CN116126461A - Online dynamic simulation device of intelligent tool - Google Patents

Abstract

The invention discloses an intelligent tool on-line dynamic simulation device, which comprises a simulation driver, a processing center, an attribute configuration module, a right management module and a Database (DB), wherein the right management module is responsible for right management and intelligent tool on-line management, the simulation driver linkage processing center is responsible for responding to equipment call, the attribute configuration module and the processing center are interactively responsible for changing the characteristics of modules in simulation equipment, and the characteristics of the simulation equipment, the simulation module and other information are all stored in the database. The invention provides a test environment for simulating real equipment for automatic test, can flexibly configure the module characteristics of the simulation equipment, and provides a debugging test environment for analyzing and positioning the error problem at the occurrence, thereby greatly improving the quality of software products.

Description

Online dynamic simulation device of intelligent tool

Technical Field

The invention relates to an intelligent tool on-line dynamic simulation device.

Background

With the continuous development of the self-service equipment industry, the number of self-service equipment is increased sharply, and the application fields are more and more extensive, including a plurality of fields such as finance, tax, government affairs, medical treatment and the like. And along with the higher intelligent degree of self-service machines, integrated basic modules are more and more, and the intelligent self-service machines comprise a card reader module capable of reading cards, a cash module for correctly identifying the authenticity and quantity of bank notes, a fingerprint instrument module and a face camera module for identifying human biological characteristics, a card making module for supporting personalized customization, a password keyboard module for guaranteeing communication safety, an identity card reader module, a handwritten signature, a card issuing module (such as a bank card and a social security card), an invoice module, a check module and the like. The functional modules are integrated, and the service functions supported by the intelligent machine are richer and more convenient.

However, in the development process of the intelligent tool matching environment, the general hardware cost of the functional modules is high and is often limited by hardware module resources, so that the hardware module resources are difficult to provide matched hardware module resources for development and testers distributed in all places of the country, the hardware module resources often become resource bottlenecks in projects, and the overall development progress of the projects is delayed because the hardware environment cannot be in place in time; or even if the hardware module is in place, when multiple persons in the team develop or test in parallel, the problem of hardware resource robbery and competition caused by insufficient hardware module resources still exists. Meanwhile, when some abnormal problems are caused in the development and test processes, the problems are difficult to reproduce by using real hardware equipment by testers, and the problem of the caused occurrence is often not solved at late stage. In addition, in order to improve the product quality, an automatic test method is often adopted, but when operations (such as card insertion, certificate insertion, fingerprint pressing, password input and the like) requiring human participation are involved, automatic test is difficult to achieve due to waiting for manual operation, and the module is urgently required to support the automatic test. In addition, the intelligent machine matching environment covers Windows, linux, android and other different operating system environments, and in order to verify the compatibility of application software, a plurality of hardware environments are often required to be built.

Disclosure of Invention

The invention aims to provide an intelligent tool on-line dynamic simulation device to solve the problems that hardware resources are bottleneck, faults are difficult to check, manual intervention steps are more difficult to realize automation and the like. In order to achieve the purpose, the invention provides the following technical scheme.

An intelligent tool on-line dynamic simulation device, comprising:

the system comprises a simulation driving module, an attribute configuration module, a database module and a permission management module, wherein the simulation driving module, the attribute configuration module and the database module are respectively in communication connection with a processing center module;

the simulation driving module comprises a plurality of simulation units for simulating all structures in the hardware equipment, and the simulation units are used for combining and simulating to form an integral hardware equipment operation;

the attribute configuration module is used for performing parameter attribute configuration operation on each simulation unit in the simulation driving module;

the database module is used for storing data including authority information and equipment information;

the processing center module is used for acquiring and processing corresponding data from the simulation driving module, the attribute configuration module and the database module so as to form simulation equipment and a simulation dynamic process and provide the simulation equipment and the simulation dynamic process for a user;

the right management module is used for managing the rights of different users.

The device, the right management module executes right management through the following steps:

step one, a system management account number and a corresponding password are established during initialization;

step two, establishing a tenant account representing an organization and a corresponding password by using the identity of the system management account;

step three, establishing a user account and a corresponding password under the tenant by using the identity of the tenant account;

and step four, the authority management module provides operation authority for a user logged in based on the user account number so as to perform corresponding simulation operation.

The device, the processing center module creates simulation equipment for the user through the following process:

setting basic information of simulation equipment and a module configuration table, wherein the basic information at least comprises information including equipment name, IP address and MAC address, and the module configuration table comprises the quantity and the type information of simulation units included in the simulation equipment;

then initializing simulation parameters for each simulation unit based on the attribute configuration module, the simulation parameters including at least a current state of the simulation unit, a current state of the medium, a list of functions supported by the simulation unit, and an expected result for each function.

The device is characterized in that in the simulation parameters, the current state of the simulation unit is used for indicating whether the structure simulated by the simulation unit is normal at present, and the current state comprises normal, offline, fault and unknown; the current state of the medium is used for representing the medium condition in the structure requiring the medium to be used, including medium, no medium, seizing and unknown; the function list supported by the simulation unit is used for representing a hardware action list which can be simulated by the simulation unit; the expected outcome of each function refers to whether the user expects this operation to be successful or failed, and setting the reason for the failure.

The device, the attribute configuration module, the configuration operation of parameter attribute for each simulation unit includes:

1) Simulating an immediate fault: modifying simulation parameters of a simulation unit according to simulation requirements, and simulating faults when specific functions are executed;

2) Simulating a post-fault: the simulation execution of a certain function is successfully returned, but the simulation unit fails after the execution is completed, namely, the attribute value is changed after the simulation unit drives to execute a certain action;

3) Simulation of random faults: and simulating the random occurrence of module faults, so that the simulation unit is enabled to generate faults according to the setting at random time, and the accidental problem is repeated.

The device, based on the step of the device simulation includes:

(1) The device initiates a simulation process based on user operation to sequentially execute actions in the simulation process;

(2) The processing center queries all the latest states of the related simulation units based on the currently executed actions;

(3) Judging whether the instruction in the currently executed action is a query instruction or an execution instruction, if the instruction is the query instruction, returning the query result in the step (2) to the user, and entering the step (11); otherwise, entering the step (4);

(4) If the instruction is executed, judging which states in the step (2) can influence the execution result, forming an equipment attribute list, checking whether each state value in the equipment attribute list is normal, if the state corresponding to the instruction is acquired, returning fault information to a user, and entering the step (11), otherwise, entering the step (5);

(5) If the states of the equipment attribute list are normal at the moment, a query request is initiated to the processing center module, and whether the simulation unit related to the instruction is configured in a manual mode or an automatic mode and the expected result of the corresponding function are queried; if the automatic mode is adopted, the step (9) is carried out, otherwise, the step (6) is carried out; the manual mode is to wait for the operation of a user, otherwise, the manual mode is an automatic mode;

(6) Judging whether the instruction relates to an action which can be completed only by manual operation of a user, and if not, entering a step (9); otherwise, entering a step (7);

(7) Judging whether overtime exists, if so, returning an overtime prompt to a user, and entering a step (11); otherwise, entering the step (8);

(8) Judging whether the user has completed the operation, and returning to the step (7) if the user has not completed the operation; if so, go to step (9);

(9) Checking whether the expected result of the function is success or failure, if so, returning success information to the user, and entering step (11); otherwise, entering step (10);

(10) Judging whether the simulation unit is a hardware type fault or other type faults according to the fault type corresponding to the failure, if the simulation unit is a hardware type fault, setting the current state of the simulation unit as a fault by a processing center, and entering the step (11); if the hardware class is not fault, directly returning fault information to the user, and then entering step (11);

(11) Judging whether the currently executed action has a next execution action, if so, continuously judging whether the next execution action is to change the state of the simulation unit or an execution instruction, if so, ending the simulation process after changing the state, and if the next execution action is the execution instruction, returning to the step (2), and if not, ending the simulation process.

The device is characterized in that the inquiry class instruction is an instruction for inquiring the information of the simulation equipment; an execution class instruction is an instruction for performing a specific device operation action.

The invention has the technical effects that under the condition that a user does not have hardware module resources, the invention can replace real hardware to use by installing the simulation driver on a common terminal computer and configuring the equipment basic information, the module list and the attribute parameter information of each module related to the terminal on the authority management module.

Drawings

FIG. 1 is an architecture diagram of an online dynamic device emulation system;

FIG. 2 illustrates a three-level user management system of the rights management module emulating an intelligent tool;

FIG. 3 shows a new simulation device and simulation module of the rights management module;

the simulation module of fig. 4 responds to upper layer device calls.

Detailed Description

The invention will be further illustrated with reference to examples. In this embodiment, the intelligent tool online dynamic simulation device includes a simulation driving module, a processing center module, an attribute configuration module, a rights management module, and a database module (DB). The simulation driving module operates on a common terminal (such as a common notebook computer and a desktop computer), and meanwhile, applications, middleware and SP are also operated on the common terminal, and are specific software components for calling the simulation device so as to facilitate the operation of an actual user. And the simulation driving module integrates a plurality of simulation units, forms interaction with the processing center, and provides equipment calling service for applications, middleware and SP. The processing center module provides data access services for the simulation driver and attribute configuration module. The rights management module manages account information, simulation device, simulation module information, and the like, as shown in fig. 1.

The authority management module is used for facilitating centralized user management in different use scenes of different types of clients such as banks, securities, medical treatment, government affairs and the like, and is used for designing a three-level user management system: the system administrator has the highest authority, can maintain and manage all account information, simulation equipment, simulation modules, equipment module attribute template information and the like involved in the system, and can usually create a plurality of tenants according to the needs; each tenant is usually a customer (such as a certain bank, a certain hospital, etc.), the information of the tenant is the basic information of the customer, the tenant has the authority to maintain all the user information, simulation equipment, simulation modules, etc. under the tenant, one tenant can create one to a plurality of users according to the purchasing requirement (the specific number of users is determined by the authority after purchasing, and the system administrator has the authority to configure); a user typically has a specific role under a tenant (e.g., a visual tester at a bank), and can maintain information about all simulation devices and simulation modules created by the user, and the user typically can create one or more simulation devices (the number of specific simulation devices is determined by the rights after purchase, and the system administrator has authority to configure), as shown in fig. 2.

In this embodiment, a specific initialization step is shown in fig. 3, and a new card sender device is taken as an example, where the initialization step is as follows:

(1) Default one system management account number and initial password when the authority management module is initialized;

(2) After a system administrator uses a default account number and a password to log in for the first time, the system forcibly requires to modify the initial password;

(3) A system administrator can establish one or more tenants in account management of the authority management module, such as a certain website organization of a certain bank, a certain hospital and the like, and when the tenant is established, the system administrator inputs basic information (such as the name of the affiliated organization, the name of the tenant, a contact phone, a mailbox and the like) of the tenant and sets a default initial password;

(4) The system administrator maintains all simulation equipment and simulation module information in the asset management of the rights management module, including a simulation equipment list, a simulation module attribute template, etc.: the simulation equipment is mainly equipment models, such as ATM equipment, card sender, card making machine and the like, and is set as card sender equipment; the simulation module specifically refers to a module for assisting in handling business, such as a simulation second-generation identity card module, a simulation card reader module, a simulation fingerprint instrument module, a simulation camera and the like;

(5) After each tenant logs in for the first time by using the default initialization password, the initialization password is forcefully required to be modified. The tenant can check and modify own information (such as affiliated organization name, tenant name, contact phone, mailbox and the like), or in account management of the authority management module, one or more users can be newly built according to authority limit configured by a system administrator, basic information (such as affiliated organization name, user name, contact phone, mailbox and the like) of the users is input, and each user is provided with an independent account number and a default initial default password; the tenant can see all user lists and user information created by the tenant;

(6) After each user logs in for the first time using the default initial password, the initial password is forcefully required to be modified. Each user can maintain all simulation devices created by the user and simulation module information associated with the simulation devices;

(7) If the user needs to newly build simulation equipment, basic information (such as equipment name is card sender equipment, IP address and MAC address are addresses of the common terminal) and a module configuration table (such as card sender equipment needs to be configured with a simulation card reader module, a second-generation identity card module, a password keyboard module, a receipt printing module, a camera module, a fingerprint instrument module and the like) of the simulation intelligent tool are required to be added;

(8) After the configuration table of the simulation module is configured, initialization parameters (the parameters include the current state of equipment, the current state of media, a method list supported by the module, return parameters of each method and the like) are set for each module according to the attribute template of the simulation module. If the current mode of the card reader module is configured to be an automatic mode, the current equipment state is equipment normal, the current medium state is medium-free, and the current method list is all method lists and parameters supported by the card reader module, such as data of tracks track1, track2 and track3 of the returned magnetic stripe card can be set by reading magnetism.

After the new creation of the card sender simulation device and the configuration initialization of the simulation module are completed, parameters of module attributes can be dynamically changed in the following three modes:

(1) Manual modification: the simulation module is selected through the attribute configuration module, and the states and parameters are manually modified. If the card reader state is manually modified to be in a fault state, all calls return to the equipment state fault; when the card is manually selected to be inserted, the simulated card reader module displays the medium state; when the card reading return medium fault is set manually, calling the card reading function returns the medium fault in the card reading fault;

(2) Performing post-modification: the simulation of fault after executing some action is successful, the attribute value is changed after the simulation module drives to execute some action, and the influence on the current simulation equipment after executing some action can be flexibly configured into any single or combined influence. If the card reader module executes the card reading action, the equipment state becomes a fault, or the equipment fails when the card is read and then returned and swallowed, etc.;

(3) Timing modification: the simulation module can randomly generate faults, the specific time can be set randomly, and the simulation module drive can randomly generate faults according to the setting. If the device fails after 2s is set, the state of the device is changed into the device failure after 2s, and a certain operation action may be randomly executed at this time.

The specific call and process flow of this embodiment are shown in fig. 4, and when the upper layer finance/medical/government application program completes a specific service, the simulation module supports the device call in the real service process flow. Taking the simulation card issuing equipment as an example, the card issuing service is handled, and the specific steps are as follows:

(1) And entering a financial service main interface, and selecting to transact card issuing service by a user, wherein simulation units such as a simulation second-generation identity card reading unit, a simulation camera, a simulation card issuing unit, a simulation fingerprint instrument, a simulation card reader, a simulation password keyboard, a simulation sign pen and the like are needed. The application calls the SP service through the middleware, and the SP calls the simulation driving service.

(2) The simulation process is required to call the reading action of the second-generation identity card.

(3) The simulation second-generation identity card unit initiates a query request to the processing center, and queries all the latest states related to the simulation second-generation identity card unit at the moment, including the equipment state of the second-generation identity card at the moment and the medium state of the second-generation identity card.

(4) Instructions can be classified into query class instructions and execution class instructions according to the nature of the call. The inquiry type instruction is mainly used for inquiring information such as equipment state, equipment capacity, medium state, consumable state and the like. The execution class instruction refers to execution of specific equipment operation actions, such as initializing equipment, reading a card, reading a second-generation identity card, issuing a card, swallowing a card, discharging a banknote, depositing a banknote, printing and the like. Judging whether the query instruction is a query instruction or an execution instruction at the moment, if the query instruction is the query instruction, returning the query result in the step (2) to the SP service, and entering the step (13).

(5) And (3) judging which equipment attribute states in the step (2) influence the current execution result to form an equipment attribute list, including information such as equipment states and medium states, checking whether the equipment states in the equipment attribute list are normal or not, and if the medium states are medium or not, returning fault information to the SP service if the equipment states are fault at the moment, and entering the step (13). If the states of the device attribute list are normal at this time, a query request is initiated to the processing center to query the return parameter configuration of the certificate reading instruction.

(6) And initiating a request for inquiring the attribute parameters of the second-generation identity card module read card to the processing center, and inquiring whether the second-generation identity card module is configured in a manual mode or an automatic mode.

(7) If the mode is manual, the certificate reading instruction relates to an action which can be completed only by manual operation of a user (waiting for the insertion of an identity card by a client), and waits for the insertion of a certificate by the user.

(8) Judging whether waiting for the overtime of the insertion card, if yes, directly returning to overtime, and entering the step (13).

(9) If the time-out or the set infinite time-out is not performed at this time, judging whether the user has completed the operation, if the operation has not been completed, proceeding to step (8), and if the operation has been completed, proceeding to step (11).

(10) If the automatic mode is the automatic mode, go directly to step (11).

(11) And judging whether the parameters of the read certificate are normally returned or an error code is returned, if so, returning normal read certificate data to the SP service, and entering the step (13).

(12) If the parameter is a return fault code, the simulation module needs to judge whether the equipment itself is faulty or other faults (such as media is unsatisfactory) according to the fault type. If the equipment type is faulty, it needs to judge which equipment attributes are affected by the execution operation, forming an equipment attribute list, initiating a request to a processing center, returning to the fault and updating each equipment state of the equipment attribute list, and entering step (13). If the equipment is not a fault caused by equipment, returning to the fault and proceeding to the step (13). For example, the attribute of the read certificate is set to return 1700044003 code, which indicates a card-in timeout, at which point the emulated device state is not affected, simply because the certificate was not inserted normally. But if it is a return 1700041032 code that indicates that the USB port read data was incorrect, then it is necessary to modify the emulated device state to fail at this point.

(13) Judging whether the currently executed instruction configures the next execution action after the execution is finished, if so, executing the next action, and flexibly simulating various fault scenes occurring after the reading of the certificate, for example, setting the equipment state as a fault after the execution of the certificate reading operation, indicating the scene that the equipment is faulty after the reading of the certificate is finished, and ending the current second-generation identity card reading reverse process after the equipment state is changed. For example, after the certificate reading operation is performed, the equipment fails and the medium state is a medium-free state, which indicates a scene that the equipment fails and the medium is not detected after the certificate reading operation is performed. If there are other actions to execute the instruction, return to step (2) and continue the loop flow. If no subsequent processing is configured, ending the simulation process.

Claims (7)

1. An intelligent tool on-line dynamic simulation device is characterized by comprising:

the system comprises a simulation driving module, an attribute configuration module, a database module and a permission management module, wherein the simulation driving module, the attribute configuration module and the database module are respectively in communication connection with a processing center module;

the simulation driving module comprises a plurality of simulation units for simulating all structures in the hardware equipment, and the simulation units are used for combining and simulating to form an integral hardware equipment operation;

the attribute configuration module is used for performing parameter attribute configuration operation on each simulation unit in the simulation driving module;

the database module is used for storing data including authority information and equipment information;

the processing center module is used for acquiring and processing corresponding data from the simulation driving module, the attribute configuration module and the database module so as to form simulation equipment and a simulation dynamic process and provide the simulation equipment and the simulation dynamic process for a user;

the right management module is used for managing the rights of different users.

2. The apparatus of claim 1, wherein the rights management module performs rights management by:

step one, a system management account number and a corresponding password are established during initialization;

step two, establishing a tenant account representing an organization and a corresponding password by using the identity of the system management account;

step three, establishing a user account and a corresponding password under the tenant by using the identity of the tenant account;

and step four, the authority management module provides operation authority for a user logged in based on the user account number so as to perform corresponding simulation operation.

3. The apparatus of claim 2, wherein the processing center module creates the simulation device for the user by:

setting basic information of simulation equipment and a module configuration table, wherein the basic information at least comprises information including equipment name, IP address and MAC address, and the module configuration table comprises the quantity and the type information of simulation units included in the simulation equipment;

then initializing simulation parameters for each simulation unit based on the attribute configuration module, the simulation parameters including at least a current state of the simulation unit, a current state of the medium, a list of functions supported by the simulation unit, and an expected result for each function.

4. The apparatus of claim 3, wherein the current state of the simulation unit in the simulation parameters is used to indicate whether the structure simulated by the simulation unit is normal at present, including normal, offline, faulty and unknown; the current state of the medium is used for representing the medium condition in the structure requiring the medium to be used, including medium, no medium, seizing and unknown; the function list supported by the simulation unit is used for representing a hardware action list which can be simulated by the simulation unit; the expected outcome of each function refers to whether the user expects this operation to be successful or failed, and setting the reason for the failure.

5. The apparatus of claim 1, wherein the attribute configuration module performs the configuration operation of the parameter attribute on each simulation unit, including:

1) Simulating an immediate fault: modifying simulation parameters of a simulation unit according to simulation requirements, and simulating faults when specific functions are executed;

2) Simulating a post-fault: the simulation execution of a certain function is successfully returned, but the simulation unit fails after the execution is completed, namely, the attribute value is changed after the simulation unit drives to execute a certain action;

3) Simulation of random faults: and simulating the random occurrence of module faults, so that the simulation unit is enabled to generate faults according to the setting at random time, and the accidental problem is repeated.

6. The apparatus of claim 5, wherein the step of simulating based on the apparatus comprises:

(1) The device initiates a simulation process based on user operation to sequentially execute actions in the simulation process;

(2) The processing center queries all the latest states of the related simulation units based on the currently executed actions;

(3) Judging whether the instruction in the currently executed action is a query instruction or an execution instruction, if the instruction is the query instruction, returning the query result in the step (2) to the user, and entering the step (11); otherwise, entering the step (4);

(4) If the instruction is executed, judging which states in the step (2) can influence the execution result, forming an equipment attribute list, checking whether each state value in the equipment attribute list is normal, if the state corresponding to the instruction is acquired, returning fault information to a user, and entering the step (11), otherwise, entering the step (5);

(5) If the states of the equipment attribute list are normal at the moment, a query request is initiated to the processing center module, and whether the simulation unit related to the instruction is configured in a manual mode or an automatic mode and the expected result of the corresponding function are queried; if the automatic mode is adopted, the step (9) is carried out, otherwise, the step (6) is carried out; the manual mode is to wait for the operation of a user, otherwise, the manual mode is an automatic mode;

(6) Judging whether the instruction relates to an action which can be completed only by manual operation of a user, and if not, entering a step (9); otherwise, entering a step (7);

(7) Judging whether overtime exists, if so, returning an overtime prompt to a user, and entering a step (11); otherwise, entering the step (8);

(8) Judging whether the user has completed the operation, and returning to the step (7) if the user has not completed the operation; if so, go to step (9);

(9) Checking whether the expected result of the function is success or failure, if so, returning success information to the user, and entering step (11); otherwise, entering step (10);

(10) Judging whether the simulation unit is a hardware type fault or other type faults according to the fault type corresponding to the failure, if the simulation unit is a hardware type fault, setting the current state of the simulation unit as a fault by a processing center, and entering the step (11); if the hardware class is not fault, directly returning fault information to the user, and then entering step (11);

(11) Judging whether the currently executed action has a next execution action, if so, continuously judging whether the next execution action is to change the state of the simulation unit or an execution instruction, if so, ending the simulation process after changing the state, and if the next execution action is the execution instruction, returning to the step (2), and if not, ending the simulation process.

7. The apparatus of claim 6, wherein the query class instruction is an instruction for querying for simulated device information; an execution class instruction is an instruction for performing a specific device operation action.

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