CN117251129A - Cross-platform same-screen method based on transfer compiling - Google Patents

Abstract

The invention relates to the field of on-screen display, and particularly provides a cross-platform on-screen method based on transfer compiling, which is used for receiving application information of cross-platform application, generating a transfer compiling request of the cross-platform application, and acquiring a compiling script corresponding to the transfer compiling request from a cloud server; the compiling script is configured in a compiling database of the cloud server in advance; configuring a transfer protocol stack for information interaction with the cross-platform application at a cloud server; the transfer protocol stack is provided with at least one transfer butt joint port and at least two information interaction ports; and connecting the compiling script with the transit docking port, and respectively connecting the compiling script with the cross-platform application through the information interaction port to perform the same-screen display. The method can realize the same-screen display among different platforms, compile among different platforms, and enable different data to accord with the display format of the corresponding platform, thereby realizing the same-screen cross-platform.

Description

Cross-platform same-screen method based on transfer compiling

Technical Field

The invention relates to the technical field of cross-platform, in particular to a cross-platform same-screen method based on transfer compiling.

Background

At present, the remote on-screen patent is mainly focused on the directions of remote education, home video, robot positioning and the like.

One reason why the remote on-screen function cannot be applied in large quantity in the engineering machinery industry is that two sets of software need to be developed, and the software developed at the equipment end cannot be directly applied to a remote PC end or a mobile end. The traditional remote same-screen function has the defects that software needs to be developed respectively for the vehicle-mounted terminal and the remote terminal, the workload is large, the software in the engineering machinery industry is changed very frequently, and therefore the software of the vehicle-mounted terminal and the remote terminal needs to be changed very troublesome.

In addition, the previous remote on-screen is limited to the same platform, and the on-screen cannot be realized for different application software.

Disclosure of Invention

The invention provides a cross-platform same-screen method based on transfer compiling, which is used for solving the problem that different application software cannot realize the same screen.

A cross-platform co-screen method based on transfer compiling comprises the following steps:

receiving application information of the cross-platform application, generating a transfer compiling request of the cross-platform application, and acquiring a compiling script corresponding to the transfer compiling request from a cloud server; wherein,

the compiling script is preconfigured in a compiling database of the cloud server;

a transit protocol stack for carrying out information interaction by cross-platform application is configured on the cloud server; wherein,

the transfer protocol stack is provided with at least one transfer butt joint port and at least two information interaction ports;

and connecting the compiling script with the transit docking port, and respectively connecting the compiling script with the cross-platform application through the information interaction port to perform the same-screen display.

Preferably, the cross-platform application is connected with the cloud server through a dynamic reconfigurable high-speed serial bus protocol; wherein,

the dynamic reconfigurable high-speed serial bus protocol performs data interaction based on a bus type topological structure of multi-channel communication;

the bus topology structure is configured with data nodes, and each data node is in butt joint with one cross-platform application; wherein,

the data node is configured with vector parameters for triggering requests including interrupt requests, compile requests and on-screen requests.

Preferably, the application information comprises on-screen application information sent by at least one request platform to a target platform; wherein,

the same screen application information corresponds to a screen interface played by a target platform in real time, and the target platform is not lower than one;

and when the target platform is not lower than one, requesting the platform to execute split-screen operation, and generating a multi-communication channel for isolating interaction on the corresponding data node.

Preferably, the transfer compiling request comprises a transfer request and a compiling request; wherein,

the transfer request includes a synchronous transfer request and a delayed transfer request;

when a synchronous transfer request and a compiling request are received, generating a timestamp synchronization mechanism based on cross-platform application in a cloud server, and compiling and mapping in the cloud server through the timestamp synchronization mechanism;

when a delayed transit request and a compiling request are received, a delayed transition mechanism based on cross-platform application is generated at the cloud server, and delayed co-screen is carried out at the cloud server through the delayed transition mechanism.

Preferably, the compiling request carries data format information of cross-platform application; wherein,

the data format information comprises first format information of a host platform displayed in real time in cross-platform application and second format information of a slave platform displayed on the same screen;

the first format information and the second format information are configured with compiling vectors for data compiling and identifying in the cloud server, and the compiling vectors and the compiling scripts have associated responses.

Preferably, the transfer protocol stack comprises an identification layer, a compiling layer and an interaction layer; wherein,

format responses are configured between the identification and compiling layers, and transmission responses are configured between the compiling layer and the interaction layer;

the identification layer is used for identifying the compiling script, and identifying the data format of a target platform for executing cross-platform and same screen in the transferring compiling request;

the compiling layer is used for configuring a script docking port, connecting compiling scripts, and starting the connected compiling scripts through data format and format response;

the interaction layer is used for connecting the cross-platform application and carrying out the same-screen display according to the cross-platform application and the transmission response after the compiling script is started.

Preferably, the interaction layer is further configured with a same-screen detection mechanism; wherein,

the on-screen detection mechanism comprises a recording clock and a detection unit, wherein the detection unit is used for frame number detection, data packet detection and coding detection;

the recording clock is used for recording the data stream before compiling the compiling script and the data stream after compiling, and judging whether the data is missing or not.

Preferably, the recording clock includes delay calculation and packet loss calculation; wherein,

when the delay calculation is performed, the cloud server is used for judging whether the first time stamp difference value of different data before compiling the compiling script reaches the compiling script is consistent with the second time stamp difference value of different data after compiling the compiling script reaches the target cross-platform application, and determining delay time when the first time stamp difference value and the second time stamp difference value are inconsistent;

when the packet loss is calculated, the cloud server is used for recording whether a first data packet of the data before compiling the compiling script reaches the compiling script and a second data packet of the data after compiling the compiling script reaches the target cross-platform application are consistent or not, and determining the packet loss rate when the data packets are inconsistent.

Preferably, the transit docking port comprises a data output port and a data receiving port which are isolated by a channel;

a conversion filling model for fusing the compiling script is configured between the data output port and the data receiving port;

the padding model is converted into a driving model for compiling the script.

Preferably, the information interaction port is used for responding to the determination operation of the cross-platform application and creating an interaction association relation associated with the cross-platform application; wherein,

the determining operation is used for forming a first determining response when the transfer compiling request is generated, and generating a second determining response after compiling the compiling script is completed.

The invention has the beneficial effects that:

(1) The method and the device can realize the same-screen display among different platforms, compile among different platforms, enable different data to accord with the display format of the corresponding platform, and therefore cross-platform same-screen.

(2) The cross-platform same-screen mode is a one-stop same-screen mode, and can realize the same-screen display of four modes of multi-platform to multi-platform, single-platform to single-platform and multi-platform to single-platform.

(3) When the same screen is displayed, different compiling scripts can be switched, so that different platforms can be docked at will, and the same screen display is realized.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and drawings.

The technical scheme of the invention is further described in detail through the drawings and the embodiments.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

FIG. 1 is a diagram of a transfer compiling structure in an embodiment of the invention;

FIG. 2 is a schematic diagram of a compiled script connection in an embodiment of the present invention;

FIG. 3 is a diagram of a multi-host display and a single-host display according to an embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.

The application provides a cross-platform co-screen method based on transfer compiling, which comprises the following steps:

receiving application information of the cross-platform application, generating a transfer compiling request of the cross-platform application, and acquiring a compiling script corresponding to the transfer compiling request from a cloud server; wherein,

the compiling script is preconfigured in a compiling database of the cloud server;

a transit protocol stack for carrying out information interaction by cross-platform application is configured on the cloud server; wherein,

the transfer protocol stack is provided with at least one transfer butt joint port and at least two information interaction ports;

and connecting the compiling script with the transit docking port, and respectively connecting the compiling script with the cross-platform application through the information interaction port to perform the same-screen display.

The principle of the technical scheme is as follows:

as shown in fig. 1, fig. 2 and fig. 3, the main technology of the application is to set a "compiling technology" to implement the transfer compiling between different platforms by setting a transfer compiling function in order to solve the same screen display function before different platforms, so that the different platforms can be displayed even if the data formats are different, and because all the slave platforms implement the transfer compiling of data through the compiling script of the transfer compiling, the display formats of the different slave platforms are met.

Compared with the cross-platform compiling means in the prior art, one compiling script can only compile data displayed in different formats of two different platforms, if three platforms, four platforms or more different platforms exist, synchronous compiling processing cannot be realized by only one compiling script, so that a transfer protocol stack is arranged, and can be abutted against various different compiling scripts, one video stream can be compiled into formats which can be displayed by various different platforms at one time, and the same-screen display of the multiple platforms is realized.

In the implementation process of the application, the application information is platform information which needs to be played in a cross-platform mode; and automatically responding by the cloud server through the platform information, and determining the format information of the target platform, thereby determining the corresponding compiling script.

And then the compiled script is in butt joint with the transfer protocol station, so that cross-platform same-screen display is realized.

The beneficial effects of the technical scheme are that:

(1) The method and the device can realize the same-screen display among different platforms, compile among different platforms, enable different data to accord with the display format of the corresponding platform, and therefore cross-platform same-screen.

(2) The cross-platform same-screen mode is a one-stop same-screen mode, and can realize the same-screen display of four modes of multi-platform to multi-platform, single-platform to single-platform and multi-platform to single-platform.

(3) When the same screen is displayed, different compiling scripts can be switched, so that different platforms can be docked at will, and the same screen display is realized.

Preferably, the cross-platform application is connected with the cloud server through a dynamic reconfigurable high-speed serial bus protocol; wherein,

the dynamic reconfigurable high-speed serial bus protocol performs data interaction based on a bus type topological structure of multi-channel communication;

the bus topology structure is configured with data nodes, and each data node is in butt joint with one cross-platform application; wherein,

the data node is configured with vector parameters for triggering requests including interrupt requests, compile requests and on-screen requests.

The principle of the technical scheme is as follows:

the method and the device adopt dynamic reconfigurable high-speed serial bus protocols in the cross-platform process, namely the protocols are dynamic to realize protocol conversion, and the multi-communication channel can be used for connecting a plurality of terminal devices or devices logged by user accounts at the same time, namely the cross-platform applications on different terminal devices are connected through different data nodes, so that corresponding vector parameters of the same-screen request are triggered, and the same-screen display is realized.

There are a variety of requests that execute different requests through the vector parameters of the request.

The beneficial effects of the technical scheme are that:

the application adopts the dynamic reconfigurable high-speed serial bus protocol when crossing platforms, namely the protocols are dynamic to realize protocol conversion, so that the display of different platforms can be realized.

Preferably, the application information comprises on-screen application information sent by at least one request platform to a target platform; wherein,

the same screen application information corresponds to a screen interface played by a target platform in real time, and the target platform is not lower than one;

and when the target platform is not lower than one, requesting the platform to execute split-screen operation, and generating a multi-communication channel for isolating interaction on the corresponding data node.

The principle of the technical scheme is as follows:

when receiving the same-screen display information, the application method and the application device send the same-screen application information to at least one platform, so that interaction of the same screen is realized.

The target platform is a main platform for carrying out on-screen display;

when the main platform is a plurality of platforms, multiple communication channels for isolated interaction can be generated through the data nodes, so that interfaces of the plurality of main platforms displayed on the same screen are generated into a nine-grid or small display interfaces with different interface sizes, and the nine-grid or small display interfaces are displayed on the sub-interfaces displayed on the same screen.

The beneficial effects of the technical scheme are that:

the method and the device can realize the same-screen display of four modes of multi-platform to multi-platform and single-platform to multi-platform, single-platform to single-platform and multi-platform to single-platform.

Preferably, the transfer compiling request comprises a transfer request and a compiling request; wherein,

the transfer request includes a synchronous transfer request and a delayed transfer request;

when a synchronous transfer request and a compiling request are received, generating a timestamp synchronization mechanism based on cross-platform application in a cloud server, and compiling and mapping in the cloud server through the timestamp synchronization mechanism;

when a delayed transit request and a compiling request are received, a delayed transition mechanism based on cross-platform application is generated at the cloud server, and delayed co-screen is carried out at the cloud server through the delayed transition mechanism.

The principle of the technical scheme is as follows:

the transfer compiling request has two requests of transfer and compiling, so that the delay same screen and the real-time same screen can be realized;

in the process, the delay on the same screen can be based on a transition mechanism, so that time delay is realized; the synchronous same screen can realize synchronous mapping compiling through a mechanism of compiling mapping.

And the timestamp synchronization mechanism is to perform interface mapping corresponding to the timestamp in the cloud server through the timestamp, and directly display the real-time interface synchronization mapping mode of the main platform in the sub-platform.

The delayed transfer request is through predetermined delay time, and then according to the delay time, the sub-platform is controlled to display the display interface of the main platform.

The beneficial effects of the technical scheme are that:

the transfer compiling request has two requests of transfer and compiling, so that the delay of the same screen and the real-time same screen can be realized, a delay mechanism can be adopted when the transfer compiling request is suitable for synchronous conference scenes and remote control, and when the main platform displays errors, errors are found based on the delay mechanism, so that error information is prevented from being directly and synchronously displayed in the sub-platform.

Preferably, the compiling request carries data format information of cross-platform application; wherein,

the data format information comprises first format information of a host platform displayed in real time in cross-platform application and second format information of a slave platform displayed on the same screen;

the first format information and the second format information are configured with compiling vectors for data compiling and identifying in the cloud server, and the compiling vectors and the compiling scripts have associated responses.

The principle of the technical scheme is as follows:

the data format information comprises different format information of the host platform and the slave platform, so that specific compiling scripts to be selected are judged, and then compiling of the association response is realized based on the compiling scripts, so that compiling errors are prevented when compiling is performed.

The beneficial effects of the technical scheme are that:

the method and the device can realize data compiling in any different formats, adapt to different scripts and realize compiling scripts for dynamic configuration compiling conversion.

Preferably, the transfer protocol stack comprises an identification layer, a compiling layer and an interaction layer; wherein,

format responses are configured between the identification and compiling layers, and transmission responses are configured between the compiling layer and the interaction layer;

the identification layer is used for identifying the compiling script, and identifying the data format of a target platform for executing cross-platform and same screen in the transferring compiling request;

the compiling layer is used for configuring a script docking port, connecting compiling scripts, and starting the connected compiling scripts through data format and format response;

the interaction layer is used for connecting the cross-platform application and carrying out the same-screen display according to the cross-platform application and the transmission response after the compiling script is started.

The principle of the technical scheme is as follows:

the transfer protocol stack comprises three layers, namely an identification layer, a compiling layer and an interaction layer, wherein the identification layer is used for identifying an accessed platform and compiling scripts.

The compiling layer is used for butting and compiling scripts so as to play different format conversion functions of different platforms and realize the same-screen display.

The interaction layer is used for connecting cross-platform applications on different terminal devices and realizing data transmission after compiling the monkey before compiling.

The function of the format response is to perform the compiling conversion format of different compiling scripts, the format response of the source format of the host platform and the target format of the slave platform, and perform the information identification of the corresponding data format;

the transmission response is the data input transmission response of the host platform and the data access response of the slave platform before and after data transmission compiling, and whether the cross-platform same screen is stable or not is judged.

The beneficial effects of the technical scheme are that:

according to the method and the device, through the transfer protocol stack, the data of different platforms and different terminal devices can be subjected to self-adaptive conversion, and based on transmission response and format response, the fact that data errors cannot occur in the process of on-screen display is guaranteed.

Preferably, the interaction layer is further configured with a same-screen detection mechanism; wherein,

the on-screen detection mechanism comprises a recording clock and a detection unit, wherein the detection unit is used for frame number detection, data packet detection and coding detection;

the recording clock is used for recording the data stream before compiling the compiling script and the data stream after compiling, and judging whether the data is missing or not.

The principle of the technical scheme is as follows:

the on-screen detection mechanism is a synchronous detection mode from a time angle and a data transmission angle through a recording clock and a detection unit;

firstly, recording a time stamp of each data in a data stream before and after compiling, wherein the time stamp comprises a frame image of a same screen display interface, a data packet in a data transmission packaging process and a coding execution process of a compiling script in the compiling process;

and (3) recording the data through time stamping, and judging the number of the data in the data streams before and after compiling, and judging whether the display interfaces of the frame images are consistent or not, thereby judging whether the data is missing or not.

The beneficial effects of the technical scheme are that:

according to the method and the device, whether data are missing or not can be judged through the on-screen detection mechanism, so that whether the interface displayed on the same screen is missing or not is prevented.

Preferably, the recording clock includes delay calculation and packet loss calculation; wherein,

when the delay calculation is performed, the cloud server is used for judging whether the first time stamp difference value of different data before compiling the compiling script reaches the compiling script is consistent with the second time stamp difference value of different data after compiling the compiling script reaches the target cross-platform application, and determining delay time when the first time stamp difference value and the second time stamp difference value are inconsistent;

when the packet loss is calculated, the cloud server is used for recording whether a first data packet of the data before compiling the compiling script reaches the compiling script and a second data packet of the data after compiling the compiling script reaches the target cross-platform application are consistent or not, and determining the packet loss rate when the data packets are inconsistent.

The principle of the technical scheme is as follows:

in the execution process, the on-screen detection mechanism can perform delay calculation and packet loss calculation, and in the process:

the delay calculation is to judge whether the difference value of the data stream transmission process is consistent before and after compiling, wherein the difference value is according to the necessary delay time generated by the data because of the network transmission speed in the transmission process, and the first detection result is provided for whether the data has the missing or not through the calculation of the necessary delay time;

the packet loss calculation is performed by data packets, and the data amount may change before and after compiling, but the number of data packets to be packed is always, so that when the transmission time is delayed and the number of data packets is inconsistent, the abnormality of the on-screen display is necessarily indicated.

The beneficial effects of the technical scheme are that:

the method and the device can judge that the abnormality exists in the process of the same-screen display certainly from two aspects of packet loss calculation and delay calculation.

Preferably, the transit docking port comprises a data output port and a data receiving port which are isolated by a channel;

a conversion filling model for fusing the compiling script is configured between the data output port and the data receiving port;

the padding model is converted into a driving model for compiling the script.

The principle of the technical scheme is as follows:

the transfer port is provided with the data output port and the data receiving port which are isolated by the channel, and an editing script loading mode based on a filling mechanism is arranged between the two ports, so that different compiling scripts are changed in the process of converting different formats, and the transfer port is suitable for converting data in any format.

The beneficial effects of the technical scheme are that:

according to the method and the device, the filling model is converted, so that different cross-platform applications are changed, and the self-adaptive collocation compiling script is realized.

Preferably, the information interaction port is used for responding to the determination operation of the cross-platform application and creating an interaction association relation associated with the cross-platform application; wherein,

the determining operation is used for forming a first determining response when the transfer compiling request is generated, and generating a second determining response after compiling the compiling script is completed.

The principle of the technical scheme is as follows:

when the interactive relation is generated, a first determination response and a second determination response are generated at the same time, so that synchronous response and synchronous association are realized.

The first determination response is a response generated by the request, and the second determination response is a response of compiling conversion completion, so that the dual identification of the on-screen display mechanism is realized.

The beneficial effects of the technical scheme are that:

the method and the device can realize synchronous response and association processing at compiling time.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (10)

1. The cross-platform same-screen method based on transfer compiling is characterized by comprising the following steps of:

receiving application information of the cross-platform application, generating a transfer compiling request of the cross-platform application, and acquiring a compiling script corresponding to the transfer compiling request from a cloud server; wherein,

the compiling script is preconfigured in a compiling database of the cloud server;

configuring a transfer protocol stack for information interaction of cross-platform application at a cloud server; wherein,

the transfer protocol stack is provided with at least one transfer butt joint port and at least two information interaction ports;

and connecting the compiling script with the transit docking port, and respectively connecting the compiling script with the cross-platform application through the information interaction port to perform the same-screen display.

2. The cross-platform co-screen method based on transfer compiling of claim 1, wherein the cross-platform application is connected with a cloud server through a dynamic reconfigurable high-speed serial bus protocol; wherein,

the dynamic reconfigurable high-speed serial bus protocol performs data interaction based on a bus type topological structure of multi-channel communication;

the bus topology structure is configured with data nodes, and each data node is in butt joint with one cross-platform application; wherein,

the data node is configured with vector parameters for triggering requests including interrupt requests, compile requests and on-screen requests.

3. The cross-platform on-screen method based on transfer compiling of claim 2, wherein the application information comprises on-screen application information sent by at least one request platform to a target platform; wherein,

the same screen application information corresponds to a screen interface played by a target platform in real time, and the target platform is not lower than one;

and when the target platform is not lower than one, requesting the platform to execute split-screen operation, and generating a multi-communication channel for isolating interaction on the corresponding data node.

4. The cross-platform on-screen method based on transfer compiling of claim 1, wherein the transfer compiling request comprises a transfer request and a compiling request; wherein,

the transfer request includes a synchronous transfer request and a delayed transfer request;

when a synchronous transfer request and a compiling request are received, generating a timestamp synchronization mechanism based on cross-platform application in a cloud server, and compiling and mapping in the cloud server through the timestamp synchronization mechanism;

when a delayed transit request and a compiling request are received, a delayed transition mechanism based on cross-platform application is generated at the cloud server, and delayed co-screen is carried out at the cloud server through the delayed transition mechanism.

5. The cross-platform and same-screen method based on transfer compiling of claim 4, wherein the compiling request carries data format information of cross-platform application; wherein,

the data format information comprises first format information of a host platform displayed in real time in cross-platform application and second format information of a slave platform displayed on the same screen;

the first format information and the second format information are configured with compiling vectors for data compiling and identifying in the cloud server, and the compiling vectors and the compiling scripts have associated responses.

6. The cross-platform same-screen method based on transfer compiling of claim 1, wherein the transfer protocol stack comprises an identification layer, a compiling layer and an interaction layer; wherein,

format response is configured between the identification layer and the compiling layer, and transmission response is configured between the compiling layer and the interaction layer;

the identification layer is used for identifying the compiling script, and identifying the data format of a target platform for executing cross-platform and same screen in the transferring compiling request;

the compiling layer is used for configuring a script docking port, connecting compiling scripts, and starting the connected compiling scripts through data format and format response;

the interaction layer is used for connecting the cross-platform application and carrying out the same-screen display according to the cross-platform application and the transmission response after the compiling script is started.

7. The cross-platform on-screen method based on transfer compiling of claim 6, wherein the interaction layer is further configured with an on-screen detection mechanism; wherein,

the on-screen detection mechanism comprises a recording clock and a detection unit, wherein the detection unit is used for frame number detection, data packet detection and coding detection;

the recording clock is used for recording the data stream before compiling the compiling script and the data stream after compiling, and judging whether the data is missing or not.

8. The cross-platform same-screen method based on transfer compiling of claim 7, wherein the recording clock comprises delay calculation and packet loss calculation; wherein,

when the delay calculation is performed, the cloud server is used for judging whether the first time stamp difference value of different data before compiling the compiling script reaches the compiling script is consistent with the second time stamp difference value of different data after compiling the compiling script reaches the target cross-platform application, and determining delay time when the first time stamp difference value and the second time stamp difference value are inconsistent;

when the packet loss is calculated, the cloud server is used for recording whether a first data packet of the data before compiling the compiling script reaches the compiling script and a second data packet of the data after compiling the compiling script reaches the target cross-platform application are consistent or not, and determining the packet loss rate when the data packets are inconsistent.

9. The cross-platform on-screen method based on transfer compiling of claim 1, wherein the transfer docking port comprises a data output port and a data receiving port which are isolated by a channel;

a conversion filling model for fusing the compiling script is configured between the data output port and the data receiving port;

the padding model is converted into a driving model for compiling the script.

10. The cross-platform same-screen method based on transfer compiling of claim 1, wherein the information interaction port is used for responding to the determination operation of the cross-platform application and creating an interaction association relation associated with the cross-platform application; wherein,

the determining operation is used for forming a first determining response when the transfer compiling request is generated, and generating a second determining response after compiling the compiling script is completed.