Patent Document

CROSS-REFERENCE TO RELATED APPLICATIONS  
       [0001]     This application claims priority based on Japanese patent application No. 2005-320854 filed on Nov. 4, 2004, the entire contents of which are incorporated herein by reference.  
       BACKGROUND  
       [0002]     The present invention relates to an information processor, a method and program for controlling an incident response device.  
         [0003]     In recent years, the importance of a response (hereinafter referred to as “incident response”) to a computer security incident (hereinafter abbreviated to “incident”) in a communication system has been recognized. Japanese Patent Application Laid-open Publication No. 2003-288282 discloses a program for preventing unauthorized accesses via a network.  
       SUMMARY OF THE INVENTION  
       [0004]     According to the program disclosed in Japanese Patent Application Laid-open Publication No. 2003-288282 or other such conventional techniques, a processing is automatically executed based on a predetermined rule. Therefore, an operator cannot flexibly determine which incident response to be performed, in accordance with a location where an incident has occurred and an importance level of the incident.  
         [0005]     The present invention has been contrived in consideration of such circumstances, and it is an object of the invention to provide an information processor capable of providing an operator with a possible incident response, and a method and program for controlling an incident response device.  
         [0006]     In order to solve the aforementioned problem, a primary aspect of the present invention is an information processor for controlling an incident response device which performs an incident response toward a communication device, comprising an incident detecting unit for detecting an incident occurrence in the communication device, a response policy storage unit for storing response information which is information indicative of the incident response that the incident response device should perform, and target information which is information to identify the communication device toward which the incident response is to be performed, with corresponding policy information regarding a response policy to an incident, a policy list out put unit for out putting a list of the policy information stored in the response policy storage unit when an incident occurrence is detected, a policy selection unit for receiving a selection of the policy information, a response policy retrieving unit for retrieving the response information and the target information corresponding to the selected policy information, from the response policy storage unit, and a command sending unit for sending the incident response device a command to perform the incident response based on the retrieved response information toward the communication device identified based on the retrieved target information.  
         [0007]     According to the present invention, it is possible to provide an operator with a possible incident response.  
         [0008]     These and other benefits are described throughout the present specification. A further understanding of the nature and advantages of the invention maybe realized by reference to the remaining portions of the specification and the attached drawings. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0009]      FIG. 1  exemplifies the overall configuration of an implementation of a communication system according to the present invention;  
         [0010]      FIG. 2  exemplifies the hardware configuration of an IDS  20 ;  
         [0011]      FIG. 3  exemplifies the software configuration of the IDS  20 ;  
         [0012]      FIG. 4  exemplifies a configuration example of incident information  61 ;  
         [0013]      FIG. 5  exemplifies the hardware configuration of a router  30 ;  
         [0014]      FIG. 6  exemplifies the software configuration of the router  30 ;  
         [0015]      FIG. 7  exemplifies an example of a configuration file  62 ;  
         [0016]      FIG. 8  exemplifies the hardware configuration of a manager device  40 ;  
         [0017]      FIG. 9  exemplifies the software configuration of the manager device  40 ;  
         [0018]      FIG. 10  exemplifies the configuration of an incident information database  45 ;  
         [0019]      FIG. 11  exemplifies the configuration of a device management database  46 ;  
         [0020]      FIG. 12e xemplifies the configuration of template information;  
         [0021]      FIG. 13  exemplifies the flow of the process for registering template information;  
         [0022]      FIG. 14  exemplifies a setting information registration screen  71 ;  
         [0023]      FIG. 15  exemplifies an incident monitor screen  72 ;  
         [0024]      FIG. 16  exemplifies the flow of the process for controlling the router  30  by the manager device  40 ;  
         [0025]      FIG. 17  exemplifies each of response policy selection screens  73  and  74 ;  
         [0026]      FIG. 18  exemplifies the flow of the process for determining recommendation levels for response policies by a recommendation level determining unit  413 ;  
         [0027]      FIG. 19  exemplifies tables that hold scores used in determining recommendation levels for response policies; and  
         [0028]      FIG. 20  exemplifies flows of processes in a communication system configured such that the manager device  40  is used as a server, and a working terminal is used as a client to access the server. 
     
    
     DETAILED DESCRIPTION OF THE EMBODIMENTS  
       [0000]     Overall Configuration  
         [0029]      FIG. 1  shows the overall configuration of an implementation of a communication system according to the present invention. As shown in  FIG. 1 , in the communication system of this implementation, a plurality of network segments  52  (hereinafter abbreviated to “segments  52 ”) is connected to a backbone network  51  (hereinafter abbreviated to “backbone  51 ”) laid in an organization through routers  30 . In this implementation, the backbone  51  and the segments  52  are configured to form a communication network with the Ethernet (registered trademark), a public telephone line or other means, and it is assumed that communications on this network are executed based on the TCP/IP protocol.  
         [0030]     A server  10  which provides information processing services, and an intrusion detection system  20  (hereinafter referred to as “IDS  20 ”) which detects an incident that has occurred in the server  10  are connected to each segment  52 .  
         [0031]     The server  10  is a computer for processing information. The incident that has occurred in the server  10  refers to an incident related to computer security, for example, an unauthorized use of resources, interference with services, a destruction of data, an information leakage without consent, and others. Specifically, there are included an unauthorized access such as ICMP attack or SYN-Flood attack, and a potential unauthorized access such as access failure that a user tries and fails to log in a predetermined number or more of times or a port scan.  
         [0032]     The IDS  20  inspects packets transmitted on the communication network or receives a communication log from the server  10  to detect an incident occurrence in the server  10 . The information about the incident detected by the IDS  20  (hereinafter referred to as “incident information”) is sent to a manager device  40 .  
         [0033]     The manager device  40  is a computer operated by an operator, and displays the incident information notified from the IDS  20  and changes the setting of the router  30  in accordance with the operator&#39;s instruction.  
         [0034]     The router  30  is a computer for executing routing control between the backbone  51  and the segment  52 , and controls packet transfer. The router  30  has a so-called firewall function and thus can control communications with the server  10 . In this implementation, the router  30  functions as an incident response unit that performs incident responses, blocking the communications with the server  10  in which the incident has occurred.  
         [0035]     For the sake of the simplification of explanation, in this implementation, an incident response to an incident that has occurred in the server  10  means only a blockage of communications with the server  10 . However, an incident response by an incident response unit is not limited to this action. In addition to a blockage of communications with the server  10 , incident responses may include the change of a user&#39;s password managed by the server  10 , the update of an application program run on the server  10 , the change of a file permission managed by the server  10 , the backup or restore of data managed by the server  10 , and a packet transfer to another computer which is set aside as an alternative to the server  10 .  
         [0000]     IDS  20   
         [0036]      FIG. 2  shows the hardware configuration of the IDS  20 . The IDS  20  comprises a CPU  201 , a memory  202 , a storage device  203 , and a communication interface  204 . The storage device  203  stores programs and data. As the storage device, for example, a hard disk drive, a CD-ROM drive, or a flash memory is used. The CPU  201  reads out a program stored in the storage device  203  to the memory  202 , and executes the program to realize various functions. The communication interface  204  is an interface for connection with the segments  52 . The communication interface  204  is, for example, an adaptor connected with the Ethernet (registered trademark) or a modem connected with a public telephone line.  
         [0037]      FIG. 3  shows the software configuration of the IDS  20 . The IDS  20  comprises an incident detecting unit  211  and an incident information sending unit  212 .  
         [0038]     The incident detecting unit  211 , for example, captures packets transmitted through the segment  52  or receives a communication log from the server  10  to detect whether or not an incident has occurred in the server  10 . The incident detecting unit  211  can detect an incident using a method adopted in commonly used intrusion detection devices.  
         [0039]     The incident information sending unit  212  sends the manager device  40  incident information  61  about an incident detected by the incident detecting unit  211 .  FIG. 4  shows a configuration example of the incident information  61  to be sent by the incident information sending unit  212 . The incident information  61  comprises a detection date and time  611  that indicates when the incident was detected, a detecting device  612  that indicates the name of the IDS  20 , an IP address  613  that indicates the network address of the IDS  20 , an incident  614  that indicates the detected incident, a service  615  that indicates the server  10 &#39;s service related to the incident, and a user  616  that indicates the user related to the incident. Some incidents are not related to the user of the server  10 . In such cases, “-” is set in the user  616 .  
         [0040]     Here, the incident detecting unit  211  and the incident information sending unit  212  are realized by the CPU  201 &#39;s executing the programs stored in the storage device  203 .  
         [0000]     Router  30   
         [0041]      FIG. 5  shows the hardware configuration of the router  30 . The router  30  comprises a CPU  301 , a memory  302 , a storage device  303 , and communication interfaces  304  and  305 . The storage device  303  stores programs and data. As the storage device, for example, a hard disk drive, a CD-ROM drive or a flash memory is used. The CPU  301  reads out a program stored in the storage device  303  to the memory  302 , and executes the program to realize various functions. The communication interface  304  is an interface for connection with the backbone  51 . The communication interface  305  is an interface for connection with the segment  52 . The communication interface  304  or  305  is, for example, an adaptor connected with the Ethernet (registered trademark) or a modem connected with a public telephone line.  
         [0042]      FIG. 6  shows the software configuration of the router  30 . The router  30  comprises a configuration file receiving unit  311 , a routing unit  312 , and a configuration file storage unit  35 .  
         [0043]     The configuration file receiving unit  311  receives a configuration file  62  which is related to routing and is sent from the manager device  40  described below, and then stores the received file  62  in the configuration file storage unit  35 .  
         [0044]     The configuration file  62  includes a rule that defines whether or not to allow packet transfer.  FIG. 7  shows an example of the configuration file  62 . In the example of  FIG. 7 , the configuration file  62  is written in the XML format. In this configuration file  62 , each rule is set within one &lt;AC&gt; tag. In the &lt;AC&gt; tag, “allow” or “deny” is set as a type attribute. If “allow” is set in the type attribute, the packet transfer is allowed. If “deny” is set in the type attribute, the packet transfer is denied. Also in this configuration file  62 , as children of the &lt;AC&gt; tag, a &lt;SRC&gt; tag, a &lt;DST&gt; tag, and a &lt;PORT&gt; tag are provided. As the value attributes in the &lt;SRC&gt; tag and the &lt;DST&gt; tag, the conditions of a packet sender and a packet receiver are specified respectively. Furthermore, in the &lt;PORT&gt; tag, the number of a port to which the server  10  provides a service is specified as the value attribute. A wildcard (“*”) can be set as the value attributes of the respective tags. The example of  FIG. 7  shows the &lt;AC&gt; tag having an id attribute of “0001” in which packets are “allowed” to be transferred from “segment  1 ” to “backbone” through the port of number “80”.  
         [0045]     The routing unit  312  handles packet routing between the backbone  51  and the segment  52 . The routing processing by the routing unit  312  is the same as one by a general router. The router  30  references the configuration file  62  stored in the configuration file storage unit  35  and applies the rules from the top in the file to the packet to be transferring, and then determines whether or not the packet can be transferred. The example of  FIG. 7  shows that, with the &lt;AC&gt; tag having the id attribute “0999”, all packets other than packets addressed to the port of number “80” or “25” should be denied to be transferred. Hence, when the router  30  follows the configuration file  62  of  FIG. 7 , only the packets addressed to the port of number “80” or “25” can be transferred.  
         [0046]     Meanwhile, the configuration file receiving unit  311  and the routing unit  312  are realized by that the CPU  301  included in the router  30  reads out the program stored in the storage device  303  to the memory  302 , and executes the program. Furthermore, the configuration file storage unit  35  is provided as a storage area in the memory  302  or the storage device  303  of the router  30 .  
         [0000]     Manager Device  40   
         [0047]      FIG. 8  shows the hardware configuration of the manager device  40 . The manager device  40  comprises a CPU  401 , a memory  402 , a storage device  403 , a communication interface  404 , an input device  405 , and an output device  406 . The storage device  403  stores programs and data. As the storage device, for example, a hard disk drive or a CD-ROM drive is used. The CPU  401  reads out a program stored in the storage device  403  to the memory  402 , and executes the program to realize various functions. The communication interface  404  is an interface for connection with the backbone  51 . For example, the communication interface is an adaptor connected with the Ethernet (registered trademark) or a modem connected with a public telephone line.  
         [0048]      FIG. 9  shows the software configuration of the manager device  40 . The manager device  40  comprises function parts such as an incident information receiving unit  411 , an incident information display unit  412 , a recommendation level determining unit  413 , a response policy display unit  414 , a response command input unit  415 , a configuration file sending unit  416 , a recovery command input unit  417 , and a response policy setting unit  418 , and databases such as an incident information database  45 , a device management database  46 , and a template information database  47 .  
         [0049]     The incident information database  45  stores the incident information  61  sent from the IDS  20 .  FIG. 10  shows the configuration of the incident information database  45 . As shown in  FIG. 10 , the incident information database  45  records the history of the aforementioned incident information  61  of  FIG. 4 .  
         [0050]     The device management database  46  stores information about the IDS  20  and the router  30  (hereinafter collectively referred to as “agent”) managed by an operator at the manager device  40 .  FIG. 11  shows the configuration of the device management database  46 . As shown in  FIG. 11 , the device management database  46  stores an agent name  461 , an agent IP address  462 , an agent type  463 , and a configuration file source  464 , coordinating each item. In the type  463 , “detect” or “respond” is set. If the “detect” is set in the type  463 , the agent is the IDS  20  for detecting an incident. If the “respond” is set in the type  463 , the agent is the router  30  for making an incident response. If the agent is the router  30 , the configuration file source  464  is URL (Uniform Resource Locator) for an access to the configuration file  62  managed by the router  30 . The configuration file source  464  is not limited to URL as long as it indicates where the configuration file  62  is stored.  
         [0051]     The template information database  47  stores information including a response policy applied when an incident has occurred in the server  10 , and a configuration file  62  to be sent to the router  30  (hereinafter referred to as “template information”).  FIG. 12  shows the configuration of the template information. As shown in  FIG. 12 , the template information stores a configuration file name  472 , and a name  473  of a router as destination of the configuration file  62 , coordinating with a response policy  471  that indicates a policy in an incident occurrence. The configuration file name  472  indicates the name of the configuration file  62  managed by the manager device  40 . In this implementation, the response policy  471  has one of five kinds of policies “normal time”, “stop all services in all servers”, “stop only the appropriate service in all servers”, “stop all services in the appropriate server”, and “stop only the appropriate service in the appropriate server”.  
         [0052]     The incident information receiving unit  411  receives the incident information  61  sent from the IDS  20  and registers the received incident information  61  in the incident information database  45 . The incident information display unit  412  displays the incident information  61  registered in the incident information database  45 . A screen example of the incident information display unit  412  displaying the incident information  61  is shown later.  
         [0053]     The recommendation level determining unit  413  determines recommendation levels of response policies to an incident (sequence of response policies). The process for determining recommendation levels of the response policies is described in detail later. The response policy display unit  414  displays the response policies in the descending order of their recommendation levels. An example of a screen displaying the response policies is shown later.  
         [0054]     The response command input unit  415  receives an entry of a command to perform an incident response (hereinafter referred to as “response command”). In this implementation, the response command input unit  415  receives a selection of a response policy on the response policy display screen as entry of a response command.  
         [0055]     The recovery command input unit  417  receives an entry of a command to reset the setting of the router  30  to the previous one which has been changed in accordance with the incident response (hereinafter, referred to as “recovery command”). The recovery command may be entered using a keyboard or the like, or entered by clicking a button displayed on the screen with a mouse.  
         [0056]     The configuration file sending unit  416  sends the router  30  the configuration file  62  corresponding to the response policy selected by an operator. In this implementation, the configuration file sending unit  416  reads out the template information from the template information database  47 , and sends the configuration file  62  specified in the configuration file name  472  to the router  30  in the name  473 .  
         [0057]     The response policy setting unit  418  creates template information and registers it in the template information database  47 .  
         [0000]     Template Information Registration  
         [0058]      FIG. 13  shows the flow of the process for registering template information.  FIG. 14  shows an example of a setting information registration screen  71  used for registering template information.  
         [0059]     The setting information registration screen  71  includes a pull-down list  711  for selecting a router  30  to be registered, and option buttons  712  for selecting a response policy. The response policy setting unit  418  reads out the name(s) in  461  with “respond” set in the type  463  from the device management database  46 , and sets the list of the read name(s)  461  in the pull-down list  711 .  
         [0060]     The setting information registration screen  71  includes an edit box  713  showing the setting information written in each &lt;AC&gt; tag(s) of the configuration file  62 . Each line of the edit box  713  corresponds to one &lt;AC&gt; tag. The number of the &lt;AC&gt; tags can be increased by an operator&#39;s clicking an “add” button  7131  in the upper portion. Moreover, when a “delete” button  7133 , an “up” button  7134 , or a “down” button  7135  is clicked after a radio button  7132  provided at the head of each setting information line is selected, the selected setting information can be deleted or the order of the setting information can be rearranged accordingly.  
         [0061]     Furthermore, the setting information registration screen  71  includes an entry field  714  for specifying a configuration file  62 . An operator can specify a created configuration file  62  without using the edit box  713 .  
         [0062]     Once receiving selections of the router  30  to be registered from the pull-down list  711  (S 511 ) and the response policy by a click on the option button  712  (S 512 ), the response policy setting unit  418  starts to search the template information database  47  for the template information corresponding to the selected router  30  and response policy. If the corresponding template information cannot be found (S 513 : YES), the configuration file source  464  corresponding to the selected router  30  is retrieved from the device management database  46 , and the configuration file  62  specified in the retrieved configuration file source  464  is obtained (S 514 ). On the other hand, if the corresponding template information is found (S 513 : NO), the configuration file name  472  is retrieved from the template information database  47  (S 515 ), and the configuration file  62  specified in the configuration file name  472  is obtained (S 516 ).  
         [0063]     The response policy setting unit  418  lists the setting information in the edit box  713  based on the thus-acquired configuration file  62 , and receives an entry about setting information from an operator (S 517 ). The response policy setting unit  418  creates a configuration file  62  based on the entered setting information (S 518 ), creates a template information in which the selected response policy, the selected router  30 , and the name of the created configuration file  62  are set (S 519 ), and then registers the created template information in the template information database  47  (S 520 ).  
         [0064]     It should be noted that at the time of creating setting information, the information should be created to cover all possible combinations of senders, receivers, and services. Also in the example of  FIG. 14 , wildcards are used in the third setting information so that the packets not matching with conditions set in the first and second information are denied to be transferred with respect to all senders, receivers, and services.  
         [0065]     Furthermore, in this registration, all possible combinations of the routers  30  and the response policies should be covered.  
         [0066]     In this way, the template information database  47  stores and manages the configuration file  62  which is used for controlling the incident response performed by the router  30  (in this implementation, a blockage of communications with the server  10 ) in accordance with one of the above four response policies when an incident has occurred in the server  10 .  
         [0000]     Incident Monitor Screen  
         [0067]     The manager device  40  of this implementation displays the incident information  61  reported by the IDS  20  to allow an operator to monitor the occurrence of an incident.  FIG. 15  shows an example of a screen  72  displaying the incident information  61  (hereinafter, referred to as “incident monitor screen  72 ”). As shown in  FIG. 15 , the incident monitor screen  72  includes a directory pane  721  that shows the network configuration of the communication system in tree structure, a device pane  722  in which communication devices are lined up, and a list box  723  in which the incident information  61  are listed.  
         [0068]     In the directory pane  721  are displayed the server  10 , the IDS  20  and the router  30  which are connected with each of the segments  52  from “segment  1 ” to “segment  4 ”.  
         [0069]     In the device pane  722 , the communication devices connected with the backbone  51  and the segments  52  are lined up in the form of icon. The displayed icons may be changed depending on the type of a communication device. Also, it is possible to set like when a segment  52  is selected in the directory pane  721 , the communication devices displayed in the device pane  722  are changed accordingly. In this case, when “segment  1 ” is selected in the directory pane  721 , only the communication devices connected with “segment  1 ”, that is, “server  1 , “IDS  1 ”, and “router  1 ” are listed in the device pane  722 .  
         [0070]     The list box  723  shows a history of the incident information  61  registered in the incident information database  45 . The incident information display unit  412 , for example, reads out the incident information  61  detected from the current time to a predetermined time ago, from the incident information database  45  and lists the information in the list box  723  in the order of the detection date and time  611 .  
         [0071]     Meanwhile, in the device pane  722 , the IDS  20  specified in the detecting device  612  of the incident information  61  and the server  10  corresponding to the IP address in  613  may be highlighted.  
         [0000]     Controlling Router  30   
         [0072]     When the IDS  20  is selected in the device pane  722  on the incident monitor screen  72 , the manager device  40  displays a list of response policies to the incident detected by the selected IDS  20 , and controls the router  30  to perform an incident response corresponding to the response policy selected by an operator.  FIG. 16  shows the flow of the process for controlling the router  30  by the manager device  40 .  FIG. 17  shows an example of each of response policy selection screens  73  and  74  used in this process.  
         [0073]     When the IDS  20  is selected in the incident monitor screen  72  (S 531 ), the manager device  40  reads out from the incident information database  45  the incident information  61  where the selected IDS  20  (hereinafter referred to as “selected IDS”) is set in the detecting device  612 , and the detection date and time  611  falls from the current time to a predetermined time ago (S 532 ). Then, the manager device  40  displays a response policy selection screen  73  of  FIG. 17 . The response policy selection screen  73  includes a field  731  where the selected IDS is displayed, a field  732  where the above-mentioned period is displayed, and a list box  733  where the read incident information  61  are listed.  
         [0074]     The manager device  40  determines whether or not the same incident has occurred in the segment  52  different from the segment  52  connected with the selected IDS for each of the read incident information  61 , by finding whether or not the incident information database  45  has the incident information  61  in which the IDS  20  different from the selected IDS is set in the detecting device  612 , using the incident  614  as a key (S 533 ). The response policy selection screen  73  includes a field  734  for selecting the segment  52  to which an incident response will be performed. If the same incident has occurred in the different segment  52  (S 533 : YES), the manager device  40  increases the recommendation level for a segment policy saying “Change settings in all segment” and put it above another policy saying “Change the setting only in the appropriate segment” on the response policy selection screen  73  (S 534 ).  
         [0075]     Conversely, if the same incident has not occurred in the different segment  52  (S 533 : NO), the manager device  40  increases the recommendation level for a segment policy saying “Change the setting only in the appropriate segment” and put it above another policy saying “Change settings in all segments” on the response policy selection screen (S 535 ).  
         [0076]     When an operator clicks a select button  735  corresponding to any one of the segment policies which define the extent of target and are displayed on the response policy selection screen  73  (S 536 ), the manager device  40  determines the segment(s)  52  to which the incident response will be performed in accordance with the selected policy, and then determines the router(s)  30  which are in the determined segment(s)  52  and are connected with the backbone  51  as the router(s)  30  to be set (hereinafter referred to as “setting-target router”) (S 537 ). If the segment policy saying “Change settings in all segments” is selected, the manager device  40  determines all the routers  30  registered in the device management database  46  as the setting-target router. Meanwhile, if the segment policy saying “Change the setting only in the appropriate segment” is selected, the manager device  40  identifies the segment  52  from the IP address  613  in each of the incident information  61  retrieved in the above-mentioned step (S 532 ), and identifies the router  30  corresponding to the identified segment  52  from the device management database  46 .  
         [0077]     The recommendation level determining unit  413  of the manager device  40  determines the recommendation levels for the four response policies which are “Stop all services in all servers”, “Stop only the appropriate service in all servers”, “Stop all services in the appropriate server”, and “Stop only the appropriate service in the appropriate server” (S 538 ), and then the response policy display unit  414  lists the four response policies in order of the determined recommendation level on the response policy selection screen  74  of  FIG. 17  (S 539 ). The process for determining the recommendation levels of the response policies is described in detail later.  
         [0078]     The response command input unit  415  of the manager device  40  receives a click (response command) on a select button  742  corresponding to any one of the response policies displayed on the response policy selection screen  74  (S 540 ). The configuration file sending unit  416  reads out the template information corresponding to the selected response policy and the selected IDS described above from the template information database  47  (S 541 ), and sends the configuration file  62  specified in the configuration file name  472  to the router  30  in the name  473  (S 542 ).  
         [0079]     In this way, the manager device  40  changes the setting of the router  30  in response to an operator&#39;s instruction.  
         [0000]     Determining Recommendation Level  
         [0080]      FIG. 18  shows the flow of the process for determining the recommendation levels of response policies by the recommendation level determining unit  413 .  FIG. 19  shows tables holding scores used in this process. In  FIG. 19  are index tables A  75  and B  76 . These tables are stored in the storage device  403  or the memory  402  of the manager device  40 . The index table A  75  manages scores in association with the number of servers  10  where an incident has occurred (hereinafter, referred to as “the number of incident-occurred servers”) and the number of segments connected with the incident-occurred server  10  out of the segments  1  to  4  ( 52 ) (hereinafter, referred to as “the number of incident-occurred segments). The index table B  76  manages scores in association with the number of services related to an incident (hereinafter, referred to as “incident-occurred services”) and the number of incident-occurred segments.  
         [0081]     The recommendation level determining unit  413  of the manager device  40  reads out from the incident information database  45  the incident information  61  whose detection date and time  611  falls from the current time to the predetermined time ago (hereinafter referred to as “predetermined period”). Then, the unit extracts IP addresses  613  without duplication from the read incident information  61 , and counts the number of extracted IP addresses as the number of incident-occurred servers (S 511 ). In addition, the recommendation level determining unit  413  identifies the segment  52  to which the IP address  613  belongs, for each of the read incident information  61 , and extracts the identified segments  52  without duplication, and then count the number of extracted segments as the number of incident-occurred segments (S 552 ). Furthermore, the recommendation level determining unit  413  extracts the services  615  from the read incident information  61  without duplication, and counts the number of extracted services  615  as the number of incident-occurred services (S 553 ).  
         [0082]     The recommendation level determining unit  413  references the index table A  75  to obtain the score corresponding to the numbers of incident-occurred servers and incident-occurred segments (hereinafter referred to as “score A”), and references the index table B  76  to obtain the score corresponding to the numbers of incident-occurred services and incident-occurred segments (hereinafter referred to as “score B”) (S 555 ).  
         [0083]     If the score A is more than 2, or the score B is more than 2 (S 556 : YES), the recommendation level determining unit  413  gives the recommendation level of 1 to the response policy saying “Stop all services in all servers” (hereinafter abbreviated to “all servers/all services”), and gives the recommendation level of 4 to the policy saying “Stop only the appropriate service in the appropriate server” (hereinafter abbreviated to “one server/one service”) (S 557 ). That is, the more the numbers of the incident-occurred segments and the incident-occurred servers are, the higher the recommendation level of the response policy therefor is.  
         [0084]     On the other hand, if the score A is 2 or less, and the score B is 2 or less (S 556 : NO), the recommendation level for “one server/one service” is set to 1, while the recommendation level for “all servers/all services” is set to 4 (S 558 ). That is, the more the numbers of the incident-occurred segments and the incident-occurred services are, the higher the recommendation level of the response policy therefor is.  
         [0085]     If the score A is larger than the score B (S 559 : YES), the recommendation level determining unit  413  gives the recommendation level of 2 to the policy saying “Stop only the appropriate service in all servers” (hereinafter abbreviated to “all servers/one service), and gives the recommendation level of 3 to the policy that “Stop all services in the appropriate server” (hereinafter abbreviated to “one server/all services”) (S 560 ). On the other hand, if the score B is larger than the score A (S 559 : NO), the recommendation level determining unit  413  gives the recommendation level of 2 to the policy “one server/all services,” and gives the recommendation level of 3 to the policy “all servers/one service” (S 561 ).  
         [0086]     In this way, the recommendation level determining unit  413  can determine the recommendation levels for the response policies in accordance with the numbers of incident-occurred servers, incident-occurred services and incident-occurred segments.  
         [0087]     Thus, if there are a plurality of segments  52  to which the servers  10  that have incurred an incident are connected, the manager device  40  of this implementation can provide an operator with the suitable response policy by recommending him/her to stop communications with enough number of segments  52  using routers  30 . On the other hand, if there are a smaller number of segments  52  to which the servers  10  that have incurred an incident are connected, the manager device  40  can provide the suitable response policy with an operator by recommending him/her to stop communications only with the segments  52  that are involved in the incident and continue communications with the remaining segments  52 .  
         [0088]     Furthermore, if an incident has occurred in plural services, the manager device  40  can provide an operator with the suitable response policy by recommending him/her to stop communications for enough number of services. On the other hand, if an incident has occurred in a smaller number of services, the device  40  can provide the suitable response policy by recommending him/her to stop communications only for the services that are involved in the incident and continue communications for the remaining services.  
         [0089]     In this way, the manager device  40  of this implementation can determine the recommendation levels in such a manner that an appropriate and effective incident response can be performed, preventing a further incident and at the same time avoiding unnecessary blockages of communications. Then, the device can provide an operator with the response policies in the descending order of the determined recommendation level. As a result, the operator can select an appropriate and effective incident response based on the output from the manager device  40 . Meanwhile, the operator can also flexibly select a response policy for the other incident response in consideration of various conditions as well as the above-mentioned state of the incident occurrence. Briefly stated, the operator can perform an incident response more flexibly.  
         [0090]     In this implementation, an incident response is performed by the router  30 , but the response may be performed by the server  10 . Assuming that a failure of user&#39;s login is detected as an incident, for example, it is possible to set that the server  10  reject the access from that user account or the group to which that user belongs from that time onward. In this case, the manager device  40  issues a command to perform the aforementioned incident response, to the server  10 . Furthermore, the server  10  can be commanded to perform such an incident response as to update an operating system or application program run by the server  10 . In this case, a patch management server to manage patch data for updating the program should be added to the communication system, so that the server  10  can get the patch data from the patch management server and apply it to the operating system or application program.  
         [0091]     Besides the router  30  and the server  10 , a special incident response unit that performs an incident response maybe additionally provided.  
         [0000]     Using Working Terminal  
         [0092]     In this implementation, an operator browses the incident information or selects a response policy by operating the manager device  40  itself. However, it is possible to configure the manager device  40  as web server, and a working terminal as client operated by an operator. In this case, each unit of the manager device  40  is realized as CGI program, for example. Then, the operator can access the manager device  40  through a Web browser on the working terminal.  FIG. 20  shows flows of processes over the entire communication system in this case.  FIG. 20  shows the flows of the process for registering the template information with the above described response policy setting unit  418  (S 810 ), the process for displaying the incident information on the incident monitor screen  72  (S 820 ), and the process for setting the router  30  through an entry of a recovery command (S 830 ).  
         [0093]     In registering the template information, an operator operates the working terminal to access the manager device  40 , and makes a request to send (send request) the setting information registration screen (S 811 ). The manager device  40  sends screen data for displaying the setting information registration screen  71  to the working terminal in response to the send request (S 812 ). When the operator enters the setting information on the setting information registration screen  71 , the setting information is sent from the working terminal to the manager device  40  (S 813 ) and the manager device  40  registers the template information including the received setting information in the template information database  47  in the same way as the above described process of  FIG. 12  (S 814 ).  
         [0094]     In displaying the incident information, an operator operates the working terminal to access the manager device  40  and makes a request to send the incident monitor screen  72  (S 831 ). The manager device  40  sends screen data for displaying the incident monitor screen  72  to the working terminal in response to the above send request (S 832 ). Meanwhile, the incident information is sent from the IDS  20  to the manager device  40  (S 833 ), and the manager device  40  registers the received incident information in the incident information database  45  (S 834 ). The working terminal regularly makes a request to send the incident monitor screen  72  to the manager device  40  (S 835 ), and the manager device  40  sends the screen data for the incident monitor screen to the working terminal for each send request (S 836 ).  
         [0095]     When a list of incident information is displayed in the list box  723  of the incident monitor screen  72 , an operator selects the IDS  20  and sends that information to the manager device (S 837 ). In turn, the manager device  40  sends the working terminal the screen data for displaying the response policy selection screen  73  where the segment policies are listed in the descending order of the recommendation level (S 838 ) The operator selects a segment policy this time, and the working terminal sends that information to the manager device  40  (S 839 ). The manager device  40  determines the recommendation level for each response policy, and sends the working terminal the screen data for displaying the response policy selection screen  74  that lists the response policies in the descending order of recommendation level (S 840 ). Then, the operator selects a response policy, and the working terminal sends that information to the manager device  40  (S 841 ). Finally, the manager device  40  sends the router  30  the configuration file  62  corresponding to the selected response policy (S 842 ) to change setting of the router  30 .  
         [0096]     In resetting the router  30  through the input of a recovery command, the working terminal sends a recovery command to the manager device  40  in accordance with the operator&#39;s operation (S 861 ), and then the manager device  40  reads out from the template information database  47  the template information where “normal time” is set in the response policy  471 , and sends the configuration file  62  specified in the configuration file name  472  to the router  30  in the name  473  (S 862 )  
         [0097]     In this way, the operator can access the manager device  40  and control the router  30  to perform an incident response by operating the working terminal.  
         [0098]     Having described the implementation of the present invention, our aim is to facilitate the understanding of the present invention, and the invention should not be construed limited by any of the details of this description. The present invention can be changed and modified without departing from the scope of the claims, and includes equivalents thereof.

Technology Category: 3