JPS61110196A - Multiwindow control system - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a multi-window control system, and particularly to a multi-window control system that can display a plurality of overlapping screens on a screen.

[Conventional technology]

FIG. 2 is an explanatory diagram of a conventional multi-window screen display. In the figure, +91ti CRT display, (1
13. fal+ is the data processing unit that is the display request source, a”
a, u31 is the virtual display memory, H, (I
9 is window, uIlil, an is display area, 0
&, α9 represent divided display screens, and hood υ represents a screen synthesis section, respectively.

Virtual Tispray memory θ21. u31 is a memory allocated as a temporary image memory to each data processing unit (1(1, has a size corresponding to the entire display screen of Ql.Therefore, each data processing unit Ql
, IJυ is this virtual display memory Q2,
It is sufficient to process the image by considering uni as the original image memory.

Virtual display memory 05, 03! The display screen (18) divided into H corresponds to the window (141).
, (15. Window (1
4J, 05 is virtual display memory tlZ,
It can be thought of as defining the range of the display area ([61, (17)) in which a part of the interior of Q31 is to be displayed on the display screen as.

And virtual display memory 03. The contents of the display area (161, (1B) extracted by Q3 to window +14) and tie are synthesized by the screen synthesis unit υ and displayed as a display screen 41119, (19).

[Problem that the invention seeks to solve]

The above-mentioned conventional technology is configured such that all the contents of the display area extracted by each window are displayed on the display screen. Therefore, if the display area is wide, only one Kti screen can be displayed, and when moving from work on one screen to another screen, the work must be interrupted once, which is inconvenient for operation. Met.

The technical aim of the present invention is to solve the problems of the prior art described above and to provide a display device with good operability that can display a plurality of display screens ff1jK overlappingly on one display device.

[Means for solving problems]

In order to solve the above-mentioned technical problem, the present invention provides a register control unit (6) controlled by a microprocessor (1).
) is equipped with a control register (8) whose contents are arbitrarily updated via the screen compositing section (7) which synthesizes data from the image memories (2) to (5). Image information for display c361
-supply c39. Then, it is confirmed that the screen composition unit (7) can control the mutual overlap of the windows (2) to 6υ based on the image information and display the superimposed screen Q-(c) on the CRT display device #(9). It is said that

[Effect]

The contents of the display area C241~punishment extracted from the virtual display memories (4)~O by the window controller~G11, that is, the contents of the image memories (2)~(5), are read into the screen synthesis unit (η). Also, at this time, the contents of the control register (8), which are sequentially updated by the microprocessor (1) via the register control unit (6), are synthesized as image information □□□～field for controlling the nine overlapping screens. section (7).Then, the screen composition section (7)
is the image memory (2) to (5) based on the image information ~Q.
Synthesize the data from the CRT as a video signal (IL)
Display (9) and CRT display (9)
) displays a plurality of superimposed screens 62 to (c).

〔Example〕

FIG. 1 is a block diagram 1. for explaining one embodiment of the present invention. @Figure 3 is an explanatory diagram of the multi-window overlapping screen display of the present invention, Figure 4 is a diagram for explaining the address coordinate relationship of the present invention, and Figure 5 is the image information in the control register (8) shown in Figure 1V. FIG. 6 is an explanatory diagram showing one embodiment of the present invention. In the figure, -(1) is a microprocessor, (2) to (5) are image memo IJs, +61 is a register control unit, (7) is a screen composition unit, +81H control register, - to Q, and 9 are virtual Tispray memory. ,c! 41 ~ @ is the display area, c31) how to, c +; a - c) 5iFi, display screen, 0 ~ 艷 is the image information I in the control register (8) (support)
N is Karihekiza Shobe, C is screen seat Sakakibe, (to) is window size, ((The bell represents status, respectively.

In addition, the part explained with respect to FIG. 2 of the prior art and 1a1
The same reference numerals are given to some parts, and detailed explanations are omitted.

First, one embodiment of the present invention will be explained using Figure 8+41. Microprocessor (+1) and image memory (2)
1 to (5) and the register control unit (61) are connected to each other by a data bus, an address bus, and a control bus. Data for creating characters, pictures, etc. are loaded into the memories (2) to (5), and image information (g) to ω shown in FIG. 5 is controlled via the register control unit (6). Register (8) K is set. Also, the screen synthesis section (7) and the microprocessor (11) are connected to each other by an address bus and a control bus, and the screen synthesis section (7) receives data from the microprocessor (1). When data is read from the image memory (2) to (5) by a command, image information 0!li1 to 09 is read from the ni control register (8), and the image memory (
2) Combine the data from (5). Thereafter, the screen composition section (7) supplies the composite data as a video signal (at) to the CRT display (9), and displays the plurality of overlapping display screens 62 to C35l shown in FIG. 3 on the CRT display.
Display on the display (9).

Next, control of multi-window overlapping screen display according to the present invention will be explained using FIG. 3 and with reference to FIGS. 1, 4, and 5. In Figure 3, the first window (
To) tIi Extract the first display area (241) from the first virtual display number memory and display the display data stored in the first image memory (2) shown in FIG. The first display screen c (a) is displayed on the CRT display (91). Here, using FIG. To explain the coordinate relationship with , the coordinates of point P in the first Kashio taste play memory mountain are (CX, CY), the coordinates of the upper left corner of F, 1 window ■ are (WX, WY), and the first display screen C321 P corresponding to PA in the first provisional Sedis Frei memory 1 in
'If the coordinates of the skin are (NCX, NCY), then they have the following relationship.

NCX=CX-WX NCY=CY-WY The above coordinate transformation is performed using the register control section (6) in Figure 1.
This is carried out in a coordinate transformation section (not shown) that constitutes a part of the system.

Further, the series of explanations regarding the screen display and coordinate transformation described above also applies to the second display screen (1) to the fourth display screen 651.

Next, the image information (7) to be supplied from the control register (8) shown in FIG. 1 to the screen composition unit (7) using the vgS diagram will be explained. Coordinate position N(CX) within ~(c)
.

Virtual seat part ω showing CY) and screen register part C3 showing the coordinate position 1it (NCX, NCY) on the display screen 33 to Tagami.
7), the window size (to) indicating the size in the X-axis direction and the Y-axis direction of window size ~61) corresponding to dimension A and dimension 8 shown in Fig. 4, and the display screen (321-(g) and status 69, which is control information when displaying.

Status 4 is set to one of four types of information: active, 7-lead, sleeve, and current.Active is information that indicates that no other screen is overlapping on one screen. For example, when displaying the first display screen C33, all the contents corresponding to the first display area C'4)K shown in FIG. 3 of the image memory (2) shown in FIG. Is displayed. A freeze is when one screen is displayed on top of another screen.
The overlapping part is information indicating that it is not displayed on the screen. For example, when displaying a state in which the first display screen C32+ overlaps the second display screen 100, the first display screen (3z) supplies active information and supplies freeze information to the second display screen G3.The first display screen Get is all displayed, but the second display screen [present] does not overlap with the first display screen G3. Only the part is displayed, and the overlapping part is not displayed.The second display screen word that is still in a frozen state is the second PH# memory (3) shown in Figure 1.
Even if the contents of the screen are updated, the screen display will not change.

The sleeve is information indicating that it is not displayed on the screen, and is not displayed on the first display surface t'i to which the sleeve information is supplied. The current is information indicating that a cursor (not shown) is displayed to display the coordinates and character position to be operated next, and the cursor is displayed on the display screen in the above-mentioned active state. Work such as data manipulation can be performed only on the display screen in the current state.

Note that the image information α; (~3! JVi display screen 32~(g) is configured to be set and supplied in units of (g), and the status field is valid for each display screen (33~).

Here, one embodiment of the present invention will be described using FIG. 6.

First, the first display screen C3'IJ, the second display screen (c),
The image information with the status 01 set to 71J-Z is supplied to the third display screen (B), and the image information G9 with the status (31 set to active (or current)) is supplied to the fourth display screen (To). When supplied, the display screen Q to 1 shown in FIG. 6(4) is displayed on the CRT display (9).

Then, in the display shown on the sixth device, the third display screen (
When you want to see the whole of the stock), supply image information with status r39 active (or current) to the third display screen (351), and display status 61 on the fourth display screen (351). By supplying the image information Ob1 to c3, which has been set to
(c) is displayed on the CRT display (9). In addition, in the display shown in FIG.
Image information (g) that has virtual coordinates (g) and screen coordinates C37) to be moved to the second display screen CI3 until it does not overlap with the fourth display screen G~ and has activated (or current) the status screen (g)~ , the status line is activated (or current) on the fourth display screen 051, and the visual information (G) is supplied to the fourth display screen G2 and the third display screen [Yes], respectively. 2! Image information with agricultural sleeves) ~ By supplying C scratches, the 6th
The display screen shown in Figure (C1) is displayed on the CRT display (9).

In the above explanation using FIGS. 6(4), (B), and (C), if the status ■ is changed to active instead of current, a cursor (not shown) will appear on the display screen of the current state, and the current state will be displayed. Work such as data manipulation can be performed only on the display screen. The current state can only be set to one display screen at a time.

In addition, by updating the window size, which is one of the image information, the X axis of the display screen 64 to C351,
You can freely update the dimension in the Y-axis direction.

〔effect〕

The present invention is configured to supply image information for controlling the overlapping state of the screens to the screen composition unit and control the overlapping of both sides, so that as many screens as possible can be displayed on one Nice Play device. Instead, each display screen can be displayed overlappingly.

Therefore, it is possible to provide a display device with good operability that allows the user to simultaneously manipulate a plurality of pieces of data and refer to data displayed on other screens without interrupting work.

[Brief explanation of drawings]

FIG. 1 is a professional diagram for explaining one embodiment of the present invention, FIG. 2 is an explanatory diagram of a multi-window screen display according to the prior art, and FIG. 3 is a diagram of a multi-window overlapping screen display control according to the present invention. Explanatory diagram, Figure 4 is the virtual display shown in Figure 3.
FIG. 5 is a diagram for explaining the address coordinate relationship between memory and window, FIG. 5 is a diagram for explaining image information in the control register, and FIG. 6 is a diagram for explaining one embodiment of the present invention. (1) Microprocessor (2) ~ (5) Image memory (6) Register control unit (sword screen synthesis unit (8) Control register f91c RT Tispray (2) ~ Q rowing screen display memory (c) ~ □□□
Display area & ~01) Window C (21-c151 display screen rules) ~C3! 'Iji image information Figure 4 Figure 5 Figure 6

Claims (1)

[Claims] A multi-window display device is equipped with a control register whose contents are arbitrarily updated via a register control section controlled by a microprocessor, and displays superimposed screens from the control register on a screen synthesis section that synthesizes data from an image memory. A multi-window control system, characterized in that by supplying image information for displaying images, the screen compositing section controls overlapping of windows, thereby displaying overlapping screens on the earth play device.