is formed from two ATM connections. One is a connection 621 to 623 and a connection 624 from the terminal 47A to the CLSF491, and the other is a connection 625 from the CLSF491 to the terminal 47F. The terminal 47A transfers the following cell to the IWU 476. That is, VPI-F is VPI which is an access address of IWU 476._476-2, VCI-F1 is a VPI which is an access address of the terminal 47A._47A, VCI-F2 have the values set when the connection 621 is set. The IWU 476 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. VCI-F1 is a VPI which is an access address for the network 471 of the IWU 476._476-1Is written. The VCI-F2 is a value determined when the connection 624 is set, and the value of the VCI-F1 of the cell received by the IWU 476, that is, the VPI-F1 which is the access address of the terminal 47A._47ACan also be copied and written.
[0496]
The datagram arriving at the CLSF 491 is subjected to cell reassembly once, and the ATM connection is terminated. The CLSF 491 analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 47F. Therefore, the CLSF 491 generates the following cell and transfers the datagram to the terminal 47F. VPI-F is VPI which is an access address of the terminal 47F._47F, VCI-F1 is VPI which is an access address of CLSF491.₄₉₁, VCI-F2 are identification numbers assigned to the connection 625. The terminal 47F can uniquely identify the datagram to which the cell belongs from VCI-F1 and VCI-F2. That is, the datagram can be reassembled.
[0497]
Next, transfer of a datagram from the terminal 47A to the public network 475 will be described. In this case, one ATM connection (connection 622 + 626 + 627) is formed. The terminal 47A transfers the following cell to the IWU 476. That is, VPI-F is VPI_476-2, VCI-F1 is VPI_47A, VCI-F2 have the values set when the connection 622 is set. The IWU 476 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. VCI-F1 is a VPI which is an access address for the network 471 of the IWU 476._476-1Is written. The VCI-F2 is a value determined when the connection 626 is set, and the value of the VCI-F1 of the cell received by the IWU 476, that is, the VPI-F1 which is the access address of the terminal 47A._47ACan also be copied and written. The IWU 479 writes the VCI / VCI assigned to the ATM connection 627 defined in the public network 475 from the received VCI information of the cell, and transfers the cell to the public network 475.
[0498]
Finally, the transfer of the datagram from the terminal 47A to the terminal 47D will be described. It is formed from two ATM connections. One is a connection 623, 628, 629 from the terminal 47A to the CLSF 494, and the other is a connection 62A from the CLSF 494 to the terminal 47D. The terminal 47A transfers the following cell to the IWU 476. That is, VPI-F is VPI which is an access address of IWU 476._476-2, VCI-F1 is a VPI which is an access address of the terminal 47A._47A, VCI-F2 have the values set when the connection 623 is set. The IWU 476 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. VCI-F1 is a VPI which is an access address for the network 471 of the IWU 476._476-1Is written. The VCI-F2 is a value determined when the connection 628 is set, and the value of the VCI-F1 of the cell received by the IWU 476, that is, the VPI-F1 which is the access address of the terminal 47A._47ACan also be copied and written.
[0499]
Next, the VCI of the cell received by the IWU 478 is analyzed, and the corresponding VPI-F, VCI-F1, and VCI-F2 are analyzed. VCI / VPI needs to be allocated so that CLSF494 can be identified even if cells from all terminals in the network (terminals capable of forwarding datagrams to CLSF494) arrive at the same time.
[0500]
The datagram arriving at the CLSF 494 is once subjected to cell reassembly, and the ATM connection is terminated. The CLSF 494 analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 47D. Therefore, CLSF494 generates the following cell and transfers the datagram to terminal 47D. That is, VPI-F is the VPI which is the access address of the terminal 47D._47D, VCI-F1 is a VPI which is an access address of CLSF494.₄₉₄, VCI-F2 are identification numbers assigned to the connection 62A. The terminal 47D can uniquely identify the datagram to which the cell belongs from VCI-F1 and VCI-F2. That is, the datagram can be reassembled.
[0501]
(2) Each CLSF has acquired a VPI address, and all connections identified by the VPI are configured to be ATM connections used for cell transfer related to datagram communication (connectionless communication). That is, the CLSF server itself needs an ATM connection (not a connectionless connection) in order to communicate with another terminal / server. That is, the CLSF needs to acquire at least two or more access addresses (VPI) at the time of boot.
[0502]
Similarly, IWUs all acquire at least two or more access addresses (VPIs) at boot time. One VPI is used for a connectionless communication cell. That is, when transferring a cell of a datagram relating to connectionless communication to an external network, each terminal attaches a VPI (for IWU) defined for connectionless communication to the cell and inserts the cell into the network.
[0503]
At this time, the following method is used as a coding method of the VCI field of the cell for connectionless communication. The VCI field is divided into two 8-bit subfields (VCI-F1 and VCI-F2: the definition position of the field is not mentioned).
[0504]
Next, a coding method of a cell transferred in the external sub-network will be described. This is the coding of the VCI field when a cell is transferred from the subnetwork to which the terminal belongs to the external subnetwork via the IWU. The identification number of the subnetwork to which the source terminal belongs is written in VCI-F1, and the identification number of the source terminal in the subnetwork is written in VCI-F2. For example, the access address (VPI) of each IWU in the network 471 may be used as the identification address of the subnetwork as the identification number of the subnetwork (the network 471 itself is appropriately coded). The terminal identification number may be an access address (VPI) of the terminal in each subnetwork. For example, the VCI field of the connectionless communication cell transmitted from the terminal 47D transferred in the external sub-network is VCI-F1 = VPI_478-1, VCI-F2 = VPI_47DIt can be.
[0505]
Next, a coding method of a cell transferred in the own sub-network will be described. This is the coding of the VCI field when a cell is transferred to the IWU of the subnetwork to which the terminal belongs. The identification number of the subnetwork to which the destination terminal belongs is written in VCI-F1, and the identification number of the source terminal in the subnetwork is written in VCI-F2. For example, the VCI-F2 field of the connectionless communication cell transmitted from the terminal 47D transferred within the own network is the VPI-F2 field._47DIt can be.
[0506]
With the above configuration, in the address resolution procedure performed prior to the transfer of the datagram, the terminal only needs to acquire the identification number of the subnetwork to which the destination terminal belongs, and the datagram (multiple or one) Cell). Hereinafter, the transfer of the datagram will be described.
[0507]
First, the transfer of a datagram from the terminal 47A to the terminal 47F will be described. The terminal 47A transfers the following cell to the IWU 476. VPI-F is VPI which is an access address of IWU 476._476-2, VCI-F1 is an identification number of the network 471 (for example, VPI which is an access address of CLSF491).₄₉₁) Can be used), and VCI-F2 is VPI which is an access address of the terminal 47A._47ASet to.
[0508]
The IWU 476 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of CLSF491 is stored in VCI-F1.₄₉₁Is written, the VPI-F of the output cell is VPI-F1 information of the received cell.₄₉₁Can be realized by copying The VCI-F1 includes a VPI, which is an access address for the network 471 of the IWU 476._476-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the CLSF491 is added to the VCI-F1 of the cell transferred from the terminal 47A.₄₉₁Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell includes VPI, which is the access address of the IWU._476-1, Cell relaying is realized.
[0509]
The datagram arriving at the CLSF 491 undergoes cell reassembly, and the ATM connection is terminated. The CLSF 491 analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 47F. Therefore, the CLSF491 determines that the VPI-F is the VPI that is the access address of the terminal 47F._47FIs generated, and the datagram is transferred to the terminal 47F. The CSLF 491 can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2 (the datagram can be reassembled). Therefore, relaying of datagrams (cells) can be performed in a pipeline manner.
[0510]
Next, transfer of a datagram from the terminal 47A to the public network 475 will be described. The terminal 47A transfers the following cell to the IWU 476. VPI-F is a VPI that is an IWU 476 access address._476-2, VCI-F1 are identification numbers of the public network 475 (for example, VPI which is an access address of IWU 479).₄₇₉VCI-F2 is a VPI that is an access address of the terminal 47A._47ASet to.
[0511]
The VCI of the cell received by the IWU 76 is analyzed, and the corresponding VPI-F and VCI-F2 are analyzed. For example, the access address VPI of the IWU 479 is stored in the VCI-F1.₄₇₉Is written, the VPI-F of the output cell is VPI-F1 information of the received cell.₄₇₉Can be realized by copying The VCI-F1 includes a VPI, which is an access address for the network 471 of the IWU 476._476-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the IWU 479 is added to the VCI-F1 of the cell transferred from the terminal 47A.₄₇₉Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell includes VPI, which is the access address of the IWU._476-1, Cell relaying is realized. The IWU 479 writes the VCI / VPI assigned to the ATM connection 627 defined by the public network 475 from the received VCI information of the cell, and transfers the cell to the public network 475.
[0512]
Finally, transfer of a datagram from the terminal 47A to the terminal 47D will be described. The terminal 47A transfers the following cell to the IWU 476. VPI-F is VPI which is an access address of IWU 476_476-2, VCI-F1 is an identification number of the network 474 (for example, VPI which is an access address of the IWU 478)._478-1VCI-F2 is a VPI that is an access address of the terminal 47A._47ASet to.
[0513]
The IWU 476 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of the IWU 478 is stored in the VCI-F1._478-1Is written, the VPI-F of the output cell is VPI-F1 information of the received cell._478-1Can be realized by copying VCI-F1 is a VPI which is an access address for the network 471 of the IWU 476._476-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the IWU 478 is added to the VCI-F1 of the cell transferred from the terminal 47A._478-1Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell has a VPI which is an access address of the IWU._476-1, Cell relaying is realized.
[0514]
Next, the VCI of the cell received by the IWU 478 is analyzed, and the corresponding VPI-F, VCI-F1, and VCI-F2 are analyzed. The VCI field of the cell transferred from the IWU 478 to the CLSF 494 can set the VCI field information of the received cell transparently. That is, VCI-F1 = VPI_476-1, VCI-F2 = VPI_47AIt can be. VPI-F is VPI which is an access address of CLSF494.₄₉₄Is set. The datagram arriving at the CLSF 494 is once subjected to cell reassembly, and the ATM connection is terminated. The CLSF 494 analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 47D. Also, CLSF494 is a VPI-F where the VPI-F is the terminal 47D access address._47DIs generated, and the datagram is transferred to the terminal 47D. The terminal 47D can uniquely identify the datagram to which the cell belongs from VCI-F1 and VCI-F2. That is, the datagram can be reassembled. Specifically, for example, the subnetwork to which the source terminal belongs or the IWU accommodating the subnetwork can be known from the VCI-F1 as the identification number of the subnetwork from the VCI-F2.
[0515]
(Embodiment 5-3) Case where general ATM network is used—No.
[0516]
FIG. 62 shows a schematic diagram of the network architecture of the present embodiment. This network is composed of a two-layer network. Each network 631-635 is internetworked via IWUs 636-639. The network 631 and the public network 635 are connected via the IWU 639. The IWUs 636 to 639 can realize ATM cell relaying without terminating the ATM connection. That is, it has a function of converting the VCI / VPI of the received cell into the VCI / VPI assigned to the corresponding ATM connection in the adjacent network. Note that CLSF-O, CLSF-I, and ARS can be mounted on the same device. Furthermore, they can be implemented on the IWU.
[0517]
FIGS. 64 and 65 show the setting of the ATM connection related to the address resolution. Each ARS manages at least address information of terminals or networks accommodated in the network to which each ARS belongs.
[0518]
FIG. 63 shows the settings of the ATM connections 641 to 646 necessary for transferring a datagram from the terminal 63A to (1) the terminal 63C, (2) the public network 635, and (3) the terminal 63B. An ATM connection (one-way ATM connection) from the CLSF-O63M to the CLSF-I63L, CLSF-I63J, and the public network 635 is set. Note that the same connection is set for other sub-networks. The ATM connection set between CLSF-I and CLSF-O is shown in FIG. Note that, in the case of connectionless communication to terminals belonging to the networks 631 to 634 defined from the public network 635, an ATM connection related to connectionless communication from the public network 635 exists in the network 631 from the public network 635. An ATM connection for connectionless communication is terminated, and terminated at a server for relaying datagrams. The server that terminates the connectionless ATM connection is transferred from the server to the target terminal by using the same procedure as described below for transferring a datagram from a terminal in a network to a terminal in another network. Is done.
[0519]
The protocol of the terminal according to the present embodiment will be described. When the terminal determines that the datagram is destined for the external subnetwork, the terminal forwards the datagram to CLSF-O. It is assumed that an ATM connection has already been set between the terminal and CLSF-O. Each terminal has information on the address space of the subnetwork to which the terminal belongs (address mask, etc.), and can determine whether the destination terminal is in its own subnetwork or an external subnetwork. .
[0520]
In the case of the network configuration shown in FIG. 62, for example, the following three methods can be used as a datagram delivery method.
[0521]
(1) CLSF-O and CLSF-I are at the same access point, and a star-shaped ATM connection is set between CLSF and the terminal. All terminals transfer cells to the CLSF when transferring datagrams. All datagrams are delivered by CLSF. That is, the communication between the terminals in the sub-network also passes through the CLSF once.
[0522]
(2) Communication between terminals in the sub-network is realized without passing through CLSF, and communication with terminals in the external network is realized via CLSF-O.
[0523]
(3) CLSF-O is used for communication with terminals on the external network, and CLSF-I is used for communication with terminals inside the own network.
[0524]
In the present embodiment, there are two types of protocols of the address resolution server, “backbone ARS-led” and “front-end ARS manual”, which are respectively as follows.
[0525]
(I) Backbone ARS initiative
A star-like ATM connection (two-way communication channel) is formed between the ARS in each network and the ARS 63G in the network 631 (FIG. 64). For example, to transfer a datagram from the terminal 63A to the terminal 63B, the CLSF-O63M obtains VPI / VCI information of the connection in order to use the ATM connection set between the CLSF-O63M and the CLSF-I63J. There is a need to. The CLSF-O63M transfers the address resolution request cell having the address information of the terminal 63B to the ARS 63D, which is the ARS of its own network 632, to obtain the VCI / VPI (written in the received datagram). Address information). The ARS 63D that has received the request cell analyzes the address of the destination terminal written in the received cell, and if the information held by the ARS 63D cannot resolve the address, the ARS 63D has already set the ARS 63G existing in the network 631. The relaying of the address resolution request cell is performed by using the established ATM connection 651.
[0526]
The ARS 63G receives VCI / VPI information (VCI / VPI) for transferring the datagram to the CLSF (existing in the network 633) to which the datagram is to be transferred from the address information of the destination terminal 63B held by the received cell. The VCI / VPI information is transferred to the ARS 63D. The ARS 63D that has received the VCI / VPI information returns VCI / VPI information to be used by the CLSF-O63M based on the VCI / VPI information (AR response).
[0527]
Address resolution in the ARS 63G is performed as follows. The ARS 63G has the address information (address space information) of the terminal accommodated in the own network 631 and the information of the address space of the sub-networks 632 to 634. The ARS 63G compares the address written in the received address resolution request cell with the address space information of each subnetwork, and analyzes the corresponding destination network.
[0528]
Note that there are the following two methods for identifying a datagram for the public network 635.
[0529]
(A) Indicates whether the address information written in the address resolution cell is a datagram intended for the public network 635 or a datagram not intended for the public network. In other words, the terminal knows whether it is for the public network or not at the time of the address resolution request, and the terminal resolves the address resolution in a way that can explicitly identify whether the ARS is for the public or not. Transfer the cell to the ARS. When the address information is not the address for the public network 635 and the address does not exist in the address entry of the ARS 63G, the information that the address does not exist is sent to the ARS 63D.
[0530]
(B) When the address of the received address resolution request cell does not exist in the address entry of the ARS 63G, it is determined that the address belongs to the public network 635.
[0531]
As described above, the ARS 63G has the address and address space information of the terminals belonging to the network 631 and the sub-networks 632 to 634, and performs address resolution. The ARS 63G does not necessarily need to have the address information up to the terminal level of the sub-network other than the sub-network to which the ARS 63G belongs, but may have the information up to the network address level.
[0532]
The address information (ATM layer) received by the ARS 63D from the ARS 63G is the identifier of the ATM connection from the IWU 636 to the CLSF-I present on the target subnet (VCI / VPI information, which may include upper layer identification information). Information. For example, when transferring a datagram from the terminal 63A to the terminal 63B, the identifier of the ATM connection 645 for accessing the CLSF-I63J is notified (AR response), and when transferring the datagram to the terminal 63C, the CLSF-I63L is transmitted. The identifier of the ATM connection 642 for access is notified.
[0533]
Note that the ARS 63D notifies the CLSF-O63M of VCI / VPI information from the VCI / VPI information received from the ARS 63G such that the ATM connection is normally relayed by the IWU 636. The VCI / VPI number notified to CLSF-O63M is rewritten by IWU 636 to another VCI / VPI.
[0534]
(Ii) Front-end ARS-led
A star-like ATM connection as shown in FIG. 64 or a mesh-like ATM connection as shown in FIG. 65 is formed between the ARS in each network and the ARS 63G in the network 631. Each ARS obtains the address space information and the ATM connection information (VCI / VPI) of the external subnetwork as viewed from its own subnetwork, using the ATM connection defined in FIG. 64 or 65, respectively. FIG. 64 shows a configuration in which the ARS 63G is like a master ARS, and FIG. 65 shows a distributed configuration in which each ARS operates independently.
[0535]
If the network does not have three or more layers, it is more appropriate to use the backbone network as the master as shown in FIG. On the other hand, when there is no limitation on the network hierarchy, which of the forms in FIGS. 64 and 65 is selected depends on the form or management form of the network and the number of sub-networks existing in the network. For example, in order for the CLSF-O63M to acquire the VCI / VPI to transfer the datagram to the terminal 63B, the CLSF-O63M sends an address resolution request having the address information of the ARS63B to the ARS63D which is the ARS of its own network 632. Transfer cells. The ARS 63D receiving the request cell analyzes that the address of the destination terminal written in the received cell is the network 633, and sends the data to the CLSF (existing in the network 633) to which the datagram is to be forwarded. VCI / VPI information for transferring the gram (VCI / VPI information will be described later) to CLSF-O63M (AR response).
[0536]
The resolution of the address in the ARS 63D is performed as follows. The ARS 63D has the address information (address space information) of the terminal accommodated in the own network 632 and the information of the address space of the sub-networks 631, 633, and 634. The ARS 63D compares the address written in the received address resolution request cell with the address space information of each sub-network, and analyzes the corresponding destination network.
[0537]
Note that there are the following two methods for identifying a datagram for the public network 635.
[0538]
(A) Indicates whether the address information written in the address resolution cell is a datagram intended for the public network 635 or a datagram not intended for the public network. That is, when the terminal knows whether or not the ARS is for the public network or not at the time of the address resolution request, the terminal resolves the address resolution in a manner that can explicitly identify whether the ARS is for the public or not. Transfer the solution cell to the ARS. If the address information is not the address for the public network 635 and the address does not exist in the address entry of the ARS 63D, it is determined that the address does not exist.
[0539]
(B) When the address of the received address resolution request cell does not exist in the address entry of the ARS 63D, it is determined that the address belongs to the public network 635.
[0540]
As described above, the ARS 63D has information on the addresses and address spaces of the terminals belonging to the network 632 and the sub-networks 631, 633, and 634, and performs address resolution. Note that the ARS 63D does not necessarily need to have address information up to the terminal level of a subnetwork other than the subnetwork to which the ARS 63D belongs, and may have information up to the network address level.
[0541]
The address information (ATM layer) that the ARS 63D receives from another ARS is an identifier (VCI / VPI information) of an ATM connection from the IWU 636 to the CLSF-I existing in the target subnet, and may include upper layer identification information. ) Information. For example, when transferring a datagram from the terminal 63A to the terminal 63B, the identifier of the ATM connection 645 for accessing the CLSF-I63J is notified (AR response), and when transferring the datagram to the terminal 63C, the CLSF-I63L is transmitted. The identifier of the ATM connection 642 for access is notified.
[0542]
The ARS 63D notifies the CLSF-O63M of VCI / VPI information from the VCI / VPI information received from another ARS, such that the ATM connection is normally relayed by the IWU 636. The VCI / VPI number notified to CLSF-O63M is rewritten by IWU 636 to another VCI / VPI. Between the ARSs, not only an exchange protocol for address space information of each sub-network but also a routing protocol for datagram communication (connectionless communication) between the sub-networks operates. Specifically, the setting management of the ATM connection as shown in FIG. 63 is performed. Note that individual ATM connections are separated by the IWU (closed inside the sub-network), and another ATM connection server process and a routing server process control the ATM connection path control and ATM connection management (for example, VCI / VPI). The ARS exchanges control messages with these servers and the IWU, and manages ATM connections required for connectionless communication.
[0543]
The routing to the destination terminal in the present embodiment will be described. The final datagram delivery to each terminal is performed only for the network to which each CLSF-I belongs. That is, for example, the CLSF-I 63L distributes datagrams to terminals belonging to the network 631 (the networks 632 to 635 do not provide service). Similarly, the CLSF-I63J distributes datagrams only to terminals in the network 633. If the network address of the datagram received by each CLSF does not exist in the address entry of the CLSF, or if the address of the received datagram is not an element of the network address space of the network, the datagram is incorrect. Is determined to have been delivered. Actions on erroneous datagram delivery are not discussed here. That is, each CLSF need only have the address information of the terminal of the network to which it belongs. When the address of the received datagram exists in the own network, an appropriate ATM connection is selected and the datagram is relayed.
[0544]
FIG. 67 shows an example of protocol processing when a datagram is transferred from the terminal 63A to the terminal 63B. The ATM connection is terminated at CLSF-O63M and CLSF-I63J. That is, the OSI layer 3 protocol is terminated by CLSF-O63M and CLSF-I63J. As described above, when transferring a datagram to a terminal other than the own subnetwork, datagram delivery is realized end-to-end at the end of two ATM connections.
[0545]
(Embodiment 5-3-1)
Next, a more specific embodiment will be described.
[0546]
An example in which a datagram is transferred from the terminal 63A to the terminal 63B in FIG. 63 will be briefly described.
[0547]
The address resolution in the present embodiment is performed as follows.
[0548]
When the terminal 63A analyzes that the terminal 63B is a terminal belonging to the external sub-network when transferring the datagram to the terminal 63B, the terminal 63A transfers the datagram to the CLSF-O63M. The CLSF-O63M analyzes the address information of the received datagram, and when it does not have the ATM layer address information for transferring the datagram to the terminal 63B (CLSF-I63J), has the address information of the terminal 63B to the ARS 63D. Transfer the address resolution request cell.
[0549]
If the ARS 63D has information that can be resolved, the ARS 63D directly transfers the AR request (VCI / VPI information for transferring a cell from the CLSF-O63M to the CLSF-I63J). However, if the ARS 63D cannot resolve the address, the ARS 63D accesses the appropriate ARS to perform the resolution. When the address resolution is completed, the result (AR response) is transferred to CLSF-O63M.
[0550]
Datagram transfer in the present embodiment is performed as follows.
[0551]
The terminal 63A transfers the cell having the datagram information to the CLSF-O63M using the ATM connection 641. The CLSF-O63M analyzes the address information of the datagram, converts the datagram into cells, and transfers the cells to the CLSF-I63J using the ATM connection 645. The IWU 636 and the IWU 637 perform the relaying of the ATM connection by rewriting the received VCI / VPI information of the cell. At the CLSF-I63J, which is the terminal point of the ATM connection 645, the processing of the network layer is performed. The CLSF-I 63J analyzes the network address, relays the datagram to the ATM connection 646, and transfers the datagram to the terminal 63B.
[0552]
As described above, there are three ATM connections, the terminal 63A to the CLSF-O63M, the CLSF-O63M to the CLSF-I63J, and the CLSF-I63J and the terminal 63B, and the ATM connection is terminated twice.
[0553]
(Embodiment 5-4) Case where VPI routing ATM network is used—Part 2
[0554]
In the present embodiment, the method of realizing the ATM connection set between the ARSs is the same as the above-described method, and the description is omitted here.
[0555]
Referring to FIG. 63 or FIG. 68, four methods for setting an ATM connection required for transferring a datagram from the terminal 63A to the terminal 63B, the public network 635, and the terminal 63C will be described.
[0556]
ATM connection setting method (1)
First, the transfer of a datagram from the terminal 63A to the terminal 63C will be described. Three ATM connections, (1) connection 691 from terminal 63A to CLSF-O63M, (2) connection 692, 693 from CLSF-O63M to CLSF-I63L, (3) connection 694 from CLSF-I63L to terminal 63C Is formed. Terminal 63A has VPI-F = VPI_63MTransfer the cell with. VCI-F1 is VPI which is an access address of the terminal 63A._63AIt is. CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI which is an access address of IWU 636._636-2, VCI-F1 is a VPI which is an access address of CLSF-O63M._63M, VCI-F2 have the values set when the connection 692 was set. The VCI of the cell received by the IWU 636 is analyzed, and the corresponding VPI-F and VCI-F2 are analyzed. VCI-F1 is a VPI which is an access address for the network 631 of the IWU 636._636-1Is written. Note that VCI-F2 is a value determined when the connection 693 is set, and the value of the VCI-F1 of the cell received by the IWU 636, that is, the VPI-F of the access address of the CLSF-O63M._63MCan also be copied and written. The datagram arriving at the CLSF-I63L is temporarily reassembled, and the ATM connection is terminated. The CLSF-I 63L analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 63C. Therefore, the CLSF-I 63L generates the following cell and transfers the datagram to the terminal 63C.
[0557]
VPI-F is VPI which is an access address of the terminal 63C._63C, VCI-F1 is a VPI which is an access address of CLSF-I63L._63L, VCI-F2 are identification numbers assigned to the connection 694. The terminal 63C can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2. That is, the datagram can be reassembled.
[0558]
Next, transfer of a datagram from the terminal 63A to the public network 635 will be described. It is formed from two ATM connections 691 and 692, 695, 696. Terminal 63A has VPI-F = VPI_63MTransfer the cell with. CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI_636-2, VCI-F1 is VPI_63M, VCI-F2 have the values set when the connection 692 was set. The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. VCI-F1 is a VPI which is an access address for the network 631 of the IWU 636._636-1Is written. Note that VCI-F2 is a value determined when the connection 695 is set, and the value of the VCI-F1 of the cell received by the IWU 636, that is, the VPI which is the access address of the CLSF-O63M._63MCan also be copied and written. The IWU 639 writes the VCI / VPI assigned to the ATM connection 696 defined by the public network 635 from the received VCI information of the cell, and transfers the cell to the public network 635.
[0559]
Finally, transfer of a datagram from the terminal 63A to the terminal 63B will be described. Three ATM connections, (1) connection 691 from terminal 63A to CLSF-O63M, (2) connection 692, 697, 698 from CLSF-O63M to CLSF-I63J, (3) connection from CLSF-I63J to 63B 699. Terminal 63A has VPI-F = VPI_63MTransfer the cell with. CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI which is an access address of IWU 636._636-2, VCI-F1 is a VPI which is an access address of CLSF-O63M._63M, VCI-F2 have the values set when the connection 692 was set. The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. VCI-F1 is a VPI which is an access address for the network 631 of the IWU 636._636-1Is written. The VCI-F2 is a value determined when the connection 697 is set, and the value of the VCI-F1 of the cell received by the IWU 636, that is, the VPI-F, which is the access address of the CLSF-O63M._63MCan also be copied and written.
[0560]
Next, the IWU 637 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F, VCI-F1, and VCI-F2. VCI / VPI is allocated so that CLSF-I63J can identify even if cells from all terminals / servers (such as CLSF) in the network, that is, terminals capable of transferring datagrams to CLSF-I63J, arrive at the same time. Need to be done.
[0561]
The datagram arriving at CLSF-I63J is subjected to cell reassembly once, and the ATM connection is terminated. The CLSF-I 63J analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 63B. Therefore, the CLSF-I 63J generates the following cell and transfers the datagram to the terminal 63B. VPI-F is VPI which is an access address of the terminal 63B._63B, VCI-F1 is a VPI which is an access address of CLSF-I63J._63J, VCI-F2 are identification numbers assigned to the connection 699. The terminal 63B can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2. That is, the datagram can be reassembled.
[0562]
ATM connection method (2)
In CLSF-O, datagram reassembly is performed, but address resolution is performed by each terminal. The address information of the resolved target network is written to the VCI-F1 of the cell transferred from the terminal to the CLSF-O. The transfer of cells (transfer of datagrams) from the CLSF-O cannot be executed in a pipeline manner. However, in CLSF-O, it is not necessary to resolve the address of the network to which the destination terminal belongs from the address information in the received datagram.
[0563]
Each IWU, CLSF-O, and CLSF-I have all obtained a VPI address, and all connections identified by the VPI seem to be ATM connections used for cell transfer for datagram communication (connectionless communication). To be configured. That is, the CLSF server and the IWU need an ATM connection (not a connectionless connection) in order for the CLSF server and the IWU to communicate with another terminal / server. That is, the CLSF and the IWU need to acquire at least two or more access addresses (VPI) at the time of boot.
[0564]
At this time, the following method is used as a coding method of the VCI field of the cell for connectionless communication. The VCI field is composed of two 8-bit subfields (VCI-F1 and VCI-F2: the definition positions of the fields are not mentioned).
[0565]
A coding method of a cell transferred in the external subnetwork in the present embodiment will be described. This is the coding of the VCI field when a cell is transferred from the subnetwork to which the terminal belongs to the external subnetwork via the IWU. The identification number of the subnetwork to which the source terminal belongs is written in VCI-F1, and the identification number of the source terminal in the subnetwork is written in VCI-F2. For example, the access address (VPI) of each IWU in the network 631 may be used as the identification address of the subnetwork as the identification number of the subnetwork (the network 631 itself is appropriately coded). The terminal identification number may be an access address (VPI) of the terminal in each subnetwork. For example, the VCI field of the connectionless communication cell output from the terminal 63B is VCI-F1 = VPI_637-1, VCI-F2 = VPI_63BIt can be.
[0566]
(Cell from CLSF-O to IWU)
The identification number of the subnetwork to which the source terminal belongs is written in VCI-F1, and the identification number of the CLSF-O in the subnetwork is written in VCI-F2. For example, the VCI-F2 field of the connectionless communication cell issued from CLSF-O63M is_63MIt can be.
[0567]
(Cell from terminal to CLSF-O)
The identification number of the subnetwork to which the destination terminal belongs is written in VCI-F1, and the identification number of the source terminal in the subnetwork is written in VCI-F2. For example, the VCI-F2 field of the connectionless communication cell output from the terminal 63B is the VPI-F2 field._63BIt can be.
[0568]
With the above configuration, the terminal can acquire the datagram (a plurality of or one datagram) as long as the terminal obtains the identification number of the subnetwork to which the destination terminal belongs in the address resolution procedure performed prior to the transfer of the datagram. Cell) can be transferred as follows.
[0569]
First, the transfer of a datagram from the terminal 63A to the terminal 63C will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 is an identification number of the network 631 (for example, VPI which is an access address of CLSF-I63L)._63LVCI-F2 is VPI which is an access address of the terminal 63A._63ASet to.
[0570]
CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI which is an access address of IWU 636._636-2Set to. The VCI-F1 can copy the VCI-F1 of the received cell as it is, and can use the identification number of the network 631 (for example, the VPI-I_63LCan also be used). VCI-F2 is VPI which is an access address of CLSF-O63M._63MSet to.
[0571]
The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of CLSF-I63L is stored in VCI-F1._63LIs written, the VPI-F of the output cell is VPI-F1 information of the received cell._63LCan be realized by copying VCI-F1 includes a VPI, which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the CLSF-I63L is added to the VCI-F1 of the cell transferred from the CLSF-O63M._63LIs written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell includes VPI, which is the access address of the IWU._636-1, Cell relaying is realized.
[0572]
The datagram arriving at the CLSF-I63L is temporarily reassembled, and the ATM connection is terminated. The CLSF-I 63L analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 63C. Therefore, the CLSF-I63L uses VPI-F, which is the access address of the terminal 63C._63CIs generated, and the datagram is transferred to the terminal 63C. The terminal 63C can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2. That is, the datagram can be reassembled.
[0573]
Next, transfer of a datagram from the terminal 63A to the public network 635 will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 is an identification number of the network 635 (for example, VPI which is an access address of the IWU 639).₆₃₉VCI-F2 is VPI which is an access address of the terminal 63A._63ASet to.
[0574]
CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI which is an access address of IWU 636._636-2Set to. The VCI-F1 can copy the VCI-F1 of the received cell as it is, and can use the identification number of the public network 635 (for example, the VPI-IPI₆₃₉Can also be used). VCI-F2 is VPI which is an access address of CLSF-O63M._63MSet to.
[0575]
The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of the IWU 639 is stored in the VCI-F1.₆₃₉Is written, the VPI-F of the cell to be output can be realized by copying the IWU 639 that is the VCI-F1 information of the received cell. VCI-F1 includes a VPI, which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the IWU 639 is added to the VCI-F1 of the cell transferred from the CLSF-O63M.₆₃₉Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell has a VPI which is an access address of the IWU._636-1, Cell relaying is realized. The IWU 639 writes the VCI / VPI assigned to the ATM connection 696 defined by the public network 635 from the received VCI information of the cell, and transfers the cell to the public network 635.
[0576]
Finally, transfer of a datagram from the terminal 63A to the terminal 63B will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 is an identification number of the network 633 (for example, VPI which is an access address of CLSF-I63J)._63JAnd VPI that is the access address of IWU 637₆₃₇VCI-F2 is VPI which is an access address of the terminal 63A._63ASet to.
[0577]
CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI which is an access address of IWU 636._636-2Set to. The VCI-F1 can copy the VCI-F1 of the received cell as it is, and can use the identification number of the network 633 (for example, the VPI-I_637-1Can also be used). VCI-F2 is VPI which is an access address of CLSF-O63M._63MSet to. The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of the IWU 637 is stored in the VCI-F1._637-1Is written, the VPI-F of the output cell is VPI-F1 information of the received cell._637-1Can be realized by copying VCI-F1 is a VPI which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the IWU 637 is added to the VCI-F1 of the cell transferred from the CLSF-O63M._637-1Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell has a VPI which is an access address of the IWU._636-1, Cell relaying is realized.
[0578]
Next, the IWU 637 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F, VCI-F1, and VCI-F2. The VCI field of the cell transferred from the IWU 637 to the CLSF-I63J can set the VCI field information of the received cell transparently. That is, VCI-F1 = VPI_636-1, VCI-F2 = VPI_63MIt can be. VPI-F is a VPI which is an access address of CLSF-I63J._63JIs set. The datagram arriving at CLSF-I63J is subjected to cell reassembly once, and the ATM connection is terminated. The CLSF-I 63J analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 63B. CLSF-I63J is a VPI-F where the VPI-F is the access address of the terminal 63B._63BIs generated, and the datagram is transferred to the terminal 63B. The terminal 63B can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2. That is, the datagram can be reassembled.
[0579]
ATM connection setting method (3)
In this method (2), a cell to which a datagram belongs is transferred in a pipeline manner. In CLSF-O, datagram reassembly is performed, but address resolution is performed by each terminal. In CLSF-O, the resolution of the address of the network to which the destination terminal belongs is determined from the address information in the received datagram. No need to do. The address information of the resolved target network is written to the VCI-F1 of the cell transferred from the terminal to the CLSF-O.
[0580]
At this time, the following method is used as a coding method of the VCI field of the cell for connectionless communication.
[0581]
(Inside external sub-network-same as method 2)
The identification number of the subnetwork to which the source terminal belongs is written in VCI-F1, and the identification number of the source terminal in the subnetwork is written in VCI-F2.
[0582]
(Cell from CLSF-O to IWU)
The identification number of the subnetwork to which the destination terminal belongs is written in VCI-F1, and the identification number of the source terminal in the subnetwork is written in VCI-F2. For example, a cell relating to a datagram output from the terminal 63A has a VCI-F2 field of VPI_63AIt can be.
[0583]
(Terminal to CLSF-O cell-same as method 2)
The identification number of the subnetwork to which the destination terminal belongs is written in VCI-F1, and the identification number in the subnetwork to which the source terminal belongs is written in VCI-F2.
[0584]
First, the transfer of a datagram from the terminal 63A to the terminal 63C will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 is an identification number of the network 631 (for example, VPI which is an access address of CLSF-I63L)._63LVCI-F2 is a VPI that is an access address of the terminal 63A._63ASet to.
[0585]
CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI which is an access address of IWU 636._636-2Is set to The VCI-F1 and VCI-F2 can copy the information of the received cell as it is. Therefore, the VCI-F1 is an identification number of the network 631 (for example, VPI which is an access address of CLSF-I63L)._63LVCI-F2 is the VPI that is the access address of the terminal 63A._63ASet to each. At this time, the cells can be sequentially transferred to the IWU 636 in a pipeline manner without once reassembling the datagram in the CLSF-O63M.
[0586]
The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of CLSF-I63L is stored in VCI-F1._63LIs written, the VPI-F of the output cell is VPI-F1 information of the received cell._63LCan be realized by copying VCI-F1 includes a VPI, which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the CLSF-I63L is added to the VCI-F1 of the cell transferred from the CLSF-O63M._63LIs written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell has a VPI which is an access address of the IWU._636-1, Cell relaying is realized.
[0587]
The datagram arriving at the CLSF-I63L is temporarily reassembled, and the ATM connection is terminated. The CLSF-I 63L analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 63C. Therefore, the CLSF-I63L uses VPI-F, which is the access address of the terminal 63C._63CIs generated, and the datagram is transferred to the terminal 63C. The terminal 63C can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2. That is, the datagram can be reassembled.
[0588]
Next, transfer of a datagram from the terminal 63A to the public network 635 will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 are identification numbers of the public network 635 (for example, VPI which is an access address of the IWU 639).₆₃₉VCI-F2 is VPI which is an access address of the terminal 63A._63ASet to.
[0589]
CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI which is an access address of IWU 636._636-2Is set to The VCI-F1 and VCI-F2 can copy the information of the received cell as it is. Therefore, VCI-F1 is an identification number of the public network 635 (for example, VPI which is an access address of IWU 639).₆₃₉VCI-F2 is the VPI that is the access address of the terminal 63A._63ASet to. At this time, in the CLSF-O63M, the cells can be sequentially transferred to the IWU 636 in a pipeline manner without reassembling the datagram.
[0590]
The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of the IWU 639 is stored in the VCI-F1.₆₃₉Is written, the VPI-F of the cell to be output can be realized by copying the IWU 639 that is the VCI-F1 information of the received cell. VCI-F1 includes a VPI, which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the IWU 639 is stored in the VCI-F1 of the cell transferred from the CLSF-O63M.₆₃₉Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell includes VPI, which is the access address of the IWU._636-1, Cell relaying is realized.
[0591]
The IWU 639 writes the VCI / VPI assigned to the ATM connection 696 defined by the public network 635 from the received VCI information of the cell, and transfers the cell to the public network 635.
[0592]
Finally, transfer of a datagram from the terminal 63A to the terminal 63B will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 is an identification number of the network 633 (for example, VPI which is an access address of CLSF-I63J)._63JVCI-F2 is VPI which is an access address of the terminal 63A._63ASet to.
[0593]
CLSF-O63M transfers the following cells to IWU 636. VPI-F is VPI which is an access address of IWU 636._636-2Is set to The VCI-F1 and VCI-F2 can copy the information of the received cell as it is. Therefore, the VCI-F1 has an identification number of the network 633 (for example, VPI which is an access address of the IWU 637)._637-1VCI-F2 is the VPI that is the access address of the terminal 63A._63ASet to. At this time, in the CLSF-O63M, the cells can be sequentially transferred to the IWU 636 in a pipeline manner without reassembling the datagram once.
The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of the IWU 637 is stored in the VCI-F1._637-1Is written, the VPI-F of the output cell is VPI-F1 information of the received cell._637-1Can be realized by copying VCI-F1 is a VPI which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the IWU 637 is added to the VCI-F1 of the cell transferred from the CLSF-O63M._637-1Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell includes VPI, which is the access address of the IWU._636-1, Cell relaying is realized.
[0594]
Next, the IWU 637 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F, VCI-F1, and VCI-F2. The VCI field of the cell transferred from the IWU 637 to the CLSF-I63J can set the VCI field information of the received cell transparently. That is, VCI-F1 = VPI_636-1, VCI-F2 = VPI_63MIt can be. VPI-F is a VPI that is an access address of CLSF-I63J._63JIs set.
[0595]
The datagram arriving at CLSF-I63J is subjected to cell reassembly once, and the ATM connection is terminated. The CLSF-I 63J analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 63B. CLSF-I63J is a VPI-F where the VPI-F is the access address of the terminal 63B._63BIs generated, and the datagram is transferred to the terminal 63B. The terminal 63B can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2. That is, the datagram can be reassembled.
[0596]
ATM connection setting method (4)
This is an example in which datagram transfer to a different subnetwork is performed in a pipeline manner in the method (2). Datagram transfer from a terminal belonging to the same subnetwork to a terminal in the same subnetwork cannot be performed in a pipeline manner, but pipeline transfer is possible if the destination subnetwork is different. In this case, CLSF-O needs to have some buffer space.
[0597]
In CLSF-O, datagram reassembly is performed, but address resolution is performed by each terminal. In CLSF-O, the resolution of the address of the network where the destination terminal is located is determined from the address information in the received datagram. Need not be done. The address information of the resolved target network is written in the VCI-F1 of the cell transferred from the terminal to the CLSF-O. A datagram transfer procedure in CLSF-O will be described below.
[0598]
Step 1: A cell is received from the terminal (the first cell for the datagram).
[0599]
Step 2: Analyze the target subnetwork address information written in the VCI-F1.
[0600]
Step 3: Check whether there is any datagram currently being transferred to the analyzed subnetwork.
[0601]
Step 4: The CLSF-O can recognize the end of the datagram transfer by using an identification code of an ATM layer or higher (for example, payload type coding in the case of AAL5). When another datagram is not transferred to the analyzed subnetwork, the received cell is relayed to the target subnetwork. Received cells are relayed without being reassembled once in CLSF-O; pipeline transfer.
[0602]
Step 5: On the other hand, when another datagram is being transferred from another terminal to the analyzed subnetwork, the received cell needs to be buffered until the datagram transfer is completed. When the completion of the transfer of another datagram is confirmed, the buffered cells are sequentially transferred. At this time, the buffered cell (datagram) does not need to be reassembled, and the transfer of the first cell must be started before the last cell of the datagram to which the buffered cell belongs. Can be. Also, if an appropriate protocol is defined between the CLSF-O and the terminal, it is possible to perform flow control so that buffered cells are not discarded due to buffer overflow.
[0603]
In the present embodiment, the following method is used as the coding method of the VCI field of the cell for connectionless communication.
[0604]
(Inside external sub-network-same as method 2)
The identification number of the subnetwork to which the source terminal belongs is written in VCI-F1, and the identification number of the source terminal in the subnetwork is written in VCI-F2.
[0605]
(Cell from CLSF-O to IWU)
The identification number of the subnetwork to which the destination terminal belongs is written in VCI-F1, and the identification number of the transmission source network is written in VCI-F2. For example, a cell relating to a datagram output from the terminal 63A has a VCI-F2 field of VPI_636-1And so on.
[0606]
(Terminal to CLSF-O cell-same as method 2)
The identification number of the subnetwork to which the destination terminal belongs is written in VCI-F1, and the identification number of the transmission source terminal in the subnetwork is written in VCI-F2.
[0607]
First, the transfer of a datagram from the terminal 63A to the terminal 63C will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 is an identification number of the network 631 (for example, VPI which is an access address of CLSF-I63L)._63LVCI-F2 is VPI which is an access address of the terminal 63A._63ASet to.
[0608]
The CLSF-O63M transfers the following cells to the IWU 636 when no other datagram transfer to the subnetwork 631 is performed. VPI-F is VPI which is an access address of IWU 636._636-2Is set to The VCI-F1 can copy the information of the received cell as it is. VCI-F1 is an identification number of the network 631 (for example, VPI which is an access address of CLSF-I63L)._63LCan also be used). VCI-F2 is, for example, a VPI that is an identification number representing the subnetwork 632._636-1(The access address of the IWU 636). VCI-F2 may be any identifier for identifying its own subnetwork. At this time, in the CLSF-O63M, the cells can be sequentially transferred to the IWU 636 in a pipeline manner without reassembling the datagram once.
[0609]
The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of CLSF-I63L is stored in VCI-F1._63LIs written, the VPI-F of the output cell is VPI-F1 information of the received cell._63LCan be realized by copying VCI-F1 includes a VPI, which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the CLSF-I63L is added to the VCI-F1 of the cell transferred from the CLSF-O63M._63LIs written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell includes VPI, which is the access address of the IWU._636-1, Cell relaying is realized.
[0610]
The datagram arriving at the CLSF-I63L is temporarily reassembled, and the ATM connection is terminated. The CLSF-I 63L analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 63C. Therefore, the CLSF-I63L uses VPI-F, which is the access address of the terminal 63C._63CIs generated, and the datagram is transferred to the terminal 63C. The terminal 63C can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2 (the datagram can be reassembled).
[0611]
Next, transfer of a datagram from the terminal 63A to the public network 635 will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 are identification numbers of the public network 635 (for example, VPI which is an access address of the IWU 639).₆₃₉VCI-F2 is VPI which is an access address of the terminal 63A._63ASet to.
[0612]
The CLSF-O63M transfers the following cells to the IWU 636 when no other datagram transfer to the public network 635 is performed. VPI-F is VPI which is an access address of IWU 636._636-2Is set to The VCI-F1 can copy the information of the received cell as it is. VCI-F1 is an identification number of the public network 635 (for example, VPI which is an access address of IWU 639).₆₃₉Can also be used). VCI-F2 is a VPI that is an identification number representing the subnetwork 632._636-1(The access address of the IWU 636). VCI-F2 may be any identifier for identifying its own subnetwork. At this time, the cells can be sequentially transferred to the IWU 636 in a pipeline manner without once reassembling the datagram in the CLSF-O63M.
[0613]
The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of the IWU 639 is stored in the VCI-F1.₆₃₉Is written, the VPI-F of the output cell is VPI-F1 information of the received cell.₆₃₉Can be realized by copying VCI-F1 includes a VPI, which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the IWU 639 is added to the VCI-F1 of the cell transferred from the CLSF 63M.₆₃₉Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell includes VPI, which is the access address of the IWU._636-1, Cell relaying is realized.
[0614]
The IWU 639 writes the VCI / VPI assigned to the ATM connection 696 defined by the public network 635 from the received VCI information of the cell, and transfers the cell to the public network 635.
[0615]
Finally, transfer of a datagram from the terminal 63A to the terminal 63B will be described. The terminal 63A transfers the following cell to the CLSF-O63M. VPI-F is VPI which is an access address of CLSF-O63M._63M, VCI-F1 is an identification number of the network 633 (for example, VPI which is an access address of IWU 637)._637-1VCI-F2 is VPI which is an access address of the terminal 63A._63ASet to.
[0616]
The CLSF-O63M transfers the following cells to the IWU 636 when no other datagram transfer to the subnetwork 633 is performed. VPI-F is VPI which is an access address of IWU 636._636-2Is set to The VCI-F1 can copy the information of the received cell as it is. VCI-F1 is an identification number of the network 633 (for example, VPI which is an access address of IWU 637)._637-1Can also be used). VCI-F2 is a VPI that is an identification number representing the subnetwork 632._636-1(The access address of the IWU 636). VCI-F2 may be any identifier for identifying its own subnetwork. At this time, in the CLSF-O63M, the cells can be sequentially transferred to the IWU 636 in a pipeline manner without reassembling the datagram.
[0617]
The IWU 636 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F and VCI-F2. For example, the access address VPI of the IWU 637 is stored in the VCI-F1._637-1Is written, the VPI-F of the output cell is VPI-F1 information of the received cell._637-1Can be realized by copying VCI-F1 is a VPI which is an access address for the network 631 of the IWU 636._636-1Is written. VCI-F2 can be set to be transparent. That is, for example, the access address VPI of the IWU 637 is added to the VCI-F1 of the cell transferred from the CLSF-O63M._637-1Is written, (1) the VCI-F1 of the receiving cell is copied to the VPI-F of the sending cell, and (2) the VCI-F2 of the receiving cell is copied to the VCI-F2 of the sending cell. (3) The VCI-F1 of the transmission cell includes VPI, which is the access address of the IWU._636-1, Cell relaying is realized.
[0618]
Next, the IWU 637 analyzes the VCI of the received cell, and analyzes the corresponding VPI-F, VCI-F1, and VCI-F2. The VCI field of the cell transferred from the IWU 637 to the CLSF-I63J can set the VCI field information of the received cell transparently. That is, VCI-F1 = VPI_637-1, VCI-F2 = VPI_636-1It can be. VPI-F is a VPI that is an access address of CLSF-I63J._63JIs set.
[0619]
The datagram arriving at CLSF-I63J is subjected to cell reassembly once, and the ATM connection is terminated. The CLSF-I 63J analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 63B. CLSF-I63J is a VPI-F where the VPI-F is the access address of the terminal 63B._63BIs generated, and the datagram is transferred to the terminal 63B. The terminal 63B can uniquely identify the datagram to which the cell belongs from the VCI-F1 and the VCI-F2 (the datagram can be reassembled).
[0620]
(Sixth embodiment)
Next, an embodiment relating to a network configuration of a horizontal topology will be described. FIG. 69 shows a system configuration of the present embodiment. As shown in the figure, a plurality of sub-networks 701 to 706 are internetworked using an IWU. The IWU can realize the relaying of the ATM cell without terminating the ATM connection. That is, it has a function of converting the VCI / VPI of the received cell into the VCI / VPI assigned to the corresponding ATM connection in the adjacent network.
[0621]
The connection line between the sub-networks 701 to 706 may be a connection line in a campus, or may be a dedicated line / switch line of a public network. Further, although public networks 707 and 708 are shown in the figure, this indicates that it is possible to access terminals and networks other than the defined network via the public network. That is, for example, when communicating with a terminal connected to a general public network, the communication is performed through the public networks 707 and 708.
[0622]
Each of the sub-networks 701 to 706 has a CLSF, and can handle cells related to connectionless communication. The setting and operation of the CLSF and a specific embodiment when connectionless communication is realized between terminals will be described later.
[0623]
There is no particular limitation on the network distance (indicator of how many relay points (sub-networks) are required to connect any point in the network). The two-layer network described in the above embodiment has a network topology such that a target subnetwork can be reached via at most one relay subnetwork. However, in the network handled here, there is basically no restriction on the distance of this network.
[0624]
Further, in the following embodiments, a method of configuring an ATM connection related to the realization of the address resolution will not be particularly described. The method of realizing the address resolution is basically the same as the method described in the above embodiment. That is, each address resolution server is on an equal footing, and a method of analyzing network address information (an image as shown in FIG. 49) and a method in which the address resolution server has a logical hierarchical structure (FIG. 50). This is a method for managing and analyzing address information. The ATM connection set between the address resolution servers is an arbitrary configuration from a full mesh configuration (configuration as shown in FIG. 59) to a minimum spanning tree configuration (configuration as shown in FIG. 58). It is possible to
[0625]
(Embodiment 6-1) A case where the present invention is applied to a general ATM network.
[0626]
The ATM connection in the present embodiment is as follows. In order to transfer a datagram from a terminal connected to each subnetwork to a terminal connected to an arbitrary subnetwork, an ATM connection is set from each IWU to CLSF existing in all subnetworks. That is, the ATM connection from the IWU to the CLSF (one-way ATM connection) is set in a full mesh state. In an IWU (relay IWU) existing on the path of the ATM connection, rewriting (at least VCI / VPI conversion) of ATM header information is performed, and cell relaying is performed as a job of the ATM layer. In other words, the ATM connection is not terminated in principle via the IWU.
[0627]
In addition, the position where the CLSF exists can also exist at the position of the IWU. When datagrams are transferred from the public networks 707 and 708 to the defined network, the received cells (to which the datagrams belong) are transferred to the server that temporarily terminates the datagram connection of the public network in the IWU 70K and IWU 70M. You. Note that this server can also exist in the IWU. The server that terminates the datagram transferred from the public network relays the datagram in the same procedure as the transfer of the datagram from the terminal in the defined network.
[0628]
FIG. 80 shows the configuration of an ATM connection when a datagram is transferred from the public network 707 to the terminal 70A. The datagram transferred from the public network 707 is once terminated in the CLSF-P811 and then transferred to the terminal 70A via the CLSF7011. ATM connections are three connections 812, 813 and 814.
[0629]
(Terminal protocol)
The procedure for the terminal in this embodiment to transmit a connectionless communication datagram to the destination terminal is as follows.
[0630]
(1) The terminal issues an address resolution request (AR request). This is performed when the terminal cannot resolve the address by its own ability (for example, when there is no entry in the address resolution cache table), or is always performed.
[0631]
(2) The terminal acquires, from the address resolution server, VCI / VPI information which is an identifier of an ATM connection prepared for accessing the corresponding terminal.
[0632]
(3) The terminal completes the datagram transfer by inserting a cell into the network with the acquired VCI / VPI. The terminal does not need to perform a connection setting procedure defined in the ATM network when transferring the datagram.
[0633]
(routing)
The final datagram delivery to each terminal in this embodiment is performed only for the network to which each CLSF belongs. That is, for example, the CLSF 7061 performs delivery of a datagram to a terminal belonging to the network 706. Similarly, the CLSF 7031 distributes datagrams only to terminals in the network 703. If the network address of the datagram received by each CLSF is not present in the address entry of the CLSF (or if the address of the received datagram is not an element of the network address space of the network), the datagram is It is determined that the delivery was incorrect. Actions on erroneous datagram delivery are not discussed here.
[0634]
That is, each CLSF need only have the address information of the terminal of the network to which it belongs. When the address of the received datagram exists in the own network, an appropriate ATM connection is selected and the datagram is relayed. FIG. 71 shows an example of protocol processing when a datagram is transferred from the terminal 70A to the terminal 70B. The ATM connection is temporarily terminated at CLSF7061. That is, the OSI layer 3 protocol is terminated by the CLSF 7061. The layer 3 protocol processing is performed in the CLSF 7061, and the data unit is transferred to the terminal 70B using the ATM connection. As described above, when transferring a datagram to a terminal other than the own subnetwork, datagram delivery is realized end-to-end at the end of only one ATM connection.
[0635]
Similarly, FIG. 73 shows a case where a datagram is transferred from the terminal 70A to the public network 708, and FIG. 81 shows a protocol configuration when a datagram is transferred from the public network 707 to the terminal 70A.
[0636]
(Embodiment 6-1-1)
Next, a more specific embodiment will be described.
[0637]
(About datagram transfer from terminal 70A to terminal 70B)
FIG. 70 shows a configuration diagram of the ATM connection. The terminal 70A resolves the address of the terminal 70B when transferring the datagram (analyzes the access address information of the subnetwork to which the terminal 70B belongs). That is, an AR request message containing the address information of the terminal 70B is transferred to the address resolution server ARS. After performing the address resolution, the ARS receiving the AR request returns VCI / VPI information for transferring a cell to the terminal 70B to the terminal 70A as an AR response.
[0638]
The terminal 70A that has acquired the ATM layer address (VCI / VPI) information for transferring the cell to the terminal 70B enters the cell with the VCI / VPI added to the network. After the VCI / VPI conversion is performed by the IWU 70D, the cell is transferred to the IWU 70G. Similarly, the cell is transferred to CLSF7061 via IWU70H and IWU70J. Upon receiving the cell, the CLSF 7061 analyzes the information of the address information (layer 3) of the datagram and transfers the cell to the terminal 70B. The cell transfer from the CLSF 7061 to the terminal 70B may be performed after the CLSF 7061 has received all the cells belonging to the datagram, or after analyzing the layer 3 address of the datagram, relaying the cells in a pipeline. You may.
[0639]
(About datagram transfer from terminal 70A to public network 708)
FIG. 72 shows a configuration diagram of the ATM connection. When transferring the datagram, the terminal 70A performs resolution of the address of the target terminal (analyzes the access address information of the subnetwork to which the destination terminal belongs). That is, an AR request message containing the address information of the destination terminal is transferred to the address resolution server ARS. After performing the address resolution, the ARS receiving the AR request returns VCI / VPI information for transferring the cell to the terminal to the terminal 70A as an AR response.
[0640]
The terminal 70A that has acquired the ATM layer address (VCI / VPI) information for transferring the cell to the destination terminal inputs the cell with the VCI / VPI added to the network. The cells are transferred to the IWU 70E after the VCI / VPI conversion is performed by the IWU 70D. Similarly, the cell is transferred to the public network 708 via the IWU 70M.
[0641]
(About datagram transfer from public network 707 to terminal 70A)
FIG. 80 shows a configuration diagram of the ATM connection. The source terminal exists in the public network 707, and cells related to connectionless communication from the public network 707 are transferred to the CLSF-P811 via the IWU 70K. The VCI / VPI conversion table of the IWU 70K is set so that when a cell having a VCI / VPI assigned to a cell used for connectionless communication arrives in the public network 707, the cell is transferred to the CLSF-P811. ing.
[0642]
The CLSF-P811 temporarily terminates the ATM connection and analyzes the layer 3 address information of the datagram. When the address information to be analyzed does not exist in the table in the CLSF-P811, an AR request is issued to the ARS. The CLSF-P811 that has acquired the ATM layer address (VCI / VPI) information for transferring the cell to the terminal 70A inputs the cell with the VCI / VPI added to the network. The cell is transferred to the IWU 70D after the VCI / VPI conversion is performed in the IWU 70G. Further, the cell is transferred from the IWU 70D to the CLSF 7011. Upon receiving the cell, the CLSF 7011 analyzes the information of the address information (layer 3) included in the datagram, and transfers the cell to the terminal 70A. Note that the cell transfer from the CLSF 7011 to the terminal 70A and the cell transfer from the CLSF-P 811 to the IWU 70G may be performed after the CLSF 7011 and the CLSF-P 811 have received all the cells belonging to the datagram, or after the datagram layer 3 After analyzing the address, the cells may be relayed in a pipeline manner.
[0643]
(Embodiment 6-2)
An embodiment applied to a general ATM network will be described. In order to transfer a datagram from any terminal connected to each subnetwork to a terminal connected to any subnetwork, an ATM connection is established from each CLSF to CLSFs present in all subnetworks. I have. That is, the ATM connection between the CLSFs is set in a full mesh form. In an IWU (relay IWU) existing on the path of the ATM connection, rewriting (at least VCI / VPI conversion) of ATM header information is performed, and cell relaying is performed as a job of the ATM layer. That is, in principle, the ATM connection is not terminated when passing through the IWU. The position where the CLSF exists may be the position of the IWU.
[0644]
When datagrams are transferred from the public networks 707 and 708 to the defined network, the received cells (to which the datagrams belong) are transferred to the server that temporarily terminates the datagram connection of the public network in the IWU 70K and IWU 70M. Is done. Note that this server may exist in the IWU. The server that terminates the datagram transferred from the public network relays the datagram in the same procedure as the transfer of the datagram from the terminal in the defined network.
[0645]
FIG. 82 shows a configuration of an ATM connection when a datagram is transferred from the public network 707 to the terminal 70A. The datagram transferred from the public network 707 is once terminated in the CLSF-P811 and then transferred to the terminal 70A via the CLSFs 7031 and 7011. The ATM connections are four connections 831, 832, 833 and 834.
[0646]
(About terminal protocol)
When the terminal determines that the datagram is destined for an external subnetwork, it forwards the datagram to CLSF. The CLSF is basically located in the same sub-network as the terminal, but may be present in another sub-network such as, for example, an adjacent node. It is assumed that an ATM connection has already been set between the terminal and the CLSF. Each terminal has information on the address space (such as an address mask) of the subnetwork to which the own terminal belongs, and can determine whether the destination terminal is in its own subnetwork or an external subnetwork.
[0647]
In the case of the network configuration shown in FIG. 69, there are the following methods as a datagram delivery method.
[0648]
(1) A star-like ATM connection is set between the CLSF and the terminal. When transferring datagrams, the terminal transfers all cells to the CLSF. All datagrams are delivered by CLSF. That is, communication between terminals in the sub-network also passes through the CLSF once.
[0649]
(2) Communication between terminals in the sub-network is realized without passing through the CLSF, while communication with terminals in the external network is realized via the CLSF.
[0650]
(About routing)
The final datagram delivery to each terminal is performed only for the network to which each CLSF belongs. That is, for example, the CLSF 7061 performs delivery of a datagram to a terminal belonging to the network 706. Similarly, the CLSF 7031 distributes datagrams only to terminals in the network 703. If the network address of the datagram received by each CLSF is not present in the address entry of the CLSF (or if the address of the received datagram is not an element of the network address space of the network), the datagram is It is determined that the delivery was incorrect. Actions on erroneous datagram delivery are not discussed here.
[0651]
That is, each CLSF need only have the address information of the terminal of the network to which it belongs. When the address of the received datagram exists in the own network, an appropriate ATM connection is selected and the datagram is relayed.
[0652]
FIG. 74 shows the configuration of a connection when a datagram is transferred from terminal 70A to terminal 70B. The ATM connection is terminated at CLSF7011 and CLSF7061. That is, the OSI layer 3 protocol is terminated by CLSF7061 and CLSF7011. Layer 3 protocol processing is performed in the CLSF 7011, and the data unit is transferred to the IWU 70D using an ATM connection. Layer 3 protocol processing is performed in the CLSF 7061, and the data unit is transferred to the terminal 70B using the ATM connection. As described above, when transferring a datagram to a terminal other than the own subnetwork, datagram delivery is realized end-to-end at the end of two ATM connections.
[0653]
Similarly, FIG. 75 shows a case where a datagram is transferred from the terminal 70A to the public network 708.
[0654]
(Embodiment 6-2-1)
Next, a more specific embodiment will be described.
[0655]
(About datagram transfer from terminal 70A to terminal 70B)
FIG. 74 shows a configuration diagram of the ATM connection. When transmitting the datagram to the terminal 70B, the terminal 70A, when analyzing that the terminal 70B is a terminal belonging to the external subnetwork, transfers the datagram to the CLSF 7011. The CLSF 7011 analyzes the address information of the received datagram, and when it does not have the ATM layer address information for transferring the datagram to the terminal 70B (CLSF7061), the address resolution having the address information of the terminal 70B to the ARS. Transfer the requested cell. After performing the address resolution, the ARS that has received the AR request returns VCI / VPI information for transferring a cell to the CLSF 7061 (terminal 70B) to the CLSF 7011 as an AR response.
[0656]
The CLSF 7011 that has acquired the ATM layer address (VCI / VPI) information for transferring the cell to the terminal 70B enters the cell with the VCI / VPI added to the network. After the VCI / VPI conversion is performed by the IWU 70D, the cell is transferred to the IWU 70G. Similarly, the cell is transferred to CLSF7061 via IWU70H and IWU70J. Upon receiving the cell, the CLSF 7061 analyzes the information of the address information (layer 3) of the datagram and transfers the cell to the terminal 70B. The cell transfer from the CLSF 7061 to the terminal 70B may be performed after the CLSF 7061 has received all the cells belonging to the datagram, or after analyzing the layer 3 address of the datagram, relaying the cells in a pipeline. You may.
[0657]
(About datagram transfer from terminal 70A to public network 708)
FIG. 75 shows a configuration diagram of the ATM connection. When transferring the datagram to the target terminal of the public network 708, the terminal 70A resolves the address of the destination terminal (analyzes the access address information of the subnetwork to which the destination terminal belongs). That is, when the terminal 70A cannot resolve the address information of the destination terminal, it transfers an AR request message containing the address information of the destination terminal to the address resolution server ARS. After performing the address resolution, the ARS that has received the AR request returns the access address information of the CLSF 7011 to the terminal 70A with the VCI / VPI information for transferring the cell to the destination terminal as an AR response. When analyzing that the destination is a terminal belonging to the external subnetwork, the terminal 70A adds the received VCI / VPI information or the VCI / VPI information obtained as a result of the analysis to the cell, and transfers the cell to the CLSF 7011.
[0658]
The CLSF 7011 analyzes the address information of the received datagram, and when the CLSF7011 does not have the ATM layer address information for transferring the datagram to the destination terminal, sends the ARS an address resolution request cell having the address information of the destination terminal to the ARS. Forward. After performing the address resolution, the ARS that has received the AR request returns VCI / VPI information for transferring the cell to the IWU 70M to the CLSF 7011 as an AR response.
[0659]
The CLSF 7011 that has acquired the ATM layer address (VCI / VPI) information for transferring the cell to the destination terminal inputs the cell with the VCI / VPI added to the network. The cells are transferred to the IWU 70E after the VCI / VPI conversion is performed by the IWU 70D. Similarly, the cell is transferred to the public network 708 via the IWU 70M.
[0660]
(About datagram transfer from public network 707 to terminal 70A)
FIG. 82 shows a configuration diagram of the ATM connection. The source terminal exists in the public network 707, and cells related to connectionless communication from the public network 707 are transferred to the CLSF-P811 via the IWU 70K. The VCI / VPI conversion table of the IWU 70K is set so that when a cell having a VCI / VPI assigned to a cell used for connectionless communication arrives in the public network 707, the cell is transferred to the CLSF-P811. ing.
[0661]
The CLSF-P811 temporarily terminates the ATM connection and analyzes the layer 3 address information of the datagram. When the address information to be analyzed does not exist in the table in the CLSF-P811, an AR request is issued to the ARS. The CLSF-P 811 that has acquired ATM layer address (VCI / VPI) information for transferring the cell to the terminal 70A (VCI / VPI information for transferring the cell to the CLSF 7031) transmits the cell to which the VCI / VPI is added to the network. To put in. The CLSF 7031 analyzes the address information of the received datagram, and when it does not have the ATM layer address information for transferring the datagram to the terminal 70A (CLSF7011), the address resolution having the address information of the terminal 70A to the ARS. Transfer the requested cell. After performing the address resolution, the ARS receiving the AR request returns VCI / VPI information for transferring the cell to the CLSF 7011 (terminal 70A) to the CLSF 7031 as an AR response.
[0662]
The CLSF 7031 that has acquired the ATM layer address (VCI / VPI) information for transferring the cell to the terminal 70A inputs the cell with the VCI / VPI added to the network.
[0663]
The cell is transferred to the IWU 70D after the VCI / VPI conversion is performed in the IWU 70G. Further, the cell is transferred from the IWU 70D to the CLSF 7011. Upon receiving the cell, the CLSF 7011 analyzes the information of the address information (layer 3) included in the datagram, and transfers the cell to the terminal 70A. The transfer of cells from the CLSF 7011 to the terminal 70A and the transfer of cells from the CLSF-P 811 to the CLSF 7031 and the transfer of cells from the CLSF 7031 to the IWU 70G are performed by CLSF 7011, CLSF 7031, and CLSF-P 811 in which all cells belonging to the datagram belong to the datagram. The cell may be relayed in a pipeline manner after the reception or after analyzing the layer 3 address of the datagram.
[0664]
(Embodiment 6-3) A case where the present invention is applied to an ATM network of VPI routing.
[0665]
(ATM connection)
Each sub-network has an 8-bit sub-network identification number. Within the defined network, the subnetwork can be uniquely identified by this identification number. The identification number of the subnetwork is Net_iIt is described. For example, the identification number of the sub-network 702 is Net₇₀₂It is. All IWUs have obtained access addresses (VPI) for connectionless communication. Also, the CLSF on the receiving side (CLSF for handling cells arriving from the IWU, which can have a different configuration from CLSF for handling cells for connectionless communication coming from terminals in its own network) is also possible for connectionless communication. Access address (VPI) has been acquired.
[0666]
The coding of the VCI / VPI field is as follows.
[0667]
(1) Cell from transmitting terminal to CLSF of own network
(1-1) VPI-F; access address of CLSF
(1-2) VCI-F1; Address Net of Destination Network_iOr any
(1-3) VCI-F2; access address of own terminal
(2) Cell between CLSF
(2-1) VPI-F; access address of next access element (IWU or destination CLSF)
(2-2) VCI-F1; Address Net of Destination Network_destination
(2-3) VCI-F1; Network address Net to which transmitting terminal belongs_source
(3) Cell from CLSF in destination network to destination terminal
(3-1) VPI-F; access address of destination terminal
(3-2) VCI-F1; can be set to any value
(3-3) VCI-F2; can be set to any value
Note that an arbitrary value can be set to an arbitrary value if the cell received by the destination terminal is set to a value that can be clearly distinguished from a cell arriving from another arbitrary access point. It is configurable.
[0668]
(Subnetwork where the sending terminal exists)
First, coding of the cell VCI / VPI field from the transmitting terminal to the CLSF will be described. VPI-F is a CLSF access address. VCI-F2 is defined as the access address of the transmitting terminal. The coding of VCI-F1 includes two cases: a case where the transmitting terminal performs resolution of the subnetwork to which the destination terminal belongs, and a case where coding is performed by CLSF.
[0669]
(A) The transmitting terminal performs resolution; the transmitting terminal resolves the address of the destination sub-network, and identifies the identification number Net of the sub-network._destinationIs written to VCI-F1.
[0670]
(B) Resolution by CLSF; Since resolution of the destination network is performed by CLSF, VCI-F1 can be set to an arbitrary value in this case.
[0671]
Next, VCI / VPI coding of cells from CLSF to IWU will be described. VPI-F is an access address of the IWU. VCI-F1 is set to the identification number of the destination network (Net_destination). The VCI-F2 is set to the network identification number of the transmitting terminal (Net_source). There are two methods of setting the VCI-F1: a case where the transmission terminal performs resolution of the subnetwork to which the destination terminal belongs, and a case where the resolution is performed by CLSF.
[0672]
(A) The transmitting terminal performs the resolution; the identification number Net of the destination network written in the VCI-F1 by the transmitting terminal._destinationIs copied and written to the VCI-F1.
[0673]
(B) CLSF performs resolution; writes the resolved value.
[0674]
When transferring cells from the CLSF to the IWU, interleaving between cells belonging to different datagrams to the same destination network is not allowed (cell interleaving is possible for datagrams to different destination networks). That is, a series of cells belonging to one datagram are continuously transferred. In other words, cells can be transferred to the CLSF from each transmitting terminal at an arbitrary timing, but cells are transferred from the CLSF to the IWU for each datagram. In the IWU, the Net written in the VCI-F1 of the received cell is_destinationThe value of VPI-F is determined based on That is, the IWU table has Net_destinationIs set in the table of VPI-F corresponding to.
[0675]
Note that VCI-F1 and VCI-F2 are transferred transparently. Also, Net_destination, A routing protocol for determining a subnetwork to be relayed is separately executed, and a table for each IWU is set.
[0676]
(Between IWU)
The cells are relayed according to the table of the IWU. That is, Net of VCI-F1 of the receiving cell_destinationAnd write the VPI-F for relaying the cell to the next IWU based on.
[0677]
(Subnetwork to which the destination terminal belongs)
The IWU to which the destination terminal belongs can see the VCI-F1 of the received cell and know that the received cell is addressed to its own subnetwork. In the table for VPI-F setting set in the IWU, a VPI number for transferring a cell to the CLSF is set. The IWU sets its VPI to VPI-F and transfers the cell to CLSF. At this time, VCI-F1 and VCI-F2 are transferred transparently.
[0678]
The received CLSF reassembles the datagram based on the VCI information. At this time, it is conceivable that cells belonging to different datagrams are interleaved and transferred to the CLSF, but each datagram can be reconstructed normally using the VCI field information even when cells are interleaved. . The destination address (layer 3 address) of the received datagram is analyzed, and the datagram is transferred to an appropriate terminal.
[0679]
VPI-F of the cell transferred from the CLSF to the terminal is the access address of the terminal. Next, the VCI field uses the VCI defined by the cell received by the terminal for the cell for connectionless communication (a plurality of VCIs may be defined). This VCI is usually preset between the CLSF and the terminal. When there are a plurality of connectionless VCIs, the transfer of cells from the CLSF to the terminal can be transferred in a pipeline manner (cells to which different datagrams belong can be interleaved) as long as the identification numbers do not collide. it can.
[0680]
For example, if the VCI field format of VCI-F1 and VCI-F2 is defined in the communication from the CLSF to the terminal, that is, if the VCI field format of the communication in the sub-network is unified as described above, the CLSF Sets the VCI-F2 of the received cell as it is to the VCI-F2 of the cell to be transferred from the CLSF to the terminal, and the VCI-F1 of the cell from the CLSF to the terminal indicates that the received cell is a cell involved in connectionless communication. If set as a recognizable value, the datagram can be completely processed in a pipeline manner.
[0681]
(Specific examples)
First, the transfer of a datagram from the terminal 70A to the terminal 70B will be described with reference to FIGS. It is formed from three ATM connections. (1) A connection 791 from the terminal 70A to the CLSF 7011, (2) a connection 792 to 796 from the CLSF 7011 to the CLSF 7061, and (3) a connection 797 from the CLSF 7061 to the terminal 70B.
[0682]
The terminal 70A has VPI-F = VPI₇₀₁₁Transfer the cell with. VCI-F2 is VPI which is an access address of the terminal 70A._70AIt is. In addition, the VCI-F1 stores the address information (Net) of the sub-network to which the terminal 70A belongs by itself.₇₀₆), This value Net₇₀₆Is written to VCI-F1. When the CLSF 7011 performs resolution, the VCI-F1 can be set arbitrarily.
[0683]
The CLSF 7011 transfers the following cell to the IWU 70D. VPI-F is VPI which is an access address of IWU 70D._70D-1, VCI-F1 is the identification address of the network 706, Net.₇₀₆, VCI-F2 are Nets which are identification addresses of the network 701.₇₀₁It is. Note that the VCI-F1 copies the received cell value as it is (when the terminal₇₀₆CLSF7011 is Net₇₀₆May be analyzed and set.
[0684]
The VCI-F1 of the cell received by the IWU 70D is analyzed, and the corresponding VPI-F is analyzed. That is, a VPI that can transfer a cell toward an IWU that transfers the packet to the network 706 is analyzed (set in the table). The VCI-F1 and VCI-F2 copy the received cell fields as they are. That is, VCI-F1 is Net, which is the network identification number of the subnetwork 706 to which the destination terminal 70B belongs.₇₀₆Is written. Thereafter, similarly, in the IWU, Net which is information written in VCI-F1 of the received cell is used.₇₀₆An appropriate VPI is selected based on this information, and the cell is transferred to the IWU 70J.
[0685]
The cell arriving at the IWU 70J recognizes from the VCI-F1 information that the cell has been transferred to the target network, and transfers the cell to the CLSF 7061. The datagram arriving at the CLSF 7061 is subjected to cell reassembly once, and the ATM connection is terminated. The CLSF 7061 analyzes the address information of the upper layer and recognizes that the destination of the datagram is the terminal 70B. Therefore, the CLSF 7061 generates a cell and transfers the datagram to the terminal 70B. When transferring a cell to the terminal 70B, when there is a sufficient connectionless communication channel to the terminal 70B, the cell can be transferred in a pipeline manner from the reception of the cell of the CLSF 7061.
[0686]
Next, transfer of a datagram from terminal 70A to public network 708 will be described with reference to FIG. The terminal 70A has VPI-F = VPI₇₀₁₁Transfer the cell with. VCI-F2 is VPI which is an access address of the terminal 70A._70AIt is. In addition, the VCI-F1 stores the address information (Net) of the sub-network to which the terminal 70A belongs by itself.₇₀₈), This value Net₇₀₈Is written to VCI-F1. When the CLSF 7011 performs resolution, the VCI-F1 can be set arbitrarily.
[0687]
The CLSF 7011 transfers the following cell to the IWU 70D. VPI-F is VPI which is an access address of IWU 70D._70D-1, VCI-F1 are Nets which are identification addresses of the public network 708.₇₀₈, VCI-F2 are Nets which are identification addresses of the network 701.₇₀₁It is. Note that the VCI-F1 copies the received cell value as it is (when the terminal₇₀₆CLSF7011 is Net₇₀₈May be analyzed and set. The VCI-F1 of the cell received by the IWU 70D is analyzed, and the corresponding VPI-F is analyzed. That is, the VPI that can transfer the cell toward the IWU that transfers the data to the network 708 is analyzed (set in the table). The VCI-F1 and VCI-F2 copy the received cell fields as they are. That is, VCI-F1 is the network identification number of the subnetwork 708 to which the destination terminal belongs, ie, Net₇₀₈Is written. Thereafter, similarly, in the IWU, Net which is information written in VCI-F1 of the received cell is used.₇₀₈, An appropriate VPI is selected, and the cell is transferred to the IWU 70M. The IWU 70M writes the VCI / VPI assigned to the ATM connection defined in the public network 708 from the received VCI information of the cell, and transfers the cell to the public network 708.
[0688]
(Seventh embodiment)
Next, an embodiment related to connectionless communication in a large-scale networking configuration will be described.
[0689]
When the number of defined sub-networks is very large, it can be handled by internetworking the above-mentioned network. That is, this is a method in which an adjacent network (a network defined as an aggregate of a plurality of sub-networks described above) is viewed as one sub-network.
[0690]
FIG. 84 shows the configuration of the network as viewed from the network 861. The actual network configuration is shown in FIG. In this way, the three networks 862 to 864 appear as one sub-network 851 when viewed from the network 861. As for the address space of the network 851 viewed from the network 861, the combined space of the networks 862 to 864 can be seen.
[0691]
FIG. 86 schematically shows the network components involved in the following datagram transfer among the network components. Hereinafter, examples of datagram transfer from terminal 87A to terminal 87B and datagram transfer from terminal 87A to terminal 87C in the two system configurations described above will be described.
[0692]
(Embodiment 7-1)
This embodiment is an example in which a terminal can directly transfer a cell to an external network. That is, this method does not use the CLSF in its own network when transferring datagrams to terminals on the external network.
[0693]
(About datagram transfer from terminal 87A to terminal 87B)
FIG. 87 shows the configuration of the ATM connection. It has four ATM connections 881-884. The terminal 87A resolves the network layer address of the terminal 87B, resolves that the terminal 87B belongs to the network 851, and simultaneously obtains VCI / VPI information for transferring a cell to the CLSF 871. Details are as described above.
[0694]
The datagram is temporarily terminated by the CLSF 871 (the ATM connection is also terminated), and the layer 3 protocol processing is performed. The analysis of the network layer address is performed by the CLSF 871, the presence of the terminal 87B in the network 863 is analyzed, and the VCI / VPI information for transferring the cell to the CLSF 872 is obtained. The datagram is forwarded to CLSF 872 using ATM connection 882.
[0696]
The datagram is terminated by the CLSF872 (the ATM connection is terminated), and the layer 3 protocol processing is performed. The analysis of the network layer address is performed by the CLSF 872, and VCI / VPI information for transferring the cell to the CLSF 873 is obtained. The datagram is transferred to the CLSF 873 using the ATM connection 883.
[0696]
The CLSF 873 that has received the datagram analyzes the access address of the terminal 87B by analyzing the network layer address of the datagram. The cell to which the appropriate VCI / VPI has been added is transferred to terminal 87B.
[0697]
In this way, the termination of the ATM connection and the protocol processing in the network layer are performed three times, and the datagram is transferred from the terminal 87A to the terminal 87B.
[0698]
(About datagram transfer from terminal 87A to terminal 87C)
FIG. 88 shows the configuration of the ATM connection. It consists of two ATM connections 891, 892. The terminal 87A resolves the network layer address of the terminal 87C, resolves that the terminal 87C belongs to the network 851, and simultaneously obtains VCI / VPI information for transferring a cell to the CLSF 871. Details are as described above.
[0699]
The datagram is temporarily terminated by the CLSF 871 (the ATM connection is also terminated), and the layer 3 protocol processing is performed. The analysis of the network layer address is performed by the CLSF 871, the presence of the terminal 87C in the network 864 is analyzed, and VCI / VPI information for transferring a cell to the network 864 is obtained. Here, cell transfer to the IWU between the network 862 and the network 864 is performed.
[0700]
In this way, one end of the ATM connection and the protocol processing in the network layer are performed, and the datagram is transferred from the terminal 87A to the network 864 where the terminal 87C exists. It should be noted that the transfer destination of the datagram from the CLSF 871 may be a CLSF in the public network 864. In this case, two or more terminations of the ATM connection and protocol processing at the network layer level are performed.
[0701]
(Embodiment 7-2)
This embodiment is an example in which a terminal cannot directly transfer a cell to an external network. In other words, the method is to use the CLSF in the own network once when transferring the datagram to the terminal of the external network.
[0702]
(About datagram transfer from terminal 87A to terminal 87B)
FIG. 89 shows the configuration of the ATM connection. It is composed of five ATM connections 901-905. The terminal 87A resolves the network layer address of the terminal 87B, resolves that the terminal 87A belongs to the network 851 (or analyzes that the cell is sent to the CLSF874), and simultaneously transfers the cell to the CLSF874. VCI / VPI information is obtained. Details are as described above.
[0703]
Upon receiving the cell, the CLSF 874 recognizes that (1) the network layer address of the datagram is analyzed, or (2) the cell needs to be transferred to the network 862 (CLSF 871) using the result analyzed by the terminal 87A. I do. At the same time, VCI / VPI information for transferring the cell to the CLSF 871 is obtained, and the datagram is transferred to the CLSF 871.
[0704]
The datagram is temporarily terminated by the CLSF 871 (the ATM connection is also terminated), and the layer 3 protocol processing is performed. The analysis of the network layer address is performed by the CLSF 871, the presence of the terminal 87B in the network 863 is analyzed, and the VCI / VPI information for transferring the cell to the CLSF 872 is obtained. The datagram is transferred to the CLSF 872 using the ATM connection 903.
[0705]
The datagram is terminated by the CLSF872 (the ATM connection is terminated), and the layer 3 protocol processing is performed. The analysis of the network layer address is performed by the CLSF 872, and VCI / VPI information for transferring the cell to the CLSF 873 is obtained. The datagram is forwarded to CLSF 873 using ATM connection 904. Upon receiving the datagram, the CLSF 873 analyzes the network layer address of the datagram and analyzes the access address of the terminal 87B. The cell to which the appropriate VCI / VPI has been added is transferred to terminal 87B.
[0706]
In this way, the termination of the ATM connection four times and the protocol processing (sometimes three times) in the network layer are performed, and the datagram is transferred from the terminal 87A to the terminal 87B.
[0707]
(About datagram transfer from terminal 87A to terminal 87C)
FIG. 90 shows the configuration of the ATM connection. It is composed of three ATM connections 911-913. The terminal 87A resolves the network layer address of the terminal 87C, resolves that the terminal 87C belongs to the network 851 (or analyzes that the cell is sent to the CLSF874), and simultaneously transfers the cell to the CLSF874. VCI / VPI information is obtained. Details are as described above.
[0708]
Upon receiving the cell, the CLSF 874 recognizes that (1) the network layer address of the datagram is analyzed, or (2) the cell needs to be transferred to the network 862 (CLSF 871) using the result analyzed by the terminal 87A. I do. At the same time, VCI / VPI information for transferring the cell to the CLSF 871 is obtained, and the datagram is transferred to the CLSF 871.
[0709]
The datagram is temporarily terminated by the CLSF 871 (the ATM connection is also terminated), and the layer 3 protocol processing is performed. The analysis of the network layer address is performed by the CLSF 871, the presence of the terminal 87C in the network 864 is analyzed, and VCI / VPI information for transferring a cell to the network 864 is obtained. Here, cell transfer to the IWU between the network 862 and the network 864 is performed.
[0710]
In this manner, the termination of the ATM connection twice and the protocol processing (sometimes once) in the network layer are performed, and the datagram is transferred from the terminal 87A to the network 864 where the terminal 87C exists. It should be noted that the transfer destination of the datagram from the CLSF 871 may be a CLSF in the public network 864. In this case, two or more terminations of the ATM connection and protocol processing at the network layer level are performed.
[0711]
【The invention's effect】
As described above, according to the present invention, communication between ATM networks can be realized without impairing the features of high speed, large capacity, and connection oriented nature of the ATM communication system.
[0712]
Further, according to the present invention, datagram delivery using the ATM network can be efficiently performed.
[0713]
Furthermore, according to the present invention, connectionless communication (datagram delivery) between terminals connected to the ATM network can be performed at high speed.
[Brief description of the drawings]
FIG. 1 is a diagram showing an ATM network according to a first embodiment;
FIG. 2 is a diagram showing an internal structure of the network connection device 13;
FIG. 3 shows a drop table.
FIG. 4 is a diagram showing an internal configuration of an ATM-LAN;
FIG. 5 is a diagram showing a connection state of an ATM connection between a terminal in the ATM-LAN and a CLSF processing unit in the network connection device;
FIG. 6 is a diagram showing a case where a separate CLSF processing unit is prepared in the ATM-LAN in FIG. 5;
FIG. 7 shows a format of a broadcast cell.
FIG. 8 is a diagram showing a format of a broadcast cell when performing ARP.
FIG. 9 is a diagram showing a connection state of an ATM connection between a terminal in the ATM-LAN and a call processing unit in the network connection device.
FIG. 10 is a diagram showing another example of the connection state of the ATM connection between the terminal in the ATM-LAN and the call processing unit in the network connection device;
FIG. 11 is a diagram showing an example in which a call processing unit does not exist in the network connection device;
FIG. 12 shows various forms of broadcasting.
FIG. 13 is a diagram showing an ATM network according to a second embodiment;
FIG. 14 is a diagram showing an internal structure of the network connection device 134;
FIG. 15 is a diagram showing an internal configuration of an ATM-LAN;
FIG. 16 is a diagram showing a connection state of an ATM connection between a terminal in an ATM-LAN and a CLSF processing unit in an inter-network connecting device;
FIG. 17 is a diagram showing a connection state of an ATM connection between a terminal in an ATM-LAN and a call processing unit in an internetwork connecting device;
FIG. 18 is a diagram showing another example of the connection state of the ATM connection between the terminal in the ATM-LAN and the call processing unit in the interworking apparatus.
FIG. 19 is a diagram showing an example in which a call processing unit does not exist in an internetwork connecting apparatus;
FIG. 20 illustrates a large-scale ATM network.
FIG. 21 is a diagram showing an internal configuration of an ATM-LAN in a large-scale ATM network.
FIG. 22 is a diagram showing an example of VPI value allocation in an ATM-LAN.
FIG. 23 is a diagram showing an example of an ARP cell format.
FIG. 24 is a diagram showing an example of a network layer protocol identification method.
FIG. 25 is a diagram illustrating an example of a cell format when an ARP response using a broadcast channel is performed using an end-to-end ATM connection.
FIG. 26 is a diagram showing an example of the flow of ARP.
FIG. 27 is a diagram showing a correspondence table between network layer addresses and ATM addresses (VPI values) in an ARP server;
FIG. 28 is a diagram showing an example of an ATM connection connection state between a CLSF processing unit in an inter-network connection device and a terminal in an ATM-LAN, and an example of a connection state of an ATM connection between the CLSF processing units in an ATM backbone network.
FIG. 29 is a diagram showing an example (phase 1) of an arrangement method of a CLSF processing unit at the time of initial introduction;
FIG. 30 is a diagram showing a header value added to an ATM cell of a datagram going from the network connection device to the CLSF processing unit;
FIG. 31 is a diagram showing a flow of header conversion.
FIG. 32 is a diagram showing an example (phase 2) of a CLSF processing unit arrangement method when a CLSF processing unit is added.
FIG. 33 shows a table in the ARP server.
FIG. 34 is a diagram showing a connection state of an ATM connection between a call processing unit in an inter-network connecting device and a terminal in an ATM-LAN, and a connection state of an ATM connection between the call processing units in an ATM backbone network.
FIG. 35 is a diagram showing another example of a call processing method in a large-scale network.
FIG. 36 shows an example of an ATM board.
FIG. 37 is a diagram showing an example of an ARP cell in VP routing.
FIG. 38 is a diagram showing an example of the internal configuration of the IWU 13;
FIG. 39 is a diagram showing another example of the internal configuration of the IWU 13;
FIG. 40 shows a datagram communication system in a sub-network.
FIG. 41 shows a datagram communication sequence.
FIG. 42 is a flowchart showing a datagram transmission procedure.
FIG. 43 shows a datagram communication system in a subnetwork.
FIG. 44 shows a datagram communication sequence.
FIG. 45 shows VPI routing.
FIG. 46 is a diagram showing a two-layer network.
FIG. 47 is a diagram showing a connection between ARs;
FIG. 48 is a diagram showing an ATM connection required for datagram communication.
FIG. 49 shows an address space view from ARS481.
FIG. 50 shows an address space view from ARS482.
FIG. 51 is a diagram showing an ATM connection between ARSs;
FIG. 52 shows an address space view from ARS482.
FIG. 53 shows an address space view from ARS481.
FIG. 54 is a view showing a VCI / VPI conversion table in the IWU 476;
FIG. 55 is a view showing a datagram transfer protocol process;
FIG. 56 is a view showing datagram transfer from the terminal 47A to the terminal 47D.
FIG. 57 shows a datagram transfer from terminal 47A to terminal 47D.
FIG. 58 is a diagram showing an example of a VCI / VPI allocation method between ARSs;
FIG. 59 is a diagram showing another example of a VCI / VPI allocation method between ARSs.
FIG. 60 is a diagram showing another example of a VCI / VPI allocation method between ARSs.
FIG. 61 is a diagram showing a VCI / VPI assignment method for datagram transfer;
FIG. 62 is a diagram showing a network configuration.
FIG. 63 is a diagram showing an ATM connection required for datagram transfer;
FIG. 64 is a diagram showing an ATM connection between ARSs;
FIG. 65 is a diagram showing an ATM connection between ARSs;
FIG. 66 is a diagram showing an ATM connection required for datagram transfer;
FIG. 67 is a diagram showing a datagram transfer protocol process.
FIG. 68 shows an example of datagram transfer.
FIG. 69 shows a network configuration.
FIG. 70 is a diagram showing a datagram communication example of terminals 70A → 70B.
FIG. 71 is a diagram showing protocol processing.
FIG. 72 is a diagram showing a datagram communication example of terminals 70A → 70B.
FIG. 73 shows an example of datagram communication from terminal 70A to public network 708.
FIG. 74 is a diagram showing an example of datagram communication between terminals 70A → 70B.
FIG. 75 is a diagram showing an example of datagram communication from the terminal 70A to the public network 708.
FIG. 76 is a diagram showing an ATM connection between terminals 70A and 70B.
FIG. 77 shows an example of datagram communication from terminal 70A to public network 708.
FIG. 78 is a diagram showing an ATM connection between terminals 70A and 70B.
FIG. 79 shows an example of datagram communication from terminal 70A to public network 708.
FIG. 80 is a diagram showing a datagram communication example between the public network 708 and the terminal 70A.
FIG. 81 is a diagram showing a protocol process of the public network 708 → terminal 70A.
FIG. 82 is a diagram showing a datagram communication example between the public network 708 and the terminal 70A.
FIG. 83 is a diagram showing a protocol process from the public network 708 to the terminal 70A.
84 is a diagram showing an image from a network 861. FIG.
FIG. 85 is a diagram showing a network configuration.
FIG. 86 is a diagram showing a network configuration.
FIG. 87 shows a datagram communication example of terminals 87A → 87B.
FIG. 88 is a diagram showing a datagram communication example of terminals 87A → 87C.
FIG. 89 is a diagram showing a datagram communication example of terminals 87A → 87B.
FIG. 90 shows an example of datagram communication between terminals 87A → 87C.
[Explanation of symbols]
11,12 ... ATM-LAN
13. IWU (inter-network connection device)
21 Add / drop processing unit
22. Multiplexer / Demultiplexer
23: CLSF processing unit (connectionless service function processing unit)
24 ... Call processing unit
25 ... IWU management unit
26: Header conversion processing unit
41 to 44: switch nodes
4A-4G ... terminal
91, 92 ... call processing unit
101, 102: Call processing unit
111, 112 ... ATM-LAN
11A, 11B ... call processing unit
131-133 ... ATM-LAN
134 ... IWU (inter-network connection device)
141 ... ATM switch
142 CLSF processing unit (connectionless service function processing unit)
143 ... Call processing unit
144: IWU management unit
14A, 14B ... input processing unit
14X, 14Y ... output processing unit
151-157 ... switch node
15A to 15J: Terminal
171-173: Call processing unit
181 to 183: Call processing unit
191-193: ATM-LAN
201: ATM backbone network
202-204 ... ATM-LAN
20A-20C: IWU (inter-network connection device)
211 to 217: switch node
21A-21J ... Terminal
311 ... ATM-LAN
312 ... ATM backbone network
31A-31B ... terminal
31P ... IWU (inter-network connection device)
31X CLSF processing unit (connectionless service function processing unit)
361 ... ATM interface
362 ARP filter section
363 ARP processing unit
364 ... insertion part
365 bus interface
411,412 ... terminal
413: ARS (address resolution server)
414: CLSF processing unit (connectionless service function processing unit)
415: IWU (inter-network connection device)
41A-41C ... ATM connection
46A-46E ... ATM connection
471 to 474... Subnetwork (ATM network)
475 ... Public network
476 to 479: IWU (inter-network connection device)
47A-47F ... Terminal
481 to 484... ARS (Address Resolution Server)
485-487 ... ATM connection
491-494: CLSF processing unit (connectionless service function processing unit)
495-49B ... ATM connection
571-576 ... ATM connection
581-584 ... ATM connection
591 to 59C: ATM connection
60xx ... ATM connection
611-61A ... ATM connection
621-62A ... ATM connection
63A-63B ... terminal
631 to 634: Subnetwork (ATM network)
635: public network
636 to 639: IWU (inter-network connection device)
63D-63G ... ARS (Address Resolution Server)
63H to 63L: CLSF processing unit outside the sub-network (connectionless service function processing unit)
63M to 63Q: CLSF processing unit in the subnetwork (connectionless service function processing unit)
641-646 ... ATM connection
651-656 ... ATM connection
661-66C ... ATM connection
691-699 ... ATM connection
701 to 706... Subnetwork (ATM network)
707, 708 ... Public network
70A, 70B ... terminals
70xx CLSF processing unit (connectionless service function processing unit)
70E to 70M: IWU (inter-network connection device)
771-776 ... ATM connection
781-784 ... ATM connection
791-797 ... ATM connection
801-805 ... ATM connection
811 CLSF processing unit (connectionless service function processing unit)
812-814 ... ATM connection
831 to 834: ATM connection
851 ... subnetwork (ATM network)
861 to 863: Subnetwork (ATM network)
864: Public network
871-874: CLSF processing unit (connectionless service function processing unit)
87A-87C ... terminal
881-884 ... ATM connection
891-892 ... ATM connection
901 to 905: ATM connection
911-913 ... ATM connection

Claims (4)

A plurality of ATM networks operated in an asynchronous transfer mode;
A plurality of terminals respectively accommodated in the plurality of ATM networks;
A plurality of datagram servers provided at least one throughout the plurality of ATM networks;
An inter-network connection device provided between the plurality of ATM networks and performing internetworking between the ATM networks;
In response to an ARP request for requesting address resolution from an ATM network connected to the inter-network connecting device, the inter-network connecting device is configured to execute the ATM network connecting an address resolution target node to the inter-network connecting device. Response means for performing an ARP response to the ARP request with a reply of an ATM address of an ATM connection connected to the network connection device when the ARP request does not exist;
Connection connection means for connecting the first ATM connection indicated by the ATM address returned by the ARP response from the response means with the second ATM connection set between the network connection device and the datagram server; An ATM communication system comprising a datagram transmitting terminal and the datagram server directly connected by an ATM connection. A plurality of ATM networks operated in an asynchronous transfer mode;
A plurality of terminals respectively accommodated in the plurality of ATM networks;
A plurality of datagram servers provided at least one throughout the plurality of ATM networks;
An inter-network connection device provided between the plurality of ATM networks and performing internetworking between the ATM networks;
The network connection device, routing protocol termination means,
Notifying means for notifying routing information to an ARP server for performing address resolution when receiving an ARP request for requesting address resolution from a first ATM network connected to the network connection device. When,
A first ATM connection indicated by an ATM address returned by an address resolution response from the address resolution server with respect to the information passed by the notifying means, and the network connection device and the datagram server; Connection connection means for connecting to a second ATM connection set between them,
An ATM communication system wherein the datagram transmitting terminal and the datagram server are directly connected by an ATM connection. The connection connection means connects the first ATM connection and the second ATM connection by at least one of an ATM cell header conversion means and an ATM cell switching means. 4. The ATM communication system according to claim 2, wherein the setting is performed by setting at least one of the ATM cell header conversion means and the ATM cell switching means. An ATM network operated in an asynchronous transfer mode;
A plurality of terminals accommodated in the ATM network,
ARP request cell extracting means for extracting an ARP request cell for requesting address resolution addressed to the terminal from ATM cells from the ATM network,
ARP response cell generating means for generating an ARP response cell for responding to the address resolution request based on the ARP request cell extracted by the ARP request cell;
An ATM communication system comprising multiplexing means for multiplexing an ARP response cell generated by the ARP response cell generation means with an ATM cell stream transmitted from the terminal device.

Images