JP2013168815A - Apparatus and method for identifying transmission source causing congestion - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide techniques for quickly and reliably identifying a transmission source that caused an abnormal condition of a communication node due to communication congestion or the like.SOLUTION: The apparatus for identifying a transmission device causing congestion of a communication node includes: an object-to-be-isolated determination unit that separates a plurality of transmission devices connected to the communication node into a group of connected transmission devices and a group of disconnected transmission devices according to a prescribed isolation method; a communication connect/disconnect unit that connects communication between transmission devices belonging to the group of connected transmission devices and the communication node, and disconnects communication between transmission devices belonging to the group of disconnected transmission devices and the communication node according to the isolation determined by the object-to-be-isolated determination unit; and a congestion determination unit that identifies the transmission device causing congestion by determining whether packets transmitted from the transmission devices belonging to the group of connected transmission devices congest the communication node. The object-to-be-isolated determination unit, the communication connect/disconnect unit, and the congestion determination unit are repeatedly run until the transmission device causing congestion is identified.

Description

  The present invention relates to a technique for identifying a source that causes a communication node that has become abnormal due to communication congestion or the like.

  There is a case where the communication node falls into an abnormal state such as congestion only by communication of some transmission sources. At this time, in order to identify the transmission source of the cause communication, as a conventional technique, a communication packet existing in a buffer or the like inside the node is confirmed and a suspicious communication is estimated therefrom, a command input to the node or There is a method of specifying a transmission source based on how the state of congestion or the like changes due to partial communication stop / communication by connecting / disconnecting a cable in the network.

JP 2006-319748 A JP 2006-319749

  However, as for the former of the above-described prior art, when the cause of node instability cannot be identified, just looking at the packet inside the node may not provide sufficient accuracy for estimation and may not lead to a quick solution. As for the latter, as shown in FIG. 1, it is usually necessary to specify a sub-interface such as VLAN, stop and communicate with commands one by one, and then repeat the operation to input a status confirmation command. There is a problem that quick resolution is difficult.

  Therefore, in view of the above-described problems, an object of the present invention is to provide a technique for quickly and surely identifying a transmission source that causes a communication node that has become abnormal due to communication congestion or the like.

  In order to solve the above problem, one feature of the present invention is an apparatus for identifying a transmission apparatus that causes congestion of a communication node, and communicates a plurality of transmission apparatuses connected to the communication node according to a predetermined isolation method. A cut target determining unit that splits into a transmission device group and a cut transmission device group, and communication between the transmission device of the communication transmission device group and the communication node according to the cut result by the cut target determination unit, the cut transmission device A communication communication / stop control unit that blocks communication between a group of transmission devices and the communication node; and determining whether a packet transmitted from the transmission device of the communication transmission device group congests the communication node. A congestion determination unit that identifies the transmission device that causes the congestion, and until the transmission device that causes the congestion is identified, Relates to a device for communication, stop control unit and said congestion determining unit is repeatedly executed.

  According to the present invention, it is possible to provide a technique for quickly and surely specifying a transmission source that is a cause in a communication node that is in an abnormal state due to communication congestion or the like.

FIG. 1 is a schematic diagram of processing for specifying a packet transmission source that causes congestion according to the conventional technology. FIG. 2 is a block diagram illustrating a communication system according to an embodiment of the present invention. FIG. 3 is a block diagram illustrating a communication system according to another embodiment of the present invention. FIG. 4 is a block diagram illustrating a configuration of a transmission source specifying apparatus according to an embodiment of the present invention. FIG. 5 is a flowchart showing overall processing in the transmission source specifying device according to the embodiment of the present invention. FIG. 6 is a schematic diagram illustrating a binary search method according to an embodiment of the present invention. FIG. 7 is a flowchart showing the separation process based on the binary search method according to the embodiment of the present invention. FIG. 8 is a flowchart showing the separation process based on the binary search method according to another embodiment of the present invention. FIG. 9 is a flowchart showing the separation process based on the binary search method according to another embodiment of the present invention. FIG. 10 is a flowchart showing the separation process based on the binary search method according to another embodiment of the present invention. FIG. 11 is a schematic diagram illustrating a sequential search method according to an embodiment of the present invention. FIG. 12 is a flowchart showing the separation process based on the sequential search method according to an embodiment of the present invention. FIG. 13 is a flowchart showing the separation process based on the sequential search method according to another embodiment of the present invention. FIG. 14 is a flowchart showing the separation process based on the sequential search method according to another embodiment of the present invention.

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

  A communication system according to some embodiments of the present invention will be described with reference to FIGS. FIG. 2 is a block diagram illustrating a communication system according to an embodiment of the present invention.

  As shown in FIG. 2, the communication system 10 according to an embodiment of the present invention includes a communication node 50, a transmission source specifying device 100, one or more packet transmission devices 150-1, 150-2,. 150-n (hereinafter collectively referred to as packet transmission device 150). In the present embodiment, the transmission source specifying apparatus 100 is configured as an apparatus independent of the communication node 50 and is connected between the communication node 50 and the packet transmission apparatus 150 via one or more interfaces.

  The communication node 50 is typically composed of a router such as an edge router that accommodates users. The communication node 50 includes a processing unit such as a CPU (Central Processing Unit) that executes various processes, a memory unit that stores a computer program and data for causing the processing unit to execute various processes, a storage unit such as storage, and a packet. It comprises a communication unit that provides a router function such as packet transfer between the transmission device 150 and an upper node (not shown). When the communication node 50 receives various packets such as a control packet from the packet transmission device 150, the processing unit processes the received packet. However, since the processing by this processing unit is relatively slow compared to hardware processing such as packet transfer, the communication node 50 becomes congested when a control request exceeding the processing capability of the processing unit is received. End up. Although it is possible to reduce the probability of congestion by considering these processing amounts when constructing a network, a large amount of control packets are transmitted to the communication node 50 due to a failure of the packet transmission device 150 or the like. As a result, the communication node 50 may become congested. The communication node 50 according to the present invention is not limited to the above-described router, and is any other device that receives various requests from a plurality of client devices such as the packet transmission device 150 and executes processing according to the received requests. There may be.

  The transmission source specifying device 100 specifies the transmission source of the packet that causes the above-described congestion, as will be described in detail below. In one embodiment, the transmission source identification device 100 may identify the packet transmission device 150 that is transmitting a packet that causes congestion to the communication node 50 by the IP address of the packet transmission device 150 or the like. Alternatively, in another embodiment, the transmission source identification device 100 transmits a packet that causes congestion to the communication node 50, and is an interface (IF) between the communication node 50 and one or more packet transmission devices 150. May be specified by a VLAN (Virtual Local Area Network) number or the like. Similarly to the communication node 50, the transmission source specifying device 100 may be configured by a hardware configuration such as a processing unit, a storage unit, and a communication unit. In the illustrated embodiment, the transmission source identification device 100 is fixedly connected between the communication node 50 and the packet transmission device 150, but typically, the transmission source identification device 100 is connected to the communication node 50. In response to the detection of an abnormal state such as congestion or in response to an activation instruction from the communication system 10.

  The packet transmission device 150 is typically composed of a user device or a client device having a packet communication function. The packet transmission device 150 communicates packets with various service providers via the communication node 50. These packets are typically composed of a data packet storing actual data and a control packet storing various control data for controlling the communication.

  FIG. 3 is a block diagram illustrating a communication system according to another embodiment of the present invention. The embodiment shown in FIG. 3 is the same as the embodiment shown in FIG. 2 except that the transmission source specifying device 100 is built in the communication node 50. In this embodiment, the transmission source specifying device 100 is activated in response to detection of an abnormal state such as congestion in the communication node 50 or in response to an activation instruction from the communication system 10.

  With reference to FIG. 4, the configuration of a transmission source specifying apparatus according to an embodiment of the present invention will be described. FIG. 4 is a block diagram illustrating a configuration of a transmission source specifying apparatus according to an embodiment of the present invention.

  As shown in FIG. 4, the transmission source specifying device 100 includes a system interface unit 102, a communication node interface unit 104, a packet transmission device interface unit 106, a separation target determination unit 108, and a communication communication / stop control unit 110. And a congestion determination unit 112.

  The system interface unit 102 is connected to the communication system 10 and exchanges various types of information and data with the transmission source identification device 100. More specifically, the system interface unit 102 receives from the communication system 10 various parameters related to the communication node 50 that is the target of the transmission source identification process and the transmission source identification process. Specifically, the system interface unit 102 is a node name of a connection destination communication node 50, login information for connecting to the communication node 50, a specific method for determining an object to be separated in an after-mentioned separation process, and an object to be separated. A search range or the like for determining the packet transmission device 150 is received from the communication system 10. In the present invention, as the separation target determination method, those based on the binary search method and those based on the sequential search method are mainly used, and these separation target determination methods will be described in detail below.

  The communication node interface unit 104 is connected to the communication node 50 and establishes communication with the communication node 50 using the node name and login information of the communication node 50 notified from the system interface unit 102. After establishing communication, the communication node interface unit 104 transmits and receives data packets and control packets to and from the communication node 50.

  The packet transmission device interface unit 106 is connected to the packet transmission device 150 via one or more interfaces provided between the communication node 50 and the packet transmission device 150, and exchanges data packets and control packets with the packet transmission device 150. . Specifically, the packet transmission device interface unit 106 communicates or blocks a packet transmitted from the packet transmission device 150 via the interface under the control of the communication communication / stop control unit 110. The communicated packet may be provided to the congestion determination unit 112, and the packet received via the blocked interface may be discarded.

  The segmentation target determination unit 108 communicates packets transmitted from any packet transmission device 150 and transmits packets transmitted from any packet transmission device 150 according to various parameters related to the transmission source identification process received via the system interface unit 102. Decide whether to stop. The segmentation target determining unit 108 notifies the communication communication / stop control unit 110 of the segmentation result determined in this way. Typically, the separation target determination unit 108 determines which VLAN is to be communicated or blocked using VLAN identification information of a VLAN that is a virtual group to which the packet transmission device 150 belongs. The separation target determining unit 108 notifies the communication communication / stop control unit 110 of the result of the determination of which VLAN is to be communicated or blocked.

  The communication communication / stop control unit 110 communicates or blocks communication with the packet transmission device 150 according to the segmentation result notified from the segmentation target determination unit 108. Specifically, the communication communication / stop control unit 110 controls the packet transmission device interface unit 106 according to the notified separation result, and selectively selects each interface between each packet transmission device 150 and the communication node 50. Communicate or stop.

  The congestion determination unit 112 monitors a packet transmitted from the packet transmission device 150 via the interface communicated by the communication communication / stop control unit 110 and determines whether the communication node 50 is congested by the transmitted packet. . Typically, the congestion determination unit 112 transfers the communication target packet received from the communication communication / stop control unit 110 to the communication node 50 for a predetermined period, and has the congestion occurred in the communication node 50 after the period has elapsed? Check. After determining whether congestion has occurred, the congestion determination unit 112 notifies the determination target determination unit 108 and / or the communication communication / stop control unit 110 of the determination result.

  Next, with reference to FIG. 5, the processing of the transmission source specifying device according to an embodiment of the present invention will be described. FIG. 5 is a flowchart showing overall processing in the transmission source specifying device according to the embodiment of the present invention.

  As illustrated in FIG. 5, in response to the occurrence of a predetermined event such as the occurrence of congestion in the communication node 50 or an activation instruction from the communication system 10, the transmission source specifying device 100 starts the transmission source specifying process.

  In step S101, the system interface unit 102 receives from the communication system 10 various parameters related to the communication node 50 that is the target of the transmission source identification process and the transmission source identification process, connects to the communication node 50 according to the received parameter, and transmits Perform original identification processing. Specifically, the system interface unit 102 receives the node name of the connection destination communication node 50 as parameters relating to the communication node 50, login information for connecting to the communication node 50, and the like, and classifies the parameters as parameters relating to the transmission source specifying process. A method for determining a segmentation target used in processing, a search range for determining the packet transmission device 150 to be segmented, and the like are received.

  In step S <b> 102, the transmission source identification device 100 executes the separation process according to the parameters regarding the transmission source identification process notified from the communication system 10. More specifically, based on the isolation target determination method and the search range received from the communication system 10, the isolation target determination unit 108 communicates with the packet transmitter 150 in the search range according to the notified isolation target determination method. The transmission device 150 is divided into the packet transmission device 150 to be stopped, and the determined separation result is notified to the communication communication / stop control unit 110. Upon receiving the segmentation result from the segmentation target determination unit 108, the communication communication / stop control unit 110 determines that the communication with the packet transmission device 150 determined to be blocked in the segmentation result is blocked and should be communicated. The packet transmission apparatus 150 receives the packet and controls to transfer the received packet to the congestion state determination unit 112. When the packet transmitted from the communication target packet transmission device 150 is received from the communication communication / stop control unit 110, the congestion state determination unit 112 determines whether the received packet causes congestion in the communication node 50, The determination result is notified to the separation target determination unit 108 and / or the communication communication / stop control unit 110. Until the transmission source estimated to be the cause of congestion is specified, the above-described separation process is repeatedly executed. When the source packet transmission device 150 estimated to be the cause of congestion is identified, the transmission source identification device 100 notifies the communication system 10 of the identified packet transmission device 150.

  In step S <b> 103, the communication system 10 instructs the communication node 50 to block communication with the specified packet transmission device 150. When receiving the instruction from the communication system 10, the communication node 50 blocks communication with the specified packet transmission device 150. In step S104, the communication system 10 is notified of the blocking result, and the transmission source specifying process is terminated.

  Next, with reference to FIGS. 6 to 14, the separation process according to various embodiments of the present invention will be described. As described above, the separation process according to the present invention mainly uses the separation object determination method based on the binary search method and the separation object determination method based on the sequential search method.

  With reference to FIG. 6, the binary search method used for the separation process according to the present invention will be described. FIG. 6 is a schematic diagram illustrating a binary search method according to an embodiment of the present invention.

  As shown in FIG. 6, according to a typical binary search method, the segmentation target determining unit 108 first equally bisects the search range VLAN # 1 to VLAN # 4096 of the transmission source received from the system node interface unit 102. , VLAN # 1 to VLAN # 2048 and VLAN # 2049 to VLAN # 4096 are divided into two separation ranges (pattern 1). The communication communication / stop control unit 110 sets one of the two separation ranges to a communication state and sets the other to a blocking state. In the illustrated embodiment, the communication communication / stop control unit 110 sets VLAN # 1 to VLAN # 2048 as the communication range and VLAN # 2049 to VLAN # 4096 as the blocking range. The congestion determination unit 112 determines whether the communication node 50 causes congestion for packets transmitted from the VLAN # 1 to VLAN # 2048 in the communication range. In the illustrated embodiment, the congestion determination unit 112 determines that there is no congestion for the communication range. In this case, it is estimated that there is a transmission source that causes congestion in the VLAN # 2049 to VLAN # 4096 in the cutoff range, the range is set as a simulated range, and further separation is executed.

  Next, the separation target determining unit 108 equally divides the simulated range VLAN # 2049 to VLAN # 4096 into two separation ranges VLAN # 2049 to VLAN # 3072 and VLAN # 3073 to VLAN # 4096. Divide (Pattern 2). The communication communication / stop control unit 110 sets one of the two separation ranges to a communication state and sets the other to a blocking state. In the illustrated embodiment, the communication communication / stop control unit 110 sets VLAN # 2049 to VLAN # 3072 to the communication range and VLAN # 3073 to VLAN # 4096 to the blocking range. The congestion determination unit 112 determines whether or not the communication node 50 causes congestion for packets transmitted from the communication range VLAN # 2049 to VLAN # 3072. In the illustrated embodiment, the congestion determination unit 112 detects that congestion has occurred in the communication range. In this case, it is presumed that there is a transmission source causing congestion in the communication range VLAN # 2049 to VLAN # 3072, the range is set as a simulated range, and further separation is executed.

  Next, the separation target determination unit 108 equally divides the simulated range VLAN # 2049 to VLAN # 3072 into two, and divides the two into two separation ranges of VLAN # 2049 to VLAN # 2560 and VLAN # 2561 to VLAN # 3072. Divide (Pattern 3). The communication communication / stop control unit 110 sets one of the two separation ranges to a communication state and sets the other to a blocking state. In the illustrated embodiment, the communication communication / stop control unit 110 sets VLAN # 2049 to VLAN # 2560 as the communication range and VLAN # 2561 to VLAN # 3072 as the blocking range. The congestion determination unit 112 determines whether or not the communication node 50 generates congestion for packets transmitted from the communication range VLAN # 2049 to VLAN # 2561. In the illustrated embodiment, the congestion determination unit 112 detects that congestion has occurred in the communication range. In this case, it is presumed that there is a transmission source causing congestion in the communication range VLAN # 2049 to VLAN # 2561, the range is set as a simulated range, and further separation is executed.

  Thereafter, the above-described processing is repeated until one transmission source is specified. As is apparent from the nature of the binary search method, according to the illustrated embodiment, one transmission source can be specified by repeating the above-described process 12 times.

  Next, with reference to FIG. 7, the separation process based on the binary search method according to an embodiment of the present invention will be described. FIG. 7 is a flowchart showing the separation process based on the binary search method according to the embodiment of the present invention.

  As illustrated in FIG. 7, in step S <b> 201, the separation target determination unit 108 initially sets the separation range X to the search range notified from the system interface unit 102.

  In step S202, the separation target determination unit 108 equally divides the separation range X into X1 and X2, and notifies the communication communication / stop control unit 110 of the separation result.

  In step S203, the communication communication / stop control unit 110 communicates the communication in the isolation range X1, and blocks the communication in the isolation range X2. In this embodiment, when the separation range is specified by an identification number such as VLAN, the communication communication / stop control unit 110 communicates the separation range X1 having a relatively small identification number and sets a relatively large identification number. The carving range X2 is cut off. However, the present invention is not limited to this, and the communication communication / stop control unit 110 blocks the separation range X1 having a relatively small identification number and separates the separation range X2 having a relatively large identification number. You may make it communicate.

  In step S204, the congestion determination unit 112 determines whether a packet transmitted from the communication range X1 causes congestion in the communication node 50. If there is congestion, the process proceeds to step S205, where it is determined that the isolation range X1 is a simulated range including a transmission source that is congested in the communication node 50, and the isolation range X is updated to X1. On the other hand, if there is no congestion, the process proceeds to step S206, and it is determined that the isolation range X2 is a pseudorange including a transmission source that causes congestion in the communication node 50, and the isolation range X is updated to X2. To do.

  In step S207, the segmentation target determining unit 108 determines whether one packet transmission device 150 included in the updated segmentation range X has been identified. If a plurality of packet transmission devices 150 are included in the separation range X, the process returns to step S202, and the above-described process is repeated. On the other hand, if one packet transmission device 150 can be identified, in step S208, the communication communication / stop control unit 110 communicates only the identified packet transmission device 150, and the congestion determination unit 112 receives the packet transmission device 150 from the packet transmission device 150. It is determined whether the transmitted packet causes congestion in the communication node 50.

  When congestion occurs, in step S209, the congestion determination unit 112 determines that the packet transmission device 150 is the cause of congestion, and notifies the communication system 10 of the determination result. On the other hand, when congestion does not occur, in step S210, the congestion determination unit 112 does not determine that the packet transmission device 150 is the cause of congestion, and notifies the communication system 10 that the determination has failed. In this case, the communication system 10 may instruct the transmission source specifying apparatus 100 to change the parameter related to the transmission source specifying process and re-execute the transmission source specifying process.

  Next, with reference to FIG. 8, a description will be given of a separation process based on a binary search method according to another embodiment of the present invention. FIG. 8 is a flowchart showing the separation process based on the binary search method according to another embodiment of the present invention. In the embodiment shown in FIG. 7 described above, when there is congestion in the communication range of the two separation ranges, the communication range is set as the simulated range, and when there is no congestion, the cutoff range is set as the simulated range. . In the embodiment shown in FIG. 8, as in the embodiment of FIG. 7, when there is congestion in the communication range of the two separation ranges, the communication range is set as the simulated range, but when there is no congestion, Switch between communication and stop, check the congestion again with the communication range as the blocking range and the blocking range as the communication range. This switching between communication and stop is repeated until congestion occurs. As a result, it is possible to avoid erroneous narrowing down of the simulated range when congestion occurs intermittently.

  As illustrated in FIG. 8, in step S <b> 301, the separation target determination unit 108 initially sets the separation range X to the search range notified from the system interface unit 102.

  In step S302, the separation target determination unit 108 equally divides the separation range X into X1 and X2, and notifies the communication communication / stop control unit 110 of the separation result.

  In step S303, the communication communication / stop control unit 110 communicates the communication in the isolation range X1, and blocks the communication in the isolation range X2. In this embodiment, when the separation range is specified by an identification number such as VLAN, the communication communication / stop control unit 110 communicates the separation range X1 having a relatively small identification number and sets a relatively large identification number. The carving range X2 is cut off. However, the present invention is not limited to this, and the communication communication / stop control unit 110 blocks the separation range X1 having a relatively small identification number and separates the separation range X2 having a relatively large identification number. You may make it communicate.

  In step S304, the congestion determination unit 112 determines whether a packet transmitted from the communication range X1 causes congestion in the communication node 50. If there is congestion, the process proceeds to step S305, where it is determined that the isolation range X1 is a simulated range including a transmission source that causes congestion in the communication node 50, and the isolation range X is updated to X1. On the other hand, if there is no congestion, the process proceeds to step S306.

  In step S306, the communication communication / stop control unit 110 switches communication / stop, blocks communication in the separation range X1, and communicates communication in the separation range X2.

  In step S307, the congestion determination unit 112 determines whether a packet transmitted from the communication range X2 causes congestion in the communication node 50. If there is congestion, the process proceeds to step S308, where it is determined that the isolation range X2 is a simulated range including a transmission source that causes the communication node 50 to generate congestion, and the isolation range X is updated to X2. On the other hand, if there is no congestion, the process returns to step S303, and the above-described process is executed until congestion is detected in the separation range that is alternately switched to communication / stop.

  In step S309, the segmentation target determination unit 108 determines whether one packet transmission device 150 included in the updated segmentation range X has been identified. If a plurality of packet transmission devices 150 are included in the separation range X, the process returns to step S302, and the above-described process is repeated. On the other hand, when one packet transmission device 150 can be specified, in step S310, the congestion determination unit 112 determines that the packet transmission device 150 is a cause of congestion, and notifies the communication system 10 of the determination result.

  Next, with reference to FIG. 9, a description will be given of a separation process based on a binary search method according to another embodiment of the present invention. FIG. 9 is a flowchart showing the separation process based on the binary search method according to another embodiment of the present invention. The embodiment shown in FIG. 9 is a modification of the above-described embodiment shown in FIG. 8, and even when congestion is not confirmed in the communication range, the separation process is progressed without switching between communication and blocking. Let After that, the separation process is executed until the packet transmission device 150 is narrowed down to one packet transmission device 150. When the narrowed packet transmission device 150 is not the cause of congestion, the process returns to the separation stage (determined range) where the occurrence of congestion is confirmed. -Switching the stop pattern and restarting the switching process from the carving stage. According to the present embodiment, the separation process is advanced without repeating switching between communication and stop until congestion occurs at each separation stage, so that a quick separation process is possible. This embodiment is effective in a case where the probability of misjudgment that erroneously determines the stop range as a simulated range when no congestion is detected in the communication range is low. Further, even when an erroneous determination occurs, it is possible to identify the transmission source that causes congestion by resuming the separation process from the fixed range without repeating the separation process from the original separation range again.

  As illustrated in FIG. 9, in step S <b> 401, the separation target determination unit 108 initially sets the separation range X to the search range notified from the system interface unit 102.

  In step S <b> 402, the separation target determination unit 108 initially sets a fixed range, which is a separation stage in which the occurrence of congestion is confirmed, as the separation range X, and sets a communication / stop pattern P. The pattern P defines which communication between the two equally divided bisection ranges X1 and X2 is to be communicated or blocked. For example, in the pattern P, when the separation range is specified by an identification number such as VLAN, the separation range X1 having a relatively small identification number is communicated and the separation range X2 having a relatively large identification number is blocked. May be defined (upper right part of FIG. 9). Further, the pattern P may be defined to block the separation range X1 having a relatively small identification number and communicate with the separation range X2 having a relatively large identification number (right side of FIG. 9). Lower part). In the present embodiment, the pattern P is first set so as to pass through the separation range X1 having a relatively small identification number and to block the separation range X2 having a relatively large identification number.

  In step S403, the separation target determination unit 108 equally divides the separation range X into X1 and X2, and notifies the communication communication / stop control unit 110 of the separation result. When receiving the separation result from the separation target determining unit 108, the communication communication / stop control unit 110 communicates the communication in the separation range X1 and blocks the communication in the separation range X2 according to the set pattern P.

  In step S404, the congestion determination unit 112 determines whether a packet transmitted from the communication range X1 causes congestion in the communication node 50. If there is congestion, the process moves to step S405, and the separation range X and / or the fixed range Z is updated. On the other hand, if there is no congestion, the process proceeds to step S408.

  In step S <b> 405, the carving target determination unit 108 determines whether the carving range X and the confirmed range Z match (X == Z) in order to update the carving range X and / or the confirmed range Z. When X == Z is not satisfied (S405: N), the separation target determination unit 108 updates the determined range Z and the separation range X with the communication range X1 in steps S406 and S407, respectively. On the other hand, if X == Z (S405, Y), the segmentation target determination unit 108 updates the segmentation range X with the communication range X1 in step S407.

  In step S <b> 408, the separation target determination unit 108 determines whether there is one packet transmission device 150 included in the separation range X. When two or more packet transmission devices 150 are included in the isolation range X, the process proceeds to step S409, and it is determined that the cutoff range X2 is a simulated range including a transmission source that causes congestion in the communication node 50. Then, the segmenting range X is updated to X2. On the other hand, when only one packet transmission device 150 is included in the separation range X, it is determined that the packet transmission device 150 that has been narrowed down to one in the previous narrowing is not a transmission source that causes congestion, and congestion occurs. The separation process is restarted by going back to the confirmed range where is confirmed.

  In step S410, the separation target determination unit 108 updates the separation range X with the fixed range Z.

  In step S411, the separation target determination unit 108 replaces the pattern P. In this embodiment, the separation target determination unit 108 blocks the separation range X1 having a relatively small identification number, and communicates the separation range X2 having a relatively large identification number. The pattern P is set so as to Thereafter, the processing returns to step S403, and the above-described processing is repeated with the updated switching range X and pattern P. In step S403, when the segmenting range X includes only one packet transmitting device 150, the packet transmitting device 150 is segmented into a communication range.

  In step S412, the separation target determination unit 108 determines whether one packet transmission device 150 included in the updated separation range X has been identified. If a plurality of packet transmission devices 150 are included in the separation range X, the process returns to step S403 and repeats the above-described process. On the other hand, if one packet transmission device 150 can be identified, in step S413, the congestion determination unit 112 determines that the packet transmission device 150 is the cause of congestion, and notifies the communication system 10 of the determination result.

  Next, with reference to FIG. 10, a segmentation process based on a binary search method according to another embodiment of the present invention will be described. FIG. 10 is a flowchart showing the separation process based on the binary search method according to another embodiment of the present invention. In the embodiment shown in FIG. 10, when congestion is not detected in the communication range, the blocking range is set as the separation range X, and the communication range is set as the remaining section Y that may include the transmission source that is the cause of congestion. Reserving and executing communication / stop at the same time for the remaining sections to check for congestion. That is, it is determined that only the blocking range that is blocked when congestion is detected in the communication range is a section that does not cause congestion, and the separation process is performed simultaneously for both the separation range X and the remaining section Y. .

  As shown in FIG. 10, in step S501, the carving target determining unit 108 may initially set the carving range X to the search range notified from the system interface unit 102, and may include a transmission source that is the cause of congestion. The remaining section Y is initially set to φ (empty set).

  In step S502, the separation target determination unit 108 equally bisects the separation range X into X1 and X2, and equally bisects the remaining section Y into Y1 and Y2, and communicates / stops the separation result. Notify the control unit 110.

  In step S <b> 503, the communication communication / stop control unit 110 communicates the communication in the separation range X <b> 1 and the remaining possibility section Y <b> 1 and blocks the communication in the separation range X <b> 2 and the remaining possibility section Y <b> 2. In this embodiment, when the separation range is specified by an identification number such as VLAN, the communication communication / stop control unit 110 communicates the separation range X1 having a relatively small identification number and the remaining possibility section Y1, The separation range X2 having a relatively large identification number and the remaining section Y2 are blocked. However, the present invention is not limited to this, and the communication communication / stop control unit 110 blocks the separation range X1 having a relatively small identification number and the remaining section Y1 and is relatively large. The separation range X2 having the identification number and the remaining section Y2 may be communicated.

  In step S504, the congestion determination unit 112 determines whether a packet transmitted from the communication range X1 and the communication section Y1 causes congestion in the communication node 50. If there is congestion, the process proceeds to step S505, and it is determined that the isolation range X1 or the remaining possibility section Y1 is a simulated range including a transmission source that generates congestion in the communication node 50, and the isolation range. X is updated to X1, and the remaining section Y is updated to Y1. In this case, the cut-off range X2 and the cut-off period Y2 are determined to be sections where there is no cause of congestion, and are added to sections determined to have no cause. On the other hand, if there is no congestion, the process proceeds to step S506.

  In step S506, the separation target determination unit 108 determines whether the number of packet transmission devices 150 included in the separation range X is 1 or more. If one or more packet transmission devices 150 are included in the separation range X, the process proceeds to step S507. On the other hand, if the packet transmission device 150 is not included in the separation range X, the process proceeds to step S509. Transition.

  In step S507, the separation target determination unit 108 determines that the cutoff range X2 is a simulated range including a transmission source that causes congestion in the communication node 50, and updates the separation range X to X2.

  In step S508, the separation target determining unit 108 adds the communication range X1 to the remaining section Y because congestion is not detected for the communication range X1 but it cannot be determined that there is no congestion cause.

  In step S509, the carving target determination unit 108 replaces the carving range X with a section Y where the possibility remains, and performs subsequent carving processing on the section Y.

  In step S510, the carving target determination unit 108 initializes a section Y with a possibility remaining as φ along with the replacement in step S509.

  In step S511, the segmentation target determining unit 108 determines whether one packet transmission device 150 included in the updated segmentation range X has been identified. If a plurality of packet transmission devices 150 are included in the separation range X, the process returns to step S502, and the above-described process is repeated. On the other hand, if one packet transmission device 150 can be identified, in step S512, the congestion determination unit 112 determines that the packet transmission device 150 is the cause of congestion, and notifies the communication system 10 of the determination result.

  Next, with reference to FIG. 11, the sequential search method used for the separation process according to the present invention will be described. FIG. 11 is a schematic diagram illustrating a sequential search method according to an embodiment of the present invention.

  As shown in FIG. 11, according to a typical sequential search method, the carving target determining unit 108 first determines the VLAN # 1 from the search range VLAN # 1 to VLAN # 4096 of the transmission source received from the system node interface unit 102. A blocking state is set, and VLANs # 2 to # 4096 are set in a communicating state (pattern 1). The congestion determination unit 112 determines whether or not the communication node 50 causes congestion for packets transmitted from the communication range VLAN # 2 to VLAN # 4096. In the illustrated embodiment, the congestion determination unit 112 detects that congestion has occurred in the communication range. In this case, it is presumed that there is a transmission source causing congestion in VLAN # 2 to VLAN # 4096 in the communication range, the range is set as a simulated range, and further separation is performed.

  Next, the separation target determining unit 108 blocks VLAN # 2 from VLAN # 2 to VLAN # 4096, which is the simulated range, and sets VLAN # 1, VLAN # 3 to VLAN # 4096 to the communication state (Pattern 2). ). The congestion determination unit 112 determines whether or not the communication node 50 causes congestion for packets transmitted from the communication range VLAN # 1, VLAN # 3 to VLAN # 4096. In the illustrated embodiment, the congestion determination unit 112 detects that congestion has occurred in the communication range. In this case, it is presumed that there is a transmission source causing congestion in VLAN # 1, VLAN # 3 to VLAN # 4096 in the communication range, the range is set as a simulated range, and further separation is executed.

  The above-described separation process is repeated until a communication range in which congestion is not detected is confirmed. In the illustrated embodiment, the detection of congestion is confirmed in VLAN #N (pattern N), and the VLAN #N is determined as the transmission source.

  In the sequential search method described above, the number of packet transmission devices or VLANs to be blocked is set to one, but the present invention is not limited to this. Two or more continuous packet transmitters or discrete VLANs or VLANs may be set in a blocking state. In the sequential search method described above, VLANs that are blocked in ascending order of VLAN identification numbers are selected starting from VLAN # 1, but the present invention is not limited to this. The VLANs to be blocked may be selected according to the descending order or any other suitable comprehensive VLAN selection order. The sequential search method can be suitably used when the influence of congestion in the communication node 50 is relatively small.

  Next, with reference to FIG. 12, the separation process based on the sequential search method according to an embodiment of the present invention will be described. FIG. 12 is a flowchart showing the separation process based on the sequential search method according to an embodiment of the present invention.

  As illustrated in FIG. 12, in step S <b> 601, the separation target determination unit 108 initially sets the separation range X to the search range notified from the system interface unit 102.

  In step S602, the separation target determination unit 108 selects a separation range X1 configured from one packet transmission device 150 or VLAN from the separation range X. As described above, this selection may be made sequentially in ascending order, descending order of VLANs, or any selection order.

  In step S603, the communication communication / stop control unit 110 blocks communication in the separation range X1 and communicates communication in the other separation range X2.

  In step S604, the congestion determination unit 112 determines whether a packet transmitted from the communication range X2 causes the communication node 50 to generate congestion. If there is no congestion, the process proceeds to step S605, and it is determined that the isolation range X1 is a simulated range including a transmission source that causes the communication node 50 to generate congestion. On the other hand, if congestion is detected, the process proceeds to step S606, where it is determined that the isolation range X2 is a simulated range including a transmission source that causes congestion in the communication node 50, and the isolation range X is updated by X2. To do. Thereafter, the processing returns to step S602, and the above-described processing is repeated until a transmission source causing congestion is detected.

  In step S605, the congestion determination unit 112 determines that the packet transmission device 150 belonging to the isolation range X1 is the cause of congestion, and notifies the communication system 10 of the determination result.

  Next, with reference to FIG. 13, the separation process based on the sequential search method according to another embodiment of the present invention will be described. FIG. 13 is a flowchart showing the separation process based on the sequential search method according to another embodiment of the present invention. In the embodiment shown in FIG. 12 described above, when the congestion is not detected in the communication range X2, the source having the congestion cause is determined in the cutoff range X1, but in the embodiment shown in FIG. When the transmission source to be determined is determined, only the blocking range X1 determined as the transmission source is communicated, and it is further confirmed whether congestion actually occurs in the communication node 50. According to the present embodiment, it is possible to identify a transmission source that causes congestion with higher accuracy.

  As illustrated in FIG. 13, in step S <b> 701, the separation target determination unit 108 initially sets the separation range X to the search range notified from the system interface unit 102.

  In step S <b> 702, the separation target determination unit 108 selects the separation range X <b> 1 including one packet transmission device 150 or VLAN from the separation range X. As described above, this selection may be made sequentially in ascending order, descending order of VLANs, or any selection order.

  In step S703, the communication communication / stop control unit 110 blocks communication in the separation range X1, and communicates communication in the other separation range X2.

  In step S704, the congestion determination unit 112 determines whether a packet transmitted from the communication range X2 causes the communication node 50 to generate congestion. When there is no congestion, the process proceeds to step S705, and it is determined that the isolation range X1 is a simulated range including a transmission source that causes the communication node 50 to generate congestion. On the other hand, if congestion is detected, the process proceeds to step S706, where it is determined that the isolation range X2 is a pseudo range including a transmission source that causes the communication node 50 to generate congestion, and the isolation range X is updated by X2. In step S707, it is determined whether the updated segmentation range X is empty. When the separation range X is empty (S707: Y), the congestion determination unit 112 determines that a transmission source causing congestion is not detected in the search range notified from the communication system 10, and returns to step S701. Set a new search range. On the other hand, when the separation range X is not empty (S707: N), the process returns to step S702, and the above-described process is repeated until a transmission source causing congestion is detected.

  In step S705, the communication communication / stop control unit 110 communicates only the isolation range X1, and the congestion determination unit 112 determines whether a packet transmitted from the communication range X1 causes congestion in the communication node 50. When congestion is detected (S705: Y), in step S708, the congestion determination unit 112 determines that the packet transmission device 150 belonging to the isolation range X1 is a transmission source that causes congestion. On the other hand, when there is no congestion (S705: N), the congestion determination unit 112 determines that the packet transmission device 150 belonging to the separation range X1 is not a transmission source that causes congestion, and executes further separation processing. The process proceeds to step S706.

  In step S708, the congestion determination unit 112 determines that the packet transmission device 150 belonging to the isolation range X1 is the cause of congestion, and notifies the communication system 10 of the determination result.

  Next, with reference to FIG. 14, a segmentation process based on a sequential search method according to another embodiment of the present invention will be described. FIG. 14 is a flowchart showing the separation process based on the sequential search method according to another embodiment of the present invention. The embodiment shown in FIG. 14 is the same as the embodiment shown in FIG. 13 described above except for the prior confirmation processing in step S802. Therefore, only the prior confirmation process in step S802 will be described below in order to omit redundant description. In the prior confirmation process in step S802, the order in which the cutoff range X1 is selected from the separation range X is determined, and the cutoff range X1 is sequentially selected according to the order in which it is estimated that the possibility of congestion is high. According to the present embodiment, it becomes possible to identify a transmission source that causes congestion more quickly than the separation process based on the sequential search method described above.

  In step S8021, the separation target determination unit 108 associates the elements of the separation range X with binary numbers. For example, when the carving range X is configured from VLAN # 1, VLAN # 2,..., VLAN # 4095, VLAN # 4096, these elements can be expressed by 12-digit binary numbers, and each is expressed as “000000000000”. ”,“ 000000000001 ”,...,“ 111111111110 ”,“ 111111111111 ”.

  In step S <b> 8022, the carving target determination unit 108 determines that the bits of each digit from the first bit of the first digit to the twelfth bit of the twelfth digit in the 12-digit binary number are “0” or “1”. Assign communication / blocking according to the situation. In the illustrated embodiment, the segmentation target determination unit 108 blocks only elements whose bits in each digit are “0” and communicates the rest. That is, for the first bit, the carving target determination unit 108 blocks the VLAN corresponding to “000000000000”, “000000000001”,..., “0111111111111” whose first bit is “0”, and the remaining “100000000000000”. ”,“ 100000000001 ”,...,“ 111111111111 ”. Further, the segmentation target determining unit 108 performs similar segmentation for each digit from the other second bit to the twelfth bit.

  In step S8023, the communication communication / stop control unit 110 communicates / blocks each VLAN according to the segmentation result received from the segmentation target determination unit 108, and the congestion determination unit 112 congests packets from the communicated VLAN to the communication node 50. It is determined whether or not When congestion is detected, the value “0” of the bit is determined, and when congestion is not detected, it is set that the value of the bit may be “1”.

  In step S <b> 8024, the carving target determination unit 108 determines the order in which the cut-off range X <b> 1 is selected from the carving range X based on the binary pattern that is set as confirmed and likely. That is, in step S8023, the VLAN corresponding to the binary number composed of the determined bit value is estimated to have the highest probability of being a transmission source causing congestion, and the carving target determining unit 108 VLAN is a candidate for blocking. In addition, the segmentation target determination unit 108 may set the bit values set as likely to be stop candidates in descending order of the Hamming distance from the VLAN that is set as a blocking candidate.

  As mentioned above, although the Example of this invention was explained in full detail, this invention is not limited to the specific embodiment mentioned above, In the range of the summary of this invention described in the claim, various deformation | transformation・ Change is possible.

DESCRIPTION OF SYMBOLS 10 Communication system 50 Communication node 100 Source identification apparatus 102 System interface part 104 Communication node interface part 106 Packet transmission apparatus interface part 108 Isolation object determination part 110 Communication communication / stop control part 112 Congestion judgment part

Claims (8)

A device that identifies a transmission device that causes congestion of a communication node,
According to a predetermined slicing method, a slicing target determining unit that divides a plurality of transmitting devices connected to the communication node into a communication transmitting device group and a blocking transmitting device group;
Communication communication for communicating between the transmission device of the communication transmission device group and the communication node according to the result of the separation by the separation target determination unit, and blocking communication between the transmission device of the blocking transmission device group and the communication node A stop control unit;
A congestion determination unit that identifies the transmission device that causes the congestion by determining whether a packet transmitted from the transmission device of the communication transmission device group congests the communication node;
Have
An apparatus in which the separation target determination unit, the communication communication / stop control unit, and the congestion determination unit are repeatedly executed until the transmission device that causes the congestion is identified. The predetermined carving method is based on a binary search method that equally bisects the sending device to be carved.
When the congestion determination unit determines that a packet transmitted from a transmission device of the communication transmission device group congests the communication node, the separation target determination unit determines the communication transmission device group as a simulated transmission device group. The transmission device of the simulated transmission device group is further divided into the communication transmission device group and the cut-off transmission device group according to the predetermined separation method until the transmission device causing the congestion is identified, and the communication transmission device The apparatus according to claim 1, wherein processing by the communication communication / stop control unit and the congestion determination unit is repeatedly applied to a group and the blocking transmission device group.   When the congestion determination unit determines that a packet transmitted from the transmission device of the communication transmission device group does not congest the communication node, the separation target determination unit determines that the blocked transmission device group is the simulated transmission device group. The apparatus of claim 2, wherein the apparatus is determined.   When the congestion determination unit determines that a packet transmitted from the transmission device of the communication transmission device group does not congest the communication node, the communication communication / stop control unit communicates with the transmission device of the communication transmission device group and the communication Blocking communication with a node, and communicating between the transmission device of the blocking transmission device group and the communication node, a communication state and a stopped state between the communication transmission device group and the blocking transmission device group The apparatus according to claim 2, wherein the switching is performed.   Until the congestion determination unit determines that a packet transmitted from the transmission device of the communication transmission device group or the blocking transmission device group congests the communication node, the communication communication / stop control unit is configured to transmit the communication transmission device. The apparatus of Claim 4 which switches a communication state and a stop state repeatedly between a group and the said interruption | blocking transmission apparatus group.   When the transmission device that causes the congestion is not specified, the isolation target determination unit determines the communication transmission that has been most recently determined when a packet transmitted from the transmission device of the communication transmission device group congests the communication node. Returning to the definite transmission device group consisting of the transmission devices of the device group, the transmission device of the definite transmission device group is further divided into the communication transmission device group and the cutoff transmission device group according to the predetermined separation method, and the communication transmission device group The apparatus according to any one of claims 2 to 5, wherein the processing by the communication communication / stop control unit and the congestion determination unit is repeatedly applied to the blocking transmission device group.   2. The predetermined slicing method is based on a sequential search method in which one of the slicing target transmission devices is set as the blocking transmission device group and the rest is set as the communication transmission device group according to a predetermined sequential order. Equipment. A method for identifying a transmission device that causes congestion of the communication node in a device connected to a communication node and a plurality of transmission devices,
Separating a plurality of transmission devices connected to the communication node into a communication transmission device group and a blocking transmission device group according to a predetermined separation method;
In accordance with the result of the separation in the step of separating, the communication between the transmission device of the communication transmission device group and the communication node, the step of blocking communication between the transmission device of the blocking transmission device group and the communication node;
Identifying a transmission device that causes the congestion by determining whether a packet transmitted from a transmission device of the communication transmission device group congests the communication node;
Have
An apparatus in which the isolation step, the communication / blocking step, and the specifying step are repeatedly executed until the transmission device causing the congestion is specified.

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