CN112148164B - Arranging method and device of multi-cluster system, computer equipment and storage medium - Google Patents

Abstract

The embodiment of the invention discloses a method and a device for arranging a multi-cluster system, computer equipment and a storage medium. The method comprises the following steps: receiving a trigger operation for triggering entry into an arrangement page of a target multi-cluster system; and displaying the layout page so as to layout the current multi-cluster layout file of the target multi-cluster system in the layout page, wherein the canvas of the layout page displays application icons of each current single cluster contained in the current multi-cluster layout file by the target multi-cluster system. By adopting the technical scheme, the embodiment of the invention can realize the visual arrangement of the multi-cluster arrangement file of the multi-cluster system, reduce the arrangement difficulty of the multi-cluster arrangement file of the multi-cluster system, further reduce the arrangement difficulty of the multi-cluster system and simplify the arrangement steps of the multi-cluster system.

Description

Arranging method and device of multi-cluster system, computer equipment and storage medium

Technical Field

The present invention relates to the field of multi-cluster technologies, and in particular, to a method and an apparatus for arranging a multi-cluster system, a computer device, and a storage medium.

Background

With the development and the mature date of cloud computing, a plurality of enterprises put services in the cloud, and a multi-cluster system can be more and more applied due to the fact that the multi-cluster system can adapt to the increasingly complicated service requirements and the increasingly large scale of the enterprises.

In the prior art, when arranging a multi-cluster system, generally, an arranging person is required to determine and input each single cluster to be set in the multi-cluster system, and then the arranging person is guided to fill configuration information of each single cluster in the multi-cluster system step by step through a form dialog box, so that a single cluster is created according to the configuration information filled by the arranging person, and the arranging person is guided to create a network communication system to establish communication connection between the single clusters.

However, the conventional multi-cluster system layout method is cumbersome, requires a lot of manpower, and is very prone to errors when filling in configuration contents.

Disclosure of Invention

In view of this, embodiments of the present invention provide a method and an apparatus for arranging a multi-cluster system, a computer device, and a storage medium, so as to simplify operations required when arranging the multi-cluster system.

In a first aspect, an embodiment of the present invention provides a method for arranging a multi-cluster system, including:

receiving a trigger operation for triggering entry into an arrangement page of a target multi-cluster system;

and displaying the layout page so as to layout the current multi-cluster layout file of the target multi-cluster system in the layout page, wherein the canvas of the layout page displays application icons of each current single cluster contained in the current multi-cluster layout file by the target multi-cluster system.

In a second aspect, an embodiment of the present invention provides an arrangement apparatus for a multi-cluster system, including:

the trigger operation receiving module is used for receiving trigger operation for triggering entry of a layout page of the target multi-cluster system;

and the page display module is used for displaying the layout page so as to layout the current multi-cluster layout file of the target multi-cluster system in the layout page, wherein the canvas of the layout page displays application icons of each current single cluster contained in the current multi-cluster layout file by the target multi-cluster system.

In a third aspect, an embodiment of the present invention provides a computer device, including:

one or more processors;

a memory for storing one or more programs,

when the one or more programs are executed by the one or more processors, the one or more processors implement the orchestration method of the multi-cluster system according to the embodiments of the present invention.

In a fourth aspect, an embodiment of the present invention further provides a computer-readable storage medium, on which a computer program is stored, where the computer program, when executed by a processor, implements the method for arranging a multi-cluster system according to the embodiment of the present invention.

The arranging method, the arranging device, the computer equipment and the storage medium of the multi-cluster system provided by the embodiment of the invention receive the triggering operation of triggering the arrangement page entering the target multi-cluster system, display the arrangement page and display the application icons of each current single cluster contained in the current multi-cluster arrangement file of the target multi-cluster system in the canvas of the arrangement page so as to arrange the current multi-cluster arrangement file of the target multi-cluster system in the arrangement page. By adopting the technical scheme, the single cluster in the multi-cluster system is abstracted to the application icon for displaying and arranging in the arrangement page, so that the visual arrangement of the multi-cluster arrangement file of the multi-cluster system can be realized, the difficulty in arranging the multi-cluster arrangement file of the multi-cluster system is reduced, the difficulty in arranging the multi-cluster system is further reduced, the arrangement steps of the multi-cluster system are simplified, and the operation and maintenance cost of the multi-cluster system is reduced.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments made with reference to the following drawings:

fig. 1 is a schematic flowchart of an arrangement method of a multi-cluster system according to an embodiment of the present invention;

fig. 2 is a schematic diagram of an arrangement page of a multi-cluster system according to an embodiment of the present invention;

fig. 3 is a schematic flowchart of an arrangement method of a multi-cluster system according to a second embodiment of the present invention;

fig. 4 is a display interface diagram of an application panel according to a second embodiment of the present invention;

FIG. 5 is a schematic view of a display interface of a parameter panel according to a second embodiment of the present invention;

fig. 6 is a schematic view of a display interface of a second parameter panel according to a second embodiment of the present invention;

fig. 7 is a schematic diagram of a prompt window for switching application versions according to a second embodiment of the present invention;

fig. 8 is a schematic diagram of a parameter detail page according to a second embodiment of the present invention;

fig. 9 is a schematic view of a display interface of a third parameter panel according to the second embodiment of the present invention;

fig. 10 is a block diagram illustrating an arrangement apparatus of a multi-cluster system according to a third embodiment of the present invention;

fig. 11 is a schematic structural diagram of a computer device according to a fourth embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some but not all of the relevant aspects of the present invention are shown in the drawings. In addition, the embodiments and features of the embodiments in the present invention may be combined with each other without conflict.

Example one

The embodiment of the invention provides a method for arranging a multi-cluster system. The method may be performed by an orchestration device of a multi-cluster system, wherein the orchestration device may be implemented by software and/or hardware, and may be configured in a computer device, and typically may be configured in a computer device having a multi-cluster system orchestration function. Fig. 1 is a schematic flowchart of an arrangement method of a multi-cluster system according to an embodiment of the present invention, and as shown in fig. 1, the arrangement method of the multi-cluster system according to this embodiment may include:

s101, receiving a trigger operation for triggering entry of a layout page of the target multi-cluster system.

In this embodiment, the target multi-cluster system can be understood as a multi-cluster system that needs to be arranged currently. The triggering operation may be any operation for triggering entry into the orchestration page of the target multi-cluster system, which may be triggered by the scheduler in any page displayed by the computer device, simply by instructing the computer device to display the scheduled page of the target multi-cluster system, e.g., the triggering operation may be an operation of a scheduler clicking an editor icon of a multi-cluster editor or an operation of triggering entry into a layout page of a corresponding multi-cluster layout file (e.g., an operation of double-clicking a response area of a certain multi-cluster layout file) located in a response area of the corresponding multi-cluster layout file, and accordingly, the computer device may determine that a triggering operation of triggering entry into a layout page of a target multi-cluster system is received when an operation of clicking an editor icon of a multi-cluster editor is monitored or an operation of triggering entry into a layout page of a multi-cluster layout file is monitored in a response area of a certain multi-cluster layout file.

And S102, displaying the layout page to layout the current multi-cluster layout file of the target multi-cluster system in the layout page, wherein the canvas of the layout page displays the application icon of each current single cluster contained in the current multi-cluster layout file by the target multi-cluster system.

The layout file of the target multi-cluster system can be understood as a layout file when the target multi-cluster system performs visual layout, the layout file is a visual configuration file of the target multi-cluster system, and the layout file records, besides all configuration information of the target multi-cluster system, related information of the layout file, which is visually displayed in a layout page, such as the position, the pattern, the size and the like of each application icon in a canvas. Therefore, if the scheduler deletes the application icon of a certain current single cluster displayed in the canvas, the configuration information of the current to-be-clustered can be deleted from the current multi-cluster scheduling file of the target multi-cluster system, and further, when the target multi-cluster system is deployed based on the current multi-cluster scheduling file, the current single cluster originally contained in the target multi-cluster system can be deleted; similarly, if a scheduler adds an application icon of a certain current single cluster to the canvas, when a target multi-cluster system is deployed according to the scheduled current multi-cluster scheduling file, the current single cluster can be added to the target multi-cluster system; when a scheduler connects two application icons displayed in a canvas through an icon connecting line, when a target multi-cluster system is deployed according to a scheduled current multi-cluster schedule file, communication connection can be established between two single clusters corresponding to the two application icons.

In the present embodiment, referring to fig. 2, the layout page may include a navigation bar 21, a canvas 22, an application panel 23 and a parameter panel 24. The navigation bar 21 may be located at the top of the layout page, the navigation bar 21 may be configured to display a system name 211 of the target multi-cluster system and a file name 212 of the current multi-cluster layout file (e.g., a version number corresponding to the current multi-cluster layout file), and a document control 213 may be further disposed in the navigation bar 21, so that when the programmer clicks the document control, the programmer is presented with an explanatory document of the multi-cluster editor. The canvas 22 is a canvas for drawing based on Scalable Vector Graphics (SVG) files, and can be used to display the application icons 221 of each current single cluster in the current multi-cluster layout file of the target multi-cluster system and the icon connecting lines 222 between the application icons, and support the layout personnel to drag the application icons 221 and draw the icon connecting lines 222. The application panel 23 may be used to display the application items 231 of each single cluster for selection by the scheduler. The parameter panel 24 may be used to display configuration information of the target multi-cluster system in the current multi-cluster orchestration file.

Illustratively, when an organizer wants to create a new multi-cluster system or a new multi-cluster layout file for a multi-cluster system, that is, when the organizer wants to create a new multi-cluster layout file, the organizer can click (e.g., click or double click) an editor icon of a multi-cluster editor, open the multi-cluster editor and enter a home page of the multi-cluster editor, further trigger a new control in the home page of the multi-cluster editor, and newly create a new layout file and enter the layout page; correspondingly, when monitoring that the scheduler clicks the editor icon of the multi-cluster editor, the computer device starts the multi-cluster editor and displays the home page of the multi-cluster editor, and when monitoring that the scheduler triggers a new control displayed in the home page of the multi-cluster editor, creates a new multi-cluster scheduling file and switches the currently displayed page to the scheduling page of the multi-cluster scheduling file. Or, the arrangement personnel can create an arrangement file in the arrangement file list of the target multi-cluster system and click the arrangement file to enter the arrangement page of the target multi-cluster system; correspondingly, when the computer device monitors click operation in the response area of the newly-built layout file in the layout file list of the target multi-cluster system, the multi-cluster editor is started and the layout page of the target multi-cluster system is displayed.

When a scheduler wants to schedule some multi-cluster systems, namely when the scheduler wants to schedule an existing multi-cluster scheduling file, an editor diagram of a multi-cluster editor can be clicked, the multi-cluster editor is opened and enters a first page of the multi-cluster editor, and then an import control in the first page of the multi-cluster editor is triggered to import the multi-cluster scheduling file to be scheduled; correspondingly, when monitoring an editor icon of a multi-cluster editor of a motor of a scheduler, the computer device starts the multi-cluster editor and displays a home page of the multi-cluster editor, when monitoring that the scheduler triggers an import control displayed in the home page of the multi-cluster editor, displays an import interface, determines a multi-cluster scheduling file selected by the scheduler in the import interface as a current multi-cluster scheduling file, and switches a current display page to a scheduling page of the current multi-cluster scheduling file. Or, the arrangement personnel can directly click the corresponding multi-cluster arrangement file in the arrangement file list of the target multi-cluster system to enter the arrangement page of the target multi-cluster system; correspondingly, when the computer device monitors click operation in a response area of a certain multi-cluster layout file in the layout file list of the target multi-cluster system, the computer device starts a multi-cluster editor and displays a layout page of the target multi-cluster system.

In this embodiment, the multi-cluster editor may use the open-source React as a rendering engine and use the open-source Mobx for state management. Specifically, after receiving a trigger operation for triggering entry into an arrangement page of a target multi-cluster system, the computer device may render a root node of the arrangement page of the multi-cluster editor and a frame component of the arrangement page through a fact, and mount the frame component on the root node of the arrangement page after rendering of the frame component is completed; after the mounting of the frame component is finished, initializing a canvas based on a preset graphic library, and mounting the canvas on a root node of a layout page; after the canvas is mounted, the computer device may obtain file information (e.g., a file version number of a current multi-cluster arrangement file) of a current multi-cluster arrangement file of the target multi-cluster system, obtain the current multi-cluster arrangement file according to the file information, and import arrangement data in the current multi-cluster arrangement file into the canvas through a global state manager (i.e., a global store), so that the multi-cluster editor renders an application icon of each current single cluster of the target multi-cluster system in the current multi-cluster arrangement file according to the arrangement data in the current multi-cluster arrangement file in the canvas; after the application icon is rendered, the computer device may query all issued single cluster configuration files applied by each single cluster, select a default single cluster configuration file or a single cluster configuration file preset by a scheduler as a current single cluster configuration file of the current single cluster, and store configuration information (such as service information, parameter information, monitoring item information, and the like) of the current single cluster recorded in the current single cluster configuration file into an internal mapping table of the global state manager, so that the global state manager may render configuration information of each current single cluster in a current display page of a parameter panel according to the internal mapping table when the page is switched to a corresponding page, so as to allow the scheduler to view and modify the configuration information.

The description specification of the multi-cluster layout file may be a platform-independent description specification. The elements in the multi-cluster layout file can be mapped to application icons in the canvas, and the connecting lines (i.e. file connecting lines) in the multi-cluster layout file can be mapped to icon connecting lines in the canvas, i.e. the application icons in the canvas can be recorded in the multi-cluster layout file in the form of the elements, and the icon connecting lines in the canvas can be recorded in the multi-cluster layout file in the form of the file connecting lines.

Referring to table 1, the multi-cluster arrangement file may record an element ID and an application ID (e.g., an ID of a corresponding single cluster) of each element, and may further record one or more of an application name (e.g., a name of a corresponding single cluster), a version ID (e.g., a version number of a single cluster configuration file of the corresponding single cluster), an application icon (i.e., identification information of the application icon), a tag name, a deployment sequence, a location coordinate, service information, an environment variable, a monitoring item, and an external dependency (i.e., other single clusters that need to be depended upon during configuration). The multi-cluster layout file may have a start point element ID (i.e., an ID of an element to which a start point is connected) and an end point element ID (i.e., an ID of an element to which an end point is connected) of each file connection line recorded therein.

Table 1 field description

First level field	Second level field	Type (B)	Description of the invention
				elements		Array of elements	Set of all elements
	elem_id	Character string	Element id, unique within the file
					app_id	Character string	Application id
	app_name	Character string	Application name
					version_id	Character string	Version id
	icon	Character string	Id of application icon, url or picture base64 resource
					label	Character string	Custom tag name
	order	Number of	The smaller the number of deployment order indexes, the earlier the deployment is
					x	Number of	X coordinate of element on canvas
	y	Number of	Y-coordinate of element on canvas
					service	Array of elements	Service information list of current application version
	env	Array of elements	Environment variable configuration of current application version
					monitor	Array of elements	Monitoring item configuration of current application version
	links	Object	External dependency configuration for current application versions
				connections		Array of elements	Connecting wire
	from	Character string	Id of starting point element of connecting line
					to	Character string	Id of wire end element

Thus, the mapping table inside the global state manager may record one or more of an application ID, a version list (i.e., a version list of a single cluster configuration file of a corresponding single cluster), a service list of a provided service, an environment variable list, a monitoring item list, and a deployment order of each application icon in the canvas.

It should be noted that, in this embodiment, rendering the frame component by the fact is performed at a virtual DOM level, and initializing the canvas (i.e., instantiating the canvas) is performed at a DOM level, so that the canvas is preferably mounted after the frame component rendered by the fact is mounted; in order to enable the preset graphics library to be applicable to different systems, the preset graphics library is preferably set to be separated from the global state manager in the embodiment, at this time, since the external graphics library is completely operated on the DOM level and separated from the global state manager, after the initialization of the canvas is completed, the canvas interface exposed by the preset graphics library can be decorated into the action class of Mobx, that is, the SVG operation of the canvas is entrusted to the Mobx, so that the Mobx automatically triggers rendering when executing the canvas operation and completely has no invasion to the preset graphics library. The canvas may be implemented based on SVG, canvas, pure DOM, or exact components, which is not limited in this embodiment.

In one embodiment, the method for orchestrating a multi-cluster system may further include: when receiving a layout file selection instruction, displaying a layout file list of the target multi-cluster system, wherein the layout file selection instruction is generated when a layout personnel clicks a layout file selection control in a navigation bar of a layout page; when it is monitored that the target multi-cluster arrangement file in the arrangement file list is switched from an unselected state to a selected state, the target multi-cluster arrangement file is determined as a current multi-cluster arrangement file of the target multi-cluster system, and the content displayed in the arrangement page is updated according to the current multi-cluster arrangement file.

In this embodiment, the target multi-cluster system may have multi-cluster layout files of different versions (e.g., multi-cluster layout files suitable for different scenes), and a scheduler may directly layout and deploy corresponding multi-cluster layout files according to actual requirements.

The layout file selection instruction can be used for instructing the computer device to display a layout file list of the target multi-cluster system, wherein the layout file list can be understood as a list of multi-cluster layout files of the target multi-cluster system, and can be displayed in a drop-down window of the layout file selection control and also can be displayed in other pop-up windows of the layout page; the target layout file list may be recorded with file names and/or version numbers of the respective multi-cluster layout files of the target multi-cluster system, and the following description will take an example in which the respective multi-cluster layout files of the target multi-cluster system are shown in a drop-down window in the form of version numbers. The target multi-cluster arrangement file is a multi-cluster arrangement file which is switched from an unselected state to a selected state in the arrangement file list.

Specifically, the computer device displays an arrangement page of the target multi-cluster system, and maps the related information recorded in the current multi-cluster arrangement file to the arrangement page for display; when the scheduler wants to change the current multi-cluster scheduling file for scheduling, the scheduler clicks a scheduling file selection control 214 (shown in fig. 2) in the navigation bar 21 of the scheduling page; correspondingly, when monitoring the click operation acting on the arrangement file selection control 214 in the navigation bar 21, the computer device determines that an arrangement file selection instruction is received, displays a pull-down window of the arrangement file selection control, and displays the version number of each multi-cluster arrangement file of the target multi-cluster system in the pull-down window; therefore, when the editing personnel wants to edit the multi-cluster editing file of a certain version, the editing personnel can click the display area of the version number of the multi-cluster editing file in the pull-down window; furthermore, when the computer device monitors the click operation in the display area of a certain version number in the pull-down window, if the version number is not the version number of the current multi-cluster layout file displayed in the layout page, the computer device can determine that the multi-cluster layout file corresponding to the version number is switched from the unselected state to the selected state, determine the multi-cluster layout file corresponding to the version number as the current multi-cluster layout file, and map the related content recorded in the current multi-cluster layout file to the layout page for display.

For example, when mapping the related content recorded in the current multi-cluster layout file to a layout page for display, the computer device may first read the data recorded in the current multi-cluster layout file; then controlling a multi-cluster system editor to empty canvas, controlling a global state manager to reset internal data and preloading a part of preset configuration information in the current multi-cluster arrangement file according to data recorded in the current multi-cluster arrangement file; finally, traversing each element and each file connecting line in the current multi-cluster arrangement file, and drawing each element and each file connecting line based on a preset graphic library so as to replace the application icons and the icon connecting lines displayed in the canvas with the application icons and the file connecting lines corresponding to each element in the current multi-cluster arrangement file; and then according to the application version ID of each element, acquiring the configuration information of each application icon in the canvas, and updating the content in the state manager according to the configuration information so as to replace the parameter information displayed by the parameter panel with the related parameter information corresponding to the current multi-cluster arrangement file.

The method for arranging a multi-cluster system provided in the embodiment of the present invention receives a trigger operation for triggering entry into an arrangement page of a target multi-cluster system, displays the arrangement page, and displays, in a canvas of the arrangement page, application icons of each current single cluster included in a current multi-cluster arrangement file of the target multi-cluster system, so as to arrange the current multi-cluster arrangement file of the target multi-cluster system in the arrangement page. By adopting the technical scheme, the single cluster in the multi-cluster system is abstracted to the application icon for displaying and arranging in the arrangement page, so that the visual arrangement of the multi-cluster arrangement file of the multi-cluster system can be realized, the arrangement difficulty of the multi-cluster arrangement file of the multi-cluster system is reduced, the arrangement difficulty of the multi-cluster system is further reduced, the arrangement steps of the multi-cluster system are simplified, and the operation and maintenance cost of the multi-cluster system is reduced.

Example two

Fig. 3 is a flowchart illustrating an arrangement method of a multi-cluster system according to a second embodiment of the present invention. The present embodiment is optimized on the basis of the foregoing embodiment, and further, after the displaying the layout page, the method further includes: receiving a first layout instruction, wherein the first layout instruction is generated when a first dragging operation acting in a layout page is monitored, and a first starting point of the first dragging operation is located in an application panel of the layout page; drawing a first application icon of the application to be drawn displayed at the first start point within a canvas of the layout page, and controlling the first application icon to move within the canvas along with a first control point of the first drag operation.

Further, after the displaying the layout page, the method further includes: receiving a second layout instruction, wherein the second layout instruction is generated when a sliding operation acting in the layout page is monitored, and a sliding starting point and a sliding ending point of the sliding operation are located on icon boundaries of two different application icons in the canvas; and drawing an icon connecting line connecting the two different application icons.

Further, after the displaying the layout page, the method further includes: when an application parameter display instruction is received, displaying configuration items of each current single cluster in a parameter panel of an arrangement page, wherein the application parameter display instruction is generated when an arranger triggers a parameter control in the parameter panel; when a configuration modification instruction is received, displaying a parameter detail interface of a configuration item to be modified so that a configuration worker can modify a parameter value of the configuration item to be modified, wherein the configuration modification instruction is generated when a scheduling worker clicks the configuration item to be modified.

Further, after the displaying the layout page, the method further includes: when a deployment sequence display instruction is received, displaying at least one sequence frame in a parameter panel of an arrangement page, and displaying cluster identifications of current single clusters in corresponding sequence frames according to the deployment sequence of the current single clusters, wherein the deployment sequence display instruction is generated when an arrangement worker triggers a deployment sequence control in the parameter panel; when a second dragging operation in the deployment sequence interface is monitored, moving a target cluster identifier at a second starting point of the second dragging operation along with a second control point of the second dragging operation into a sequence frame to which a termination point of the second dragging operation belongs, so as to adjust the deployment sequence of a current target single cluster corresponding to the target cluster identifier.

Correspondingly, as shown in fig. 3, the method for arranging a multi-cluster system provided in this embodiment may include:

s201, receiving a trigger operation for triggering entry of a layout page of the target multi-cluster system.

And S202, displaying the layout page, and executing S203, S205, S207 or S209 to layout the current multi-cluster layout file of the target multi-cluster system in the layout page, wherein an application icon of each current single cluster contained in the current multi-cluster layout file by the target multi-cluster system is displayed in a canvas of the layout page.

S203, receiving a first layout instruction, wherein the first layout instruction is generated when a first dragging operation acting in a layout page is monitored, and a first starting point of the first dragging operation is located in an application panel of the layout page.

S204, drawing a first application icon of the application item to be drawn displayed at the first starting point in the canvas of the layout page, controlling the first application icon to move in the canvas along with the first control point of the first dragging operation, and ending the operation.

In this step, as shown in FIG. 2, the first orchestration instruction may be used to instruct the computer device to add a new application icon to the canvas 22 and move it to a position corresponding to the first orchestration instruction. The first drag operation may be a drag operation having a start point located within the application panel 23 of the layout page and an end point located within the canvas 22; the first control point may be a touch point or a cursor point of the first drag operation; the first application icon is an application icon of an application item (i.e., an application item to be drawn) at the first drag operation start point position. An application panel 23 is arranged in the arrangement page, and the application panel 23 can divide the platform depending on the single cluster corresponding to each displayed application item 231 into a cloud application panel and an integrated application code, so that Software as a Service (SaaS) single-cluster application items developed by cluster Service providers outside an enterprise can be displayed in the integrated application panel, such single cluster can be accessed through a Uniform Resource Locator (URL) and can be integrated with a multi-cluster system through an interface; and displaying the application items of other single clusters except the SaaS single cluster in the cloud application panel. At this time, correspondingly, the orchestrator may instruct the computer device to display the cloud application panel by clicking on the cloud application control 25 located at one side of the orchestration page, and may instruct the computer device to display the integrated application panel by clicking on the integrated application control 26 located at one side of the orchestration page. The application panel 23 may be automatically displayed when the currently displayed page of the computer device is switched from another page to the orchestrated page, or may be displayed after the orchestrator clicks a corresponding control (e.g., the cloud application control 25 or the integrated application control 26).

For example, please continue to refer to fig. 2 (fig. 2 takes a cloud application panel as an example), the application panel 23 may be displayed on an upper layer of the canvas in a form of a floating window, and a plurality of application items 231 of a single cluster may be displayed in the application panel 23, where the application items may be understood as identification information of the corresponding single cluster, such as an application icon and a name of the single cluster, so that the scheduler may add the application icon of the single cluster corresponding to the application item 231 in the canvas in a manner of dragging the application item 231 displayed in the scheduling panel, and further add an element corresponding to the single cluster in the current multi-cluster scheduling file. In addition, a filter control 232, a search box 233 and a panel closing control 234 may be further displayed in the application panel 23, and when the scheduler clicks on the filter control 232, the computer device may be instructed to pop up the filter condition list 235, as shown in fig. 4, so that when the scheduler clicks on a certain filter condition in the filter condition list 235, the application 231 displayed in the application panel may be switched to an application of a single cluster meeting the filter condition; when the scheduler enters a keyword in the search box 233 and triggers (e.g., clicks) a search control (not shown) in the search box, the computer device may search for and display an application corresponding to the keyword in the application panel 23; when the scheduler clicks on the panel close control 234 in the application panel 23, the computer device may be instructed to close the application panel 23. The filtering conditions may be set according to the purpose of the single cluster, for example, the filtering conditions may include at least one of total data, big data, databases, middleware, containers, research, development, operation, maintenance, security management, enterprise management, internet of things, and artificial intelligence.

Specifically, the computer device displays an application panel in the layout page; dragging the application items of the corresponding single clusters in the application panel when a scheduler wants to add a new application icon to the canvas, namely, when a new single cluster is added to the target application system; correspondingly, when the dragging operation of the orchestrator, the starting point of which is located in the application panel, and the starting point of the dragging operation is located in the display area of an application item in the application panel, the computer device draws the first application icon of the application item, controls the first application icon to move along with the first control point of the first dragging operation, and controls the first application icon to stop moving when the first application icon moves to the end point of the first dragging operation, that is, when the orchestrator finishes dragging. When the termination point of the first dragging operation is located outside the canvas, the first application icon can be controlled to move to the intersection point position of the moving track of the first dragging operation and the canvas boundary and then stop moving; the first application icon may also be directly no longer displayed in the canvas, that is, the first application icon already drawn in the canvas is deleted, which is not limited in this embodiment.

In one embodiment, if a dependent cluster exists in a first current single cluster corresponding to the first application icon, drawing the dependent application icon of the dependent cluster in the canvas, and controlling the dependent application icon to move along with the first application icon in the canvas, wherein the dependent application icon is connected with the first application icon through an icon connecting line.

In the foregoing embodiment, since the single cluster corresponding to the application icon dragged into the canvas may need to rely on other single clusters when providing services, when the scheduler drags the first application icon into the canvas, it may be determined whether the first current single cluster needs to rely on other single clusters when providing services, that is, it may be determined whether the first current single cluster has a dependent cluster, if it is determined whether the external dependent field of the element corresponding to the first application icon in the current multi-cluster scheduling file is not empty, if so, the first application icon and the dependent application icon are simultaneously drawn, the first application icon and the dependent application icon are connected by an icon connecting line, and the first control point of the first application icon and the dependent application icon along with the first dragging operation is synchronously controlled to move to the termination point of the first dragging operation within the canvas (as shown in fig. 5, fig. 5 takes the first application icon as the application icon corresponding to the cluster name 13 and the dependent application icon as the application icon corresponding to the cluster name 14 as an example), for example, when moving, the center of the first application icon, the center of the dependent icon or the center of the whole composed of the first application icon and the dependent icon is controlled to overlap with the first control point; and if not, drawing the first application icon and controlling the first application icon to move to the termination point of the first dragging operation along with the first control point of the first dragging operation in the canvas. The first current single cluster is a single cluster corresponding to the first application icon, the dependent cluster is a single cluster which the first current single cluster needs to depend on when providing services, and the dependent application icon is an application icon of the dependent cluster.

In one embodiment, if an original application icon identical to the first application icon exists within the canvas, displaying an adjustment prompt window; when an adjusting instruction is received, the first application icon and the original application icon are adjusted into one application icon, the adjusting prompt window is closed, and the adjusting instruction is generated when a scheduler triggers an adjusting control in the adjusting prompt window; and when a rejection instruction is received, closing the adjustment prompt window, wherein the rejection instruction is generated when the scheduling personnel triggers a rejection control in the adjustment prompt window.

In this embodiment, since only one same single cluster is generally deployed in one multi-cluster system to provide the service of the single cluster, when the scheduler adds the first current single cluster to the target multi-cluster system, if the target multi-cluster system is already provided with one same single cluster (i.e., the cluster IDs are the same), the scheduler may be prompted to reduce the redundancy of the target multi-cluster system on the premise of implementing the function of the target multi-cluster system.

Specifically, after the first dragging operation is completed, acquiring an application ID of the first application icon, determining whether an original application icon with the application ID being the same as that of the first application icon exists in the canvas, and if not, not popping up an adjustment prompt window; and if so, popping up an adjustment prompt window to prompt that the same icon exists in the canvas through the adjustment prompt window. Therefore, if the scheduler wants to combine the same first application icon and the original application icon in the canvas into one, the scheduler can trigger (for example, click or drag) the adjustment control in the adjustment prompt window; if the scheduler wants to simultaneously reserve the first application icon and the original application icon in the canvas, the adjustment of the rejection control in the prompt window may be triggered. Correspondingly, when monitoring that the scheduler triggers an adjusting control in the adjusting prompt window, the computer equipment confirms that the adjusting instruction is received, adjusts the first application icon and the original application icon into one application icon, and closes the adjusting prompt window; and when monitoring that the scheduler triggers a rejection control in the adjustment prompt window, the computer equipment confirms that the rejection instruction is received and closes the adjustment prompt window.

In the above embodiment, the manner of adjusting the first application icon and the original application icon into one application icon may be selected as needed, for example, the first application icon may be deleted, the icon connecting line connected to the first application icon may be adjusted to be connected to the original application icon, the original application icon may be deleted, the icon connecting line connected to the original application icon may be adjusted to be connected to the first application icon, or the first application icon and the original application icon may be deleted at the same time, a new application icon identical to the first application icon may be drawn at another position of the canvas (for example, a midpoint of the connecting line between the original application icon and the first application icon), and the icon connecting line connected to the first application icon or the original application icon may be adjusted to be connected to the new application icon, and so on, this embodiment does not limit this.

In one embodiment, after said displaying said layout page, further comprising: and when a position moving instruction is received, controlling the target application icon to move in the canvas along with a target control point of the target dragging operation, wherein the position moving instruction is generated when the target dragging operation acting on the target application icon in the canvas is monitored.

The position moving instruction may be used to instruct the computer device to move a position of a target application icon displayed in the canvas, where the target application icon is an application icon located at a starting position of the target dragging operation, and accordingly, the target dragging operation may be an operation in which a starting point of the dragging trajectory is located in the canvas and the starting point is located in a display area of the target application icon.

In this embodiment, the scheduler may also change the display position of the application icon in the canvas by dragging. Specifically, when the position of an application icon displayed in the canvas is to be adjusted, the scheduler drags the application icon; correspondingly, when the computer device monitors the dragging operation of an application icon in the canvas, the computer device controls the application icon to move to the termination point of the dragging operation along with the control point of the dragging operation, for example, when the computer device monitors the dragging operation of a scheduler, the computer device modifies corresponding data recorded in the global state manager, such as the display coordinates of the application icon recorded by the global state manager; therefore, when the data transmission in the global state manager changes, the multi-cluster editor renders the application icon at a new display coordinate again to change the display position of the application icon. When the termination point of the target dragging operation is positioned outside the canvas, the target application icon can be controlled to move to the intersection point position of the dragging track of the dragging operation and the canvas boundary; the target application icon may also be moved to its position before the orchestrator drags, i.e., the start point of the dragging trajectory.

S205, receiving a second arranging instruction, wherein the second arranging instruction is generated when the sliding operation acting in the arranging page is monitored, and the sliding starting point and the sliding ending point of the sliding operation are located on the icon boundaries of two different application icons in the canvas.

And S206, drawing an icon connecting line connecting the two different application icons, and ending the operation.

Wherein the second orchestration instruction may be used to instruct the computer device to draw a connecting line for connecting some two icons displayed in the canvas, i.e. an icon connecting line. The icon connecting line may be a straight line or a curved line with or without an arrow, and preferably may have an arrow, and the arrow may be located at the end point of the icon connecting line and point to the icon at the end point position, so as to facilitate the scheduler to determine the drawing direction of the target connecting line, at this time, when drawing the icon connecting line between a certain application icon and its dependent application icon, the arrow of the icon connecting line may point to the dependent application icon of the application icon, so that the scheduler determines the dependency relationship between the application icon and the dependent application icon through the arrow direction of the icon connecting line between the two.

Specifically, when two application icons displayed in the canvas are to be connected, the scheduler can select the icon connecting line of the corresponding model and slide from the boundary position of one application icon to the boundary position of the other application icon to be connected; correspondingly, when the computer device monitors the sliding operation after the arrangement personnel selects the icon connecting line with the corresponding model, the computer device draws the icon connecting line with the model selected by the arrangement personnel by taking the starting point of the sliding operation as the starting point, and controls the terminal point of the icon connecting line to move along with the control point of the sliding operation until the arrangement personnel finishes the sliding operation, so that when the arrangement personnel stops sliding at the boundary position of another application icon to be connected, the icon connecting line connecting the two application icons can be obtained. Wherein, the icon connecting lines of different models can have different shapes, different colors and/or different widths, etc.

And S207, when an application parameter display instruction is received, displaying the configuration items of each current single cluster in a parameter panel of the layout page, wherein the application parameter display instruction is generated when a scheduler triggers a parameter control in the parameter panel.

The application parameter display instruction may be used to instruct the computer device to display, in the parameter panel of the layout page, configuration information of a current single cluster corresponding to each application icon in the canvas, that is, instruct the computer device to switch the current display content of the parameter panel to the configuration item of the single cluster corresponding to each application icon in the canvas. The configuration item of a certain current single cluster can be understood as the configuration information of the current single cluster.

In this embodiment, as shown in fig. 2, the parameter panel 24 may include a control area 241 for displaying a control and a parameter area 242 for displaying a corresponding parameter, where a service control 2411, a parameter control 2412, a monitoring control 2413, and a deployment order control 2414 may be displayed in the control area, so that a scheduler may control a computer device to display service information, such as a service port, of each current single cluster in the parameter area 242 of the parameter panel 24 by triggering the service control 2411; controlling the computer device to display the parameter information of each current single cluster, namely the configuration items of each current single cluster, in the parameter area 242 of the parameter panel 24 by triggering the parameter control 2412; controlling the computer device to display the monitoring items of each current single cluster in the parameter area 242 of the parameter panel 24 by triggering the monitoring control 2413; and controls the computer device to display the deployment order of each current single cluster within the parameter area 242 of the parameter panel 24 by triggering a deployment order control 2414. Here, when the scheduler does not trigger any control in the control area, the computer device may default to display the service information of each current single cluster in the parameter area 242 of the parameter panel 24; when the computer device displays the service information, the configuration item or the monitoring item in the parameter area 242, a new frame may be further displayed for the user to add new service information, configuration item or monitoring item.

Specifically, when looking over or modifying the configuration information of one or more current single clusters, the scheduler triggers a parameter control in a parameter panel; correspondingly, when monitoring that the scheduler triggers the parameter control in the parameter panel, the computer device determines that the application parameter display instruction is received, and updates the content displayed in the parameter area of the parameter panel to the configuration item of each current single cluster corresponding to each application icon in the canvas, as shown in fig. 6. The configuration item of a certain current single cluster can be determined based on the current single cluster configuration file of the current single cluster.

In one embodiment, when a configuration file selection instruction is received, displaying a configuration file list of a second current single cluster corresponding to a second application icon, wherein the configuration file selection instruction is generated when a scheduler clicks a configuration file selection control of the second application icon; when it is monitored that the target single cluster configuration file in the configuration file list is switched from an unselected state to a selected state, determining the target single cluster configuration file as a current single cluster configuration file of the second current single cluster, and updating the configuration item of the second current single cluster displayed in the application parameter interface according to the current single cluster configuration file.

In this embodiment, the current single cluster in the canvas may have different versions of single cluster configuration files (e.g., single cluster configuration files suitable for different scenes), and the scheduler may change the single cluster configuration file of the current single cluster in the canvas according to actual requirements.

The second application icon is an application icon corresponding to the configuration file selection control clicked by the scheduler at the current moment in the canvas, and correspondingly, the second current single cluster is a single cluster corresponding to the second application icon. The configuration file selection instruction may be used to instruct the computer device to display a configuration file list of a second current single cluster corresponding to the second application icon, where the configuration file list may be understood as a list of a single cluster configuration file of the second current single cluster, and may be displayed in a drop-down window of a configuration file selection control of the second application icon, or may be displayed in other pop-up windows of the layout page; the configuration file list may record a file name and/or a version number of each single cluster configuration file of the second current single cluster, and the following description will take an example in which each single cluster configuration file of the second current single cluster is shown in a drop-down window in the form of a version number. The target single cluster configuration file is a single cluster configuration file which is switched from an unselected state to a selected state in the configuration file list.

Specifically, referring to fig. 5 (fig. 5, taking the second application icon 223 as the application icon corresponding to the cluster name 14 as an example), the computer device displays the application icon 221 of each current single cluster to the scheduler in the canvas; when the scheduler wants to adjust the current single cluster configuration file of a current single cluster (i.e. a second current single cluster), the scheduler may adjust the application icon (i.e. the second application icon 223) of the current single cluster to a selected state, for example, click the application icon of the current single cluster. Accordingly, when the computer device monitors the trigger operation of adjusting the second application icon 223 to the selected state, the configuration file selection control 2231 of the second application icon is displayed at a set position (e.g., an upper side, a lower side, a left side, or a right side, etc.) of the second application icon. Thus, the scheduler may click on the profile selection control 2231 of the second application icon and select the version number of the single cluster profile to be adjusted in the popped-up drop-down window. When monitoring that an orchestrator clicks the configuration file selection control 2231 of the second application icon, the computer device determines that a configuration file selection instruction is received, displays a configuration file list of the second single cluster, and when monitoring that the orchestrator selects a trigger operation of a certain version number in the configuration file list, determines that the single cluster configuration file corresponding to the version number is switched from an unselected state to a selected state if the version number is not the version number of the current single cluster configuration file of the second single cluster, determines the single cluster configuration file corresponding to the version number as the current single cluster configuration file, and maps related content recorded in the current single cluster configuration file into parameter codes of an orchestration page for display; or when it is determined that the single cluster configuration file corresponding to the version number is switched from the unselected state to the selected state, the switching application version prompt window 2232 is displayed, as shown in fig. 7, when it is monitored that the scheduler clicks the confirmation control 2233 in the switching application version prompt window, the single cluster configuration file corresponding to the version number is determined as the current single cluster configuration file, and the related content recorded in the current single cluster configuration file is mapped into the parameter code of the scheduling page for display, and correspondingly, when it is monitored that the scheduler clicks the cancel control 2234 in the switching application version prompt window, the current single cluster configuration file of the second current single cluster is not switched.

S208, when a configuration modification instruction is received, displaying a parameter detail interface of the configuration item to be modified so that a configuration worker can modify the parameter value of the configuration item to be modified, and ending the operation, wherein the configuration modification instruction is generated when the configuration worker clicks the configuration item to be modified.

The configuration item to be modified can be understood as a configuration item whose parameter value is to be modified or checked by the scheduler. The configuration modification instructions may be used to instruct the computer device to display a parameter detail interface for the configuration item to be modified.

Specifically, the computer device displays the configuration items of each current single cluster to the scheduler in the parameter panel of the scheduling page, as shown in fig. 6; when looking over or modifying the parameter value of a certain configuration item of a certain current single cluster, a scheduler can click the display area of the configuration item; correspondingly, when it is monitored that the scheduler clicks a display area of a certain configuration item in the parameter panel, the computer device switches the current display interface of the parameter panel to the parameter detail interface of the configuration item, as shown in fig. 8, displays the parameter value of the configuration item in the parameter detail page, and when a modification operation for modifying the parameter value of the parameter to be modified, which is triggered by the scheduler, is monitored, modifies the parameter value of the configuration item based on the modification operation of the scheduler.

S209, when a deployment sequence display instruction is received, displaying at least one sequence frame in a parameter panel of the layout page, and displaying the cluster identifier of each current single cluster in the corresponding sequence frame according to the deployment sequence of each current single cluster, wherein the deployment sequence display instruction is generated when a scheduler triggers a deployment sequence control in the parameter panel.

Referring to fig. 5, the sequence frame 243 may be understood as a display frame for representing a deployment sequence of each cluster identifier displayed inside the display frame in the target multi-cluster system, that is, the deployment sequence of each current single cluster is a sequence of a sequence frame to which the cluster identifier belongs in a sequence frame sequence, that is, when the target multi-cluster system is deployed, the current single cluster corresponding to the cluster identifier in the sequence frame with the priority of the deployment sequence frame sequence being the top one. Correspondingly, after adding an application icon of a current single cluster with a dependent cluster and an application icon of the dependent cluster in the canvas, the cluster identifier of the dependent cluster may be automatically added to one sequential frame, and the cluster identifier of the current single cluster may be added to another sequential frame located after the sequential frame, as shown in fig. 5, each sequential frame 243 may be provided with its sequence number in the sequence of the sequential frames, and when the cluster identifier is included, the sequential frame 243 may be displayed in a form of a solid line (that is, the boundary line of the sequential frame is a solid line); when the sequence frame 243 does not include the cluster identifier, the sequence frame 243 may be displayed in a form of a dotted line, after the computer device displays the sequence frame including the cluster identifier, a set number (e.g., 1 or 2, etc.) of empty sequence frames not including the cluster identifier may be further displayed after the sequence frame including the cluster identifier, so that the scheduler adjusts the deployment sequence of each current single cluster, and accordingly, after the scheduler drags a certain cluster identifier into a certain empty sequence frame, the boundary line of the sequence frame is switched from the dotted line to implement. The cluster identifier may be understood as identification information capable of a single cluster, such as an application icon and/or a cluster name of the single cluster. The deployment sequence display instructions may instruct the computer device to display the deployment sequence of each current single cluster in the form of sequence box 243 for viewing and adjustment by the scheduler.

Specifically, when the arrangement personnel want to view or adjust the deployment sequence of each current single cluster, the arrangement personnel triggers a deployment sequence control in the parameter panel; correspondingly, when monitoring that deployment sequence control is triggered by the scheduler, the computer device displays each sequence frame in the parameter panel of the scheduling page according to the sequence of the current single cluster represented by each sequence frame, and displays the cluster identifier of the corresponding current single cluster in each sequence frame.

S210, when a second dragging operation in the deployment sequence interface is monitored, moving a target cluster identifier at a second starting point of the second dragging operation to a sequence frame to which a termination point of the second dragging operation belongs along with a second control point of the second dragging operation so as to adjust the deployment sequence of the current target single cluster corresponding to the target cluster identifier.

The target cluster identifier is a cluster identifier dragged by the second dragging operation; the second control point may be a touch point or a cursor that triggers generation of the second drag operation.

In this embodiment, the orchestrator may adjust the deployment sequence of the current single cluster in the target multi-cluster system by adjusting the sequence frame to which the cluster identifier of the current single cluster belongs, as shown in fig. 5. For example, when the scheduler wants to adjust the deployment sequence of a certain current single cluster, the cluster identifier of the current single cluster may be dragged from the initially located sequence frame to the sequence frame corresponding to the sequence to be adjusted; correspondingly, when monitoring the second dragging operation of the orchestrator, the computer device may control the cluster identifier at the starting point of the second dragging operation to move along with the second control point of the second dragging operation to the sequential frame where the ending point of the second dragging operation is located, as shown in fig. 9, where fig. 9 takes the cluster identifier to which the dragging cluster name 3 belongs as an example. At this time, when the termination point of the second dragging operation is not located in any sequential frame, the cluster identifier dragged by the second dragging operation may be moved into a preset sequential frame, such as moving the cluster identifier back into the sequential frame in which the cluster identifier was located before dragging or the sequential frame closest to the termination point of the second dragging operation, and so on.

In one embodiment, the arrangement information recorded in the current multi-cluster arrangement file is updated, and the updated current multi-cluster arrangement file is saved; and when a deployment instruction is received, deploying the target multi-cluster system according to the updated current multi-cluster layout file, wherein the deployment instruction is generated when a scheduler clicks a deployment control in the layout page.

In the above embodiment, when the scheduler triggers a scheduling operation in the scheduling page, for example, when the triggering operation of adding a new application icon to the canvas, deleting one or more application icons from the canvas, adjusting the display position of an application icon in the canvas, or adjusting the value of a configuration item displayed in a parameter panel or the deployment sequence of each current single cluster is triggered, the changed information in the scheduling page may be automatically updated to the current multi-cluster scheduling file, and the updated current multi-cluster scheduling file may be stored, so as to avoid the occurrence of a situation that the scheduler needs to frequently click on the storage, and avoid a large amount of useless computations. In addition, the current limiting processing can be carried out on the storage interface, and the pressure of the multi-cluster system editor on the back end is reduced. Specifically, an auto mechanism of Mobx may be used, after the components of the multi-cluster system editor are mounted, a handle of the auto is registered, and when an orchestrator triggers an orchestration operation in an orchestration page, observable data in the global state manager changes; when internal observable data changes, the global state manager can acquire a current multi-cluster arrangement file before the observable data changes and a current multi-cluster arrangement file after the observable data changes, compare whether the data recorded by the current multi-cluster arrangement file and the data recorded by the observable data change are different, and if so, call the saving interface to execute the autorun, thereby indirectly executing the saving action of the multi-cluster system editor and saving the updated current multi-cluster arrangement file; if not, the autorun can be executed.

In the above embodiment, referring to fig. 2, a deployment control 215 may be disposed in the navigation bar, and when an orchestrator intends to deploy a target multi-cluster system according to an updated current multi-cluster orchestration file, the orchestrator may click on the deployment control 215; correspondingly, when monitoring that the deployment control 215 is clicked by the scheduler, the computer equipment confirms that the deployment instruction is received, and deploys the target multi-cluster system according to the current multi-cluster scheduling file; or after the deployment instruction is confirmed to be received, the configuration information of the target multi-cluster system can be firstly displayed to the arrangement personnel for the arrangement personnel to adjust and confirm, and after the arrangement personnel clicks the confirmation control, the target multi-cluster system is deployed according to the current multi-cluster arrangement file. Therefore, automatic deployment of the multi-cluster system is realized, labor cost is reduced, and the condition that manual repeated operation is prone to error is avoided.

In addition, when the arrangement personnel finishes arranging the current multi-cluster arrangement file of the target multi-cluster system, the current multi-cluster arrangement file can be exported, and the exported current multi-cluster arrangement file can be further released to an application mall to be downloaded and used by other personnel.

The arranging method of the multi-cluster system provided by the embodiment of the invention can realize the visual arranging of the multi-cluster system, and an arranging person only needs to drag to add a new single cluster to the target multi-cluster system, without concerning the details of each single cluster, thereby further reducing the arranging difficulty of the multi-cluster system and reducing the time spent on arranging the multi-cluster system.

EXAMPLE III

The third embodiment of the invention provides an arranging device of a multi-cluster system. The device can be realized by software and/or hardware, can be configured in computer equipment, and can perform the arrangement on the multi-cluster system by executing the arrangement method of the multi-cluster system. Fig. 10 is a block diagram of an organizing apparatus of a multi-cluster system according to a third embodiment of the present invention, as shown in fig. 10, the organizing apparatus of the multi-cluster system according to the present embodiment may include a trigger operation receiving module 1001 and a page display module 1002, wherein,

a trigger operation receiving module 1001, configured to receive a trigger operation for triggering entry into an arrangement page of a target multi-cluster system;

a page display module 1002, configured to display the layout page, so as to layout a current multi-cluster layout file of the target multi-cluster system in the layout page, where an application icon of each current single cluster included in the current multi-cluster layout file by the target multi-cluster system is displayed in a canvas of the layout page.

In the arranging device of the multi-cluster system provided in the third embodiment of the present invention, the trigger operation receiving module receives the trigger operation for triggering the entry of the arrangement page of the target multi-cluster system, the page display module displays the arrangement page and the application icons of the current single clusters contained in the current multi-cluster arrangement file of the target multi-cluster system are displayed in the canvas of the arrangement page, so that the current multi-cluster arrangement file of the target multi-cluster system in the arrangement page is arranged. By adopting the technical scheme, the single cluster in the multi-cluster system is abstracted to the application icon for displaying and arranging in the arrangement page, so that the visual arrangement of the multi-cluster arrangement file of the multi-cluster system can be realized, the arrangement difficulty of the multi-cluster arrangement file of the multi-cluster system is reduced, the arrangement difficulty of the multi-cluster system is further reduced, the arrangement steps of the multi-cluster system are simplified, and the operation and maintenance cost of the multi-cluster system is reduced.

Further, the orchestration device of the multi-cluster system may further include: a first layout instruction receiving module, configured to receive a first layout instruction after the layout page is displayed, where the first layout instruction is generated when a first dragging operation acting on a layout page is monitored, and a first starting point of the first dragging operation is located in an application panel of the layout page; and the icon drawing module is used for drawing a first application icon of the application item to be drawn displayed at the first starting point in the canvas of the layout page and controlling the first application icon to move in the canvas along with the first control point of the first dragging operation.

In the foregoing solution, the icon drawing module may be further configured to: when a first current single cluster corresponding to the first application icon has a dependent cluster, drawing the dependent application icon of the dependent cluster in the canvas, and controlling the dependent application icon to move in the canvas along with the first application icon, wherein the dependent application icon is connected with the first application icon through an icon connecting line.

Further, the orchestration device of the multi-cluster system may further include: the adjustment prompt window display module is used for displaying an adjustment prompt window when an original application icon which is the same as the first application icon exists in the canvas; the icon adjusting module is used for adjusting the first application icon and the original application icon into one application icon and closing the adjusting prompt window when an adjusting instruction is received, wherein the adjusting instruction is generated when a scheduler triggers an adjusting control in the adjusting prompt window; and when a rejection instruction is received, closing the adjustment prompt window, wherein the rejection instruction is generated when the scheduling personnel triggers a rejection control in the adjustment prompt window.

Further, the orchestration device of the multi-cluster system may further include: a second layout instruction receiving module, configured to receive a second layout instruction after the layout page is displayed, where the second layout instruction is generated when a sliding operation acting on the layout page is monitored, and a sliding start point and a sliding end point of the sliding operation are located on icon boundaries of two different application icons in the canvas; and the connecting line drawing module is used for drawing the icon connecting line for connecting the two different application icons.

Further, the orchestration device of the multi-cluster system may further include: the configuration item display module is used for displaying the configuration items of each current single cluster in a parameter panel of the layout page when an application parameter display instruction is received after the layout page is displayed, wherein the application parameter display instruction is generated when a scheduler triggers a parameter control in the parameter panel; and the parameter value modification module is used for displaying a parameter detail interface of the configuration item to be modified when a configuration modification instruction is received so that a configurator can modify the parameter value of the configuration item to be modified, wherein the configuration modification instruction is generated when the configuration personnel clicks the configuration item to be modified.

Further, the orchestration device of the multi-cluster system may further include: the first list display module is used for displaying a configuration file list of a second current single cluster corresponding to a second application icon when a configuration file selection instruction is received, wherein the configuration file selection instruction is generated when a scheduler clicks a configuration file selection control of the second application icon; and the configuration file switching module is used for determining the target single cluster configuration file as the current single cluster configuration file of the second current single cluster when it is monitored that the target single cluster configuration file in the configuration file list is switched from the unselected state to the selected state, and updating the configuration item of the second current single cluster displayed in the application parameter interface according to the current single cluster configuration file.

Further, the orchestration device of the multi-cluster system may further include: the sequence display module is used for displaying at least one sequence frame in a parameter panel of the layout page when a deployment sequence display instruction is received after the layout page is displayed, displaying the cluster identifier of each current single cluster in the corresponding sequence frame according to the deployment sequence of each current single cluster, and generating the deployment sequence display instruction when a scheduler triggers a deployment sequence control in the parameter panel; and the sequence adjusting module is used for moving the target cluster identifier at a second starting point of the second dragging operation to a sequence frame to which a termination point of the second dragging operation belongs along with a second control point of the second dragging operation when monitoring the second dragging operation in the deployment sequence interface so as to adjust the deployment sequence of the current target single cluster corresponding to the target cluster identifier.

Further, the orchestration device of the multi-cluster system may further include: the file storage module is used for updating the arrangement information recorded in the current multi-cluster arrangement file and storing the updated current multi-cluster arrangement file; and the deployment module is used for deploying the target multi-cluster system according to the updated current multi-cluster layout file when a deployment instruction is received, and the deployment instruction is generated when a layout worker clicks a deployment control in the layout page.

Further, the orchestration device of the multi-cluster system may further include: the second list display module is used for displaying the layout file list of the target multi-cluster system when a layout file selection instruction is received, wherein the layout file selection instruction is generated when a layout person clicks a layout file selection control in a navigation bar of a layout page; and the layout file switching module is used for determining the target multi-cluster layout file as the current multi-cluster layout file of the target multi-cluster system when the situation that the target multi-cluster layout file in the layout file list is switched from the unselected state to the selected state is monitored, and updating the content displayed in the layout page according to the current multi-cluster layout file.

The arranging device of the multi-cluster system provided by the third embodiment of the invention can execute the arranging method of the multi-cluster system provided by any embodiment of the invention, and has the corresponding functional modules and beneficial effects of executing the arranging method of the multi-cluster system. For details of the technology that is not described in detail in this embodiment, reference may be made to the arranging method of the multi-cluster system provided in any embodiment of the present invention.

Example four

Fig. 11 is a schematic structural diagram of a computer device according to a fourth embodiment of the present invention, as shown in fig. 11, the computer device includes a processor 110 and a memory 111, and may further include an input device 112 and an output device 113; the number of the processors 110 in the computer device may be one or more, and one processor 110 is taken as an example in fig. 11; the processor 110, the memory 111, the input device 112 and the output device 113 in the computer apparatus may be connected by a bus or other means, and the connection by the bus is exemplified in fig. 11.

The memory 111 is used as a computer-readable storage medium, and can be used for storing software programs, computer-executable programs, and modules, such as program instructions/modules corresponding to the arranging method of the multi-cluster system in the embodiment of the present invention (for example, the trigger operation receiving module 1001 and the page display module 1002 in the arranging device of the multi-cluster system). The processor 110 executes various functional applications and data processing of the computer device by executing software programs, instructions and modules stored in the memory 111, that is, implements the above-mentioned arranging method of the multi-cluster system.

The memory 111 may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function; the storage data area may store data created according to the use of the terminal, and the like. Further, the memory 111 may include high speed random access memory, and may also include non-volatile memory, such as at least one magnetic disk storage device, flash memory device, or other non-volatile solid state storage device. In some examples, the memory 111 may further include memory located remotely from the processor 110, which may be connected to a computer device through a network. Examples of such networks include, but are not limited to, the internet, intranets, local area networks, mobile communication networks, and combinations thereof.

The input device 112 may be used to receive input numeric or character information and generate key signal inputs related to user settings and function controls of the computer apparatus. The output device 113 may include a display device such as a display screen.

An embodiment of the present invention further provides a storage medium containing computer-executable instructions, where the computer-executable instructions are executed by a computer processor to perform an orchestration method for a multi-cluster system, and the method includes:

receiving a trigger operation for triggering entry into an arrangement page of a target multi-cluster system;

and displaying the layout page so as to layout the current multi-cluster layout file of the target multi-cluster system in the layout page, wherein the canvas of the layout page displays application icons of each current single cluster contained in the current multi-cluster layout file by the target multi-cluster system.

Of course, the storage medium provided by the embodiment of the present invention contains computer-executable instructions, and the computer-executable instructions are not limited to the method operations described above, and may also perform related operations in the method for arranging a multi-cluster system provided by any embodiment of the present invention.

From the above description of the embodiments, it is obvious for those skilled in the art that the present invention can be implemented by software and necessary general hardware, and certainly, can also be implemented by hardware, but the former is a better embodiment in many cases. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which can be stored in a computer-readable storage medium, such as a floppy disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a FLASH Memory (FLASH), a hard disk or an optical disk of a computer, and includes several instructions for enabling a computer device (which may be a personal computer, a server, or a network device) to execute the methods according to the embodiments of the present invention.

It should be noted that, in the embodiment of the orchestration device of the multi-cluster system, each included unit and module are only divided according to functional logic, but are not limited to the above division, as long as the corresponding functions can be implemented; in addition, specific names of the functional units are only for convenience of distinguishing from each other, and are not used for limiting the protection scope of the present invention.

It is to be noted that the foregoing is only illustrative of the preferred embodiments of the present invention and the technical principles employed. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail by the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the spirit of the present invention, and the scope of the present invention is determined by the scope of the appended claims.

Claims (11)

1. A method for arranging a multi-cluster system is characterized by comprising the following steps:

receiving a trigger operation for triggering entry into an arrangement page of a target multi-cluster system;

displaying the layout page to layout a current multi-cluster layout file of the target multi-cluster system in the layout page, wherein an application icon of each current single cluster contained in the current multi-cluster layout file by the target multi-cluster system is displayed in a canvas of the layout page;

wherein, after the displaying the layout page, further comprising:

receiving a first layout instruction, wherein the first layout instruction is generated when a first dragging operation acting in a layout page is monitored, and a first starting point of the first dragging operation is located in an application panel of the layout page;

drawing a first application icon of the application to be drawn displayed at the first start point within a canvas of the layout page and controlling the first application icon to move within the canvas along with a first control point of the first drag operation;

the arranging method of the multi-cluster system further comprises the following steps:

if the first current single cluster corresponding to the first application icon has a dependent cluster, drawing the dependent application icon of the dependent cluster in the canvas, and controlling the dependent application icon to move in the canvas along with the first application icon, wherein the dependent application icon is connected with the first application icon through an icon connecting line.

2. The method of claim 1, further comprising:

if an original application icon which is the same as the first application icon exists in the canvas, displaying an adjustment prompt window;

when an adjusting instruction is received, the first application icon and the original application icon are adjusted into one application icon, the adjusting prompt window is closed, and the adjusting instruction is generated when a scheduler triggers an adjusting control in the adjusting prompt window;

and when a rejection instruction is received, closing the adjustment prompt window, wherein the rejection instruction is generated when the scheduling personnel triggers a rejection control in the adjustment prompt window.

3. The method of claim 1, further comprising, after said displaying said layout page:

receiving a second layout instruction, wherein the second layout instruction is generated when a sliding operation acting in the layout page is monitored, and a sliding starting point and a sliding ending point of the sliding operation are located on icon boundaries of two different application icons in the canvas;

and drawing an icon connecting line connecting the two different application icons.

4. The method of claim 1, further comprising, after said displaying said layout page:

when an application parameter display instruction is received, displaying configuration items of each current single cluster in a parameter panel of an arrangement page, wherein the application parameter display instruction is generated when an arranger triggers a parameter control in the parameter panel;

when a configuration modification instruction is received, displaying a parameter detail interface of a configuration item to be modified so that a configuration worker can modify a parameter value of the configuration item to be modified, wherein the configuration modification instruction is generated when a scheduling worker clicks the configuration item to be modified.

5. The method of claim 4, further comprising:

when a configuration file selection instruction is received, displaying a configuration file list of a second current single cluster corresponding to a second application icon, wherein the configuration file selection instruction is generated when a scheduler clicks a configuration file selection control of the second application icon;

when it is monitored that the target single cluster configuration file in the configuration file list is switched from an unselected state to a selected state, determining the target single cluster configuration file as a current single cluster configuration file of the second current single cluster, and updating the configuration item of the second current single cluster displayed in the application parameter interface according to the current single cluster configuration file.

6. The method of claim 1, further comprising, after said displaying said layout page:

when a deployment sequence display instruction is received, displaying at least one sequence frame in a parameter panel of an arrangement page, and displaying cluster identifications of current single clusters in corresponding sequence frames according to the deployment sequence of the current single clusters, wherein the deployment sequence display instruction is generated when an arrangement worker triggers a deployment sequence control in the parameter panel;

when a second dragging operation in the deployment sequence interface is monitored, moving a target cluster identifier at a second starting point of the second dragging operation along with a second control point of the second dragging operation into a sequence frame to which a termination point of the second dragging operation belongs, so as to adjust the deployment sequence of a current target single cluster corresponding to the target cluster identifier.

7. The method of any of claims 1-6, further comprising:

updating the arrangement information recorded in the current multi-cluster arrangement file, and storing the updated current multi-cluster arrangement file;

and when a deployment instruction is received, deploying the target multi-cluster system according to the updated current multi-cluster layout file, wherein the deployment instruction is generated when a scheduler clicks a deployment control in the layout page.

8. The method of any of claims 1-6, further comprising:

when receiving a layout file selection instruction, displaying a layout file list of the target multi-cluster system, wherein the layout file selection instruction is generated when a layout personnel clicks a layout file selection control in a navigation bar of a layout page;

when it is monitored that the target multi-cluster arrangement file in the arrangement file list is switched from an unselected state to a selected state, the target multi-cluster arrangement file is determined as a current multi-cluster arrangement file of the target multi-cluster system, and the content displayed in the arrangement page is updated according to the current multi-cluster arrangement file.

9. An arrangement apparatus of a multi-cluster system, comprising:

the trigger operation receiving module is used for receiving trigger operation for triggering entry of a layout page of the target multi-cluster system;

the page display module is used for displaying the layout page so as to lay out a current multi-cluster layout file of the target multi-cluster system in the layout page, wherein an application icon of each current single cluster contained in the current multi-cluster layout file by the target multi-cluster system is displayed in a canvas of the layout page;

a first layout instruction receiving module, configured to receive a first layout instruction after the layout page is displayed, where the first layout instruction is generated when a first dragging operation acting on a layout page is monitored, and a first starting point of the first dragging operation is located in an application panel of the layout page; an icon drawing module for drawing a first application icon of the application item to be drawn displayed at the first start point within a canvas of the layout page and controlling the first application icon to move within the canvas along with a first control point of the first drag operation;

and the icon drawing module is used for drawing the dependent application icon of the dependent cluster in the canvas and controlling the dependent application icon to move in the canvas along with the first application icon when the first current single cluster corresponding to the first application icon has the dependent cluster, wherein the dependent application icon is connected with the first application icon through an icon connecting line.

10. A computer device, comprising:

one or more processors;

a memory for storing one or more programs,

when executed by the one or more processors, cause the one or more processors to implement the orchestration method of the multi-cluster system according to any of claims 1-8.

11. A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out the method of orchestration of a multi-cluster system according to any one of claims 1-8.

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