Alternate display content controller

Information

  • Patent Grant
  • 6686936
  • Patent Number
    6,686,936
  • Date Filed
    Friday, March 5, 1999
    25 years ago
  • Date Issued
    Tuesday, February 3, 2004
    20 years ago
Abstract
An alternate display content controller provides a technique for controlling a video display separately from and in addition to the content displayed on the operating system monitor. Where the display is a computer monitor, the alternate display content controller interacts with the computer utility operating system and hardware drivers to control allocation of display space and create and control one or more parallel graphical user interfaces adjacent the operating system desktop. An alternate display content controller may be incorporated in either hardware or software. As software, an alternate display content controller may be an application running on the computer operating system, or may include an operating system kernel of varying complexity ranging from dependent on the utility operating system for hardware system services to a parallel system independent of the utility operating system and capable of supporting dedicated applications. The alternate display content controller may also include content and operating software delivered over the internet or any other LAN. The alternate display content controller may also be included in a television decoder/settop box to permit two or more parallel graphical user interfaces to be displayed simultaneously.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




This invention relates to user interface displays and, in particular, the use of a parallel user interface separate from the standard user interface display.




2. Description of the Prior Art




There was a time when the most popular operating system for personal computers (DOS) did not include a graphical user interface. Any company could create a “menu” or “shell” which would be the first program launched upon starting the computer and which would present options to the user for launching and managing various applications. Although graphics programming was difficult in the DOS environment, some companies even created graphical user interfaces that could then launch other programs.




Microsoft Corporation of Redmond, Wash., introduced such a graphical user interface for launching applications which it called “Windows”. The first three versions of Windows were merely applications which ran under DOS and could be one of numerous items to be selected from a previously running shell or menu which might be offered by a company other than Microsoft. This continued to allow other companies to offer primary user interface programs to users without the user going through a Microsoft controlled user interface.




However, with the introduction by Microsoft of Windows 95™, the initial loading of the operating system presents a Microsoft-developed graphical user interface (GUI) at the outset, which occupies the entire screen display. This operating system created GUI is commonly known as a “desktop”. As with its previous operating system products, Microsoft arranged with manufacturers of the standard computer hardware to include this operating system with each computer sold. Microsoft's OEM licensing restrictions prevent vendors from altering, obscuring, or preceding the Microsoft desktop display. The Windows environment also presumes its ownership of the entire display and is designed in ways that assume that it can write to any screen location at any time. With Microsoft's domination of this market, it became impossible for other software vendors to present an interface to users other than as a Microsoft style icon within the Microsoft “desktop” consisting of the entire screen display. This prompted a need for access to a user interface which could be presented outside of the standard computer screen display and therefore independent of the dictates of Microsoft for items within its “desktop”.




Standard personal computers use VGA or Super VGA or XGA video display systems. These display systems operate in standardized graphics modes such as 640×480 pixels, 800×600 pixels, 1024×768 pixels, and 1280×1024 pixels. When one of these display modes is selected, this is the entire area available for display. In the Microsoft Windows environment, the user instructs the Windows operating system to select one of these standard display modes and the Windows operating system then presents all of the applications and their icons within the selected display area. There is no way at present to cause the Windows “desktop” to use less than the entire display area and still function as intended and allow another program from another vendor to control the remainder. What is needed is the ability to designate a portion of video memory a separate from the Windows desktop, and to make sure that Windows functions normally but at the same time cannot obstruct anything subsequently allocated into that space




SUMMARY OF THE INVENTION




A first aspect of the present invention includes a technique for controlling allocation and content of display space among one or more user interfaces, operating systems or applications permitting an application or parallel graphical user interface (GUI) to operate outside the desktop, the area designated for display of the operating system interface and it's associated applications. In a first aspect, a computer operating under the control of any utility operating system such as Microsoft Windows™, Linux, Apple O/S or Unix may have the allocation of visible display controlled by the present invention. The operating system desktop may be scaled and/or moved to a specific area of the display permitting a parallel GUI to operate in the open area. The present invention may be an application operating under the primary or utility operating system or it may be combined with an operating system kernel to control the display and content in the parallel display.




Another aspect of the present invention includes a technique provided for adding and using a parallel graphical user interface adjacent to the standard user graphical display interface, for example in the border beyond the standard screen display area. Conventional video systems, such as VGA, SVGA and XGA video systems, include a defined border surrounding the display area. The original purpose of this border was to allow adequate time for the horizontal and vertical retrace of the electron gun in a cathode ray tube display. However, with the advent of LCD displays and as retrace speeds have increased in modern monitors, it is now possible to present a user interface display in this border. The border which can be controlled as a user interface is a portion of what is known as the “overscan”. This invention is a method for presenting one or more additional or secondary user interfaces, for example, in the overscan area surrounding the conventional user interface display often called the desktop.




When the electron gun in a CRT retraces to the left of the screen or the top of the screen, it requires a significant amount of time relative to the presentation of a scanned line of data. During the retrace, the electron gun is turned off (“blanked”). If the blanking time required for the retrace is equal to the amount of time available, there is no usable overscan. However, modern monitors have become much faster in their retrace speeds, leaving a significant amount of time when the electron gun need not be blanked, allowing a displayable border. In the prior art, although the border is usually “black” (the gun is turned off), it is well known how to specify that the border shall be given any one of six colors. Standard BIOS allows a specification of this color. The desired color is simply specified in one of the registers for the video controller. Typically no data for this color is stored in the buffer of video memory for the display. This invention establishes an additional video buffer for the border and allows this buffer to be written with display data like the regular display buffer. The additional video buffer is often present but unused in the graphics systems of most computers because video memory is usually implemented in sizes that are powers of 2 e.g. “512K”, whereas standard desktop dimensions are not “e.g. 640×480=300K”. The display area is thereby expanded, on one or more edges, to provide a visible area previously invisible. The pixels within this newly visible area of the display are made accessible to programs through an application programming interface (API) component of this invention. A program incorporating a parallel graphical user interface may be displayed in the previously blanked area of the display, functionally increasing the accessible area of the display without hardware modification. In other cases the desktop may be increased or decreased to non-standard sizes.




A further aspect of the present invention includes a method for displaying an image on a video display system in an area outside of the primary display area generated by the video display system. Two dimensions define the standard display area, each specifying a number of pixels. Selecting a video “mode” specifies these dimensions. The method is accomplished by adjusting parameters for the video display system to increase the number of pixels in at least one dimension of the display system. The number of pixels which is added is less than or equal to the difference between the number of pixels specified in the video mode and a maximum number of pixels which the video display system can effectively display. Any such difference is defined here as the overscan area. Thus, the overscan area may be the difference between the current desktop video mode and the display capability of the display device or more specifically, any portion of video memory unused when the operating system is in a given screen dimension. Because all interface displays are created by writing a desired image to a buffer or memory for the video display, the method requires allocating additional video display memory for the increased pixels. The image written to such memory is then displayed by the system alongside the original display area.




In a still further aspect of the present invention, only the vertical dimension is increased and the overscan user interface is presented above or below the primary display area. Alternatively, the horizontal dimension may be increased and the overscan user interface displayed to the right or the left of the primary display area. Similarly, the interface image may be displayed on any or all of the four sides of the primary display area.




In another still further aspect of the present invention, a parallel GUI is provided that includes access to existing search engines and browsers. In another embodiment, the parallel GUI includes a search engine and/or browser. A search engine and/or browser using the present invention may be opened in either the overscan space or a space within or over the operating system display.











These and other features and advantages of this invention will become further apparent from the detailed description and accompanying figures that follow. In the figures and description, numerals indicate the various features of the invention, like numerals referring to like features throughout both the drawings and the description.




BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a block diagram of a first embodiment of the present invention.





FIG. 2

is a block diagram of a second embodiment of the present invention.





FIG. 3

is a diagram of a standard display with an overscan user interface on all four borders of the display.





FIG. 4

is a block diagram of the basic components of the present invention.





FIG. 5

is a diagram of a cursor or pointer within the overscan user interface and the hotspot above it within the standard display.





FIG. 6

is a diagram of the usable border within the vertical overscan and the horizontal overscan surrounding the standard display.





FIG. 7

is an overview flow chart showing the operation of a preferred embodiment of the present invention.





FIG. 8

is a flowchart of the sub-steps in Identify Display step


102


of FIG.


7


.





FIG. 9

is a flowchart of the sub-steps of changing the display resolution step


114


of FIG.


7


.





FIG. 10

is a flowchart of the sub-steps in the Paint the Display step


120


of FIG.


7


.





FIG. 11

is a flowchart of the sub-steps of Enable Linear Addressing step


112


of FIG.


7


.





FIG. 12

is a flowchart of the sub-steps of the Process Message Loop of FIG.


7


.





FIG. 13

is a flowchart of the sub-steps of the Check Mouse and Keyboard Events step


184


in FIG.


12


.





FIG. 14

is a flowchart of the sub-steps of the Change Emulation Resolution step


115


in FIG.


7


.





FIG. 15

is a diagram of a standard display of the prior art.





FIG. 16

is a diagram of a standard display with an overscan user interface in the bottom overscan area.





FIG. 17

is a diagram of a standard display including a desktop, an overscan user interface in the bottom overscan area and a context sensitive browser on the side.





FIG. 18

is a diagram of a standard display with an overscan user interface in the bottom and on the right overscan area.











DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT




The present invention includes techniques for providing and using an additional user interface, preferably a secondary graphical user interface or parallel GUI, to be present on the display at least apparently simultaneously with the primary user interface, such as the conventional desktop GUI.




Referring now to

FIGS. 1 and 2

, in a preferred embodiment, programming mechanisms and interfaces in a video display and control system such as computer system


7


or settop box


8


provide one or more parallel GUIs such as space


2


C and/or space


4


in a display area such as display area


1


or display area


9


by providing access and visibility to a portion of the display otherwise ignored and/or inaccessible (hereinafter “overscan area”). Display areas'such as display area


1


or display area


9


may be created on any type of analog or digital display hardware including but not limited to CRT, TFT, LCD and flat panel.




Alternate display content controller


6


interacts with the computer utility operating system


5


B and hardware drivers


5


C to control allocation of display space


1


and create and control one or more parallel graphical user interfaces such as context sensitive network browser (CSNB)


2


and internet pages


2


A and


2


B adjacent the operating system desktop


3


. Alternate display content controller


6


may be incorporated in either hardware or software. As software, an alternate display content controller may be an application running on the computer operating system, or may include an operating system kernel of varying complexity ranging from dependent on the utility operating system for hardware system services to a parallel system independent of the utility operating system and capable of supporting dedicated applications. The alternate display content controller may also include content and operating software such as JAVA delivered over the Internet I or any other LAN.




The alternate display content controller may also be included in a television decoder/settop box such as box


8


to permit two or more parallel graphical user interfaces such as pages


9


A and


9


B to be displayed simultaneously. The present invention may be compatible with conventional television formats such as NTSC, PAL, PAL-C, SECAM and MESECAM. In this configuration content and software may be delivered over any conventional delivery medium


10


including but not limited to over the air broadcast signals


10


A, cable


10


C, optical fiber, and satellite


10


B.





FIGS. 1 and 2

will be referenced in more detail later in the application.





FIG. 15

shows a standard prior art display desktop generated by a Microsoft Windows 95™ operating system. Within the desktop


31


are the taskbar


32


and desktop icons


33


.




In a preferred embodiment of the present invention, a graphical user interface image is painted onto one or more of the sides of the overscan area as shown in FIG.


3


.

FIG. 3

is a depiction of a Super VGA (SVGA) display with the addition of a graphical bar user interface displayed in the overscan area. The overscan user interface bar


30


is defined to reside outside the borders of the “desktop” display area


31


. In

FIG. 16

, the display is modified to include a graphical user interface


30


in a bar 20-pixels high below the bottom edge. In

FIG. 3

, the display is modified to include a graphical user interface in four bars each 20-pixels high/wide outside each of the four display edges: a bottom bar


30


, a left side bar


34


, a right side bar


36


, and a top bar


38


.




The overscan interface may include, and is riot limited to, buttons, menus, application output controls (such as a “ticker window”), animations, and user, input controls (such as edit boxes). Because the overscan interface is not obscured by other applications running within the standard desktop, the overscan interface may be constantly visible or it may toggle between visible and invisible states based upon any of a number of programming parameters (including, but not limited to, the state of the active window, the state of a toggle button, etc.).





FIG. 4

is a block diagram of the basic components of the present invention. Within the software component S are the operating system


63


and one or more applications such as application


61


. Within the protected modes of modern systems, applications


61


do not have direct access to the video or Graphics Drivers


64


or hardware components such as the video card


66


which contains the video chipset


66


A,


66


B and


66


C. Abstraction layers such as Application Interface (API)


60


, and/or Direct API


62


, provide limited access, often through the operating system


63


.




The invention provides a technique for painting and accessing an area of the computer display not accessible, or used, in the operative desktop graphics modes. In the Microsoft Windows environments (including Microsoft Window 95 and derivatives, and Microsoft Windows NT 4.0 and derivatives) and other contemporary operating environments, the primary display area “desktop” is usually assigned by the operating system to be one of a set of pre-determined video “modes” such as those laid out in Tables 1 and 2 below, each of which is predefined at a specific pixel resolution. Thus, the accessible area of the computer display may not be modified except by selecting another of the available predefined modes.












TABLE 1











ROM BIOS video modes















Mode





Mode




Buffer







Number




Resolution




Colors




Type




Segment


















00H




42x25 chars (320x350 pixels)




16




Alpha




B800






00H




42x25 chars (320x350 pixels)




16




Alpha




B800






00H




42x25 chars (320x400 pixels)




16




Alpha




B800






00H




42x25 chars (320x400 pixels)




16




Alpha




B800






01H




42x25 chars (320x200 pixels)




16




Alpha




B800






01H




42x25 chars (320x350 pixels)




16




Alpha




B800






01H




42x25 chars (320x400 pixels)




16




Alpha




B800






01H




42x25 chars (320x400 pixels)




16




Alpha




B800






02H




80x25 chars (640x200 pixels)




16




Alpha




B800






02H




80x25 chars (640x350 pixels)




16




Alpha




B800






02H




80x25 chars (640x400 pixels)




16




Alpha




B800






02H




80x25 chars (640x400 pixels)




16




Alpha




B800






03H




80x25 chars (640x200 pixels)




16




Alpha




B800






03H




80x25 chars (640x350 pixels)




16




Alpha




B800






03H




80x25 chars (640x400 pixels)




16




Alpha




B800






03H




80x25 chars (720x400 pixels)




16




Alpha




B800






04H




320x200 pixels




4




Graphics




B800






05H




320x200 pixels




4




Graphics




B800






06H




840X200 pixels




2




Graphics




B800






07H




80x25 chars (720x350 pixels)




2




Alpha




B000






07H




80x25 chars (720x400 pixels)




2




Alpha




B000






0DH




320x200 pixels




16




Graphics




A000






0EH




640x200




16




Graphics




A000






0FH




640x350




4




Graphics




A000






10H




640x350




4




Graphics




A000






10H




640x350




16




Graphics




A000






11H




640x480




2




Graphics




A000






12H




640x480




16




Graphics




A000






13H




640x200




256




Graphics




A000






















TABLE 2











SVGA video modes defined in the VESA BIOS extension
















Mode










Number




Resolution




Mode Colors




Buffer Type




















100H




640x480 pixels




256




Graphics







101H




640x480 pixels




256




Graphics







102H




800x600 pixels




16




Graphics







103H




800x600 pixels




256




Graphics







104H




1024x768 pixels




16




Graphics







105H




1024x768 pixels




256




Graphics







106H




1280x1024 pixels




16




Graphics







107H




1280x1024 pixels




256




Graphics







108H




80x60 chars




16




Alpha







109H




132x25 chars




16




Alpha







10AH




132x43 chars




16




Alpha







10BH




132x50 chars




16




Alpha







10CH




132x60 chars




16




Alpha







10DH




320x200 pixels




32,768




Graphics







10EH




320x200 pixels




65,536




Graphics







10FH




320x200 pixels




16,777,216




Graphics







110H




640x480 pixels




32,768




Graphics







111H




640x480 pixels




65,536




Graphics







112H




640x480 pixels




16,777,216




Graphics







113H




800x600 pixels




32,768




Graphics







114H




800x600 pixels




65,536




Graphics







115H




800x600 pixels




16,777,216




Graphics







116H




1024x788 pixels




32,768




Graphics







117H




1024x768 pixels




65,536




Graphics







118H




1024x768 pixels




16,777,216




Graphics







119H




1280x1024 pixels




32,768




Graphics







11AH




1280x1024 pixels




65,536




Graphics







11BH




1280x1024 pixels




16,777,216




Graphics















As shown in

FIG. 6

, a displayed image is “overscanned”. That is, the displayed video buffer data occupies less than the entire drivable screen size. The drivable screen size is determined by the total amount of video memory and the operative video display characteristics. The width of the usable overscan border depends on the amount of the horizontal overscan


52


reduced by the horizontal blanking


54


and the amount of the vertical overscan


53


reduced by the vertical blanking


55


.




In a first preferred embodiment, only a border at the bottom of the standard display area is used. Consequently, only the vertical control parameters for the cathode ray tube (CRT) controller, shown as Control Registers


6


H,


16


H,


11


H,


10


H,


12


H and


15


H in

FIG. 4

need to be adjusted. These parameters and others are shown in Table 3 below:












TABLE 3











Vertical timing parameters for CR programming.













Reg-








ister




Name




Description









 6H




Vertical




Value = total number of scan lines per frame - 2







Total




The high-order bits of this value are stored in the








overflow registers.






 7H




Overflow




High order bits from other CR registers.






10H




Vertical




Scan line at which vertical retrace starts.







Retrace




The high-order bits of this value are stored in the







Start




overflow registers.






11H




Vertical




Only the low order 4 bits of the actual Vertical







Retrace




Retrace End value are stored.







End




(Bit 7 is set to 1 to write-protect registers 0








through 7.)






12H




Vertical




Scan line at which display on the screen ends.







Display




The high-order bits of this value are stored in the







End




overflow registers.






15H




Start




Scan line at which vertical blanking starts.







Vertical




The high order bits of this value are stored in the







Blank




overflow registers.






16H




End




Scan line at which vertical blanking ends.







Vertical




The high order bits of this value are stored in the







Blank




overflow registers.






59H-




Linear




Linear address window position in 32-bit CPU address






5AH




Address




space.







Window







Position














In the standard 640×480 graphics mode, the nominal horizontal scan rate is 31.5 KHz (31,500 times per second) with a vertical scan rate of 60 Hz (60 frames per second). So the number of lines in one frame is 31,500/60, or 525. Because only 480 lines of data need to be displayed, there are 525-480, or 45, lines available for vertical overscan. Leaving a more than adequate margin for retrace, which requires only 2 lines worth of time, the preferred embodiment uses 20 lines for the alternate display. Thus the additional


23


unused but available lines may be used to increase the size of the operating system desktop to some non-standard size while still allowing two lines for retrace, or may be left blank, or may be used for one or more additional alternate parallel user interface displays.




The disclosed method of the preferred embodiment of the present invention is accomplished by achieving three requirements:




(1) to address and modify the visible resolution of the video display system such that portions of the overscan area are visible as shown in

FIG. 6

,




(2) to address and modify the video display contents for the visible portion of the overscan area, and




(3) to provide an application programming interface (API) or other mechanism to allow applications to implement this functionality.





FIG. 7

, and the additional details and sub-steps provided in

FIGS. 8-13

, provides a flow chart of an implementation of a preferred embodiment of the present invention meeting the requirements described above. The environment of this implementation is a standard Microsoft Windows 95™ operating environment, using Microsoft Visual C and Microsoft MASM for the development platform. That is not to imply that this invention is limited in scope to that environment or platform. The invention could be implemented within any graphical interface environment, such as X-Windows, OSF Motif, Apple OS, a Java OS, and others in which similar video standards (VGA, SVGA, XGA, 8514/A) are practiced. The reference books PC Video Systems by Richard Wilton, published by Microsoft Press and Programmer's Guide to the EGA, VGA, and Super VGA Cards by Richard F. Ferrano, published by Addison Wesley provide more than adequate background information to implement this embodiment.




Referring now in particular to

FIG. 7

, upon initialization, at Identify Display Type step


102


, the program attempts to determine the display type, and current location in memory used by the display driver, in order to determine the size and locations of any display modifications to be made, .e.g. to the size and location of overscan area(s) to be used.




As described in further detail in

FIG. 8

, the program first queries the hardware registry in Query. Hardware Registry, step


131


, to attempt to determine the registered display type. If successful, the program then determines compatibility information in Display Type Supported, step


135


, to verify that the program supports that display type and determine memory allocation information.




If the hardware registry information is unavailable, as determined in step


131


, or the display type determined in step


131


is unsupported as determined by step


104


, the program may use an alternate approach, shown as subroutine Query hardware, steps


135


in

FIG. 8

, to query the BIOS, in step


134


, and the video chipset


66


, in step


136


, for similar information as; described immediately below.




If the BIOS is to be accessed in step


134


, physical memory is first allocated in Allocate Physical Memory, step


132


, and accessed using Microsoft's DPMI (DOS Protected Mode Interface) to map it to the linear memory address in which the BIOS resides in Use DPMI to assign BIOS linear address to physical memory, step


133


.




Thereafter, the program queries the BIOS in Read BIOS block, Search for VGA/XVA type and manufacturer ID, step


134


. If successful, the driver and chipset are then further queried to determine the display type and memory location in Query driver/chipset for exact chipset, step


136


.




If the compatibility information does not indicate a standard VGA, SVGA, XGA, or 8514/A signature, step


134


, this routine returns a failure. If a known chipset manufacturer's identification is found, the driver and/or chipset may be queried with manufacturer-specific routines, step


136


, to identify and initialize, as necessary, the specific chipset.




If, at step


104


, the program was unable to finally unable to identify the display type, either because the registry query in step


131


or the hardware query in step


135


was unsuccessful, the user may be prompted at Run in windowed mode, step


116


, as to whether the program should continue to run as a standard “application bar” or “toolbar”. The program may either exit or proceed to run as a toolbar on the desktop.




Returning now to

FIG. 8

, if a supported display type is detected, the program then determines the screen borders to be accessed in identify borders to display in overscan, step


106


, based upon user preferences, and determines, as necessary, whether sufficient video memory exists to make the necessary display changes. For example, if the screen is currently set to a 1024×768 resolution at 16 bits-per-pixel, and the program is to include four graphical interface bars, one on each edge, with each bar 20 pixels deep, the program must check that video memory is greater than 1.7 MB (required number of bytes=Pixels Width*BitsPerPixel*PixelsHeight).




The controller registers


6


H,


16


H,


11


H,


10


H,


12


H and


15


H as shown in FIG.


4


and detailed in Table 3, may be accessed through standard input/output ports, using standard inp/outp functions. The CR registers


6


H,


16


H,


11


H,


10


H,


12


H and


15


H must first be unlocked, as indicated in Unlock CRTC registers, step


108


in

FIG. 7

, to make them writeable. They are unlocked by clearing bit


7


in controller register


11


H.




Addressing of video memory, step


112


, is accomplished through one of several means. One is to use the standard VGA 64 Kb “hardware window”, moving it along the video memory buffer


67


(

FIG. 4

) in 64 Kb increments as necessary. The preferred method is to enable linear addressing by querying the video chipset for the linear window position address, step


138


of FIG.


11


. This 32-bit offset in memory allows the program to map the linear memory to a physical address, steps


140


and


142


of

FIG. 11

, that can be manipulated programmatically.




At this point the program can modify the size of the display, step


114


and

FIG. 9

, to include the border areas. This routine first checks to determine whether or hot the system is running in “toolbar” mode, step


144


, and, if so, returns true. If not, it then determines whether to reset all registers and values to their original state, effectively returning the display to its original appearance, step


152


. The determination is based upon a number of parameters, such as whether the current resolution, step


146


, reflects a standard value or previous programmatic manipulation, step


148


. If a standard resolution is already set, the variables are reset to include the specified border areas, step


150


. The CR registers are adjusted, step


154


, to modify the scanned and blanked areas of the display. If the top or side areas are modified existing video memory is moved accordingly in step


162


of FIG.


10


.




If any of the foregoing routines returns a failure, the program may prompt the user to determine whether “emulation” mode, step


13


, or windowed mode step


116


should be used or if the program should exit at step


124


.




In its simplest form, the invention can be treated as a technique for adding a secondary GUI by reconfiguring the actual display mode to add a modified, non-standard GUI mode in which the standard display size or resolution has been adjusted to include a secondary display in addition to the primary display. For example, a standard 640×480 display is modified in accordance with the present invention to become a larger display, one section of which corresponds to the original 640×480 display while another section corresponds to a 640×25 secondary GUI display.




There are various techniques or mechanisms required for modifying the system to include the secondary GUI, depending upon the requirements of the secondary GUI and upon the present circumstances of the unmodified system.




In another embodiment of the present invention system resources are allocated for a secondary GUI by fooling the video driver into going to larger resolution. This technique automatically guarantees that enough space is kept clean, since the video driver allocates system resources according to the resolution that the video driver believes it will be operating in. To operate one or more secondary user interfaces in one or more areas of the screen it is necessary to have the memory that was associated in video memory or in the frame buffer with that location, contiguously below the primary surface free and available. By writing a series of small applets specific to hardware known to have system resource allocation problems for a secondary user interface, the secondary user interface application may run such applet whenever resolutions will be switched, initializing the chip set pertinent to that particular applet. If the application finds an applet pertinent to the current particular chip set it will be launched. The applet or minidriver initializes itself, performs the necessary changes to the driver's video resolution tables, forces a reenable, and sufficient space is subsequently available for one or more secondary user interfaces.




When reenabled, the driver allocates video memory as needed for the primary display according to the data on the UCCO resolution tables. Therefore, the modified values result in a larger allocation. Once the driver has allocated memory necessary for the primary surface, the driver will allow no outside access to the allocated memory. Thus by fooling the driver into believing that it needs to allocate sufficient memory for a resolution exactly x bytes larger than the current resolution where x is the size of one or more secondary user interfaces, the application can be sure that no internal or external use of the allocated memory location can conflict with the secondary user interface.




This method ensures that system resources will be allocated for one or more secondary user interfaces by writing an applet that would address the video driver in such a way as to force the video driver, on its next reenable, to allocate video memory sufficient for a resolution higher than the actual operating system resolution. This may also be done by modifying each instance of the advertised mode tables, and thus creating a screen size larger than the primary user interface screen size.




This technique has an additional benefit of eliminating the need to prevent the driver from actually shifting into the specified larger resolution, handing the primary user interface a larger display surface resolution. The “hardware mode table,” a variant of the aforementioned video resolution tables, is not advertised and not accessible. Therefore, when the driver validates the new resolution, checking against the hardware mode table, it will always fail and therefore refuse to shift into that resolution. Because this technique modified the advertised video resolution tables early enough in the driver's process, allocated memory was modified, and memory addresses set before the failure in validate mode. Subsequently when the CRTCs are modified, in step


114


, the driver is reserving sufficient memory for one or more secondary user interfaces and not making it available for any other process or purpose.




In yet another embodiment of the present invention, an enveloping driver is installed to sit above the existing driver and shims itself in between the hardware abstraction layer and the actual video driver in order to be able to handle all calls to the video driver and modify the driver and the driver's tables in a much more generic fashion rather than in a chipset specific fashion. The enveloping driver shims into the primary video driver, transparently passing calls back and forth to the primary video driver. The enveloping driver finds the video resolution tables in the primary video driver which may be in a number of locations within the driver. The enveloping driver modifies the tables (for example, increasing 800 by 600 to 800 by 620). A 1024 by 768 table entry may become 1024 by 800.




Like the previously described embodiment, the primary driver cannot validate the new resolution and therefore cannot actually change the display setting. As a result, the driver allocated memory, allocated the cache space, determined memory address and moved cache and off screen buffers as necessary. So the primary driver never uses all the space allocated, and will never draw in that space.




As stated earlier, the method of the present invention may include three primary steps, finding or producing unused video memory, creating or expanding the overscan area, and putting data in the overscan area.




The step of finding or producing the unused video memory requires a review of the contents of the Controller Registers, the CR registers, used by VGA compatible chip sets or graphic boards to identify where the overscan area, the blanking, the vertical and horizontal total and the sinking should be set. The CR defines the desktop display, how its synched, where it's laid out left and right, how much buffer area there would be on each side, where it would be stored within the video memory area. A review of the contents of the CR data registers therefore fully defines and allows one to control the potential location and size of the overscan area.




In order to accomplish the step of creating or expanding the overscan area the CRs may currently be used directly for systems with video display resolutions up to and including 1024 pixels in any dimension, that is, resolutions which can be defined in the generally accepted VGA standards by 10 bits per register. To expand the overscan area, new data is written into the CR using standard techniques such as the Inp and Outp, functions. A standard video port and MMIO functions may also be used to modify the CRs.




At greater resolutions, 11 bits may be needed to properly define the resolution. There is currently no standard way in which the 11


th


bit location is defined. Therefore, at a resolution above 1280 by 1024, for example, an understanding about the video card itself, particularly how the 11 bits representing the resolution are stored, is currently required and will be described below in greater detail.




When expanding the overscan, it is important to make sure a previous overscan bar is not already displayed, possibly from a previous crash or other unexpected problem. Either the display must be immediately reset to the appropriate resolution defaults, or the CR queried to determine if the total screen resolution as understood by the video card and drivers differs from the screen resolution known by the operating system display interface. An overscan bar may already be displayed if the total screen resolution is not equal to one of the standard VGA or SVGA resolutions. In particular, if the total screen resolution is equal to a standard VGA/SVGA resolution plus the area required for the overscan bar or is greater than the resolution reported by the operating system display interface, the display is reset.




Once the display area or resolution as stored in the CR is determined, the resolution or display area can be extended in several different ways. The overscan area can be added to the bottom, the top, or the right of the current display area, and optionally, the display area can be repositioned so that the overscan bar can remain centered in appearance. Alternatively the overscan area can be added anywhere and the original or desktop display area can be centered to improve appearance. In any event, the height/width of the display area required for the overscan bar is presented adjacent the desktop area stored in the CR and the combination is written into the CR, overwriting the previous data.




The screen typically shows a quick flash as it is placed in a different mode, including the desktop display area as well as a parallel GUI such as a display bar in the overscan area. As soon as that change occurs, a black mask can be positioned over the new areas. The new menu data can then be safely written on top of the black mask so that the user never sees memory “garbage”.




There is typically a few seconds of load time during which a simple message can be displayed, such as “Loading . . . ”, to avoid confusing the user.




There are a number of mechanisms by which this may be done. A set of class objects is used, all derived from a common base class corresponding to the above described VGA-generic technique.




The first mechanism is an implementation of the VGA-generic technique. Using this mechanism, no information specific to a video-card is necessary, other than ensuring VGA support. Using standard application programming interface (API) routines, primary and secondary surfaces are allocated. The new display data in the CR is simply the physical address at the start of the primary surface plus the number of pixels defined by the screen size.




Allocation of the primary surface will always be based on the entire screen display. Given the linear address of the allocated primary surface, from which a physical address can be derived, it can be extrapolated that the physical address of the location in video memory immediately adjacent to the primary surface is represented by the sum of the number of bytes of memory used to maintain the primary surface in memory plus the value of the physical address of the primary surface.




Once the physical address of the primary surface is known, the size of the primary surface as represented in video memory can be determined.




For example, the system looks in the CRs for the resolution of the screen, 800 by 600, in terms of number of bits per pixel, or bytes per pixel. Then any data stored in the CR representing any horizontal synching space is added. This is the true scan line length. The scan line length is a more accurate measurement of the width in a given resolution.




Next, the physical address of the allocated secondary surface is derived from its linear address. In the case where the allocated secondary surface is, in fact, allocated in the memory space contiguous to the primary surface (the value of the secondary surface physical address is equal to the value of the primary surface physical address plus the size of the primary), the secondary surface is determined to be the location in memory for the overscan display.




If, however, the above is not true and the secondary surface is not contiguous to the primary surface, another approach mechanism is required.




To summarize, the first mechanism determines how much physical area to allocate for the desktop allowing adjacent area for parallel GUI secondary space beyond that to display in the overscan area. The newly allocated area will be the very first block of memory available. If this block immediately follows the primary surface, the physical address will correspond to the value associated with the physical address of the primary surface, plus the size of the primary surface. If that is true, the memory blocks are contiguous, this VGA-generic mechanism can be used.




If this first, VGA-generic mechanism cannot be used, the video card and driver name and version information retrieved from the hardware registry and BIOS, as described earlier, is used in conjunction with a look-up-table to determine the best alternatives among the remaining mechanisms. The table includes a set of standards keyed to the list of driver names found in the hardware registry. A class object specific to the video chipset is instantiated based, directly or indirectly, on the VGA-generic object.




If the hardware look up does not result in a reliable match, a reliability, or confidence, fudge factor may be used. For example, if the hardware look up determines that an XYZ-brand device of some kind is being used, but the particular XYZ device named is not found in the look up table, a generic model from that chipset manufacturer many often be usable. If no information is available, the user may get a message indicating that the hardware is not supported and that the program cannot run in the overscan area. The user may then be queried to determine if the system should be operated in the “application-toolbar” mode, which basically runs with exactly the same functionality but in a windowed environment within the desktop rather than in the overscan area outside the desktop.




The next alternative mechanism uses surface overlays. The first step to this approach is to determine if the system will support surface overlays. A call is made to the video driver to determine what features are supported and what other factors are required. If surface overlays are supported, for example, there may be a scaling factor required.




For example, a particular video card in a given machine, using 2 megabytes of video RAM, might support unscaled surface overlays at 1024×768 at 8 bits per pixel, but not at 1024×768 at 16 bits per-pixel because the bandwidth of the video card or the speed of the card, coupled with the relatively small amount of video memory would not be sufficient to draw a full width overlay. It is often horizontal scaling that is at issue, preventing the driver from drawing a full width overlay. An overlay is literally an image that is drawn on top of the primary surface. It is not a secondary surface, which is described above. Typically, the system sends its signal from the video driver to the hardware such that it merges the two signals together, overlaying a second signal on top of the first.




If a system can not support unscaled overlays, perhaps because of bandwidth issues or memory issues, this mechanism is not desirable. It is not rejected, but becomes a lower priority alternative. For example, if the scaling factor is below 0.1, then the normal bar can be drawn and it will be clipped closer to the edge. If the scaling factor is more than 10%, another approach mechanism is required




In the next set of alternative mechanisms, a secondary surface is allocated sufficient in size to encompass the normal desktop display area plus the overscan area to be used for display of the overscan bar or bars. Using these mechanisms, the allocated secondary surface does not have to be located contiguous in memory to the primary surface. However, these approaches use more video memory than the others.




The first step is to allocate a secondary surface sufficient in size to contain the video display (the primary surface) plus the overscan area to be used. If the allocation fails, that means that there is not enough video memory to accomplish the task and this set of mechanisms is skipped and the next alternative tried. After the new block of memory is allocated, a timer of very small granularity is used to execute a simple memory copy of in the contents of the primary surface onto the appropriate location of this secondary surface. The timer executes the copy at approximately 85 times per second.




Within this set of alternative mechanisms is a variant that uses the system page tables. This mechanism queries the system page tables to determine the current GDI surface address, that is, the physical address in the page table for the primary surface. A secondary surface is then created large enough to hold all of what is in the video memory plus the memory required for the overscan bar to be displayed. This surface address is then pushed into the system page table and asserted as the GDI surface address.




Thereafter, when GDI reads from or writes to the primary surface through the driver, it actually reads from or, writes the new, larger surface. The overscan bar program can, subsequently, modify the area of the surface not addressed by GDI. The original primary surface can be de-allocated and the memory usage reclaimed. This mechanism, being more memory-efficient than the previously described mechanism, is the preferred alternative. But the page tables solution will not work correctly on a chipset that includes a coprocessor device. If the initial device query reveals that the device does include a coprocessor, this variant mechanism will not be attempted.




Other variations of the above-described mechanisms are accounted for in derived class objects. For example, the VGA-generic mechanisms may vary when the video card requires more than ten bits to represent the video resolution in the CR. Some instances may require 11 bits. Such registers typically do not use contiguous bytes, but use extension bits to designate the address information for the higher order bits.




In this example, the eleventh bit is usually specified in an extended CR register and the extended CR registers are usually chip specific.




Similarly, a variation of the surface overlay mechanism includes a scaling factor, as described above. This alternative is handled in specific implementations through derived class objects and may be the best solution in certain situations.




Another implementation of this technology uses a “hooking” mechanism as shown in FIG.


14


. After the display driver is identified through the hardware registry or the BIOS, as described above, certain programming interface entry points into the driver are hooked such as at step


117


. In other words, when the video system device interface, Windows GDI for example, calls those entry points into the display driver, the program can take the opportunity to modify the parameters being passed to the display driver, and/or to modify the values being returned from the display driver.




By hooking the “ReEnable” function in the display driver, at step


117


, the overscan bar program can allocate screen area in different ways in step


119


:




(1) In step-up mode, step


121


, by intercepting a resolution change request and identifying the next-higher supported screen resolution and passing that higher resolution to the display driver, then, when the display driver acknowledges the change, intercepting the returned value, which would reflect the new resolution, and actually returning the original requested resolution instead. For example, GDI requests a change from 640×480 resolution to 800×600 resolution; the overscan program intercepts the request and modifies it to change the display driver to the next supported resolution higher than 800×600, say 1024×768. The display driver will change the screen resolution to 1024×768 and return that new resolution. The overscan program intercepts the return and instead passes the original request, 800×600, to GDI. The display driver has allocated and displays a 1024×768 area of memory. GDI and Windows will display the desktop in an 800×600 area of that display, leaving areas on the right and bottom edges of the screen available to the overscan program.




(2) In shared mode, step


123


, by intercepting only the return from the display driver and modifying the value to change the operating system's understanding of the actual screen resolution. For example, GDI requests a change from 800×600 resolution to 1024×768 resolution. The overscan program intercepts the returned acknowledgment, subtracting 32 before passing the return on to GDI. The display driver has allocated and displays a 1024×768 area of memory. GDI and Windows will display the desktop in an 1024×736 area of that display, leaving an area on the bottom edge of the screen available to the overscan bar program.




After hooking, the overscan bar program can display by:




(1) using standard API calls to render the bar to an off-screen buffer, as described in the next section, and then hooking the “BitBlt” function entry point into the display driver in order to modify the offset and size parameters and subsequently redirect the BitBlt to the area outside of that which the API believes is onscreen.




(2) using mechanisms of primary and secondary surface addresses, described earlier, the program determines the linear addresses for the off-desktop memory location(s) left available to it, and can render directly to those memory locations.




Phase 2 of the invention begins by painting the new images into a standard off-screen buffer, step


118


, as is commonly used in the art, and making the contents visible, step


120


, as described in FIG.


10


. If the program is in “toolbar” mode, step


156


, the off-screen buffer is painted into the standard window client space, step


166


, and made visible, step


164


, using generic windowing-system routines. Otherwise, the linear window position address is mapped, step


158


, as described in

FIG. 11

which has been previously explained. Once the linear memory is mapped to a physical memory address, step


142


, the contents of the off-screen display buffer can be copied into the video buffer directly, step


154


of

FIG. 10

, or painted as to a secondary surface.




The preferred embodiment application includes a standard application message loop, step


122


, which processes system and user events. An example of a minimum functionality process loop is in FIG.


12


. Here the application handles a minimal set of system events, such as painting requests, step


170


, system resolution changes, step


172


, and activation/deactivation, step


174


. Here, too, is where user events, such as key or mouse events, may be handled, step


184


, detailed in FIG.


13


. System paint messages are handled by painting as appropriate into the off-screen buffer, step


178


, and painting the window or display buffer, step


180


, as appropriate, as described earlier in FIG.


10


. System resolution messages are received whenever the system or user changes the screen or color resolution. The programs reset all registers to the correct new values, then change the display resolution, step


182


, as earlier described in

FIG. 9

, to reflect the new resolution modified. User messages are ignored when the program is not the active application.





FIG. 13

describes a method of implementing user-input events. In this embodiment, there are three alternative mechanisms used to implement cursor or mouse support so that the user has a pointing device input tool within the overscan area user interface.




In the preferred mechanism, GDI's “cliprect” is modified to encompass the overscan bar's display area. That keeps the operating system from clipping the cursor as it moves into the overscan area. This change doesn't necessarily make the cursor visible or provide event feedback to the application, but is the first step.




Some current Windows applications continually reset the cliprect. It is a standard programming procedure to reset the cliprect after use or loss of input focus. Some applications use the cliprect to constrain the mouse to a specific area as may be required by the active application. Whenever the overscan display bar interface receives the input focus it reasserts the cliprect, making it large enough for the mouse to travel down into the overscan space.




Once the cliprect has been expanded, the mouse can generate messages to the operating system reflecting motion within the expansion area. GDI does not draw the cursor outside what it understands to be its resolution, however, and does not pass “out-of-bounds” event messages on to an application. The overscan program uses a VxD device driver, and related callback function, to make hardware driver calls at ring zero to monitor the actual physical deltas, or changes, in the mouse position and state. Every mouse position or state change is returned as an event to the program which can graphically represent the position within the menu display bar.




An alternative mechanism avoids the need to expand the cliprect in order to avoid conflict with a class of device drivers that use the cliprect to facilitate virtual display panning. Querying the mouse input device directly the overscan program can determine “delta's”, changes in position and state. Whenever the cursor touches the very last row or column of pixels on the standard display, it is constrained there by setting the cliprect to a rectangle comprised of only that last row or column. A “virtual” cursor position is derived from the deltas available from the input device. The actual cursor is hidden and a virtual cursor representation is explicitly displayed at the virtual coordinates to provide accurate feedback to the user. If the virtual coordinates move back onto the desktop from the overscan area, the cliprect is cleared, the virtual representation removed, and the actual cursor restored onto the screen.




A third alternative mechanism creates a transparent window that overlaps the actual Windows desktop display area by a predefined number of pixels, for example, two or four pixels. If the mouse enters that small, transparent area, the program hides the cursor. A cursor image is then displayed within the overscan bar area, at the same X-coordinate but at a Y-coordinate correspondingly offset into the overscan area. If a two-pixel overlap area is used, this method uses a granularity of two. Accordingly, this API-only approach provides only limited vertical granularity. This alternative mechanism assures that all implementations will have some degree of mouse-input support, even when cliprect and input device driver solutions fail.





FIG. 7

describes the cleanup mechanisms executed when the program is closed, step


124


. The display is reset to the original resolution, step


126


, and the CR registers are reset to their original values, step


128


, and locked, step


130


.




In another embodiment of the present invention, the launching or initiating of alternate display content controller


6


may be modified and controlled. Alternate display content controller


6


may be launched as a service, as an application, or as a user application. As a service, alternate display content controller


6


may be launched as a service within the registry of utility operating system


5


B. The first kind of application is launched in the Run section in the registry, and the user application may be initiated from the Start Up Group within the Start button. Thus, alternate display content controller


6


may be initiated any time from the first thing after graphics mode is enabled to the very last thing initiated.




Launched as a service, alternate display content controller


6


may be visible shortly after utility operating system


5


B such as Windows actually addresses the display, and how soon after depends on where alternate display content controller


6


is put it in the order of the things that will be launched as services. It may be possible to put alternate display content controller


6


so that it launches as essentially the first service and thus would launch almost at the same time as the drivers, very, very shortly after the drivers are launched. Accordingly, it is possible to have the screen change from textmode to graphics, draw the colored background, immediately re-display with the overscan addressed and a parallel GUI such as CSNB


2


display the very close to the same time as taskbar. Launched as a run-line application, alternate display content controller


6


may be visible in display space


1


shortly after icons appear.




NetSpace




Referring again to

FIG. 1

, in an alternate embodiment of the present invention, the technique of controlling the allocation of display area


1


is used to open a context sensitive network browser


2


(CSNB) adjacent but not interfering with operating system desktop


3


and/or parallel graphical user interface


4


. A display controller such as alternate display content controller


6


may include CSNB


2


thus permitting the browser to create and control a space for itself on display


1


which may not be overwritten by utility operating system


5


B. The combined controller/browser may be an application running on the computer operating system, or may include an operating system kernel of varying complexity ranging from dependenton the utility operating system for hardware system services to a parallel system independent of the utility operating system and capable of supporting dedicated applications. The alternate display content controller/browser may also include content and operating software, such as JAVA delivered over the Internet I or any other LAN. There may also be more than one context sensitive network browser and more than one parallel graphical user interface in addition to the operating system desktop.




Context sensitive interface such as network browser


2


may respond to movement and placement of cursor IC controlled by a pointing device such as mouse


1


M anywhere on display area


1


. The generation and control of a cursor across two or more parallel graphical user interfaces was described previously.




The location of cursor


1


C will trigger CSNB


2


to retrieve appropriate and related network pages such as web page


2


A. CSNB


2


may store the last X number of CSNB enabled network addresses for display offline. In a currently preferred embodiment of the present invention, X is ten pages. If a user is examining a saved CSNB enabled page offline, a mouse click on the page or a link on the page will initiate the users dial-up sequence and establish an online connection.




In an alternate embodiment, alternate display content controller


6


may include a browser or search engine. In an alternate embodiment of the present invention, space


2


C may include an edit input box 2D. Edit input box 2D may include conventional functionality's such as edit, copy, paste, etc. A user may enter a URL into edit input box 2D using any conventional input device and then select a button to launch or initiate alternate display content controller


6


as a browser. This may be accomplished by using objects and or drivers from utility operating system


5


B. Initiating alternate display content controller


6


as a browser would include a simple window to display the URL as a live HTML document with all conventional functionality. By implementing alternate display content controller


6


as a little applet that uses that DLL, it may slide on, or slide off. Thus initiating alternate display content controller


6


as a browser is like a window into the Internet.




Secondly, a user may enter any text into edit input box 2D using any conventional input device and then select a button to launch or initiate alternate display content controller


6


as a search engine. By entering a search string and selecting “search” and enter any string and click on “search” and pass that to any number from one to whatever or existing search engines, and subsequently have the search string acted on by one or more selected search engines and or by alternate display content controller


6


as a search engine. Resulting in multiple different windows appearing in some sort of stacked or cascaded or tiled format, with the different searches within them.




Using alternate display content controller


6


as a search engine or browser, the results or HTML document may be displayed in any overscan area or on the desktop.




Referring now to

FIG. 17

, a context sensitive network browser such as CSNB


13


may also include a suite of tools such as tools


14


that may or may not have fixed locations on the browser space. Such tools may include but are not limited to e-mail, chat, buddy lists and voice. As shown, spaces such as desktop


14


A, web page


14


B, secondary GUI


14


C and browser


13


may be arranged in any convenient manner.




Alternative Embodiments




1. Utilizing the VESA BIOS Extensions (VBE) in place of the CRT Controller registers (

FIG. 5

) to determine the linear window position address, step


138


, as necessary.




2. Utilizing API's (application programming interfaces)


62


capable of direct driver and/or hardware manipulation, such as Microsoft's DirectX and/or DirectDraw, in place of the CRT Controller registers and/or direct access to the display buffer.




3. Utilizing API's (applications programming interfaces)


62


, such as Microsoft's DirectX and/or DirectDraw, capable of direct driver and/or hardware manipulation, to create a second virtual display surface on the primary display with the same purpose, to display a separate and unobscured graphical user interface.




4. Utilizing modifications in the video subsystem of the operating system


63


in place of the CRT Controller registers and/or DirectX access to the display buffer.




5. Utilizing modifications in the video subsystem of the operating system


63


to create a second virtual display surface on the primary display with the same purpose, to display a separate and unobscured graphical user interface.




6. Building this functionality into the actual video drivers


64


and/or mini-drivers. Microsoft Windows provides support for virtual device drivers, VxDs, which could also directly, interface with the hardware and drivers. These could also include an API to provide applications with an interface to the modified display.




7. Incorporating the same functionality, with or without the VGA registers, into the BIOS and providing an API to allow applications an interface to the modified display.




8. Incorporating the same functionality into hardware devices, such as monitor itself, with hardware and/or software interfaces to the CPU.




9. This technique may be used to control the desktop (i.e. Windows) to easily enable the desktop to operate in virtually any non-standard size limited only by the capability of the display hardware. This may be in combination with parallel graphical user interface displays or exclusively to maximize the primary operating system desktop display area. This may not require any modification to the operating system.




In overview, the visual display area is conventionally defined by the values maintained in the CRTC registers on the chip and available to the driver. The normally displayed area is defined by VGA standards, and subsequently by SVGA standards, to be a preset number of modes, each mode including a particular display resolution which specifies the area of the display in which the desktop can be displayed.




The desktop can only be displayed in this area because Windows does not directly read/write the video memory, rather it uses programming interface calls to the video driver. And the video driver simply reads/writes using an address that happens to be in video memory. So the value this mechanism needs to realize is the value the video card and driver assert is available for painting. This value is queried from the registers, modified by specific amounts and rewritten to the card. Subsequently, the present invention changes the area of writable visible display space without informing the operating system's display interface of the change




This invention doesn't necessary change the CRTCs to add just to the bottom. Preferably the top is also moved up a little. This keeps the displayed interfaces centered within the drivable display area. For example, rather than just add thirty-two scan lines to the bottom, the top of the display area is moved up by sixteen lines.




Nor does this invention depend solely upon the ability to change the CRTCs to modify the visible display area. Alternative mechanisms define other methods of creating and accessing visible areas of the screen that are outside the dimensions of the desktop accessed by the operating system's display interface.




From a consideration of the specifications, drawings, and claims, other embodiments and variations of the invention will be apparent to one skilled in the art of computer science.




In particular, the secondary GUI may be positioned in areas not normally considered the conventional overscan area. For example, the secondary GUI may be positioned in a small square exactly in the center of the normal display in order to provide a service required by the particular system and application. In fact, the techniques of reading and rewriting screen display information can be used within the scope of the invention to maintain the primary GUI information, or portions of it, in an additional memory and selectively on a timed, computed, interactive, or any or other basis, replace a portion of the primary GUI with the secondary GUI such as a pop-up, window, or any other display space.




As a simple example, a security system may require the ability to display information to a user without regard to the status of the computer system and/or require the user to make a selection, such as call for help by clicking on “911?”. The present invention could provide a video display buffer in which a portion of the primary GUI interface was continuously recorded and displayed in a secondary GUI for example in the center of the screen. Under non-emergency conditions, the secondary GUI would then be effectively invisible in that the User would not notice anything except the primary GUI.




Under the appropriate emergency conditions, an alarm monitor could cause the secondary GUI to present the “911?” to the user by overwriting the copy of the primary display stored in the secondary GUI memory. Alternatively, a database of photographs may be stored and one recalled in response to an incoming phone call in which caller ID identified a phone number associated with a database photo entry.




In general, the present invention may provide one or more secondary user interfaces which may be useful whenever it is more convenient or desirable to control a portion of the total display, either outside the primary display in an unused area such as overscan or even in a portion of the primary GUI directly or by time division multiplexing, directly by communication with the video memory, or by bypassing at least a portion of the video memory to create a new video memory. In other words, the present invention may provide one or more secondary user interfaces outside of the control of the system, such as the operating system, which controls the primary GUI.




Additional user interfaces may be used for a variety of different purposes. For example, a secondary user interface may be used to provide simultaneous access to the Internet, full motion video, and a conference channel. A secondary user interface may be dedicated to a local network or multiple secondary user interfaces may provide simultaneous access and data for one or more networks to which a particular computer may be connected.




Having now described the invention in accordance with the requirements of the patent statutes, those skilled in this art will understand how to make changes and modifications in the present invention to meet their specific requirements or conditions. Such changes and modifications may be made without departing from the scope and spirit of the invention as set forth in the following claims.



Claims
  • 1. A method in a computer system for enabling unobscured display of output on a video display system, the computer system having an operating system display interface that enables an operating system user interface to display data on a first display area of the video display system under control of the operating system, the output for unobscured display generated from a network associated with the computer system, comprising:adjusting the display parameters of the video display system to create a second display area not under control of the operating system, the second display area being capable of displaying output that is not obscured by output from the operating system display interface; and writing the output generated from the network to the second display area so that the output generated from the network is displayed in conjunction with the operating system user interface.
  • 2. The method of claim 1 wherein an online connection to the network is reestablished automatically when the displayed output generated from the network is accessed in a manner that indicates that the displayed output is to be updated from the network.
  • 3. The method of claim 1 wherein the displayed output is a web page from the Internet.
  • 4. The method of claim 1 wherein the displayed output includes an input field associated with a search engine, and further comprising:receiving a network search request that has been entered into the input field; sending the received search request to the search engine; receiving search results from the search engine; and displaying the search results on the second display area.
  • 5. The method of claim 1 wherein the displayed output includes an input field, and further comprising:receiving an address of additional network data entered into the input field, wherein the data is any type of output; sending the received address over the network to retrieve the additional data; receiving the additional data; and displaying the received additional data on the second display area.
  • 6. The method of claim 1 wherein the network generated output is displayed in both the first display area and the second display area, thereby prohibiting a portion of the network generated output from being overwritten by the operating system user interface.
  • 7. The method of claim 1 wherein the adjusting the display parameters of the video display system operates by changing the resolution of the video display system and reducing the size of the first display area available to the operating system user interface.
  • 8. A network portal in a computer system for enabling unobscured display of output generated from a network on a video display system, the computer system having an operating system display interface that enables an operating system user interface to display itself on a first display area of the video display system, comprising:display area adjuster that adjusts the display parameters of the video display system to create a second display area that is capable of displaying output that is not obscured by output from the operating system display interface and which cannot be controlled by the operating system; and display transfer facility that writes the output generated from the network to the second display area so that the output generated from the network is displayed in conjunction with the operating system user interface.
  • 9. The system of claim 8 wherein an online connection to the network is reestablished automatically when the displayed output generated from the network is accessed in a manner that indicates that the displayed output is to be updated from the network.
  • 10. The system of claim 8 wherein the displayed output is a web page from the Internet.
  • 11. The system of claim 8 wherein the displayed output includes an input field associated with a search engine, the system further comprising:network search facility that receives a network search request that has been entered into the input field; sends the received search request to the search engine; receives search results from the search engine; and displays he search results on the second display area.
  • 12. The system of claim 8 wherein the displayed output includes an input field, the system further comprising:network browse facility that receives an address of additional network data that has been entered into the input field, wherein the data comprises any type of output; sends the received address over the network to retrieve the additional network data; receives the additional data; and displays the received data on the second display area.
  • 13. The system of claim 8 wherein the display transfer facility writes the network generated output to both the first display area and the second display area, thereby prohibiting a portion of the network generated output from being overwritten by the operating system user interface.
  • 14. The system of claim 8 wherein the display area adjuster creates the second display area by changing the resolution of the video display system and by reducing the size of first display area available to the operating system user interface.
  • 15. A computer-readable memory medium containing instructions for controlling a computer processor of a computer system to display unobscured output of a video display system, the computer system having an operating system display interface that enables an operating system user interface to display itself on a first display area of the video display system, the output for unobscured display generate from a network associated with the computer system, by:adjusting the display parameters of the video display system to create a second display area that is capable of displaying output that is not obscured by output from the operating system display interface and which cannot be controlled by the operating system; and writing the output generated from the network to the second display area so that the output generated from the network is displayed in conjunction with the operating system user interface.
  • 16. The computer-readable memory medium of claim 15 wherein an online connection to the network is reestablished automatically when the displayed output generated from the network is accessed in a manner that indicates that the displayed output is to be updated from the network.
  • 17. The computer-readable memory medium of claim 15 wherein the displayed output is a web page from the Internet.
  • 18. The computer-readable memory medium of claim 15 wherein the displayed output includes an input field associated with a search engine, and further comprising:receiving a network search request that has been entered into the input field; sending the received search request to the search engine; receiving search results from the search engine; and displaying the search results on the second display area.
  • 19. The computer-readable memory medium of claim 15 wherein the displayed output includes an input field, and further comprising:receiving an address of additional network data entered into the input field, wherein the data is any type of output; sending the received address over the network to retrieve the additional data; receiving the additional data; and displaying the received additional data on the second display area.
  • 20. The computer-readable memory medium of claim 15 wherein the network generated output is displayed in both the first display area and the second display area, thereby prohibiting a portion of the network generated output from being overwritten by the operating system user interface.
  • 21. The computer-readable memory medium of claim 15 wherein the adjusting the display parameters of the video display system operates by changing the resolution of the video display system and reducing the size of the first display area available to the operating system user interface.
  • 22. A method in a computer system for displaying designated output on a video display system, the computer system having an operating system display interface that enables an operating system user interface to display itself on a first display area of the video display system, comprising:adjusting the display parameters of the video display system in a manner transparent to the operating system to create a second display area that is capable of displaying output that is not obscured by output from the operating system display interface; and writing the designated output to the second display area so that the designated output is displayed in conjunction with the operating system user interface, wherein the method is performed by one of a service of the operating system and an application program.
  • 23. The method of claim 22 wherein, when the method is performed as a service of the operating system, the displayed output appears to be displayed as part of the operating system initialization of the video display system.
  • 24. The method of claim 22 wherein, when the method is performed by launching an application program, the displayed output appears to be displayed on the second display area when the application program is launched.
  • 25. The method of claim 22 wherein the adjusting of the display parameters is performed by function calls to device driver software that communicates with the video display system.
  • 26. The method of claim 22 further comprising reducing the size of the first display area.
  • 27. The method of claim 22 wherein a portion of the output displayed in the second display area appears to continuously overwrite the user interface displayed in the first display area while the output is displayed in the second display area.
  • 28. The method of claim 22 wherein the adjusting the display parameters operates by changing the resolution of the video display system and reducing the size of the first display area available to the operating system user interface.
  • 29. A display controller in a computer system having an operating system display interface that enables an operating system user interface to display itself on a first display area of a video display system, comprising:display adjustment facility that adjusts the display parameters of the video display system in a manner transparent to the operating system to create a second display area that is capable of displaying output that is not obscured by output from the operating system display interface; and display transfer mechanism that writes designated output to the second display area so that the designated output is displayed in conjunction with the operating system user interface wherein the display controller is invoked as one of a service of the operating system and an application program.
  • 30. The display controller of claim 29 wherein, when the display controller is invoked as a service of the operating system, the display transfer mechanism appears to display the designated output as part of the operating system initialization of the video display system.
  • 31. The display controller of claim 29 wherein, when the display controller is invoked by launching an application program, the display transfer mechanism appears to display the designated output on the second display area when the application program is launched.
  • 32. The display controller of claim 29 wherein the display adjustment facility adjusts the parameters of the video display system by performing function calls to device driver software that communicates with the video display system.
  • 33. The display controller of claim 29 wherein the display adjustment facility reduces the size of the first display area.
  • 34. The display controller of claim 29, wherein a portion of the output displayed in the second display area appears to continuously overwrite the user interface displayed in the first display area, while the display transfer mechanism displays the output in the second display area.
  • 35. The display controller of claim 29 wherein the display adjustment facility adjusts the display parameters by changing the resolution of the video display system and reducing the size of the first display area available to the operating system user interface.
  • 36. A computer-readable memory medium containing instructions for controlling a computer processor in a computer system to display designated output on a video display system, the computer system having an operating system display interface that enables an operating system user Interface to display itself on a first display area of the video display system, by:adjusting the display parameters of the video display system in a manner transparent to the operating system to create a second display area that is capable of displaying output that is not obscured by output from the operating system display interface; and writing the designated output to the second display area so that the designated output is displayed in conjunction with the operating system user interface; wherein the instructions are performed by one of a service of the operating system and an application program.
  • 37. The computer-readable memory medium of claim 36 wherein, when the instructions are performed as a service of the operating system, the displayed output appears to be displayed as part of the operating system initialization of the video display system.
  • 38. The computer-readable memory medium of claim 36 wherein, when the instructions are performed by launching an application program, the displayed output appears to be displayed on the second display area when the application program is launched.
  • 39. The computer-readable memory medium of claim 36 wherein the adjusting of the display parameters is performed by function calls to device driver software that communicates with the video display system.
  • 40. The computer-readable memory medium of claim 36, further comprising reducing the size of the first display area.
  • 41. The computer-readable memory medium of claim 36 wherein a portion of the output displayed in the second display area appears to continuously overwrite the user interface displayed in the first display area while the output is displayed in the second display area.
  • 42. The computer-readable memory medium of claim 36 wherein the adjusting the display parameters operates by changing the resolution of the video display system and reducing the size of the first display area available to the operating system user interface.
RELATED APPLICATIONS

This application is a continuation-in-part of application Ser. No. 09/246,040, filed Feb. 2, 1999, now U.S. Pat. No. 6,337,717, which is a continuation-in-part of application Ser. No. 09/191,322, filed Nov. 13, 1998, now U.S. Pat. No. 6,330,010, which is a continuation-in-part of application Ser. No. 08/975,268, filed Nov. 21, 197, now U.S. Pat. No. 6,018,332 the priority of which are hereby claimed, and also claims the priority of provisional application Ser. No. 60/088,478 filed Jun. 5, 1998.

US Referenced Citations (81)
Number Name Date Kind
4476464 Hobbs Oct 1984 A
4586035 Baker et al. Apr 1986 A
4642790 Minshull et al. Feb 1987 A
4649499 Sutton et al. Mar 1987 A
4710761 Kapur et al. Dec 1987 A
4868765 Diefendorff Sep 1989 A
4899136 Beard et al. Feb 1990 A
4972264 Bishop et al. Nov 1990 A
5001697 Torres Mar 1991 A
5036315 Gurley Jul 1991 A
5060170 Bourgeois et al. Oct 1991 A
5072412 Henderson, Jr. et al. Dec 1991 A
5119082 Lumelsky et al. Jun 1992 A
5146556 Hullot et al. Sep 1992 A
5202961 Mills et al. Apr 1993 A
5305435 Bronson Apr 1994 A
5339390 Robertson et al. Aug 1994 A
5367623 Iwai et al. Nov 1994 A
5367658 Spear et al. Nov 1994 A
5371871 Spilo Dec 1994 A
5394521 Henderson, Jr. et al. Feb 1995 A
5418572 Nonweiler et al. May 1995 A
5434969 Heilveil et al. Jul 1995 A
5473745 Berry et al. Dec 1995 A
5491795 Beaudet et al. Feb 1996 A
5500934 Austin et al. Mar 1996 A
5513342 Leong et al. Apr 1996 A
5521614 Kotha et al. May 1996 A
5561471 Kim et al. Oct 1996 A
5568603 Chen et al. Oct 1996 A
5586244 Berry et al. Dec 1996 A
5617526 Oran et al. Apr 1997 A
5619639 Mast Apr 1997 A
5621428 King et al. Apr 1997 A
5621904 Elliott et al. Apr 1997 A
5625782 Soutome et al. Apr 1997 A
5631825 van Weele et al. May 1997 A
5651127 Gove et al. Jul 1997 A
5652851 Stone et al. Jul 1997 A
5673403 Brown et al. Sep 1997 A
5675755 Trueblood Oct 1997 A
5704050 Redpath Dec 1997 A
5724104 Eom Mar 1998 A
5742285 Ueda Apr 1998 A
5742797 Celi, Jr. et al. Apr 1998 A
5745109 Nakano et al. Apr 1998 A
5745762 Celi, Jr. et al. Apr 1998 A
5757386 Celi, Jr. et al. May 1998 A
5764964 Dwin et al. Jun 1998 A
5771042 Santos-Gomez Jun 1998 A
5793438 Bedard Aug 1998 A
5796393 MacNaughton et al. Aug 1998 A
5812132 Goldstein Sep 1998 A
5818416 Hwang Oct 1998 A
5825357 Malamud et al. Oct 1998 A
5831592 Cahill, III Nov 1998 A
5838296 Butler et al. Nov 1998 A
5847709 Card et al. Dec 1998 A
5864347 Inoue Jan 1999 A
5874937 Kesatoshi Feb 1999 A
5874958 Ludolph Feb 1999 A
5874965 Takai et al. Feb 1999 A
5940077 Amro Aug 1999 A
5940610 Baker et al. Aug 1999 A
5995120 Dye Nov 1999 A
6002411 Dye Dec 1999 A
6008803 Rowe et al. Dec 1999 A
6018332 Nason et al. Jan 2000 A
6025841 Finkelstein et al. Feb 2000 A
6025884 Choi Feb 2000 A
6067098 Dye May 2000 A
6091430 Bodin et al. Jul 2000 A
6094230 Han Jul 2000 A
6108014 Dye Aug 2000 A
6151059 Schein et al. Nov 2000 A
6172669 Murphy et al. Jan 2001 B1
6185629 Simpson et al. Feb 2001 B1
6320577 Alexander Nov 2001 B1
6356284 Manduley et al. Mar 2002 B1
6426762 Nason et al. Jul 2002 B1
6437809 Nason et al. Aug 2002 B1
Foreign Referenced Citations (9)
Number Date Country
0419765 Apr 1991 EP
0 564 174 Oct 1993 EP
0747805 Dec 1996 EP
11167478 Jun 1999 JP
302453 Apr 1997 TW
357304 May 1999 TW
WO 96 34467 Oct 1996 WO
WO 9721183 Jun 1997 WO
WO 9927517 Jun 1999 WO
Non-Patent Literature Citations (16)
Entry
“Co-ordinating Multiple Graphical User Interfaces Video Access”, IBM Technical Disclosure Bulletin, vol. 39, No. 5, May 1996, pp. 7-9, XP000584036, New York, U.S.
U.S. patent application Ser. No. 09/344,409, Porter, filed Jun. 24, 1999.
U.S. patent application Ser. No. 09/517,874, Porter, filed Mar. 02, 2000.
Brunhoff, “Pleasing the Eye,” Unix Review 7(10):65-72, 1989.
Cohen et al., “Constraint-Based Tiled Windows,” IEEE Computer Society Press, pp. 35-45, 1986.
Gancarz, “Uwm: A User Interface for X Windows,” Summer Conference Proceedings, USENIX Association, Jun. 9-13, 1986, pp. 429-440.
Lantz and Rashid, “Virtual Terminal Management in a Multiple Process Environment,” Proceedings of the Seventh Symposium on Operating System Principles, Association for Computing Machinery, Dec. 10-12, 1979, pp. 86-97.
Meyrowitz and Moser, “Bruwin: An Adaptable Design Strategy for Window Manager/Virtual Terminal Systems,” Proceedings of the Eighth Symposium on Operating Systems Principles, Association for Computing Machinery, Dec. 14-16, 1981, pp. 180-189.
Stille et al., “A 2DL-An Adaptive Automatic Display Layout System,” Third Annual Symposium on Human Interaction with Complex Systems HICS '96,, IEEE Computer Society Press, pp. 243-250.
“Control Strip en Desktop Strip,” Apple World Magazine, pp. 6132-6133, XP002152897, Jul.-Aug. 1995.
“Flexible Tool Bar,” IBM Technical Disclosure Bulletin 36(08):91, XP000390153, Aug. 1993.
“Internet Kiosk Touch Panel Shell,” IBM Technical Disclosure Bulletin 39(08):85-87, XP000638146, Aug. 1996.
“Method and Apparatus for a Graphical Dial Interface,” IBM Technical Disclosure Bulletin 37(01):403, XP000428826, Jan. 1994.
“Single-Click Action Buttons,” IBM Technical Disclosure Bulletin 37(03):93, XP000441391, Mar. 1994.
“Three-Dimensional Selection Widget,” IBM Technical Disclosure Bulletin 38(02):423, XP000502528, Feb. 1995.
Van Name et al, “Easing the RAM-Cram Blues,” Byte 15(3):227-228, 230, 232, XP000652459, Mar. 1990.
Provisional Applications (1)
Number Date Country
60/088478 Jun 1998 US
Continuation in Parts (3)
Number Date Country
Parent 09/246040 Feb 1999 US
Child 09/263612 US
Parent 09/191322 Nov 1998 US
Child 09/246040 US
Parent 08/975268 Nov 1997 US
Child 09/191322 US