JP2009130501A - Terminating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem that communication between an application of a service subscriber and a server of the Internet fails when an IPv6 packet transferred to a service network specific to a carrier does not reach the server of the Internet. <P>SOLUTION: When an answer section of a DNS response message which is received from a DNS server of an ISP by a customer's terminating device includes an IPv6 address for an AAAA record, the DNS response message is transmitted to a terminal of the service subscriber after deleting the IPv6 address. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a termination device, and more particularly to a termination device in a mixed state of a plurality of environments.

  In an IP network connection service provided by a telecommunications carrier, a home terminal device is arranged in the service subscriber home. As a result, a service provider's unique service such as IP phone, video distribution, file sharing, and Internet connection service via ISP are provided. When a service provider-specific service is provided by IPv6, and an Internet connection service is provided by IPv4 payout through a tunnel such as PPPoE (PPP over Ether) or IPv4-over-IPv6, the service subscriber uses the IPv6 communication for the communication business. A service specific to the user is used for connection to the Internet by IPv4 communication.

  An application running on a terminal used by a service subscriber corresponds to the IPv6 communication function, a terminal used by the service subscriber holds an IPv6 communication function, a service belonging to the Internet holds an IPv6 communication function, and DNS (Domain Consider a case where the result of name resolution by Name System) is both an IPv6 address and an IPv4 address, and communication of an application used by a service subscriber is performed by IPv6. At this time, the in-house terminal device transfers all frames related to IPv6 communication from the subscriber to the service network of the communication carrier. For this reason, the frame does not reach the Internet server of the IPv4 network. Therefore, communication between the service subscriber's application and the Internet server fails.

  In the above-described environment, as the service subscriber terminal corresponding to IPv6, the application on the terminal, or the Internet server corresponding to IPv6 communication increases, the service for the service subscriber that fails in communication increases.

  An object of the present invention is to cope with a communication failure between a service subscriber application and an Internet server caused by the above-mentioned problem without greatly changing the network configuration and operation mode of an existing communication carrier. is there.

  In order to solve this problem, in the case where the answering section of the DNS response message from the DNS server of the ISP includes the IPv6 address corresponding to the AAAA (quad A) record, the in-house terminal device receives the IPv6 address from the Answer Section. Delete and transfer to service subscriber's terminal.

  In addition, a first interface connected to the first network, a second interface connected to the terminal, and an interface determination unit that determines that the first interface is connected to the second network through a tunnel. And the DNS control unit, and when the first interface receives the DNS response message and the interface determination unit determines that it is connected to the second interface, the DNS control unit This can be achieved by a terminating device that deletes the defined address and forwards it to the terminal.

  According to the present invention, the problem of IPv6 communication impossibility that occurs when a terminal of a service subscriber communicates with an Internet server that provides a service having an IPv4 address and an IPv6 address is avoided.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings using examples. The same reference numerals are assigned to substantially the same parts, and the description will not be repeated. Here, FIG. 1 is a block diagram illustrating the logical configuration of the network. FIG. 2 is a functional block diagram of the home terminal device. FIG. 3 is a hardware block diagram of the home terminal device. FIG. 4 is a diagram for explaining the DNS cache table. FIG. 5 shows a DNS message format. FIG. 6 is a sequence diagram among a terminal, a home terminal device, and a DNS server. FIG. 7 is a flowchart of Answer Section processing.

  In FIG. 1, the in-home terminal device 100 is connected to a service subscriber terminal 200 by an external interface 110-1. The home terminal device 100 is connected to the telecommunications carrier network 300 via the telecommunications carrier network connection line 50-A by the external interface 110-2A. Further, the home terminal device 100 is connected to the ISP network 400 via the ISP connection tunnel (IPv4-over-IPv6 tunnel) 50-B by the external network interface 110-2B. The ISP network 400 is connected to the Internet 500. The ISP network 400 includes a DNS server 410 for the Internet for service subscribers. The telecommunications carrier network 300 performs unique services such as IP phone, video distribution, file sharing, and the like with IPv6. The ISP network 400 provides an Internet connection service using IPv4. A server 510 that provides services corresponding to IPv4 and IPv6 is connected to the Internet 500.

  On the other hand, when the service subscriber terminal 200 starts an application and communicates with the server 510 on the Internet, the service subscriber terminal 200 transmits a DNS query message to the DNS server 410 to obtain the address of the server 510. The application starts communication toward the obtained address.

  FIG. 1 shows a logical configuration. Therefore, physically, the interface 110-2A and the interface 110-2B are the same interface 110-2. The connection line 50-A and the ISP connection tunnel 50-B are also physically the same line 50. The ISP network 400 is connected to the communication carrier network 300.

  In FIG. 2, the in-home terminal device 100 includes two physical network interfaces 110, a device control unit 120, a tunnel control unit 130, a frame reception processing unit 140, a frame transmission processing unit 150, and an interface determination unit 160. And a frame transfer processing unit 170 and a DNS control unit 180.

  The in-home terminal device 100 uses the device control unit 120 and, if necessary, the tunnel control unit 130 to control the network interface 110 and connect to an external network. The home terminal device 100 receives frame processing through the network interface 110 as input to the frame reception processing unit 140, outputs it from the frame transmission processing unit 150, and transfers the frame processing through the frame transfer processing unit 170.

  The in-home terminal device 100 uses the interface determination unit 160 to specify the logical network interface 110-2A / 110-2B to which the frame is input. The in-home terminal device 100 includes a DNS control unit 180 having a DNS cache server function. The DNS control unit 180 uses the DNS query message processing unit 181 and the DNS response message processing unit 182 to transmit and receive a DNS query message and a DNS response message with a device other than the in-home terminal device 100. The DNS control unit 180 holds a DNS cache table 188 as a conversion table that associates a domain name such as www.example.com with an IP address. The DNS cache database 188 updates records as necessary by the record determination unit 184, the record reflection unit 185, and the timer processing unit 187.

  The frame reception processing unit 140 calls the DNS response message processing unit 182 when the input frame is a DNS response message. Also, the DNS response message processing unit 182 uses an Answer Section determination unit 183 having an Answer Section determination function included in the response message.

  For the DNS response message received by the in-home terminal device 100, the network interface determination unit 160 determines whether the DNS response message has been input through a tunnel with the ISP network. The Answer Section determination unit 183 determines whether an IPv6 address for the AAAA record is included. The record determination unit 185 determines whether the record is updated. The record editing unit 186 deletes the IPv6 address and leaves the IPv6 address empty without registering it in the AAAA record of the cache database 188. Note that the record editing unit 186 may register the IPv6 address in the AAAA record of the cache database 188 without deleting the IPv6 address. FIG. 4 to be described later displays the latter state.

  Next, the residential terminal device 100 transmits a DNS response message in which an empty AAAA record is stored in the Answer Section to the service subscriber terminal. The DNS response message is created by the DNS response message processing unit 182 and transmitted using the frame processing unit 150.

  In FIG. 3, the in-home terminal device 100 includes a CPU 115, a memory 125, a storage device 135, and three network interfaces 110 that are interconnected by an internal communication line 105. The CPU 115 executes a program loaded from the storage device 135 to the memory 125. As is clear from the comparison between FIG. 2 and FIG. 3, the functional block in FIG. 2 is realized by a program executed by the CPU 115.

  In FIG. 4, the DNS cache table 188 includes a domain name 1881, a record 1882, and an IP address 1883. “A” in the record 1882 is an A record, and an IP address 1883 describes an IPv4 IP address. Further, “AAAAA” in the record 1882 is an AAAA record, and the IP address 1883 describes the IPv6 IP address.

  In FIG. 5, the DNS message 500 includes a Header Section 501, a Question Section 502, an Answer Section 503, an Authority Section 504, and an Additional Section 505. The Header Section 501 is an essential section and includes an identification field and the like. The Question Section 502 describes a question to the DNS server 410. The Answer Section 503 accommodates a resource record that is an answer from the DNS server 410. The Authority Section 504 contains a resource record that points to the authority. Further, the Additional Section 505 accommodates resource records having additional information.

  With reference to FIG. 6, the sequence between the home terminal device and the DNS server when the service subscriber terminal connects to the Internet server will be described. In FIG. 6, the service subscriber terminal 200 transmits a DNS query message for requesting an AAAA record to the in-home terminal device 100 (T301). The in-home terminal device 100 transfers the received DNS query message to the DNS server 410 of the ISP (T302).

  The DNS server 410 of the ISP performs name resolution of the AAAA record, and a DNS response message storing the IPv6 address is transmitted to the in-home terminal device 100 (T303). Upon receipt of the DNS response message 306, the in-home terminal device 100 determines the Answer Section (T304), deletes the IPv6 address, sets the empty Answer Section, and transmits the DNS response message to the terminal (T306).

  The service subscriber terminal 200 receives the DNS response message 308 and transmits a DNS query message requesting an A record (T307). Note that T301 and T307 are executed asynchronously. The home terminal device 100 transfers the DNS query message to the DNS server 410 of the ISP (T308). The DNS server 410 performs name resolution of the A record, and transmits a DNS response message storing the IPv4 address to the in-home terminal device 100 (T309). Upon receipt of the DNS response message, the in-home terminal device 100 determines Answer Section (T311), and transmits the DNS response message to the terminal without changing Answer Section (T312). The service subscriber terminal 200 that has received the DNS response message makes an IP address determination (T313), obtains an IPv4 address, and starts an IPv4 connection with an Internet server.

  FIG. 7 is a flowchart showing details of the answer section process of the DNS response message in the in-home terminal device 100, which is performed in the answer section determination process (T304 and T311) of FIG.

  In FIG. 7, when the DNS response message is received, the interface determination unit 160 determines whether the input interface is connected to the ISP connection tunnel (S402). If the tunnel is an ISP connection tunnel (YES), the Answer Section determination unit 183 investigates the Answer Section of the DNS response message (S403). If the IPv6 address for the AAAA record is stored in the Answer Section, the Answer Section determination unit 183 deletes the IPv6 address from the Answer Section (S404), and the process ends. If NO in step 402 or step 403, the process is terminated as it is.

  According to the present embodiment, only the in-home terminal device is changed, and the terminal of the service subscriber and the Internet server may remain existing.

It is a block diagram explaining the logical structure of a network. It is a functional block diagram of a home terminal device. It is a hardware block diagram of an in-home terminal device. It is a figure explaining a DNS cache table. This is a DNS message format. It is a sequence diagram among a terminal, a home terminal device, and a DNS server. It is a flowchart of Answer Section processing.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 ... Home terminal apparatus, 110 ... Network interface, 120 ... Device control part, 130 ... Tunnel control part, 140 ... Frame reception process part, 150 ... Frame transmission process part, 160 ... Interface determination part, 170 ... Frame transfer process part, 180 ... DNS control unit, 188 ... DNS cache database, 200 ... service subscriber terminal, 410 ... DNS server, 510 ... server.

Claims (3)

A first interface connected to the first network, a second interface connected to the terminal, and an interface determination unit for determining that the first interface is connected to the second network through a tunnel; A terminating device comprising a DNS control unit,
When the first interface receives the DNS response message and the interface determination unit determines that it is connected to the second interface, the DNS control unit deletes a predetermined address of the DNS response message Then, the terminal device is transferred to the terminal. The termination device according to claim 1,
The DNS control unit includes a DNS cache database. The termination device according to claim 1 or 2,
The termination apparatus, wherein the first network is an IPv6 network and the second network is an IPv4 network.

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