JP2009146095A - Information processor, system, program, and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem that real property or reliability in operation verification is insufficient, and that it is not possible to flexibly facilitate countermeasures to the configuration change of this system. <P>SOLUTION: This first information processor 100 is provided with: a first manipulation processing part 110 which transmits a first operation instruction based on first operation designation input by a first manipulation, and generates first manipulation information based on the first operation designation, and acquires first operation information, and makes the first manipulation information cooperate with the first operation information; and a first operation processing part which acquires the first operation instruction from a first manipulation processing part, and generates the first operation information based on the first operation instruction, and transmits the first operation information to a first manipulation processing part. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an information processing apparatus, system, program, and method, and more particularly, to an information processing apparatus, system, program, and method for processing history information.

  Related techniques are described in Patent Documents 1, 2, 3 and 4.

  Patent Document 1 describes a technique in which a trail management server centrally collects trails of each machine and performs an audit based on time-series information.

  In Patent Literature 2, when a user instructs session information, an integrated log display server collects related log information from logs stored for each server in association with session information, and presents them in a time-series integrated manner. The technology is described.

  Patent Document 3 describes a technology in which a communication history processing device performs a matching check between a center side communication history and a user side communication history and presents whether or not it is compatible.

  Patent Document 4 notifies a relay device of an identifier of a session between two computers belonging to different networks, the relay device adds a session identifier to a log, and the management computer selects all the relay devices based on the session identifier. Describes the technology to collect logs from

JP 2007-026207 A JP 2004-227360 A JP-A-2005-321200 Japanese Patent Laid-Open No. 10-198616

  The techniques of Patent Documents 1, 2, 3, or 4 collect all the related history information that is specified in advance by the trail management server, the integrated log display server, the communication history processing device, or the management computer. They were processed and presented as needed.

  Therefore, when using the techniques of Patent Documents 1, 2, 3, or 4, since all information, that is, including unnecessary information is collected, compared with collecting only the intended information, There is a problem that the load of equipment related to information collection is large. As a result, when these technologies are used, especially in a large-scale system, it takes time to collect all information, and verification using old information instead of the latest information may be performed. There is a problem that reliability and reliability are lowered.

  In addition, when the techniques of Patent Documents 1, 2, 3, or 4 are used, the trail management server, the integrated log display server, the communication history processing device, or the management computer recognizes the configuration of the system to be audited. I need some information to do. For this reason, there exists a problem that it cannot respond flexibly to a system configuration change.

  The objective of this invention is providing the information processing apparatus, system, program, and method which solve the said subject.

  The first information processing apparatus of the present invention sends a first operation instruction based on the first operation designation input in the first operation, and the first operation information based on the first operation designation. A first operation processing unit that obtains the first operation information and links the first operation information and the first operation information, and the first operation processing unit from the first operation processing unit. A first operation processing unit that acquires an operation instruction, generates the first operation information based on the first operation instruction, and sends the first operation information to the first operation processing unit; Have

  In the first system of the present invention, a first information processing apparatus and a second information processing apparatus are connected via a network, and the first information processing apparatus is connected to the first information processing apparatus that is input by a first operation. A first operation instruction is sent to the second information processing apparatus based on the operation designation, first operation information is generated based on the first operation designation, and the first information processing apparatus generates the first operation information from the second information processing apparatus. At least a first operation processing unit that associates the first operation information with the first operation information, and the second information processing apparatus includes the first information processing unit. The first operation instruction is acquired from the apparatus, the first operation information is generated based on the first operation instruction, and the first operation information is transmitted to the first information processing apparatus. At least one operation processing unit.

  The first program of the present invention includes a process of sending a first operation instruction based on a first operation designation input in a first operation, and first operation information based on the first operation designation. Generating the first operation information, processing for linking the first operation information and the first operation information, and the first operation processing unit to the first operation A process for obtaining an instruction, a process for generating the first movement information based on the first movement instruction, and a process for sending the first movement information to the first operation processing unit. To run.

According to the first method of the present invention, the computer sends out a first operation instruction based on the first operation designation input in the first operation, and the first operation is performed based on the first operation designation. Generate information,
First operation information is acquired, the first operation information and the first operation information are linked, the first operation instruction is acquired from the first operation processing unit, and the first operation is acquired. The first operation information is generated based on the instruction, and the first operation information is sent to the first operation processing unit.

  The effect of the present invention is that it is possible to collect history information with a small load on related devices and a high real-time property without requiring awareness of the system configuration.

  First, general items related to the present invention will be described.

  Each component described in the following embodiments may be realized by hardware, may be realized by software, or may be realized by mixing hardware and software.

  Further, the physical configuration of each component is not limited to the description of the following embodiment, and may exist independently, may exist in combination, or may be separated. May be configured.

  In addition, each operation of each component is not limited to the description of the following embodiment, and is within a range that does not hinder the functional, performance, and other characteristics in carrying out the present invention. You can change it.

  In the following embodiments, an operation is not limited to an operation by an operator, but refers to all operations for instructing an operation to a computer, such as an operation by a program and an operation performed via a network.

  Next, a first embodiment of the present invention will be described in detail with reference to the drawings.

  Referring to FIG. 1, the first embodiment of the present invention includes an information processing apparatus 100.

  The information processing apparatus 100 includes an operation processing unit 110 and an operation processing unit 130.

  FIG. 2 is a diagram illustrating an example of the structure of the operation information 120 according to the first embodiment of this invention. The operation information 120 in the first embodiment of the present invention is stored in a storage unit (not shown) in the operation processing unit 110. The operation information 120 includes operation time information 121, an instruction destination identifier 122, an operation identifier 123, and operation content information 124.

  FIG. 3 is a diagram illustrating an example of the structure of the operation information 140 according to the first embodiment of this invention. The operation information 140 according to the first embodiment of the present invention is stored in a storage unit (not shown) in the operation processing unit 130. The operation information 140 includes operation time information 141, an instruction source identifier 142, an operation identifier 143, and operation content information 144.

  Next, the operation of the first exemplary embodiment of the present invention will be described. FIG. 4 is a flowchart showing an operation flow in the information processing apparatus 100 according to the first embodiment of this invention.

  For example, the information processing apparatus 100 starts the processing when an operation for causing the information processing apparatus 100 to execute the operation MV is performed by the operator (step S601). The “operation MV” is, for example, “an operation MV that is instructed to be executed by a command xxxx”. The “operation MV” is an “operation executed in response to an operation” in the present invention. “Operation MV” is distinguished from, for example, a general operation in “operation of the embodiment of the present invention” (and so on). The “operation” is, for example, “input of operation designation (for example, command xxxx and, for example, name of the operation processing unit 130)”.

  The operation processing unit 110 generates an operation instruction based on the operation designation input by the operation, and sends the operation instruction to the operation processing unit 130 based on the operation specification input by the operation (step S602). This operation instruction is generated as follows, for example. For example, the operation processing unit 110 acquires time from operating system means or clock circuit means (not shown) in the information processing apparatus 100 and generates operation time information 121. Then, the operation processing unit 110 generates an operation identifier 123 by adding, for example, a 2-digit serial number to the operation time information 121. The operation identifier 123 may use a value uniquely determined using a random number, a hash generated based on the operation, or the like.

  Then, the operation processing unit 110 generates an operation instruction in which the operation identifier 123 is added to the operation designation. Here, the operation designation format included in the operation instruction does not have to be the input format.

  Further, the transmission of the operation instruction to the operation processing unit 130 is executed as follows, for example. The operation processing unit 110, for example, designates the name of the operation processing unit 130 as necessary to the operating system unit or the communication control unit, and requests the operation processing unit 130 to send an operation instruction. Upon receiving this request, the operating system unit or the communication control unit described above generates an operation instruction, for example, an instruction destination identifier 122 from the name of the operation processing unit 130 as necessary, and operates based on the instruction destination identifier 122. The data is sent to the processing unit 130. Note that a configuration in which the operation processing unit 110 directly sends an operation instruction to the operation processing unit 130 is also possible.

  Next, the operation processing unit 110 generates operation information 120 (step S603). The operation information 120 is generated as follows, for example. The operation processing unit 110 acquires the instruction destination identifier 122 from the operating system unit or the communication control unit that has requested the transmission of the operation instruction. Then, the operation processing unit 110 generates operation content information 124 based on the operation. Then, the operation processing unit 110 generates the operation information 120 by combining the instruction destination identifier 122, the operation content information 124, the operation time information 121 generated in step S602, and the operation identifier 123. The operation information may include the user ID that performed the operation, other reference information, and the like.

  Next, the operation processing unit 130 acquires an operation instruction (step S604).

  Next, the operation processing unit 130 executes the operation MV based on the operation instruction (step S605). Note that the subject that executes the operation MV is not limited to the operation processing unit 130, and may be other means (not shown).

  Next, the operation processing unit 130 generates operation information 140 (step S606). The operation information 140 is generated as follows, for example. For example, the operation processing unit 130 acquires time from the operating system means or the clock circuit means described above, and generates the operation time information 141. Then, the operation processing unit 130 acquires the instruction source identifier 142 of the operation processing unit 110 from, for example, the operating system unit or the communication control unit described above. The instruction source identifier 142 is, for example, information that identifies the operation processing unit 110 that has sent the operation instruction and is held by the operating system unit or the communication control unit. That is, the instruction source identifier 142 is, for example, a host name, task ID, network address, application name, session number, or a combination thereof. Then, the operation processing unit 130 extracts the operation identifier 123 from the operation instruction and sets it as the operation identifier 143. Then, the operation processing unit 130 generates the operation content information 144 based on the operation instruction. Then, the motion processing unit 130 combines the motion time information 141, the instruction source identifier 142, the motion identifier 143, and the motion content information 144 to generate the motion information 140. The operation information may include an operation result and other reference information.

  Next, the motion processing unit 130 sends the motion information 140 to the operation processing unit 110 (step S607). The transmission of the operation information 140 to the operation processing unit 110 is executed as follows, for example. For example, the operation processing unit 130 requests the operating system unit or the communication control unit described above to transmit the operation information 140 by specifying the instruction source identifier 142. When the operating system means or the communication control means described above receives this request, it sends the operation information 140 to the operation processing unit 110 based on the instruction source identifier 142.

  Next, the operation processing unit 110 acquires the operation information 140 (step S608). Then, the operation processing unit 110 links the operation information 120 and the operation information 140 (step S609). For example, the operation information 120 and the operation information 140 are linked as follows. When the operation processing unit 110 receives a display request for either the operation information 120 or the operation information 140 from, for example, a display unit (not shown), the operation information 120 and the operation information 140 having the same values of the operation identifier 123 and the operation identifier 143 are displayed. Are also output to the display means, for example. The cooperation may be performed, for example, by receiving a request from an input unit (not shown), a printing unit (not shown), a storage unit (not shown), or a communication unit (not shown), and outputting the request to any of these units.

  According to the first embodiment of the present invention, the operation processing unit generates operation information, the operation processing unit generates operation information, and the corresponding operation information and operation information are linked.

  Thus, the first embodiment of the present invention has high real-time performance and reliability, and can collect history information of operations and operation MVs without having to be aware of the system configuration.

  Next, a second embodiment of the present invention will be described in detail with reference to the drawings.

  The configuration of the second embodiment of the present invention is the same as that of the first embodiment of the present invention, as shown in FIG.

  FIG. 5 is a diagram illustrating an example of the structure of the operation information 120 according to the second embodiment of the present invention. The operation information 120 according to the second embodiment of the present invention is stored in a storage unit (not shown) in the operation processing unit 110. The operation information 120 includes operation time information 121, an instruction destination identifier 122, an operation identifier 123, operation content information 124, and an operation verification result 125.

  FIG. 6 is a diagram illustrating an example of the structure of the operation information 140 according to the second embodiment of the present invention. The operation information 140 in the second embodiment of the present invention is stored in a storage unit (not shown) in the operation processing unit 130. The operation information 140 includes operation time information 141, an instruction source identifier 142, an operation identifier 143, operation content information 144, and an operation verification result 145.

  Next, the operation of the second exemplary embodiment of the present invention will be described. 7 and 8 are flowcharts showing the overall operation flow in the information processing apparatus 100 according to the second embodiment of this invention. In the description of the operation of the second embodiment of the present invention, the same description as the operation of the first embodiment of the present invention is omitted to the extent that it is not unclear.

  The information processing apparatus 100 starts processing when, for example, an operation (for example, input of the command xxxx) for causing the information processing apparatus 100 to execute the operation MV (for example, command xxx) is performed by the operator. (Step S621).

  The operation processing unit 110 sends the operation instruction generated based on the operation to the operation processing unit 130 based on the operation (step S622).

  Next, the operation processing unit 130 acquires an operation instruction (step S623).

  The operation processing unit 110 generates operation information 120 (step S624). Then, the operation processing unit 110 sends the operation information 120 to the operation processing unit 130 (step S625). The transmission of the operation information 120 to the operation processing unit 130 is executed as follows, for example. For example, the operation processing unit 110 requests the operating system unit or the communication control unit described above to transmit the operation information 120 by designating the transmission destination by the instruction destination identifier 122. When the operating system means or the communication control means described above receives this request, it sends the operation information 120 to the operation processing unit 130 based on the instruction destination identifier 122.

  Next, the operation processing unit 130 acquires the operation information 120 (step S626). Then, the motion processing unit 130 generates motion information 140 (step S627).

  Next, the operation processing unit 130 verifies the consistency between the operation information 120 and the operation information 140 (step S628). The verification of consistency is performed according to a predetermined rule as follows, for example. The operation processing unit 130 calculates the difference between the operation time information 121 and the operation time information 141. Then, the motion processing unit 130 determines that the difference is normal when the difference is within a predetermined threshold, and determines that the difference is abnormal when the difference exceeds a predetermined threshold.

  Further, the operation processing unit 130 refers to operation source information (not shown) indicating the correspondence between the predetermined operation content information 124 and the instruction source identifier 142, and determines whether the instruction source identifier 142 and the operation content information 124 correspond to each other. It is verified whether it exists in the operation source information. Then, the operation processing unit 130 determines that the correspondence is normal when it exists in the operation source information, and determines that it is abnormal when the correspondence does not exist in the operation source information.

  Further, the operation processing unit 110 refers to instruction destination information (not shown) indicating the correspondence between the predetermined operation content information 144 and the instruction destination identifier 122, so that the correspondence between the instruction destination identifier 122 and the operation content information 144 is established. It is verified whether it exists in the pointee information. The operation processing unit 110 determines that the correspondence is normal when the instruction destination information is present, and determines that the correspondence is abnormal when the correspondence is not present in the support destination information.

  Then, when the verification result is normal (step S629 / YES), the operation processing unit 130 sets the operation verification result 145 to “normal” (step S631). Then, the operation processing unit 130 executes the operation MV based on the operation instruction (step S632).

  If the verification result is abnormal (step S629 / NO), the operation processing unit 130 sets the operation verification result 145 to “abnormal” (step S633).

  Next, the motion processing unit 130 sends the motion information 140 to the operation processing unit 110 (step S634).

  Next, the operation processing unit 110 acquires the operation information 140 (step S635).

  Next, the operation processing unit 110 verifies the consistency between the operation information 120 and the operation information 140 (step S636). The verification of consistency can be understood by referring to the description of verification of consistency in the operation processing unit 130 in step S628, and thus description thereof is omitted.

  If the verification result is normal (step S637 / YES), the operation processing unit 110 sets the operation verification result 125 to “normal” (step S638). If the verification result is abnormal (step S637 / NO), the operation processing unit 110 sets the operation verification result 125 to “abnormal” (step S639).

  Next, the operation processing unit 110 links the operation information 120 and the operation information 140 (step S641).

  According to the second embodiment of the present invention, the operation processing unit verifies the consistency between the operation information and the operation information. Thus, the second embodiment of the present invention makes it easy to check the consistency between operation information and operation information.

  Also, according to the second embodiment of the present invention, the motion processing unit verifies the consistency between the operation information and the motion information. Thus, the second embodiment of the present invention makes it possible to easily check the consistency between the operation information and the operation information and at the same time prevent the execution of the operation MV having an abnormal consistency.

  Next, a third embodiment of the present invention will be described in detail with reference to the drawings.

  Referring to FIG. 9, the third embodiment of the present invention includes a network 200, an information processing device 300, an information processing device 400, and an information processing device 500.

  The information processing apparatus 300 includes an operation processing unit 310 and a storage unit 350. The information processing apparatus 400 includes an operation processing unit 410, an operation processing unit 430, and a storage unit 450. The information processing apparatus 500 includes an operation processing unit 530 and a storage unit 550.

  In the third embodiment of the present invention, for example, a process in which “an operation to be instructed for operation is included in the operation MV instructed by the operation instruction” (hereinafter referred to as multistage processing). It is embodiment corresponding to.

  FIG. 10 is a diagram illustrating an example of the structure of the integrated control information 160 according to the third exemplary embodiment of the present invention. The integrated control information 160 according to the third embodiment of the present invention is stored in a storage unit (not shown) in the operation processing unit 110. The integrated control information 160 includes an integrated counter 161 and an omission flag 162, which are standards for controlling the generation mode of the integrated operation information 180.

  The integrated counter 161 is information instructing to generate the (N-1) th integrated operation information 180 that does not include both the subsequent operation information 140 and the subsequent operation information 180 in multistage processing.

  The latter stage operation information 140 is the Nth operation information 140 that is the operation information 140 of the “N + 1th information processing apparatus” in the Nth (N = 2 or more natural number) information processing apparatus.

  Similarly, the integrated operation information 180 at the latter stage is the Nth integrated operation information that is the integrated operation information 180 of the “N + 1 information processing device” in the Nth (N = 2 or more natural number) information processing device. 180.

  Here, for example, in the case where N is “2”, the relationship between the description contents of FIGS. 9 and 11 will be described. The information processing device 300 corresponds to the first (N-1) information processing device, and the operation processing unit 310 corresponds to the first (N-1) operation processing unit. The operation information 120 generated by the operation processing unit 310 corresponds to the first (N-1) operation information 120, and the operation instruction generated by the operation processing unit 310 corresponds to the first (N-1) operation instruction. . The information processing device 400 is a second (N) information processing device, the operation processing unit 410 is a second (N) operation processing unit, and the operation processing unit 430 is a second (N) operation processing unit. Correspond. The operation information 120 generated by the operation processing unit 410 corresponds to the second (N) operation information 120, and the operation instruction generated by the operation processing unit 410 corresponds to the second (N) operation instruction. The operation information 140 generated by the operation processing unit 430 corresponds to the first (N-1) operation information 140, and the operation instruction acquired by the operation processing unit 430 corresponds to the first (N-1) operation instruction. . The information processing apparatus 500 corresponds to a third (N + 1) information processing apparatus, and the operation processing unit 530 corresponds to a third (N + 1) operation processing unit. The operation information 140 generated by the operation processing unit 530 corresponds to the second (N) operation information 140, and the operation instruction acquired by the operation processing unit 530 corresponds to the second (N) operation instruction.

  For example, the integrated counter 161 is instructed in advance as a value of “N” in the information processing apparatus that is first operated. In this case, the integrated operation information 180 before the (N-1) th is obtained from the (N-1) th operation information 140 that is the operation information 140 of the “Nth information processing apparatus”. The operation information 140 of the “processing unit” is integrated. That is, in this case, the (N−1) th integrated operation information 180 does not include any of the Nth operation information 140 and the Nth integrated operation information 180 that are the operation information 140 of the “N + 1th information processing apparatus” ( (See (1) in FIG. 11 and (2) in FIG. 11)).

  The omission flag 162 is information for instructing to have only the subsequent operation information 140 or the integrated operation information 180 as the integrated operation information 180 in the multistage processing. The omission flag 162 is instructed in advance as a value of, for example, “1” in the information processing apparatus in which the operation has been performed first. In this case, the (N−1) th integrated operation information 180 uses only the Nth operation information 140 or the Nth integrated operation information 180 that is information related to the operation MV of the “N + 1th information processing apparatus”. In other words, in this case, the (N-1) th integrated operation information 180 is any one of the (N-1) th operation information 140 and the Nth operation information 120 that are information related to the operation MV and the operation of the “Nth information processing apparatus”. (See (1) in FIG. 11 and (3) in FIG. 11).

  Next, the operation of the third exemplary embodiment of the present invention will be described. FIG. 12 and FIG. 13 are flowcharts showing the overall operation flow in the third embodiment of the present invention. In the description of the operation of the third embodiment of the present invention, the same description as the operation of the first and second embodiments of the present invention is omitted to the extent that it is not obscured.

  The storage unit 350, the storage unit 450, and the storage unit 550 store data that the information processing device 300, the information processing device 400, and the information processing device 500 write or read as necessary. That is, the storage unit 350, the storage unit 450, and the storage unit 550 may store the operation information 120, the operation information 140, the integrated control information 160, or the integrated operation information 180, for example. In addition, the storage unit 350, the storage unit 450, and the storage unit 550 may store, for example, operation instructions, details of operations performed by the operator, operation source information, and the like (not illustrated). The storage unit 350, the storage unit 450, and the storage unit 550 are not illustrated, for example, a program that controls the operation of the information processing apparatus 300, the information processing apparatus 400, and the information processing apparatus 500, work data for operating a program, and the like. May be stored.

  For example, the information processing device 300 starts processing when an operation (for example, input of the command xxxx) for causing the information processing device 100 to execute the operation MV (for example, the command xxxx) is performed by the operator. To do. It is assumed that the operation includes instruction information necessary for the information processing apparatus 300 to generate the integrated control information 160 (step S651). This instruction information is, for example, “2” used as the N value of the integrated counter 161 and “1” used as the value of the omission flag 162.

  In the information processing apparatus 300, the operation processing unit 310 sends an operation instruction generated by adding the integrated control information 160 based on the operation to the information processing apparatus 400 based on the operation (step S652).

  Next, in the information processing apparatus 400, the operation processing unit 430 acquires an operation instruction (step S653).

  Next, in the information processing apparatus 300, the operation processing unit 310 generates operation information 120. Then, the operation processing unit 310 stores the operation information 120 in the storage unit 350 (step S654). Then, the operation processing unit 310 sends the operation information 120 to the information processing apparatus 400 (step S655).

  Next, in the information processing apparatus 400, the operation processing unit 430 acquires the operation information 120 and stores it in the storage unit 450 (step S656). Then, the operation processing unit 430 generates the operation information 140 (Step S657).

  Next, the operation processing unit 430 verifies the operation consistency between the operation information 120 and the operation information 140 (step S658). The verification of the operation consistency can be understood by referring to the description of the verification of the consistency in the operation processing unit 130 in step S628 described in the second embodiment of the present invention, and thus the description is omitted.

  Next, when the verification result is abnormal (step S659 / NO), the operation processing unit 430 sets the operation verification result 145 to “abnormal” (step S661). Then, the operation processing unit 430 sends the operation information 140 to the information processing apparatus 300 (step S662).

  If the verification result is normal (step S659 / YES), the operation processing unit 430 sets the operation verification result 145 to “normal” (step S663). Then, the operation processing unit 430 executes the operation MV based on the operation instruction (step S664).

  Subsequently, the operation processing unit 430 subtracts “1” if the integration counter 161 of the integration control information 160 is not “0”. The operation processing unit 430 does not perform subtraction when the integration counter 161 of the integration control information 160 is “0” (step S665).

  Next, the operation processing unit 430 generates the integrated operation information 180 based on the integrated control information 160 (step S666). The operation processing unit 430 generates the integrated operation information 180 as follows, for example.

  The first example is the case shown in (1) of FIG. 11 where the integrated counter 161 ≠ 0 and the omission flag 162 = 0. In this case, the operation processing unit 430 integrates the operation information 140 of the information processing device 400, the operation information 120 of the information processing device 400, and the operation information 140 of the information processing device 500. Note that the operation information 140 of the information processing apparatus 400 is the (N-1) th operation information 140 of the Nth information processing apparatus, if a generalized expression is used. Similarly, the operation information 120 of the information processing apparatus 400 is the Nth operation information 120 of the Nth information processing apparatus. Similarly, the operation information 140 of the information processing apparatus 500 is the Nth operation information 140 of the (N + 1) th information processing apparatus. Note that the operation information 140 of the information processing apparatus 500 is acquired in step S664 as described later.

  The second example is the case shown in (2) of FIG. 11 where the integrated counter 161 = 0 and the omission flag 162 = 0. In this case, the operation processing unit 430 integrates the operation information 140 of the information processing device 400 and the operation information 120 of the information processing device 400. That is, the operation processing unit 430 does not integrate the operation information 140 of the information processing apparatus 500 with the integrated operation information 180 because the integration counter 161 is “0”.

  A third example is the case shown in (3) of FIG. 11 where the integrated counter 161 ≠ 0 and the omission flag 162 = 0. In this case, the operation processing unit 430 sets the operation information 140 of the information processing apparatus 500 as the integrated operation information 180. That is, since the omission flag 162 is “0”, the operation processing unit 430 does not integrate the operation information 140 of the information processing device 400 and the operation information 120 of the information processing device 400 into the integrated operation information 180.

  A fourth example is the case shown in (4) of FIG. 11 where the integrated counter 161 = 0 and the omission flag 162 = 1. In this case, the operation processing unit 430 does not generate the integrated operation information 180.

  Then, the operation processing unit 430 receives the operation information 140 (when the integrated operation information 180 is not generated at step S666) or the integrated operation information 180 (when the integrated operation information 180 is generated at step S666) as the information processing apparatus 300. (Step S667).

  Next, in the information processing apparatus 300, the operation processing unit 310 acquires the operation information 140 or the integrated operation information 180 (step S671).

  Next, the operation processing unit 310 verifies the operation consistency between the operation information 120 and the operation information 140 or the integrated operation information 180 (step S672). The verification of the operation consistency can be understood by referring to the description of the verification of the consistency in the operation processing unit 130 in step S628 described in the second embodiment of the present invention.

  If the verification result is abnormal (step S673 / NO), the operation processing unit 310 sets the operation verification result 125 to “abnormal” (step S674).

  Further, when the verification result is normal (step S673 / YES), the operation processing unit 310 sets the operation verification result 125 to “normal” (step S675).

  Next, the operation processing unit 110 links the operation information 120 with the operation information 140 or the integrated operation information 180 (step S676).

  FIG. 14 and FIG. 15 are flowcharts showing an operation flow when an operation (an example of the Nth operation) to be instructed is included in step S664 (an example of the (N-1) th operation MV). is there.

  In the information processing apparatus 400, for example, the operation processing unit 430 starts processing upon detection of an operation for causing the information processing apparatus 500 to execute the operation MV while executing the operation MV (step S681).

  In the information processing apparatus 400, the operation processing unit 410 generates an operation instruction generated by adding the integrated control information 160 based on the operation detected by the operation processing unit 430, based on the operation detected by the operation processing unit 430. The data is sent to 500 (step S682).

  Subsequent operations from step S683 to step S700 are the same as the operations from step S623 to step S641 in FIGS. 7 and 8 described in the operation of the second embodiment of the present invention, and thus description thereof is omitted. .

  Although the third embodiment of the present invention has been described above with the configuration of three information processing devices, by adding another information processing device that performs the same operation as the information processing device 400, It is possible to arbitrarily increase the number of stages of multistage connection.

  Further, in order to facilitate understanding, the information processing apparatus 400 has been described by dividing the operation of the operation processing unit 410 and the operation processing unit 430. However, the operation processing unit 430 includes the operation processing unit in the operation MV execution operation. The operation of 410 may be implemented.

  According to the third embodiment of the present invention, the information processing apparatus detects an operation in the operation MV, and integrates operation information and operation information corresponding to this operation. Thus, the third embodiment of the present invention is the same as the first embodiment and the second embodiment in information processing apparatuses connected in multiple stages (the same applies to operation processing sections connected in multiple stages). It became possible to obtain the effect of.

  Further, according to the third embodiment of the present invention, the operation processing unit selects information to be integrated based on the integrated control information. Thus, the third embodiment of the present invention made it possible to collect only necessary information.

  Next, a fourth embodiment of the present invention will be described in detail with reference to the drawings.

  Referring to FIG. 16, the fourth embodiment of the present invention includes an information processing apparatus 700 (for example, a computer). The information processing apparatus 700 includes a control unit 701 and a storage unit 702. The storage unit 702 stores a program 703 that causes the information processing apparatus 700 to perform processing.

  The program 703 realizes the functions described with reference to FIGS. 1 to 15 in the first, second, and third embodiments of the present invention.

  The program 703 is stored in the storage unit 702, read and executed by the control unit 701, and controls the operation of the information processing apparatus 700. The information processing apparatus 700 executes processing equivalent to the processing of the information processing apparatuses 100, 300, 400, and 500 in the first, second, and third embodiments under the control of the program 703.

  According to the fourth embodiment of the present invention, since the processing is executed by cooperation of hardware and software, there is an effect that the implementation is easy.

  In addition, with respect to the embodiment of the present invention described above, an operator designates a verification target from an operation date, operation content, user name, etc. by using an input / output device or by a program or script. Anyway.

  In addition, the operator may verify the linked operation information and operation information using an input / output device.

  Further, the operator may input the integrated control information using an input / output device or by a program, a script, or the like. In addition, the operator may instruct the contents and method of verification of consistency using an input / output device or by a program or script.

  Further, the configurations of the first embodiment, the second embodiment, and the third embodiment of the present invention may be mixed.

  The present invention can be applied to applications such as history information verification in a system connected to a network, for example, a client-server type configuration. The present invention can also be applied to applications such as history information verification in a multi-tier system such as a web three-tier system (Web / application server / database server).

It is a block diagram which shows the structure of the 1st and 2nd embodiment of this invention. It is a figure which shows the structure of the operation information in the 1st Embodiment of this invention. It is a figure which shows the structure of the operation information in the 1st Embodiment of this invention. It is a flowchart which shows operation | movement of the information processing apparatus in the 1st Embodiment of this invention. It is a figure which shows the structure of the operation information in the 2nd Embodiment of this invention. It is a figure which shows the structure of the operation information in the 2nd Embodiment of this invention. It is a flowchart which shows operation | movement of the information processing apparatus in the 2nd Embodiment of this invention. It is a flowchart which shows operation | movement of the information processing apparatus in the 2nd Embodiment of this invention. It is a block diagram which shows the structure of the 3rd Embodiment of this invention. It is a figure which shows the structure of the integrated control information in the 3rd Embodiment of this invention. It is a figure which shows the example of integrated operation | movement information generation in the 3rd Embodiment of this invention. It is a flowchart which shows operation | movement of the information processing apparatus in the 3rd Embodiment of this invention. It is a flowchart which shows operation | movement of the information processing apparatus in the 3rd Embodiment of this invention. It is a flowchart which shows operation | movement of the information processing apparatus in the 3rd Embodiment of this invention. It is a flowchart which shows operation | movement of the information processing apparatus in the 3rd Embodiment of this invention. It is a block diagram which shows the structure of the 4th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Information processing apparatus 110 Operation processing part 120 Operation information 121 Operation time information 122 Instruction destination identifier 123 Operation identifier 124 Operation content information 125 Operation verification result 130 Operation processing part 140 Operation information 141 Operation time information 142 Instruction origin identifier 143 Operation identifier 144 Operation Content information 145 Operation verification result 160 Integrated control information 161 Integrated counter 162 Omission flag 180 Integrated operation information 200 Network 300 Information processing device 310 Operation processing unit 350 Storage unit 400 Information processing device 410 Operation processing unit 430 Operation processing unit 450 Storage unit 500 Information Processing device 530 Operation processing unit 550 Storage unit 700 Information processing device 701 Control unit 702 Storage unit 703 Program

Claims (40)

A first operation instruction is sent out based on the first operation designation input in the first operation,
Generating first operation information based on the first action designation;
Get first action information,
A first operation processing unit that links the first operation information and the first operation information;
Obtaining the first operation instruction from the first operation processing unit, generating the first operation information based on the first operation instruction;
A first motion processing unit for sending the first motion information to the first operation processing unit;
An information processing apparatus. 2. The information processing apparatus according to claim 1, wherein the first operation processing unit verifies a first consistency between the first operation information and the first operation information according to a predetermined first rule. . The difference between the first operation input time included in the first operation information and the operation execution time included in the first operation information is determined in advance for the first consistency. The information processing apparatus according to claim 2, wherein verification is performed based on whether or not the value is within a threshold range. The first consistency is defined by information indicating an instruction destination of the first action instruction based on the first action designation included in the first operation information, and the first action information included in the first action information. The information processing apparatus according to claim 2, wherein the information on the content of the operation based on the operation instruction of 1 is verified based on whether or not the information is predetermined as normal correspondence. The first operation processing unit sends out the first operation information,
The first operation processing unit acquires the first operation information, and determines a second consistency between the first operation information and the first operation information according to a predetermined second rule. The information processing apparatus according to claim 1, wherein the information processing apparatus is verified. For the second consistency, a difference between the input time of the first operation included in the first operation information and the execution time of the operation included in the first operation information is determined in advance. The information processing apparatus according to claim 5, wherein verification is performed based on whether the value is within a threshold range. The second consistency is determined based on the first operation content based on the first operation designation included in the first operation information and the first operation included in the first operation information. The information processing apparatus according to claim 5, wherein the information indicating the instruction source of the first operation instruction that has transmitted the instruction is verified based on whether or not the information is predetermined as normal correspondence. The Nth (N is a natural number equal to or greater than 2) operation processing unit, when the content of the Nth operation is included in the N−1th operation,
Based on the Nth operation designation input in the Nth operation, an Nth operation instruction is sent to the (N + 1) th operation processing unit,
Generating Nth operation information based on the Nth motion designation;
Nth operation information or Nth integrated operation information is acquired from the (N + 1) th operation processing unit,
Linking the Nth operation information with the Nth operation information or the Nth integrated operation information;
The Nth operation processing unit obtains an N-1th operation instruction from the N-1th operation processing unit,
Generating N-1th operation information based on the N-1th operation instruction;
Generating the (N-1) th operation information, the Nth operation information, and the Nth operation information or the Nth integrated operation information, and generating the (N-1) th integrated operation information.
The information processing apparatus according to claim 1, wherein the N−1th operation information or the N−1th integrated operation information is transmitted to the N−1th operation processing unit. The Nth operation processing unit is configured to perform Nth operation consistency between the Nth operation information and the Nth operation information or the Nth integrated operation information in accordance with a predetermined Nth operation rule. Verify
The Nth operation processing unit integrates the N-1th operation information, the Nth operation information including the verification result, and the Nth operation information or the Nth integrated operation information. The information processing apparatus according to claim 8, wherein the N-1th integrated operation information is generated. The N-1th operation processing unit sends the N-1th operation information to the Nth operation processing unit,
The Nth motion processing unit acquires the N-1th operation information,
10. The information processing apparatus according to claim 8, wherein the N-th operation consistency between the N-1th operation information and the N-1th operation information is verified according to a predetermined Nth operation rule. The N-th operation processing unit, when the content of the N-th operation is included in the N-th operation, according to a predetermined criterion, the N-th operation information and the N-th operation The information processing apparatus according to any one of claims 8 to 10, wherein the N-1th integrated operation information not including the integrated operation information is generated. The Nth operation processing unit includes the Nth operation information and the Nth operation according to a predetermined criterion when the content of the Nth operation is included in the N−1th operation. The information processing apparatus according to claim 8, wherein the N−1th integrated operation information not including the −1 operation information is generated. The first operation information includes an operation identifier;
The first operation information includes an operation identifier;
The first operation processing unit, when the operation identifier of the first operation information and the operation identifier of the operation information of the first operation information have the same value, The information processing apparatus according to claim 1, wherein the information processing apparatus cooperates by outputting the first operation information together. The N-1th operation information includes an operation identifier,
The N-1th operation information includes an operation identifier,
The N-1th operation processing unit includes:
When the operation identifier of the N-1th operation information and the operation identifier of the N-1th operation information have the same value, the N-1th operation information and the N-1th operation It cooperates by outputting together with information,
When the operation identifier of the N-1th operation information and the operation identifier of the N-1st integrated operation information have the same value, the N-1th operation information and the N-1th operation information 14. The information processing apparatus according to claim 8, wherein the information processing apparatus cooperates by outputting the integrated operation information together. A first information processing apparatus and a second information processing apparatus are connected via a network;
The first information processing apparatus sends a first operation instruction to the second information processing apparatus based on the first operation designation input in the first operation,
Generating first operation information based on the first action designation;
Having at least a first operation processing unit that obtains first operation information from the second information processing apparatus and links the first operation information and the first operation information;
The second information processing apparatus acquires the first operation instruction from the first information processing apparatus, generates the first operation information based on the first operation instruction,
A system having at least the first operation processing unit for sending the first operation information to the first information processing apparatus. At least three or more information processing devices are connected to each other via a network,
The Nth operation processing unit of the Nth information processing apparatus, when the content of the Nth operation is included in the (N-1) th operation,
Based on the Nth operation designation input in the Nth operation, an Nth operation instruction is sent to the (N + 1) th operation processing unit,
Generating Nth operation information based on the Nth operation command;
Nth operation information or Nth integrated operation information is acquired from the (N + 1) th information processing apparatus,
Linking the Nth operation information with the Nth operation information or the Nth integrated operation information;
The Nth operation processing unit of the Nth information processing apparatus obtains an (N-1) th operation instruction from the (N-1) th operation processing unit,
Generating the (N-1) th operation information based on the (N-1) th operation instruction;
Generating the N-1th operation information, the Nth operation information, the Nth operation information or the Nth integrated operation information, and generating the N-1st operation information.
The system according to claim 15, wherein the N−1th operation information or the N−1th integrated operation information is transmitted to the N−1th information processing apparatus. The Nth operation processing unit is configured to perform Nth operation consistency between the Nth operation information and the Nth operation information or the Nth integrated operation information in accordance with a predetermined Nth operation rule. Verify
The Nth operation processing unit integrates the N-1th operation information, the Nth operation information including the verification result, and the Nth operation information or the Nth integrated operation information. 17. The system according to claim 16, wherein the N-1th integrated operation information is generated. The N-1th operation processing unit sends N-1th operation information to the Nth information processing apparatus,
The Nth operation processing unit obtains the (N-1) th operation information, and obtains the N-1th operation information and the Nth operation information according to a predetermined Nth operation rule. The system according to claim 16 or 17, wherein the operation consistency of N is verified. The first operation information includes an operation identifier;
The first operation information includes an operation identifier;
The first operation processing unit, when the operation identifier of the first operation information and the operation identifier of the operation information of the first operation information have the same value, The system according to claim 15, which cooperates by outputting the first operation information together. The N-1th operation information includes an operation identifier,
The N-1th operation information includes an operation identifier,
The N-1th operation processing unit includes:
When the operation identifier of the N-1th operation information and the operation identifier of the N-1th operation information have the same value, the N-1th operation information and the N-1th operation It cooperates by outputting together with information,
When the operation identifier of the N-1th operation information and the operation identifier of the N-1st integrated operation information have the same value, the N-1th operation information and the N-1th operation information 20. The system according to claim 16, wherein the system cooperates by outputting the integrated operation information together. A process of sending a first operation instruction based on the first operation designation input in the first operation;
Processing for generating first operation information based on the first operation designation;
Processing for obtaining first operation information;
Processing for linking the first operation information and the first operation information;
Processing for obtaining the first operation instruction from the first operation processing unit;
Processing for generating the first motion information based on the first motion instruction;
Processing for sending the first operation information to the first operation processing unit;
A program that causes a computer to execute. When the content of the Nth operation is included in the (N-1) th operation,
A process of sending an N-th operation instruction to the (N + 1) -th operation processing unit based on the N-th operation designation input in the N-th operation;
Generating Nth operation information based on the Nth motion designation;
Processing for obtaining Nth motion information or Nth integrated motion information from the (N + 1) th motion processing unit;
A process for linking the Nth operation information with the Nth operation information or the Nth integrated operation information;
An N-1th operation instruction is acquired from the N-1th operation processing unit;
A process of generating N-1th operation information based on the N-1th operation instruction;
Processing for generating the (N-1) th operation information, the Nth operation information, and the Nth operation information or the Nth integrated operation information to generate the (N-1) th operation information. ,
A process of sending the N-1th operation information or the N-1th integrated operation information to the N-1th operation processing unit;
The program according to claim 21, wherein the program is executed by a computer. A process of verifying the Nth operation consistency between the Nth operation information and the Nth operation information or the Nth integrated operation information in accordance with a predetermined Nth operation rule;
The (N-1) th integrated operation information obtained by integrating the (N-1) th operation information, the Nth operation information including the verification result, and the Nth operation information or the Nth integrated operation information. Processing to generate
21. The program according to claim 20, wherein the program is executed by a computer. A process of sending the N-1th operation information to the Nth operation processing unit;
A process of acquiring the N-1th operation information;
A process of verifying the Nth operation consistency between the N-1th operation information and the N-1th operation information in accordance with a predetermined Nth operation rule;
The program according to claim 22 or 23, which causes a computer to execute. The first operation information includes an operation identifier;
The first operation information includes an operation identifier;
When the operation identifier of the first operation information and the operation identifier of the first operation information have the same value, the first operation information and the first operation information are output together. The program according to any one of claims 21 to 24, which causes a computer to execute processing to cooperate with each other. The N-1th operation information includes an operation identifier,
The N-1th operation information includes an operation identifier,
When the operation identifier of the N-1th operation information and the operation identifier of the N-1th operation information have the same value, the N-1th operation information and the N-1th operation It cooperates by outputting together with information,
When the operation identifier of the N-1th operation information and the operation identifier of the N-1st integrated operation information have the same value, the N-1th operation information and the N-1th operation information The program according to any one of claims 22 to 25, which causes a computer to execute a cooperative process by outputting the integrated operation information together. Computer
A first operation instruction is sent out based on the first operation designation input in the first operation,
Generating first operation information based on the first action designation;
Get first action information,
Linking the first operation information and the first operation information;
Obtaining the first operation instruction from the first operation processing unit, generating the first operation information based on the first operation instruction;
Sending the first operation information to the first operation processing unit;
Method. Computer
27. The method according to claim 26, wherein a first consistency between the first operation information and the first operation information is verified according to a predetermined first rule. The difference between the first operation input time included in the first operation information and the operation execution time included in the first operation information is determined in advance for the first consistency. 27. The method according to claim 26, wherein the verification is based on whether or not the threshold value is within a range. The first consistency includes information indicating an instruction destination of the first operation instruction based on the first operation designation, and contents of the operation based on the first operation instruction included in the first operation information. 30. The method according to claim 28 or 29, wherein the information is verified based on whether or not the information is predetermined as normal correspondence. Computer
Sending out the first operation information, obtaining the first operation information,
31. The method according to claim 27, wherein the second consistency between the first operation information and the first operation information is verified according to a predetermined second rule. For the second consistency, a difference between the input time of the first operation included in the first operation information and the execution time of the operation included in the first operation information is determined in advance. 32. The method according to claim 31, wherein the verification is made based on whether or not the threshold value is within a range. The second consistency is determined based on the first operation content based on the first operation designation included in the first operation information and the first operation included in the first operation information. The method according to any one of claims 31 to 32, wherein verification is performed based on whether or not the information indicating the instruction source of the first operation instruction that has transmitted the instruction is predetermined as normal correspondence. Computer
When the Nth operation is included in the (N-1) th operation,
Based on the Nth operation designation input in the Nth operation, an Nth operation instruction is sent to the (N + 1) th operation processing unit,
Generating Nth operation information based on the Nth motion designation;
Nth operation information or Nth integrated operation information is acquired,
Linking the Nth operation information with the Nth operation information or the Nth integrated operation information;
An N-1th operation instruction is acquired from the N-1th operation processing unit;
Generating N-1th operation information based on the N-1th operation instruction;
Generating the (N-1) th operation information, the Nth operation information, and the Nth operation information or the Nth integrated operation information, and generating the (N-1) th integrated operation information.
The method according to any one of claims 27 to 33, wherein the N-1th operation information or the N-1th integrated operation information is sent to the N-1th operation processing unit. Computer
Verifying the consistency between the Nth operation information and the Nth operation information or the Nth integrated operation information in accordance with a predetermined Nth operation rule;
The (N-1) th integrated operation obtained by integrating the (N-1) th operation information, the Nth operation information including the verification result, and the Nth operation information or the Nth integrated operation information. 35. The method of claim 34, wherein information is generated. Computer
N-1th operation information is sent to the Nth operation processing unit,
Obtaining the N-1th operation information;
36. The method according to claim 34 or 35, wherein the Nth operation consistency between the N-1th operation information and the N-1th operation information is verified according to a predetermined Nth operation rule. Computer
When the content of the Nth operation is included in the N-1th operation,
37. The method according to claim 34 or 36, wherein the (N-1) th integrated operation information not including the Nth operation information and the Nth integrated operation information is generated according to a predetermined criterion. Computer
When the content of the Nth operation is included in the N-1th operation,
The method according to any one of claims 34 to 37, wherein the (N-1) th integrated operation information that does not include the Nth operation information and the (N-1) th operation information is generated according to a predetermined criterion. . The first operation information includes an operation identifier;
The first operation information includes an operation identifier;
When the operation identifier of the first operation information and the operation identifier of the first operation information have the same value, the computer combines the first operation information and the first operation information. 39. A method according to any one of claims 27 to 38, which cooperates by outputting the output. The N-1th operation information includes an operation identifier,
The N-1th operation information includes an operation identifier,
Computer
When the operation identifier of the N-1th operation information and the operation identifier of the N-1th operation information have the same value, the N-1th operation information and the N-1th operation It cooperates by outputting together with information,
When the operation identifier of the N-1th operation information and the operation identifier of the N-1st integrated operation information have the same value, the N-1th operation information and the N-1th operation information 40. The method according to any one of claims 34 to 39, wherein cooperation is performed by outputting the integrated operation information together.

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