JP5971026B2 - Gateway device and program for gateway device - Google Patents

Description

  The present invention relates to a gateway device and a gateway device program, and can be applied to, for example, a SBC (Session Border Controller) having a NAPT (Network Address Port Translation) function.

  For example, when communication is performed across networks (networks) having different operation policies such as IP (Internet Protocol) telephones, SBCs are arranged at the boundaries between the networks to absorb differences in operation policies. .

  The conventional SBC implements the NAPT function of RTP / RTCP (Real-time Transport Protocol / RTP Control Protocol) signals as a solution function for the IPv4 (IP ver. 4) address exhaustion problem. The SBC has the above-mentioned NAPT function that performs media stream address conversion (including port number conversion) (address conversion is described in Patent Document 1), and ALG (Application Level Gateway) function that rewrites the contents of the protocol description. And have. The NAPT function for RTP / RTCP signals, when a call (session) is established via the SBC, the TrGW (Translator Gateway) part of the SBC issues a virtual address (including port number) for RTP / RTCP transmission / reception , SIP (Session Initiation Protocol) -ALG part sets this address at a predetermined location on the SIP signal described in SDP (Session Description Protocol), and notifies the arriving / departing UA (User Agent). This is realized by transmitting / receiving an RTCP signal via the TrGW unit.

JP 2010-193091 A

  By the way, there is a case where communication between the calling side network and the called side network is possible, and a call via the SBC passes through the SBC again (not necessarily the same as the above-mentioned SBC) by a transfer service or the like. When the call goes through the SBC again in this way, the virtual address has already been paid out, so if the payout is performed again, resources are wasted.

  The present invention has been made in consideration of the above points, and even when a gateway device having an address conversion function is provided in multiple stages, a gateway device capable of suppressing the address payout for address conversion to one time, and This is an attempt to provide a gateway device program.

The first aspect of the present invention is a gateway device including an address conversion unit that issues a virtual address and converts a caller-side address or a destination-side address of a call control signal into a virtual address that has been issued. (1) Upon receiving a call control signal, A discriminating means for analyzing the information of a predetermined field of the received call control signal, and determining whether or not the gateway device performs the virtual address delivery and address conversion; and (2) the received call control signal is the calling side. When the gateway device determines that the gateway device performs virtual address delivery and address conversion when the call control signal is directed from the gateway to the called party, the direction of travel from the gateway device to the predetermined field of the received call control signal A virtual gateway address and address translation by the gateway device And an information adding means for adding conversion control information that can determine that the information adding apparatus is the gateway apparatus; and (3) if the gateway apparatus does not execute the virtual address payout and address conversion, the determining means when it is determined to have a signal transmitting means for transmitting the received call control signals, (4) the predetermined field, the call control directed from the receiver side in response to the call control signal from the originating directed to the destination to the calling party This field also exists in the signal, and the field of the call control signal directed from the called side to the calling side also takes over the conversion control information. (5) The determination means includes the call control signal from the called side to the calling side. When receiving, based on the conversion control information, it recognizes whether or not the conversion control information adding device is the gateway device, and issues a virtual address. And (6) when a call control signal is sent from the incoming side to the outgoing side, the virtual address is issued and the address is converted. Is executed, it further comprises information deletion means for deleting the conversion control information from the predetermined field of the call control signal .

A program for a gateway device according to a second aspect of the present invention is a computer installed in a gateway device that includes an address conversion unit that issues a virtual address and converts a caller-side address or a callee-side address of the call control signal into a payout virtual address. (1) When receiving a call control signal, a determination unit that analyzes information of a predetermined field of the received call control signal and determines whether or not the gateway device executes a virtual address issuance and address conversion; 2) When the received call control signal is a call control signal directed from the calling side to the called side, when the determining unit determines that the gateway device performs the virtual address delivery and address conversion, the received call control signal In the predetermined field, the gateway device on the traveling direction side of the gateway device An information adding means for adding a translation control information capable of discriminating that the information adding device is the gateway device, and (3) issuing the virtual address and converting the address. When the determining means determines that the gateway device is not executed, it functions as a signal transmitting means for transmitting the received call control signal . (4) The predetermined field responds to the call control signal from the calling side to the receiving side. This field is also present in the call control signal going from the called side to the calling side, and the field of the call control signal going from the called side to the calling side also takes over the conversion control information. (5) When receiving a call control signal from the mobile station to the caller, the conversion control information adding device is based on the conversion control information. It recognizes whether or not it is a toy device, and determines whether or not the gateway device performs virtual address delivery and address translation. (6) Reception of call control signal from the incoming side to the outgoing side Sometimes, when the gateway device performs the virtual address delivery and the address translation, it further functions as an information deleting means for deleting the translation control information from a predetermined field of the call control signal .

  According to the present invention, it is possible to provide a gateway device and a gateway device program that can suppress the payout of addresses for address conversion to one time even when gateway devices having an address conversion function are provided in multiple stages.

It is a block diagram which shows an example of the large-scale network over several networks including SBC of embodiment. It is a flowchart (the 1) which shows the operation | movement at the time of reception of the SIP signal in SBC of embodiment. It is a flowchart (the 2) which shows the operation | movement at the time of reception of the SIP signal in SBC of embodiment. It is a sequence diagram in case SBC of three embodiment passes for transmission / reception of the SIP signal between transmission UA and termination | terminus UA. It is the sequence figure which showed centering on the process in SBC of embodiment which functions for address translation between origination UA and termination | terminus UA. It is the sequence figure which showed centering on the process in SBC of embodiment which does not function for address conversion between transmission UA and termination | terminus UA.

(A) Main Embodiment Hereinafter, an embodiment of a gateway device and a gateway device program according to the present invention will be described in detail with reference to the drawings. The gateway device of the embodiment is an SBC having a NAPT function.

(A-1) Configuration of Embodiment FIG. 1 is a block diagram illustrating an example of a large-scale network that spans multiple networks, including the SBC of the embodiment.

  The large-scale network shown in FIG. 1 includes first and second operator networks 1 and 2.

  FIG. 1 shows the internal details of the first operator network 1. The first operator network 1 has a subscriber accommodation network 3 and its upper switch network 4. The subscriber accommodation network 3 includes a plurality of SIP terminals (hereinafter also referred to as UAs) 5 as user terminals. The upper switch network 4 is an upper network of the subscriber accommodation network 3 and performs media packet exchange processing. The upper switch network 4 includes an SBC 6 that exchanges media packets with the SIP terminal 4 in accordance with UNI (User-Network Interface) (hereinafter also referred to as UNI-SBC) 6 and an NNI (Network-Network Interface). Accordingly, an SBC (which may be referred to as NNI-SBC hereinafter) 7 that exchanges media packets with the second operator network 2 and a SIP server 8 are included.

  The SIP server 8 has various functions to supplement direct communication between UAs. For example, “Register function” that accepts registration from UA or authenticates whether it is a correct terminal, “Proxy function” that accepts connection request from UA and forwards packet to partner UA, It has a “redirect function” that teaches a transfer destination address, a “location function” that manages UA information and receives inquiries from the above three functions. One SIP server 8 may be responsible for a plurality of functions, and the SIP server 8 may be provided for each function.

  In FIG. 1, only one UNI-SBC 6 is shown, but a plurality of UNI-SBCs 6 may be provided in the upper switch network 4 such as by region. Although only one NNI-SBC 7 is shown in FIG. 1, a plurality of NNI-SBCs 7 may be provided in the upper switch network 4 according to the number of other operator networks. That is, depending on the service, a route from the originating UA to the terminating UA may pass through a plurality of SBCs.

  Each of the UNI-SBC 6 and the NNI-SBC 7 is an SBC having a NAPT function, and corresponds to the gateway device of the embodiment. The UNI-SBC 6 includes, for example, a hardware communication configuration (transmission / reception unit) and a software execution configuration such as a CPU, a ROM, a RAM, and an EEPROM (registered trademark). Functions realized by the CPU executing the program stored in the ROM in the software execution configuration are functions as the TrGW unit 6a and the SIP-ALG unit 6b as shown in FIG. Similarly, the NNI-SBC 7 functionally includes a TrGW unit 7a and a SIP-ALG unit 7b.

  In this embodiment, when the SBC 6 or 7 receives a SIP signal (INVITE request) for establishing a call of a media line, it determines whether the SIP signal has already arrived via another SBC. If it is determined that the address is not routed through another SBC, the virtual address for address translation is issued, the source address is translated, the SIP signal is transferred, and the address is routed through another SBC. The incoming SIP signal is transmitted without paying out a virtual address for translation.

(A-2) Operation | movement of embodiment Next, operation | movement of SBC (UNI-SBC6 and NNI-SBC7) of embodiment is demonstrated, referring drawings. In the following description, the code “10” is applied to the SBC of the embodiment, the code “10a” is applied to the TrGW part of the SBC 10, and the code “10b” is applied to the SIP-ALG part of the SBC 10.

  2 and 3 are flowcharts showing an operation at the time of receiving a SIP signal in the SBC of the embodiment. 2 and 3 show the operation in relation to the address conversion function.

  When receiving the SIP signal, the SIP-ALG unit 10b of the SBC 10 determines whether or not the received SIP signal is a BYE request (step 100).

  If the received SIP signal is not a BYE request, the SIP-ALG unit 10b determines whether the SIP signal is from the outgoing UA to the incoming UA or from the incoming UA to the outgoing UA (step 101). For example, depending on the type of SIP signal, the direction of travel can be determined based on only the type of SIP signal this time, and the type of SIP signal received immediately before the same call and the type of SIP signal The traveling direction can be determined based on the relationship. For example, the INVITE request is a SIP signal from the outgoing UA to the incoming UA, and the 18x response and the 200 OK response are SIP signals from the outgoing UA to the incoming UA.

  If the received SIP signal is a SIP signal from the originating UA to the terminating UA, the SIP-ALG unit 10b determines whether there is a prefix in the Call-ID field (step 102). This determination is a determination as to whether or not the SBC 10 is an SBC that performs address translation in the case of a route from the originating UA to the incoming UA via a plurality of SBCs (however, the SBC 10 is It is not possible to recognize whether or not it goes through a plurality of SBC).

  When there is no prefix in the Call-ID field, the SIP-ALG unit 10b captures the media line (for example, when the received SIP signal is INVITE) or updates (for example, receives) the TrGW unit 10a in the same SBC10. Request (when the SIP signal is ACK) (step 103).

  The TrGW unit 10a issues a virtual address in response to the request, and returns the virtual address issued in response to the request to the SIP-ALG unit 10b (step 104).

  The SIP-ALG unit 10b changes the address information of the outgoing UA described in accordance with the SDP in the received SIP signal to the issued virtual address (step 105), and the Call-ID in the received SIP signal. A prefix is added to the field (step 106), and the SIP signal changed in this way is transmitted to the next node (SBC, SIP server or incoming UA) (step 107). The prefix added before the call specific information in the Call-ID field is composed of, for example, a character string indicating that it is related to address conversion and a numerical value indicating the number of SBC passes of the SIP signal subjected to address conversion. The numerical value immediately after the addition is the initial value “1”.

  If it is determined in the above-described step 102 that the Call-ID field of the received SIP signal has a prefix, the SIP-ALG unit 10b is described in the Call-ID prefix of the received SIP signal. After incrementing the numerical value by 1 (step 108), the SIP signal is immediately transmitted to the next node (SBC, SIP server or incoming UA) (step 109).

  If there is a prefix in the Call-ID field, only the above-described processing is performed, and the SIP-ALG unit 10b performs all media line control for the TrGW unit 10a, including media line acquisition requests and media line update requests. do not do.

  If the received SIP signal other than the BYE request is a SIP signal directed from the incoming UA to the outgoing UA, the SIP-ALG unit 10b determines whether the numerical value in the prefix of the Call-ID field is “1” (step 110). ). This determination is made as to whether or not the SBC 10 is an SBC that performs address translation in the case of a route from the incoming UA to the outgoing UA via a plurality of SBCs (however, the SBC 10 is It is not possible to recognize whether or not it goes through a plurality of SBC).

  When the numerical value in the prefix of the Call-ID field is “1”, the SIP-ALG unit 10b requests the TrGW unit 10a in the same SBC 10 to update the media line (step 111).

  The TrGW unit 10a issues a virtual address in response to the request, and returns the virtual address issued in response to the request to the SIP-ALG unit 10b (step 112).

  The SIP-ALG unit 10b changes the address information of the incoming UA described in accordance with SDP in the received SIP signal to the issued virtual address (step 112), and the Call-ID in the received SIP signal. The prefix in the field is deleted (step 113), and the SIP signal changed in this way is transmitted to the next node (SIP server or outgoing UA) (step 114).

  If it is determined in step 110 described above that the numerical value of the prefix in the Call-ID field of the received SIP signal is greater than 1, the SIP-ALG unit 10b uses the Call-ID prefix of the received SIP signal as the prefix. After decrementing the described numerical value by 1 (step 115), the SIP signal is immediately transmitted to the next node (SIP server or transmission UA) (step 116).

  When the prefix value in the Call-ID field is larger than 1, only the above-described processing is performed, and the SIP-ALG unit 10b does not perform any media line control for the TrGW unit 10a including the media line update request. .

  If it is determined in step 100 above that the received SIP signal is a BYE request, the SIP-ALG unit 10b requests the TrGW unit 10a to release the media line (step 117). At this time, the TrGW unit 10a responds to the SIP-ALG unit 10b by releasing the virtual address issued for replacement with the address of the originating UA and the virtual address issued for replacement with the address of the incoming UA (step 118). Waiting for this response, the SIP-ALG unit 10b transmits a BYE request to the next node (step 119).

  FIG. 4 shows a sequence diagram in the case where three SBCs pass through the exchange of SIP signals between the originating UA and the terminating UA. Although a SIP server (see reference numeral 8 in FIG. 1) is also interposed between the originating UA and the terminating UA as appropriate, this embodiment is characterized by the processing in the SBC. The illustration of the intervention is omitted.

  Assume that the originating UA 11 describes the address of the originating UA in SDP, sends an INVITE request including “ABC” as information specifying the call in the Call-ID field, and this INVITE request reaches the SBC 10-1. .

  Since the SBC 10-1 is a SIP signal from the originating UA 11 to the terminating UA 12 and does not include a prefix in the Call-ID field, the SBC 10-1 issues a virtual address (here, address B) and originates the SDP. The UA address is replaced with the issued virtual address B, and a prefix is added to the Call-ID field and transferred to the next node (here, SBC 10) (S1).

  The SBC 10-2 includes a prefix in the Call-ID field of the received INVITE request, so the prefix value is incremented by 1 and changed to “2” and immediately the next node (here, SBC 10-3). (S2). Similarly, since the prefix is included in the Call-ID field of the received INVITE request, the SBC 10-3 increments the numerical value of the prefix by 1 and changes it to “3” and immediately receives the next node (in this case, the incoming UA12). (S3).

  Since the incoming UA 12 has received the INVITE request, the incoming UA 12 returns a SIP signal as a reception response. Here, it is assumed that the SIP signal is an 18x response. In the 18x response that is a SIP signal from the incoming UA 12 to the outgoing UA 11, the address of the incoming UA is described in SDP, and the Call-ID field has the same information as the Call-ID field of the received INVITE request.

  The SBC 10-3 to which the 18x response has arrived is a SIP signal from the incoming UA 12 to the outgoing UA 11, and since the numeric value of the prefix in the Call-ID field is “3”, the numerical value of the prefix is decremented by 1 to “2”. Immediately after the change, the data is transferred to the next node (here, SBC 10-2) (S4). Similarly, since the numerical value of the prefix in the Call-ID field of the received 18x response is “2”, the SBC 10-2 decrements the numerical value of the prefix by 1 and changes it to “1” immediately after the next node (here Then, the data is transferred to SBC 10-1 (S5).

  The SBC 10-1 to which the 18x response has arrived is a SIP signal from the incoming UA 12 to the outgoing UA 11, and since the numeric value of the prefix in the Call-ID field is “1”, the virtual address (here, address A) is issued. Then, the address of the incoming UA described in the SDP is replaced with the issued virtual address A, the prefix is deleted from the Call-ID field, and it is transferred to the next node (here, called the outgoing UA 11) (S6).

  On the incoming UA side, the same processing as that of the 18x response is executed for the address conversion for the 200 OK response sent from the incoming UA 12 because the subscriber goes off-hook.

  FIG. 5 is a sequence diagram that mainly shows processing in the SBC (reference numeral 10 is used in the following description) that functions for address conversion between the originating UA and the terminating UA.

  When the SIP-ALG unit 10b of the SBC 10 receives the INVITE request in which the address of the originating UA is described in SDP, the TrGW unit 10a requests the TrGW unit 10a to acquire the media line (S11). The virtual address B is issued and responded to the SIP-ALG unit 10b (S12, S13), and the SIP-ALG unit 10b replaces the address of the outgoing UA described in SDP with the virtual address B as the next node. To send.

  In the case of this embodiment, if the SIP signal from the originating UA 11 to the terminating UA 12 and the SIP signal from the terminating UA 12 to the originating UA 11 are both SIP signals related to the same call, the same SBC 10 executes the address conversion process.

  When an 18x response or a 200 OK response corresponding to the above-mentioned INVITE request arrives, the SIP-ALG unit 10b of the SBC 10 requests the TrGW unit 10a to update the media line (S21), and the TrGW unit 10a responds to this request. The virtual address A is issued and responded to the SIP-ALG unit 10b (S22, S23). The SIP-ALG unit 10b sends an 18x response or 200OK response in which the address of the incoming UA described in SDP is replaced with the virtual address A. Send to the next node.

  When the SIP-ALG unit 10b of the SBC 10 receives the BYE request (in FIG. 5, the source UA 11 is the transmission source, the same applies when the incoming UA 12 is the transmission source), the TrGW unit 10a is requested to release the media line. In response to this request, the TrGW unit 10a releases the virtual addresses A and B and responds to the SIP-ALG unit 10b (S32, S33), and the SIP-ALG unit 10b waits for this response. A BYE request is sent to the next node.

  FIG. 6 is a sequence diagram mainly showing processing in SBC (reference numeral 10 is used in the following description) that does not function for address conversion between the outgoing UA and incoming UA.

  Although a detailed description is omitted, the SIP-ALG unit 10b of the SBC 10 that does not function for address translation allows any type of SIP signal to pass therethrough. However, except for the BYE request, the prefix value is incremented by 1 for the SIP signal from the originating UA 11 to the terminating UA 12, and the prefix value is decremented by 1 for the SIP signal from the terminating UA 12 to the originating UA 11.

(A-3) Effect of Embodiment According to the above embodiment, even if a plurality of SBCs are present on the route from the UA on the caller side to the UA on the callee side, the virtual address is issued and address conversion is performed. The number of SBCs can be reduced to one, virtual addresses are not paid out by other SBCs, and consumption of extra resources can be eliminated when viewed as the entire network.

(B) Other Embodiments In the above-described embodiment, the virtual address is issued and the information related to the conversion is added to the front side (prefix) of the call identification information in the Call-ID field. Information relating to paying out of the virtual address and conversion may be added to the rear side.

  In the above-described embodiment, the information for recognizing the SBC for issuing a virtual address and address conversion for the SIP signal from the incoming UA to the outgoing UA is shown as the prefix numerical value, but other information may be used. . To pass through the SBC, add or delete the product number of the SBC, and based on the product number of the prefix, issue a virtual address for the SIP signal from the incoming UA to the outgoing UA, and recognize the SBC that performs address conversion You may make it let it. Also, each time it passes, the SBC product number is not added or deleted, but only the SBC product number for which a virtual address is issued and address conversion is described in the prefix, and each SBC has its own product number described. You may make it confirm whether it is.

  In the above embodiment, the application to the SBC having the NAPT function is shown. However, the present invention can be applied to other apparatuses having the address conversion function.

  DESCRIPTION OF SYMBOLS 10, 10-1-10-3 ... SBC, 10a ... TrGW part, 10b ... SIP-ALG part, 11 ... Originating UA, 12 ... Incoming UA.

Claims (3)

In a gateway device comprising an address conversion unit that issues a virtual address and converts a caller-side address or a callee-side address of the call control signal into a paid-out virtual address,
A determination unit that analyzes information of a predetermined field of the received call control signal at the time of reception of the call control signal, and determines whether or not the gateway device performs virtual address allocation and address conversion;
When the received call control signal is a call control signal directed from the calling side to the called side, the predetermined field of the received call control signal when the gateway unit performs the virtual address assignment and address conversion. And an information adding means for adding a conversion control information capable of discriminating that the information adding device is the gateway device while preventing the virtual device from issuing a virtual address and address conversion by the gateway device on the traveling direction side from the gateway device. ,
When the payout and address translation of the virtual address corresponding gateway device does not execute the determination means has determined to have a signal transmitting means for transmitting the received call control signals,
The predetermined field is also present in a call control signal from the incoming side to the outgoing side in response to a call control signal from the outgoing side to the incoming side, and a field of a call control signal from the incoming side to the outgoing side is also present. , Taking over the above conversion control information,
The determination means recognizes whether or not the addition device of the conversion control information is the gateway device based on the conversion control information when receiving a call control signal from the incoming side to the outgoing side, To determine whether or not the gateway device performs the address conversion,
An information deletion means for deleting the conversion control information from a predetermined field of the call control signal when the gateway device performs a virtual address delivery and address conversion upon reception of a call control signal from the called side to the calling side; A gateway device further comprising: The conversion control information includes a numerical value indicating the number of passages of the gateway device,
The signal transmission means increments the numerical value when transmitting a call control signal from the calling side to the receiving side, and denies the numerical value when transmitting a call control signal from the receiving side to the calling side. after increment, the gateway device according to claim 1, characterized in that to transmit the call control signal. A computer installed in a gateway device provided with an address conversion unit that pays out a virtual address and converts a calling address or a called address of a call control signal into a paid-out virtual address,
A determination unit that analyzes information of a predetermined field of the received call control signal at the time of reception of the call control signal, and determines whether or not the gateway device performs virtual address allocation and address conversion;
When the received call control signal is a call control signal directed from the calling side to the called side, the predetermined field of the received call control signal when the gateway unit performs the virtual address assignment and address conversion. And an information adding means for adding a conversion control information capable of discriminating that the information adding device is the gateway device while preventing the virtual device from issuing a virtual address and address conversion by the gateway device on the traveling direction side from the gateway device. ,
When the determination unit determines that the gateway device does not perform virtual address delivery and address conversion, it functions as a signal transmission unit that transmits the received call control signal .
The predetermined field is also present in a call control signal from the incoming side to the outgoing side in response to a call control signal from the outgoing side to the incoming side, and a field of a call control signal from the incoming side to the outgoing side is also present. , Taking over the above conversion control information,
The determination means recognizes whether or not the addition device of the conversion control information is the gateway device based on the conversion control information when receiving a call control signal from the incoming side to the outgoing side, To determine whether or not the gateway device performs the address conversion,
As information deletion means for deleting the conversion control information from a predetermined field of the call control signal when the gateway device executes the virtual address delivery and address conversion when receiving the call control signal from the called side to the calling side. A gateway device program characterized by further functioning .

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