CN117348858A - Graphical-based Web security test task planning method and system - Google Patents

Abstract

The invention provides a Web security test task planning method and system based on graphics, comprising the following steps: constructing a Web security test model library; preprocessing the resource model data in the Web safety test model library, and integrating the resource model data into a model library based on Web safety test; and constructing a task planning graphical editing platform according to the model library based on the Web security test, and editing a task planning topological graph through the task planning graphical editing platform to complete graphical task planning of the Web security test task. According to the method, a Web security test resource model library is established through a visualization technology, a resource model is visually displayed in a classified mode, and attribute information of the resource model is checked or edited through a self-developed visual custom editing component. The Web security tester can utilize the visual model library to establish resource nodes required by task planning topology, and view or edit attribute information of the resource model, so that the time for the tester to establish tasks is saved.

Description

Graphical-based Web security test task planning method and system

Technical Field

The invention relates to the technical field of network security, in particular to a Web security test task planning method and system based on graphics.

Background

In recent years, the increasing demands of network applications have led to various new network services, and network attacks have been exponentially increased while enjoying network services, so that more and more unsafe factors of the system are exposed. These unsafe factors cause the Web application program to be destroyed, changed and information to be leaked, which affects the continuous, reliable and normal operation of the system. Therefore, ensuring confidentiality, integrity, availability, authenticity and irrelevance of network security, and improving defending ability of the system is increasingly important.

Generally, when Web security test is performed, a tester firstly composes a test scheme by writing a test outline, a test rule and the like of a text plate. Then, the tester operates the tools and the tested targets used in the testing process in sequence according to the description of the testing scheme. And finally, manually recording and counting the test result to complete the test task. However, in the face of a complex test scheme, the test process is complex and tedious, and the testers often work idle. In addition, the test task execution cannot be completed in time, and immeasurable network potential safety hazards can be brought. Therefore, it is particularly important to improve the efficiency of the Web security test task.

Patent document CN110162979a discloses a security test method and device for Web API of Web interface, electronic device and storage medium. The method comprises the following steps: according to the storage paths of the access logs corresponding to all the Web APIs to be tested, obtaining the access logs corresponding to all the Web APIs to be tested in a Web server; extracting interface information corresponding to each Web API to be tested from access logs corresponding to each Web API to be tested according to the log format of the interface information corresponding to all the Web APIs to be tested; and carrying out black box security test on each Web API to be tested according to the interface information corresponding to each Web API to be tested.

However, patent document CN110162979a lacks planning of a Web security test task, and there is room for improvement in Web security test task efficiency.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a Web security test task planning method and system based on graphics.

The invention provides a Web security test task planning method based on graphics, which comprises the following steps:

step S1: constructing a Web security test model library;

step S2: preprocessing the resource model data in the Web safety test model library, and integrating the resource model data into a model library based on Web safety test;

step S3: and constructing a task planning graphical editing platform according to the model library based on the Web security test, and editing a task planning topological graph through the task planning graphical editing platform to complete graphical task planning of the Web security test task.

Preferably, the resource model attribute in the Web security test model library comprises a general basic attribute and a specific model attribute;

the general basic attribute comprises basic information corresponding to a model, and the basic information comprises model names, types, icons and descriptions;

the task planning graphical editing platform comprises a resource model graphical display module, a task planning topology module, a graphical data processing module and a model attribute editing module.

Preferably, step S1 comprises:

step S1.1: inputting the general basic attribute into a Web security test model library, and establishing a graphical resource model;

step S1.2: and inputting the special model attribute into a Web safety test model library, customizing a control component and converting a programming code into a graphical interface.

Preferably, step S2 includes:

step S2.1: classifying data according to the model original data input by the tester, and fusing data based on classification layers to obtain fused data;

step S2.2: and extracting the data after fusion, discarding redundant parameters caused by data fusion, and performing data conversion.

Preferably, step 3 comprises:

step S3.1: rendering the resource model in a view in a graphical form, constructing a resource model graphical display module, screening the model according to the model type through the resource model graphical display module, and displaying the resource model in a graphical form;

step S3.2: in the resource model graphical display module, a model for Web safety test is dragged to a graphical drawing area of the task planning topology module, and the connection relation between a resource model node and a network link is drawn in the area;

step S3.3: the graphic data processing module classifies, converts and stores the data related to the topological graph;

step S3.4: and in the resource model attribute editing module, checking or editing the related information of the task planning by selecting nodes and links on the topological graph.

The invention provides a Web security test task planning system based on graphics, which comprises:

module M1: constructing a Web security test model library;

module M2: preprocessing the resource model data in the Web safety test model library, and integrating the resource model data into a model library based on Web safety test;

module M3: and constructing a task planning graphical editing platform according to the model library based on the Web security test, and editing a task planning topological graph through the task planning graphical editing platform to complete graphical task planning of the Web security test task.

Preferably, the resource model attribute in the Web security test model library comprises a general basic attribute and a specific model attribute;

the general basic attribute comprises basic information corresponding to a model, and the basic information comprises model names, types, icons and descriptions;

the task planning graphical editing platform comprises a resource model graphical display module, a task planning topology module, a graphical data processing module and a model attribute editing module.

Preferably, the module M1 comprises:

module M1.1: inputting the general basic attribute into a Web security test model library, and establishing a graphical resource model;

module M1.2: and inputting the special model attribute into a Web safety test model library, customizing a control component and converting a programming code into a graphical interface.

Preferably, the module M2 comprises:

module M2.1: classifying data according to the model original data input by the tester, and fusing data based on classification layers to obtain fused data;

module M2.2: and extracting the data after fusion, discarding redundant parameters caused by data fusion, and performing data conversion.

Preferably, step 3 comprises:

module M3.1: rendering the resource model in a view in a graphical form, constructing a resource model graphical display module, screening the model according to the model type through the resource model graphical display module, and displaying the resource model in a graphical form;

module M3.2: in the resource model graphical display module, a model for Web safety test is dragged to a graphical drawing area of the task planning topology module, and the connection relation between a resource model node and a network link is drawn in the area;

module M3.3: the graphic data processing module classifies, converts and stores the data related to the topological graph;

module M3.4: and in the resource model attribute editing module, checking or editing the related information of the task planning by selecting nodes and links on the topological graph.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the method, a Web security test resource model library is established through a visualization technology, a resource model is visually displayed in a classified mode, and attribute information of the resource model is checked or edited through a self-developed visual custom editing component. The Web security tester can utilize the visual model library to establish resource nodes required by task planning topology, and view or edit attribute information of the resource model, so that the time for the tester to establish tasks is saved.

2. The invention is based on the visual Web security test resource model library, and can self-define and construct a Web security test topological graph in the task planning topological module. Resources used in the testing process and the behavior relation among the resources can be intuitively displayed in the topological graph, and the testing flow of the Web security test can be displayed from the side face. By using a graphical mode, a tester can rapidly, clearly and intuitively conduct task planning, and the execution efficiency of Web safety test is further improved as a whole.

Drawings

Other features, objects and advantages of the present invention will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

FIG. 1 is a schematic of the workflow of the present invention.

FIG. 2 is a schematic diagram of the block diagram of the task planning graphical editing platform according to the present invention.

FIG. 3 is a schematic workflow diagram of a graphical editing platform according to the present invention.

FIG. 4 is a schematic diagram of the workflow of the tree layout algorithm according to the present invention.

Detailed Description

The present invention will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the present invention, but are not intended to limit the invention in any way. It should be noted that variations and modifications could be made by those skilled in the art without departing from the inventive concept. These are all within the scope of the present invention.

According to the invention, as shown in fig. 1, the method for planning the Web security test task based on the graphics comprises the following steps:

step S1: and constructing a Web security test model library. Specifically, a tester performs manual input on the model through a graphical interface, and then a Web security test model library is built. The resource model attributes in the Web security test model library comprise general basic attributes and specific model attributes. The general basic attribute comprises basic information corresponding to the model, and the basic information comprises model names, types, icons and descriptions. The step S1 comprises the following steps:

step S1.1: and inputting the general basic attribute into a Web security test model library, and establishing a graphical resource model. Fixed attributes, namely general basic attributes, are pre-defined for the test resource library. Interaction with the tester provides a graphical editable view including single line input of model names, selection of model types, uploading of model icons, multiple lines of input of model descriptions, and so forth.

Step S1.2: and inputting the attribute of the special model into a Web safety test model library, customizing a control component, and converting the programming code into a graphical interface with good readability and usability. Such as custom input box types, custom selectable parameters, etc. That is, for entry of the unique attributes contained in each resource model, the control plugin is custom-ground, and plugin functions include custom-generating a single row of input boxes, multiple rows of input boxes, drop-down boxes, check boxes. Drop-down boxes and check boxes support tester customization of the selectable value sets. The step can facilitate the testers to input the specific attribute information of the resource model.

Step S2: and preprocessing the resource model data in the Web safety test model library, and integrating the resource model data into a model library based on Web safety test. The model library based on the Web security test provides a model data base for graphical task planning. The step S2 comprises the following steps:

step S2.1: and classifying the data according to the model original data input by the tester, and fusing the data based on the classification hierarchy to obtain fused data. Wherein the classification hierarchy includes a model type layer, a model attribute layer, and a test type layer. And e.g. according to a model type layer and a model attribute layer, carrying out attribute classification fusion on the input resource model data, and carrying out data extraction and arrangement according to attributes, such as service class, application class, host class and the like. And classifying and fusing according to the entered model attributes, such as model basic attributes and model specific attributes. And classifying and fusing according to the test type, such as data acquisition, vulnerability mining, vulnerability scanning and the like.

Step S2.2: and extracting the fused data, discarding redundant parameters caused by data fusion, and converting the data. The step can provide a data basis for the resource model graphical display module and the resource model attribute editing module in the step S3. Specifically, data cleansing processes invalid values and missing values in data in order to ensure consistency of the data. And the data conversion converts the model data structure after data cleaning into a data structure for graphical display of the resource model and attribute editing of the resource model.

Step S3: and constructing a task planning graphical editing platform according to the model library based on the Web security test, and editing a task planning topological graph through the task planning graphical editing platform to complete graphical task planning of the Web security test task. As shown in fig. 2, the task planning graphical editing platform comprises a resource model graphical display module, a task planning topology module, a graphical data processing module and a model attribute editing module. As shown in fig. 3, step 3 includes:

step S3.1: rendering the resource model in a view in a graphical form, constructing a resource model graphical display module, screening the model according to the model type through the resource model graphical display module, and displaying the resource model in a graphical form. The resource model graphical display module displays the resource model in a layering mode in a folding panel mode, and testers can also inquire the resource model used in the task planning process through fuzzy inquiry of model names, test types and the like. The query result is displayed in a form of model icons plus model names in a two-column vertical list arrangement in the resource model graphical region.

Step S3.2: and in the resource model graphical display module, dragging the model for Web safety test to a graphical drawing area of the task planning topology module, and drawing a connection relation between a resource model node and a network link in the area. The topology display adopts a tree-type layout form to efficiently display a multi-granularity and multi-layer Web security test task planning topology map. Specifically, a task planning topology module is mainly realized, and the module monitors events such as mouse translation, key pressing, loosening key pressing and the like of testers to finish dragging and copying of a resource model in a model library. And selecting a resource model node as an initial node by a tester, and realizing topology link drawing by a module in a mode of monitoring the actions of mouse buttons and translating to a termination node.

Different resource models such as a network layer, a host layer and an application layer selected by a tester can be presented by adopting a tree layout algorithm, and different links are selected to represent different network security test behaviors such as vulnerability mining, vulnerability scanning and the like. And displaying the Web security test task planning topological graph in a multi-layer and multi-granularity manner.

Further, as shown in fig. 4, the tree-type layout algorithm flow is high in algorithm efficiency due to high layout speed, and in addition, the tree-type structural form is similar to the hierarchical result of the Web security test task planning topology. The hierarchical result of task planning can be embodied by adopting the layout form, for example, a root node is defined as a first layer, for example, a network layer node is positioned at the top of the layout; the child of the root node is defined as a second level, such as a host level node, located only below the root node; similarly, the third tier node is located below the second tier node, such as an application tier node. In a topological graph realized by the tree-type layout algorithm, nodes at the same level are horizontally aligned and have different abscissas, and the abscissas of the father node are positioned at the average value positions of all child nodes of the father node, so that a recursion layer-by-layer rule is followed. The initial position of the root node is determined, the coordinates of each child node are calculated by recursively traversing all the child nodes, and the tree-shaped layout of task planning is realized by a graphical rendering technology.

Specifically, an initial position of the root node is first determined, and initial root node coordinates located at the topmost position are initialized.

Judging whether the current initial root node coordinates have child nodes or not, if so, traversing the child nodes of the initial root node, prescribing left-right intervals of the child nodes and up-down intervals of parent nodes, calculating the coordinates of each child node according to the number of the child nodes, and updating the horizontal and vertical coordinates of the child nodes with the same level to enable the horizontal and vertical coordinates of the child nodes to be aligned horizontally; if not, the process is ended.

And finally, traversing the current position node in sequence after alignment, judging whether the current position node has a subsequent node in sequence, if so, taking the current position node as a new root node, calculating coordinates distributed on the leftmost child node in child nodes of the root node, horizontally centering the leftmost boundary child node and updating coordinates of other child nodes in sequence, and performing next-level traversal; if not, the technical flow is carried out.

Step S3.3: and the graphic data processing module classifies, converts and stores the data related to the topological graph. The graphic data processing module adopts a polling interface mode to correlate user interaction with database data in real time, such as increase and decrease of the number of resource model nodes in a topological graph, positions of the resource model nodes and connection with other resource nodes. Meanwhile, the topological graph data is divided into a node set and a link set, and the high-efficiency mutual conversion of the graph data and the data table data is realized through the processing of the graph data.

Step S3.4: in the resource model attribute editing module, the related information of task planning is checked or edited by selecting nodes and links on the topological graph. And (3) mainly realizing a resource model attribute editing module, and viewing and editing model attributes by highlighting resource nodes and links in the selected topological graph based on the step S3.2 and the step S3.3 and adopting the custom control plugin constructed in the step 1.2.

The invention also provides a graphical-based Web security test task planning system, which can be realized by executing the flow steps of the graphical-based Web security test task planning method, namely, a person skilled in the art can understand the graphical-based Web security test task planning method as a preferred implementation mode of the graphical-based Web security test task planning system.

The invention provides a Web security test task planning system based on graphics, which comprises:

module M1: and constructing a Web security test model library. The resource model attributes in the Web security test model library comprise general basic attributes and specific model attributes. The general basic attribute comprises basic information corresponding to the model, and the basic information comprises model names, types, icons and descriptions. The module M1 includes: module M1.1: and inputting the general basic attribute into a Web security test model library, and establishing a graphical resource model. Module M1.2: and inputting the attribute of the special model into a Web safety test model library, customizing a control component and converting the programming code into a graphical interface.

Module M2: and preprocessing the resource model data in the Web safety test model library, and integrating the resource model data into a model library based on Web safety test. The module M2 includes: module M2.1: and classifying the data according to the model original data input by the tester, and fusing the data based on the classification hierarchy to obtain fused data. Module M2.2: and extracting the fused data, discarding redundant parameters caused by data fusion, and converting the data.

Module M3: and constructing a task planning graphical editing platform according to the model library based on the Web security test, and editing a task planning topological graph through the task planning graphical editing platform to complete graphical task planning of the Web security test task. The task planning graphical editing platform comprises a resource model graphical display module, a task planning topology module, a graphical data processing module and a model attribute editing module. The step 3 comprises the following steps: module M3.1: rendering the resource model in a view in a graphical form, constructing a resource model graphical display module, screening the model according to the model type through the resource model graphical display module, and displaying the resource model in a graphical form. Module M3.2: and in the resource model graphical display module, dragging the model for Web safety test to a graphical drawing area of the task planning topology module, and drawing a connection relation between a resource model node and a network link in the area. Module M3.3: and the graphic data processing module classifies, converts and stores the data related to the topological graph. Module M3.4: in the resource model attribute editing module, the related information of task planning is checked or edited by selecting nodes and links on the topological graph.

Those skilled in the art will appreciate that the invention provides a system and its individual devices, modules, units, etc. that can be implemented entirely by logic programming of method steps, in addition to being implemented as pure computer readable program code, in the form of logic gates, switches, application specific integrated circuits, programmable logic controllers, embedded microcontrollers, etc. Therefore, the system and various devices, modules and units thereof provided by the invention can be regarded as a hardware component, and the devices, modules and units for realizing various functions included in the system can also be regarded as structures in the hardware component; means, modules, and units for implementing the various functions may also be considered as either software modules for implementing the methods or structures within hardware components.

The foregoing describes specific embodiments of the present invention. It is to be understood that the invention is not limited to the particular embodiments described above, and that various changes or modifications may be made by those skilled in the art within the scope of the appended claims without affecting the spirit of the invention. The embodiments of the present application and features in the embodiments may be combined with each other arbitrarily without conflict.

Claims (10)

1. The Web security test task planning method based on the graphics is characterized by comprising the following steps of:

step S1: constructing a Web security test model library;

step S2: preprocessing the resource model data in the Web safety test model library, and integrating the resource model data into a model library based on Web safety test;

step S3: and constructing a task planning graphical editing platform according to the model library based on the Web security test, and editing a task planning topological graph through the task planning graphical editing platform to complete graphical task planning of the Web security test task.

2. The graphical-based Web security test task planning method according to claim 1, wherein the resource model attributes in the Web security test model library comprise general basic attributes and specific model attributes;

the general basic attribute comprises basic information corresponding to a model, and the basic information comprises model names, types, icons and descriptions;

the task planning graphical editing platform comprises a resource model graphical display module, a task planning topology module, a graphical data processing module and a model attribute editing module.

3. The graphical-based Web security test mission planning method as claimed in claim 2, wherein step S1 includes:

step S1.1: inputting the general basic attribute into a Web security test model library, and establishing a graphical resource model;

step S1.2: and inputting the special model attribute into a Web safety test model library, customizing a control component and converting a programming code into a graphical interface.

4. The graphical-based Web security test mission planning method as claimed in claim 1, wherein step S2 includes:

step S2.1: classifying data according to the model original data input by the tester, and fusing data based on classification layers to obtain fused data;

step S2.2: and extracting the data after fusion, discarding redundant parameters caused by data fusion, and performing data conversion.

5. The graphical-based Web security test mission planning method as claimed in claim 2, wherein step 3 includes:

step S3.1: rendering the resource model in a view in a graphical form, constructing a resource model graphical display module, screening the model according to the model type through the resource model graphical display module, and displaying the resource model in a graphical form;

step S3.2: in the resource model graphical display module, a model for Web safety test is dragged to a graphical drawing area of the task planning topology module, and the connection relation between a resource model node and a network link is drawn in the area;

step S3.3: the graphic data processing module classifies, converts and stores the data related to the topological graph;

step S3.4: and in the resource model attribute editing module, checking or editing the related information of the task planning by selecting nodes and links on the topological graph.

6. A Web security test mission planning system based on patterning, comprising:

module M1: constructing a Web security test model library;

module M2: preprocessing the resource model data in the Web safety test model library, and integrating the resource model data into a model library based on Web safety test;

module M3: and constructing a task planning graphical editing platform according to the model library based on the Web security test, and editing a task planning topological graph through the task planning graphical editing platform to complete graphical task planning of the Web security test task.

7. The graphical-based Web security test mission planning system of claim 6, wherein the resource model attributes in the Web security test model library comprise generic basic attributes and unique model attributes;

the general basic attribute comprises basic information corresponding to a model, and the basic information comprises model names, types, icons and descriptions;

the task planning graphical editing platform comprises a resource model graphical display module, a task planning topology module, a graphical data processing module and a model attribute editing module.

8. The graphical-based Web security test mission planning system of claim 7, wherein module M1 comprises:

module M1.1: inputting the general basic attribute into a Web security test model library, and establishing a graphical resource model;

module M1.2: and inputting the special model attribute into a Web safety test model library, customizing a control component and converting a programming code into a graphical interface.

9. The graphically-based Web security test mission planning system as claimed in claim 6, wherein module M2 includes:

module M2.1: classifying data according to the model original data input by the tester, and fusing data based on classification layers to obtain fused data;

module M2.2: and extracting the data after fusion, discarding redundant parameters caused by data fusion, and performing data conversion.

10. The graphical-based Web security test mission planning system of claim 7, wherein step 3 comprises:

module M3.1: rendering the resource model in a view in a graphical form, constructing a resource model graphical display module, screening the model according to the model type through the resource model graphical display module, and displaying the resource model in a graphical form;

module M3.2: in the resource model graphical display module, a model for Web safety test is dragged to a graphical drawing area of the task planning topology module, and the connection relation between a resource model node and a network link is drawn in the area;

module M3.3: the graphic data processing module classifies, converts and stores the data related to the topological graph;

module M3.4: and in the resource model attribute editing module, checking or editing the related information of the task planning by selecting nodes and links on the topological graph.