CN104571907B - A kind of information processing method and electronic equipment - Google Patents

Abstract

The invention discloses a kind of information processing method, including：The first non-full screen window in first state is determined in the non-full screen window currently opened；Described first non-full screen window is arranged to the first dispaly state；Obtain the first display information corresponding to the described first non-full screen window；According to first display information, the display information of functional area is determined；The display interface of the first non-full screen window is generated using first display information and the display information of the functional area.The invention also discloses a kind of electronic equipment, and the quantity in the display function region on electronic equipment can be reduced using the present invention, user is reduced and the situation of maloperation occurs, so as to lift the usage experience of user, and ensure the ease for use of multiple wicket systems.

Description

Information processing method and electronic equipment

Technical Field

The present invention relates to the field of wireless communications, and in particular, to an information processing method and an electronic device.

Background

With the development of mobile terminals, especially the improvement of the resolution and the increase of the size of the screen, users gradually put forward the requirements of multi-window operation interfaces, that is, a plurality of small windows are opened simultaneously in the same mobile device, and each small window displays and operates an application.

However, if the multi-window operation interface is put into use, it may happen that each of the small windows has a corresponding control area for controlling operations such as zooming, moving, closing and the like of the small window, so that when the plurality of small windows are opened, the small windows corresponding to the control areas may not be distinguished on the display screen of the mobile terminal, or a visually confused feeling may be brought to the client, so that the use experience of the user may be affected, and the usability of the system of the plurality of small windows may not be ensured.

Disclosure of Invention

In view of the above, an object of the present invention is to provide an information processing method and an electronic device, which can reduce the number of display function areas on the electronic device and reduce the occurrence of misoperation for a user, thereby improving the user experience and ensuring the usability of a plurality of widget systems.

In order to achieve the purpose, the technical scheme of the invention is realized as follows:

the invention provides an information processing method, which is applied to electronic equipment, wherein the electronic equipment is provided with a touch display unit, the electronic equipment can run a plurality of applications and display the applications in a display area of the touch display unit, and a full-screen display window corresponding to the applications is converted by utilizing conversion parameters to obtain a non-full-screen window of the applications; when N windows of the non-full screen mode running application are opened, N is an integer greater than or equal to 1; the method comprises the following steps:

determining a first non-full screen window in a first state in a currently opened non-full screen window;

setting the first non-full screen window to be in a first display state;

acquiring first display information corresponding to the first non-full screen window;

determining display information of a functional area according to the first display information;

and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area.

The present invention also provides an electronic device, including: the touch control display unit and the processing unit; wherein,

the touch display unit is used for converting a full-screen display window corresponding to the application by using the conversion parameter to obtain a non-full-screen window of the application; when N windows of the non-full screen mode running application are opened, N is an integer greater than or equal to 1;

the processing unit is used for running a plurality of applications, displaying non-full screen windows of the applications in a display area of the touch display unit, and determining a first non-full screen window in a first state in the currently opened non-full screen windows; setting the first non-full screen window to be in a first display state; acquiring first display information corresponding to the first non-full screen window; determining display information of a functional area according to the first display information; and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area.

The information processing method and the electronic equipment provided by the invention determine a first non-full screen window in a first state in a currently opened non-full screen window; setting the first non-full screen window to be in a first display state; acquiring first display information corresponding to the first non-full screen window; determining display information of a functional area according to the first display information; and generating frame buffer data by using the first display information and the display information of the functional area and displaying the frame buffer data in a display area of the touch display unit. Therefore, the functional area is displayed in the non-full screen window in the first state only, the number of the functional areas displayed on the electronic equipment is reduced, the situation that misoperation occurs to a user is reduced, the use experience of the user is improved, and the usability of a plurality of small window systems is guaranteed.

Drawings

FIG. 1 is a flow chart of an information processing method according to an embodiment of the present invention;

FIG. 2 is a first schematic view illustrating a display effect according to an embodiment of the present invention;

FIG. 3 is a schematic diagram illustrating a second display effect according to an embodiment of the present invention;

FIG. 4 is a third schematic view of the display effect of the embodiment of the present invention;

fig. 5 is a schematic structural diagram of an electronic device according to an embodiment of the invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

The first embodiment,

According to the information processing method provided by the embodiment of the invention, the electronic equipment is provided with a touch display unit, the electronic equipment can run a plurality of applications and display the applications in a display area of the touch display unit, and a full-screen display window corresponding to the applications is converted by using a conversion parameter to obtain a non-full-screen window of the applications; when the electronic equipment runs an application in a non-full screen mode and opens a non-full screen window running in the non-full screen mode; as shown in fig. 1, the method includes:

step 101: a first non-full screen window in a first state is determined in a currently open non-full screen window.

Step 102: and setting the first non-full screen window to be in a first display state.

Step 103: and acquiring first display information corresponding to the first non-full screen window.

Step 104: and determining the display information of the functional area according to the first display information.

Step 105: and generating a display interface of a first non-full screen window by using the first display information and the display information of the functional area.

Wherein the first non-full screen window in the first state is: and the non-full screen window of the last interactive event in the N windows of the non-full screen mode running application.

The first display state is a state in which a functional area is displayed at the first non-full screen window.

The first display information may include: the display position of the display area of the first non-full screen window and the graphic cache data corresponding to the first non-full screen window.

The determining the display information of the functional area according to the first display information includes: extracting the display position of the display area of the first non-full screen window from the first display information, determining the display coordinates of the functional area and the graphic cache data of the functional area according to the display position of the display area, and combining the display coordinates of the functional area and the graphic cache data into the display information of the functional area;

the functional area is an area including functional keys for controlling the states of closing, zooming, and moving the first non-full screen window as shown in fig. 2.

Wherein, the starting of the non-full screen window running in the non-full screen mode comprises: selecting an application running in a non-full screen mode, and acquiring a conversion parameter; and converting the full-screen display window corresponding to the application by using the conversion parameter to obtain a display area of the non-full-screen window of the application.

The converting the display window corresponding to the selected application by using the conversion parameter to obtain the display area of the non-full screen window of the application comprises the following steps: reading the graph cache data of the application; converting the read graph cache data by using the conversion parameter, and generating frame cache data corresponding to the touch display unit by using the graph cache data; and displaying the non-full screen window of the application on the touch display unit by utilizing the frame cache data.

The conversion parameters take the form of: parameter values, matrices, parameter sets, and parameter sets.

The graphics cache data may include: coordinate information of each pixel point and Red, Green and Blue (RGB, Red Green Blue) three-color information of each pixel point.

Considering the situation that a superposition area possibly exists between the non-full screen display windows corresponding to the two applications, the coordinate information of the pixel points in the graphic cache data of the non-full screen display window corresponding to the applications is set as a three-dimensional coordinate (x)_o，y_o，z_o) (ii) a Wherein different non-full screen display windows have different third-dimensional coordinates z_oTherefore, when the two non-full screen windows are overlapped or completely covered, different non-full screen windows can be distinguished by different third-dimensional coordinates.

The conversion parameter may be an identity matrix, and the three-dimensional coordinate (x) extended in the graphics cache data is converted by the conversion parameter_o，y_o，z_o) Converting to obtain the non-full screen display window of the application, wherein the graphic cache data corresponding to the non-full screen display window comprises the converted (x)_o，y_o，z_o) And the RGB information of the corresponding pixel point.

Therefore, the application displayed in the full screen mode can be converted into the non-full screen window through the conversion matrix, the non-full screen windows corresponding to the multiple applications are provided for the user, and the content in the application operated by any one non-full screen window can be flexibly checked.

Preferably, the non-full screen window may also be subjected to multiple adjustments, specifically, adjusting a conversion matrix corresponding to the non-full screen window,

for example, if the non-full screen window is reduced by 1/2, the conversion matrix corresponding to the non-full screen window is changed into the conversion matrix corresponding to the non-full screen window according to the response informationThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

then the non-full screen window is moved transversely by delta x and longitudinally by delta y, and the conversion matrix of the non-full screen window isThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

the effect of this embodiment is as shown in fig. 2-3, for example, as shown in fig. 2, two non-full screen windows are currently opened, where the non-full screen window 1 is a window in a first state, that is, a window in which user interaction operation has just been completed, and the non-full screen window 2 is in a second state; when it is determined that the first non-full screen window is set to the second display state, that is, when it is determined that the control bar is added at the first non-full screen window, the position of the control bar is determined according to the position of the first non-full screen window, for example, the control bar is set at the lower edge of the first non-full screen window, and then the final display effect is as shown in fig. 3; the control bar comprises three operation keys of zooming, closing and moving.

Assuming that 3 non-full screen windows are opened currently, as shown in fig. 4, where the non-full screen window 1 is in the first state, that is, the window in which the interaction event occurs last, the non-full screen window 2 and the non-full screen window 3 are in the second state, the control bar is not displayed, and the control bar is only displayed below the non-full screen window 1.

Therefore, by using the technical scheme provided by the invention, the functional area can be displayed only in the non-full screen window in the first state, so that the number of the displayed functional areas on the electronic equipment is reduced, the situation of misoperation of a user is reduced, the use experience of the user is improved, and the usability of a plurality of small window systems is ensured.

Example II,

According to the information processing method provided by the embodiment of the invention, the electronic equipment is provided with a touch display unit, the electronic equipment can run a plurality of applications and display the applications in a display area of the touch display unit, and a full-screen display window corresponding to the applications is converted by using a conversion parameter to obtain a non-full-screen window of the applications; when the electronic equipment runs an application in a non-full screen mode and opens a non-full screen window running in the non-full screen mode; as shown in fig. 1, the method includes:

step 101: a first non-full screen window in a first state is determined in a currently open non-full screen window.

Step 102: and setting the first non-full screen window to be in a first display state.

Step 103: and acquiring first display information corresponding to the first non-full screen window.

Step 104: and determining the display information of the functional area according to the first display information.

Step 105: and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area.

Wherein the first non-full screen window in the first state is: and the non-full screen window of the last interactive event in the N windows of the non-full screen mode running application.

After the step 102 is completed, the method further includes: and switching the non-full screen window in the second state to a second display state.

And the non-full screen windows in the second state are all non-full screen windows which are not in the first state. The second display state is a state in which the functional area is not displayed at the non-full screen window.

The first display information may include: the display position of the display area of the first non-full screen window and the graphic cache data corresponding to the first non-full screen window.

The determining the display information of the functional area according to the first display information includes:

extracting the display position of the display area of the first non-full screen window from the first display information, determining the display coordinates of the functional area and the graphic cache data of the functional area according to the display position of the display area, and combining the display coordinates of the functional area and the graphic cache data into the display information of the functional area;

the functional area is an area including functional keys for controlling the states of closing, zooming, and moving the first non-full screen window as shown in fig. 2.

Wherein, the starting of the non-full screen window running in the non-full screen mode comprises: selecting an application running in a non-full screen mode, and acquiring a conversion parameter; and converting the full-screen display window corresponding to the application by using the conversion parameter to obtain a display area of the non-full-screen window of the application.

The converting the display window corresponding to the selected application by using the conversion parameter to obtain the display area of the non-full screen window of the application comprises the following steps: reading the graph cache data of the application; converting the read graph cache data by using the conversion parameter, and generating frame cache data corresponding to the touch display unit by using the graph cache data; and displaying the non-full screen window of the application on the touch display unit by utilizing the frame cache data.

The graphics cache data may include: coordinate information of each pixel point and Red, Green and Blue (RGB, Red Green Blue) three-color information of each pixel point.

Considering the situation that a superposition area possibly exists between the non-full screen display windows corresponding to the two applications, the coordinate information of the pixel points in the graphic cache data of the non-full screen display window corresponding to the applications is set as a three-dimensional coordinate (x)_o，y_o，z_o) (ii) a Wherein different non-full screen display windows have different third-dimensional coordinates z_oTherefore, when the two non-full screen windows are overlapped or completely covered, different non-full screen windows can be distinguished by different third-dimensional coordinates.

The conversion parameters take the form of: parameter values, matrices, parameter sets and parameter sets;

assuming that the conversion parameter is an identity matrix, the three-dimensional coordinate (x) extended in the graphics cache data is mapped by using the conversion parameter_o，y_o，z_o) Converting to obtain the non-full screen display window of the application, wherein the graphic cache data corresponding to the non-full screen display window comprises the converted (x)_o，y_o，z_o) And the RGB information of the corresponding pixel point.

Therefore, the application displayed in the full screen mode can be converted into the non-full screen window through the conversion matrix, the non-full screen windows corresponding to the multiple applications are provided for the user, and the content in the application operated by any one non-full screen window can be flexibly checked.

Preferably, the non-full screen window may also be subjected to multiple adjustments, specifically, adjusting a conversion matrix corresponding to the non-full screen window,

for example, if the non-full screen window is reduced by 1/2, the conversion matrix corresponding to the non-full screen window is changed into the conversion matrix corresponding to the non-full screen window according to the response informationThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

then the non-full screen window is moved transversely by delta x and longitudinally by delta y, and the conversion matrix of the non-full screen window isThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

preferably, after the step 105 is completed, the method may further include: detecting whether functional areas are displayed at other non-full screen windows except the functional area at the first non-full screen window, and if so, deleting the functional areas displayed at other non-full screen windows; otherwise, return to step 101.

The generating frame buffer data by using the first display information and the display information of the functional area and displaying the frame buffer data in the display area of the touch display unit includes:

generating frame cache data of the display module according to the first display information of the first non-full screen window and the display information of the functional area; and displaying the frame buffer data in a display area of the touch display unit.

When another non-full screen window is in the first state, the other non-full screen window is used as the first non-full screen window, and the functional area is transferred to the new first non-full screen window.

The effect of this embodiment is as shown in fig. 2-3, for example, as shown in fig. 2, two non-full screen windows are currently opened, where the non-full screen window 1 is a window in a first state, that is, a window in which user interaction operation has just been completed, and the non-full screen window 2 is in a second state; when it is determined that the first non-full screen window is set to the second display state, that is, when it is determined that the control bar is added at the first non-full screen window, the position of the control bar is determined according to the position of the first non-full screen window, for example, the control bar is set at the lower edge of the first non-full screen window, and then the final display effect is as shown in fig. 3; the control bar comprises three operation keys of zooming, closing and moving.

Assuming that 3 non-full-screen windows are opened currently, as shown in fig. 4, where the non-full-screen window 1 is in the first state, that is, the window in which the interaction event occurs last, the non-full-screen window 2 and the non-full-screen window 3 are in the second state, and set to the second display state, that is, the control bar is not displayed, and the control bar is displayed only below the non-full-screen window 1.

Therefore, by using the technical scheme provided by the embodiment of the invention, the functional area can be displayed only in the non-full screen window in the first state, so that the number of the displayed functional areas on the electronic equipment is reduced, the situation of misoperation of a user is reduced, the use experience of the user is improved, and the usability of a plurality of small window systems is ensured.

Example III,

According to the information processing method provided by the embodiment of the invention, the electronic equipment is provided with a touch display unit, the electronic equipment can run a plurality of applications and display the applications in a display area of the touch display unit, and a full-screen display window corresponding to the applications is converted by using a conversion parameter to obtain a non-full-screen window of the applications; when N windows of the non-full screen mode running application are opened, N is an integer greater than or equal to 1; as shown in fig. 1, the method includes:

step 101: a first non-full screen window in a first state is determined in a currently open non-full screen window.

Step 102: and setting the first non-full screen window to be in a first display state.

Step 103: and acquiring first display information corresponding to the first non-full screen window.

Step 104: and determining the display information of the functional area according to the first display information.

Step 105: and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area.

Wherein the first non-full screen window in the first state is: and the non-full screen window of the last interactive event in the N windows of the non-full screen mode running application.

After the step 102 is completed, the method further includes: and switching the non-full screen window in the second state to a second display state.

And the non-full screen windows in the second state are all non-full screen windows which are not in the first state. The second display state is a state in which the functional area is not displayed at the non-full screen window. The second display state is different from the first display state.

Preferably, the displaying of the functional area at the non-full screen window may be displaying at a specified position of the non-full screen window, such as displaying below, or to the right, or to the left, or to the top of the non-full screen window; fig. 3 and 4 show a state in which a control bar, which is a functional area, is displayed below the non-full screen window 1.

The first display information may include: the display position of the display area of the first non-full screen window and the graphic cache data corresponding to the first non-full screen window.

The determining the display information of the functional area according to the first display information includes:

extracting the display position of the display area of the first non-full screen window from the first display information, determining the display coordinates of the functional area and the graphic cache data of the functional area according to the display position of the display area, and combining the display coordinates of the functional area and the graphic cache data into the display information of the functional area;

the functional area is an area including functional keys for controlling the states of closing, zooming, and moving the first non-full screen window as shown in fig. 2.

Wherein, the starting of the non-full screen window running in the non-full screen mode comprises: selecting an application running in a non-full screen mode, and acquiring a conversion parameter; and converting the full-screen display window corresponding to the application by using the conversion parameter to obtain a display area of the non-full-screen window of the application.

The converting the display window corresponding to the selected application by using the conversion parameter to obtain the display area of the non-full screen window of the application comprises the following steps: reading the graph cache data of the application; converting the read graph cache data by using the conversion parameter, and generating frame cache data corresponding to the touch display unit by using the graph cache data; and displaying the non-full screen window of the application on the touch display unit by utilizing the frame cache data. The conversion parameters take the form of: parameter values, matrices, parameter sets, and parameter sets.

The graphics cache data may include: coordinate information of each pixel point and Red, Green and Blue (RGB, Red Green Blue) three-color information of each pixel point.

Considering the situation that a superposition area possibly exists between the non-full screen display windows corresponding to the two applications, the coordinate information of the pixel points in the graphic cache data of the non-full screen display window corresponding to the applications is set as a three-dimensional coordinate (x)_o，y_o，z_o) (ii) a Wherein different non-full screen display windows have different third-dimensional coordinates z_oThus, when two are notWhen the full-screen window has an overlapping area or is completely covered, different non-full-screen windows can be distinguished by different third-dimensional coordinates.

The conversion parameter may be an identity matrix, and the three-dimensional coordinate (x) extended in the graphics cache data is converted by the conversion parameter_o，y_o，z_o) Converting to obtain the non-full screen display window of the application, wherein the graphic cache data corresponding to the non-full screen display window comprises the converted (x)_o，y_o，z_o) And the RGB information of the corresponding pixel point.

Therefore, the application displayed in the full screen mode can be converted into the non-full screen window through the conversion matrix, the non-full screen windows corresponding to the multiple applications are provided for the user, and the content in the application operated by any one non-full screen window can be flexibly checked.

Preferably, the non-full screen window may also be subjected to multiple adjustments, specifically, adjusting a conversion matrix corresponding to the non-full screen window,

for example, if the non-full screen window is reduced by 1/2, the conversion matrix corresponding to the non-full screen window is changed into the conversion matrix corresponding to the non-full screen window according to the response informationThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

then the non-full screen window is moved transversely by delta x and longitudinally by delta y, and the conversion matrix of the non-full screen window isThe frame cache data corresponding to the non-full screen windowThree-dimensional coordinates (x) of each pixel point_t，y_t，z_t) Comprises the following steps:

the generating frame buffer data by using the first display information and the display information of the functional area and displaying the frame buffer data in the display area of the touch display unit includes:

adding display parameters of the functional area in the display information of the functional area; generating frame buffer data of the display module according to the first display information and the display information of the functional area; and displaying the frame buffer data in a display area of the touch display unit.

Wherein the display parameters of the functional area may include: display color, display transparency, and the like of the functional region.

After the step 105 is completed, the method may further include: timing when the first non-full screen window interaction event is completed; when the timing time reaches a preset time threshold, generating a judgment result; and changing the display parameters of the first non-full screen window according to the judgment result, and changing the display effect of the first non-full screen window.

Wherein the display effect may be to completely hide a functional area in the first non-full screen window; alternatively, the functional area of the first non-full screen window may be converted into a semi-transparent state.

The effect of this embodiment is as shown in fig. 2-3, for example, as shown in fig. 2, two non-full screen windows are currently opened, where the non-full screen window 1 is a window in a first state, that is, a window in which user interaction operation has just been completed, and the non-full screen window 2 is in a second state; when it is determined that the first non-full screen window is set to the second display state, that is, when it is determined that the control bar is added at the first non-full screen window, the position of the control bar is determined according to the position of the first non-full screen window, for example, the control bar is set at the lower edge of the first non-full screen window, and then the final display effect is as shown in fig. 3; the control bar comprises three operation keys of zooming, closing and moving.

Assuming that 3 non-full-screen windows are opened currently, as shown in fig. 4, where the non-full-screen window 1 is in the first state, that is, the window in which the interaction event occurs last, the non-full-screen window 2 and the non-full-screen window 3 are in the second state, and set to the second display state, that is, the control bar is not displayed, and the control bar is displayed only below the non-full-screen window 1.

Therefore, by using the technical scheme provided by the embodiment of the invention, the functional area can be displayed only in the non-full screen window in the first state, so that the number of the displayed functional areas on the electronic equipment is reduced, the situation of misoperation of a user is reduced, the use experience of the user is improved, and the usability of a plurality of small window systems is ensured.

In addition, the embodiment of the invention can change the display parameters of the functional area, so that diversified operation interfaces can be provided, and the use experience of a user is improved.

Example four,

According to the electronic device provided by the embodiment of the invention, the electronic device can be a mobile terminal, such as a smart phone, a tablet computer and the like; as shown in fig. 5, the electronic device includes: the touch control display unit and the processing unit; wherein,

the touch display unit is used for converting a full-screen display window corresponding to the application by using a conversion parameter to obtain a non-full-screen window of the application; when N windows of the application running in the non-full screen mode are opened, N is an integer greater than or equal to 1, and the non-full screen window running in the non-full screen mode is opened to select a first non-full screen window in a first state in the currently opened non-full screen windows in the touch display unit;

the processing unit is used for running a plurality of applications, displaying the applications in a display area of the touch display unit, and determining a first non-full screen window in a first state in a currently opened non-full screen window; setting the first non-full screen window to be in a first display state; acquiring first display information corresponding to the first non-full screen window; and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area, and displaying the display interface in a display area of the touch display unit.

The processing unit is specifically configured to take a non-full screen window, in which an interaction event occurs last time, of the windows in which the applications run in the N non-full screen modes as a first non-full screen window in a first state.

The first display information may include: the display position of the display area of the first non-full screen window and the graphic cache data corresponding to the first non-full screen window.

The processing unit is specifically configured to extract a display position of a display area of the first non-full screen window from the first display information, determine display coordinates of the functional area and graphics cache data of the functional area according to the display position of the display area, and synthesize the display coordinates of the functional area and the graphics cache data into the display information of the functional area;

as shown in fig. 3, the functional area is assumed to be an area containing functional keys for controlling the states of closing, zooming, and moving of the first non-full screen window 1.

The processing unit is specifically used for selecting an application running in a non-full screen mode and acquiring a conversion parameter; and converting the full-screen display window corresponding to the application by using the conversion parameter to obtain a display area of the non-full-screen window of the application.

The processing unit is specifically configured to read the graph cache data of the application; converting the read graph cache data by using the conversion parameter, and generating frame cache data corresponding to the touch display unit by using the graph cache data; and displaying the non-full screen window of the application on the touch display unit by utilizing the frame cache data.

The graphics cache data may include: coordinate information of each pixel point and Red, Green and Blue (RGB, Red Green Blue) three-color information of each pixel point.

Considering the situation that a superposition area possibly exists between the non-full screen display windows corresponding to the two applications, the coordinate information of the pixel points in the graphic cache data of the non-full screen display window corresponding to the applications is set as a three-dimensional coordinate (x)_o，y_o，z_o) (ii) a Wherein different non-full screen display windows have different third-dimensional coordinates z_oTherefore, when the two non-full screen windows are overlapped or completely covered, different non-full screen windows can be distinguished by different third-dimensional coordinates.

The conversion parameter may be an identity matrix, and the three-dimensional coordinate (x) extended in the graphics cache data is converted by the conversion parameter_o，y_o，z_o) Converting to obtain the non-full screen display window of the application, wherein the graphic cache data corresponding to the non-full screen display window comprises the converted (x)_o，y_o，z_o) And the RGB information of the corresponding pixel point. The conversion parameters take the form of: parameter values, matrices, parameter sets, and parameter sets.

Therefore, the application displayed in the full screen mode can be converted into the non-full screen window through the conversion matrix, the non-full screen windows corresponding to the multiple applications are provided for the user, and the content in the application operated by any one non-full screen window can be flexibly checked.

Preferably, the processing unit may further perform various adjustments on the non-full screen window, where the adjustment is specifically to adjust a conversion matrix corresponding to the non-full screen window,

for example, if the non-full screen window is reduced by 1/2, the conversion matrix corresponding to the non-full screen window is changed into the conversion matrix corresponding to the non-full screen window according to the response informationThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

then the non-full screen window is moved transversely by delta x and longitudinally by delta y, and the conversion matrix of the non-full screen window isThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

the effect of this embodiment is as shown in fig. 2-3, for example, as shown in fig. 2, two non-full screen windows are currently opened, where the non-full screen window 1 is a window in a first state, that is, a window in which user interaction operation has just been completed, and the non-full screen window 2 is in a second state; when it is determined that the first non-full screen window is set to the second display state, that is, when it is determined that the control bar is added at the first non-full screen window, the position of the control bar is determined according to the position of the first non-full screen window, for example, the control bar is set at the lower edge of the first non-full screen window, and then the final display effect is as shown in fig. 3; the control bar comprises three operation keys of zooming, closing and moving.

Assuming that 3 non-full-screen windows are opened currently, as shown in fig. 4, where the non-full-screen window 1 is in the first state, that is, the window in which the interaction event occurs last, the non-full-screen window 2 and the non-full-screen window 3 are in the second state, and set to the second display state, that is, the control bar is not displayed, and the control bar is displayed only below the non-full-screen window 1.

Therefore, by using the electronic equipment provided by the invention, the functional area can be displayed only in the non-full screen window which is currently in the first state, so that the number of the displayed functional areas on the electronic equipment is reduced, the situation that the user has misoperation is reduced, the use experience of the user is improved, and the usability of a plurality of small window systems is ensured.

Example V,

According to the electronic device provided by the embodiment of the invention, the electronic device can be a mobile terminal, such as a smart phone, a tablet computer and the like; as shown in fig. 5, the electronic device includes: the touch control display unit and the processing unit; wherein,

the touch display unit is used for converting a full-screen display window corresponding to the application by using a conversion parameter to obtain a non-full-screen window of the application; when N windows of the application running in the non-full screen mode are opened, N is an integer greater than or equal to 1, and the non-full screen window running in the non-full screen mode is opened to select a first non-full screen window in a first state in the currently opened non-full screen windows in the touch display unit;

the processing unit is used for running a plurality of applications, displaying the applications in a display area of the touch display unit, and determining a first non-full screen window in a first state in a currently opened non-full screen window; setting the first non-full screen window to be in a first display state; acquiring first display information corresponding to the first non-full screen window; and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area and displaying the display interface in a display area of the touch display unit.

The processing unit is specifically configured to take a non-full screen window, in which an interaction event occurs last time, of the windows in which the applications run in the N non-full screen modes as a first non-full screen window in a first state.

The first display information may include: the display position of the display area of the first non-full screen window and the graphic cache data corresponding to the first non-full screen window.

The processing unit is further configured to switch the non-full screen window in the second state to the second display state. The non-full screen window in the second state is all non-full screen windows which are not in the first state; (ii) a The second display state is different from the first display state, and the second display state is a state in which the functional region is not displayed.

The processing unit is specifically configured to extract a display position of a display area of the first non-full screen window from the first display information, determine display coordinates of the functional area and graphics cache data of the functional area according to the display position of the display area, and synthesize the display coordinates of the functional area and the graphics cache data into the display information of the functional area;

the functional area is an area containing functional keys for controlling the states of closing, zooming, moving and the like of the first non-full screen window.

The processing unit is specifically used for selecting an application running in a non-full screen mode and acquiring a conversion parameter; and converting the full-screen display window corresponding to the application by using the conversion parameter to obtain a display area of the non-full-screen window of the application. The conversion parameters take the form of: parameter values, matrices, parameter sets, and parameter sets.

The processing unit is specifically configured to read the graph cache data of the application; converting the read graph cache data by using the conversion parameter, and generating frame cache data corresponding to the touch display unit by using the graph cache data; and displaying the non-full screen window of the application on the touch display unit by utilizing the frame cache data.

The graphics cache data may include: coordinate information of each pixel point and Red, Green and Blue (RGB, Red Green Blue) three-color information of each pixel point.

Considering the situation that a superposition area possibly exists between the non-full screen display windows corresponding to the two applications, the coordinate information of the pixel points in the graphic cache data of the non-full screen display window corresponding to the applications is set as a three-dimensional coordinate (x)_o，y_o，z_o) (ii) a Wherein different non-full screen display windows have different third-dimensional coordinates z_oTherefore, when the two non-full screen windows are overlapped or completely covered, different non-full screen windows can be distinguished by different third-dimensional coordinates.

The conversion parameter may be an identity matrix, and the three-dimensional coordinate (x) extended in the graphics cache data is converted by the conversion parameter_o，y_o，z_o) Converting to obtain the non-full screen display window of the application, wherein the graphic cache data corresponding to the non-full screen display window comprises the converted (x)_o，y_o，z_o) And the RGB information of the corresponding pixel point.

Therefore, the application displayed in the full screen mode can be converted into the non-full screen window through the conversion matrix, the non-full screen windows corresponding to the multiple applications are provided for the user, and the content in the application operated by any one non-full screen window can be flexibly checked.

Preferably, the processing unit may further perform various adjustments on the non-full screen window, where the adjustment is specifically to adjust a conversion matrix corresponding to the non-full screen window,

for example, if the non-full screen window is reduced by 1/2, the conversion matrix corresponding to the non-full screen window is changed into the conversion matrix corresponding to the non-full screen window according to the response informationThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

then the non-full screen window is moved transversely by delta x and longitudinally by delta y, and the conversion matrix of the non-full screen window isThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

the processing unit is further configured to generate frame cache data of the display module according to the first display information of the first non-full screen window and according to the display information of the functional area; and displaying the frame buffer data in a display area of the touch display unit.

The effect of this embodiment is as shown in fig. 2-3, for example, as shown in fig. 2, two non-full screen windows are currently opened, where the non-full screen window 1 is a window in a first state, that is, a window in which user interaction operation has just been completed, and the non-full screen window 2 is in a second state; when it is determined that the first non-full screen window is set to the second display state, that is, when it is determined that the control bar is added at the first non-full screen window, the position of the control bar is determined according to the position of the first non-full screen window, for example, the control bar is set at the lower edge of the first non-full screen window, and then the final display effect is as shown in fig. 3; the control bar comprises three operation keys of zooming, closing and moving.

Assuming that 3 non-full-screen windows are opened currently, as shown in fig. 4, where the non-full-screen window 1 is in the first state, that is, the window in which the interaction event occurs last, the non-full-screen window 2 and the non-full-screen window 3 are in the second state, and set to the second display state, that is, the control bar is not displayed, and the control bar is displayed only below the non-full-screen window 1.

Therefore, by using the electronic equipment provided by the invention, the functional area can be displayed only in the non-full screen window which is currently in the first state, so that the number of the displayed functional areas on the electronic equipment is reduced, the situation that the user has misoperation is reduced, the use experience of the user is improved, and the usability of a plurality of small window systems is ensured.

Example six,

According to the electronic device provided by the embodiment of the invention, the electronic device can be a mobile terminal, such as a smart phone, a tablet computer and the like; as shown in fig. 5, the electronic device includes: the touch control display unit and the processing unit; wherein,

the touch display unit is used for converting a full-screen display window corresponding to the application by using a conversion parameter to obtain a non-full-screen window of the application; when N windows of the application running in the non-full screen mode are opened, N is an integer greater than or equal to 1, and the non-full screen window running in the non-full screen mode is opened to select a first non-full screen window in a first state in the currently opened non-full screen windows in the touch display unit;

the processing unit is used for running a plurality of applications, displaying the applications in a display area of the touch display unit, and determining a first non-full screen window in a first state in a currently opened non-full screen window; setting the first non-full screen window to be in a first display state; acquiring first display information corresponding to the first non-full screen window; and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area and displaying the display interface in a display area of the touch display unit.

The processing unit is specifically configured to take a non-full screen window, in which an interaction event occurs last time, of the windows in which the applications run in the N non-full screen modes as a first non-full screen window in a first state.

The first display information may include: the display position of the display area of the first non-full screen window and the graphic cache data corresponding to the first non-full screen window.

The processing unit is further configured to switch the non-full screen window in the second state to the second display state. The non-full screen window in the second state is all non-full screen windows which are not in the first state; (ii) a The second display state is different from the first display state, and the second display state is a state in which the functional region is not displayed.

The processing unit is specifically configured to extract a display position of a display area of the first non-full screen window from the first display information, determine display coordinates of the functional area and graphics cache data of the functional area according to the display position of the display area, and synthesize the display coordinates of the functional area and the graphics cache data into the display information of the functional area;

the functional area comprises an area of functional keys for controlling the states of closing, zooming, moving and the like of the first non-full screen window.

The processing unit is specifically used for selecting an application running in a non-full screen mode and acquiring a conversion parameter; and converting the full-screen display window corresponding to the application by using the conversion parameter to obtain a display area of the non-full-screen window of the application.

The processing unit is specifically configured to read the graph cache data of the application; converting the read graph cache data by using the conversion parameter, and generating frame cache data corresponding to the touch display unit by using the graph cache data; and displaying the non-full screen window of the application on the touch display unit by utilizing the frame cache data.

The graphics cache data may include: coordinate information of each pixel point and Red, Green and Blue (RGB, Red Green Blue) three-color information of each pixel point.

Considering the situation that a superposition area possibly exists between the non-full screen display windows corresponding to the two applications, the coordinate information of the pixel points in the graphic cache data of the non-full screen display window corresponding to the applications is set as a three-dimensional coordinate (x)_o，y_o，z_o) (ii) a Wherein different non-full screen display windows have different third-dimensional coordinates z_oTherefore, when the two non-full screen windows are overlapped or completely covered, different non-full screen windows can be distinguished by different third-dimensional coordinates.

The conversion parameter may be an identity matrix, and the three-dimensional coordinate (x) extended in the graphics cache data is converted by the conversion parameter_o，y_o，z_o) Converting to obtain the non-full screen display window of the application, wherein the graphic cache data corresponding to the non-full screen display window comprises the converted (x)_o，y_o，z_o) And the RGB information of the corresponding pixel point.

Therefore, the application displayed in the full screen mode can be converted into the non-full screen window through the conversion matrix, the non-full screen windows corresponding to the multiple applications are provided for the user, and the content in the application operated by any one non-full screen window can be flexibly checked.

Preferably, the processing unit may further perform various adjustments on the non-full screen window, where the adjustment is specifically to adjust a conversion matrix corresponding to the non-full screen window,

for example, if the non-full screen window is reduced by 1/2, the conversion matrix corresponding to the non-full screen window is changed into the conversion matrix corresponding to the non-full screen window according to the response informationThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

then the non-full screen window is moved transversely by delta x and longitudinally by delta y, and the conversion matrix of the non-full screen window isThe three-dimensional coordinate (x) of each pixel point in the frame cache data corresponding to the non-full screen window_t，y_t，z_t) Comprises the following steps:

the processing unit is further configured to add a display parameter of the functional area to the display information of the functional area; generating frame buffer data of the display module according to the first display information and the display information of the functional area; and displaying the frame buffer data in a display area of the touch display unit.

Wherein the display parameters of the functional area may include: display color, display transparency, and the like of the functional region.

Preferably, the processing unit may be further configured to time when the first non-full-screen window interaction event is completed; when the timing time reaches a preset time threshold, generating a judgment result; and changing the display parameters of the first non-full screen window according to the judgment result, and changing the display effect of the first non-full screen window.

The effect of this embodiment is as shown in fig. 2-3, for example, as shown in fig. 2, two non-full screen windows are currently opened, where the non-full screen window 1 is a window in a first state, that is, a window in which user interaction operation has just been completed, and the non-full screen window 2 is in a second state; when it is determined that the first non-full screen window is set to the second display state, that is, when it is determined that the control bar is added at the first non-full screen window, the position of the control bar is determined according to the position of the first non-full screen window, for example, the control bar is set at the lower edge of the first non-full screen window, and then the final display effect is as shown in fig. 3; the control bar comprises three operation keys of zooming, closing and moving.

Assuming that 3 non-full-screen windows are opened currently, as shown in fig. 4, where the non-full-screen window 1 is in the first state, that is, the window in which the interaction event occurs last, the non-full-screen window 2 and the non-full-screen window 3 are in the second state, and set to the second display state, that is, the control bar is not displayed, and the control bar is displayed only below the non-full-screen window 1.

Therefore, by using the electronic equipment provided by the invention, the functional area can be displayed only in the non-full screen window which is currently in the first state, so that the number of the displayed functional areas on the electronic equipment is reduced, the situation that the user has misoperation is reduced, the use experience of the user is improved, and the usability of a plurality of small window systems is ensured.

In addition, the embodiment of the invention can change the display parameters of the functional area, so that diversified operation interfaces can be provided, and the use experience of a user is improved.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above-described device embodiments are merely illustrative, for example, the division of the unit is only a logical functional division, and there may be other division ways in actual implementation, such as: multiple units or components may be combined, or may be integrated into another system, or some features may be omitted, or not implemented. In addition, the coupling, direct coupling or communication connection between the components shown or discussed may be through some interfaces, and the indirect coupling or communication connection between the devices or units may be electrical, mechanical or other forms.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed on a plurality of network units; some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, all the functional units in the embodiments of the present invention may be integrated into one processing module, or each unit may be separately used as one unit, or two or more units may be integrated into one unit; the integrated unit can be realized in a form of hardware, or in a form of hardware plus a software functional unit.

Those of ordinary skill in the art will understand that: all or part of the steps for implementing the method embodiments may be implemented by hardware related to program instructions, and the program may be stored in a computer readable storage medium, and when executed, the program performs the steps including the method embodiments; and the aforementioned storage medium includes: a mobile storage device, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (14)

1. An information processing method is applied to electronic equipment, the electronic equipment is provided with a touch display unit, the electronic equipment can run a plurality of applications and display the applications in a display area of the touch display unit, and the electronic equipment converts a full-screen display window corresponding to the applications by using conversion parameters to obtain a non-full-screen window of the applications; when N windows of the non-full screen mode running application are opened, N is an integer greater than or equal to 1; the method comprises the following steps:

determining a first non-full screen window in a first state in a currently opened non-full screen window;

setting the first non-full screen window to be in a first display state;

acquiring first display information corresponding to the first non-full screen window;

determining display information of a functional area according to the first display information;

and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area, and not displaying the functional area on other non-full screen windows in the non-first state except the first non-full screen window.

2. The method of claim 1, further comprising:

switching the non-full screen window in the second state to a second display state;

the second display state is different from the first display state.

3. The method of claim 2, wherein the first non-full screen window in the first state is: and the non-full screen window of the last interactive event in the N windows of the non-full screen mode running application.

4. The method according to claim 3, wherein the generating frame buffer data by using the first display information and the display information of the functional area and displaying the frame buffer data in the display area of the touch display unit comprises:

generating frame cache data of the touch display unit according to the first display information of the first non-full screen window and the display information of the functional area;

and displaying the frame buffer data in a display area of the touch display unit.

5. The method of claim 4, wherein before generating frame buffer data of the touch-sensitive display unit according to the first display information of the first non-full-screen window and according to the display information of the functional area, the method further comprises:

and adding the display parameters of the functional area in the display information of the functional area.

6. The method according to any one of claims 1 to 5, wherein the determining the display information of the functional area according to the first display information comprises:

extracting the display position of the display area of the first non-full screen window from the first display information, determining the display coordinates of the functional area and the graphic cache data of the functional area according to the display position of the display area, and combining the display coordinates of the functional area and the graphic cache data into the display information of the functional area.

7. The method of claim 6, wherein the form of the conversion parameter comprises at least one of: conversion matrix, parameters, parameter set.

8. An electronic device, the electronic device comprising: the touch control display unit and the processing unit; wherein,

the touch display unit is used for converting a full-screen display window corresponding to the application by using the conversion parameter to obtain a non-full-screen window of the application; when N windows of the non-full screen mode running application are opened, N is an integer greater than or equal to 1;

the processing unit is used for running a plurality of applications, displaying non-full screen windows of the applications in a display area of the touch display unit, and determining a first non-full screen window in a first state in the currently opened non-full screen windows; setting the first non-full screen window to be in a first display state; acquiring first display information corresponding to the first non-full screen window; determining display information of a functional area according to the first display information; and generating a display interface of the first non-full screen window by using the first display information and the display information of the functional area, and not displaying the functional area on other non-full screen windows in the non-first state except the first non-full screen window.

9. The electronic device of claim 8,

the processing unit is further used for switching the non-full screen window in the second state to the second display state; the second display state is different from the first display state.

10. The electronic device of claim 9,

the processing unit is specifically configured to take a non-full screen window, in which an interaction event occurs last time, of the windows in which the applications run in the N non-full screen modes as a first non-full screen window in a first state.

11. The electronic device according to claim 10, wherein the processing unit is specifically configured to generate frame buffer data of the touch display unit according to the first display information of the first non-full screen window and according to the display information of the functional area; and displaying the frame buffer data in a display area of the touch display unit.

12. The electronic device according to claim 11, wherein the processing unit is further configured to add a display parameter of the functional area to the display information of the functional area.

13. The electronic device according to any one of claims 8 to 12, wherein the processing unit is specifically configured to extract a display position of a display area of the first non-full screen window from the first display information, determine display coordinates of the functional area and graphics cache data of the functional area according to the display position of the display area, and combine the display coordinates of the functional area and the graphics cache data into the display information of the functional area.

14. The electronic device of claim 13, wherein the form of the conversion parameter comprises at least one of: conversion matrix, parameters, parameter set.