CN113300912B - Equipment testing method and device and electronic equipment - Google Patents

Abstract

The invention provides a device testing method, a device and electronic equipment.A server simulates an abnormal data link corresponding to an abnormal identification of a data link and obtains a data embedded point testing result based on a comparison result of embedded point data and preset standard embedded point data corresponding to the abnormal identification of the data link. When the abnormal scene of the data link is simulated, whether the data point burying mode is normal is verified in a mode that whether the result fed back by the server is the preset standard data corresponding to the abnormal identification of the data link. The invention directly tests the data embedded points in the abnormal scene of the data link, so the problem of low accuracy of the data embedded point test caused by the abnormal data link can be avoided.

Description

Equipment testing method and device and electronic equipment

Technical Field

The present invention relates to the field of testing, and in particular, to a device testing method and apparatus, and an electronic device.

Background

Data embedding is a good privatized data acquisition deployment mode. Before the data buried point is used, the data buried point needs to be tested, and the specific test process is as follows: and collecting data collected in a data embedding mode, comparing the data with corresponding standard data, and obtaining a test result of the data embedding mode according to a comparison result.

In the process of data buried point testing, when a data link is abnormal, the data acquired in a data buried point mode is inconsistent with standard data, and at the moment, if the data buried point mode is abnormal, a misjudgment phenomenon occurs, so that the data buried point testing accuracy is low.

Disclosure of Invention

In view of this, the present invention provides a device testing method, an apparatus and an electronic device, so as to solve the problem that when a data link is abnormal, data acquired by a data embedding manner is inconsistent with standard data, and at this time, the data embedding manner is considered to be abnormal, so that the accuracy of data embedding testing is low.

In order to solve the technical problem, the invention adopts the following technical scheme:

a device testing method is applied to a server and comprises the following steps:

acquiring a data link abnormity identifier sent by test case management equipment;

sending an interception instruction to preset interception software, and acquiring a data link acquisition request intercepted by the preset interception software; the data link acquisition request is a request for acquiring a link, which is sent by the tested device when the data buried point test case is executed;

responding to the data link acquisition request, and determining a data link identification return result corresponding to the data link abnormal identification;

sending the data link identification return result to the tested device through the preset interception software so that the tested device executes the test operation corresponding to the data link identification return result;

acquiring data of buried points uploaded by the tested equipment after the test operation is executed and intercepted by the preset interception software, and acquiring a data buried point test result based on a comparison result of the data of buried points and preset standard data of buried points corresponding to the data link abnormal identification.

Optionally, determining that the data link identifier corresponding to the data link abnormal identifier returns a result includes:

sending the data link abnormal identification to a preset database so that the preset database inquires a corresponding relation corresponding to the data link abnormal identification; the preset database stores the corresponding relation between the returned results of the first-stage data link abnormal identification and the data link identification corresponding to the first-stage data link abnormal identification when the data link abnormal identification is the first-stage data link abnormal identification, and the corresponding relation between the returned results of the data link identification corresponding to the normal identification of each stage of data link before the last stage and the returned results of the data link identification corresponding to the normal identification of each stage of data link and the returned results of the data link identification corresponding to the last-stage data link abnormal identification when the data link abnormal identification is the multi-stage data link abnormal identification;

and receiving the corresponding relation returned by the preset database, and determining a data link identification return result corresponding to the primary data link identification from the corresponding relation.

Optionally, sending the data link identifier return result to the device under test through the preset interception software, so that the device under test performs a test operation corresponding to the data link identifier return result, including:

and under the condition that the data link abnormity identification is the primary data link abnormity identification, sending a data link identification return result corresponding to the primary data link abnormity identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedding point test according to the data link identification return result.

Optionally, sending the data link identifier return result to the device under test through the preset interception software, so that the device under test performs a test operation corresponding to the data link identifier return result, including:

under the condition that the data link abnormal identification is the multistage data link abnormal identification, sending a data link identification return result corresponding to the primary data link normal identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedded point test according to the data link identification return result;

acquiring a new data link acquisition request which is acquired by the preset interception software and sent by the tested equipment when the data burying point test is continuously executed;

responding to the new data link acquisition request, and determining a data link identification return result corresponding to the next-level data link identification from the corresponding relation returned by the preset database; the next-level data link identification comprises a next-level data link normal identification or a last-level data link abnormal identification;

and sending a data link identification return result corresponding to the next-level data link identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedded point testing according to the data link identification return result corresponding to the next-level data link identification, and returning a step of acquiring a new data link acquisition request sent by the tested equipment when the data embedded point testing is continuously performed, wherein the step is acquired by the preset interception software, and the step is sequentially performed until the tested equipment continues to perform the data embedded point testing according to a data link identification return result corresponding to the last-level data link abnormal identification.

Optionally, obtaining a data buried point test result based on a comparison result between the data buried point and preset standard data buried point corresponding to the data link abnormal identifier includes:

acquiring preset standard buried point data corresponding to the data link abnormal identification;

and comparing the buried point data with the preset standard buried point data, determining that a data buried point test result is a first identification which is qualified in the characterization test under the condition that the buried point data is the same as the preset standard buried point data, and determining that the data buried point test result is a second identification which is unqualified in the characterization test under the condition that the buried point data is different from the preset standard buried point data.

A device testing apparatus applied to a server, the device testing apparatus comprising:

the identification acquisition module is used for acquiring the data link abnormal identification sent by the test case management equipment;

the request acquisition module is used for sending an interception instruction to preset interception software and acquiring a data link acquisition request intercepted by the preset interception software; the data link acquisition request is a request for acquiring a link, which is sent by the tested device when the data buried point test case is executed;

the result determining module is used for responding to the data link acquisition request and determining a data link identification return result corresponding to the data link abnormal identification;

the test module is used for sending the data link identification return result to the tested equipment through the preset interception software so as to enable the tested equipment to execute the test operation corresponding to the data link identification return result;

and the verification module is used for acquiring data burying point data uploaded by the tested equipment after the test operation is executed and intercepted by the preset interception software, and obtaining a data burying point test result based on a comparison result of the data burying point data and preset standard data burying point data corresponding to the data link abnormal identifier.

Optionally, the result determining module is specifically configured to:

sending the data link abnormal identification to a preset database so that the preset database queries a corresponding relation corresponding to the data link abnormal identification; the preset database stores the corresponding relation between the first-stage data link abnormal identifier and the data link identifier return result corresponding to the first-stage data link abnormal identifier when the data link abnormal identifier is the first-stage data link abnormal identifier, and stores the corresponding relation between the data link identifier return result corresponding to the data link normal identifier of each stage before the last stage and the data link identifier return result corresponding to the data link normal identifier of each stage when the data link abnormal identifier is the multi-stage data link abnormal identifier, and the data link identifier return result corresponding to the data link abnormal identifier of the last stage;

and receiving the corresponding relation returned by the preset database, and determining a data link identification return result corresponding to the primary data link identification from the corresponding relation.

Optionally, the test module is specifically configured to:

and under the condition that the data link abnormity identification is the primary data link abnormity identification, sending a data link identification return result corresponding to the primary data link abnormity identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedding point test according to the data link identification return result.

Optionally, the test module comprises:

the data sending submodule is used for sending a data link identification return result corresponding to the normal identification of the first-level data link to the tested equipment through the preset interception software under the condition that the data link abnormal identification is the multi-level data link abnormal identification, so that the tested equipment continues to execute data embedded point test according to the data link identification return result;

the request acquisition submodule is used for acquiring a new data link acquisition request which is acquired by the preset interception software and sent by the tested equipment when the data embedded point test is continuously executed;

the result determining submodule is used for responding to the new data link acquisition request and determining a data link identification return result corresponding to the next-stage data link identification from the corresponding relation returned by the preset database; the next-level data link identification comprises a next-level data link normal identification or a last-level data link abnormal identification;

the judgment sub-module is used for judging whether the tested equipment continues to execute the data buried point test according to a data link identification return result corresponding to the last-stage data link abnormal identification;

the data sending submodule is further configured to send the data link identifier return result corresponding to the next-stage data link identifier to the device under test through the preset interception software under the condition that the judging submodule judges that the device under test does not continue to perform the data embedded point test according to the data link identifier return result corresponding to the last-stage data link abnormal identifier, so that the device under test continues to perform the data embedded point test according to the data link identifier return result corresponding to the next-stage data link identifier.

An electronic device, comprising: a memory and a processor;

wherein the memory is used for storing programs;

the processor invokes the program and is used to:

acquiring a data link abnormal identifier sent by test case management equipment;

sending an interception instruction to preset interception software, and acquiring a data link acquisition request intercepted by the preset interception software; the data link acquisition request is a request for acquiring a link, which is sent by the tested device when the data buried point test case is executed;

responding to the data link acquisition request, and determining a data link identification return result corresponding to the data link abnormal identification;

sending the data link identification return result to the tested device through the preset interception software so that the tested device executes the test operation corresponding to the data link identification return result;

acquiring data of buried points uploaded by the tested equipment after the test operation is executed and intercepted by the preset interception software, and acquiring a data buried point test result based on a comparison result of the data of buried points and preset standard data of buried points corresponding to the data link abnormal identification.

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

the invention provides a device testing method, a device and electronic equipment.A server simulates an abnormal data link corresponding to an abnormal identification of a data link and obtains a data embedded point testing result based on a comparison result of embedded point data and preset standard embedded point data corresponding to the abnormal identification of the data link. When the abnormal scene of the data link is simulated, whether the data point burying mode is normal is verified in a mode that whether the result fed back by the server is the preset standard data corresponding to the abnormal identification of the data link. The invention directly relates to the data embedded point test in the abnormal scene of the data link, so the problem of low accuracy of the data embedded point test caused by the abnormal data link can be avoided.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a flowchart of a method for testing a device according to an embodiment of the present invention;

fig. 2 is a schematic view of a scenario of an apparatus testing method according to an embodiment of the present invention;

FIG. 3 is a flow chart of another method for testing a device according to an embodiment of the present invention;

fig. 4 is a schematic view of a scenario of another device testing method according to an embodiment of the present invention;

fig. 5 is a schematic view of a scenario of another device testing method according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of an apparatus testing device according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

In the process of data buried point testing, when a data link is abnormal, the data acquired in the data buried point mode is inconsistent with standard data, at the moment, the data buried point mode is considered to be abnormal, but the situation that the data acquired in the data buried point mode is inconsistent with the standard data is caused. At this time, if the data embedding mode is directly considered to have a problem, misjudgment occurs, so that the data embedding test accuracy is low.

In order to solve the above problems, the inventor finds, through research, that if an abnormal scene of a data link can be simulated, and analyzes whether data acquired in a data embedding manner is standard data corresponding to the simulated abnormal scene of the data link in the scene, that is, whether the tested device feeds back data required by the tested device for the simulated abnormal scene of the data link is judged, if yes, the data embedding manner is normal, and if not, the data embedding manner is abnormal, that is, whether the data embedding manner is normal is verified. The invention directly relates to the data embedded point test in the abnormal scene of the data link, so the problem of low accuracy of the data embedded point test caused by the abnormal data link can be avoided.

In addition, the inventor also finds that in practical applications, for example, when a user plays a video scene, situations such as a playing error and a playing page cannot be displayed normally occur, and the reasons for these situations are generally link anomalies.

In order to facilitate the background maintenance personnel to know errors caused by the abnormal links of several layers in time, the abnormal scenes of the data links also need to be simulated, so that the background maintenance personnel can analyze the specific link reasons of the video playing errors in certain scenes through various test data in the abnormal scenes of the data links.

Specifically, on the basis of the above content, the embodiment of the present invention provides an apparatus testing method, which is applied to a server, and specifically, in the embodiment of the present invention, a server is pre-constructed, the server may be a web server, and the server can simulate an abnormal data link scenario, so that a device under test can perform a data embedded point test when a data link is abnormal.

Referring to fig. 1, the device testing method includes:

and S11, acquiring the data link abnormity identification sent by the test case management equipment.

In practical applications, referring to fig. 2, the test case management device may be an RF (test case management) device, and the test cases in the test case management device are divided into two types, one type of test case is a test case executed when the data link is considered to be normal, and the test case is not provided with a corresponding data link exception identifier. Another test case is a test case executed when the data link is abnormal, and a corresponding data link abnormality identifier, such as 404, 500, etc., is preset for the test case. Here, 404 indicates that the server cannot provide correct information or the server cannot return information normally due to unknown reasons when the user browses the web page. Briefly, if a web page is not found or if a web page is lost, a status code is present 404. The web page that appears 404, we call 404 page.

When a user wants to perform data embedding point testing on a tested device in a data link abnormal scene, a test instruction in the data link abnormal scene is sent to the test case management device through user interface UI operation, and the test instruction carries a data link abnormal identifier of the data link abnormal scene to be simulated, such as 404 or 500.

It should be noted that, because the number of layers of data links that need to be requested in different scenes, such as a video playing scene, a shopping scene, etc., several layers of data link anomalies, such as a one-layer data link anomaly, a two-layer data link anomaly, etc., need to be identified in the data link anomaly identification.

After the test case management equipment receives the test instruction, the data link abnormal identification is sent to the server, the server sends an interception instruction to the preset interception software, and the preset interception software is arranged on a gateway or a router corresponding to the tested equipment and can intercept data output by the tested equipment. The preset interception software in this embodiment may be char les software.

In addition, the test case management device issues the test case corresponding to the data link abnormal identifier to the tested device, wherein the tested device may be various terminals, such as a mobile phone, a notebook computer, and the like. After the tested device receives the test case, the test case is executed. It should be noted that, the device under test is preset with a data embedding manner, and the instruction or data generated by the device under test is acquired through the data embedding manner. The test case in this embodiment is to verify whether the data embedding manner set by the device under test is normal, so the test case in this embodiment may be referred to as a data embedding test case.

In practical application, the test case management device can communicate with the database through an interface, and send various data link exception identifiers and response data corresponding to the data link exception identifiers to the database through the interface, so that the database stores data. The response data refers to data which needs to be returned to the tested device so that the tested device can continuously execute the test case.

And S12, sending an interception instruction to preset interception software, and acquiring a data link acquisition request intercepted by the preset interception software.

After receiving the data link abnormal identifier, the server sends an interception instruction to preset interception software, wherein the preset interception software is arranged on a gateway or a router corresponding to the equipment to be detected and can intercept data output by the equipment to be detected.

And the tested device executes the test case after receiving the test case issued by the test case management device. If the test case is a test case in a video acquisition scene, the tested device needs to acquire three layers of data links at the moment to acquire the video.

When acquiring a three-layer data link, layer-by-layer acquisition is needed, namely, a first-layer link is acquired first, a second-layer link is acquired, and a third-layer link is acquired finally.

In practical application, when the device to be tested executes a test case of a test site, a request for acquiring a link is sent, which is referred to as a data link acquisition request in this embodiment.

S13, responding the data link acquisition request and determining the data link identification return result corresponding to the data link abnormal identification.

In practical application, the server has received the data link exception identifier sent by the test case management device, that is, it has been known that the test of the device under test is in an exception data link scenario, so that an exception data link scenario needs to be simulated at this time, and the server has obtained the data link exception identifier from the test case management device.

More specifically, various data link exception identifiers and response data corresponding to the data link exception identifiers are stored in the database in advance, so the server needs to acquire the response data corresponding to the data link exception identifiers from the database according to the data link exception identifiers.

It should be noted that, for a single-layer data link scenario, a complete test case can be executed only by acquiring one layer of data link. The data link acquisition request at this time is a one-layer data link acquisition request.

For a scene with an abnormal multilayer data link, a complete test case can be executed only by acquiring the multilayer data link layer by layer. In this embodiment, the data link acquisition request also refers to a layer link acquisition request. In a multi-layer data link scene, the abnormal scene of the data link of the last layer can be simulated only by ensuring that other data links except the last layer are normal.

For example, if it is verified that the three-layer data link is abnormal, it is necessary to ensure that the first two layers of data links are normal, and then the acquisition of the third layer of data link can be executed, and an abnormal scene of the third layer of data link is simulated.

In another embodiment of the present invention, determining a returned result of the data link identifier corresponding to the data link abnormal identifier may include:

1) and sending the data link abnormal identification to a preset database so that the preset database inquires the corresponding relation corresponding to the data link abnormal identification.

The preset database stores the corresponding relation between the primary data link abnormal identifier and the data link identifier return result corresponding to the primary data link abnormal identifier when the data link abnormal identifier is the primary data link abnormal identifier.

Specifically, when the data link exception identifier is a primary data link exception identifier, only the corresponding relationship between the primary data link exception identifier and the returned result of the data link identifier corresponding to the primary data link exception identifier is stored in the database, and the returned result of the data link identifier corresponding to the primary data link exception identifier is primary data link exception data.

In addition, when the data link abnormal identification is a multi-level data link abnormal identification, the corresponding relationship between the data link identification return result corresponding to each level of data link normal identification before the last level and each level of data link normal identification and the data link identification return result corresponding to the last level of data link abnormal identification is also stored in the database.

Specifically, when the data link abnormal identifier is a multi-level data link abnormal identifier, the data link identifier corresponding to each level of data link normal identifier before the last level returns a result that the data link is normal and the content of the specific data link.

And the data link identifier corresponding to the last-stage data link exception identifier returns a result of data link exception.

And if the corresponding relation is pre-stored in the database, after the server receives a data link acquisition request, the data link abnormal identifier is sent to the preset database, so that the preset database inquires and returns the corresponding relation with the data link abnormal identifier.

2) And receiving the corresponding relation returned by the preset database, and determining a data link identification return result corresponding to the primary data link identification from the corresponding relation.

After the server receives the corresponding relation, a data link identification corresponding to the first-level data link abnormal identification is determined from the corresponding relation and a return result is obtained.

If the data link abnormal identification is the primary data link abnormal identification, the corresponding relation only comprises primary data link abnormal data, and the primary data link abnormal data is directly used as the data link identification corresponding to the primary data link abnormal identification to return a result.

And if the data link abnormal identifier is a multi-level data link abnormal identifier, acquiring a data link identifier return result corresponding to the primary data link normal identifier from the corresponding relation, namely the data link is normal and the content of the specific data link, and taking the data link is normal and the content of the specific data link as the data link identifier return result corresponding to the data link abnormal identifier.

And S14, sending the data link identification return result to the tested device through the preset interception software, so that the tested device executes the test operation corresponding to the data link identification return result.

In practical application, the data link identifier return result is also sent to the tested equipment through the preset interception software, and after the tested equipment receives the data link identifier return result, if the data link identifier return result is primary data link abnormal data, namely, when a primary data link abnormal scene is simulated, the tested equipment can independently execute the test operation corresponding to the data link identifier return result.

If the returned result of the data link identifier is that the data link is normal and the content of the specific data link is simulated, namely the abnormal scene of the multi-level data link is simulated, the tested device and the server cooperate to execute the test operation corresponding to the returned result of the data link identifier.

S15, acquiring data burying point data uploaded by the tested equipment intercepted by the preset interception software after the test operation is executed, and obtaining a data burying point test result based on a comparison result of the data burying point data and preset standard data burying point data corresponding to the data link abnormal identification.

After the tested device executes the test operation, the data of the buried point is uploaded, the data of the buried point is intercepted by using preset interception software at the moment, and after the data of the buried point is obtained, the preset standard data of the buried point (namely the template data in fig. 2) corresponding to the abnormal identifier of the data link is inquired at the moment. It should be noted that, manually, preset standard buried data corresponding to the data link abnormal identifier needs to be preset. If the data link anomaly flag is 404, the predetermined standard buried data corresponding to 404 is 404 error.

The preset standard buried point data corresponding to the data link abnormal identifier in this embodiment may also be stored in the preset database, and at this time, the server needs to obtain the preset standard buried point data from the preset database. In addition, the preset standard buried point data can also be stored in the local of the server, and the server can directly inquire in the local.

In practical applications, step S15 may include:

and acquiring preset standard buried point data corresponding to the data link abnormal identifier, and comparing the buried point data with the preset standard buried point data. The comparison in this embodiment is to compare whether the two data are the same.

And under the condition that the buried point data is the same as the preset standard buried point data, determining that the data buried point test result is a first identifier which represents that the test is qualified, wherein the first identifier can be 0 or qualified.

And under the condition that the buried point data is different from the preset standard buried point data, determining that the data buried point test result is a second identifier which is unqualified in the characterization test, wherein the second identifier can be 1 or unqualified.

The first identifier or the second identifier in this embodiment may be displayed on a display interface of the server, or pushed to the user terminal or the test case management device, so that the user can know the test result (that is, the verification result in fig. 2) in time.

In this embodiment, the server simulates an abnormal data link corresponding to the abnormal identifier of the data link, and obtains a data buried point test result based on a comparison result of the data buried point and preset standard data buried point corresponding to the abnormal identifier of the data link. When the abnormal scene of the data link is simulated, whether the data point burying mode is normal is verified in a mode that whether the result fed back by the server is the preset standard data corresponding to the abnormal identification of the data link. The invention directly relates to the data embedded point test in the abnormal scene of the data link, so the problem of low accuracy of the data embedded point test caused by the abnormal data link can be avoided.

In addition, the invention can analyze the scene code, automatically carry out customized response on the upstream and downstream interfaces, realize various scene simulation of various links, such as video stream link abnormity, and carry out validity check on abnormal buried point data.

In the above embodiment, the step of sending the data link identifier return result to the device under test through the preset interception software so that the device under test executes the test operation corresponding to the data link identifier return result is mentioned, and specifically, the step S14 may include:

and under the condition that the data link abnormity identification is the primary data link abnormity identification, sending a data link identification return result corresponding to the primary data link abnormity identification to the tested equipment through the preset interception software, so that the tested equipment continues to execute the data buried point test according to the data link identification return result.

In other words, in an actual scenario, under the condition that the data link exception identifier is the primary data link exception identifier, it is described that a primary data link exception scenario is simulated. At this time, if the data link identifier corresponding to the first-level data link exception identifier returns a result of the first-level data link exception data, referring to fig. 2, the device under test continues to execute the test case.

It should be noted that the simulation of the exception of the data link in the first layer is simple, and only the exception result of the data link in the first layer needs to be returned to the device to be tested. For an abnormal scenario of a multi-layer data link, the server is required to reply to the acquisition request of each layer of data link. Specifically, referring to fig. 3, step S14 may include:

and S21, under the condition that the data link abnormal identifier is a multi-level data link abnormal identifier, sending a data link identifier return result corresponding to the primary data link normal identifier to the tested device through the preset interception software, so that the tested device continues to perform data embedding point test according to the data link identifier return result.

Specifically, when a multi-layer data link abnormal scene is simulated, it is necessary to ensure that other links before the last layer of data link are normal, specifically referring to fig. 4 and 5, fig. 4 shows that a two-layer data link is abnormal, at this time, it is necessary to ensure that a one-layer data link is normal, fig. 5 shows that a three-layer data link is abnormal, at this time, it is necessary to ensure that a one-layer data link and a two-layer data link are normal.

In the above embodiment, the data link acquisition request intercepted by the preset interception software is a layer of data link acquisition request, and at this time, the data link identifier return result corresponding to the normal identifier of the primary data link is sent to the device to be tested through the preset interception software, so that the device to be tested continues to perform the data embedded point test according to the data link identifier return result.

And S22, acquiring a new data link acquisition request which is acquired by the preset interception software and sent by the tested device when the tested device continues to execute the data buried point test.

After receiving a data link identification return result corresponding to the normal identification of the first-level data link, the tested device continues to execute the test case according to the return result and continues to acquire the next-layer data link. When the last link obtained is a multilayer link, the next link of the multilayer link is obtained until the last abnormal link is obtained.

S23, responding to the new data link acquisition request, and determining a data link identification return result corresponding to the next level data link identification from the corresponding relation returned by the preset database.

The next level data link identification comprises a next level data link normal identification or a last level data link abnormal identification.

When the link obtained last time is a first-layer link, a second-layer link is obtained at the moment, and the server determines a data link identifier return result corresponding to the second-layer data link identifier from the corresponding relation returned from the preset database.

And when the link obtained last time is a multilayer link, obtaining a next-layer link of the multilayer link at the moment, and determining a data link identifier corresponding to the next-layer data link identifier from the corresponding relation returned from the preset database by the server until the last-layer abnormal link is obtained.

It should be noted that, if the simulated two-layer data link is abnormal, the data link identifier corresponding to the two-layer data link abnormal identifier is returned to the device under test.

If the multilayer data link is abnormal in a simulated way, for example, if the multilayer data link is abnormal in three layers, the server returns to the tested equipment a data link identifier return result corresponding to the normal identifier of the two-layer data link and a data link identifier return result corresponding to the abnormal identifier of the three-layer data link in turn.

It should be noted that, when receiving a new data link acquisition request, the server first returns a data link identifier return result corresponding to the normal identifier of the two-layer data link, and when receiving a new data link acquisition request again, returns a data link identifier return result corresponding to the abnormal identifier of the three-layer data link. That is, each data link acquisition request is only used for acquiring a data link identifier return result corresponding to a layer of data link identifier.

And S24, sending the data link identification return result corresponding to the next-level data link identification to the tested device through the preset interception software, so that the tested device continues to perform the data embedding point test according to the data link identification return result corresponding to the next-level data link identification.

Specifically, similar to the above steps, after receiving the data link identifier return result corresponding to the next-stage data link identifier, the device under test continues to perform the data buried point test.

S25, judging whether the tested equipment continues to execute the data embedded point test according to the data link identification return result corresponding to the last level data link abnormal identification; if yes, ending, otherwise, returning to the step of executing S22, and executing sequentially until the tested device continues to execute the data embedding point test according to the data link identifier return result corresponding to the last level data link exception identifier.

Specifically, the device under test sequentially acquires the data link of the first layer and the data link of the second layer … … until the data link of the last layer is acquired, wherein the data links of the other layers are normal except for the abnormality of the data link of the last layer.

And the tested equipment receives the data link identification return result corresponding to the last-stage data link abnormal identification, continues to execute the data buried point test, and uploads the data buried point.

Referring to fig. 4, fig. 4 simulates that the data link of the second layer is abnormal, and the data link of the first layer requested by the device under test is normal. Fig. 4 simulates a three-layer data link anomaly, and the one-layer and two-layer data links requested by the device under test are normal.

In the embodiment, when an abnormal scene of a multilayer data link is simulated, other data links except the last layer of data link are ensured to be normal, and the tested device can execute the data link with the abnormal last layer, so that the simulation and the test of the abnormal data link which is chopped are realized.

In order that those skilled in the art will be able to clearly understand the present invention, it is now explained in terms of a specific scenario.

Assuming the steps required to verify that the server 404 is erroneous:

the test case management equipment sets a scene code in a test case script as an http404 error, the script calls an interface to insert the code into a database to indicate that the case is about to verify 404 the scene, the script is executed, at the moment, a client calls a layer of interface which is hijacked and redirected to the web server, the web server simulates the layer of interface 404 according to the code and returns the layer of interface 404 to the client, the client displays a 404-error page and reports 404-error data embedded points, the 404-error data embedded points are also redirected to the web server, the web server obtains data embedded points, template data in the database are called, operation, screening and comparison are carried out, and a test result is returned.

Optionally, on the basis of the above method for testing a device applied to a server, another embodiment of the present invention provides a device testing apparatus applied to a server, and with reference to fig. 6, the device testing apparatus includes:

an identifier obtaining module 11, configured to obtain a data link exception identifier sent by a test case management device;

the request acquisition module 12 is configured to send an interception instruction to preset interception software, and acquire a data link acquisition request intercepted by the preset interception software; the data link acquisition request is a request for acquiring a link, which is sent by the tested device when the data buried point test case is executed;

a result determining module 13, configured to respond to the data link acquisition request, and determine a data link identifier return result corresponding to the data link abnormal identifier;

the test module 14 is configured to send the data link identifier return result to the device under test through the preset interception software, so that the device under test performs a test operation corresponding to the data link identifier return result;

and the verification module 15 is configured to obtain data burying point data uploaded by the device under test after the test operation is executed, where the data burying point data is intercepted by the preset interception software, and obtain a data burying point test result based on a comparison result of the data burying point data and preset standard data burying point data corresponding to the data link abnormal identifier.

Further, the result determination module is specifically configured to:

sending the data link abnormal identification to a preset database so that the preset database queries a corresponding relation corresponding to the data link abnormal identification; the preset database stores the corresponding relation between the returned results of the first-stage data link abnormal identification and the data link identification corresponding to the first-stage data link abnormal identification when the data link abnormal identification is the first-stage data link abnormal identification, and the corresponding relation between the returned results of the data link identification corresponding to the normal identification of each stage of data link before the last stage and the returned results of the data link identification corresponding to the normal identification of each stage of data link and the returned results of the data link identification corresponding to the last-stage data link abnormal identification when the data link abnormal identification is the multi-stage data link abnormal identification;

and receiving the corresponding relation returned by the preset database, and determining a data link identification return result corresponding to the primary data link identification from the corresponding relation.

Further, the test module is specifically configured to:

and under the condition that the data link abnormity identification is the primary data link abnormity identification, sending a data link identification return result corresponding to the primary data link abnormity identification to the tested equipment through the preset interception software, so that the tested equipment continues to execute the data buried point test according to the data link identification return result.

Further, the test module includes:

the data sending submodule is used for sending a data link identification return result corresponding to the normal identification of the first-level data link to the tested equipment through the preset interception software under the condition that the data link abnormal identification is the multi-level data link abnormal identification, so that the tested equipment continues to execute data embedded point test according to the data link identification return result;

the request acquisition sub-module is used for acquiring a new data link acquisition request which is acquired by the preset interception software and sent by the tested equipment when the data buried point test is continuously executed;

the result determining submodule is used for responding to the new data link obtaining request and determining a data link identification return result corresponding to the next-level data link identification from the corresponding relation returned by the preset database; the next-level data link identification comprises a next-level data link normal identification or a last-level data link abnormal identification;

the judgment submodule is used for judging whether the tested equipment continues to perform data embedded point test according to a data link identification return result corresponding to the last-stage data link abnormal identification;

the data sending submodule is further configured to send the data link identifier return result corresponding to the next-stage data link identifier to the device under test through the preset interception software under the condition that the judging submodule judges that the device under test does not continue to perform the data embedded point test according to the data link identifier return result corresponding to the last-stage data link abnormal identifier, so that the device under test continues to perform the data embedded point test according to the data link identifier return result corresponding to the next-stage data link identifier.

Further, the verification module is specifically configured to:

acquiring preset standard buried point data corresponding to the abnormal identification of the data link, comparing the buried point data with the preset standard buried point data, determining that a data buried point test result is a first identification qualified in the characterization test under the condition that the buried point data is the same as the preset standard buried point data, and determining that the data buried point test result is a second identification unqualified in the characterization test under the condition that the buried point data is different from the preset standard buried point data.

In this embodiment, the server simulates an abnormal data link corresponding to the abnormal data link identifier, and obtains a data buried point test result based on a comparison result between the data buried point and preset standard data buried point corresponding to the abnormal data link identifier. When the abnormal scene of the data link is simulated, whether the data point burying mode is normal is verified in a mode that whether the result fed back by the server is the preset standard data corresponding to the abnormal identification of the data link. The invention directly relates to the data embedded point test in the abnormal scene of the data link, so the problem of low accuracy of the data embedded point test caused by the abnormal data link can be avoided.

It should be noted that, please refer to the corresponding description in the above embodiment for the working process of each module and sub-module in this embodiment, which is not described herein again.

Optionally, on the basis of the device testing method and apparatus applied to the server, another embodiment of the present invention provides an electronic device, including: a memory and a processor;

wherein the memory is used for storing programs;

the processor invokes the program and is used to:

acquiring a data link abnormal identifier sent by test case management equipment;

sending an interception instruction to preset interception software, and acquiring a data link acquisition request intercepted by the preset interception software; the data link acquisition request is a request for acquiring a link, which is sent by the tested device when the data buried point test case is executed;

responding to the data link acquisition request, and determining a data link identification return result corresponding to the data link abnormal identification;

sending the data link identification return result to the tested equipment through the preset interception software so that the tested equipment executes the test operation corresponding to the data link identification return result;

acquiring data of buried points uploaded by the tested equipment after the test operation is executed and intercepted by the preset interception software, and acquiring a data buried point test result based on a comparison result of the data of buried points and preset standard data of buried points corresponding to the data link abnormal identification.

Further, determining a data link identifier return result corresponding to the data link abnormal identifier includes:

sending the data link abnormal identification to a preset database so that the preset database inquires a corresponding relation corresponding to the data link abnormal identification; the preset database stores the corresponding relation between the first-stage data link abnormal identifier and the data link identifier return result corresponding to the first-stage data link abnormal identifier when the data link abnormal identifier is the first-stage data link abnormal identifier, and stores the corresponding relation between the data link identifier return result corresponding to the data link normal identifier of each stage before the last stage and the data link identifier return result corresponding to the data link normal identifier of each stage when the data link abnormal identifier is the multi-stage data link abnormal identifier, and the data link identifier return result corresponding to the data link abnormal identifier of the last stage;

and receiving the corresponding relation returned by the preset database, and determining a data link identification return result corresponding to the primary data link identification from the corresponding relation.

Further, sending the data link identifier return result to the device under test through the preset interception software, so that the device under test performs a test operation corresponding to the data link identifier return result, including:

and under the condition that the data link abnormity identification is the primary data link abnormity identification, sending a data link identification return result corresponding to the primary data link abnormity identification to the tested equipment through the preset interception software, so that the tested equipment continues to execute the data buried point test according to the data link identification return result.

Further, sending the data link identifier return result to the device under test through the preset interception software, so that the device under test performs a test operation corresponding to the data link identifier return result, including:

under the condition that the data link abnormal identification is a multi-stage data link abnormal identification, sending a data link identification return result corresponding to a primary data link normal identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedded point testing according to the data link identification return result;

acquiring a new data link acquisition request which is acquired by the preset interception software and sent by the tested equipment when the data burying point test is continuously executed;

responding to the new data link acquisition request, and determining a data link identification return result corresponding to the next-level data link identification from the corresponding relation returned by the preset database; the next-level data link identification comprises a next-level data link normal identification or a last-level data link abnormal identification;

and sending a data link identification return result corresponding to the next-level data link identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedding point testing according to the data link identification return result corresponding to the next-level data link identification, and returning a new data link acquisition request which is acquired by the preset interception software and sent by the tested equipment when the data embedding point testing continues to be performed, and sequentially performing the steps until the tested equipment continues to perform the data embedding point testing according to a data link identification return result corresponding to the last-level data link abnormal identification.

Further, obtaining a data buried point test result based on a comparison result of the data buried point and preset standard data buried point corresponding to the data link abnormal identifier, including:

acquiring preset standard buried point data corresponding to the data link abnormal identification;

and comparing the buried point data with the preset standard buried point data, determining that a data buried point test result is a first identification which is qualified in the characterization test under the condition that the buried point data is the same as the preset standard buried point data, and determining that the data buried point test result is a second identification which is unqualified in the characterization test under the condition that the buried point data is different from the preset standard buried point data.

In this embodiment, the server simulates an abnormal data link corresponding to the abnormal identifier of the data link, and obtains a data buried point test result based on a comparison result of the data buried point and preset standard data buried point corresponding to the abnormal identifier of the data link. When the abnormal scene of the data link is simulated, whether the data point burying mode is normal is verified in a mode that whether the result fed back by the server is the preset standard data corresponding to the abnormal identification of the data link. The invention directly tests the data embedded points in the abnormal scene of the data link, so the problem of low accuracy of the data embedded point test caused by the abnormal data link can be avoided.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A device testing method is applied to a server, and comprises the following steps:

acquiring a data link abnormity identifier sent by test case management equipment;

sending an interception instruction to preset interception software, and acquiring a data link acquisition request intercepted by the preset interception software; the data link acquisition request is a request for acquiring a link, which is sent by the tested equipment when a data buried point test case is executed; the data buried point test case is a test case corresponding to the data link abnormal identifier;

responding to the data link acquisition request, and determining a data link identification return result corresponding to the data link abnormal identification;

sending the data link identification return result to the tested equipment through the preset interception software so that the tested equipment executes the test operation corresponding to the data link identification return result;

acquiring data of buried points uploaded by the tested equipment after the test operation is executed and intercepted by the preset interception software, and acquiring a data buried point test result based on a comparison result of the data of buried points and preset standard data of buried points corresponding to the data link abnormal identification.

2. The device testing method of claim 1, wherein determining that the data link identifier corresponding to the data link exception identifier returns a result comprises:

sending the data link abnormal identification to a preset database so that the preset database queries a corresponding relation corresponding to the data link abnormal identification; the preset database stores the corresponding relation between the returned results of the first-stage data link abnormal identification and the data link identification corresponding to the first-stage data link abnormal identification when the data link abnormal identification is the first-stage data link abnormal identification, and the corresponding relation between the returned results of the data link identification corresponding to the normal identification of each stage of data link before the last stage and the returned results of the data link identification corresponding to the normal identification of each stage of data link and the returned results of the data link identification corresponding to the last-stage data link abnormal identification when the data link abnormal identification is the multi-stage data link abnormal identification;

and receiving the corresponding relation returned by the preset database, and determining a data link identification return result corresponding to the primary data link identification from the corresponding relation.

3. The device testing method according to claim 2, wherein sending the data link identifier return result to the device under test through the preset interception software, so that the device under test performs a testing operation corresponding to the data link identifier return result, includes:

and under the condition that the data link abnormity identification is the primary data link abnormity identification, sending a data link identification return result corresponding to the primary data link abnormity identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedding point test according to the data link identification return result.

4. The device testing method according to claim 2, wherein the step of sending the data link identifier return result to the device under test through the preset interception software so that the device under test performs a testing operation corresponding to the data link identifier return result includes:

under the condition that the data link abnormal identification is a multi-stage data link abnormal identification, sending a data link identification return result corresponding to a primary data link normal identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedded point testing according to the data link identification return result;

acquiring a new data link acquisition request which is acquired by the preset interception software and sent by the tested equipment when the tested equipment continues to perform data embedded point testing;

responding to the new data link acquisition request, and determining a data link identification return result corresponding to the next-level data link identification from the corresponding relation returned by the preset database; the next-level data link identification comprises a next-level data link normal identification or a last-level data link abnormal identification;

and sending a data link identification return result corresponding to the next-level data link identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedded point testing according to the data link identification return result corresponding to the next-level data link identification, and returning a step of acquiring a new data link acquisition request sent by the tested equipment when the data embedded point testing is continuously performed, wherein the step is acquired by the preset interception software, and the step is sequentially performed until the tested equipment continues to perform the data embedded point testing according to a data link identification return result corresponding to the last-level data link abnormal identification.

5. The device testing method of claim 1, wherein obtaining a data embedded point testing result based on a comparison result of the embedded point data and preset standard embedded point data corresponding to the data link anomaly identifier comprises:

acquiring preset standard buried point data corresponding to the data link abnormal identifier;

and comparing the data burying point with the preset standard data burying point, determining that the data burying point test result is a first identifier which is qualified in the characterization test under the condition that the data burying point is the same as the preset standard data burying point, and determining that the data burying point test result is a second identifier which is unqualified in the characterization test under the condition that the data burying point is different from the preset standard data burying point.

6. A device testing apparatus, applied to a server, includes:

the identification acquisition module is used for acquiring the abnormal identification of the data link sent by the test case management equipment;

the request acquisition module is used for sending an interception instruction to preset interception software and acquiring a data link acquisition request intercepted by the preset interception software; the data link acquisition request is a request for acquiring a link, which is sent by the tested equipment when a data buried point test case is executed; the data buried point test case is a test case corresponding to the data link abnormal identifier;

the result determining module is used for responding to the data link acquisition request and determining a data link identification return result corresponding to the data link abnormal identification;

the test module is used for sending the data link identification return result to the tested equipment through the preset interception software so as to enable the tested equipment to execute the test operation corresponding to the data link identification return result;

and the verification module is used for acquiring data burying point data uploaded by the tested equipment after the test operation is executed and intercepted by the preset interception software, and obtaining a data burying point test result based on a comparison result of the data burying point data and preset standard data burying point data corresponding to the data link abnormal identifier.

7. The device testing apparatus of claim 6, wherein the result determination module is specifically configured to:

sending the data link abnormal identification to a preset database so that the preset database queries a corresponding relation corresponding to the data link abnormal identification; the preset database stores the corresponding relation between the returned results of the first-stage data link abnormal identification and the data link identification corresponding to the first-stage data link abnormal identification when the data link abnormal identification is the first-stage data link abnormal identification, and the corresponding relation between the returned results of the data link identification corresponding to the normal identification of each stage of data link before the last stage and the returned results of the data link identification corresponding to the normal identification of each stage of data link and the returned results of the data link identification corresponding to the last-stage data link abnormal identification when the data link abnormal identification is the multi-stage data link abnormal identification;

and receiving the corresponding relation returned by the preset database, and determining a data link identification return result corresponding to the primary data link identification from the corresponding relation.

8. The device testing apparatus of claim 7, wherein the testing module is specifically configured to:

and under the condition that the data link abnormity identification is the primary data link abnormity identification, sending a data link identification return result corresponding to the primary data link abnormity identification to the tested equipment through the preset interception software, so that the tested equipment continues to perform data embedding point test according to the data link identification return result.

9. The device testing apparatus of claim 7, wherein the testing module comprises:

the data sending submodule is used for sending a data link identification return result corresponding to a primary data link normal identification to the tested equipment through the preset interception software under the condition that the data link abnormal identification is a multi-stage data link abnormal identification, so that the tested equipment continues to perform data embedded point test according to the data link identification return result;

the request acquisition submodule is used for acquiring a new data link acquisition request which is acquired by the preset interception software and sent by the tested equipment when the data embedded point test is continuously executed;

the result determining submodule is used for responding to the new data link obtaining request and determining a data link identification return result corresponding to the next-level data link identification from the corresponding relation returned by the preset database; the next-level data link identification comprises a next-level data link normal identification or a last-level data link abnormal identification;

the judgment submodule is used for judging whether the tested equipment continues to perform data embedded point test according to a data link identification return result corresponding to the last-stage data link abnormal identification;

the data sending sub-module is further configured to send the data link identifier return result corresponding to the next-stage data link identifier to the device to be tested through the preset interception software under the condition that the judging sub-module judges that the device to be tested does not continue to perform the data embedded point test according to the data link identifier return result corresponding to the last-stage data link abnormal identifier, so that the device to be tested continues to perform the data embedded point test according to the data link identifier return result corresponding to the next-stage data link identifier.

10. An electronic device, comprising: a memory and a processor;

wherein the memory is used for storing programs;

the processor calls a program and is used to:

acquiring a data link abnormity identifier sent by test case management equipment;

sending an interception instruction to preset interception software, and acquiring a data link acquisition request intercepted by the preset interception software; the data link acquisition request is a request for acquiring a link, which is sent by the tested equipment when a data buried point test case is executed; the data buried point test case is a test case corresponding to the data link abnormal identifier;

responding to the data link acquisition request, and determining a data link identification return result corresponding to the data link abnormal identification;

sending the data link identification return result to the tested equipment through the preset interception software so that the tested equipment executes the test operation corresponding to the data link identification return result;

acquiring data of buried points uploaded by the tested equipment after the test operation is executed and intercepted by the preset interception software, and acquiring a data buried point test result based on a comparison result of the data of buried points and preset standard data of buried points corresponding to the data link abnormal identification.

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