CN115665172B - Management system of embedded terminal equipment - Google Patents

Abstract

The application relates to a management system and a management method of embedded terminal equipment, which belong to the field of embedded systems and comprise a container interface module, a container configuration module, a network interface module and a mirror image decoding module, wherein the container configuration module, the network interface module and the mirror image decoding module are respectively connected with the container interface module; the container interface module is connected with embedded terminal equipment, a container is configured in the embedded terminal equipment, and the container is used for running a container mirror image; the network interface module is connected with a mirror image construction cloud platform, and the mirror image construction cloud platform is used for constructing a container mirror image. The method has the effect of improving the control force of the container in the embedded system.

Description

Management system of embedded terminal equipment

Technical Field

The present disclosure relates to the field of embedded systems, and in particular, to a management system for an embedded terminal device.

Background

The embedded terminal equipment is provided with a plurality of containers, the containers are provided with container mirror images in a running mode, and an operating system of the terminal equipment provides an operating environment when the containers are used for running the container mirror images. In order to facilitate the container mirror image of the container replacement operation, the task of building the container mirror image is outsourced to the mirror image construction cloud platform, a container manager is configured in the embedded terminal, and the container manager and the mirror image construction cloud platform perform information interaction, so that the container mirror image required by the container replacement is realized.

However, if the container manager and the mirror image construction cloud platform are continuously adopted to perform information interaction to replace the container mirror image required by the container, a plurality of container managers simultaneously access the mirror image construction cloud platform, so that a large amount of transmission space of the mirror image construction cloud platform is occupied, and even the stability of the mirror image construction cloud platform is affected.

Disclosure of Invention

The application provides a management system and a management method of embedded terminal equipment, which have the characteristic of improving the management and control strength of a container in an embedded system.

The first object of the present application is to provide a management system for an embedded terminal device.

The first object of the present application is achieved by the following technical solutions:

a management system of embedded terminal equipment comprises a container interface module, a container configuration module, a network interface module and a mirror image decoding module, wherein the container configuration module, the network interface module and the mirror image decoding module are respectively connected with the container interface module;

the container interface module is connected with embedded terminal equipment, a container is configured in the embedded terminal equipment, and the container is used for running a container mirror image;

the network interface module is connected with a mirror image construction cloud platform, and the mirror image construction cloud platform is used for constructing a container mirror image.

By adopting the technical scheme, the embedded terminal equipment is connected with the mirror image construction cloud platform through the management system, and the management system transmits and exchanges information between the embedded terminal equipment and the mirror image construction cloud platform, so that the plurality of embedded terminal equipment is prevented from being directly connected with the mirror image construction cloud platform, and the plurality of embedded terminal equipment is prevented from frequently accessing the mirror image construction cloud platform. Meanwhile, the management system runs on independent equipment outside the embedded terminal equipment, so that the occupation of resources of the embedded terminal equipment is avoided, and the operation and maintenance configuration cost of the embedded terminal equipment is reduced. In addition, as the management system runs on the independent equipment outside the embedded terminal equipment, the transplanting workload of transplanting the management system software to the embedded terminal equipment is avoided, and the research and development cost of the embedded terminal equipment is reduced. In addition, because the management system software is not required to be transplanted to the embedded terminal equipment, the requirement on the embedded terminal equipment is reduced, the selection and application range of the embedded terminal equipment is enlarged, and the overall management and control cost of the embedded system is reduced.

The present application may be further configured in a preferred example to: the container interface module is arranged in the local area network gateway, and the container configuration module, the network interface module, the mirror image decoding module and the embedded terminal equipment are arranged in the same local area subnet.

By adopting the technical scheme, the container interface module is placed in the local area network gateway, the management system and the embedded terminal equipment are deployed in the same local area subnet, the management system is used as the gateway for the embedded terminal equipment to access the mirror image construction cloud platform, and meanwhile, the management system is used as the execution agent for the mirror image construction cloud platform to issue the command, and the command is forwarded to the embedded terminal equipment in the internal network. That is, in one intranet, only one management system is deployed, so that a plurality of embedded terminal devices can be managed. Only one management system is used to cope with a plurality of embedded terminal devices, which not only saves the cost of managing containers in the embedded system, but also reduces the maintenance cost of the management system in the later period. In addition, the embedded terminal equipment is hidden in the intranet, so that direct attack from the extranet can be avoided, and the safety of the embedded terminal equipment is improved.

The present application may be further configured in a preferred example to: the container configuration module stores basic information of the embedded terminal equipment, wherein the basic information comprises an equipment ID number, a hardware architecture and a software architecture adopted by the equipment and realized functions.

By adopting the technical scheme, the basic information of the embedded terminal equipment is stored in the container configuration module, so that when the image construction cloud platform constructs the container image, the required data can be directly called from the container configuration module without interaction with the embedded terminal equipment, thereby providing guarantee for avoiding a plurality of embedded terminal equipment to frequently access the image construction cloud platform.

The present application may be further configured in a preferred example to: the network interface module comprises a resource transmission interface and an information interaction interface;

the resource transmission interface is used for transmitting the container mirror image and configuration data, wherein the configuration data comprises hardware resources and software resources;

the information interaction interface is used for transmitting a request instruction, and the request instruction comprises a request construction instruction and a request configuration instruction.

By adopting the technical scheme, the resource transmission interface and the information interaction interface are arranged, and the resource transmission interface and the information interaction interface are arranged to transmit different information contents, so that the management system is convenient to manage and control the information sent to the mirror image construction cloud platform.

The present application may be further configured in a preferred example to: the image decoding module is used for decoding the container image and outputting an application program, and hardware resources and software resources are needed to build an operating environment for operating the application program.

By adopting the technical scheme, the image decoding module has the decoding function, so that a management system is convenient to judge whether the container image output by the image construction cloud platform is matched with the embedded terminal equipment or not, namely, when the embedded terminal equipment cannot provide the running environment of an application program, the embedded terminal equipment is not matched with the container image output by the image construction cloud platform, and the container image is not transmitted to the container of the embedded terminal equipment any more, so that the invalid container image is prevented from entering the embedded terminal equipment. It can be seen that the mirror decoder can provide technical support for managing and controlling the containers in the embedded terminal equipment.

The present application may be further configured in a preferred example to: the image decoding module adopts a Hopen OCI image decoder.

The second purpose of the application is to provide a management method of the embedded terminal equipment.

The second object of the present application is achieved by the following technical solutions:

a management method of embedded terminal equipment is realized by adopting a container interface module, and comprises the following steps:

sending a request construction instruction to a mirror image construction cloud platform;

receiving a request configuration instruction and transmitting the request configuration instruction to a container configuration module;

configuration data are obtained and sent to the mirror image construction cloud platform;

receiving a container mirror image output by the mirror image construction cloud platform, and transmitting the container mirror image to a mirror image decoding module;

receiving an application program output by the image decoding module, and matching a target container for the container image according to the application program;

the container image is transferred into the target container.

By adopting the technical scheme, the container interface module is used as an interaction center, the container configuration module, the network interface module, the mirror image decoding module and the embedded terminal equipment which are connected with the container interface module can be mobilized, and the cloud platform is built by mobilizing the mirror image through the network interface module, so that the strength of managing and controlling the containers in the embedded system is ensured.

The present application may be further configured in a preferred example to: the request construction instruction is generated by the container interface module, or generated by the embedded terminal device, or initiated by a user through a user terminal and sent to the container interface module.

By adopting the technical scheme, the method supports three modes for driving the mirror image to build the cloud platform to build the container mirror image: the method comprises the steps of constructing an instruction for a request generated by a container interface module, constructing an instruction for a request generated by embedded terminal equipment, and constructing an instruction for a request generated by a user terminal. From this, three driving modes improve the utility of the present application.

In summary, the present application includes at least one of the following beneficial technical effects:

1. according to the method and the device, the container interface module is used as an interaction center, and the container configuration module, the network interface module and the mirror image decoding module which are connected with the container interface module are mobilized according to the requirements of the embedded terminal equipment, so that the purpose of mirror images of containers required for container transmission in the embedded terminal equipment is achieved, the problem that a cloud platform is built by frequently accessing the mirror images by a plurality of embedded terminal equipment is avoided, and the management and control force of the containers in the embedded system is improved;

2. according to the method, the container interface module is placed in the local area network gateway, the management system and the embedded terminal equipment are deployed in the same local area subnet, the management system is used as the gateway for the embedded terminal equipment to access the mirror image construction cloud platform, and is used as the execution agent for the mirror image construction cloud platform to issue the command, and the command is forwarded to the embedded terminal equipment in the intranet. That is, in one intranet, only one management system is deployed, so that a plurality of embedded terminal devices can be managed. Only one management system is used for coping with a plurality of embedded terminal devices, so that the cost for managing and controlling containers in the embedded system is saved, and the maintenance cost of the management system in the later period can be reduced;

3. the method and the device also support three modes for driving the mirror image to construct the cloud platform to construct the container mirror image, and the three driving modes improve the practicability of the method and the device.

Drawings

FIG. 1 is a schematic diagram of an exemplary operating environment for an embodiment of the present application.

Fig. 2 is a block diagram of an embedded terminal device according to an embodiment of the present application.

Fig. 3 is a diagram of a mirror image construction cloud platform according to an embodiment of the present application.

Fig. 4 is a flowchart of a management method of an embedded terminal device applied to a container interface module according to an embodiment of the present application.

Reference numerals illustrate: 1. an embedded terminal device; 11. a container layer; 12. an interface configuration layer; 13. a real-time operating system layer; 14. a hardware layer; 2. a cloud platform is built by mirror images; 21. a data processing module; 22. a proxy node module; 23. supporting an environmental warehouse; 24. a base mirror warehouse; 25. a safety monitoring module; 3. a container manager; 31. a container interface module; 32. a container configuration module; 33. a network interface module; 34. a mirror image decoding module; 4. and a user terminal.

Detailed Description

For the purposes of making the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

FIG. 1 illustrates an exemplary operating environment in which embodiments of the present application can be implemented. Referring to fig. 1, the operating environment includes an embedded terminal device 1, a mirror build cloud platform 2, a container manager 3, and a user terminal 4. The embedded terminal device 1 performs information interaction with the mirror image construction cloud platform 2 through the container manager 3, and the user terminal 4 is respectively connected with the mirror image construction cloud platform 2 and the container manager 3.

Referring to fig. 2, the embedded terminal device 1 connected to the container manager 3 is provided in plurality, and in this example, only one is shown. The embedded terminal device 1 includes a container layer 11, an interface configuration layer 12, a real-time operating system layer 13, and a hardware layer 14, and the interface configuration layer 12 is connected to the container layer 11, the real-time operating system layer 13, and the hardware layer 14, respectively.

Specifically, the real-time operating system layer 13 stores a plurality of software resources, the hardware layer 14 includes a plurality of hardware resources, the container layer 11 is provided with N containers, and N is a positive integer greater than 2. The container may obtain software resources from the real-time operating system layer 13 and hardware resources from the hardware layer 14 through the interface configuration layer 12, thereby building an operating environment for running the container image. In the application, because the number of the containers in the embedded terminal device 1 is large, in order to improve the efficiency of replacing the container mirror image by the containers in the embedded terminal device 1, the work of building the container mirror image is distributed to the mirror image construction cloud platform 2, and the container mirror image is constructed by the mirror image construction cloud platform 2.

Referring to fig. 3, the mirror build cloud platform 2 includes a data processing module 21, a proxy node module 22, a support environment repository 23, a base mirror repository 24, and a security monitoring module 25. The data processing module 21 is a connection center and is in bidirectional communication with the agent node module 22, the supporting environment warehouse 23, the base mirror warehouse 24 and the security monitoring module 25, respectively.

The proxy node module 22 stores therein a hardware architecture and a software architecture. The supporting environment repository 23 stores hardware files, which refer to the smallest file system required under the hardware architecture, and software files, which refer to the smallest file system required under the software architecture. The hardware architecture and hardware files are collectively referred to as hardware resources, while the software architecture and software files are collectively referred to as software resources. The base image repository 24 stores built models and historically built container images. The data processing module 21 is configured to retrieve a hardware architecture and a software architecture from the proxy node module 22, retrieve a hardware file and a software file from the supporting environment repository 23, retrieve a construction model from the base image repository 24, construct a container image according to the obtained hardware architecture, software architecture, hardware file, software file and construction model, detect security and confidentiality of the container image by the security monitoring module 25, and finally output the container image detected by security by the data processing module 21 to the container manager 3. Or the data processing module 21 retrieves the historical container images stored in the base image repository 24, thereby reducing the amount of computation of image building the cloud platform 2.

Referring to fig. 1, in this example, the container manager 3 is also referred to as a management system, which is a stand-alone device running outside the embedded terminal device. Specifically, the container manager 3 includes a container interface module 31, a container configuration module 32, a network interface module 33, and a mirror decoding module 34. The container interface module 31 is arranged in the local area network gateway, the container interface module 31 is connected with the mirror image construction cloud platform 2 through the network interface module 33, meanwhile, the container interface module 31 is respectively connected with the embedded terminal device 1, the container configuration module 32, the network interface module 33 and the mirror image decoding module 34, and the container interface module 31 is used as an interaction center of each module connected with the container interface module 31, so that information transmission and exchange can be realized. In the present embodiment, the container manager 3 and the embedded terminal device 1 are deployed in the same local subnet.

The container configuration module 32 stores basic information of the embedded terminal device 1, such as a device ID number, a hardware architecture and a software architecture adopted by the device, an implemented function, a security level, a maintenance record, and the like, which are convenient for the container manager 3 to manage data items of the embedded terminal device 1.

The network interface module 33 is connected with the mirror image construction cloud platform 2, and the network interface module 33 comprises a resource transmission interface and an information interaction interface. The resource transmission interface is used for transmitting software resources and hardware resources between the embedded terminal device 1 and the mirror image construction cloud platform 2, and is also used for transmitting the container mirror image output by the mirror image construction cloud platform 2, and in practical application, the resource transmission interface for transmitting the data can be switched according to the requirement of the data. The information interaction interface is used for transmitting various request instructions, such as a request construction instruction, a request configuration instruction, and the like, between the container manager 3 and the mirror image construction cloud platform 2.

The image decoder is a Hopen OCI image decoder, and is used for receiving the container image output by the image construction cloud platform 2, decoding the container image to obtain an application program, a file system of the application program and a specification description file of the container in operation, so that a management system can conveniently judge whether the container image output by the image construction cloud platform 2 is matched with the embedded terminal equipment 1, namely, when the embedded terminal equipment 1 cannot provide an operation environment of the application program, the embedded terminal equipment 1 is not matched with the container image output by the image construction cloud platform 2, and at the moment, the container interface module 31 does not transmit the container image to a container of the embedded terminal equipment 1 any more, thereby avoiding invalid container images from entering the embedded terminal equipment 1. If the embedded terminal device 1 matches the container image output by the image construction cloud platform 2, the container interface module 31 transmits the container image to the container of the embedded terminal device 1, and marks the container as a target container.

In order to facilitate the explanation of the function of the management system, the present application also provides a management method of the embedded terminal device 1, which is mainly applied to the container interface module 31. Referring to fig. 4, the main flow of the management method is described as follows.

Step S1: and sending a request construction instruction to the mirror image construction cloud platform 2.

The request construction instruction is for driving the image construction cloud platform 2 to construct the container image. In the present embodiment, the embedded terminal device 1 may transmit a request construction instruction to the container manager 3 as needed, and then the request construction instruction is transmitted into the image construction cloud platform 2 by the container manager 3. The method can also be initiated by a developer or a user through the user terminal 4, the user terminal 4 can directly send the instruction to the mirror image construction cloud platform 2, or the request construction instruction can be transmitted to the container manager 3, and finally the container manager 3 transmits the request construction instruction to the mirror image construction cloud platform 2. The request construction instructions may also be generated by the container manager 3 and transmitted into the mirror construction cloud platform 2.

The user terminal 4 may be an electronic device such as a mobile phone, a computer, or a tablet.

Step S2: the request configuration instruction is received and transmitted to the container configuration module 32.

The configuration request instruction is a standard when the mirror image construction cloud platform 2 is used for constructing the container mirror image, namely, a hardware architecture, a software architecture, a hardware file, a software file, a function to be realized by the built container mirror image and the like required by the mirror image construction cloud platform 2 when the container mirror image is constructed. Thus, the request configuration instruction is generated by the mirror build cloud platform 2 after receiving the request build instruction.

The network interface module 33 is configured to receive the configuration request instruction output by the mirror image build cloud platform 2, and transmit the configuration request instruction to the container interface module 31, that is, the container interface module 31 receives the configuration request instruction.

The container interface module 31 serves as an interaction center, and when receiving a configuration request instruction, the container interface module transmits the configuration request instruction to the container configuration module 32, and the container configuration module 32 invokes configuration data in the basic information according to the configuration request instruction.

Step S3: and acquiring configuration data and sending the configuration data to the mirror image construction cloud platform 2.

When the container configuration module 32 receives the request configuration instruction, it first determines the reason for generating the request configuration instruction:

when the request configuration instruction is generated by the request construction instruction sent by the embedded terminal device 1, the container configuration module 32 reports the hardware resource and the software resource of the embedded terminal device 1 sending the request construction instruction to the mirror image construction cloud platform 2, that is, generates configuration data and transmits the configuration data to the container interface module 31, and the container interface module 31 transmits the configuration data to the mirror image construction cloud platform 2 through the network interface module 33;

when the request configuration instruction is generated by the request construction instruction generated by the container manager 3 or by the request construction instruction input by the user terminal, the container configuration module 32 reports the hardware resource and the software resource of the embedded terminal device 1 that currently has the need to replace the container image to the image construction cloud platform 2. Likewise, the container configuration module 32 still outputs the reported data as configuration data, and the configuration data is transmitted to the mirror image construction cloud platform 2 by the container interface module 31 through the network interface module 33.

Step S4: the container image output by the image construction cloud platform 2 is received and transmitted to the image decoding module 34.

After the image construction cloud platform 2 obtains the configuration data, the corresponding container image is matched in the base image warehouse 24 according to the hardware resources and the software resources in the configuration data, and if the container image corresponding to the configuration data exists in the base image warehouse 24, the container image is output. Otherwise, when there is no corresponding container image in the base image repository 24, the data processing module 21 will respectively retrieve the hardware architecture and the software architecture from the proxy node module 22, retrieve the hardware file and the software file from the supporting environment repository 23, retrieve the build model from the base image repository 24, build the container image according to the obtained hardware architecture, software architecture, hardware file, software file and build model, then input the built container image into the security monitoring module 25 for detection, and finally output the container image passing the security detection to the network interface module 33.

The network interface module 33 receives the container image, transmits the container image to the container interface module 31, and then transmits the container image to the image decoding module 34 through the container interface module 31, and decompresses the container image through the image decoding module 34.

Step S5: the application program output by the image decoding module 34 is received, and the target container is matched for the container image according to the application program.

As known from the embodiment of the operation environment part, the image decoding module 34 decodes the container image to obtain the application program, and then the container interface module 31 determines whether the container image output by the image construction cloud platform 2 is matched with the embedded terminal device 1, that is, when the embedded terminal device 1 can provide the operation environment of the application program, it is indicated that the embedded terminal device 1 is matched with the container image output by the image construction cloud platform 2, and at this time, the container interface module 31 transmits the container image to the container of the embedded terminal device 1 and marks the container as a target container. Otherwise, it is explained that the embedded terminal device 1 is not matched with the container image output by the image construction cloud platform 2, so that the container image is not output to the embedded terminal device 1 any more.

Step S6: the container image is transferred into the target container.

Finally, after the target container is confirmed, the container interface module 31 transmits the container image to the target container, meanwhile, the container interface module 31 outputs an adjustment instruction to the container configuration module 32, and after the container configuration module 32 receives the adjustment instruction, the basic information stored in the container configuration module is updated, that is, the need of changing the container image of the embedded terminal device 1 to which the target container belongs is switched to be satisfied, so that the embedded terminal device 1 is not included in the list of matching target containers for the next container image.

In summary, the implementation principle of the management method of the embedded terminal device provided in the embodiment of the present application is: firstly, a container manager 3 sends a request construction instruction to a mirror image construction cloud platform 2 so as to drive the mirror image construction cloud platform 2 to construct a container mirror image; then, the container manager 3 receives a request configuration instruction returned by the mirror image construction cloud platform 2, and returns configuration data according to the request configuration instruction, so that the mirror image construction cloud platform 2 can conveniently construct a container mirror image according to the configuration data; finally, the container mirror image generated by the mirror image construction cloud platform 2 is matched with the target container, and the container mirror image is transmitted to the target container, so that the purpose of the container mirror image required for the container transmission in the embedded terminal equipment is achieved, frequent access of a plurality of embedded terminal equipment to the mirror image construction cloud platform is avoided, and the management and control force of the container in the embedded system is improved. In addition, because the management system software is not required to be transplanted to the embedded terminal equipment, the requirement on the embedded terminal equipment is reduced, the selection and application range of the embedded terminal equipment is enlarged, and the overall management and control cost of the embedded system is reduced.

The foregoing description is only of the preferred embodiments of the present application and is presented as a description of the principles of the technology being utilized. It will be appreciated by persons skilled in the art that the scope of the disclosure referred to in this application is not limited to the specific combinations of features described above, but it is intended to cover other embodiments in which any combination of features described above or equivalents thereof is possible without departing from the spirit of the disclosure. Such as the above-described features and technical features having similar functions (but not limited to) disclosed in the present application are replaced with each other.

Claims (4)

1. A management system of embedded terminal equipment is characterized in that: the system comprises a container interface module (31), and a container configuration module (32), a network interface module (33) and a mirror image decoding module (34) which are respectively connected with the container interface module (31), wherein the container interface module (31) is arranged in a local area network gateway, and the container configuration module (32), the network interface module (33), the mirror image decoding module (34) and the embedded terminal equipment (1) are arranged in the same local area subnet;

the container interface module (31) is connected with an embedded terminal device (1), and a container is configured in the embedded terminal device (1) and is used for running a container mirror image;

the network interface module (33) is connected with a mirror image construction cloud platform (2), and the mirror image construction cloud platform (2) is used for constructing a container mirror image;

the container configuration module (32) stores basic information of the embedded terminal equipment (1), wherein the basic information comprises an equipment ID number, a hardware architecture and a software architecture adopted by the equipment and realized functions;

the image decoding module (34) is used for decoding the container image and outputting an application program, and hardware resources and software resources are required for operating the application program to build an operating environment;

the container interface module (31) is configured to:

sending a request construction instruction to a mirror image construction cloud platform (2);

receiving a request configuration instruction and transmitting the request configuration instruction to a container configuration module (32);

configuration data are obtained and sent to the mirror image construction cloud platform (2);

receiving a container mirror image output by the mirror image construction cloud platform (2), and transmitting the container mirror image to a mirror image decoding module (34);

receiving an application program output by the image decoding module (34), and matching a target container for the container image according to the application program;

the container image is transferred into the target container.

2. The management system of an embedded terminal device according to claim 1, wherein: the network interface module (33) comprises a resource transmission interface and an information interaction interface;

the resource transmission interface is used for transmitting the container mirror image and configuration data, wherein the configuration data comprises hardware resources and software resources;

the information interaction interface is used for transmitting a request instruction, and the request instruction comprises a request construction instruction and a request configuration instruction.

3. The management system of an embedded terminal device according to claim 1, wherein: the image decoding module (34) adopts a Hopen OCI image decoder.

4. The management system of an embedded terminal device according to claim 1, wherein: the request construction instruction is generated by the container interface module (31) or by the embedded terminal device (1) or initiated by a user via a user terminal (4) and sent into the container interface module (31).

Images