CN104657034A - Dynamic window layout adjusting system and method - Google Patents

Abstract

The invention provides a dynamic window layout adjustment method, which divides a main window into a display area and a floating area, wherein the upper area and the lower area of the floating area respectively display a layout style and a menu list, the display area is divided into a plurality of display columns, and each display column displays a limited number of windows. When a user drags a menu item to a display bar, a window of the menu item is opened, and the size of the display bar is evenly distributed by the existing window and the window of the menu item. When a user drags a window in a display bar to a menu list, the dragged window is closed, and the size of the display bar is evenly distributed to the rest windows in the display bar. In addition, the invention also provides a system for dynamically adjusting the window layout.

Description

Window layout dynamic debugging system and method

Technical field

The present invention relates to the technology of user interface, particularly relate to the technology of window or page display.

Background technology

Now, no matter be the public places such as subway, hospital or market, multiple self-service terminal machine or giant-screen all can be set up to notice hurdle, to be convenient for people to obtain information on services etc.Such as, in subway self-service terminal machine facilitate passenger pay subway card expense or travel route inquiry or city sites introduction, megastore provides iPad to check market layout and various preferential advertising campaigns etc. to user.When people use said system, open multiple window to browse detailed information.User more wishes that the information of multiple window is checked at the interface integrated by, instead of opens multiple window and repeatedly switch window is checked.

At present, various application program realizes the display of multiple window or the page by following two kinds of different modes: 1) click the menu option of menu list or the label option of index tab, switches the window that each option of display is corresponding in a viewing area; 2) thumbnail buttons is clicked, all windows after a viewing area display on average reduces certain proportion.First method user can click different menu options flexibly and switch the corresponding window of display, but cannot show multiple window simultaneously; Second method user can show all windows simultaneously, but user cannot select the window that will show flexibly, and when window number is too much, each window inconvenience user after on average reducing checks.

Summary of the invention

In view of foregoing, be necessary to provide a kind of window layout dynamic debugging system and method, multiple window can be shown simultaneously, and user can select the layout of window and the adjustment window shown, and facilitates user to check the content of different windows simultaneously.

Described window layout dynamic debugging system comprises: cutting module, for being viewing area and floating zone by main window cutting, and viewing area cutting is multiple display field to the layout pattern chosen according to user and each display field shows limited number window, this floating zone is divided into upper and lower two regions display layout's pattern and menu list respectively, this layout pattern is the form of n × m, m refers to the number of display field, and n is the higher limit of window sum in each display field; Determination module, for judging that user is that the window that drags in menu item to display field or drag in display field is to menu list; Order module, for when dragging menu item existing window number not reaching higher limit to display field and in this display field, the relatively origin coordinates of the existing origin coordinates of window and the icon of this menu item ascending sort in this display field, this clooating sequence is the line number of the window of existing window and this menu item in this display field; This order module also for, when drag the window in display field to menu list and remain in this display field window sum be greater than zero time, relatively this display field is interior except being dragged the origin coordinates ascending sort that are remained window except window, and this clooating sequence is the line number of residue window in this display field; Computing module, for according to window sum in ranking results and display field, calculates new size and the origin coordinates of each window in display field; Adjusting module, for when dragging menu item to display field, opens the window of this menu item, according to above-mentioned result of calculation, adjusts size and the display position of the window of existing window and menu item in this display field; This adjusting module also for, when dragging the window in display field to menu list, closing the window of this dragging, according to above-mentioned result of calculation, adjusting the size and display position that remain window in this display field.

Described window layout dynamic adjusting method comprises: main window cutting is viewing area and floating zone by (a), and viewing area cutting is multiple display field to the layout pattern chosen according to user and each display field shows limited number window, this floating zone is divided into upper and lower two regions display layout's pattern and menu list respectively, this layout pattern is the form of n × m, m refers to the number of display field, and n is the higher limit of window sum in each display field; B () judges that user is that the window that drags in menu item to display field or drag in display field is to menu list; C () is when dragging menu item existing window number not reaching higher limit to display field and in this display field, the relatively origin coordinates of the existing origin coordinates of window and the icon of this menu item ascending sort in this display field, this clooating sequence is the line number of the window of existing window and this menu item in this display field; (d) when drag the window in display field to menu list and remain in this display field window sum be greater than zero time, relatively this display field is interior except being dragged the origin coordinates ascending sort that are remained window except window, and this clooating sequence is the line number of residue window in this display field; E (), according to window sum in ranking results and display field, calculates new size and the origin coordinates of each window in display field; F (), when dragging menu item is to display field, opens the window of this menu item, according to above-mentioned result of calculation, adjust size and the display position of the window of existing window and menu item in this display field; G (), when dragging the window in display field to menu list, is closed the window of this dragging, according to above-mentioned result of calculation, is adjusted the size and display position that remain window in this display field.

Compared to existing technology, window layout dynamic debugging system of the present invention can freely determine by user the window needing display, and the layout adjusting multiple window is checked with applicable individual subscriber, menu option is selected to switch display without the need to user between multiple window by not rest point.

Accompanying drawing explanation

Fig. 1 is the running environment figure of window layout dynamic debugging system of the present invention preferred embodiment.

Fig. 2 is the method flow diagram of window layout dynamic adjusting method of the present invention preferred embodiment.

Fig. 3 is the method flow diagram switched between different layout pattern.

Fig. 4-A, Fig. 4-B are layout pattern respectively when being 2 × 2,2 × 3, the cutting schematic diagram of viewing area.

Fig. 5-A to 5-F is layout pattern is 3 × 3, and user drags the schematic diagram that menu item increases, replaces, removes with dragging window to display field to the window in display field during menu list.

Fig. 6-A, 6-B are layout pattern is switched to 2 × 3 by user schematic diagram by 3 × 3.

Main element symbol description

Electronic equipment	1
		Window layout dynamic debugging system	10
Processor	20
		Storer	30
Touch display screen	40
		Main window	50
Viewing area	60
		Floating zone	70
Layout pattern	71
		Float icon	72
Menu list	73
		Display field	80
Cutting module	101
		Determination module	102
Order module	103
		Computing module	104
Replace module	105
		Adjusting module	106
Handover module	107
		Calculating sub module	1071
Cutting submodule	1072

Screening submodule	1073
		Adjustment submodule	1074
Decision sub-module	1075

Following embodiment will further illustrate technical scheme of the present invention in conjunction with above-mentioned accompanying drawing.

Embodiment

Consulting shown in Fig. 1, is the running environment figure of window layout dynamic debugging system of the present invention preferred embodiment.Described window layout dynamic debugging system 10 is applied in electronic equipment 1.This electronic equipment 1 comprises processor 20, storer 30, touch display screen 40 and other peripheral interface circuits and electric power supply circuit etc.This electronic equipment 1 can be panel computer, electronic announcement board etc.

This processor 20, for executive routine code, controls the collaborative work coordinating each element.This processor 20 can be monokaryon or multinuclear.This storer 30 is for program code stored, each windows content and form data etc.The program code of described window layout dynamic debugging system 10 is preserved in memory 30, and is controlled to perform by processor 20.

This touch display screen 40 is for providing a user and the mutual interface of electronic equipment 1, can be capacitive touch screen or resistive touch screen, the touch-control event or drag events that occur in screen plurality of positions can be sensed, comprise the perception of the behaviors such as the slip/dragging in the pressing to screen, single multi-point touch, certain area.The present invention is not limited to the display screen of touch technology, and the display screen for non-touch-control is applicable equally, and now, user and electronic equipment 1 are not by the behavior of screen touch-control alternately but user carries out the clicking operation of right and left key by electronic equipment 1 external access of mouse.

Consult shown in Fig. 1, this window layout dynamic debugging system 10 comprises multiple functional module, is cutting module 101, determination module 102, order module 103, computing module 104, replacement module 105, adjusting module 106 respectively.The program segment completing certain function that described functional module is made up of program code, is more suitable for describing software implementation within a processor than program.Process flow diagram below in conjunction with Fig. 2 describes the function of each module in detail.

Fig. 1 is only example, and in actual applications, the application of described window layout dynamic debugging system 10 is not limited in this.

It should be noted that, described window layout dynamic debugging system 10 integrates with certain application service system (as urban traffic service system, school business management system, hospital management system etc.), this application service system is made up of webpage or Windows window etc., and user can carry out certain operation (as inquiry, newly-increased, amendment, deletion etc.) by each window.After this application service system and described window layout dynamic debugging system 10 being integrated, making user when using this application service system, the window of display can be chosen flexibly and adjust the layout of window.

Consulting shown in Fig. 2, is the method flow diagram of window layout dynamic adjusting method of the present invention.In this process flow diagram, the order of step can change, and some step can be omitted, merges or disassemble.

Step S01, initialization main window, the transverse axis of cutting module 101 pairs of main windows is with the ratio cutting of a:b, and cutting is region, two, left and right, is viewing area and floating zone respectively.

As shown in Fig. 4-A, in this preferred embodiment, with the main window upper left corner for true origin, the transverse axis of main window is X-axis, and the longitudinal axis is Y-axis, carries out cutting to main window transverse axis with the ratio of a:b, and region, two, the left and right after cutting is respectively viewing area and floating zone.Origin coordinates (the x of this viewing area ₁, y ₁) be (0,0) and length width w1=W, the origin coordinates of floating zone is length is width is W, and wherein L, W are respectively the length and width of main window, a, b be respectively be greater than zero natural number, such as with the ratio of 3:1 or with the ratio of 4:1, cutting is carried out to the transverse axis of main window, then as shown in Fig. 4-A, this floating zone is divided into upper and lower two regions, respectively display layout's pattern 71 and menu list 73.It should be noted that, above-mentioned main window, viewing area, floating zone and the follow-up display field and window etc. mentioned, for rectangular region, and definition horizontal direction is for long, vertical direction is wide, and the coordinate of rectangle upper left angle point is the origin coordinates of main window, viewing area, floating zone, display field and window.

As shown in Fig. 4-A, main window 50 cutting is two, left and right rectangular region by cutting module 101, is respectively viewing area 60 and floating zone 70, and this floating zone be hidden or be shown to click float icon 72 can.As shown in Fig. 4-A, floating zone 70 is display state, now, float icon 72 is the arrow towards right sensing, clicks this icon and then hides floating zone 70, otherwise, when floating zone 70 is hidden state, float icon 72 is the arrow towards left sensing, clicks this icon and then shows floating zone 70.When hide or when showing this floating zone, the corresponding increase of area size of the viewing area 60 in left side or reduction.Described menu list 73 includes all menu items that above-mentioned application service system provides, and each menu item is corresponding with a window.

Step S02, according to the layout pattern that user chooses, cutting module 101 pairs of viewing area transverse axis are divided into multiple display field and show the window of some in each display field.

Described layout pattern is the form of n × m, refers to that, to viewing area transverse axis m decile, each region after decile is a display field, and to each display field longitudinal axis n decile, each region after decile is that a window region is for showing a window.It should be noted that, the higher limit of the window number shown in each display field is n, but in actual user's operating process, determines the window number (being no more than higher limit) of actual displayed in each display field according to the demand of user.

As shown in Fig. 4-A, three kinds of layout pattern are provided in this preferred embodiment, be 2 × 2,2 × 3 and 3 × 3 respectively, the screen size of the hardware device that can run according to this window layout dynamic debugging system 10 in other embodiments sets different layout pattern.

In this preferred embodiment, each display field after the transverse axis cutting of viewing area order is from left to right the row number of each display field, after the cutting of each display field longitudinal axis, each window order is from top to bottom the line number of each window, and in each display field, the row number of each window equal the row number of this window place display field.

In this preferred embodiment, in order to increase visuality, between display field and main window up-and-down boundary, between each display field and between each window, there is certain interval.As shown in Fig. 4-B, cutting module 101, by the transverse axis m decile of viewing area, is divided into m display field, then the length l of each display field ₂=(l ₁-m × β) m, width w ₂=w ₁-2 α, the X-axis component x of the origin coordinates of each display field ₂=c β+(c-1) l ₂, Y-axis component y ₂=α, wherein, l ₁, w ₁be respectively length and the width of viewing area, c is the row number of display field, and m is the number of display field, and α is the distance at each display field and main window up-and-down boundary interval, and β is the distance at interval between each display field.

As shown in Fig. 4-A, when layout pattern is 2 × 2, halved by viewing area 60 transverse axis, the row number of display field 80 are from left to right respectively 1,2, and each display field 80 is display two windows at most.As shown in Fig. 4-B, when layout pattern is 2 × 3, viewing area 60 transverse axis trisection, the row number of display field 80 are from left to right respectively 1,2,3, and each display field 80 is display two windows at most.

Step S03, determination module 102 judges that user drags in certain menu item to certain display field and still drags window in certain display field to menu list.When dragging menu item to display field, entering step S04, when dragging the window in certain display field to menu list, then entering step S10.

In this preferred embodiment, when dragging the menu item in menu list in display field, then in this display field, open the window of this menu item, when dragging the window in display field to menu list, then in this display field, this window is closed.Determination module 102 by by the judgement drag object of user and the initial sum final position of dragging, determines the operation that the current drag operation of user closes window or the operation of opening window.

As shown in fig. 5-A, when user drags menu item A, occur that mark has the rectangular icon (in figure shown in dashed rectangle) of menu item A, the coordinate of this rectangle upper left angle point is the origin coordinates of this menu item icons, the icon dragging this menu item A is the display field of 1 to row number, after discharging the icon of this menu item A, as shown in fig. 5-b, increase the window of this menu item A in this display field, in menu list, delete menu item A.As shown in Fig. 5-E, user drags window D to menu list, and when after this window of release, as shown in Fig. 5-F, close window in this display field D, remains each window adjusting window size and display position and increase menu item D in menu list.

Step S04, judges whether the sum of the existing window in this display field reaches the upper limit, if then enter step S05, otherwise enters step S06.

As shown in Fig. 5-A to 5-F, the layout pattern that user chooses is 3 × 3, then open in each display field or the window sum that shows is no more than 3.

Step S05, when drag menu item to display field and in this display field existing window add up to higher limit, then replace the window that module 105 falls into the origin coordinates that the window of the menu item of this dragging replaces this menu item icons, and delete the menu item of this dragging in menu list and increase the menu item that this is substituted window.

As shown in Fig. 5-D, current layout pattern is 3 × 3, and it is in the process of the display field of 1 that user drags menu item D to row number, and the origin coordinates of the icon of this menu item D is illustrated rectangle diagram target upper left corner point coordinate.After the icon of this menu item of release D, as shown in Fig. 5-E, in this display field, existing window adds up to 3, the window C that the origin coordinates point that then the window D of menu item D replaces the icon of this menu item D falls into, and delete the menu item D of this dragging in menu list and increase the menu item C of the window C that this is substituted.

Step S06, order module 103 compares the origin coordinates ascending sort that have the origin coordinates of window and the icon of this menu item in this display field, and this clooating sequence is the line number of the window of existing window and this menu item in this display field.

As shown in fig. 5-A, the display field that menu item A to row number is 1 is dragged, in dragging process, there is the rectangular icon of this menu item A, with rectangle top left co-ordinate for origin coordinates, in this display field, existing window number is 0, then the line number being about to the window A of the menu item A opened is 1.

As shown in fig. 5-b, dragging menu item B is that in the display field of 1, opened window A in this display field, window A origin coordinates is less than the origin coordinates of the icon of menu item B, then the line number of window A is 1, and the line number being about to the window B of the menu item B opened is 2 to row number.

As shown in fig. 5-c, dragging menu item C is in the display field of 1 to row number, window A and B has been opened in this display field, the origin coordinates of window A is less than the origin coordinates of the icon of menu item C, the origin coordinates of the icon of menu item C is less than the origin coordinates of window B, then the line number of window A is 1, and the line number being about to the window C of the menu item C opened is 2, and the line number of window B is 3.

Step S07, calculates new size and the origin coordinates of the window of existing window and this menu item in this display field, after completing calculating, enters step S08 according to above-mentioned ranking results.

In this preferred embodiment, layout pattern is n × m, then carry out standard cutting according to this layout pattern to main window: be divided into m display field to viewing area transverse axis m, and the longitudinal axis n of each display field is divided into n window region and each window region shows a window.According to above-mentioned standard cutting, the length l of each window ₃=l ₂, width the X-axis component x of the origin coordinates of each window ₃=x ₂, Y-axis component $y_3=\frac{w_2-\mathrm{\ω}(n-1)}{n}(r-1)+\mathrm{\ω}(r-1)+y_2,$ Wherein, l ₂, w ₂be respectively length and the width of display field, r is the line number of window, and ω is the distance at interval between each window in display field, and n is window sum higher limit in display field, x ₂, y ₂be respectively the X-axis of the origin coordinates of display field, Y-axis component.

In actual mechanical process, user's freely dragging menu item is in display field, and the window number of each display field display is not higher limit, and the size of each window obtains according to the size of the window sum mean allocation display field in display field.Computing module 104 is according to the size of window sum mean allocation display field in display field, and each window size is according to the increase of window sum in the display field of place or reduce corresponding window size and reduce thereupon or increase.When dragging menu item is to display field, this display field increases the window of this menu item, then now window adds up to the sum of the window of existing window and menu item in this display field; When dragging the window in display field to menu list, this display field removes this window, then now window adds up to except by the sum of remaining window except dragging window in this display field.

From the above mentioned, user drags menu item to display field and after discharging this menu item icons, computing module 104 is according to the size of each window in following formulae discovery display field and origin coordinates:

The length l that each window is new ₃=l ₂, wherein, l ₂for the length of this display field;

The width that each window is new wherein, ω is the distance at interval between each window in display field, w ₂for the width of this display field, k is window sum in this display field (having the sum of the window of window and menu item in this display field);

The X-axis component x of the origin coordinates that each window is new ₃=x ₂, wherein, x ₂for the X-axis component of the origin coordinates of this display field;

The Y-axis component of the origin coordinates that each window is new $y_3=\frac{w_2-\mathrm{\ω}(k-1)}{k}(r-1)+\mathrm{\ω}(r-1)+y_2,$ Wherein, r is the line number of window, y ₂for the Y-axis component of the origin coordinates of this display field.

As shown in fig. 5-A, dragging menu item A is that in the display field of 1, the line number of the window A of menu item A is 1 to row number, and in this display field, the length of window sum k=1, window A is l ₂, the width of window A is w ₂.Be the display situation of window A in this display field after the icon of release menu item A as shown in fig. 5-b.

As shown in fig. 5-b, dragging menu item B is that in the display field of 1, the line number of the window B of window A, menu item B is followed successively by 1,2 to row number, and in this display field, the length of window sum k=2, window A is l ₂widely be and origin coordinates is (x ₂, y ₂), the length of window B is l ₂widely be and origin coordinates is (x ₂, ).Be the display situation of window A, B in this display field after the icon of release menu item B as shown in fig. 5-c.

As shown in fig. 5-c, the window C of window A, menu item C, the line number of window B are followed successively by 1,2,3; The length of window A is l ₂widely be and origin coordinates is (x ₂, y ₂), the length of window C is l ₂widely be and origin coordinates is (x ₂, ), the length of window B is l ₂widely be and origin coordinates is (x ₂, ).As Fig. 5-D is depicted as the display situation of window A, B, C in this display field after the icon of release menu item C.

Step S08, adjusting module 106 opens the window of the menu item of this dragging, according to the window of the menu item of this dragging of above-mentioned calculating and the new size of existing window and origin coordinates, adjust size and the display position of each window in this display field, then enter step S09.

Step S09, adjusting module 106 deletes the menu item of this dragging from menu list.

Shown in composition graphs 5-A, 5-B, drag menu item A in display field, then in display field, open the window A of menu item A and from menu list, delete this menu item A.

Shown in composition graphs 5-B, 5-C, drag in the display field of menu item B to existing window A, then this display field is followed successively by window A, B from top to bottom, and deletes this menu item B in menu list.

Shown in composition graphs 5-C, 5-D, drag menu item C in the display field of existing window A, B, then display window A, C, B successively from top to bottom in this display field, and in menu list, delete this menu item C.

Step S10, when dragging the window in display field to menu list, determination module 102 judges that whether remain window sum in this display field is greater than zero, if be greater than zero, enters step S11, otherwise enters step S14.

Step S11, order module 103 compares except by the origin coordinates of each window of residue that drags except window and ascending sort in this display field, and this clooating sequence is the line number remaining each window.

As shown in Fig. 5-E, row number are display window A, D, B successively from top to bottom in the display field of 1, the current line number of each window is followed successively by 1,2,3, when dragging window D is to menu list, order module 103 compares the origin coordinates ascending sort that remain window A, B in this display field, then the line number of window A, B is 1,2.

Step S12, computing module 104 calculates in this display field the new size and origin coordinates that remain each window according to ranking results.

In this preferred embodiment, user in operation, drag the window of then this display field increase (opening) this menu item in menu item to display field, the window dragged in display field removes the window of (closedown) this dragging to menu list then this display field, and in display field, the size of each window is according to the increase of window sum in the display field of place or minimizing corresponding reduction or increase thereupon.Drag window in display field in step S12 to menu list, the computation process of the new size and origin coordinates that remain window in this display field, see step S07, repeats no more herein.It should be noted that, when dragging the window in display field to menu list, now in this display field, window sum k refers to except by the sum of the residue window except dragging window.

Shown in composition graphs 5-E, 5-F, drag row number be window D in the display field of 1 to menu list, then in this display field, the line number of residue window A, B is followed successively by 1,2, and in this display field, the length of window sum k=2, window A is l ₂widely be and origin coordinates is (x ₂, y ₂), the length of window B is l ₂widely be and origin coordinates is (x ₂, ).

Step S13, adjusting module 106 closes this trailing window, according to the new size and the origin coordinates that remain window in this display field, the size of adjustment residue window and display position.

Step S14, will increase the menu item of the window of this dragging in menu list.

Shown in composition graphs 5-E, 5-F, when dragging the window D in display field to menu list, adjusting module 106 close the window D of this dragging and the menu item D adding the window D of this dragging in menu list, the width of this display field of residue window A, B mean allocation.

Above-mentioned adjusting module 106 also realizes following functions: the frame of user's window, when mouse is changed to the arrow pointed to left and right, stretches or shrinks window border, to increase or to reduce the size of window.In this preferred embodiment, under default situations, the width of window in display field is the width of this display field, and window breadth extreme is the width of this display field.In addition, described window layout dynamic debugging system 10 also comprises one and preserves module, when user closes main window or logs off, preserve the parameter value such as size and origin coordinates of current layout pattern, the window shown in each display field and each window chosen, so that during the follow-up login system of this user, can according to the window layout of Parameter reconstruction last time of preserving.

Consulting shown in Fig. 3, is the method flow diagram switched between different layout pattern.In this process flow diagram, the order of step can change, and some step can be omitted, merge or disassemble segmentation.

As shown in Figure 1, described window layout dynamic debugging system 10 also comprises handover module 107, window layout for realizing different layout pattern switches, and this handover module 107 comprises calculating sub module 1071, cutting submodule 1072, screening submodule 1073, adjustment submodule 1074 and decision sub-module 1075.The function of each submodule of this handover module 107 is described in detail below in conjunction with the process flow diagram shown in Fig. 3.

Step S701, under calculating sub module 1071 calculates current (old) layout pattern, the weights of all windows in each display field.

The weights of described window calculate according to formula v=(r-1) × m+c, and wherein, r is the line number of window, and m is the number (the m value in layout pattern) of display field, and c is the row number (i.e. the row number of window place display field) of window.As shown in Fig. 6-A, current arrangements's pattern is 3 × 3, row number are display window A, C, B and line number is respectively 1,2,3 successively from top to bottom in the display field of 1, row number are only comprise window D in the display field of 2 and line number is 1, and row number are display window K, F, L and line number is respectively 1,2,3 successively from top to bottom in the display field of 3.According to the weights of each window of above-mentioned formulae discovery, then the weights of window A, D, K, C, F, B, L are respectively 1,2,3,4,6,7,9.

Step S702, carries out standard cutting according to the new layout pattern that user chooses to viewing area, the weights of all window regions under calculating new layout pattern.

Described standard cutting refers to and is divided into m display field to viewing area transverse axis m, the longitudinal axis n decile of each display field, each region after decile be a window region and this window region each for showing a window.

The detailed process of this standard cutting is as follows:

The transverse axis of viewing area is divided into m display field by m, and each display field order is from left to right the length l of the row number of display field, each display field ₂=(l ₁-m × β) m, width w ₂=w ₁-2 α, the X-axis component x of the origin coordinates of each display field ₂=c β+(c-1) l ₂, Y-axis component y ₂=α, wherein, l ₁, w ₁be respectively length and the width of viewing area, c is the row number of display field, and m is the number of display field, and α is the spacing distance of each display field and main window up-and-down boundary, and β is the spacing distance between each display field;

N window region is divided into the longitudinal axis n of each display field, the length l of each window ₃=l ₂, width the X-axis component of the origin coordinates of each window is x ₃=x ₂, Y-axis component is $y_3=\frac{w_2-\mathrm{\ω}(n-1)}{n}(r-1)+\mathrm{\ω}(r-1)+y_2,$ Wherein, l ₂, w ₂be respectively length and the width of display field, r is the line number of window, and ω is the distance at interval between each window in display field, and n is window sum higher limit in display field, x ₂, y ₂be respectively the X-axis of the origin coordinates of display field, Y-axis component.

It should be noted that, described window region is for showing a window, and the window of display takes this window region completely, and this window region can be regarded as can be equal to the space that certain window concrete that will show is reserved in display field and regard a window as.

As shown in figure 6-b, user chooses new layout pattern 2 × 3, then standard cutting is carried out in viewing area by cutting submodule 1072, cutting is three display fields and each display field cutting is two window regions, each window region as shown in dotted outline in FIG., distinguish each window region with the line number of window region and row number, be respectively window region 11,12,13,21,22,23.Calculating sub module 1071 calculates the weights of each window region according to window weights formula v=(r-1) × m+c, then the weights of each window region are 1,2,3,4,5,6 respectively.

Step S703, screening submodule 1073 selects the weights window identical with the weights of each window region in new layout pattern from all windows current arrangements's pattern, and the menu item of the window be not selected is added in menu list.

Shown in composition graphs 6-A, 6-B, window A, D, K, C, F under old layout pattern are identical with the weights of window region 11,12,13,21,23, are selected, and menu item B, L of window B, L of not being selected are added in menu list.

Step S704, the window chosen is presented at the position of the window region identical with the weights of this selected window by adjustment submodule 1074 one by one, and the size of this selected window is the size of window region.

As shown in figure 6-b, window A, D, K, C, F is presented at the position of the window region 11,12,13,21,23 identical with each window weights and each window size is the size of window region respectively.

Step S705, whether the window sum of decision sub-module 1075 under judging new layout pattern in each display field reaches the window sum higher limit in each display field.If do not reach higher limit, then enter step S706, otherwise terminate.

As shown in figure 6-b, new layout pattern is 2 × 3, and the window sum higher limit in each display field is two windows, and row number are only comprise a window D in the display field of 2, and do not reach higher limit, the window sum in all the other display fields reaches higher limit.

Step S706, when the window sum in display field does not reach higher limit, the size of this display field of adjustment submodule 1074 mean allocation, readjusts the size of each window in this display field.

As shown in figure 6-b, when the size of the window respectively chosen according to the relation adjustment that weights are corresponding in display field and display position, when in display field, window sum does not reach higher limit, have not for the window region of display window in this display field, then cause certain space waste.Given this, the size of submodule 1075 according to window sum in display field again mean allocation display field is adjusted, then the width of window wherein, w ₂for the width of display field, ω is the distance at interval between each window in display field, and k is window sum in display field.

As shown in figure 6-b, row number are only display window D in the display field of 2, do not reach higher limit, then the size of mean allocation display field, window width therefore the width of this window D is the width of this display field.

Finally it should be noted that, above preferred embodiment is only unrestricted for illustration of technical scheme of the present invention, although according to above preferred embodiment to invention has been detailed description, those of ordinary skill in the art is to be understood that, can modify to technical scheme of the present invention or equivalent replacement, should not depart from the spirit and scope of technical solution of the present invention.

Claims (18)

1. a window layout dynamic adjusting method, is characterized in that, the method comprises:

Dicing step: be viewing area and floating zone by main window cutting, and viewing area cutting is multiple display field to the layout pattern chosen according to user and each display field shows limited number window, this floating zone is divided into upper and lower two regions display layout's pattern and menu list respectively, this layout pattern is the form of n × m, m refers to the number of display field, and n is the higher limit of window sum in each display field;

Determination step: judge that user is that the window that drags in menu item to display field or drag in display field is to menu list;

Ordered steps one: when dragging menu item existing window number not reaching higher limit to display field and in this display field, the relatively origin coordinates of the existing origin coordinates of window and the icon of this menu item ascending sort in this display field, this clooating sequence is the line number of the window of existing window and this menu item in this display field;

Ordered steps two: when drag the window in display field to menu list and remain in this display field window sum be greater than zero time, relatively this display field is interior except being dragged the origin coordinates ascending sort that are remained window except window, and this clooating sequence is the line number of residue window in this display field;

Calculation procedure: according to window sum in ranking results and display field, calculate new size and the origin coordinates of each window in display field;

Set-up procedure one: when dragging menu item is to display field, open the window of this menu item, according to above-mentioned result of calculation, adjusts size and the display position of the window of existing window and menu item in this display field;

Set-up procedure two: when dragging the window in display field to menu list, closing the window of this dragging, according to above-mentioned result of calculation, adjusting the size and display position that remain window in this display field.

2. window layout dynamic adjusting method as claimed in claim 1, it is characterized in that, this dicing step comprises the following steps:

By the transverse axis of main window with the ratio cutting of a:b for viewing area and floating zone, with transverse axis, direction is for X-axis forward from left to right, and the longitudinal axis from top to bottom direction is Y-axis forward, then origin coordinates (the x of this viewing area ₁, y ₁) be (0,0), length width w ₁=W, the origin coordinates of floating zone is length is width is W, and wherein, L, W are respectively the length and width of main window, a, b be greater than zero natural number;

According to the layout pattern that user chooses, the transverse axis m of viewing area is divided into m display field and the higher limit of the window sum shown in each display field is n, display field order is from left to right the row number of each display field, the length l of each display field ₂=(l ₁-m × β) m, width w ₂=w ₁-2 α, the X-axis component x of origin coordinates ₂=c β+(c-1) l ₂, Y-axis component y ₂=α, wherein, c is the row number of display field, and α is the distance at each display field and main window up-and-down boundary interval, and β is the distance at each display field interval.

3. window layout dynamic adjusting method as claimed in claim 2, is characterized in that, this calculation procedure calculates new size and the origin coordinates of each window in display field by following steps:

New length l ₃=l ₂;

New width wherein, k is window sum in this display field, and ω is the distance at interval between each window in display field;

The X-axis component x of new origin coordinates ₃=x ₂;

The Y-axis component of new origin coordinates $y_3=\frac{w_2-\mathrm{\ω}(k-1)}{k}(r-1)+\mathrm{\ω}(r-1)+y_2,$ Wherein, r is the line number of window;

When dragging menu item to display field, window sum k in this display field is the sum of the window of the menu item of existing window and this dragging in this display field, when dragging the window in display field to menu list, the window sum k in this display field is except being dragged the sum remaining window except window in this display field.

4. window layout dynamic adjusting method as claimed in claim 1, it is characterized in that, this set-up procedure one also comprises: when dragging menu item to display field, delete the menu item of this dragging in menu list; Set-up procedure two also comprises: when dragging the window in display field to menu list, increase the menu item of this dragging window in menu list.

5. window layout dynamic adjusting method as claimed in claim 1, it is characterized in that, the method also comprises a step of replacing, when dragging menu item existing window sum reaching higher limit to display field and in this display field, the window that the origin coordinates point that the window of this menu item replaces the icon of this menu item falls into, and delete the menu item of this dragging in menu list and increase the menu item being substituted window.

6. window layout dynamic adjusting method as claimed in claim 1, is characterized in that, the method also comprises the switch step of the window layout switching carrying out different layout pattern:

Under calculating current arrangements's pattern, the weights of all windows in each display field;

According to the new layout pattern that user chooses, standard cutting is carried out to viewing area, and the weights of each window region under calculating new layout pattern;

The window that weights are identical with the weights of each window region in new layout pattern is selected from all windows current arrangements's pattern;

The window be selected is presented at the window region identical with these window weights respectively;

When window sum under new layout pattern in each display field does not reach higher limit, according to the size of this display field of window sum mean allocation of display field, adjust the size of each window.

7. window layout dynamic adjusting method as claimed in claim 6, it is characterized in that, the computing formula of described weights is v=(r-1) × m+c, and wherein, r is the line number of window or window region, and c is the row number of display field, and m is the number of display field.

8. window layout dynamic adjusting method as claimed in claim 1, it is characterized in that, the method also comprises one and preserves step: when user closes main window or logs off, and preserves current layout pattern, the window shown in each display field and the size of each window chosen and the parameter value of origin coordinates.

9. window layout dynamic adjusting method as claimed in claim 1, it is characterized in that, this set-up procedure also comprises: when the frame of user's window and mouse is changed to the arrow pointed to left and right time, stretch or shrink window border, to increase or to reduce the size of window.

10. a window layout dynamic debugging system, is characterized in that, this system comprises:

Cutting module: for being viewing area and floating zone by main window cutting, and viewing area cutting is multiple display field to the layout pattern chosen according to user and each display field shows limited number window, this floating zone is divided into upper and lower two regions display layout's pattern and menu list respectively, this layout pattern is the form of n × m, m refers to the number of display field, and n is the higher limit of window sum in each display field;

Determination module: for judging that user is that the window that drags in menu item to display field or drag in display field is to menu list;

Order module: for when dragging menu item existing window number not reaching higher limit to display field and in this display field, the relatively origin coordinates of the existing origin coordinates of window and the icon of this menu item ascending sort in this display field, this clooating sequence is the line number of the window of existing window and this menu item in this display field;

This order module also for: when drag the window in display field to menu list and remain in this display field window sum be greater than zero time, relatively this display field is interior except being dragged the origin coordinates ascending sort that are remained window except window, and this clooating sequence is the line number of residue window in this display field;

Computing module: for according to window sum in ranking results and display field, calculate new size and the origin coordinates of each window in display field;

Adjusting module: for when dragging menu item to display field, open the window of this menu item, according to above-mentioned result of calculation, adjusts size and the display position of the window of existing window and menu item in this display field;

This adjusting module also for: when dragging the window in display field to menu list, closing the window of this dragging, according to above-mentioned result of calculation, adjusting the size and display position that remain window in this display field.

11. window layout dynamic debugging systems as claimed in claim 10, is characterized in that, this cutting module is used for carrying out cutting to main window:

By the transverse axis of main window with the ratio cutting of a:b for viewing area and floating zone, with transverse axis, direction is for X-axis forward from left to right, and the longitudinal axis from top to bottom direction is Y-axis forward, then origin coordinates (the x of this viewing area ₁, y ₁) be (0,0), length width w ₁=W, the origin coordinates of floating zone is length is width is W, and wherein, L, W are respectively the length and width of main window, a, b be greater than zero natural number;

According to the layout pattern that user chooses, the transverse axis m of viewing area is divided into m display field and the higher limit of the window sum shown in each display field is n, display field order is from left to right the row number of each display field, the length l of each display field ₂=(l ₁-m × β) m, width w ₂=w ₁-2 α, the X-axis component x of origin coordinates ₂=c β+(c-1) l ₂, Y-axis component y ₂=α, wherein, c is the row number of display field, and α is the distance at each display field and main window up-and-down boundary interval, and β is the distance at each display field interval.

12. window layout dynamic debugging systems as claimed in claim 11, is characterized in that, this computing module is for calculating new size and the origin coordinates of each window in display field:

New length l ₃=l ₂;

New width wherein, k is window sum in this display field, and ω is the distance at interval between each window in display field;

The X-axis component x of new origin coordinates ₃=x ₂;

The Y-axis component of new origin coordinates $y_3=\frac{w_2-\mathrm{\ω}(k-1)}{k}(r-1)+\mathrm{\ω}(r-1)+y_2,$ Wherein, r is the line number of window;

When dragging menu item to display field, window sum k in this display field is the sum of the window of the menu item of existing window and this dragging in this display field, when dragging the window in display field to menu list, the window sum k in this display field is except being dragged the sum remaining window except window in this display field.

13. window layout dynamic debugging systems as claimed in claim 10, is characterized in that, this adjusting module also for: when drag menu item to display field time, in menu list, delete the menu item of this dragging; When dragging the window in display field to menu list, in menu list, increase the menu item of this dragging window.

14. window layout dynamic debugging systems as claimed in claim 10, it is characterized in that, this system also comprises one and replaces module, for when dragging menu item existing window sum reaching higher limit to display field and in this display field, the window that the origin coordinates point that the window of this menu item replaces the icon of this menu item falls into, and delete the menu item of this dragging in menu list and increase the menu item being substituted window.

15. window layout dynamic debugging systems as claimed in claim 10, it is characterized in that, this system also comprises a handover module, and for switching between the window layout of different layout pattern, this handover module is realized by following steps:

Under calculating current arrangements's pattern, the weights of all windows in each display field;

According to the new layout pattern that user chooses, standard cutting is carried out to viewing area, and the weights of each window region under calculating new layout pattern;

The window that weights are identical with the weights of each window region in new layout pattern is selected from all windows current arrangements's pattern;

The window be selected is presented at the window region identical with these window weights respectively;

When window sum under new layout pattern in each display field does not reach higher limit, according to the size of this display field of window sum mean allocation of display field, adjust the size of each window.

16. window layout dynamic debugging systems as claimed in claim 15, is characterized in that, the computing formula of described weights is v=(r-1) × m+c, and wherein, r is the line number of window or window region, and c is the row number of display field, and m is the number of display field.

17. window layout dynamic debugging systems as claimed in claim 10, it is characterized in that, this system also comprises one and preserves module, during for closing main window as user or logging off, preserve current layout pattern, the window shown in each display field and the size of each window chosen and the parameter value of origin coordinates.

18. window layout dynamic debugging systems as claimed in claim 10, it is characterized in that, this adjusting module also for: when the frame of user's window and mouse is changed to the arrow pointed to left and right time, stretch or shrink window border, the corresponding size increasing or reduce window.