JP5204603B2 - Quadruple computer system and duplex ring network - Google Patents

Description

  The present invention relates to a quadruple computer system that executes predetermined processes while synchronizing them with each other, and a duplex ring network that interconnects computers constituting the quadruple computer system.

  As a method for achieving high reliability of a computer system, there is known a method in which three or more computers execute the same processing and the majority is obtained for the results obtained by the processing of each computer. A problem in such a multiplex computer system having the function of majority decision is how to synchronize the timing of taking the majority vote, that is, synchronization of processing.

  Patent Document 1 discloses an example of a triple computer system that has a clock synchronization bus and uses the clock synchronization bus to synchronize the operation of each computer at a clock level. In the triple computer system, each computer operates with a synchronized clock and appropriately outputs the processing result to the majority circuit. Accordingly, the majority circuit can take a majority vote at any time with respect to the result of the processing of each computer. That is, in the triple computer system disclosed in Patent Document 1, it seems that the problem of process synchronization does not occur.

  However, in the triple computer system disclosed in Patent Document 1, the operation of each computer is synchronized at the clock level, so the timing at which one computer outputs the processing result and the other two computers are When the timing at which the processing result is output deviates even by one clock, the one computer is regarded as malfunctioning (has a failure). Therefore, even when a processing clock shift occurs due to, for example, memory error correction in one computer, it is regarded as malfunctioning. In other words, the synchronization method in the triple computer system disclosed in Patent Document 1 has a strict timing for synchronization, so that even an error correction of the memory cannot be performed, and it is not flexible.

Further, not only the triple computer system disclosed in Patent Document 1, but in the case of a general triple computer system, if any one of the computers fails, the reliability of the processing result by majority vote is determined. It becomes impossible to secure the sex. Similarly, even when one computer is stopped for maintenance, the reliability of the processing result by majority vote cannot be ensured.
JP-A-9-16535

  Therefore, in the present invention, it is assumed that a quadruple computer system is constructed using general-purpose personal computers that operate asynchronously with each other. In the case of a quadruple computer system, even if one computer stops due to a failure or maintenance, a majority vote can be taken based on the processing results of the remaining three computers. In addition, since synchronization of processing between computers operating asynchronously is performed by processing of a program, it is possible to match the processing synchronization deviation in any way. In other words, the flexibility of process synchronization can be increased.

  On the other hand, a new problem occurs in such a quadruple computer system. First, since the process is synchronized by a program, the required time tends to be long. Therefore, there arises a problem of how to shorten the time required for processing synchronization.

  Secondly, if a failure occurs in one of the four computers constituting the quadruple computer system, any communication path configuration can be used between the remaining three computers. The problem of how to construct a more reliable quadruple computer system that can send and receive synchronized data to synchronize with each other and can make a majority decision, that is, Occurs.

  The present invention has been made to solve the above problems, and an object of the present invention is to reduce the time required for process synchronization in a quadruple computer system. Even if a failure occurs in one of the four computers that make up the computer system, the remaining three computers can continue to synchronize and majority process It is to provide a highly reliable quadruple computer system and a duplex ring network.

In order to achieve the object of the present invention, the four computers constituting the quadruple computer system are connected to each other by a store-and-forward dual ring network. The double ring network is constituted by a first ring network and a second ring network that operate independently of each other. At this time, if the four computers are arranged at the vertices of the quadrilateral, the computers arranged at the vertices are connected to each other by communication paths along the sides of the quadrilateral. Thus, the first ring network is configured. In addition, each computer arranged at each vertex of the quadrilateral is connected to a communication path formed along two opposite sides of the four sides of the quadrilateral, and two diagonal lines of the quadrilateral. Are connected to each other through a communication path formed along the line A to form a second ring network. Then, blocking of the second ring network is provided in any one of the communication path portions of the second ring network formed along the two opposite sides of the quadrilateral, The communication path of the first ring network formed by blocking the ring network of the first ring network along a side opposite to the side of the quadrilateral along which the communication path provided with the blocking of the second ring network is provided. Provide in the part.

  As described above, when four computers are connected to each other in a store-and-forward type dual ring network, as described in detail in the embodiment, each computer is connected to a double ring network. All other three computers will be adjacent via at least one. Therefore, it is possible to receive the synchronization data for synchronizing the processing among the four computers directly from all the other three computers, that is, in the middle without interposing another computer. . Therefore, each computer can shorten the time required for process synchronization.

  Further, in the case of a store-and-forward type double ring network configured as described above, even if a failure occurs in one of the four computers, the double ring The connection between the three computers is maintained via at least one of the networks. Accordingly, since the synchronized data can be transmitted and received between the three computers, a majority decision can be taken with respect to the processing results of the three computers.

  Here, the store-and-forward type ring network is a network in which so-called node devices such as computers, routers, switching hubs and the like are connected to each other via a communication path, and the entire communication path has a ring shape. Each of the node devices receives a transmitted packet, temporarily buffers (temporarily stores) the packet, and then transmits the packet to an adjacent node device.

  According to the quadruple computer system of the present invention, the time required for the process synchronization can be shortened. Furthermore, among the four computers constituting the quadruple computer system, one computer can be used. Even when a failure occurs, it is possible to achieve such high reliability that the processing can be synchronized and the majority can be continuously performed among the remaining three computers.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram showing an example of the configuration of a quadruple computer system and a dual ring network according to an embodiment of the present invention.

  As shown in FIG. 1A, the quadruple computer system 7 includes four computers 1, each of which includes a CPU (Central Processing Unit) 11, a main memory 12, and two NICs (Network Interface Card) 13 is included. These four computers 1 are connected to each other by a double ring network. In FIG. 1A, the first ring network is drawn as a thick solid line as a network (# 1) 2a. The ring network No. 2 is drawn as a thick broken line as the network (# 2) 2b.

  Furthermore, as shown in FIG. 1A, each of the two NICs 13 included in each computer 1 includes two transmission / reception ports 131. In FIG. 1A, the transmission / reception port 131 is depicted as a small square terminal on the upper or lower side of the rectangular block representing the NIC 13.

In addition, the network (# 1) 2a drawn by a thick solid line is connected to the two transmission / reception ports 131 of the NIC 13 on one side (left side in FIG. 1A) of each computer 1, and the other (FIG. In a), the network (# 2) 2b drawn by a thick broken line is connected to the two transmission / reception ports 131 of the NIC 13 on the right side).

  FIGS. 1B and 1C are schematic views showing the connection relationship of the four computers in FIG. 1A. As shown in FIG. 1B, the network (# 1) 2a, which is the first ring network, connects four computers 1 to (# 1)-(# 2)-(# 3)-(# 4). -Connect in a ring shape in the order of ((# 1)). As shown in FIG. 1C, the network (# 2) 2b, which is the second ring network, connects four computers 1 to (# 2)-(# 4)-(# 1)-(# 3) Connect in a ring shape in the order of ((# 2)).

  Further, as shown in FIG. 1A, blocking 3 is provided at both ends of the communication path connecting the computers (# 4) to (# 1) of the network (# 1) 2a. Blocking 3 is provided at both ends of the communication path connecting the computers (# 3) and (# 2) in the network (# 2) 2b. In the present specification, when a part connecting two computers 1 is extracted from the ring network, it is called a communication path.

  Here, the blocking 3 is a mark that means that the packet transmission / reception function of the transmission / reception port 131 that is in contact with the blocking 3 is stopped, and in order to prevent a packet from going around the ring network even in a general ring network. Provided. Such blocking 3 is realized by the NIC 13 including the transmission / reception port 131 in contact with the blocking 3 stopping the packet transmission / reception function of the transmission / reception port 131. As described above, the transmission / reception port 131 in which the packet transmission / reception function is stopped in order to set the blocking 3 is referred to as a blocking port.

  Next, characteristics of the connection configuration of the four computers 1 in the dual ring network (network (# 1) 2a and network (# 2) 2b) used in the quadruple computer system 7 according to the present embodiment will be described. .

  In the present embodiment, as shown in FIGS. 1A to 1C, it is assumed that four computers 1 constituting the quadruple computer system 7 are arranged at each vertex of a quadrilateral. In that case, the network (# 1) 2a, which is the first ring network, connects each computer 1 via a communication path along each side of the quadrilateral as shown in FIG. 1 (b). Composed. Further, as shown in FIG. 1C, the network (# 2) 2b which is the second ring network includes communication paths along two opposite sides of the four sides of the quadrilateral, and the four sides. Each computer 1 is configured to be connected by a communication path along two diagonal lines of the shape.

  In the above configuration, the network (# 1) 2a connects four computers 1 in a ring shape (O-shape), but the network (# 2) 2b connects four computers 1 to each other. It is connected in a horizontal 8-character form.

  In this case, the blocking 3 of the network (# 2) 2b is a part of the communication path constituting the network (# 2) 2b, and is a communication path provided along the two opposite sides of the quadrilateral. Of these, it is provided in the communication channel portion of one communication channel. Further, the blocking 3 of the network (# 1) 2a is a communication path portion constituting the network (# 1) 2a, and is an edge facing the side along the communication path portion where the network (# 2) 2b is provided. Is provided in the communication path portion of the communication path along the line.

  That is, as shown in FIG. 1A, when the blocking 3 of the network (# 2) 2b is provided in a communication path portion along the side connecting the computers (# 2) to (# 3), The blocking 3 of the network (# 1) 2a is provided in a communication path portion that connects the computers (# 4) to (# 1) along the side opposite to the side.

  In FIG. 1, the network (# 2) 2b connects four computers 1 in a horizontal 8-character form, but may be connected in a vertical 8-character form. In that case, of the communication paths that make up the network (# 2) 2b, the communication paths along the quadrilateral with the four computers 1 as vertices are along the upper or lower side of the quadrilateral. Therefore, blocking 3 is provided on one of the communication paths (for example, a communication path connecting computers (# 3)-(# 4)). The blocking 3 of the network (# 1) 2a is a communication path (for example, a communication path connecting the computers (# 1) to (# 2)) opposite to the communication path in which the blocking is provided in the network (# 2) 2b. Provided.

  As described above, the feature of the connection structure of the double ring network has been described assuming that four computers 1 are arranged at each vertex of the quadrilateral. The physical arrangement position of the computer 1 is not limited. The characteristics of the dual ring network connection configuration described above represent a topological connection relationship, and the physical arrangement of the four computers 1 may be any arrangement.

  Next, in the quadruple computer system 7, it is necessary to explain the effects of configuring the network (# 1) 2a and the network (# 2) 2b as described above. A configuration and a method of synchronizing processes in the computer 1 will be described.

  FIG. 2 is a diagram showing an example of the configuration of the computer 1 used in the quadruple computer system 7 and the NIC 13 included in the computer 1 according to the embodiment of the present invention. As shown in FIG. 2 and as shown in FIG. 1 as a part of the configuration, the computer 1 includes a CPU 11, a main memory 12, two NICs 13, etc. connected to each other via an internal bus 14. Is done. At this time, the computer 1 may further include a hard disk device, a display device, a keyboard, various sensor devices, a control device, and the like.

  The NIC 13 includes a transmission / reception port 131, a port connection switch 132, a packet buffer memory 133, a transmission / reception control unit 134, and the like.

  The transmission / reception port 131 is configured by an electrical transmission / reception circuit and a connector jack for connecting a network cable, which are not shown. For example, an Ethernet (registered trademark) specification communication cable is connected to the connector jack, and communication paths 21a and 21b (see FIG. 2) connecting the two computers 1 are formed by the communication cable.

  2 constitutes part of the network (# 1) 2a in FIG. 1, and the communications path 21b constitutes part of the network (# 2) 2b. Therefore, the left NIC 13a shown in FIG. 2 controls communication in the network (# 1) 2a, and the right NIC 13b controls communication in the network (# 2) 2b.

  In FIG. 2, the port connection switch 132 corresponds to a so-called L2 switch, and not only functions as a simple path switch but also functions such as packet destination address determination and attribute determination, and a function for operating the transmission / reception port 131 as a blocking port. Etc. The packet buffer memory 133 is a memory for temporarily storing packets received via the transmission / reception port 131, and is configured by, for example, a DRAM (Dynamic Random Access Memory).

  The transmission / reception control unit 134 controls the port connection switch 132 and the packet buffer memory 133 as appropriate, thereby performing various controls related to packet transmission / reception. For example, if the received packet is addressed to its own computer 1, the transmission / reception control unit 134 notifies the CPU 11 to that effect, and receives the received data obtained by removing the header portion from the received packet. Control to transfer to 12 is performed. When the CPU 11 outputs transmission data, the transmission / reception control unit 134 configures a transmission packet by appropriately adding a header part to the transmission data, and transmits and receives both left and right via the port connection switch 132. Control to send the transmission packet from the port 131 is performed. Further, the transmission / reception control unit 134 also has a function of controlling the setting change process of the blocking 3 due to a failure of the other computer 1 and the stop of the transmission / reception function at the time of the setting change process.

  In FIG. 2, the main memory 12 has a synchronized data area 121. Here, the synchronization data area 121 is synchronized with the computer 1, that is, the synchronization data generated by the CPU 11 (for example, the synchronization data # 1) and the synchronization transmitted from the other three computers 1. Data (for example, synchronization data # 2 to # 4). The handling of these synchronization data # 1 to # 4 will be described with reference to FIG.

  FIG. 3 is a diagram illustrating an example of a process synchronization flow in each computer 1. Here, the process synchronization means that the execution progress of a program is matched between a plurality of computers that execute the program of the same process. In the present embodiment, processing is synchronized among four computers 1 (see FIG. 1) constituting the quadruple computer system 7, but these four computers 1 operate with clocks asynchronous with each other. It shall be. The process is synchronized every time a predetermined group of processes (hereinafter referred to as a task) is completed.

  As shown in FIG. 3, when the CPU 11 finishes a task A (step S0), the CPU 11 includes, for example, an identification number of the task A for the transmission / reception control unit 134 included in each of the two NICs 13a and 13b. Sending out the synchronized data is instructed (step S1).

  When the transmission / reception control unit 134 included in each of the NICs 13a and 13b receives an instruction to send the synchronization data from the CPU 11, the designated synchronization data is converted into a packet of a predetermined format, and the port connection switch 132 and the two transmission / reception units The data is sent to the communication paths 21a and 21b via the port 131 (step S11). Accordingly, the same synchronization data is transmitted from each computer 1 to each of the network (# 1) 2a and the network (# 2) 2b.

  A packet including the synchronization data is transmitted as a broadcast packet, and it is assumed that the packet includes information for identifying that the packet is a packet including the synchronization data.

  On the other hand, each of the transmission / reception control units 134 of the NICs 13a and 13b waits for reception of the synchronization data transmitted from the other computer 1, and receives the synchronization data transmitted from the other computer 1 (step S12). The received synchronization data is stored in the synchronization data area corresponding to the transmission source computer 1 (step S13). For example, if the transmission source of the received synchronization data is the computer (# 2), the synchronization data is stored in the synchronization data # 2 portion of the synchronization data area 121.

  The operation of storing the synchronization data received by the transmission / reception control unit 134 in the synchronization data area 121 is based on, for example, DMA (Direct Memory Access).

  As described above, since the same synchronization data is transmitted from both the computers 1 to both the communication paths 21a and 21b, in the computer 1 that receives the same, the respective transmission / reception control units 134 of the NICs 13a and 13b Synchronized data with the same transmission source is received independently and stored in each packet buffer memory 133. Each transmission / reception control unit 134 transfers the synchronization data to the synchronization data area 121 when the synchronization data arrives first, and discards the synchronization data when it arrives later.

  In order to realize this operation, for example, for each synchronization data in the synchronization data area 121 (however, except for the synchronization data corresponding to its own computer 1), a flag indicating an incoming call is provided, and transmission / reception is performed. When the control unit 134 reads the received flag and the received flag is not set, step S13 is executed. When the received flag is set, step S13 is skipped. That's fine.

  While receiving the synchronization data from the other computer 1 as described above, the CPU 11 verifies the synchronization data stored in the synchronization data area 121 (step S2). Here, the verification of the synchronization data is a process for determining whether or not the synchronization data transmitted from another computer 1 is valid. For example, if the synchronization data transmitted from another computer 1 and the synchronization data generated by the processing of its own computer 1 are the same or satisfy a predetermined relationship, the synchronization data Assume that the data is valid. The predetermined relationship refers to, for example, a relationship in which the remainder codes and hashes between the synchronized data are the same, or the same number sequence relationship.

  As a result of the verification, if valid synchronization data has been received from all the other computers 1 (Yes in step S3), the next task is activated (step S4). At this time, if the next task is task B, CPU 11 starts processing of task B (step S5). If valid synchronization data has not yet been received from all other computers 1 (No in step S3), the synchronization data is verified again (step S2).

  Here, “all computers 1” refers to the other three computers other than itself when all of the four computers 1 constituting the quadruple computer system 7 are operating normally. If any one of the four computers is not operating due to a failure, it refers to the other two operating computers other than itself.

  Next, the effects produced by the quadruple computer system 7 configured as described above will be described with reference to FIGS.

  FIG. 4 is a diagram showing an example of the connection configuration of four computers 1 in the quadruple computer system 7 shown in FIG. 1, and (a) shows the computer 1 according to the connection order of the network (# 1) 2a. (B) is a diagram showing the arrangement of the computers 1 according to the connection order of the network (# 2) 2b. That is, FIG. 4 (a) and FIG. 4 (b) differ only in the display arrangement of the computer 1, and both have the connection configuration of the computer 1 in the quadruple computer system 7 shown in FIG. It is a representation. 4A and 4B, the position of the blocking 3 is also matched with the position of the blocking 3 in the connection configuration of the four computers 1 shown in FIG.

  As described above, FIGS. 4A and 4B show the same thing. From FIG. 4A, four computers 1 are connected to the network (# 1) 2a. It is easy to see that they are connected in a loop in the order of (# 1)-(# 2)-(# 3)-(# 4). From FIG. 4B, four computers 1 are connected to the network. (# 2) It is easy to see that 2b is connected in a loop in the order of computers (# 2)-(# 4)-(# 1)-(# 3).

  FIG. 5 shows that the computers 1 constituting the quadruple computer system 7 shown in FIG. 1 are adjacent to each other via a double ring network (network (# 1) 2a and network (# 2) 2b). It is the figure which showed having done.

  In FIG. 5, the connection relationship of the computer 1 is further simplified and displayed based on the description in FIG. That is, in each of FIGS. 5A to 5D, the upper diagram shows the arrangement of the computers 1 in the order of connection of the network (# 1) 2a, and the lower diagram shows the network (# 2). 2) An arrangement of the computers 1 in the order of connection 2b. Therefore, in the arrangement of the upper and lower computers 1, the computers 1 having the same # numbers represent the same computer 1 as an entity.

  In FIG. 5A, the computer (# 1) marked with a circle represents the reference computer 1, and the curly bracket ({) opened above is adjacent to the reference computer 1. 2 is a diagram showing a range of a computer 1. FIG. That is, FIG. 5A shows that the computer (# 1) is adjacent to the computer (# 2) via the network (# 1) 2a, and the computer (# 3) and the computer (# 3) are connected via the network (# 2) 2b. This indicates that it is adjacent to (# 4).

  Similarly, FIG. 5B shows that the computer (# 2) is adjacent to the computers (# 1) and (# 3) via the network (# 1) 2a, and is also connected via the network (# 2) 2b. It is adjacent to the computer (# 4). FIG. 5C shows that the computer (# 3) is adjacent to the computers (# 2) and (# 4) via the network (# 1) 2a, and is also connected via the network (# 2) 2b. It is adjacent to (# 1). FIG. 5D shows that the computer (# 4) is adjacent to the computer (# 3) via the network (# 1) 2a, and the computer (# 1) and the computer (# 1) are connected via the network (# 2) 2b. It is adjacent to (# 2).

  As described above, in the present embodiment, each of the four computers 1 is adjacent to any of the other three computers 1 via the network (# 1) 2a or the network (# 2) 2b. Will be.

  In the present embodiment, as described above, the synchronization data at the time of the process synchronization is transmitted to both the network (# 1) 2a and the network (# 2) 2b. Process synchronization is performed using the received synchronization data. That is, each computer 1 can directly receive the synchronization data from the other three adjacent computers 1.

  Here, a quadruple computer system of a comparative example is assumed. In the quadruple computer system of the comparative example, it is assumed that the dual link network connecting the four computers has a simple duplex configuration. That is, it is assumed that the connection relationship for connecting the four computers is the same in both the first network and the second network. Therefore, both the first network and the second network are computers (# 1)-(# 2)-(# 3)-(# It is represented as a ring network connected in the order of 4).

  In the case of this comparative example, the computer (# 1) can directly receive the synchronization data of the computer (# 2), but the synchronization data of the computer (# 3) Will be received via. In this case, the synchronization data transmitted from the computer (# 3) is temporarily stored in the packet buffer memory 133 of the computer (# 2) and then transmitted to the computer (# 1). As a result, the synchronization data transmitted from the computer (# 3) arrives at the computer (# 1) later than the computer (# 2). Further, since the synchronization data transmitted from the computer (# 4) passes through the computer (# 3) and the computer (# 2), it arrives at the computer (# 1) later.

  Therefore, in the case of this comparative example, it takes a long time for a computer to receive all the synchronization data of the other three computers, compared to the case of the embodiment of the present invention. Accordingly, the time required for the process synchronization is also increased accordingly. In other words, according to the embodiment of the present invention, the time required for processing synchronization is shortened.

  6 shows that when one computer 1 out of the four computers 1 constituting the quadruple computer system 7 of FIG. 1 fails, the other three computers 1 are connected to a double ring network ( It is the figure which showed that it exists in the state mutually connected via one network of the network (# 1) 2a and the network (# 2) 2b).

  In FIG. 6A, a computer (# 1) marked with a cross indicates a computer 1 in which a failure has occurred, and the braces ({) opened above are connected to three computers 1 continuously. It means that it is in the state. The degree of failure of the computer (# 1) here is severe, and it is assumed that all the functions from the CPU 11 to all the transmission / reception ports 131 are lost.

  As shown in FIG. 6A, when a failure occurs in the computer (# 1), the connection of the computers (# 2)-(# 3)-(# 4) is maintained in the network (# 1) 2a. However, in the network (# 2) 2b, the connection is disconnected by the faulty computer (# 1). However, since the computers (# 2), (# 3), and (# 4) can send and receive synchronized data to and from each other via the connection by the network (# 1) 2a, the processes are synchronized. be able to.

  Similarly, FIG. 6 (b) shows that even if a failure occurs in the computer (# 2), the computers (# 4)-(# 1)-(# 3) are connected by the network (# 2) 2b. Indicates that the connection is maintained. FIG. 6C shows the connection of computers (# 2)-(# 4)-(# 1) via the network (# 2) 2b even when a failure occurs in the computer (# 3). Is maintained. FIG. 6D shows the connection of computers (# 1)-(# 2)-(# 3) by the network (# 1) 2a even when a failure occurs in the computer (# 4). Is maintained.

  Therefore, in any case, even if a failure occurs in one computer 1, the connection of the remaining three computers 1 is maintained by the network (# 1) 2a or the network (# 2) 2b. Therefore, the synchronization data can be transmitted and received between the three computers 1, so that the processing can be synchronized.

  As described above, in the quadruple computer system 7 of the present embodiment, even if a failure occurs in any one of the computers 1, the remaining three connections are maintained. The three computers 1 can synchronize the processing, and when the processing is synchronized, the majority of the processing results can be taken.

  By the way, in the quadruple computer system of the comparative example described above, when a failure occurs in the computer (# 2) or (# 3) (see the upper diagrams in FIGS. 6B and 6C). The connection of the remaining three computers is not maintained. Accordingly, it becomes impossible to synchronize the processing among the remaining three computers, and it becomes impossible to take a majority decision of the processing results.

  As is well known, in a ring network, it is possible to configure a network excluding a computer in which a failure has occurred by changing the blocking position. This is also possible in the case of the comparative example described above. If the blocking position is changed so as to exclude the computer in which the failure has occurred, the processing can be synchronized again by the remaining three computers. The majority of results can be taken.

  However, in that case, when changing the blocking position, communication in the network is disabled although it is a short time. On the other hand, in the case of the present embodiment, in any one of the double ring networks, the connection of the three computers is maintained, so that the other ring network blocks. Even if the position is changed, communication is not disabled.

  Therefore, it can be said that the quadruple computer system 7 of this embodiment has higher reliability than the quadruple computer system of the comparative example in the above points.

  FIG. 7 is a diagram showing an example in which another computer or a network switch is connected to the duplex ring network in the duplex computer system 7 shown in FIG. In FIG. 7, the other computers are represented as computer (# 5) 1a and computer (# 6) 1b, and the network switches are represented as LANSW (# 1) 4a and LANSW (# 2) 4b. The network switch here refers to a so-called switching hub or router.

  As shown in FIG. 7, the computer (# 5) 1a and the LANSW (# 1) 4a are connected to a communication path portion connecting the computer (# 4) and the computer (# 1) of the network (# 1) 1a. . In FIG. 4A, this communication path portion is a portion that has been excluded from a communicable network due to blocking 3. However, in the case of FIG. 7, the computer (# 5) 1a and the LANSW (# 1) 4a need to communicate with the computers (# 1) to (# 4) constituting the quadruple computer system 7. Therefore, the blocking 3 is provided, for example, between the computer (# 5) 1a and the LANSW (# 1) 4a (not shown).

  Thus, as long as at least one of the computer (# 5) 1a and the LANSW (# 1) 4a is connected to the communication path portion, the effect of the quadruple computer system 7 described with reference to FIGS. Is not lost.

  Similarly, the computer (# 6) 1b and the LANSW (# 2) 4b are connected to a communication path portion connecting the computer (# 3) and the computer (# 4) of the network (# 2) 1b. In FIG. 4A, this communication path portion is a portion that has been excluded from a communicable network due to blocking 3. However, in the case of FIG. 7, the computer (# 6) 1b and the LANSW (# 2) 4b need to communicate with the computers (# 1) to (# 4) constituting the quadruple computer system 7. Therefore, the blocking 3 is provided, for example, between the computer (# 6) 1b and the LANSW (# 2) 4b (not shown).

  Thus, as long as at least one of the computer (# 6) 1b and the LANSW (# 2) 4b is connected to the communication path portion, the effect of the quadruple computer system 7 described with reference to FIGS. Is not lost.

The figure which showed the example of the structure of the quadruple computer system and duplex ring network which concern on embodiment of this invention. The figure which showed the example of a structure of NIC used in the computer used with the quadruple computer system which concerns on embodiment of this invention, and the computer. The figure which showed the example of the flow of a process synchronization in each computer. The figure which showed the example of the connection structure of four computers in a quadruple computer system. The figure which showed that each computer which comprises a quadruple computer system mutually adjoins via a double ring network. When a failure occurs in one of the four computers that make up the quadruple computer system, the other three computers are connected to each other via one of the double ring networks. The figure which showed that it exists in the state. The figure which showed the example in the case of connecting another computer and a network switch with respect to the double ring network in a quadruple computer system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Computer 3 Blocking 2a Network (# 1): 1st ring network 2b Network (# 2): 2nd ring network 7 Quadruple computer system 11 CPU
12 Main memory 13 NIC
14 Internal bus 121 Synchronized data area 131 Transmission / reception port 21a, 21b Communication path 132 Port connection switch 133 Packet buffer memory 134 Transmission / reception control unit

Claims (10)

A quadruple computer system that is connected to each other by a store-and-forward dual ring network and includes four computers that transmit and receive predetermined synchronization data to synchronize processing. There,
The double ring network is composed of a first ring network and a second ring network that operate independently of each other,
The first ring network is formed such that the computers arranged at the vertices of the four computers are arranged at the vertices of the quadrilateral along the sides of the quadrilateral. Configured to connect to each other via a
In the second ring network, the computers arranged at the vertices of the quadrilateral are connected to communication paths formed along two opposite sides of the four sides of the quadrilateral, and the 4 Configured to be connected to each other by communication paths formed along two diagonal lines of the side ,
The blocking of the second ring network is provided in one of the communication path portions of the second ring network formed along the two opposite sides of the quadrilateral,
The blocking of the first ring network is the first ring network formed along a side opposite to the side of the quadrilateral along the communication path provided with the blocking of the second ring network. A quadruple computer system provided in a communication path portion . When each of the four computers performs the process synchronization,
Sending predetermined synchronization data to both the first ring network and the second ring network;
Of the four computers, only the synchronization data that has arrived first is received out of the synchronization data respectively transmitted via the double ring network from each of the other computers except the computer itself. ,
When the synchronization data is received from all of the other computers other than the computer, and the received synchronization data and the synchronization data generated by the computer are the same or satisfy a predetermined relationship, the process synchronization The quadruple computer system according to claim 1 , wherein: Formed along one side of the two opposite sides of the quadrilateral, the communication path portion of the second ring network, and formed along the side facing the one side, The at least one node device comprising a computer or a network switch different from the four computers is connected to at least one of the communication path portions of the first ring network. Item 4. A quadruple computer system according to item 1. A quadruple computer system that is connected to each other by a store-and-forward dual ring network and includes four computers that transmit and receive predetermined synchronization data to synchronize processing. There,
The four computers include a first computer, a second computer, a third computer, and a fourth computer,
The double ring network is composed of a first ring network and a second ring network that operate independently of each other,
The first ring network includes a communication path that connects the first computer and the second computer, a communication path that connects the second computer and the third computer, and the third computer. A communication path connecting the fourth computer, and a communication path connecting the fourth computer and the first computer;
The second ring network includes a communication path that connects the second computer and the fourth computer, a communication path that connects the fourth computer and the first computer, and the first computer. A communication path connecting the third computer and a communication path connecting the third computer and the second computer ;
The blocking of the first ring network is provided in a communication path portion connecting the fourth computer and the first computer of the first ring network,
The quadruple computer system according to claim 2, wherein blocking of the second ring network is provided in a communication path portion connecting the third computer and the second computer of the second ring network . When each of the four computers performs the process synchronization,
Sending predetermined synchronization data to both the first ring network and the second ring network;
Of the four computers, only the synchronization data that has arrived first is received out of the synchronization data respectively transmitted via the double ring network from each of the other computers except the computer itself. ,
When the synchronization data is received from all of the other computers other than the computer, and the received synchronization data and the synchronization data generated by the computer are the same or satisfy a predetermined relationship, the process synchronization The quadruple computer system according to claim 4 , wherein: A communication path portion connecting the fourth computer and the first computer in the first ring network; and the third computer and the second computer in the second ring network. channel portion connected to at least one communication path portion of claim 4, wherein the one or more node devices consisting of another computer or network switch and four computers, characterized in that it is connected Quadruple computer system. A store-and-forward type system for interconnecting the four computers in a quadruple computer system configured to include four computers that synchronize processing by transmitting and receiving predetermined synchronization data to and from each other. A dual ring network,
The duplex ring network is composed of a first ring network and a second ring network that operate independently of each other,
The first ring network is formed such that the computers arranged at the vertices of the four computers are arranged at the vertices of the quadrilateral along the sides of the quadrilateral. Configured to connect to each other via a
In the second ring network, the computers arranged at the vertices of the quadrilateral are connected to communication paths formed along two opposite sides of the four sides of the quadrilateral, and the 4 Configured to be connected to each other by communication paths formed along two diagonal lines of the side ,
The blocking of the second ring network is provided in one of the communication path portions of the second ring network formed along the two opposite sides of the quadrilateral,
The blocking of the first ring network is the first ring network formed along a side opposite to the side of the quadrilateral along the communication path provided with the blocking of the second ring network. A duplex ring network provided in a communication path portion . Formed along one side of the two opposite sides of the quadrilateral, the communication path portion of the second ring network, and formed along the side facing the one side, The at least one node device comprising a computer or a network switch different from the four computers is connected to at least one of the communication path portions of the first ring network. Item 8. The duplex ring network according to item 7 . A store-and-forward type system for interconnecting the four computers in a quadruple computer system configured to include four computers that synchronize processing by transmitting and receiving predetermined synchronization data to and from each other. A dual ring network,
The four computers include a first computer, a second computer, a third computer, and a fourth computer,
The duplex ring network is composed of a first ring network and a second ring network that operate independently of each other,
The first ring network includes a communication path that connects the first computer and the second computer, a communication path that connects the second computer and the third computer, and the third computer. A communication path connecting the fourth computer, and a communication path connecting the fourth computer and the first computer;
The second ring network includes a communication path that connects the second computer and the fourth computer, a communication path that connects the fourth computer and the first computer, and the first computer. A communication path connecting the third computer and a communication path connecting the third computer and the second computer ;
The blocking of the first ring network is provided in a communication path portion connecting the fourth computer and the first computer of the first ring network,
The blocking of the second ring network is provided in a communication ring portion that connects the third computer and the second computer of the second ring network. A communication path portion connecting the fourth computer and the first computer in the first ring network; and the third computer and the second computer in the second ring network. channel portion connected to at least one communication path portion of claim 9, wherein the one or more node devices consisting of another computer or network switch and four computers, characterized in that it is connected Dual ring network.

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