JP2017147534A - Communication control unit and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To changeover two load balancers appropriately according to the situation.SOLUTION: A communication control unit includes a communication connection establishment section for establishing communication connection with a first load balancer, a connection changeover section for changing over the communication connection destination from the first load balancer to a second load balancer, when a determination is made that the first load balancer became inoperative, and a connection switch back section for monitoring the first load balancer after the communication connection destination is switched from the first load balancer to second load balancer, until the first load balancer becomes operative, and switching back the communication connection destination from the second load balancer to first load balancer, when the first load balancer became operative.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a communication control device and a program.

A technique for distributing processing using a load balancer has been known (see, for example, Patent Document 1).
[Prior art documents]
[Patent Literature]
[Patent Document 1] JP-A-2005-275534

  In order to prevent the entire process from stopping when the load balancer becomes inoperable, for example, when two load balancers are placed in parallel and operated, and one load balancer becomes inoperable In addition, when a configuration is adopted in which processing is performed by the other load balancer, it is desirable that appropriate switching according to the situation can be realized.

  According to the first aspect of the present invention, when it is determined that the communication connection establishment unit that establishes communication connection with the first load balancer and the first load balancer has become inoperable, the communication connection destination is designated as the first load balancer. A connection switching unit for switching from the first load balancer to the second load balancer, and after the communication connection destination is switched from the first load balancer to the second load balancer, the first load balancer is monitored until the first load balancer becomes operable, A communication control device is provided that includes a connection switchback unit that switches the communication connection destination from the second load balancer to the first load balancer when the first load balancer becomes operable.

  The communication control device transmits the mail data to the first load balancer when the communication connection is established with the mail data receiving unit that receives the mail data and the first load balancer, and the second load balancer. When the communication connection is established, a mail data transmission unit that transmits the mail data to the second load balancer may be further included. The mail data receiving unit may receive an MMS message, and the mail data transmitting unit is configured to store the MMS message received by the mail data receiving unit in a destination mailbox of the MMS message. The first load balancer may transmit the MMS message received from the mail data transmission unit to any one of a plurality of servers that store the MMS message in the mailbox. The second load balancer may transmit the MMS message received from the mail data transmission unit to any of the plurality of servers.

  The connection switchback unit continuously transmits an SMTP connection establishment command to the first load balancer after the communication connection destination is switched from the first load balancer to the second load balancer. The communication connection destination may be switched back from the second load balancer to the first load balancer in response to receiving a normal response to. The communication control device may be an MMSC. The connection switchback unit continuously executes a command for confirming network communication with the first load balancer after the communication connection destination is switched from the first load balancer to the second load balancer. The first load balancer may be monitored by

  According to the 2nd aspect of this invention, the program for functioning a computer as said communication control apparatus is provided.

  It should be noted that the above summary of the invention does not enumerate all the necessary features of the present invention. In addition, a sub-combination of these feature groups can also be an invention.

1 schematically shows an example of a communication system 10. An example of functional composition of MMSC100 is shown roughly. An example of the flow of processing by MMSC100 is shown roughly. An example of the flow of processing by MMSC100 is shown roughly. 2 shows an exemplary hardware configuration of a computer 1000 functioning as the MMSC 100.

  Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. In addition, not all the combinations of features described in the embodiments are essential for the solving means of the invention.

  FIG. 1 schematically illustrates an example of a communication system 10. The communication system 10 according to the present embodiment executes a process of storing an MMS (Multimedia Messaging Service) message received from the network 20 in a destination user's mailbox. Further, the communication system 10 executes processing for transmitting the MMS message stored in the mailbox to the destination user's communication terminal. The network 20 may include the Internet and a telephone network.

  The communication system 10 includes an MMSC (MMS Center) 100, an MMSC 200, a load balancer 300, a load balancer 400, a server group 500, a server group 600, a user information DB (Database) 700, a mailbox system 800, and an SMSC (Short Message Service Center). ) 900.

  The MMSC 100 is connected to the load balancer 300 and the load balancer 400. The MMSC 100 may establish a communication connection with the load balancer 300 when both the load balancer 300 and the load balancer 400 are operable. When receiving the MMS message from the network 20, the MMSC 100 may transmit the MMS message to the load balancer 300 or the load balancer 400 that has established the communication connection.

  The MMSC 200 is connected to the load balancer 300 and the load balancer 400. The MMSC 200 may establish a communication connection with the load balancer 400 when both the load balancer 300 and the load balancer 400 are operable. When receiving the MMS message from the network 20, the MMSC 200 may transmit the MMS message to the load balancer 300 or the load balancer 400 that has established a communication connection.

  The load balancer 300 is connected to the server group 500. The server group 500 includes a server 510, a server 520, and a server 530. The number of servers included in the server group 500 is not limited to this, and an arbitrary number of servers may be included.

  When the load balancer 300 receives the MMS message from the MMSC 100 or the MMSC 200, the load balancer 300 transmits the MMS message to any of the server 510, the server 520, and the server 530 depending on the load status of the server 510, the server 520, and the server 530. To do.

  The load balancer 400 is connected to the server group 600. The server group 600 includes a server 610, a server 620, and a server 630. The number of servers included in the server group 600 is not limited to this, and an arbitrary number of servers may be included.

  When the load balancer 400 receives an MMS message from the MMSC 100 or the MMSC 200, the load balancer 400 transmits the MMS message to any of the server 610, the server 620, and the server 630 depending on the load status of the server 610, the server 620, and the server 630. To do.

  When the server 510, the server 520, the server 530, the server 610, the server 620, and the server 630 receive the MMS message, the user 510 refers to the user information DB 700 and specifies a mailbox in which the MMS message is to be stored. The user information DB 700 may store, for each of a plurality of users, at least one of a telephone number and a mail address and a mailbox ID for identifying the mailbox in association with each other. The mailbox ID may be the same as the user ID that identifies each of the plurality of users.

  The server 510, the server 520, the server 530, the server 610, the server 620, and the server 630 receive the mailbox ID corresponding to the destination of the received MMS message from the user information DB 700, and are identified by the mailbox ID In order to store the MMS message in the box, it is transmitted to the mailbox system 800.

  Mailbox system 800 stores each mailbox of a plurality of users in association with a mailbox ID. When the mailbox system 800 receives the mailbox ID and the MMS message from the server 510, the server 520, the server 530, the server 610, the server 620, and the server 630, the mail system identifies the MMS message by the mailbox ID. Store in a box.

  When the MMSC 100 receives the MMS message, the MMSC 100 transmits the notification message via SMSC 900 to the destination communication terminal of the MMS message by SMS. When the MMSC 200 also receives the MMS message, the MMSC 200 transmits the notification message via SMSC 900 to the communication terminal that is the destination of the MMS message.

  The communication terminal that has received the notification message transmits an MMS message acquisition request to the MMSC 100 or MMSC 200 that is the transmission source of the notification message. The MMSC 100 or MMSC 200 that has received the acquisition request acquires an MMS message from the mailbox system 800 via the load balancer 300 or the load balancer 400 that has established a communication connection, and transmits it to the communication terminal.

  The MMSC 100 according to the present embodiment switches the communication connection destination from the load balancer 300 to the load balancer 400 when it is determined that the load balancer 300 becomes inoperable. After switching the communication connection destination to the load balancer 400, the MMSC 100 monitors the load balancer 300 until the load balancer 300 becomes operable. When the load balancer 300 becomes operable, the MMSC 100 switches back the communication connection destination from the load balancer 400 to the load balancer 300.

  In this way, after the MMSC 100 switches the communication connection destination to the load balancer 400, the load balancer 300 is monitored until the load balancer 300 becomes operable, so that the load balancer 300 can be operated quickly. In addition, the communication connection destination can be switched back to the load balancer 300.

  In the present embodiment, the MMSC 100 may be an example of a communication control device. The load balancer 300 may be an example of a first load balancer. The load balancer 400 may be an example of a second load balancer.

  FIG. 2 schematically shows an example of the functional configuration of the MMSC 100. The MMSC 100 includes a communication connection establishment unit 102, a message reception unit 104, a message transmission unit 106, a connection switching unit 108, a connection switchback unit 110, a notification message transmission unit 112, and an acquisition request reception unit 114.

  The communication connection establishment unit 102 executes communication connection establishment processing with the load balancer 300. The communication connection establishment unit 102 executes communication connection establishment processing with the load balancer 400.

  The message receiving unit 104 receives an MMS message via the network 20. The message receiving unit 104 may be an example of a mail data receiving unit, and the MMS message may be an example of mail data.

  The message transmission unit 106 transmits the MMS message to the load balancer 300 or the load balancer 400 that has established the communication connection in response to the message reception unit 104 receiving the MMS message. The message transmission unit 106 may be an example of a mail data transmission unit.

  The connection switching unit 108 switches the communication connection destination from the load balancer 300 to the load balancer 400 when it is determined that the load balancer 300 becomes inoperable.

  After the communication switching destination is switched from the load balancer 300 to the load balancer 400 by the connection switching unit 108, the connection switchback unit 110 monitors the load balancer 300 until the load balancer 300 becomes operable. When the operation becomes possible, the communication connection destination is switched back from the load balancer 400 to the load balancer 300.

  For example, after the communication switching destination is switched from the load balancer 300 to the load balancer 400 by the connection switching unit 108, the connection switchback unit 110 continuously executes a command for confirming network communication with the load balancer 300. Thus, the load balancer 300 is monitored. Commands for confirming network communication are, for example, a Ping command, a Traceroute command, and the like. The connection switchback unit 110 may periodically or irregularly execute a command for confirming network communication. The timing at which the connection switchback unit 110 executes the command may be set in advance. The connection switch-back unit 110 switches the communication connection destination from the load balancer 400 to the load balancer 300 when the network communication is confirmed.

  For example, after the communication switching destination is switched from the load balancer 300 to the load balancer 400 by the connection switching unit 108, the connection switchback unit 110 continuously sends a connection establishment command of SMTP (Send Mail Transfer Protocol) to the load balancer. You may transmit to 300. Thereby, the connection switchback unit 110 realizes monitoring of the load balancer 300 and switching back of a communication connection destination to the load balancer 300 when the load balancer 300 becomes operable. When the connection switchback unit 110 transmits a connection establishment command to the load balancer 300, the load balancer 300 is not disabled, but an application such as SMTP in the load balancer 300 is disabled. Thus, when the MMS message transfer process for the server group 500 cannot be executed, it can be determined that the operation is impossible. The connection establishment command may be HELO or EHLO, for example. The connection switchback unit 110 may transmit a connection establishment command periodically or irregularly. The timing at which the connection return unit 110 transmits the connection establishment command may be set in advance.

  The notification message transmission unit 112 transmits the notification message via SMSC 900 to the communication terminal that is the destination of the MMS message in response to the message reception unit 104 receiving the MMS message. The acquisition request receiving unit 114 receives an MMS message acquisition request from a communication terminal.

  The message receiving unit 104 receives the MMS message acquisition request from the mailbox system 800 via the load balancer 300 or the load balancer 400 that has established a communication connection in response to the acquisition request receiving unit 114 receiving the acquisition request for the MMS message. Get the message. The message transmitting unit 106 transmits the MMS message acquired by the message receiving unit 104 to the communication terminal that transmitted the acquisition request.

  FIG. 3 schematically shows an example of the flow of processing by the MMSC 100. The processing shown in FIG. 3 will be described with the state where the MMSC 100 and the load balancer 300 have established a communication connection as a start state. Each process illustrated in FIG. 3 is executed mainly by a control unit included in the MMSC 100.

  In step 302 (step may be abbreviated as S) 302, it is determined whether or not the message receiving unit 104 has received an MMS message. If it is determined that it has been received, the process proceeds to S304, and if it is determined that it has not been received, the process proceeds to S306. In S304, the message transmission unit 106 transmits the received MMS message to the load balancer 300 (may be described as LB300).

  In step S <b> 306, the connection switching unit 108 determines whether to check the operation of the load balancer 300. For example, when the operation check of the load balancer 300 is set to be executed every predetermined period, the connection switching unit 108 determines whether or not a predetermined period has elapsed since the previous operation check was executed. Determine whether. If it is determined to confirm the operation, the process proceeds to S308. If it is determined not to perform the operation check, the process returns to S302.

  In S <b> 308, the connection switching unit 108 confirms the operation of the load balancer 300. The connection switching unit 108 confirms the operation of the load balancer 300 by, for example, executing a command for confirming network communication with the load balancer 300. The connection switching unit 108 may check the operation of the load balancer 300 by transmitting a connection establishment command to the load balancer 300.

  In S310, the connection switching unit 108 determines whether or not the load balancer 300 is operable. If it is determined that it is operable, the process returns to S302, and if it is determined that it is not operable, the process proceeds to S312.

  In S312, the connection switching unit 108 determines whether communication connection with the load balancer 400 (may be described as LB400) is possible. If it is determined that it is possible, the process proceeds to S314. If it is determined that it is not possible, the process proceeds to S328. In S <b> 314, the connection switching unit 108 establishes a communication connection with the load balancer 400.

  In S316, it is determined whether the message receiving unit 104 has received an MMS message. When it determines with having received, it progresses to S318, and when it determines with not having received, it progresses to S320. In S318, the message transmission unit 106 transmits the received MMS message to the load balancer 400.

  In S320, the connection switchback unit 110 determines whether or not to check the operation of the load balancer 300. For example, when the operation check of the load balancer 300 is set to be executed every predetermined period, the connection switch-back unit 110 determines whether the predetermined period has elapsed since the previous operation check was executed. Determine whether or not. If it is determined to confirm the operation, the process proceeds to S322. If it is determined not to perform the operation check, the process returns to S316.

  In S <b> 322, the connection switchback unit 110 performs an operation check of the load balancer 300. For example, the connection switchback unit 110 confirms the operation of the load balancer 300 by executing a command for confirming network communication with the load balancer 300. The connection switchback unit 110 may execute an operation check of the load balancer 300 by transmitting a connection establishment command to the load balancer 300.

  In S324, the connection switchback unit 110 determines whether or not the load balancer 300 is operable. If it is determined that the state is operable, the process proceeds to S326, and if it is determined that the state is not operable, the process returns to S316. In S326, the connection switchback unit 110 establishes a communication connection with the load balancer 300.

  In S328, the connection switching unit 108 executes error processing. For example, the connection switching unit 108 notifies the administrator of the MMSC 100 of the error. Then, the process ends.

  FIG. 4 schematically shows another example of the flow of processing by the MMSC 100. The process shown in FIG. 4 will be described assuming that the MMSC 100 is waiting for an MMS message as a start state. Each process illustrated in FIG. 4 is executed mainly by a control unit included in the MMSC 100.

  In S402, it is determined whether the message receiving unit 104 has received an MMS message. When it determines with having received, it progresses to S404. In S <b> 404, the connection switching unit 108 transmits HELO, which is an SMTP connection establishment command, to the load balancer 300.

  In S <b> 406, the connection switching unit 108 determines whether a response indicating that the command has been normally completed is received with respect to HELO transmitted to the load balancer 300 in S <b> 404. If it is determined that a response has been received, the process proceeds to S408. If it is determined that a response has not been received, the process proceeds to S412.

  In S408, the message transmission unit 106 transmits the MMS message received in S402 to the load balancer 300. In S <b> 410, the connection switching unit 108 transmits a QUIT that is an SMTP connection end command to the load balancer 300. Then, the process returns to S402.

  In S <b> 412, the connection switching unit 108 transmits HELO to the load balancer 400. In S414, the connection switching unit 108 determines whether a response indicating that the command has been normally completed is received with respect to HELO transmitted to the load balancer 400 in S412. If it is determined that a response has been received, the process proceeds to S416. If it is determined that a response has not been received, the process proceeds to S434.

  In S416, the message transmission unit 106 transmits the MMS message received in S402 to the load balancer 400. In S418, the connection switching unit 108 transmits a QUIT to the load balancer 400.

  In S420, it is determined whether the message receiving unit 104 has received an MMS message. When it determines with having received, it progresses to S422. In S <b> 422, the connection switchback unit 110 transmits HELO to the load balancer 300.

  In S424, the connection switchback unit 110 determines whether or not a response indicating that the command has been normally completed is received with respect to HELO transmitted to the load balancer 300 in S422. If it is determined that a response has been received, the process returns to S408. If it is determined that a response has not been received, the process proceeds to S426.

  In S <b> 426, the connection switchback unit 110 transmits HELO to the load balancer 400. In S428, the connection switch-back unit 110 determines whether or not a response indicating that the command has been normally completed with respect to HELO transmitted to the load balancer 400 in S426 has been received. If it is determined that a response has been received, the process proceeds to S430. If it is determined that a response has not been received, the process proceeds to S434.

  In S430, the message transmission unit 106 transmits the MMS message received in S420 to the load balancer 400. In S432, the connection switch-back unit 110 transmits a QUIT that is an SMTP connection termination command to the load balancer 400. Then, the process returns to S420.

  In S434, the connection switchback unit 110 executes error processing. For example, the connection switchback unit 110 notifies the administrator of the MMSC 100 of an error. Then, the process ends.

  FIG. 5 shows an example of the hardware configuration of the computer 1000 that functions as the MMSC 100. The computer 1000 according to this embodiment includes a CPU peripheral unit including a CPU 1010, a RAM 1030, and a graphic controller 1085 connected to each other by a host controller 1092; a communication I / F 1040 connected to the host controller 1092 by an input / output controller 1094; An input / output unit having a hard disk drive 1050 and a DVD drive 1070, and a legacy input / output unit having a ROM 1020, an FD drive 1060, and an input / output chip 1080 connected to the input / output controller 1094 are provided.

  The CPU 1010 operates based on programs stored in the ROM 1020 and the RAM 1030 and controls each unit. The graphic controller 1085 acquires image data generated by the CPU 1010 or the like on a frame buffer provided in the RAM 1030 and displays the image data on the display 1090. Alternatively, the graphic controller 1085 may include a frame buffer that stores image data generated by the CPU 1010 or the like.

  The communication I / F 1040 communicates with other devices via a network by wire or wireless. The communication I / F 1040 functions as hardware that performs communication. The hard disk drive 1050 stores programs and data used by the CPU 1010. The DVD drive 1070 reads a program or data from the DVD-ROM 1072 and provides it to the hard disk drive 1050 via the RAM 1030.

  The ROM 1020 stores a boot program executed when the computer 1000 is started up, a program depending on the hardware of the computer 1000, and the like. The FD drive 1060 reads a program or data from the flexible disk 1062 and provides it to the hard disk drive 1050 via the RAM 1030. The input / output chip 1080 connects the FD drive 1060 to the input / output controller 1094, and connects various input / output devices to the input / output controller 1094 via, for example, a parallel port, a serial port, a keyboard port, and a mouse port. Connect to.

  A program provided to the hard disk drive 1050 via the RAM 1030 is stored in a recording medium such as the flexible disk 1062, the DVD-ROM 1095, or an IC card and provided by the user. The program is read from the recording medium, installed in the hard disk drive 1050 via the RAM 1030, and executed by the CPU 1010.

  A program that is installed in the computer 1000 and causes the computer 1000 to function as the MMSC 100 may work on the CPU 1010 or the like to cause the computer 1000 to function as each unit of the MMSC 100. The information processing described in these programs is read into the computer 1000, whereby the communication connection establishing unit 102 and the message receiving unit 104, which are specific means in which the software and the various hardware resources described above cooperate. , Message transmission unit 106, connection switching unit 108, connection switchback unit 110, notification message transmission unit 112, and acquisition request reception unit 114. The specific MMSC 100 according to the purpose of use is constructed by realizing calculation or processing of information according to the purpose of use of the computer 1000 in this embodiment by these specific means.

  In the above embodiment, the MMSC 100 has been described by taking an example of controlling switching and switching back of communication connections to the load balancer 300 and the load balancer 400 that distribute processing for storing MMS messages in a mailbox. However, the present invention is not limited to this. The MMSC 100 may control switching and switching back of communication connections to the load balancer 300 and the load balancer 400 that distribute arbitrary processing.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

  The order of execution of each process such as operations, procedures, steps, and stages in the apparatus, system, program, and method shown in the claims, the description, and the drawings is particularly “before” or “prior to”. It should be noted that it can be realized in any order unless the output of the previous process is used in the subsequent process. Regarding the operation flow in the claims, the description, and the drawings, even if it is described using “first,” “next,” etc. for convenience, it means that it is essential to carry out in this order. It is not a thing.

10 communication system, 20 network, 100 MMSC, 102 communication connection establishment unit, 104 message reception unit, 106 message transmission unit, 108 connection switching unit, 110 connection switchback unit, 112 notification message transmission unit, 114 acquisition request reception unit, 200 MMSC, 300 load balancer, 400 load balancer, 500 server group, 510 server, 520 server, 530 server, 600 server group, 610 server, 620 server, 630 server, 700 user information DB, 800 mailbox system, 900 SMSC, 1000 Computer, 1010 CPU, 1020 ROM, 1030 RAM, 1040 Communication I / F, 1050 Hard disk drive, 1060 FD drive, 1062 Flexible disk 1070 DVD drive, 1072 DVD-ROM, 1080 input / output chip, 1085 graphic controller, 1090 display, 1092 host controller, 1094 input / output controller

Claims (7)

A communication connection establishment unit for establishing a communication connection with the first load balancer;
A connection switching unit that switches the communication connection destination from the first load balancer to the second load balancer when it is determined that the first load balancer has become inoperable;
After the communication connection destination is switched from the first load balancer to the second load balancer, the first load balancer is monitored until the first load balancer is operable, and the first load balancer is operable. A connection control unit comprising: a connection switchback unit that switches the communication connection destination from the second load balancer back to the first load balancer. An email data receiver for receiving email data;
When the communication connection is established with the first load balancer, the mail data is transmitted to the first load balancer, and when the communication connection is established with the second load balancer, the mail data is sent to the second load balancer. The communication control device according to claim 1, further comprising: a mail data transmission unit that transmits to the load balancer. The mail data receiving unit receives an MMS message,
The mail data transmitting unit transmits the MMS message received by the mail data receiving unit to the first load balancer or the second load balancer so as to be stored in a mailbox of a destination of the MMS message,
The first load balancer transmits the MMS message received from the mail data transmission unit to any of a plurality of servers that store the MMS message in the mailbox,
The communication control device according to claim 2, wherein the second load balancer transmits the MMS message received from the mail data transmission unit to any of the plurality of servers.   The connection switchback unit continuously transmits an SMTP connection establishment command to the first load balancer after the communication connection destination is switched from the first load balancer to the second load balancer, and the connection establishment command The communication control device according to claim 2 or 3, wherein the communication connection destination is switched back from the second load balancer to the first load balancer in response to receiving a normal response to the request.   The communication control device according to any one of claims 1 to 4, wherein the communication control device is an MMSC.   The connection switchback unit continuously executes a command for confirming network communication with the first load balancer after the communication connection destination is switched from the first load balancer to the second load balancer. The communication control device according to any one of claims 1 to 3, wherein the first load balancer is monitored by:   The program for functioning a computer as a communication control apparatus as described in any one of Claim 1 to 6.

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