High performance low cost video game system with coprocessor providing high speed efficient 3D graphics and digital audio signal processing

Information

  • Patent Grant
  • 6556197
  • Patent Number
    6,556,197
  • Date Filed
    Monday, September 18, 2000
    24 years ago
  • Date Issued
    Tuesday, April 29, 2003
    21 years ago
Abstract
A low cost high performance three dimensional (3D) graphics system is disclosed that can model a world in three dimensions and project the model onto a two dimensional viewing plane selected based on a changeable viewpoint. The viewpoint can be changed on an interactive, real time basis by operating user input controls such as game controllers. The system rapidly produces a corresponding changing image (which can include animated cartoon characters or other animation) on the screen of a color television set.The richly featured high performance low cost system is intended to give consumers the chance to interact in real time right inside magnificent virtual 3D worlds to provide a high degree of image realism, excitement and flexibility. An optimum feature set/architecture (including a custom designed graphics/audio coprocessor) provides high quality fast moving 3D images and digital stereo sound for video game play and other graphics applications. Numerous features provide flexibility and capabilities in a system that is intended to be within the cost range of most consumers.
Description




FIELD OF THE INVENTION




The present invention relates to low cost video game systems. More particularly, the invention relates to a video game system that can model a world in three dimensions and project the model onto a two dimensional viewing plane selected based on a changeable viewpoint.




BACKGROUND AND SUMMARY OF THE INVENTION




People's imaginations are fueled by visual images. What we actually see at sunset, what we dream at night, the pictures we paint in our mind when we read a novel—all of these memorable scenes are composed of visual images. Throughout history, people have tried to record these images with pencils or paints or video tape. But only with the advent of the computer can we begin to create images with the same vividness, detail and realism that they display in the real world or in the imagination.




Computer-based home video game machines such as the Nintendo Entertainment System and the Super Nintendo Entertainment System have been highly successful because they can interactively produce exciting video graphics. However, without additional add-on hardware, these prior video graphics systems generally operated in two dimensions, creating graphics displays from flat (planar) image representations in a manner somewhat analogous to tacking flat paper cutouts onto a bulletin board. Although very exciting game play can be created using two dimensional graphics techniques, a 2D system cannot provide the realism offered by a three-dimensional graphics system.




3D graphics are fundamentally different from 2D graphics. In 3D graphics techniques, a “world” is represented in three dimensional space. The system can allow the user to select a viewpoint within the world. The system creates an image by “projecting” the world based on the selected viewpoint. The result is a true three-dimensional image having depth and realism.




For many years, specialists have used super computers and high end workstations to create incredible realistic 3D images—for example, ultra-detailed models of cars, planes and molecules; virtual reality as seen from the cockpit of a jet fighter or the front seat of an Olympic bobsled; and dinosaurs of “Jurassic Park.” However, in the past, computer systems required to produce such images interactively cost tens of thousands of dollars—well beyond the reach of the average consumer.




The low cost high performance 3D graphics system disclosed herein is intended to for the first time give millions of game players, not just the specialists, the chance to interact right inside these magnificent virtual 3D worlds with a richly featured high performance low cost system. What players get is truly amazing—many times the power of any home computer system, far more realistic 3-dimensional animation, stunning graphics—all delivered at a sufficiently low cost to be within the reach of the average consumer.




The following are a few examples of the many advantageous features provided by a system in accordance with the present invention:




Realistic interactive 3D graphics in a low price system




Optimum feature set/architecture for a low cost system for use with a color television set to provide video game play and other graphics applications in a low cost system and/or to produce particular screen effects




Coprocessor that provides high performance 3D graphics and digital sound processing




Signal processor sharing between graphics digital processing and audio signal processing to achieve high quality stereo sound and 3-D graphics in a low cost color television based system




Unified RAM approach increases flexibility




All major system components can communicate through the shared RAM




Techniques/structures for compensating for narrow main memory bus width




Executable code from a storage device (e.g., a portable memory cartridge) can be loaded into the common RAM and accessed by the main processor through coprocessor memory access/arbitration circuitry




Graphics coprocessor loadable microcode store receives microcode from a portable storage medium to provide additional flexibility and simplify compatibility issues




Microcode is loaded via execution of “boot ROM” instructions




Optimal commands and associated formats are used to invoke graphics and audio functions within the coprocessor and provide an interface between the graphics coprocessor and the rest of the system




Coprocessor register set including particular hardware register definitions, formats and associated functions




Microcode graphics and audio structure/processes provide efficient high performance operation




Vector unit provides optimal performance for graphics and audio digital processing in a low cost package




Pipelined rasterizing engine provides a one-pixel-per-cycle and two-pixel-per-cycle modes to minimize hardware cost while providing a rich feature set




Low coprocessor pin out











BRIEF DESCRIPTION OF THE DRAWINGS




These and other features and advantages of the present invention will be better and more completely understood by referring to the following detailed description of a presently preferred exemplary embodiment in connection with the drawings, of which:





FIG. 1

shows an overall video game system capable of generating 3-D images and digitally processed stereo sound;





FIGS. 1A-1F

show example 3-D screen effects achievable using the

FIG. 1

system;





FIG. 2

shows an example of principal components of an overall video game system;





FIG. 3

shows example major processing operations of an overall video game system;





FIG. 4

shows example overall operation of a video game system;





FIG. 4A

shows example overall steps performed by a video game system to generate graphics images;





FIG. 5

shows a detailed overall system architecture example;





FIG. 5A

shows an example main processor initialization routine;





FIG. 5B

shows an example main processor memory map;





FIG. 6

shows an example coprocessor internal architecture;





FIG. 6A

shows an example coprocessor internal bus architecture;





FIG. 7

shows an example signal processor internal architecture;





FIG. 7A

shows an example signal processor instruction format;





FIG. 7B

shows an example slicing of the

FIG. 7A

source or destination field for processing by the vector unit shown in

FIG. 7

;





FIG. 7C

shows an example add operation performed by the example signal processor vector unit;





FIGS. 7D-7L

show example signal processor registers;





FIG. 8

shows an example hierarchical task list including graphics display lists and audio play lists;





FIG. 9

shows an example microcode load routine;





FIG. 10

shows an example simple signal processor display list processing example;





FIG. 11

shows an example signal processor graphics microcode control step sequence;





FIG. 12A

shows an example double precision representation;





FIG. 12B

shows an example matrix format;





FIG. 13A

shows an example signal processor vertex buffer format;





FIG. 13B

shows an example vertex data definition;





FIG. 13C

shows an example signal processor segment addressing arrangement;





FIG. 14

shows an example audio software architecture;





FIG. 15

shows an example simple signal processor play list processing example;





FIG. 16

shows an example signal processor audio microcode control step sequence;





FIG. 17

shows an example signal processor audio processing construct;





FIG. 18

shows example overall display processor processing steps;





FIGS. 19A and 19B

show example display processor pipeline configurations;





FIG. 20

shows an example display processor architecture;





FIGS. 21A-21J

show example display processor registers;





FIG. 22

shows an example texture memory tile descriptor arrangement;





FIG. 23

shows an example texture unit process;





FIG. 24

shows an example texture coordinate unit and texture memory unit architecture;





FIG. 25

shows an example texture memory color index mode lookup;





FIG. 26

shows an example more detailed use of the texture memory to store color indexed textures;





FIG. 27

shows an example color combiner operation;





FIG. 28

shows an example alpha combiner operation;





FIG. 29

shows an example alpha fix up operation;





FIG. 30

shows an example of blending different types of primitives;





FIG. 31

shows an example blender operation;





FIG. 32

shows an example color pixel format;





FIG. 33

shows an example depth (z) pixel format;





FIG. 33A

shows an example write enable generation process;





FIG. 34

shows an example video interface architecture;





FIG. 34A

shows an example video interface operating sequence;





FIGS. 35A-35P

show example video interface control registers;





FIG. 36

shows an example main memory interface architecture;





FIGS. 37A-37H

show example memory interface controller registers;





FIG. 38

shows an example main processor interface architecture;





FIGS. 39A-39D

show example main processor interface registers;





FIG. 40

shows an example audio interface architecture;





FIGS. 41A-41F

show example audio interface registers;





FIG. 42

shows an example serial interface architecture;





FIGS. 43A-43D

show example serial interface registers;





FIG. 44

shows an example peripheral interface architecture;





FIGS. 45A-45I

show example peripheral interface control/status registers; and





FIGS. 46-118

show display processor


500


graphic display command example formats and associated functions.











DETAILED DESCRIPTION OF A PRESENTLY PREFERRED EXAMPLE EMBODIMENT





FIG. 1

shows an example embodiment video game system


50


in accordance with the present invention(s). Video game system


50


in this example includes a main unit


52


, a video game storage device


54


, and handheld controllers


56


(or other user input devices). In this example, main unit


52


connects to a conventional home color television set


58


. Television set


58


displays 3D video game images on its television screen


60


and reproduces stereo sound through its loud speakers


62


.




In this example, the video game storage device


54


is in the form of a replaceable memory cartridge insertable into a slot


64


on a top surface


66


of main unit


52


. Video game storage device


54


can comprise, for example, a plastic housing


68


encasing a read only memory (ROM) chip


76


. The read only memory


76


contains video game software in this example. When the video game storage device


54


is inserted into main unit slot


64


, cartridge electrical contacts


74


mate with corresponding “edge connector” electrical contacts within the main unit. This action electrically connects the storage device's read only memory


76


to the electronics within main unit


52


.




“Read only memory” chip


76


stores software instructions and other information pertaining to a particular video game. The read only memory chip


76


in one storage device


54


may, for example, contain instructions and other information for an adventure game. The read only memory chip


76


in another storage device


54


may contain instructions and information to play a driving or car race game. The read only memory chip


76


of still another storage device


54


may contain instructions and information for playing an educational game. To play one game as opposed to another, the user of video game system


50


simply plugs the appropriate storage device


54


into main unit slot


64


—thereby connecting the storage device's read only memory chip


76


(and any other circuitry the storage device may contain) to the main unit


52


. This enables the main unit


52


to access the information contained within read only memory


76


, which information controls the main unit to play the appropriate video game by displaying images and reproducing sound on color television set


58


as specified under control of the video game software in the read only memory.




To play a video game using video game system


50


, the user first connects main unit


52


to his or her color television set


58


by hooking a cable


78


between the two. Main unit


52


produces both “video” signals and “audio” signals for controlling color television set


58


. The “video” signals are what controls the images displayed on the television screen


60


, and the “audio” signals are played back as sound through television loudspeakers


62


. Depending on the type of color television set


58


, it may be necessary to use an additional unit called an “RF modulator” in line between main unit


52


and color television set


58


. An “RF modulator” (not shown) converts the video and audio outputs of main unit


52


into a broadcast type television signal (e.g., on television channel 2 or 3) that can be received and processed using the television set's internal “tuner.”




The user also needs to connect main unit


52


to a power source. This power source may comprise a conventional AC adapter (not shown) that plugs into a standard home electrical wall socket and converts the house current into a lower DC voltage signal suitable for powering main unit


52


.




The user may then connect hand controllers


56




a


,


56




b


to corresponding connectors


80


on main unit front panel


82


. Controllers


56


may take a variety of forms. In this example, the controllers


56


shown each include various push buttons


84


and a directional switch or other control


86


. The directional switch


88


can be used, for example, to specify the direction (up, down, left or right) that a character displayed on television screen


60


should move and/or to specify a point of view in a 3D world. Other possibilities include, for example, joysticks, mice pointer controls and other conventional user input devices. In this example, up to four controllers


56


can be connected to main unit


52


to allow 4-player games.




The user then selects a storage device


54


containing the video game he or she wants to play, and inserts that storage device into main unit slot


64


(thereby electrically connecting read only memory


76


to the main unit electronics via a printed circuit board


70


and associated edge contacts


74


). The user may then operate a power switch


88


to turn on the video game system


50


. This causes main unit


52


to begin playing the video game based on the software stored in read only memory


54


. He or she may operate controllers


86


to provide inputs to main unit


52


and thus affect the video game play. For example, depressing one of push buttons


84


may cause the game to start. As mentioned before, moving directional switches


86


can cause animated characters to move on the television screen


60


in different directions or can change the user's point of view in a 3D world. Depending upon the particular video game stored within the storage device


54


, these various controls


84


,


86


on the controller


56


can perform different functions at different times. If the user wants to restart game play, he or she can press a reset button


90


.




EXAMPLE 3D SCREEN EFFECTS




System


50


is capable of processing, interactively in real time, a digital representation or model of a three-dimensional world to display the world (or portions of it) from any arbitrary viewpoint within the world. For example, system


50


can interactively change the viewpoint in response to real time inputs from game controllers


86


. This can permit, for example, the game player to see the world through the eyes of a “virtual person” who moves through the world, and looks and goes wherever the game player commands him or her to go. This capability of displaying quality 3D images interactively in real time can create very realistic and exciting game play.





FIGS. 1A-1F

show just one example of some three-dimensional screen effects that system


50


can generate on the screen of color television set


58


.

FIGS. 1A-1F

are in black and white because patents cannot print in color, but system


50


can display these different screens in brilliant color on the color television set. Moreover, system


50


can create these images very rapidly (e.g., seconds or tenths of seconds) in real time response to operation of game controllers


86


.




Each of

FIGS. 1A-1F

was generated using a three-dimensional model of a “world” that represents a castle on a hilltop. This model is made up of geometric shapes (i.e., polygons) and “textures” (digitally stored pictures) that are “mapped” onto the surfaces defined by the geometric shapes. System


50


sizes, rotates and moves these geometric shapes appropriately, “projects” them, and puts them all together to provide a realistic image of the three-dimensional world from any arbitrary viewpoint. System


50


can do this interactively in real time response to a person's operation of game controllers


86


.





FIGS. 1A-1C

and


1


F show aerial views of the castle from four different viewpoints. Notice that each of the views is in perspective. System


50


can generate these views (and views in between) interactively in a matter of seconds with little or no discernible delay so it appears as if the video game player is actually flying over the castle.





FIG. 1D and 1E

show views from the ground looking up at or near the castle main gate. System


50


can generate these views interactively in real time response to game controller inputs commanding the viewpoint to “land” in front of the castle, and commanding the “virtual viewer” (i.e., the imaginary person moving through the 3-D world through whose eyes the scenes are displayed) to face in different directions.

FIG. 1D

shows an example of “texture mapping” in which a texture (picture) of a brick wall is mapped onto the castle walls to create a very realistic image.




Overall Video Game System Electronics





FIG. 2

shows that the principal electronics within main unit


52


includes a main processor


100


, a coprocessor


200


, and main memory


300


. Main processor


100


is a computer that runs the video game program provided by storage device


54


based on inputs provided by controllers


56


. Coprocessor


200


generates images and sound based on instructions and commands it gets from main processor


100


. Main memory


300


is a fast memory that stores the information main processor


100


and coprocessor


200


need to work, and is shared between the main processor and the coprocessor. In this example, all accesses to main memory


300


are through coprocessor


200


.




In this example, the main processor


100


accesses the video game program through coprocessor


200


over a communication path


102


between the main processor and the coprocessor


200


. Main processor


100


can read from storage device


54


via another communication path


104


between the coprocessor and the video game storage device. The main processor


100


can copy the video game program from the video game storage device


54


into main memory


300


over path


106


, and can then access the video game program in main memory


300


via coprocessor


200


and paths


102


,


106


.




Main processor


100


generates, from time to time, lists of commands that tell the coprocessor


200


what to do. Coprocessor


200


in this example comprises a special purpose high performance application—specific integrated circuit (ASIC) having an internal design that is optimized for rapidly processing 3-D graphics and digital audio. In response to commands provided by main processor


100


over path


102


, coprocessor


200


generates video and audio for application to color television set


58


. The coprocessor


200


uses graphics, audio and other data stored within main memory


300


and/or video game storage device


54


to generate images and sound.





FIG. 2

shows that coprocessor


200


in this example includes a signal processor


400


and a display processor


500


. Signal processor


400


is an embedded programmable microcontroller that performs graphics geometry processing and audio digital signal processing under control of a “microcode” computer program supplied by video game storage device


54


. Display processor


500


is a high speed state machine that renders graphics primitives, thereby creating images for display on television


58


. The signal processor


400


and display processor


500


work independently, but the signal processor can supervise the display processor by sending graphics commands to it. Both signal processor


400


and display processor


500


can be controlled directly by main processor


100


. The following are examples of functions and operations the signal processor


400


and display processor


500


can perform:




Signal Processor




Matrix control




3D transformations




Lighting




Clipping, perspective and viewport application




Display processor command generation




Display Processor




Rasterization




Texture coordinate generation




Texture application and filtering




Color combining




Blending




Fogging




Antialiasing




Frame buffer and frame buffer control





FIG. 3

shows the main processes performed by the main processor


100


, coprocessor


200


and main memory


300


in this example system


50


. The main processor


100


receives inputs from the game controllers


56


and executes the video game program provided by storage device


54


to provide game processing (block


120


). It provides animation, and assembles graphics and sound commands for use by coprocessor


200


. The graphics and sound commands generated by main processor


100


are processed by blocks


122


,


124


and


126


—each of which is performed by coprocessor


200


. In this example, the coprocessor signal processor


400


performs 3D geometry transformation and lighting processing (block


122


) to generate graphics display commands for display processor


500


. Display processor


500


“draws” graphics primitives (e.g., lines, triangles and rectangles) to create an image for display on color TV


58


. Display processor


500


performs this “drawing” or rendering function by “rasterizing” each primitive and applying a texture to it if desired (block


126


). It does this very rapidly—e.g., on the order of many millions of “pixels” (color television picture elements) a second. Display processor


500


writes its image output into a frame buffer in main memory


300


(block


128


). This frame buffer stores a digital representation of the image to be displayed on the television screen


60


. Additional circuitry within coprocessor


200


reads the information from the frame buffer and outputs it to television


58


for display (block


130


).




Signal processor


400


also processes sound commands received from main processor


100


using digital audio signal processing techniques (block


124


). Signal processor


400


writes its digital audio output into a sound buffer in main memory


300


. The main memory temporarily “buffers” (i.e., stores) the sound output (block


132


). Other circuitry in coprocessor


200


reads this buffered sound data from main memory


300


and converts it into electrical audio signals (stereo left and right channels) for application to and reproduction by television speakers


62




a


,


62




b


(block


134


).




Television


58


displays


30


or


60


new images a second. This “frame rate” fools the human eye into seeing continuous motion, allowing main unit


52


to create animation effects on television screen


60


by changing the image slightly from one frame to the next. To keep up with this television frame rate, coprocessor


200


must create a new image every {fraction (1/30)} or {fraction (1/60)} of a second. Coprocessor


200


must also be able to produce a stream of continuous sound to go along with the animation effects on screen


60


.




Overall System Operation





FIG. 4

shows the overall operation of system


50


in more detail, and

FIG. 4A

shows overall steps performed by the system to generate graphics. In this example, main processor


100


reads a video game program


108


stored in main memory


300


(generally, this video game program will have originated in video game storage device


54


and have been copied from the video game storage device into the main memory). In response to executing this video game program


108


(and in response to inputs from game controllers


56


), main processor


100


creates (or reads from storage device


58


) a list


110


of commands for coprocessor


200


(

FIG. 4A

, block


120




a


). This list


110


, in general, includes two kinds of commands:




(1) graphics commands




(2) audio commands. Graphics commands tell coprocessor


200


what images to generate on TV screen


60


. Audio commands tell coprocessor


200


what sounds it should generate for reproduction on TV loudspeakers


62


.




The list of graphics commands is called a “display list” because it controls the images coprocessor


200


displays on the TV screen


60


. The list of audio commands is called a “play list” because it controls the sounds that are played over loudspeaker


62


. Generally, main processor


100


specifies both a new display list and a new play list for each video “frame” time of color television set


58


.




In this example, main processor


100


provides its display/play list


110


to coprocessor


200


by storing it into main memory


300


and then telling the coprocessor where to find it (

FIG. 4A

, block


120




c


). Main processor


100


also makes sure the main memory


300


contains a graphics and audio database


112


that includes all of the data coprocessor


200


will need to generate the graphics and sound requested in the display/play list


110


. Some or all of this graphics and audio database


112


can come from storage device


54


. The display/play list


110


specifies which portions of graphics and audio database


112


the coprocessor


200


should use. Main processor


100


also is responsible for making sure that signal processor


400


has loaded “microcode”—i.e., a computer program that tells the signal processor what to do.




Signal processor


400


reads the display/play list


110


from main memory


100


(

FIG. 4A

, block


122




a


) and processes this list—accessing additional data within the graphics and audio database


112


as needed (

FIG. 4A

, block


122




b


). Signal processor


400


generates two main outputs: graphics display commands


112


for further processing by display processor


500


(

FIG. 4A

, block


122




c


); and audio output data


114


for temporary storage within main memory


300


. Signal processor


400


processes the audio data in much less than the time it takes to play the audio through loudspeakers


62


. Another part of the coprocessor


200


called an “audio interface” (not shown) subsequently reads the buffered audio data and outputs it in real time for reproduction by television loudspeakers


62


.




The signal processor


400


can provide the graphics display commands


112


directly to display processor


500


over a path internal to coprocessor


200


, or it may write those graphics display commands into main memory


300


for retrieval by the display processor (not shown). These graphics display commands


112


command display processor


500


to draw (“render”) specified geometric shapes with specified characteristics (

FIG. 4



a


, block


126




a


). For example, display processor


500


can draw lines, triangles or rectangles (polygons) based on these graphics display commands


112


, and may fill triangles and rectangles with particular colors and/or textures


116


(e.g., images of leaves of a tree or bricks of a brick wall—all as specified by the graphics display commands


112


. Main processor


100


stores the texture images


116


into main memory


300


for access by display processor


500


. It is also possible for main processor


100


to write graphics display commands


112


directly into main memory


300


for retrieval by display processor


500


to directly command the display processor.




Display processor


500


generates, as its output, a digitized representation of the image that is to appear on television screen


60


(

FIG. 4A

, block


126




b


). This digitized image, sometimes called a “bit map,” is stored within a frame buffer


118


residing in main memory


300


. Display processor


500


can also store and use a depth (Z) buffer


118




b


in main memory


300


to store depth information for the image. Another part of coprocessor


200


called the “video interface” (not shown) reads the frame buffer


118


and converts its contents into video signals for application to color television set


58


(

FIG. 4



a


, block


127


). Typically, frame buffer


118


is “double buffered,” meaning that coprocessor


200


can be writing the “next” image into half of the frame buffer while the video interface is reading out the other half.




The various steps shown in FIG.


4


A and described above are “pipelined” in this example. “Pipelining” means that different operations are performed concurrently for different stages in the graphics generation process. A simple analogy is the way most people do laundry. A non-pipelined mode of doing laundry would involve completing all relevant tasks (washing, drying, ironing/folding, and putting away) for one load of laundry before beginning the next load. To save time, people with multiple loads of laundry “pipeline” the laundry process by performing washing, drying, ironing/folding and putting away operations concurrently for different loads of laundry.




Similarly, the operations performed by main processor


100


, signal processor


400


, display processor


500


and video interface


210


are “pipelined” in this example. For example, main processor


100


in this example can be assembling a display list two video frames ahead while signal processor


400


and display processor


500


are processing data for one video frame ahead and video interface


210


is processing data for the current video frame in progress. As is explained below, the detailed graphics rendering steps performed by display processor


500


in block


126




a


are also pipelined to maximize speed performance.




More Detailed System Architecture





FIG. 5

shows a more detailed architecture of video game system


50


. This diagram shows video game main unit


52


including, in addition to main processor


100


, coprocessor


200


and main memory


300


, additional components such as a clock generator


136


, a serial peripheral interface


138


, an audio digital-to-analog converter (DAC)


140


, an audio amplifier/mixer


142


, a video digital-to-analog converter


144


, and a video encoder


146


.




In this example, the clock generator


136


(which may be controlled by a crystal


148


) produces timing signals to time and synchronize the other components of main unit


52


. Different main unit components require different clocking frequencies, and clock generator


136


provides suitable such clock frequency outputs (or frequencies from which suitable clock frequencies can be derived such as by dividing). A timing block


216


within coprocessor


200


receives clocking signals from clock generator


136


and distributes them (after appropriate dividing as necessary) to the various other circuits within the coprocessor.




In this example, the game controllers


58


are not connected directly to main processor


100


, but instead are connected to main unit


52


through serial peripheral interface


138


. Serial peripheral interface


138


demultiplexes serial data signals incoming from up to four (or five) game controllers


56


(or other serial peripheral devices) and provides this data in a predetermined format to main processor


100


via coprocessor


200


. Serial peripheral interface


138


is bidirectional in this example, i.e., it is capable of transmitting serial information specified by main processor


100


in addition to receiving serial information.




Serial peripheral interface


138


in this example also includes a “boot ROM” read only memory


150


that stores a small amount of initial program load (IPL) code. This IPL code stored within boot ROM


150


is executed by main processor


100


at time of startup and/or reset to allow the main processor to begin executing game program instructions


108




a


within storage device


54


(see

FIG. 5A

, blocks


160




a


,


160




b


). The initial game program instructions


108




a


may, in turn, control main processor


100


to initialize the drivers and controllers it needs to access main memory


300


(see

FIG. 5A

, blocks


160




c


,


160




d


) and to copy the video game program and data into the faster main memory


300


for execution and use by main processor


100


and coprocessor


200


(see

FIG. 5A

, blocks


160




e


,


160




f


,


160




g


).




Also in this example, serial peripheral interface


138


includes a security processor (e.g., a small microprocessor) that communicates with an associated security processor


152


(e.g., another small microprocessor) within storage device


54


(see FIG.


5


). This pair of security processors (one in the storage device


54


, the other in the main unit


52


) perform an authentication function to ensure that only authorized storage devices may be used with video game main unit


52


. See U.S. Pat. No. 4,799,635. In this example, the security processor within serial peripheral interface


138


may process data received from game controllers


56


under software control in addition to performing a security function under software control.





FIG. 5

shows a connector


154


within video game main unit


52


. This connector


154


connects to the electrical contacts


74


at the edge of storage device printed circuit board


70


in this example (see FIG.


1


). Thus, connector


154


electrically connects coprocessor


200


to storage device ROM


76


. Additionally, connector


154


connects the storage device security processor


152


to the main unit's serial peripheral interface


138


. Although connector


154


in the particular example is used primarily to read data and instructions from a non-writable read only memory


76


, system


52


is designed so that the connector is bidirectional, i.e., the main unit can send information to the storage device


54


in addition to reading information from it.





FIG. 5

also shows that the audio and video outputs of coprocessor


200


are processed by some electronics outside of the coprocessor before being sent to television set


58


. In particular, in this example coprocessor


200


outputs its audio and video information in digital form, but conventional home color television sets


58


generally require analog audio and video signals. Therefore, the digital outputs of coprocessor


200


are converted into analog form—a function performed for the audio information by DAC


140


and for the video information by VDAC


144


. The analog audio output of DAC


140


is amplified by an audio amplifier


142


that may also mix audio signals generated externally of main unit


52


and supplied through connector


154


. The analog video output of VDAC


144


is provided to video encoder


146


, which may, for example, convert “RGB” input signals to composite video outputs. The amplified stereo audio output of amplifier


142


and the composite video output of video encoder


146


are provided to home color television set


58


through a connector not shown.




As shown in

FIG. 5

, main memory


300


stores the video game program in the form of CPU instructions


108




b


. These CPU instructions


108




b


are typically copied from storage device


54


. Although CPU


100


in this example is capable of executing instructions directly out of storage device ROM


76


, the amount of time required to access each instruction from the ROM is much greater than the time required to access instructions from main memory


300


. Therefore, main processor


100


typically copies the game program/data


108




a


from ROM


76


into main memory


300


on an as-needed basis in blocks, and accesses the main memory in order to actually execute the instructions (see

FIG. 5A

, blocks


160




e


,


160




f


). The main processor


100


preferably includes an internal cache memory to further decrease instruction access time.





FIG. 5

shows that storage device


54


also stores a database of graphics and sound data


112




a


needed to provide the graphics and sound of the particular video game. Main processor


100


reads the graphics and sound data


112




a


from storage device


54


on an as-needed basis and stores it into main memory


300


in the form of texture data


116


, sound data


112




b


and graphics data


112




c


. In this example, display processor


500


includes an internal texture memory


502


into which the texture data


116


is copied on an as-needed basis for use by the display processor.




Storage device


54


also stores coprocessor microcode


156


. As described above, in this example signal processor


400


executes a computer program to perform its various graphics and audio functions. This computer program or “microcode,” is provided by storage device


54


. Because the microcode


156


is provided by storage device


54


, different storage devices can provide different microcodes—thereby tailoring the particular functions provided by coprocessor


200


under software control. Typically, main processor


100


copies a part of the microcode


156


into main memory


300


whenever it starts the signal processor, and the signal processor


400


then accesses other parts of the microcode on an as-needed basis. The signal processor


400


executes the microcode out of an instruction memory


402


within the signal processor


400


. Because the SP microcode


156


may be too large to fit into the signal processor's internal instruction memory


402


all at once, different microcode portions may need to be loaded from main memory


300


into the instruction memory


402


to allow signal processor


400


to perform different tasks. For example, one part of the SP microcode


156


may be loaded into signal processor


400


for graphics processing, and another part of microcode may be loaded into the signal processor for audio processing. In this example, the signal processor microcode RAM


402


(and an additional signal processor data memory RAM not shown in

FIG. 5

) is mapped into the address space of main processor


100


so the main processor can directly access the RAM contents under software control through load and store instructions.




Main Processor


100






Main processor


100


in this example is a MIPS R4300 RISC microprocessor designed by MIPS Technologies, Inc., Mountain View, Calif. This R4300 processor includes an execution unit with a 64-bit register file for integer and floating-point operations, a 16 KB Instruction Cache, a 8 KB Write Back Data Cache, and a 32-entry TLB for virtual-to-physical address calculation. The main processor


100


executes CPU instructions (e.g., a video game program)


108


in kernel mode with 32-bit addresses. 64-bit integer operations are available in this mode, but 32-bit calling conventions are preferable to maximize performance. For more information on main processor


100


, see, for example, Heinrich,


MIPS Microprocessor R


4000


User's Manual


(MIPS Technologies, Inc., 1994, Second Ed.).




Main processor


100


communicates with coprocessor


200


over bus


102


, which in this example comprises a bi-directional 32-bit SysAD multiplexed address/data bus, a bi-directional 5-bit wide SysCMD bus, and additional control and timing lines. See chapter 12 et seq. of the above-mentioned Heinrich manual.




The conventional R4300 main processor supports six hardware interrupts, one internal (timer) interrupt, two software interrupts, and one non-maskable interrupt (NMI). In this example, three of the six hardware interrupt inputs (INT


0


, INT


1


and INT


2


) and the non-maskable interrupt (NMI) input allow other portions of system


50


to interrupt the main processor. Specifically, main processor INT


0


is connected to allow coprocessor


200


to interrupt the main processor, main processor interrupt INT


1


is connected to allow storage device


54


to interrupt the main processor, and main processor interrupts INT


2


and NMI are connected to allow the serial peripheral interface


138


to interrupt the main processor. Any time the processor is interrupted, it looks at an internal interrupt register to determine the cause of the interrupt and then may respond in an appropriate manner (e.g., to read a status register or perform other appropriate action). All but the NMI interrupt input from serial peripheral interface


138


are maskable (i.e., the main processor


100


can selectively enable and disable them under software control).




Main processor


100


reads data from and writes data to the rest of system


50


via the CPU-to-coprocessor bus


102


. The coprocessor


200


performs a memory mapping function, allowing the main processor


100


to address main memory


300


, the storage device cartridge ROM


76


, the “boot ROM”


150


within serial peripheral interface


138


(and other parts of the serial peripheral interface), various parts of coprocessor


200


(including signal processor RAM


402


), and other parts of system


50


.




In the example, the operations performed by main processor


100


are completely dependent on videogame program


108


. In this example, all “system” software is supplied by the storage device


58


to provide maximum flexibility. Different video games (or other applications) may run more efficiently with different kinds of high level software. Therefore, main unit


52


in this example does not provide any standard software libraries—or any software at all for that matter—since such libraries could limit flexibility. Instead, all software in this example is supplied by storage device


54


.




Developers of video game software


108


may wish to employ advanced software architecture such as, for example, device drivers, schedulers and thread libraries to manage the various resources within system


50


. Since main processor


100


is a state-of-the-art RISC processor/computer, it is appropriate to use such software architecture/constructs and to implement video game program


108


in a high level software environment.




An example system “memory map” of the main processor


100


address space is shown in FIG.


5


B. As shown in this

FIG. 5B

, main memory


300


is divided into two banks (bank 0 and bank 1) in this example. In addition, certain configuration registers


307


within the main memory


300


are mapped into the main processor address space, as are registers within coprocessor


200


. Main processor


100


in this example can control each of the various coprocessor subblocks by writing, under control of video game program


108


, into control registers associated with each coprocessor


200


sub-block.




As shown in

FIG. 5B

, storage device


54


address space is divided into two “domains” (for two different devices, for example). These “domains” are mapped into several parts of the main processor


100


address space. Various parts of the serial peripheral interface


138


(i.e., PIF boot ROM


150


, a PIF buffer RAM, and a PIF status register) are also mapped into the main processor


100


address space.




Unified Main Memory


300






Main memory


300


in this example comprises a RDRAM dynamic random access memory available from Rambus Inc. of Mountain View, Calif. In this example, main memory


300


is expandable to provide up to 8 megabytes of storage, although main unit


52


may be shipped with less RAM (e.g., 2 or 3 MB) to decrease cost.




Main memory


300


provides storage for the entire system


50


in this example. It provides a single address space (see

FIG. 5B

above) for storing all significant data structures, including for example (as shown in FIG.


5


):




Main processor instructions


108






Signal processor microcode


156






Display list graphic commands


110




a






Play list audio commands


110




b






Texture maps


116


and other graphics data


112




c






Color image frame buffer


118




a






Depth (z) buffer


118




b






sound data


112




b






Audio output buffer


114






Main processor working values




Coprocessor working values




Data communicated between various parts of the system.




Advantages and disadvantages in using single address space memory architectures for raster scan display systems are known (see, for example, Foley et al,


Computer Graphics: Principles and Practice


at 177-178 (2d Ed. Addison-Wesley 1990). Many video game (and other graphics) system architects in the past rejected a single address space architecture in favor of using dedicated video RAM devices for graphics data and using other types of memory devices for other types of data. However, a unified main memory


300


provides a number of advantages in this particular example of a video game system


50


. For example:




Data communications between system elements is simplified. Once data is stored in main memory


300


, there is little or no additional overhead in communicating the data to another part of the system. The overhead of transferring data between different parts of the system is thus minimized. For example, since the main processor


100


and each sub-block within the coprocessor


200


can each access system main memory


300


, the main memory used by all system elements for data structure storage can also be used as a general purpose communication channel/data buffer between elements.




For example, display lists


110


main processor


100


stores within main memory


300


can be directly accessed by signal processor


400


. Similarly, display commands the main processor (and/or the signal processor) stores within the main memory can be directly accessed by display processor


500


. The main processor


100


working data (which can automatically be written into the main memory


300


via a “cache flush”) is immediately available to all other parts of the system.




The unified memory provides memory allocation flexibility. Main memory


300


locations look alike, and therefore each location can be used for storing any type of data structure. All main memory


300


allocation decisions are left to the application programmer. This provides great flexibility in terms of data structure sizes and memory usage. Data structures can be stored anywhere in main memory


300


, and each location in memory


300


can be allocated however the application programmer specifies.




For example, one video game programmer might provide a large frame buffer for high resolution images and/or image scrolling and panning, while another programmer may decide to use a smaller frame buffer so as to free up memory space for other data structures (e.g., textures or audio data). One application may devote more of main memory


300


storage for audio data structures and less to graphics data, while another application may allocate most of the storage for graphics related data. The same video game program


108


can dynamically shift memory allocation from one part of game play to another (e.g., at the time the game changes levels) to accomplish different effects. Application flexibility is not limited by any fixed or hardwired memory allocation.




The Unified RAM architecture supports flexible data structure sharing and usage. Since all significant data structures are stored within common main memory


300


, they can all be accessed by main processor


100


and other system elements. There is no hardware distinction between display images and source images. For example, main processor


100


can, if desired, directly access individual pixels within frame buffer


118


. The scan conversion output of display processor


500


can be used as a texture for a texture mapping process. Image source data and scan converted image data can be interchanged and/or combined to accomplish special effects such as, for example, warping scan-converted images into the viewpoint.




The shortcomings of a unified memory architecture (e.g., contention for access to the main memory


300


by different parts of the system) have been minimized through careful system design. Even though main memory


300


is accessed over a single narrow (9-bit-wide) bus


106


in this example, acceptable bandwidth has been provided by making the bus very fast (e.g., on the order of 240 MHz). Data caches are provided throughout the system


50


to make each sub-component more tolerant to waiting for main memory


300


to become available.




Coprocessor


200







FIG. 5

shows that coprocessor


200


includes several components in addition to signal processor


400


and display processor


500


, namely:




CPU interface


202


,




a serial interface


204


,




a parallel peripheral interface


206


,




an audio interface


208


,




a video interface


210


,




a main memory DRAM controller/interface


212


,




a main internal bus


214


and




a timing block


216


.




In this example, main bus


214


allows each of the various main components within coprocessor


200


to communicate with one another.





FIG. 6

, a more detailed diagram of coprocessor


200


, shows that the coprocessor is a collection of processors, memory interfaces and control logic all active at the same time and operating in parallel. The following briefly describes the overall functions provided by each of these other sub-blocks of coprocessor


200


:




Signal processor


400


is a microcoded engine that executes audio and graphics tasks.




Display processor


500


is a graphics display pipeline that renders into frame buffer


118


.




Coprocessor serial interface


204


provides an interface between the serial peripheral interface


128


and coprocessor


200


in this example.




Coprocessor parallel peripheral interface


206


interfaces with the storage device


54


or other parallel devices connected to connector


154


.




Audio interface


208


reads information from audio buffer


114


within main memory


300


and outputs it to audio DAC


140


.




Coprocessor video interface


210


reads information from frame buffer


118




a


within main memory


300


and outputs it to video DAC


144


.




The CPU interface


202


is the gateway between main processor


100


, coprocessor


200


and the rest of system


50


.




DRAM controller/interface


212


is the gateway through which coprocessor


200


(and main processor


100


) accesses main memory


300


. Memory interface


212


provides access to main memory


300


for main processor


100


, signal processor


400


, display processor


500


, video interface


210


, audio interface


208


, and serial and parallel interfaces


204


,


206


.




Each of these various processors and interfaces may be active at the same time.




Signal processor


400


in this example includes the instruction memory


402


discussed above, a data memory


404


, a scalar processing unit


410


and a vector processing unit


420


. Instruction memory


402


stores microcode for execution by scalar unit


410


and/or vector unit


420


. Data memory


404


stores input data, work data and output data for the scalar unit


410


and for the vector unit


420


. Signal processor


400


can execute instructions only out of instruction memory


402


in this example, but has access to main memory


300


via direct memory accessing (DMA) techniques.




In this example, scalar unit


410


is a general purpose integer processor that executes a subset of the MIPS R4000 instruction set. It is used to perform general purpose operations specified by microcode within instruction memory


402


. Vector unit


420


comprises eight 16-bit calculating elements capable of performing numerical calculations in parallel. Vector unit


420


is especially suited for graphics matrix calculations and certain kinds of digital audio signal processing operations.




Display processor


500


in this example is a graphics display pipelined engine that renders a digital representation of a display image. It operates based on graphics display commands generated by the signal processor


400


and/or main processor


100


. Display processor


500


includes, in addition to texture memory


502


, a rasterizer


504


, a texture unit


506


, a color combiner


508


, a blender


510


and a memory interface


512


. Briefly, rasterizer


504


rasterizes polygon (e.g., triangle, and rectangle) geometric primitives to determine which pixels on the display screen


60


are within these primitives. The texture unit can apply texture maps stored within texture memory


502


onto textured areas defined by primitive edge equations solved by rasterizer


504


. The color combiner


508


combines and interpolates between the texture color and a color associated with the graphic primitive. Blender


510


blends the resulting pixels with pixels in frame buffer


118


(the pixels in the frame buffer are accessed via memory interface


512


) and is also involved in performing Z buffering (i.e., for hidden surface removal and anti-aliasing operations). Memory interface


512


performs read, modify and write operations for the individual pixels, and also has special modes for loading/copying texture memory


502


, filling rectangles (fast clears), and copying multiple pixels from the texture memory


502


into the frame buffer


118


. Memory interface


512


has one or more pixel caches to reduce the number of accesses to main memory


300


.




Display processor


500


includes circuitry


514


that stores the state of the display processor. This state information is used by the rest of display processor


500


to, for example, select rendering modes and to ensure that all previous rendering effected by a mode change occurs before the mode change is implemented.




The command list for display processor


500


usually comes directly from signal processor


400


over a private “X bus”


218


that connects the signal processor to the display processor. More specifically, X-bus


218


in this example is used to transfer graphics display commands from the signal processor data memory


404


into a command buffer (not shown in

FIG. 6

) within display processor


500


for processing by the display processor. However, in this example it is also possible for signal processor


400


and/or main processor


100


to feed graphics display commands to display processor


500


via main memory


300


.




Display processor


500


accesses main memory


300


using physical addresses to road its internal texture memory


502


, read frame buffer


118


for blending, read the Z buffer


118


B for depth comparison, to write to the Z-buffer and the frame buffer, and to read any graphics display commands stored in the main memory.




Coprocessor Internal Bus Architecture





FIG. 6A

is a more detailed diagram showing an example coprocessor bus


214


arrangement, which in this example comprises a 32-bit address (“C”) bus


214


C and a 64-bit data (“D”) bus


214


D. These busses


214


C,


214


D are connected to each of signal processor


400


, display processor


500


, CPU interface


202


, audio interface


208


, video interface


210


, serial interface


204


, parallel peripheral interface


206


, and main memory (RAM) interface


212


. As shown in

FIG. 6A

, main processor


100


and each of the sub-blocks of coprocessor


200


communicates with main memory


300


via internal coprocessor busses


214


C,


214


D, and main memory interface/controller


212




a


/


212




b.






In this example, main memory interface/controller


212




a


,


212




b


converts main memory addresses asserted on coprocessor address bus


214


C into 9-bit-wide format for communication over the 9-bit-wide main memory multiplexed address/data bus


106


, and also converts between the main memory bus


106


9-bit-wide data format and the coprocessor data bus


214


D 64-bit wide data format. In this example, the DRAM controller/interface


212


includes, as a part thereof, a conventional RAM controller


212




b


(see

FIG. 5C

) provided by Rambus Inc. The use of a 9-bit-wide main memory bus


106


reduces the chip pin count of coprocessor


200


.




In this example, each of the coprocessor


200


sub-blocks shown has an associated direct memory access (DMA) circuit that allows it to independently address and access main memory


300


. For example, signal processor DMA circuit


454


, display processor DMA circuit


518


, audio interface DMA circuit


1200


, video interface DMA circuit


900


, serial interface DMA circuit


1300


, and parallel peripheral interface DMA circuit


1400


each allow their associated coprocessor sub-block to generate addresses on coprocessor address bus


214


C and to communicate data via coprocessor data bus


214


D (additionally, display processor


500


has a further memory interface block


512


for access to the main memory frame buffer


118


and texture data


116


).




Although each of the coprocessor


200


sub-blocks can independently access main memory


300


, they all share common busses


214


C,


214


D in this example—and only one of the subblocks can use these shared busses at a time. Accordingly, coprocessor


200


has been designed to make most efficient use of the shared busses


214


. For example, the coprocessor


200


sub-blocks may buffer or “cache” information to minimize the frequency of different bus accesses by the same sub-block and to make the subblocks more tolerant of temporary bus unavailability. A private bus


218


allows signal processor


400


to communicate with display processor


500


without having to wait for main bus


214


to become available.




Also as shown in

FIG. 6A

, each of the sub-blocks of coprocessor


200


includes control/status registers that can be accessed by main processor


100


via CPU interface


202


. For example, signal processor registers


407


, display processor registers


507


, audio interface registers


1207


, video interface registers


907


, serial interface registers


1307


, parallel peripheral interface registers


206


, RAM interface registers


1007




a


, and RAM controller registers


1007




b


are each mapped into the main processor


100


address space. The main processor


100


can read from and/or write to these various registers under control of game program


108


to directly control the operation of sub-blocks within coprocessor


200


.




Signal Processor


400







FIG. 7

shows the architecture of signal processor


400


of this example in more detail. As explained above, signal processor


400


includes a scalar unit


410


, a vector unit


420


, an instruction memory


402


and a data memory


404


. In this example, scalar unit


410


is a 32-bit integer processor that executes a sub-set of the MIPS 4000 instruction set. Vector unit


420


(which is defined as a “CP


1


” coprocessor of scalar unit


410


under the MIPS 4000 architecture) performs integer calculations (e.g., multiplications, additions, subtractions and multiply/accumulates) on eight 16-bit sets of values in parallel.




Vector unit


420


can perform the same operation on eight pairs of 16-bit operands in parallel simultaneously. This makes signal processor


400


especially suited for “sum of products” calculations such as those found in matrix multiplications, texture resampling, and audio digital signal processing such as, for example, digital audio synthesis and spatial and frequency filtering.




Signal processor


400


uses a RISC (reduced instruction set computer) architecture to provide high performance machine control based on instructions residing in the instruction memory


402


. In this example, execution unit includes a program counter


432


that is used to address instruction memory


402


over path


434


. This program counter


432


can access only the 4 kilobyte instruction space within instruction memory


402


in this example—requiring that all instructions to be executed by the signal processor first be placed into the instruction memory. Execution unit


430


generates output control signals


436


based on the particular instructions currently being executed. These output control signals


436


control all other parts of signal processor


400


, and are sequenced to manage pipelined instruction processing. Scalar unit


410


and vector unit


420


are controlled by these control signals


436


. For example, scalar unit


410


may address data memory


404


via path


438


to read data from and/or write data into the data memory using load/store block


440


. Data path


414


may perform tests based on results of calculations and provide resulting condition outputs to execution unit


430


via path


442


. This execution unit


430


may use these condition outputs to perform a conditional branch or jump, loading program counter


432


with the appropriate (next) address into instruction memory


402


. Because scalar processor


410


has these more general capabilities, it is used in this example for general purpose functions such as, for example, control flow, address calculation and the like—in addition to providing 32-bit integer calculations.




Execution unit


430


executes intermediate, jump and register instruction formats in accordance with the standard MIPS R4000 instruction set.

FIG. 7A

shows an example of a register instruction format


450


and how signal processor


400


uses that register instruction format to access three 128-bit wide words


452


within data memory


404


. Register instruction format


450


may include a 6-bit operation code field


450


(


a


), a 5-bit source register specifier


450


(


b


), a 5-bit target (source/destination) register specifier


450


(


c


), a 5-bit destination register specifier


450


(


d


), and a parameter field


450


(


e


). The parameter field


450


(


e


) may specify shift amounts and/or functions, and together with operation code


450


(


a


) defines the operation to be performed. Each of fields


450


(


b


),


450


(


c


) and


450


(


d


) specifies a location within data memory


404


—and thus each designates 128-bit word.




As shown in

FIG. 7B

, vector unit


420


treats each of these 128-bit words as a concatenated sequence of eight 16-bit values, and operates on each of the 16-bit values in parallel. The operations of vector unit


420


are invoked by instructions within the CP


1


type instructions typically reserved for floating point operations in the MIPS R4000 instruction set (signal processor


400


has no floating point unit in this example).




Scalar unit


410


includes a register file


412


comprising 32 registers, each register being 32 bits wide. Scalar unit also includes a data path


414


comprising adders, shifters, and other logic required to execute integer calculations and other operations. Register file


412


is similar to the general purpose register file defined by the MIPS R4000 architecture, and accepts instructions in R4000 format. Data path


414


includes an integer multiplier/divider, and operates in conjunction with an execution unit


430


that receives 64-bit wide instructions from instruction memory


402


.




Vector unit


420


includes eight sets of register files


422


(


0


)-


422


(


7


) and eight sets of corresponding data paths


423


(


0


)-


423


(


7


). Data paths


423


each include a 16-bit multiplier, a 16-bit adder and a 48-bit accumulator (48 bit accumulation accommodates audio filters with a large number of taps, and also accommodates partial products wherein a series of 16-bit multiplies and sums is used to obtain a 32-bit result for certain graphics calculations requiring more than 16-bit precision). Each of register files


422


comprises 32 registers each of which are 32-bits wide. A 128 bit wide data path


444


connects vector unit


420


to load/store block


440


, and another 128 bit wide data path


446


connects the load/store block


440


to data memory


404


. Data memory


404


stores


4096


(4 KB) words, each word being 128 bits wide. When a word in data memory


404


is retrieved for use by vector unit


420


, it is sliced into eight 16-bit segments, with each segment being sent to a different register file


422


within vector unit


420


(see FIG.


7


B).

FIG. 7C

shows an example add operation performed by vector unit


420


. When vector unit


420


writes to a destination addressed within data memory


404


, each of register files


422


contributes 16-bits which are combined into a 128 bit word before being written into the data memory (see FIG.


7


A). Alternatively, load/store block


440


includes a steering multiplexer arrangement (not shown) that can steer 16-bit sub-words within the data memory 128-bit word to/from different vector unit register files


422


—with the particular sub-word and the particular vector unit register file being selectable based on instructions from instruction memory


402


. Similarly, load/store block


440


includes a further steering multiplexer arrangement (not shown) that can steer different sized data units (e.g., bytes, 16-bit half-words, or 32-bit words) between data memory


408


and scalar unit


410


—with the particular data unit and size being specified by instructions within instruction memory


402


. See, for example, description of Load and Store “Byte”, “Halfword”, “Word”, “Word Left” and “Word Right” in Heinrich,


MIPS R


4000


Microprocessor User's Manual


(2d Ed. 1994).




Signal processor


400


also includes a DMA controller


454


and CPU control registers


456


. DMA controller


454


is connected to the coprocessor internal bus


214


, and is used to transfer data into and out of instruction memory


402


and/or data memory


404


. For example, DMA controller


454


can copy microcode modules


156


from main memory


300


into signal processor instruction memory


402


. DMA controller


454


may also be used to transfer information between data memory


404


and main memory


300


. DMA controller


454


can be commanded by execution unit


430


, and receives DMA address and data information from scalar unit data path


414


over path


438


. DMA controller


454


may also be commanded by main processor


100


via CPU control registers


456


. CPU control registers


456


are mapped into the main processor


100


address space, and can be accessed by signal processor


400


and execution unit


430


using MIPS “CP


0


” instruction formats.





FIGS. 7D-7L

show example CPU control registers


756


. The registers shown in

FIGS. 7D-7H

are used to control and/or monitor the DMA controller


454


.




For example, the SP-DRAM DMA address register


458


shown in

FIG. 7D

can be written to or read from by main processor


100


(as well as SP execution unit


430


), and is used to specify a starting DMA address within instruction memory


402


or data memory


404


. SP memory DMA address


460


shown in

FIG. 7E

is used to specify a starting DMA address in main memory


300


. Read and write DMA length registers


462


,


464


shown in

FIGS. 7F and 7G

, respectively, specify the length of a block of data to be transferred between signal processor


400


and main memory


300


—with the direction of transfer depending upon which one of these two registers is used to specify the block length. DMA status registers


466


,


468


shown in

FIGS. 7H and 7I

respectively, can be read by main processor


100


to determine whether DMA controller


454


is full or busy, respectively.





FIG. 7J

shows the main SP status register


470


within CPU control registers


456


. SP status register


470


acts as an SP control register when it is written to by main processor


100


(top diagram of FIG.


7


J), and indicates SP status when read by the main processor (bottom diagram in FIG.


7


J). When used as a status register, SP status register


470


tells main processor


100


whether the SP is halted (field


471


), whether the SP is operating in a breakpoint mode (field


472


), whether the DMA controller


454


is busy (field


474


) or full (field


475


), whether SP I/O is full (field


476


), whether the SP is operating in single step mode (field


477


), whether the SP is operating in a mode in which it won't generate an interrupt upon reaching a breakpoint (block


478


), and whether the SP has generated various general purpose “signals”


479


that can be defined under software control to provide status concerning various software-dependent parameters. Main processor


100


can write to register


470


to stop or start signal processor


400


(fields


480


,


481


), to clear breakpoint mode (field


482


), to clear or set an interrupt mode (fields


483


,


484


), to clear or set single step mode (fields


485


,


486


), to clear or set an interrupt on breakpoint mode (fields


487


,


488


), and to clear or set the various software-dependent “signals” (fields


489


,


490


).





FIG. 7K

shows an additional SP register


491


used as a “semaphore” for general purpose communications between the main processor


100


and the signal processor


400


. This register


491


contains a flag that main processor


100


sets upon reading the register and clears upon writing to the register. Signal processor


400


can also set or clear this flag.





FIG. 7L

shows an SP instruction memory BIST status register


492


that is used as a BIST control register when written to by main processor


100


(top diagram in

FIG. 7L

) and indicates BIST status when read by the main processor (bottom diagram of FIG.


7


L). Program counter


432


is preferably also mapped into the CPU control registers


456


so that it can be written to and read from by main processor


100


.




Signal Processor Microcode




The particular functions signal processor


400


performs depend on the SP microcode


156


provided by storage device


54


. In this example, SP microcode


156


provides both graphics and audio processing functions. As explained above, the main tasks performed by signal processor


400


for graphics processing include reading a display list, performing 3-dimensional geometry transformation and lighting calculations, and generating corresponding graphics display commands for use by display processor


500


. In more detail, signal processor


400


performs the following overall graphics functions under control of microcode


156


:




Display list processing




Matrix definition




Vertex generation and lighting




Texture definition/loading




Clipping and culling




Display processor command setup




Flow control




Signal processor


400


performs the following overall functions under control of microcode


156


to process audio:




Play list processing




Digital audio synthesis/processing




Writing digital audio samples to main memory audio buffer


114






Task Lists




Main processor


100


tells signal processor


400


what to do by providing the signal processor with a task list. The microcode


156


program that runs on signal processor


400


is called a task. Main processor


100


(and thus the video game program


108


supplied by storage device


54


) is responsible for scheduling and invoking tasks on signal processor


400


. The task list contains all of the information signal processor


400


needs to begin task execution, including pointers to the microcode


156


routines it needs to run in order to perform tasks. Main processor


100


provides this task list under control by game program


108


.





FIG. 8

shows an example of a task list


250


. The task list


250


may reference one or more display lists and/or play lists


110


. These display lists or play lists


110


, in turn, may reference additional data structures including other display lists or play lists. A display list


110


can point to other display lists and/or graphics data. Similarly, a play list can reference other play list and/or sound data. In this example, display lists and play lists can be thought of as hierarchical data structures up to ten levels deep. Signal processor


400


processes the display lists and play lists of the stack, pushing and popping the current display list pointer. All display lists must terminate with an “end” command. For example, display list


110


(


1


) shown in

FIG. 8

references another display list


110


(


2


). Display list


110


(


2


) references graphics data


112


needed to execute the list. Similarly, play list


110


(


4


) shown in

FIG. 8

references sound data


112


B.




For graphics animation, it is desirable to “double buffer” only parts of the display list


110


that change from one frame to another. In this way, only the data that changes from one frame to the next needs to be “double buffered”—thus conserving space in main memory


300


. Swapping between double buffers is efficiently done by changing segment base addresses within task lists


250


and by organizing the hierarchical display lists in an appropriately efficient manner. Display lists or fragments of display lists can be chained together for more efficient memory utilization.





FIG. 9

shows an example process performed by main processor


100


to invoke processing of a new task list by signal processor


400


. Main processor


100


first loads the task (display) list into main memory


300


(block


601


). It then halts signal processor


400


(or checks to insure that the signal processor is halted) by writing to and/or reading from SP status register


470


(block


602


). Main processor


100


then writes to SP DMA registers


458


,


460


,


462


to load an initial microcode module into signal processor instruction memory


402


(


604


, FIG.


9


). Main processor


100


next stores the address in main memory


300


of the task (display) list loaded by block


601


into signal processor data memory


404


(block


606


, FIG.


9


). Main processor


100


then resets the signal processor program counter


432


(block


608


, FIG.


9


), and writes to SP status register


470


to start the signal processor


400


(block


610


, FIG.


9


). The signal processor


400


typically then uses its DMA controller


454


to fetch the task (display) list from main memory


300


into its data memory


404


.




Now that signal processor


400


has a task list and is started, it proceeds to perform each of the operations requested in the task list. It continues to execute the task list until it reaches the end of the task list, at which time it stops and waits for main processor


100


to provide a new task list. Generally, main processor


100


provides a new task list once each video frame—although, as discussed above, in many cases only a portion of the task list and/or the display and/or play lists the task list references may actually change from one frame to the next. Portions of the task list in main memory


300


may be “double buffered” so the main processor


100


can be writing to one buffer while signal processor


400


reads from another buffer. Before the next video frame, the main processor


100


can change a pointer to give the signal processor


400


access to the new buffer.




As signal processor


400


executes the task list, it retrieves additional SP microcode


156


modules from main memory


300


as needed to perform the specified tasks. For example, signal processor


400


may use its DMA facility


454


to load particular graphics microcode into instruction memory


402


to execute graphics commands specified by a task list, and may similarly retrieve and load audio processing microcode routines to perform audio processing specified by the task list. Different microcode routines or “overlays” may be loaded on an as-needed basis to more optimally handle particular types of graphics and/or audio processing operations. As one example, the signal processor


400


may load special lighting graphics routines as overlays to perform particular lighting operations, and may load clipping routines or overlays to perform particular culling operations. Microcode loading and reloading into signal processor


400


during execution of the single task list


250


is necessary in this example because signal processor instruction memory


402


is not large enough to store all of SP microcode


156


, and the signal processor is designed so that it can execute instructions only out of its internal instruction memory.





FIG. 10

shows an example of a simplified graphics process performed by signal processor


400


based on a display list


110


. In this simplified process, the display list


110


first commands signal processor


400


to set various attributes defining the overall graphical images that are to be rendered by the co-processor. Such attributes include, for example, shading, lighting, Z buffering, texture generation, fogging and culling (

FIG. 10

block


612


). The display list next commands signal processor


400


to define a modeling/ viewing matrix and a projection matrix (

FIG. 10

, block


614


). Once the appropriate matrices have been defined, the display list commands signal processor


400


to transform a set of vertices based on the modeling/viewing matrix and the projection matrix defined by block


614


and also based on the attributes set by block


612


(

FIG. 10

, block


616


). Finally, the display list commands signal processor


400


to generate a graphics display (e.g., triangle) command that directs display processor


500


to render a primitive based on the vertices generated by block


616


and the attributes set by block


612


(

FIG. 10

, block


618


). Signal processor


400


may, in response to step


618


, transfer the display processor command it has generated (or the address of the command, which the signal processor may store in its data memory


404


or in main memory


300


) for access and execution by display processor


500


.





FIG. 11

shows an overall process


620


performed by signal processor graphics microcode


156


to process a display list


110


(e.g., to perform the type of process shown in FIG.


10


). Signal processor


400


gets the next display list command and determines what kind of a command it is (

FIG. 11

, block


622


). Display lists commands in this example generally have five different types:




Signal processor attribute command




Display processor command




Matrix command




Vertex command




Triangle command




Flow control command




If the display list command is a signal processor attribute command, signal processor


400


sets signal processor attributes as specified by the command (

FIG. 11

, block


624


). In this example, the following types of SP attribute command are defined:




shading




lighting




Z-buffering




texturing




fogging




culling.




The following are example SP attribute command formats and associated definitions:




SIGNAL PROCESSOR ATTRIBUTE COMMANDS















G_SETGEOMETRYMODE:

























command













command















This command “sets” some of the rendering pipeline state. This state is maintained in the signal processor


400


, and a SET/CLEAR interface is presented to the user.




Bits which are “on” in the command field are turned ON in the internal state.


















G_SHADE




Enable vertex shading or use







primitive color to paint the polygon







(default is vertex shading).






G_LIGHTING




Enable lighting calculations.






G_SHADING_SMOOTH




Enable smooth or flat shading (the







default, with this bit cleared is flat







shading).






G_ZBUFFER




Enable z-buffer depth calculations.






G_TEXTURE_GEN




Enable automatic generation of the







texture coordinates S & T. After







transformations, a spherical mapping







will be used to replace any S &







T value originally given with the vertex.






G_FOG




Enable fog coefficient to be generated







and replace the vertex alpha. Large







alphas are more foggy (farther).






G_TEXTURE_GEN_LINEAR




Enable linearization of the texture







coordinates generated when







G_TEXTURE_GEN







is set. For example, this allows the







use of a panoramic texture







map when performing environment







mapping.






G_LOD




Enable generation level of detail







(LOD) value for mipmapped textures







and texture-edge mode.






G_CULL_FRONT




Cull the front-facing polygons.






G_CULL_BACK




Cull the back-facing polygons.














G_CLEARGEOMETRY MODE




Same as G_SETGEOMETRYMODE, but this command “clears” some of the rendering pipeline state (bits which are “on” in the command field are turned OFF in the internal state).




G_Light















G_LIGHT:

























Command




param




length = 16














seg




address

































light.r




light.g




light.b




0x00







light.r




light.g




light.b




0x00







light.x




light.y




light.z




0x00















This command passes a light to the rendering pipeline. There can be up to 7 directional lights (numbered


1


-


7


) plus an ambient light. The param specifies which light number (n) to replace with this light description. Use the G_NUM_LIGHTS command to specify how many of the 8 lights to use. If the number of lights specified is N, then the first N lights (1−N) will be the ones used, and the Nth+1 lights will be the ambient light. The “param” field should be set based on a value maintained in data memory


404


+(n−1)×2.




The ambient light is defined by a color: light.r, light.g, light.b (unsigned 8 bit integers) which should be set to the color of the ambient light multiplied by the color of the object which is to be drawn (If you are lighting a texture mapped object just use the color of the ambient light). (For ambient lights the light.x, light.y, and light.z fields are ignored). The ambient light cannot be turned off except by specifying a color of black in this example.




Directional lights are specified by a color: light.r, light.g, light.b (unsigned 8 bit integers) which, like the ambient light color, should be set to the color of the light source multiplied times the color of the object which is to be drawn. Directional lights also have a direction. The light.x, light.y, light.z fields (signed 8 bit fractions with 7 bits of fraction) indicates the direction from the object to light. There must be at least one directional light (if G_LIGHTING is enabled in G_SETGEOMETRYMODE command) turned on, but if its color is black it will have no effect on the scene.




The G_NUM_LIGHTS command should always be used sometime after G_LIGHT command(s) before the next G_VTX command even if the number of lights has not changed.















G_NUM_LIGHTS:

























Command




param




length = 8














seg




address































0x8000




32 × (1 + N)











0x00000000











N = number of diffuse light sources (1-7).













This command specifies how many lights should be used. It should always be used after the G_LIGHT command before the next G_VTX command. The parameter specifies the number of diffuse light sources (N) which must be at least 1 and not more than 7. The ambient light source will be light number N+1 and the directional light sources will be lights numbered 1 through N.















G_SETOTHERMODE_H:




























command





shift




len











word














This command sets the high word of the “other” modes in the display processor, including blending, texturing, and frame buffer parameters. The signal processor


400


remembers the high and low words of the display processor


500


“other” state, in order to present a simple set-command interface. Although this is a display processor command, it must be parsed and interpreted by the signal processor


400


and therefore cannot be sent directly to the display processor without first going through the signal processor.




The shift and len parameters in this command are used to construct a mask:




(((0×01<<len) −1)<<shift)




This mask is used to clear those bits in the display processor


500


status word. New bits, from the word parameter are OR'd into the status word. (the parameter word must be pre-shifted).




G_SETOTHERMODE_L




Same as G_SETOTHERMODE_H, but affects the low word of the “other” modes on the display processor


500


.















G_TEXTURE:

























command





s scale














t scale




mipmap




tile




on







level




num














This command turns texture mapping ON/OFF, provides texture coordinate scaling, and selects the tile number (within a tiled texture). Scale parameters are in the format of (0.16) and scale the texture parameters in vertex commands. Texture on/off turns on and off the texture coordinate processing in the geometry pipeline. Tile number corresponds to tiles chosen in the raster portion of the pipeline. The tile num also holds the maximum levels for level of detail (LOD) (mid-mapping).















G_LOOKAT_X:

























Command




param




length = 16














seg




address































0x00000000








0x00000000

















X




Y




Z




0x00















This command is used for automatic texture coordinate generation. It is used to describe the orientation of the eye so that the signal processor


400


knows with respect to what to generate texture coordinates. The XYZ values (8 bit signed fractions with 7 bits of fraction) describe a vector in worldspace (the space between the MODELVIEW matrix and the PROJECTION matrix) which is perpendicular to the viewer's viewing direction and pointing towards the viewer's right.




G_LOOKAT_Y




Same as G_LOOKAT_X, but the first zero words in the addressed segment are zero (0×00000000).




DP Command Generation




Referring back to

FIG. 11

, if the next display list command is one intended for display processor


500


, signal processor


400


simply writes the command to the display processor (block


626


of FIG.


11


). Block


626


can either DMA the display processor command into display processor


500


via the X-bus


218


, or it can deposit the display processor command in a buffer within main memory


300


for access by the display processor.




MATRIX COMMANDS




If the next display list command is a matrix command, signal processor


400


updates the state of the current matrix it is using (

FIG. 11

, block


628


) and places the updated matrix on the matrix stack (block


630


). As mentioned above, in this example signal processor


400


maintains a 10-deep modeling/viewing matrix stack. New matrices can be loaded onto the stack, multiplied (concatenated) with the top of the stack, or popped off of the stack. In this example, signal processor


400


maintains a “one-deep” projection matrix. Therefore, new matrices can be loaded onto or multiplied with the current projection matrix, but cannot be pushed or popped.




In this example, the modeling/viewing matrix stack resides in main memory


300


. The video game program


108


must allocate enough memory for this stack and provide a pointer to the stack area in task list


250


. The format of the matrix is optimized for the signal processor's vector unit


420


. To provide adequate resolution, signal processor


400


in this example represents each matrix value in 32-bit “double precision”—with an upper 16 bit signed integer portion (indicating the part of the value greater than 1) and a lower 16-bit fractional portion (indicating the part of the value between 0 and 1). However, vector unit


420


in this example operates on 16-bit wide values and cannot directly multiply 32-bit wide values. The matrix format (which is shown in

FIG. 12B

) groups all of the integer parts of the elements, followed by all of the fractional parts of the elements. It allows signal processor


400


to more efficiently manipulate the matrix by multiplying 16 bit integer parts and 16 bit fractional parts separately without have to repeatedly “unpack” or “pack” the matrix.




For example, vector unit


420


can multiply each of the 16-bit fixed point signed integer values in a matrix row in one operation, it can multiply each of the 16-bit fractional portions of the same row in another operation. These two partial results can be added together to obtain a 32-bit double precision value, or they can be used separately (e.g., for operations that require only the integer part of the result or only the fractional part of the result). Thus, matrix representations thus allows signal processor


400


to efficiently process 32-bit precision values even though vector unit


420


in this example, operates on 16-bit values and as no explicit “double precision” capability.




The following are example signal processor matrix commands and associated formats:




Example Matrix Commands















G_MTX:

























Command




param




length














seg




address































m00 int




m00 frac







m10 int




m10 frac







. . .




. . .















The matrix command points to a 4×4 transformation matrix (See

FIG. 12B

) that will be used to transform the subsequent geometry, in a manner controlled by the flags in the parameter field. The length is the size of the incoming matrix in bytes. A 4×4 matrix pointed to by this command has the following format: It is a contiguous block of memory, containing the 16 elements of the matrix in ROW MAJOR order. Each element of the matrix is in a fixed point format, S


15


.


16


. The length of a 4×4 matrix in bytes should be 64 bytes. The segment id and address field are used to construct the main memory


300


address of the actual matrix. (see G_SEGMENT SP command for more information).




The following flags in the parameter field are used:


















G_MTX_MODELVIEW




Identifies the incoming matrix as a







modelview matrix, which is necessary to







provide efficient transformation of polygon







normals for shading, etc. (default)






G_MTX_PROJECTION




Identifies the incoming matrix as a







projection matrix, which does not affect







the transformation of the polygon normals







for shading, etc.






G_MTX_MUL




The incoming matrix is concatenated with







the current top of the matrix stack. (default)






G_MTX_LOAD




The incoming matrix replaces the current top







of the (modelview or projection) matrix







stack.






G_MTX_NOPUSH




The current top of the matrix stack is not







pushed prior to performing the load or concat







operation with the top of the stack. (default)






G_MTX_PUSH




The current top of the matrix stack is pushed







prior to performing the load or concat







operation with the top of the stack.







Push is only supported with







G_MTX_MODELVIEW, and not with







G_MTX_PROJECTION.







--Since there is no projection matrix







stack (the projection must be







explicitly reloaded)














This single command with the combination of parameters allows for a variety of commonly used matrix operations. For example, (G_MTX_LOAD|G_MTX_NOPUSH) replaces the top of the stack. (G_MTX_MUL|G_MTX_PUSH) performs a concatenation while pushing the stack for typical modeling hierarchy construction.




For lighting and texturing, the polygon normal also must be transformed by the inverse transpose of the modelview matrix (reference the “OpenGL Programming Guide”). This is the reason separate modelview and projection stacks are kept, and incoming matrices must be identified.















G_POPMTX:

























command













param















This command pops the modelview matrix stack. The parameter field should be 0. Popping an empty stack results in . . . (doesn't pop). Since there is no projection matrix stack, this command is supported only for the modelview matrix.















G_VIEWPORT:

























Command




param




length = 16














seg




address































x scale




y scale







z scale




pad







x translate




y translate







z translate




pad















This command sends a viewport structure to the graphics pipeline.




The segment id and address field are used to construct the main memory


300


address of the actual VIEWPORT structure (see G_SEGMENT for more information).




The viewport transformation is a scale-translation of the normalized screen coordinates. In general, the viewport must be constructed in cooperation with the projection matrix in order to meet the hardware requirements for screen device coordinates.




The scale and translation terms for x and y have 2 bits of fraction, necessary to accommodate the sub-pixel positioning in the hardware. The z values have no fraction.




Accounting for the fractional bits, using one of the default projection matrices, the viewport structure can be initialized like this:




(SCREEN_WD/2*4, (SCREEN_HT/2)*4, G_MAXZ, 0,/*scale*/




(SCREEN_WD/2*4, (SCREEN_HT/2)*4, 0, 0,/*translate*/




Vertex Command Processing




Referring once again to

FIG. 11

, if the next display list command is a “vertex command”, signal processor


400


transforms the vertices specified by the vertex command by the current matrix state and possibly shaded by the current lighting state, performs a clip test on the vertices, and loads the resulting vertices into a vertex buffer


408


within data memory


404


. Signal processor


400


in this example has a vertex buffer that holds up to sixteen vertices.

FIG. 13A

shows the signal processor


400


vertex buffer, which is fully exposed to main processor


100


and thus to video game program


108


. This internal vertex buffer


404


, which can hold up to 16 points, is stored in signal processor data memory


404


and can be read by main processor


100


.




Although signal processor


400


in this example, can handle only lines, triangles or rectangles (i.e., surfaces defined by 2, 3, or 4 vertices), vertex buffer


408


in this example, stores up to 16 vertices so that the signal processor can re-use transformed vertex values instead of having to recalculate the vertices each time. 3D authoring/modeling software used to create video game program


108


, in this example, should preferably organize display list


110


to maximize vertex re-use (and thus speed performance).





FIG. 13B

shows an example vertex data structure signal processor


400


uses to represent each of the vertices stored in vertex buffer


408


. In this example, the transformed x, y, z, and w, values corresponding to the vertex are stored in double precision format, with the integer parts first followed by the fractional parts (fields


408


(


1


)(


a


)-


408


(


1


)(


h


)). With vertex color (r, g, b, a) are stored in fields


408


(


1


)(I)-


408


(


1


)(


l


), and vertex texture coordinates (s, t) are stored in fields


408


(


1


)(


m


),


408


(


1


)(


n


). Additionally, from this example, the vertex values in screen space coordinates (i.e., transformed and projected onto the viewing plane) are stored in fields


408


(


1


)(


o


)-


408


(


1


)(


t


) (with the one/w value stored in double precision format). The screen coordinates are used by display processor


500


to draw polygons defined by the vertex. The transformed 3-dimensional coordinates are maintained in vertex buffer


408


for a clipping test. Since polygons (not vertices) are clipped, and since the vertices in vertex buffer


408


may be re-used for multiple polygons, these transformed 3D vertex values are stored for multiple possible clipping test to be performed. In addition, the vertex data structure


408


(


1


) includes flags


408


(l)(


v


) that signal processor


400


can use, for example, to specify clip test results (i.e., whether the vertex falls inside or outside of each of six different clip planes). The perspective projection factor stored in fields


408


(


1


)(


s


),


408


(


1


)(


t


) is retained for perspective correction operations performed by the display processor texture coordinate unit (explain below).




The following is an example of a vertex command format used to load the internal vertex buffer with some points:















G_VTX:




























Command




n




vO




length














seg




address


































x





y








z





flag







s





t
















r or nx




g or ny




b or nz




a













.







.







.















This command loads (n+1) points into the vector buffer beginning at location v


0


in the vertex buffer. The segment id and address field are used to construct the main memory


300


address of the actual VTX structure. (see G_SEGMENT for more information). The number of vertices n, is encoded as “the number minus one”, in order to allow a full 16 vertices to be represented in 4 bits. The length is the number of points times 16, the size of the VTX structure (in bytes). Vertex coordinates are 16-bit integers, the texture coordinates s and t are S


10


.


5


. The flag parameter is ignored in this example. A vertex either has a color or a normal (for shading). Colors are 8 bit unsigned numbers. Normals are 8 bit signed fractions (7 bits of fraction). (0×7


f


maps to +1.0, 0×81 maps to −1.0, and 0×0 maps to 0.0). Normal vectors must













x




2




+y




2




+z




2


≦127






be normalized, i.e.,




Upon receiving a vertex command, signal processor


400


transforms the vertices specified in the vertex command using the current modeling/viewing matrix (

FIG. 11

, block


632


). See Neider et al,


Open GL Programming Guide


(Silicon Graphics 1993) at chapter 3 (“viewing”). These transformations orient the object represented by the vertices in 3-dimensional space relative to the selected view point. For example, they may translate, rotate and/or scale the represented object relative to a selected point of view. Such transformation calculations make heavy use of the signal processor vector unit


420


and its ability to perform eight parallel calculations simultaneously. The transformed results are stored in vertex data structure fields


408


(


1


)(


a


)-


408


(


1


)(


h


) in double precision format in this example.




Clip Test




Signal processor


400


then performs a clip test (

FIG. 11

, block


636


) to determine whether the transformed vertex is inside or outside of the scene. Six clipping planes define the sides and ends of the viewing volume. Each transformed vertex is compared to each of these six planes, and the results of the comparison (i.e., on which side of the clip plane the vertex is located) are stored in vertex buffer “flags” field


408


(


v


) (see FIG.


13


B). These results are used by clipping block


646


in response to a “triangle command” (see below). Note that because this example clips polygons and not vertices,

FIG. 11

block


636


does not actually perform clipping, it simply tests vertex position relative to the clip planes.




Projection




Signal processor


400


then transforms the vertex values using the projection matrix (

FIG. 11

, block


638


). The purpose of the projection transformation is to define a viewing volume, which is used in two ways. The viewing volume determines how an object is projected onto the 2-dimensional viewing screen (that is, by using a perspective or an orthographic projection). (See


Open GL Programming Guide


at 90 et seq.) The resulting transformed vertices have now been projected from 3-dimensional space onto the 2-dimensional viewing plane with the proper for shortening (if the projection matrix defines a perspective projection) or orthographically (if the projection matrix defines an orthographic projection). These screen coordinates values are also written to the vertex buffer data structure at fields


408


(


1


)(


o


)-


408


(


1


)


t


) (the“ 1/w” value is retained for later perspective correction).




Lighting




Signal processor


400


next performs lighting calculations in order to “light” each of the vertices specified in the vertex command. System


50


supports a number of sophisticated real-time lighting effects, including ambient (uniform) lighting, diffuse (directional) lights, and specular highlights (using texture mapping). In order to perform lighting calculations in this example, signal processor


400


must first load an SP microcode


108


overlay to perform the lighting calculations. The G_SETGEOMETRYMODE command must have specified that lighting calculations are enabled, and the lights must have been defined by the G_NUM_LIGHTS command discussed above. The part of microcode


108


that performs the lighting calculations is not normally resident within signal processor


400


, but is brought in through an overlay when lighting calls are made. This has performance implications for rendering scenes with some objects lighted and others colored statically. In this example, the lighting overlay overwrites the clipping microcode, so to achieve highest performance it is best to minimize or completely avoid clipped objects in lighted scenes.




To light an object, the vertices which make up the objects must have normals instead of colors specified. In this example, the normal consists of three signed 8-bit numbers representing the x, y and z components of the normal (see the G_VTX command format described above). Each component ranges in value from −128 to +127 in this example. The x component goes in the position of the red color of the vertex, the y into the green and the z into the blue. Alpha remains unchanged. The normal vector must be normalized, as discussed above.




Lighting can help achieve the effect of depth by altering the way objects appear as they change their orientation. Signal processor


400


in this example supports up to seven diffused lights in a scene. Each light has a direction and a color. Regardless of the orientation of the object and the viewer, each light will continue to shine in the same direction (relative to the open “world”) until the light direction is changed. In addition, one ambient light provides uniform illumination. Shadows are not explicitly supported by signal processor


400


in this example.




As explained above, lighting information is passed to signal processor


400


in light data structures. The number of diffuse lights can vary from 0 to 7. Variables with red, green and blue values represent the color of the light and take on values ranging from 0 to 255. The variables with the x, y, z suffixes represent the direction of the light. The convention is that the direction points toward the light. This means the light direction indicates the direction to the light and not the direction that the light is shining (for example, if the light is coming from the upper left of the world the direction might be x=−141, y=−141, z=0). To avoid any ambient light, the programmer must specify the ambient light is black (0, 0, 0,).




The G_light command is used to activate a set of lights on a display list. Once lights are activated, they remain on until the next set of lights is activated. This implies that setting up a new structure of lights overwrites the old structure of lights in signal processor


400


. To turn on the lighting computation so that the lights can take effect, the lighting mode bit needs to be turned on using the G_SETGEOMETRYMODE command.




The lighting structures discussed above are used to provide color values for storing into vertex buffer fields


408


(


1


)(


i


)-


408


(


1


)(


l


).




Texture Coordinate Scaling/Creation




Signal processor


400


next performs texture coordinate scaling and/or creation (

FIG. 11

, block


642


). In this example, the operations performed by block


642


may be used to accomplish specular highlighting, reflection mapping and environment mapping. To render these effects, coprocessor


200


in this example uses a texture map of an image of the light or environment, and computes the texture coordinates s,t based on the angle from the viewpoint to the surface normal. This texture mapping technique avoids the need to calculate surface normals at each pixel to accomplish specular lighting. It would be too computationally intensive for system


50


in this example to perform such surface normal calculations at each pixel.




The specular highlight from most lights can be represented by a texture map defining a round dot with an exponential or Gaussian function representing the intensity distribution. If the scene contains highlights from other, oddly shaped lights such as fluorescent tubes or glowing swords, the difficulty in rendering is no greater provided a texture map of the highlight can be obtained.




Although display processor


500


performs texture mapping operations in this example, signal processor


400


performs texture coordinate transformations for each vertex when these effects are required. Activation or de-activation of the signal processor texture coordinate transformations is specified by a value within the G_SETGEOMETRYMODE Command (see above). In addition, the G_SETGEOMETRYMODE Command can specify linearization of the generated textured coordinates, e.g., to allow use of a panoramic texture map when performing environment mapping.




In this example, signal processor


400


texture coordinate generation utilizes the projection of the vertex normals in the x and y directions in screen space to derive the s and t indices respectively for referencing the texture. The angle between the viewpoint and the surface normal at each vertex is used to generate s, t. The normal projections are scaled to obtain the actual s and t values in this example. Signal processor


400


may map the vertices “behind” the point of view into 0, and may map positive projections into a scaled value.




In this example, texturing is activated using the G_TEXTURE command described above in the signal processor attribute command section. This command provides, among other things, scaling values for performing the texture coordinate mapping described above.




As explained above, the texture coordinate mapping performed by signal processor


400


, in this example, also requires information specifying the orientation of the eye so that the angle between the vertex surface normal and the eye can be computed. The G_LOOKAT_X and the G_LOOKAT_Y commands supply the eye orientation for automatic texture coordinate generation performed by signal processor


400


. The transformed texture coordinate values, if they are calculated, are stored by signal processor


400


in the vertex data structure at fields


408


(


1


)(


m


),


408


(


1


)(


n


). These texture coordinate values are provided to display processor


500


to perform acquired texture mapping using a texture specified by the G_TEXTURE command.




Since these effects use texture mapping, they cannot be used with objects which are otherwise texture mapped.




Vertex Buffer Write




After performing all of these various steps, signal processor


400


writes the transformed, lighted, projected vertex values into vertex buffer


408


(

FIG. 11

, block


644


), and returns to parse the next display list command (block


622


).




Triangle Command Processing




Once signal processor


400


has written vertices into its vertex buffer


408


, the display list


110


can provide a “triangle command”. The “triangle command,” which specifies a polygon defined by vertices in vertex buffer


408


, is essentially a request for signal processor


400


to generate a graphics display command representing a polygon and to send that command to display processor


500


for rendering. In this example, signal processor


400


can render three different kinds of primitives: lines, triangles and rectangles. Different modules of microcode


108


need to be loaded in this example to render lines or triangles. In this example, all rectangles are 2-dimensional primitives specified in screen-coordinates, and are neither clipped nor scissored.




The following is an example of a format and associated function of triangle commands:




Example of Triangle Commands




The following command specifies a triangle defined by 3 vertices in the vertex buffer:















G_TRI1:























command
















N




v0




v1




v2















This command results in one triangle, using the vertices v


0


, v


1


, and v


2


stored in the internal vertex buffer. The N field identifies which of the three vertices contains the normal of the face (for flat shading) or the color of the face (for flat shading).




The following command is used to control signal processor


400


to generate display processor


500


commands for rendering a line defined by two vertices in vertex buffer


408


:















G_LINE3D:
























command

















N




v0




v1















This command generates one line, using the vertices v


0


and v


1


in the internal vertex buffer. The N field specifies which of the two vertices contain the color of the face (for flat shading).




Textured and filled rectangles require intervention by signal processor


400


and are thus a signal processor operation. The following is an example command format and associated function of a texture rectangle command:















G_TEXRECT

























command




x0




y0







x1




y1

















command




0x000000














S (top left texture coord)




T(top left texture coord)


















command




0x000000














DsDx




 DtDy















These 3 commands draw a 2D rectangle with the current texture. The parameters x


0


, y


0


specify the upper left corner of the rectangle; x


1


, y


1


are the lower right corners. All coordinates are 12 bits. S and T are signed 10.5 bit numbers, and specify the upper left coordinate of s, t. DsDx and DtDy are signed 5.10 bit numbers, and specify change in s (t) per change in x (y) coordinate.




Signal processor


400


also in this example supports a G_TEXRECT_FLIP command that is identical to the G_TEXRECT command except that the texture is flipped so that the s coordinate changes in the y direction and the t coordinate changes in the x direction.















G_FILLRECT:



























command




x0




y0








x1




y1















This command draws a 2D rectangle in the current fill color. The parameters x


0


, y


0


specify the upper left corner of the rectangle; x


1


, y


1


are the lower right corners. All coordinates are 12 bits.




Clipping/Setup




Referring back to

FIG. 11

, upon receipt of a triangle command, signal processor


400


performs any necessary clipping of the vertices (

FIG. 11

, block


646


). This clipping operation eliminates portions of geometric primitives that lie outside of the six clipped planes defining the view plane.




As explained above, the results of the clip test


636


performed for each vertex are stored and available in vertex buffer


408


. With the triangle command now defining a primitive defined by those vertices, signal processor


400


can proceed to clip the primitive. If all of the vertices of a primitive lay within the space defined by the six clip planes, the entire primitive exists within the display space and does not need to be clipped. If all of the vertices defining a primitive lay outside of the same clip plane (as indicated by the flags field of vertex data structure


408


(


1


) shown in FIG.


13


B), the entire primitive can be excluded from display and thus discarded. If some of the vertices defining a primitive lie within the display space and some lay outside of it (or if all vertices lay outside of the display space but define a primitive which passes through the displayed space), the primitive needs to be clipped and new vertices defined. These tests and operations are performed by clipping block


646


in this example.




Signal processor


400


next performs backface culling (

FIG. 11

, block


647


). This operation maximizes drawing speed by discarding polygons that can be determined to be on the backface of an object and thus hidden from view. In this example, either front-facing, back-facing, neither or both types of primitives can be culled (i.e., discarded) by block


647


. The types of primitives to cull are specified by parameters in the G_SETGEOMETRYMODE command described above—allowing geometry to be ordered in any direction or where used with different culling flags to achieve various effects (e.g., interior surfaces, two-sided polygons, etc.).




Signal processor


400


also performs some set up operations (

FIG. 11

, block


648


), and may then pass a graphics display command to display processor


500


to control the display processor to render the primitive (

FIG. 11

, block


650


). As part of the set up operation (block


648


), signal processor


400


in this example translates “segmented” addresses in the display list


110


into physical addresses that the display processor


500


can use (the display processor is a physical address machine in this example).




In this example, signal processor


400


uses a segment table


416


(see

FIG. 13C

) to assist it in addressing main memory


300


. More specifically, addresses within signal processor


400


may be represented by a table entry


417


A and a 26-bit offset


417


B. The table entry


417


A references one of 16 base addresses within segment address table


416


. The referenced base address may be added to the offset


417




b


to generate a physical address into main memory


300


. Signal processor


400


constructs a main memory


300


address by adding the base address for the segment and a 26-bit offset (which could be provided, for example, by a display list


110


). The segment table


416


is constructed based on the following example G_SEGMENT command:















G_SEGMENT


























command















seg




address















This command adds an entry in the segment table


416


discussed above.




The segmented addressing used by signal processor


400


in this example can be useful to facilitate double-buffered animation. For example, video game program


108


can keep two copies of certain display list fragments within main memory


300


, with the same offsets in two different segments. Switching copies of them is as easy as swapping the segment pointers in signal processor


400


. Another use is to group data and textures in one segment and to group static background geometry in another segment. Grouping data might help optimize memory caching in main processor


100


. All data which contains embedded addresses must be preceded by the appropriate G_SEGMENT command that loads the signal processor


400


segment table with the proper base address.




Although signal processor


400


can use the segment addressing scheme shown in

FIG. 13C

, this arrangement is not available to display processor


500


in this example. Hence, part of set up processing


648


is to translate any segment addresses that point to data structures required for rendering into physical addresses that can be used directly by display processor


500


.




DP Command Write




The primary output of signal processor


400


for graphics purposes is one or more commands to display processor


500


that are outputted by

FIG. 11

, block


650


. Although main processor


100


(or storage device


54


) can directly supply display processor


500


commands, for 3D images the signal processor


400


generally needs to perform the transformation processes described above to generate display processor commands representing transformed, projected lighted, clipped, culled primitives.




The repertoire of display processor commands is set forth in

FIGS. 46-118

. Signal processor


400


is responsible for formatting appropriately the display processor commands it generates, and for including the appropriate information and address information in the commands. In addition, signal processor


400


may generate and provide certain appropriate mode and attribute commands the display processor may require to render a particular primitive specified by the signal processor using the appropriate parameters (although many of the mode and attribute commands for the display processor


500


are typically supplied directly by main processor


100


under control of game program


108


). As mentioned above, main processor


100


can provide any display processor


500


directly, but in general, needs to rely on the signal processor to generate at least some display processor commands whenever 3D objects need to be transformed.




Flow Control Command Processing




Referring once again to

FIG. 11

, if the display list command received by signal processor


400


is a flow control command, then signal processor


400


will respond to this command in an appropriate manner to navigate through or traverse the display list


110


. The following example commands and formats provide flow control.




Example Flow Control Commands















G_DL:



























Command




param




(not used)














seg




address





























.






.






.














This command points to another display list and is used to create display list hierarchies, nested display lists, indirect references, etc. The segment field identifies a memory segment. The address field is the offset from the base of that segment. Together, these form an address in main memory


300


pointing to the new display list. A length field (not shown) may describe the length of the new display list in bytes-although in this example it is preferred that all display lists are terminated by a G_ENDDL command. The parameter field holds flags which control the behavior of the transfer. If the flag G_DL_NOPUSH is set, the current display list is not pushed onto the stack before transferring control. This behaves more like a branch or go to, rather than a hierarchial display list (this may be useful to break up a larger display list into non-contiguous memory pieces, then just connect them with display list branches).















G_ENDDL:


























command















The end display list command terminates this branch of the display list hierarchy, causing a “pop” in the processing of the display list hierarchy. This command is most useful for constructing display list pieces of variable or unknown size, terminated with an end command instead of providing a display list length a priori. All display lists must terminate with this command.















G_NOOP:


























command















This command does nothing. It is generated internally under some circumstances.





FIG. 11

, block


652


performs the function of maintaining a display list stack in main memory


300


and, pushing and nooping (traversing) this display list stack. Block


652


halts signal processor


400


when the signal processor encounters an “open end” display list command.




SIGNAL PROCESSOR MICROCODE AUDIO PROCESSING




Signal processor


400


in this example performs digital audio processing in addition to the graphics processing discussed above. Signal processor vector unit


420


is especially suited for performing “sum of products” calculations that are especially useful in certain types of digital signal processing for audio signals such as, for example, audio decompression, wavetable resampling, synthesis and filtering. Digital spatial and/or frequency filtering with a relatively large number of taps can be accommodated without loss of precision because of the 48-bit-wide accumulators contained with vector unit data paths


423


. As one example of a particular optimum usage of vector unit


420


for audio processing, the eight separate register files


422


and associated data paths


423


of signal processor vector unit


420


can be used to simultaneously process eight different MIDI voices in parallel. The following are examples of additional audio processing that can be efficiently performed using vector unit


420


:




solving polynomial equations,




processing 8 audio voices or 8 time samples in parallel,




wavetable synthesis using cubic interpolation, wherein four of the vector unit data paths


423


are used to process one sample, and the other four vector unit data paths are used to process a second sample,




audio enveloping processing wherein the 8 vector unit data paths can each multiply a different audio sample by a different weighting factor, and




audio mixing processing wherein the 8 vector unit data paths can each multiply a different audio sample by a corresponding mixer weighting factor.




Because signal processor


400


can perform audio digital signal processing efficiently at high speed, it takes the signal processor only a small fraction of an audio playback real time interval to perform and complete the digital audio processing associated with that time interval. For example, signal processor


400


takes much less than {fraction (1/30)}th of a second to digitally process audio that coprocessor audio interface


208


will playback in real time over a {fraction (1/30)}th of a second time interval. Because of this capability, signal processor


400


in this example can be time-shared between graphics processing and digital audio processing.




Generally, main processor


100


gives signal processor


400


a task list


250


at the beginning of a video frame that specifies the image and sound to be produced during the next succeeding video frame. Coprocessor


200


must be finished with both the audio and graphics processing for this next succeeding frame by the time that next succeeding frame begins. Because video display and audio playback is a real time continuous process (i.e., a new video image must be provided each video frame time, and audio must be continuously provided), coprocessor


200


needs to finish all audio and video signal processing associated with each next succeeding video frame by the time that next frame begins.




In this example, signal processor


400


is shared between graphics processing and digital audio signal processing. Because of the high speed calculating capabilities of signal processor vector unit


420


, signal processor


400


is able to complete processing of the audio to be played during the next succeeding video frame in much less than the current video frame time, and is also able to complete graphics processing for the image to be displayed during the next succeeding image in less than the current frame time. This allows task list


250


to specify both graphics display lists and audio play lists that all must be completed by signal processor


400


/coprocessor


200


by the beginning of the next video frame time. However, in this example there is nothing to prevent main processor


100


from giving coprocessor


200


a task list


250


that the coprocessor cannot complete before the next video frame begins. If the combined audio and graphics processing required by signal processor


400


is sufficiently intensive and time-consuming, the signal processor


400


can work on processing the task list for the entire current video frame time and still not be done by the beginning of the next video frame. It is up to video game program


108


to avoid overtaxing coprocessor


200


, and to handle any overtaxing in an appropriate manner should it occur. A video game programmer can avoid overtaxing signal processor


400


by ensuring that all display lists


110


are organized efficiently, modeling the objects in 3-D in an efficient manner, and taking precautions to ensure that extensive time consuming processing (e.g., clipping) is avoided or minimized. Even with such precautions, however, it may take coprocessor


200


more than a single video frame time to complete especially complicated images. A video game programmer can handle this situation by slowing down the effective frame rate so that television


58


redisplays the same image stored in one part of frame buffer


118


for multiple video frames during which time coprocessor


200


can complete processing the next image. Because the user may perceive a variable frame rate as undesired delay, it is often best to slow down the overall effective frame rate to the rate required for coprocessor


200


to complete the most processing-intensive images-thus preventing more complex images from appearing more slowly than less complex images.




With respect to audio processing, it is generally unacceptable to fail to provide audio for a given video frame time since the user will hearing a disturbing “click” in a stream of otherwise continuous audio. Such audio disruptions are easily heard and can be annoying. Therefore, they should be avoided. One way to avoid an easily detectable audio disruption in a situation where signal processor


400


has failed to complete its assigned audio processing in time is for main processor


100


to command audio interface


208


to replay the last frame's worth of audio during the next succeeding frame. Acceptable audio can be produced in this way without the user noticing a disruption if done carefully. Other strategies include having signal processor


400


process multiple video frames worth of audio within a single video frame time—thereby providing an effective audio “frame” rate that is different (faster) than the effective video frame rate. By “effective frame rate” we mean the rate at which coprocessor


200


produces a frame's worth of information (in this example, the television actual video frame rate stays constant).




Example Audio Software Architecture





FIG. 14

shows an example of the overall software architecture provided by system


50


to synthesize and manipulate audio. This overall software architecture


700


includes four software objects, in this example a sequence player


702


, a sound player


704


, a synthesis driver


706


and audio synthesis microcode


708


. In this example, sequence player


702


, sound player


704


, and synthesis driver


706


all execute on main processor


100


, and audio synthesis microcode


708


runs on coprocessor signal processor


400


. Thus, sequence player


702


, sound player


704


and synthesis driver


706


are each supplied as part of game program


108


of storage device


54


, and audio synthesis microcode


708


is supplied as part of SP microcode


156


.




Sequence player


702


, sound player


704


and synthesis driver


706


may differ depending on the particular video game being played. In general, sequence player


702


is responsible for the playback of Type 0 MIDI music sequence files. It handles sequence, instrument bank and synthesizer resource allocation, sequence interpretation, and MIDI message scheduling. Sound player


704


is responsible for the playback of all ADPCM compressed audio samples. It is useful for sound effects and other streamed audio. Synthesis driver


706


is responsible for creating audio play lists


110


which are packaged into tasks by main processor


100


under software control and passed to coprocessor


200


in the form of task lists


250


. In this example, synthesis driver


706


allows sound player


704


or other “clients” to assign wave tables to synthesizer voices, and to control playback parameters. As discussed above, the audio synthesis microcode


708


processes tasks passed to it and synthesizes L/R stereo 16-bit samples, which signal processor


400


deposits into audio buffers


114


within main memory


300


for playback via audio interface


208


, audio DAC


140


and amplifier/mixer


142


.




In this example, synthesis driver


706


passes audio tasks to signal processor


400


in the form of audio “frames.” A “frame” is a number of audio samples-usually something close to the number of samples required to fill a complete video frame time at the regular video frame rate (for example, 30 or 60 Hz). Although television set


58


receives and processes audio signals in a continuous stream unconstrained by any video frame rate parameter (e.g., the television can generate audio during horizontal and vertical video blanking and retrace), system


50


in this example organizes audio processing in terms of video frame rate because signal processor


400


-which is shared between audio and graphics processing-must operate in accordance with the video frame rate because the graphics related tasks it performs are tied to the video frame rate.




Example Play List Processing





FIG. 15

shows an example of a simple signal processor play list process. The

FIG. 15

process is specified by a play list


10


generated by main processor


100


under control of video game program


108


, and specified as part of a task list


250


. Thus, the

FIG. 15

SP play list process is an example of an output of synthesis driver


706


that is provided to signal processor


400


in the form of an audio play list


110


.




Because of the limited size of instruction memory


402


in this example, audio synthesis microcode


708


is generally not continuously resident within signal processor


400


. Instead, the initialization microcode main processor


100


arranges to be loaded into instruction memory


402


(see

FIG. 9

, block


604


), ensures that the appropriate audio microcode routine is loaded into the instruction memory for audio processing (also ensures that the appropriate graphics microcode routine is loaded into the instruction memory for graphics processing). The steps shown in

FIG. 15

assume that the audio synthesis microcode


708


is resident within the signal processor instruction memory


402


, and that the signal processor


400


is reading an audio play list


110


specifying the steps shown.




Generally, the first task of an audio play list


110


is to set up buffers within signal processor data memory


408


required to perform the audio processing task (

FIG. 15

, block


710


). Generally, this buffer set up process involves allocating areas within data memory


404


to be used as one or more audio input buffers, and allocating an audio output buffer within the data memory. Generally, main processor


100


also commands signal processor


400


to use its DMA facility


454


to retrieve audio input data


112




b


from main memory into the allocated input buffer(s) for processing. Main processor


100


may next set certain attributes (e.g., volume ranges and change rates) to be used for the audio processing (

FIG. 15

, block


712


). Main processor


100


then specifies the types of signal processing to be performed by signal processor


400


along with appropriate parameters (

FIG. 15

, block


714


). In this example, main processor


100


can specify decompression, resampling, envelope/pan, mixing, and other processing (e.g., reverb) to be performed individually or in combination. The audio play list


110


typically will terminate with a command to save the contents of the output audio buffer stored in signal processor data memory


404


into main memory


300


(block


716


).




Example Audio Synthesis Microcode





FIG. 16

shows the overall tasks performed by audio synthesis microcode


708


in this example. Signal processor


400


under microcode control retrieves the next play list command from the current audio play list


110


, and determines what kind of command it is (

FIG. 16

, block


718


). In this example, the audio command within an audio play list


110


may fall into the following general types:




buffer command




flow control command




attribute command




decompress command




resample command




envelope/pan command




mix command




special signal processing/effects command.




Buffer Command Processing




Buffer commands manage audio buffers within signal processor data memory


404


, and permit audio data to be transferred between the data memory and main memory


300


. The following are examples of buffer command formats and associated functions:




Example Buffer Commands















A_SETBUFF:




























command




dmemin














dmemout




count















This command sets the internal signal processor data memory


404


buffer pointers and count value used by the processing commands. This command is typically issued before any processing command. dmemin points to an input buffer, dmemout to an output buffer and count defines the number of 16 bit samples to process.















A_LOADBUFF:



























command















seg




address















This command loads a signal processor data memory


404


buffer from the main memory


300


address given by the seg+address fields. The SP data memory buffer location and the number of 16 bit samples to load are defined by issuing an A_SETBUFF command prior to the A_LOADBUFF command.















A_CLEARBUFF:



























command




dmemin















count















This command clears an area of size count 16 bit samples starting at the signal processor


400


data memory address given by dmem.















A_SAVEBUFF:

























command















seg




address















This command saves a buffer of 16 bit samples in the signal processor data memory


404


to the main memory


300


address given by the seg+address field. The input SP data memory buffer and number of samples are defined by issuing a A_SETBUFF command.















A_SEGMENT:

























command















seg




address















See graphics G-SEGMENT command. This command is used to map indirect “segment” addresses into main memory


300


physical addresses.




Referring again to

FIG. 16

, signal processor audio synthesis microcode


708


performs the specified buffer command by establishing, managing, writing data into, or reading data from the associated data memory buffer


409


(

FIG. 16

, block


720


). Typically, signal processor


400


may use its DMA facility


454


to transfer data between main memory


300


and signal processor memory


404


in order to retrieve audio input data for processing or save audio data into main memory for playback by audio interface


208


.




Flow Control Command Processing




If the next play list command is a flow control command, signal processor


400


responds to the command by traversing the current audio play list in the manner specified by the command. Nesting of audio play lists


110


is preferably permitted, and signal processor


400


may maintain an audio play list stack in main memory


300


(just as it may do for graphics display lists).




Attribute Command Processing




If the next audio play list command is an attribute command, signal processor


400


processes the command by establishing appropriate mode and/or attribute conditions to be used for subsequent audio processing (

FIG. 16

, block


724


). In this example, audio synthesis microcode


708


supports the following example attribute command format and associated function:




Example Attribute Commands















A_SETVOL:


























command




volume














volume target




volume rate















This command is used to set the volume parameters for subsequent processing commands. Currently this should be issued prior to A_ENVELOPE, A_PAN and A_RESAMPLE.




Decompress Command Processing




If the next audio play list command retrieved by signal processor


400


is a decompression command, the signal processor performs a decompression operation to decompress a compressed audio binary stream stored in an input buffer within data memory


404


to produce 16-bit audio samples which it stores in a defined audio output buffer within its data memory (

FIG. 16

, block


726


). In this example, audio synthesis microcode


708


supports the following audio decompression command format and associated function:




Example Decompression Command















A_ADPCM:



























command




flags




gain















seg




address















This command decompresses a binary stream in signal processor data memory


404


to produce 16 bit samples. The addresses in the data memory


404


for the input and output buffers and the number of samples to process are defined by issuing a A_SETBUFF command prior to the A_ADPCM command. The seg+address field points to a main memory


300


location which is used to save and restore state. The gain parameter is used to scale the output and is represented as S.


15


.




The flags define the behavior of the command. Currently defined flags are:




A_INIT, The seg+address field is used to restore state at the beginning of the command. If not set the pointer to state is ignored upon initiation, however, state is saved to this address at the end of processing.




A_MIX, The results are mixed into the output buffer. If not set results are put into the output buffer.




Resample Command Processing




If the next audio play list command signal processor


400


reads is a resample command, then the signal processor provides pitch shifting/resampling as well as integral envelope modulation based on the parameters specified in the command (

FIG. 16

, block


728


). The following is an example of a resample command and associated function supported by audio synthesis microcode


708


.




Example Resample Command















A_RESAMPLE:



























command




flags




pitch















seg




address















This command provides pitch shifting/resampling as well as integral envelope modulation. The signal processor data memory


404


input and output buffers and the number of samples are defined by issuing an A_SETBUFF command, and the volume envelope parameters are defined by issuing an A_SETVOL command. Resampling factor is defined by pitch.




The flags define the behavior of the command. Currently defined flags are:


















A_INIT,




The seg + address field field is used to restore state at the







beginning of the command. If not set the pointer to state is







ignored upon initiation, however, state is saved to this address







at the end of processing.






A_MIX,




The results are mixed into the output buffer. If not set results







are put into the output buffer.














Envelope/Pan Command Processing




If the next audio play list command signal processor


400


reads is an envelope/pan command, the signal processor performs that command by modulating one or two audio signal streams using a linear envelope (

FIG. 16

, block


730


). An envelope command multiplies an audio input sample stream by a linear function, and is thus able to ramp the volume of the audio up or down. A “pan” command generally applies inverse linear functions to audio in left and right stereo channels—accomplishing the effect of moving the perceived source of a sound or voice in space (i.e., from left to right or from right to left). The following examples of envelope/pan command formats and associated functions are supported by audio synthesis microcode


708


in this example of system


50


.




Example Envelope/Pan Commands















A ENVELOPE:





























command




flags









seg





address















This command modulates a sample stream using a linear envelope. The parameters for the volume envelope are defined by issuing A_SETVOL and the signal processor data memory


404


buffer locations and number of samples to process are defined by issuing an A_SETBUFF prior to issuing the A_ENVELOPE command.




The flags define the behavior of the command. Currently defined flags are:




A_INIT, The seg+address field field is used to restore state at the beginning of the command. If not set the pointer to state is ignored upon initiation, however, state is saved to this address at the end of processing.




A_MIX, The results are mixed into the output buffer. If not set results are put into the output buffer.















A PAN:






























command




flags




dmemout2


















seg




address















This command provides 1 input, 2 output panning. Input, first output and number of samples are defined by issuing an A_SETBUFF command and the panning parameters are defined by issuing an A_SETVOL command. The second output is defined by dmemout


2


.




The flags defined the behavior of the command. Currently defined flags are:


















A_INIT,




The seg + address field field is used to restore state at the







beginning of the command. If not set the pointer of state is







ignored upon initiation, however, state is saved to this address







at the end of processing.






A_MIX,




The results are mixed into the output buffer. If not set results







are put into the output buffer.














Mixing Command Processing




If the next audio play list command is a mixing command, signal processor


400


performs a mixing function to mix two audio input sample streams into the output audio buffer (

FIG. 16

, block


732


). The following example mixing command format and associated function is supported by signal processor


400


and audio synthesis microcode


708


in this example.




Example Mixer Command















A MIXER:



























command





gain









dmemoutf














This command provides a double precision mixing function. The single precision input is added to the double precision output after multiplication by gain. dmemoutf points to a signal processor data memory


404


area which stores the fractional part of the mixed stream. The input buffer, number of samples and integer part of the mixed output are defined by issuing an A_SETBUFF prior to the A_MIX.




Special Audio Effects Processing




If the next audio play list command is a special signal processing/effects command, signal processor


400


executes the command by providing the specified special effect or signal processing (

FIG. 16

, block


734


). An example special signal processing/effect is the addition of reverberation to create presence. This special effect simulates sound reflection in caves, concert halls, etc., and can also be used for various other special effects. Signal processor


400


and audio synthesis microcode


708


supports the following example reverberation special effects command format and associated function:




Example Effects Command















A REVERB:





























command




flags









seg





address















This command applies the reverb special effect to a sample stream. Signal processor data memory


404


input, output and number of samples are defined by issuing an A_SETBUFF command.




The flags define the behavior of the command. Currently defined flags are:


















A_INIT,




The seg + address field field is used to restore state at the







beginning of the command. If not set the pointer to state is







ignored upon initiation, however, state is saved to this address







at the end of processing.






A_MIX,




The results are mixed into the output buffer. If not set results







are put into the output buffer.














Audio Processing Structure




To accomplish each of audio processing functions


728


,


730


,


732


,


734


in this example, audio synthesis microcode


708


uses a general purpose effects implementation that manipulates data in a single delay line.

FIG. 17

shows an example general purpose audio processing implementation


740


. In this example, the audio input samples can be conceived of as being applied to the input of contiguous single delay line


742


. The output tap of the delay line is applied through a gain


744


to the audio output buffer within signal processor data memory


404


. Samples from another tap on delay line


742


are passed through a summer


746


and returned to the delay line directly (over path


748


) and also through a coefficient block


750


, another summer


752


and a low pass filter


754


. A further tap


756


from delay line


742


is connected to the other input of summer


752


and also to the other input of summer


746


(this time through a further coefficient block


758


). This generalized implementation


740


allows a particular effect to be constructed by attaching an arbitrary number of effect primitives to single delay line


742


. The parameters for each primitive in the effect are passed through via the commands discussed above. Each primitive consists of an all-pass with a variable length tap followed by a DC normalize (unity gain at DC) single poll low-pass filter


754


followed by an output gain


744


specifying how much of this primitive's output is to be contributed to the final effect output. The value of each of the parameters for a primitive specifies the function of that primitive as a whole within the effect. Note that in

FIG. 17

, the feedback coefficient


758


can be used to construct an “all-pass inside a comb” reverb (in response to the a_reverb command discussed above).




The general nature of implementation


740


does not mean that all functions are implemented. Only those functions which are driven by legitimate parameters actually generate audio command operations by signal processor


400


. This gives video game programmers a great degree of flexibility in defining an effect that is appropriate in terms of both sonic quality and efficiency.




COPROCESSOR DISPLAY PROCESSOR


500






Display processor


500


in this example rasterizes triangles and rectangles and produces high quality pixels that are textured, anti-aliased and z-buffered.

FIG. 18

shows the overall processes performed by display processor


500


. Display processor


500


receives graphics display commands that, for example, specify the vertices, color, texture, surface normal and other characteristics of graphics primitives to be rendered. In this example, display processor


500


can render lines, triangles, and rectangles. Typically, display processor


500


will receive the specifications for the primitives it is to render from signal processor


400


, although it is also possible for main processor


100


to specify these commands directly to the display processor.




The first operation display processor


500


performs on an incoming primitive is to rasterize the primitive, i.e., to generate pixels that cover the interior of the primitive (

FIG. 18

, block


550


). Rasterize block


550


generates various attributes (e.g., screen location, depth, RGBA color information, texture coordinates and other parameters, and a coverage value) for each pixel within the primitive. Rasterize block


550


outputs the texture coordinates and parameters to a texture block


552


. Texture block


552


accesses texture information stored within texture memory


502


, and applies (“maps”) a texel (texture element) of a specified texture within the texture memory onto each pixel outputted by rasterized block


550


. A color convert block


554


and a chroma keying block


556


further process the pixel value to provide a texture color to a color combine block


558


.




Meanwhile, rasterize block


550


provides a primitive color (e.g., as a result of shading) for the same pixel to color combine block


558


. Color combine block


558


combines these two colors to result in a single pixel color. This single pixel color output may have fog applied to it by block


560


(e.g., to create the effect of a smoke filled room, or the less extreme, natural effect of reducing color brilliance as an object moves further away from the viewer). The resulting pixel color value is then blended by a block


562


with a pixel value framebuffer


118


stores for the same screen coordinate location. An additional anti-alias/z-buffer operation


564


performs hidden surface removal (i.e., so closer opaque objects obscure objects further away), anti-aliasing (to remove jaggedness of primitive edges being approximated by a series of pixels), and cause the new pixel value to be written back into framebuffer


118


.




The operations shown in

FIG. 18

are performed for each pixel within each primitive to be rendered. Many primitives may define a single complex scene, and each primitive may contain hundreds or thousands of pixels. Thus, display processor


500


must process millions of pixels for each image to be displayed on color television set


58


.




Typically, framebuffer


118


is “double buffered”—meaning that it is sized to contain two complete television screen images. Display processor


500


fills one screen worth of framebuffer information while video interface


210


reads from the other half of the framebuffer


118


. At the end of the video frame, the video interface


210


and display processor


500


trade places, with the video interface reading from the new image representation just completed by display processor


500


and the display processor rewriting the other half of the framebuffer. This double buffering does not give display processor


500


any more time to complete an image; it must still finish the image in nominally one video frame time (i.e., during the video frame time just prior to the frame time during which the new image is to be displayed).




Pipelining




Because high speed operation is very important in rendering pixels, display processor


500


has been designed to operate as a “pipeline.” Referring again to

FIG. 18

“pipelining” means that the various steps shown in

FIG. 18

can be performed in parallel for different pixels. For example, rasterize block


550


can provide a first pixel value to texture block


552


, and then begin working on a next pixel value while the texture block is still working on the first pixel value. Similarly, rasterize block


550


may be many pixels ahead of the pixel that blend block


562


is working on.




In this example, display processor


500


has two different pipeline modes: one-cycle mode, and two-cycle mode. In one-cycle mode, one pixel is processed for each cycle time period of display processor


500


. A one-cycle mode operation is shown in FIG.


19


A. Note that the operations shown in

FIG. 19A

are themselves pipelined (i.e., the blend operation


562


operates on a different pixel than the rasterize operation


550


is currently rasterizing), but the overall operation sequence processes one pixel per cycle.





FIG. 19B

shows the two-cycle pipeline mode operation of display processor


500


in this example. In the

FIG. 19B

example, some of the operations shown in

FIG. 18

are performed twice for each pixel. For example, the texture and color convert/filtering operations


552


,


554


shown in

FIG. 18

are repeated for each pixel; the color combine operation


558


is performed twice (once for the texture color output of one texture operation, and once for the texture color output of the other texture operation). Similarly, blend operation


562


shown in

FIG. 18

is performed twice for each pixel.




Even though these various operations are performed twice, display processor


500


in this example does not contain duplicate hardware to perform the duplicated operations concurrently (duplicating such hardware would have increased cost and complexity). Therefore, in this example, display processor


500


duplicates an operation on a pixel by processing it with a particular circuit (e.g., a texture unit, a color combiner or a blender), and then using the same circuit again to perform the same type of operation again for the same pixel. This repetition slows down the pipeline by a factor of two (each pixel must “remain” at each stop in the pipeline for two cycles instead of one), but allows more complicated processing. For example, because the two-cycle-per-pixel mode can map two textures onto the same pixel, it is possible to do “trilinear” (“mipmapping”) texture mapping. In addition, since in this example, display processor


500


uses the same blender hardware to perform both the fog operation


560


and the blend operation


562


(but cannot both blend and fog simultaneously), it is generally necessary to operate in the two-cycle-per-pixel mode to provide useful fog effects.




The following tables summarize the operations performed by the various blocks shown in

FIGS. 19A and 19B

during the one-cycle and two-cycle modes:
















Block




Functionality























Display Processor Pipeline Block Functionality in One-Cycle Mode












Rasterize 550




Generates pixel and its attribute covered by the







interior of the primitive.






Texture 552




Generates 4 texels nearest to this pixel in a texture







map.






Filter Texture 554




Bilinear filters 4 texels into 1 texel, OR performs







step 1 of YUV-to-RGB conversion.






Combine 558




Combines various colors into a single color, OR







performs step2 of YUV-to-RGB conversion.






Blend 562




Blends the pixel with framebuffer memory pixel,







OR fogs the pixel for writing to framebuffer.






Framebuffer 563




Fetches and writes pixels (color and z) from and to







the framebuffer memory.











Display Processor Pipeline Block Functionality in Two-Cycle Mode












Rasterize 550




Generates pixel and its attribute covered by the







interior of the primitive.






Texture 552a




Generates 4 texels nearest to this pixel in a texture







map. This can be level X of a mipmap.






Texture 552b




Generates 4 texels nearest to this pixel in a texture







map. This can be level X + 1 of a mipmap.






Filter Texture 554a




Bilinear; filters 4 texels into 1 texel.






Filter Texture 554b




Bilinear; filters 4 texels into 1 texel.






Combine 558a




Combines various colors into a single color, OR







linear interpolates the 2 bilinear filtered texels







from 2 adjacent levels of a mipmap, OR performs







step 2 of YUV-to-RGB conversion.






Combine 558b




Combines various colors into a single color, OR







chroma keying.






Blend 562a




combines fog color with resultant CC1 color.






Blend 562b




Blends the pipeline pixels with framebuffer







memory pixels.






Framebuffer 563a




Read/modify/write color memory; and






Framebuffer 563b




Read/modify/write Z memory.














Fill and Copy Operations




Display processor


500


also has a “fill” mode and a “copy” mode, each of which process four pixels per cycle. The fill mode is used to fill an area of framebuffer


118


with identical pixel values (e.g., for high performance clearing of the framebuffer or an area of it). The copy mode is used for high-performance image-to-image copying (e.g., from display processor texture memory


502


into a specified area of framebuffer


118


). The copy mode provides a bit “blit” operation in addition to providing high performance copying in the other direction (i.e., from the framebuffer into the texture memory).




The pipeline operations shown in

FIGS. 19A and 19B

are largely unused during the fill and copy modes, because in this example, the operations cannot keep up with the pixel fill or copy rate. However, in this example, an “alpha compare” operation (part of blend operation


562


) is active in the copy mode to allow display processor


500


to “blit” an image into framebuffer


118


and conditionally remove image pixels with the word alpha=0 (e.g., transparent pixels).




The display processor's mode of operation is selected by sending the display processor


500


a “set other mode” command specifying a “cycle type” parameter. See

FIGS. 46-118

. In the one-cycle-per-pixel or two-cycle-per-pixel pipeline modes, additional display processor


500


commands are available to insure that pipeline synchronization is maintained (e.g., so that the pipeline is emptied of one primitive before the parameters of another primitive take effect). See “Sync Pipe” command set forth in

FIGS. 46-118

.




EXAMPLE DISPLAY PROCESSOR


500


ARCHITECTURE





FIG. 20

shows an example architecture of display processor


500


. In this example, display processor


500


includes a command unit


514


with associated RAM


516


and DMA controller


518


; an “edge walker”/rasterizer


504


; a RGBAZ pixel stepper


520


; a color combiner/level interpreter


508


, a blender/fogger


510


, a ditherer


522


, a coverage evaluator


524


, a depth (z) comparator


526


, a memory interface


512


and a texture unit


506


. In this case, texture unit


506


includes, in addition to texture memory


502


, texture steppers


528


, a texture coordinate unit


530


and a texture filter unit


532


.




Command unit


514


and DMA controller


518


connect to coprocessor main internal bus


214


, and also connect to the signal processor


400


via a private “x” bus


218


. Memory interface


512


is a special memory interface for use by display processor


500


primarily to access to the color framebuffer


118




a


and the z buffer


118




b


stored within main memory


300


(thus, display processor


500


has access to main memory


300


via memory interface


512


and also via coprocessor internal bus


214


).




DMA Controller




DMA controller


518


receives DMA commands from signal processor


400


or main processor


100


over bus


214


. DMA controller


518


has a number of read/write registers shown in

FIGS. 21A-21C

that allow signal processor


400


and/or main processor


100


to specify a start and end address in SP data memory


404


or main memory


300


from which to read a string of graphics display commands (

FIG. 21A

shows a start address register


518


A, and

FIG. 21B

shows an end address register


518


B). DMA controller


518


reads data over main coprocessor bus


214


if registers


518




a


,


518




b


specify a main memory


300


address, and it reads data from the signal processor's data memory


404


over private “x bus”


214


if the registers


518




a


,


518




b


specify a data memory


404


address. DMA controller


518


also includes a further register (register


518


C shown in

FIG. 21C

) that contains the current address DMA controller


518


is reading from. In this example, DMA controller


518


is uni-directional—that is, it can only write from bus


214


into RAM


516


. Thus, DMA controller


518


is used in this example for reading from signal processor


400


or main memory


300


. In this example, display processor


500


obtains data for its texture memory


502


by passing texture load commands to command unit


514


and using memory interface


512


to perform those commands.




Command Unit




Command unit


514


retains much of the current state information pertaining to display processor


500


(e.g., mode and other selections specified by “set commands”), and outputs attributes and command control signals to specify and determine the operation of the rest of display processor


500


. Command unit


514


includes some additional registers that may be accessed by main processor


100


(or signal processor


400


) via coprocessor bus


214


. These additional registers, which are mapped into the address space of main processor


100


, permit the main processor to control and monitor display processor


500


.




For example, command unit


514


includes a status/command register


534


shown in

FIG. 21D

that acts as a status register when read by main processor


100


and acts as a command register when the main processor writes to it. When reading this register


534


, main processor


100


can determine whether display processor


500


is occupied performing a DMA operation reading from signal processor data memory


404


(field


536


(


1


); whether the display processor is stalled waiting for access to main memory


300


(field


536


(


2


); whether the display processor pipeline is being flushed (field


536


(


3


); whether the display processor graphics clock is started (field


536


(


4


); whether texture memory


502


is busy (field


536


(


5


); whether the display processor pipeline is busy (field


536


(


6


); whether command unit


514


is busy (field


536


(


7


); whether the command buffer RAM


516


is ready to accept new inputs (field


536


(


8


); whether DMA controller


518


is busy (field


536


(


9


); and whether the start and end addresses and registers


518




a


and


518




b


respectively valid (fields


536


(


10


),


536


(


11


). When writing to this same register


534


, main processor


100


(or signal processor


400


) can clear an X-bus DMA operation from the signal processor


400


(field


538


(


1


); begin an X-bus DMA operation from signal processor data memory


404


(field


538


(


2


); start or stop the display process (fields


538


(


3


),


538


(


4


); start or stop a pipeline flushing operation (fields


538


(


5


),


538


(


6


); clear a texture memory address counter


540


shown in

FIG. 21H

(field


538


(


7


); clear a pipeline busy counter


542


shown in

FIG. 21F

(field


538


(


8


); clear a command counter


544


used to index command buffer RAM


516


(field


538


(


9


) (the counter


544


is shown in FIG.


21


G); and clear a clock counter


546


(see

FIG. 21E

) used to count clock cycles (field


538


(


10


).




As mentioned above, the clock count, buffer count, pipeline count and texture memory count can all be read directly from registers


540


-


546


(see FIGS.


21


E-


21


H). In addition, main processor


100


or signal processor


400


can read and control the BIST operation pertaining to texture memory


502


(see BIST status/control register


548


shown in FIG.


211


), and can also enable and control testing of memory interface


512


by manipulating mem span test registers


549


(


a


),


549


(


b


) and


549


(


c


) shown in FIG.


21


J.




Referring back to

FIG. 20

, once one or more commands have been loaded into command unit buffer ram


518


and display processor


500


has been started, command unit


514


begins reading and processing each command sequentially. The repertoire of commands display processor


500


understands are set forth in

FIGS. 46-118

. Hardware (e.g., logic, gate arrays and the like) within display processor


500


directly interpret the graphics display commands within RAM


516


. In this example, display processor


500


has no ability to branch or jump in traversing this list of commands. Rather, display processor


500


in this example is a sequential state machine that accepts each new command as an input in strict sequence and alters its states and outputs in response to the command.




Display processor


500


halts if its command buffer RAM


516


is empty (i.e., it has processed all of the commands in the buffer, which buffer acts as a FIFO). Main processor


100


or signal processor


400


can determine if display processor


500


has halted by reading display processor status register


534


and may, if desired, pass the display processor a command that stalls the display processor temporarily (see “Sync Full” command in FIGS.


46


-


118


).




Edgewalker and Steppers




Edgewalker


504


shown in

FIG. 20

performs the rasterize process


550


shown in FIG.


18


. In this example, edgewalker


504


receives the edge coefficients, shade coefficients, texture coefficients and z buffer coefficients specified in a “triangle command” (see

FIGS. 46-118

specifying a particular primitive open line, triangle or rectangle), and outputs “span” values from which the following attributes for each pixel enclosed within the primitive can be derived:




screen x, y location




z depth for z buffer purposes




RGBA color information




s/w, t, w, 1/w texture coordinates, level-of-detail for texture index, perspective correction, and mipmapping (these are commonly referred to s, t, w, 1)




coverage value (pixels on the edge of a primitive have partial coverage values, whereas pixels within the interior of a primitive are full).




Edgewalker


504


sends the parameters for a line of pixels across the primitive (a “span”) to the pipeline hardware downstream for other computations. In particular, texture steppers


528


and RGBAZ steppers


520


receive the “span” information specified by edgewalker


504


, and step sequentially along each pixel in the horizontal line (in the view plane coordinate system) of the “span” to derive the individual texture coordinates and RGBAZ values for each individual pixel in the span.




The RGBAZ stepper


520


may also perform a “scissoring” operation on triangle primitives (this does not work for rectangles in this example) to efficiently eliminate portions of triangle primitives extending outside of a view plane scissoring rectangle. Scissoring is commonly used to eliminate running performance-intensive clipping operations on signal processor


400


. Scissoring is similar in concept to clipping, but whereas clipping is performed in the 3-D coordinate system, scissoring is performed in the 2-D coordinate system of the viewing plane. Scissoring by steppers


520


,


528


is invoked by sending display processor


500


a “set scissor” command (see FIGS.


46


-


118


).




As mentioned above, steppers


520


produces color and alpha information for each pixel within the “span” defined by edgewalker


504


. Similarly, texture steppers


528


produces texture coordinate values (s, t, w) for each pixel within the span. Steppers


520


,


528


operate in a synchronized fashion so that texture unit


506


outputs a mapped texture value for a pixel to color combiner


58


at the same time that the RGBAZ steppers


520


output a color value for the same pixel based on primitive color, shading, lighting, etc.




Texture Unit




Texture unit


506


in this example takes the texture coordinates s, t, w and level-of-detail values for a pixel (as mentioned above, texture steppers


528


derive these values for each individual pixel based upon “span” information provided by edgewalker


504


), and fetches appropriate texture information from onboard texture memory


502


for mapping onto the pixel. In this example, the four nearest texels to the screen pixel are fetched from texture memory


502


, and these four texel values are used for mapping purposes. Video game program


108


can manipulate texture states such as texture image types and formats, how and where to load texture images, and texture sampling attributes.




Texture coordinate unit


530


computes appropriate texture coordinates for mapping texture stored within texture memory


502


onto the primitive being rendered. Since the 2-dimensional textures stored in texture memory


502


are square or rectangular images that must be mapped onto triangles of various sizes, the texture coordinate in


530


must select appropriate texels within the texture to map onto pixels in the primitive to avoid distorting the texture. See


OpenGL Programming Guide


at


278


.




Texture coordinate unit


530


computes a mapping between the inputted pixel texture coordinates and four texels within the appropriate texture stored in texture memory


502


. Texture coordinate unit


530


then addresses the texture memory


502


appropriately to retrieve these four texels. The four texel values are passed to the texture filter unit


532


. Texture filter


532


takes the four texels retrieved from texture memory


502


and produces a simple bilinear-filtered texel. Texture filter


532


in this example can perform three types of filter operations: point sampling, box filtering, and bilinear interpolation. Point sampling selects the nearest texel to the screen pixel. In the special case where the screen pixel is always the center of four texels, the box filter can be used. In the case of the typical 3-D, arbitrarily rotated polygon, bilinear filtering is generally the best choice available. For hardware cost reduction, display processor texture filter unit


532


does not implement a true bilinear filter. Instead, it linearly interpolates the three nearest texels to produce the result pixels. This has a natural triangulation bias which is not noticeable in normal texture images but may be noticed in regular pattern images. This artifact can be eliminated by prefiltering the texture image with a wider filter. The type of filtering performed by texture filter unit


532


is set using parameters in the “set modes” display command (see FIGS.


46


-


118


).




TEXTURE MEMORY


502






Display processor


500


treats texture memory


502


as a general-purpose texture memory. In this example, texture memory


502


is divided into four simultaneously accessible banks, giving output of four texels per clock cycle. Video game program


58


can load varying-sized textures with different formats anywhere in the texture memory


502


. Texture coordinate unit


530


maintains eight texture tile descriptors that describe the location of texture images within texture memory


502


, the format of each texture, and its sampling parameters. This allows display processor


500


to access as many as eight different texture tiles at a time (more than eight texture tiles can be loaded into the texture memory, but only eight tiles are accessible at any time).





FIG. 22

shows an example of the texture tile descriptors and their relationship to texture tiles stored in texture memory


502


. In this particular example shown in

FIG. 22

, eight different texture tiles


802


are stored within texture memory


502


. Each texture tile


802


has an associated texture tile descriptor block


804


(as discussed above, display processor


500


maintains up to eight descriptors


804


corresponding to eight texture tiles stored within texture memory


502


). The texture descriptors contain information specified by a “set tile” command (see FIGS.


46


-


118


). For example, these texture tile descriptors specify the image data format (RGBA, YUV, color index mode, etc.), the size of each pixel/texel color element (four, eight, sixteen, thirty-two bits), the size of the tile line in 64-bit words, the starting address of the tile in texture memory


502


, a palette number for 4-bit color indexed texels, clamp and mirror enables for each of the S and T directions, masks for wrapping/mirroring in each of S and T directions, level of detail shifts for each of S and T addresses. These descriptors


804


are used by texture coordinate unit


530


to calculate addresses of texels within the texture memory


502


.




Texture Coordinate Unit





FIG. 23

shows a more detailed example of the processing performed by texture coordinate unit


530


.

FIG. 23

shows the various tile descriptors


804


being applied as inputs to texture coordinate unit


530


.

FIG. 23

also shows that texture coordinate unit


530


receives the primitive tile/level/texture coordinates for the current pixel from texture steppers


528


. Texture coordinate unit


530


additionally receives mode control signals from command unit


514


based, for example, on the “set other mode” and “set texture image” commands (see FIGS.


46


-


118


). Based on all of this input information, texture coordinate unit


530


calculates which tile descriptor


804


to use for this primitive, and converts the inputted texture image coordinates to tile-relative coordinates which the texture coordinate unit wraps, mirrors and/or clamps as specified by the tile descriptor


804


. Texture coordinate unit


530


then generates an offset into texture memory


502


based on these tile coordinates. The texture coordinate unit


530


in this example can address 2×2 regions of texels in one or two cycle mode, or 4×1 regions in copy mode. Texture coordinate unit


530


also generates S/T/L fraction values that are used to bi-linearly or tri-linearly interpolate the texels.





FIG. 24

is a detailed diagram of texture coordinate unit


530


and texture memory unit


502


. As shown in

FIG. 24

, the incoming s, t, w texture coordinates are inputted into a perspective correction block


566


which provides a perspective correction based on w when perspective correction is enabled. The perspective-corrected s, t values are then provided to a level-of-detail or precision shift block


568


which shifts the texture coordinates after perspective divide (e.g., for MIP mapping and possibly for precision reasons). A block


570


then converts the shifted texture coordinates to tile coordinates, providing fractional values to the texture filter unit


532


. These tile coordinate values are then clamped, wrapped and/or mirrored by block


572


based on the current texture mode parameters of display processor


500


. Meanwhile, the perspective-corrected texture coordinates provided by perspective correction block


566


are also provided to a level of detail block


574


which, when level of detail calculations are enabled, calculates a tile descriptor index into a tile descriptor memory


576


and also calculates a level of detail fractional value for interpolation by the color combiner


508


. The tile descriptors


804


are stored in tile descriptor memory


576


, and are retrieved and outputted to a memory conversion block


578


which conversion block also receives the adjusted texture coordinate values of block


572


. Address conversion block


578


converts the adjusted texture coordinate values into texture memory unit addresses based on current tile size, format and other parameters as specified by the tile descriptor


804


. Address conversion block


578


outputs the texel address to texture memory unit


502


. The texture memory unit


502


also receives additional parameters which are used, for example, if the texture is color indexed. Texture memory unit


502


outputs four texel values to texture filter unit


532


for filtering as discussed above.




Texture Memory Loading




Texture memory unit


502


includes a four kilobyte random access memory onboard coprocessor


200


. Because texturing requires a large amount of random accesses with consistent access time, it is impractical to texture directly from main memory


300


in this example. The approach taken is to cache up to four kilobytes of an image in on-chip, high-speed texture memory


502


. All primitives can be textured using the contents of texture memory


502


.




In order to use texture memory


502


, video game program


108


must load a texture tile into the texture memory and then load the associated descriptor


804


into tile descriptor


576


. The “load tile” command (see

FIGS. 46-118

) is used to load a tile into texture memory


502


, and a “set tile” and “set tile size” command are used to load corresponding tile descriptor blocks


804


into tile descriptor memory


576


. In addition, a “Load Tlut” command (see

FIGS. 46-118

) can be used to load a color lookup table into texture memory


502


for use by color indexed textures.




Physically, texture memory


502


is organized in four banks, each comprising


256


16-bit wide words, each bank having a low half and a high half. This organization can be used to store 4-bit textures (twenty texels per row), 8-bit textures (ten texels per row), 16-bit textures (six texels per row), 16-bit YUV textures (twelve texels per row), and 32-bit textures (six texels per row). In addition, texture unit


506


in this example supports a color-indexed texture mode in which the high half of texture memory


502


is used to store a color lookup table and the low half of the texture memory is used to store 4-bit or 8-bit color indexed textures. This organization is shown in FIG.


25


. In this

FIG. 25

example, a color indexed texture tile


580


is stored in a low half


502


(L) of texture memory


502


, and a corresponding color lookup table


582


is stored in the upper half


502


(H) of the texture memory.





FIG. 26

shows a more detailed depiction of a particular texture memory color indexed mode, in which the color lookup table


582


is divided into four palette banks


584


or tables, each having, for example, sixteen entries, each entry being 16-bits wide. The color lookup table may represent color in 16-bit RGBA format, or in 16-bit IA format. Since four texels are addressed simultaneously, there are four (usually identical) lookup tables


484


stored in the upper half of texture memory


502


. As mentioned above, these lookup tables are loaded using the “load Tlut” command shown in

FIGS. 46-118

.




Display processor


500


supports another color-indexed texture mode in which each texel in the lower half of texture memory


502


comprises eight bits—and therefore can directly access any one of the


256


locations in the upper half


502


(H) of texture memory


502


. Thus, 8-bit color-indexed textures do not use the palette number of the tile, since they address the whole


256


-element lookup table directly. It is not necessary to use the entire upper half of texture memory


502


for a lookup table when using 8-bit color-indexed textures. For example, if less than eight of the bits of the 8-bit color-indexed texture tile is being used for color lookup, only a portion of color memory upper half


502


(H) is required to store the lookup table—and the remainder of the upper half of the texture memory


502


might thus be used for storing a non-color-indexed texture such as a 4-bit I texture (see FIG.


25


). Similarly, even when color-indexed texture


580


is stored in the lower half


502


(L) of texture memory


502


, it is possible to also store non-color-indexed textures in the lower half as well. Thus, color-indexed textures and non-color-indexed textures can be co-resident in texture memory


502


.




The following texture formats and sizes are supported by texture memory


502


and texture coordinate unit


530


:















Texture Format and Sizes

















Type




4-bit




8-bit




16-bit




32-bit











RGBA






X




X







YUV






X







Color Index




X




X







Intensity Alpha (IA)




X




X




X







Intensity (I)




X




X















In this example, texture unit


506


will, unless explicitly told otherwise, change a tile descriptor


804


or a texture tile


802


immediately upon loading—even if it is still being used for texture mapping of a previous primitive. Texture loads after primitive rendering should be preceded by a “sync load” command and tile descriptor attribute changes should be preceded by a “sync tile” command to ensure that the texture tile and tile descriptor state of texture unit


506


does not change before the last primitive is completely finished processing (see

FIGS. 46-118

for example formats and functions of these commands).




As mentioned above in connection with the signal processor


400


, two special commands (“texture rectangle” and “texture rectangle flip”) can be used to map a texture onto a rectangle primitive (see FIGS.


46


-


118


). It is possible to use the “texture rectangle” command to copy an image from texture memory


502


into frame buffer


118


, for example. See

FIGS. 46-118

.




COLOR COMBINER




Referring once again to

FIG. 20

, color combiner


508


combines texels outputted by texture unit


506


with stepped RGBA pixel values outputted by RGBAZ steppers


520


. Color combiner


508


can take two color values from many sources and




newcolor=(A−B)*C+D




linearly interpolate between them. The color combiner


508


performs the equation:




Here, A, B, C and D can come from many different sources (note that if D=B, then color combiner


508


performs simple linear interpolation).





FIG. 27

shows possible input selection of a general purpose linear interpolator color combiner


508


for RGB and Alpha color combination in this example. As can be seen in

FIG. 27

, only some of the inputs in the lefthand column come from texture unit


506


or RBGAZ steppers


520


. The rest of the inputs are derived from color combiner


508


internal state that can be programmed by sending commands to display processor


500


. As discussed above, the “combined color” and “combined Alpha” values provided to color combiner


508


are obtained from the RGBAZ steppers


520


, and the texel color and texture Alpha are obtained from texture unit


506


(two texel colors and corresponding Alpha values are shown since in two-cycle-per-pixel mode two texels will be provided by texture unit


506


for purposes of mipmapping for example). Additionally, the level of detail fractional input is obtained from

FIG. 24

block


574


, and the primitive level of detail value along with the primitive color and primitive Alpha value may be obtained from a “set primitive color” command sent to display processor


500


(see

FIGS. 46-118

) (the primitive color value/alpha/level of detail fraction value can be used to set a constant polygon face color). Similarly, a shade color and associated Alpha value may be obtained from a “shade coefficient” command (see FIGS.


46


-


118


), and an environment color and associated Alpha value may be obtained from a “set environment color” command (see

FIGS. 46-118

) (the environment color/alpha value described above can be used to represent the ambient color of the environment). Two kinds of “set key” commands (one for green/blue, the other for red) are used for green/blue color keying and red color keying respectively—these supplying the appropriate key:center and key:scale inputs to color combiner


508


(see FIGS.


46


-


118


). Both the primitive and environment values are programmable and thus can be used as general linear interpolation sources.




Convert K


4


and K


5


Inputs to color combiner


508


are specified in this example by the “set convert” command (see

FIGS. 46-118

) that adjust red color coordinates after conversion of texel values from YUV to RGB format (the remainder of the conversion process responsive to this set convert command being performed within texture filter unit


532


).





FIG. 28

shows a portion of color combiner


508


used for combining the alpha values shown as inputs in FIG.


27


. For both the RGB color combine in alpha color combine operations performed by color combiner


508


, there are two modes, one for each of the two possible pipeline modes one cycle-per-pixel, and two cycles-per-pixel). In the two-cycle mode, color combiner


508


can perform two linear interpolation arithmetic computations. Typically, the second cycle is used to perform texture and shading color modulation (i.e., the operations color combiner


508


are typically used for exclusively in the one-cycle mode), and the first cycle can be used for another linear interpolation calculation (e.g., level of detail interpolation between two bi-linear filtered texels from two mipmap tiles). Color combiner


508


also performs the “alpha fix-up” operation shown in

FIG. 29

in this example (see “set key GB” command in FIGS.


46


-


118


).




Blender




As discussed above, blender


510


takes the combined pixel value provided by color combiner


508


can blends them against the frame buffer


118


pixels. Transparency is accomplished by blending against the frame buffer color pixels. Polygon edge antialias is performed, in part, by blender


510


using conditional color blending based on depth (z) range. The blender


510


can also perform fog operations in two-cycle mode.




Blender


510


can perform different conditional color-blending and z buffer updating, and therefore can handle all of the various types of surfaces shown in

FIG. 30

(i.e., opaque surfaces, decal surfaces, transparent surfaces, and inter-penetrating surfaces).




An important feature of blender


510


is its participation in the antialias process. Blender


510


conditionally blends or writes pixels into frame buffer


118


A based on depth range (see

FIG. 33

which shows example z buffer formats including a “dz” depth-range field). See U.S. patent application Ser. No. 08/562,283 of Akeley et al, entitled “System and Method For Merging Pixel Fragments Based On Depth Range Values”, filed concurrently herewith.




In this example, video interface


210


applies a spatial filter at frame buffer read-out time to account for surrounding background colors to produce antialias silhouette edges. The antialiasing scheme requires ordered rendering sorted by surface or line types. Here is the rendering order and surface/line types for z buffer antialiasing mode:




1. All opaque surfaces are rendered.




2. All opaque decal surfaces are rendered.




3. All opaque interpenetrating surfaces are rendered.




4. All of the translucent surface and lines are rendered last.




These can be rendered in any order, but proper depth order gives proper transparency.




The mode blender


510


is controlled, in part by the groups of coefficients specified in the triangle command defining the primitive (see FIGS.


46


-


118


). Thus, a primitive can be rendered in a z buffered mode or non-z buffered mode as specified by the triangle command. In addition, the “set other modes” command (see

FIGS. 46-118

) specifies blend mode words for cycle 0 and cycle 1 in addition to specifying “blend masks” and enabling/disabling antialiasing.




Blender


510


has two internal color registers: fog color and blend color. These values are programmable using the “set fog color” and “set blend color” commands, respectively (see FIGS.


46


-


118


). These values can be used for geometry with constant fog or transparency.




Blender


510


can compare the incoming pixel alpha value with a programmable alpha source to conditionally update frame buffer


118


A. This feature can allow complex, outlined, billboard type objects, for example. Besides thresholding against a value, blender


510


in this example can also compare against a dithered value to give a randomized particle effect. See “set other modes” command (FIGS.


46


-


118


). Blender


510


can also perform fog operations, either in 1-cycle or 2-cycle mode. Blender


510


uses the stepped z value as a fog coefficient for fog and pipeline color blending.





FIG. 31

shows an example of the overall operations performed by blender


510


in this example. In this particular example, blender


510


can be operated in a mode in which a coverage value produced by coverage evaluator


524


can be used to specify the amount of blending. Coverage evaluator


524


compares the coverage value of the current pixel (provided by edge walker


504


) to stored coverage value within frame buffer


118


A. As shown in

FIG. 32

(a depiction of the format of the color information stored for each pixel within color frame buffer


118


A), the color of a pixel is represented by 5-bits each of red, green, and blue data and by a 3-bit “coverage” value. This “coverage” value can be used as-is, or multiplied by an alpha value for use as pixel alpha and/or coverage (see “set other modes” command in FIGS.


46


-


118


).




The “coverage” value nominally specifies how much of a pixel is covered by a particular surface. Thus, the coverage value outputted by edge walker


504


will be 1 for pixels lying entirely within the interior of a primitive, and some value less than 1 for pixels on the edge of the primitive. In this example, blender


510


uses the coverage value for antialiasing. At the time blender


510


blends a primitive edge, it does not know whether the primitive edge is internal to an object formed from multiple primitives or whether the edge is at the outer edge of a represented object. To solve this problem in this example, final blending of opaque edge values is postponed until display time, when the video interface


210


reads out frame buffer


118


A for display purposes. Video interface


210


uses this coverage value to interpolate between the pixel color and the colors of neighboring pixels in the frame buffer


118


A. In order to accomplish this antialiasing at display time, blender


510


must maintain the coverage value for each pixel within frame buffer


118




a


, thereby allowing video interface


210


to later determine whether a particular pixel is a silhouette edge or an internal edge of a multi-polygon object.




Memory Interface


512


and Z Buffering




Memory interface


512


provides an interface between display processor


500


and main memory


300


. Memory interface


512


is primarily used during normal display processor


500


operations to access the color frame buffer


118




a


and the Z buffer


118




b


. Color frame buffer


118




a


stores a color value for each pixel on color television screen


60


. The pixel format is shown in

FIG. 32. Z

buffer


118




b


stores a depth value and a depth range value for each color pixel value stored in color frame buffer


118




a


. An example format for z buffer values is shown in FIG.


33


. The Z buffer


118




b


is used primarily by blender


510


to determine whether a newly rendered primitive is in front of or behind a previously rendered primitive (thereby providing hidden surface removal). The “DZ” depth range value shown in

FIG. 33

may be used to help ascertain whether adjacent texels are part of the same object surface.




Memory interface


512


can write to main memory


300


, read from main memory, or read, modify and write (RMW) locations in the main memory. For RMW operations, memory interface


512


, in this example, pre-fetches a row of pixels from frame buffer


118




a


as soon as edge walker


504


determines the x, y coordinates of the span. Memory interface


512


includes an internal “span buffer”


512




a


used to store this span or row of pixels. Memory interface


512


provides the appropriate pre-fetched pixel value from span buffer


510




a


to blender


510


at the appropriate time—thus minimizing the number of accesses to main memory


300


. Span buffer


512




a


is also used to temporarily store blended (modified) pixel values so that display processor


500


need not access main memory


300


each time a new pixel value is blended. In general, memory interface


512


writes the entire span worth of pixels into main memory


300


as a block all at once.




Memory interface


512


has enough on-chip RAM to hold several span buffers. This can cause problems, however, if two spans in sequence happen to overlap the same screen area. A parameter “atomic space” in the “Set Other Modes” command (see

FIGS. 46-118

) forces memory interface


512


to write one primitive to frame buffer


118




a


before starting the next primitive—thereby avoiding this potential problem by adding no cycles after the last span of a primitive is rendered.




Depth comparator


526


operates in conjunction with z buffer


118




b


to remove hidden surfaces and to insure the transparent values are blended properly. Depth comparator


526


compares the z or depth value of the current pixel with the z value currently residing in z buffer


118




a


for that screen location. At the beginning of the rendering of a new frame, all locations in z buffer


118




b


are preferably initialized to maximum distance from the viewer (thus, any object will be open “in front of” this initialized value). Generally, each time display processor


500


is to blend a new pixel into frame buffer


118




a


, depth comparator


526


compares the depth of the current pixel with the depth residing in that location of z buffer


118




b


. If the old z buffer value indicates that the previously written pixel is “closer” to the viewer than is the new pixel, the new pixel is discarded (at least for opaque values) and is not written into the frame buffer—thus accomplishing hidden surface removal. If the new pixel is “closer” to the old pixel as indicated by depth comparator


526


, then the new pixel value (at least for opaque pixels) may replace the old pixel value in frame buffer


118




a


—and the corresponding value in z buffer


118




b


is similarly updated with the z location of the new pixel (see FIG.


33


A). Transparency blending may be accomplished by blending without updating the z buffer value—but nevertheless reading it first and not blending if the transparent pixel is “behind” an opaque pixel.




Video Interface


210






Video interface


210


reads the data out of frame buffer


118


and generates the composite, S video RGB video output signals. In this example, video interface


210


also performs anti-aliasing operations, and may also perform filtering to remove truncation caused by the introduction of dithering noise.




Video interface


210


in this example works in either NTSC or PAL mode, and can display 15-bit or a 24-bit color pixels with or without filtering at both high and low resolutions. The video interface


210


can also scale up a smaller image to fill the screen. The video interface


210


provides


28


different video modes plus additional special features.




Video interface


210


reads color frame buffer


118




a


in synchronization with the electron beam scanning the color television screen


60


, and provides RGB values for each pixel in digital form to video DAC


144


for conversion into analog video levels in this example. Video interface


210


performs a blending function for opacity values based on coverage (thereby providing an antialiasing function), and also performs a back-filtering operation to remove some of the noise introduced by screen-based dithering.





FIG. 34

is a block diagram of the architecture of video interface


210


. In this example, video interface


210


includes the DMA controller


900


, a buffer


902


, control logic


904


, anti-aliasing filters


906




a


,


906




b


, error correction blocks


908




a


,


908




b


, vertical interpolator (filter)


910


, horizontal interpolator (filter)


912


, “random” function generator


914


, gamma block


916


, and bus driver


918


.




DMA controller


900


is connected coprocessor bus


214


. DMA controller


900


reads color frame buffer


118




a


beginning at an “origin” address in the main memory specified by main process


100


(see FIG.


35


B). DMA controller


900


sequentially reads the pixel color and coverage values (see

FIG. 32

) from frame buffer


118




a


in synchronism with the line scanning operations of television


58


. The pixel values read by DMA controller


900


are processed by the remainder of video interface


210


and are outputted to video DAC


144


for conversion into an analog composite video signal NTSC or PAL format in this example.




DMA controller


900


in this example provides the color/coverage values it has read from main memory frame buffer


118




a


, to a RAM buffer


902


for temporary storage. In this example, buffer


902


does not store the pixel color values corresponding to an entire line of television video. Instead, buffer


902


stores a plurality of blocks of pixel data, each block corresponding to a portion of a line of video. Buffer


902


provides “double buffering,” i.e., it has sufficient buffers to make some line portions available to filters


906


while other buffers are being written by DMA controller


900


.




In this example, DMA controller


900


accesses, and stores into buffers


902


, several of the pixel data corresponding to several horizontally-aligned portions of the video lines to be displayed on television screen


60


. Looking at

FIG. 34A

, frame buffer


118




a


is shown—for purposes of illustration—as being organized in a row/column order corresponding to pixels on the television screen (it will be understood that the frame buffer as stored in main memory


300


may actually be stored as a long sequential list of pixel color/coverage values). In this example, DMA controller


900


reads out a block of pixel values corresponding to a particular segment of the current line n of video to be displayed (top shaded block in

FIG. 34A

frame buffer


118




a


), and also reads out the pixel values corresponding to a horizontally-aligned (on the television screen) line segment of a “next” video line n+1 (i.e., the part of the pixel data representing the part of the “next” line just beneath the line n). In this particular example, also reads a further block of pixel values from the frame buffer corresponding to the horizontally-aligned line segment of video line n+2.




Each of these blocks of pixel values is stored in buffer


902


. Filters


906




a


,


906




b


perform a filtering/anti-aliasing operation based on coverage value to interpolate the current line's pixel values with neighboring pixel values (i.e., pixel values that are adjacent with respect to the displayed position on color television screen


60


). The anti-aliasing filtering operations performed by filters


906




a


,


906




b


are as described in co-pending U.S. patent application Ser. No. 08/539,956 of Van Hook et al, entitled “Antialiasing of Silhouette Edges” filed on Oct. 6, 1995. Briefly, a three-scan-line high neighborhood is color weighted by coverage value in a blending process performed by filter


906


. This filtering operation results in smoother, less jagged lines at surface edges by using the pixel coverage value retained in frame buffer


118




a


(which coverage value indicates what percentage of the pixel is covered by a polygon) to adjust the contribution of that pixel value relative to the contributions of neighboring pixel values in a blending process to produce the current pixel value. “Divot” error correction blocks


908




a


,


908




b


correct the outputs of anti-alias filters


906




a


,


906




b


for slight artifacts introduced by the anti-aliasing process. In particular, for any pixels on or adjacent to a silhouette edge, the error correction blocks


908


take the median of three adjacent pixels as the color to be displayed in place of the center pixel. This error correction can be enabled or disabled under software control (see FIG.


35


A), and a video game programmer may wish to disable the error correction since it interacts poorly with decal line rendering modes.




Anti-aliasing filters


906




a


,


906




b


operate in parallel in this example to produce pixel data blocks corresponding to horizontally aligned portions of two successive lines (line n, line n+1) of the image represented by frame buffer


118




a


. These pixel values are provided to vertical interpolator


910


, which performs a linear interpolation between the two image lines to produce an image portion of a single scan line (see FIG.


34


A). Interpolator


910


interpolates between successive scan lines in order to reduce flicker in interlaced displays. For example, interpolator


910


can add in a contribution from a previous or next successive horizontally-aligned scan line portion to make transitions between successive video scan lines less noticeable—thereby reducing flicker.




Additionally, interpolator


910


in this example can perform a vertical scaling function that allows the number of lines displayed on television screen


60


to be different from the number of lines represented by the frame buffer


118




a


pixel information. In this example, filter


906


scales in the vertical dimension by resampling the pixel data for successive lines of image represented by frame buffer


118




a


—thereby allowing television screen


60


to have a different number of lines. This scaling operation (which also accommodates offsetting) is controlled by the values within the video interface Y scale register (see FIG.


35


N). The ability to scale the television image relative to the digital image size of frame buffer


118




a


provides additional flexibility. For example, the scaling ability makes it possible for signal processor


400


and display processor


500


to generate a smaller digital image representation in frame buffer


118


—and yet allow that smaller image to fill the entire television screen


60


. Since a smaller frame buffer


118


requires less time to rasterize (i.e., display processor


500


needs to handle fewer spans and fewer pixels per span for a given polygon) and less memory to store, the scaling ability can provide increased performance—albeit at the cost of a lower resolution image.




The output of vertical filter


910


in this example is a block of pixel data representing the pixel values for a portion of the video line to be displayed. As shown in

FIG. 34A

, this block of pixel values is provided to horizontal interpolator


912


. Horizontal interpolator


912


provides a linear interpolation between neighboring pixel values in order to resample the pixels based on a horizontal scaling factor stored in the X scale register (see FIG.


35


M). Horizontal interpolator


112


thus provides a horizontal scaling ability, e.g., to convert a smaller number of frame buffer values into a larger number of screen pixels along a horizontal line.




The output of horizontal interpolator


912


is provided to a Gamma correction circuit


916


that converts linear RGB intensity into non-linear intensity values suitable for composite video generation for the gamma non-linearity of TV monitors. This amounts to taking a square root of the linear color space. The TV monitor effectively raises these color values to a power of 2.2 or 2.4. A “random” function block


914


introduces additional bits of resolution to each of the R, G and B color values in order to “de-dither” (i.e., to compensate for the bit truncation performed by display processor dithering block


522


). As shown in

FIG. 32

, one example frame buffer


118


color pixel format in this example provides only five bits of resolution of each R, G and B to conserve storage space within main memory


300


. Display processor dithering block


522


may truncate 8-bit RGB color values provided by blender


510


to provide the compressed representation shown in FIG.


32


. Block


914


can reverse this truncation process to decompress the RGB values to provide


256


different display color levels for each R, G and B. See U.S. application Ser. No. 08/561,584, filed on Nov. 21, 1995 in the name of Gossett, entitled “Restoration Filter For Truncated Pixels,”. This dither filter operation can be turned on and off under software control (see FIG.


35


A).




Example Video Interface Registers




There are sixteen control registers for the video interface


210


which control all its functions including sync generation, video resealing, and anti-aliasing.

FIGS. 35A-35P

show the various registers within video interface


210


the can be accessed by main processor


100


.





FIG. 35



a


shows the video interface control register


952


. Main processor


100


can write the following values into this register


952


to control the operation of video interface


210


:




Type field


952




a


specifies pixel data size as blank (no data, no sync), the format shown in

FIG. 32

(5 bits each of RGB and a 3-bit coverage value), or 8/8/8/8 (32-bit color value and 8 bits of coverage);




Gamma dither enable field


952




b


turns on and off the addition of some random noise to the least significant bits of the video out before the final quantization to 7 bits to eliminate Mach banding artifacts;




Gamma enable field


952




c


turns on and off gamma correction;




Divot enable field


952




d


turns on and off the divot error correction discussed above;




video bus clock enable field


952




e


turns an internal clock on or off;




Interlace field


952




f


turns interlacing on and off;




Test mode field


952




g;






anti-alias mode on/off field


952




h;






diagnostic field


952




i;






pixel advance field


952




j


; and




dither filter enable field


952




k.







FIG. 35B

shows the video interface origin register


954


used to specify the beginning main memory


300


address of frame buffer


118




a


for read out. In this example, main processor


100


needs to explicitly set this register


954


each time video interface


210


is to read from a new area in main memory


300


(e.g., to read the other half of double buffered frame buffer


118


).





FIG. 35



c


shows the video interface line width register


956


, which can be set to specify the number of pixels in each horizontal line.

FIG. 35



d


shows the video interface vertical interrupt register


958


, which main processor


100


can set with a particular vertical line number so that coprocessor


200


will interrupt the main processor once per frame at the specified vertical line or half line.

FIG. 35



e


shows the video interface current line register


960


, which specifies the current vertical line when read from by the main processor


100


and clears the vertical line interrupt when written to by the main processor.




The registers


962


-


972


shown in

FIGS. 35G-35L

are used by main processor to specify detailed composite video timing parameters. For example:





FIG. 35F

shows the vertical interface timing register


962


which main processor


100


can write to to specify horizontal sync pulse width, color burst width, vertical sync pulse width, and color burst start timing.





FIG. 35G

shows the video interface vertical sync register


964


that main processor


100


may write to specify the number of vertical half-lines per field.





FIG. 35H

shows the video interface horizontal sync register


965


which main processor


100


can write to specify the total duration of a line and a horizontal “leap pattern” for PAL.





FIG. 35I

shows the video interface h sync leap register


966


specifying two alternate h sync leap parameters for PAL.




The video interface horizontal video register and vertical video register


968


,


970


shown in

FIGS. 35



j


,


35




k


, respectively, are used to specify horizontal and vertical video start and end times relative to hsync and vsync.




The vertical interfaced vertical burst register


972


shown in

FIG. 35L

specifies color burst start and end timing.




The timing parameters programmable into registers


962


-


972


can be used to provide compatibility with different kinds of television sets


58


. For example, most television sets


58


in the United States use a composite video format known as NTSC, whereas most European television sets use a composite video format known as PAL. These formats differ in terms of their detailed timing parameters (e.g., vertical blanking integral width and location within the signal pattern, horizontal synchronization pulse width, color burst signal pulse width, etc.). Because registers


962


-


972


control these composite video timing parameters and are programmable by software executing on main processor


100


, a programmer of video game


108


can make her program NTSC compatible, PAL compatible, or both (as selected by a user) by including appropriate instructions within the video game program that write appropriate values to registers


962


-


972


. Thus, in this example, coprocessor


200


is compatible with NTSC-standard television sets


58


, with PAL standard compatible television sets—and even with video formats other than these within a range as specified by the contents of registers


962


-


972


.




Vertical interface x and y scale registers


974


,


976


(see

FIG. 35



m


,


35




n


, respectively) specify x and y scale up and subpixel offset parameters for horizontal and vertical scaling, as discussed above.

FIGS. 35



o


and


35




p


show video interface test data and address registers


978


,


980


for diagnostic purposes.




Memory Controller/Interface


212






As explained above, coprocessor memory interface


212


interfaces main memory


300


with coprocessor internal bus


214


. In this example, main memory


300


is accessed over a 9-bit wide bus, and one of the tasks memory interface


212


is responsible for is to buffer successive 9-bit words so they can be more conveniently handled by coprocessor


200


.

FIG. 36

is an example diagram showing the overall architecture of memory controller/interface


212






In this example, memory interface/controller


212


includes a pair of registers/buffers


1000


,


1002


, a control block


1004


, and a RAM controller block


212




b


. RAM controller block


212




b


comprise RAM control circuits designed and specified by Rambus Inc. for controlling main memory


300


. Registers


1000


,


1002


are used to latch outgoing and incoming data, respectively. Control block


1004


controls the operation of memory interface


212


.




Example Memory Controller/Interface Registers





FIGS. 37A-37H

show example control registers used by main processor


100


to control memory interface


212


.

FIG. 37A

shows a read/write mode register specifying operating mode and whether transmit or receive is active (


1052


).

FIG. 37B

shows a configuration register


1054


that specifies current control input and current control enable.

FIG. 37C

represents a current mode register


1056


that is write only, with any writes to this register updating the current control register.

FIG. 37D

shows a select register


1058


used to select receive or transmit.

FIG. 37E

shows a latency register


1060


used to specify DMA latency/overlap.

FIG. 37F

shows a refresh register


1062


that specifies clean and dirty refresh delay, indicates the current refresh bank, indicates whether refresh is enabled, indicates whether refresh is optimized, and includes a field specifying refresh multi-bank device.

FIG. 37G

shows an error register which in a read mode indicates NACK, ACK and over-range errors, and when written to by main processor


100


clears all error bits.

FIG. 37H

shows a bank status register


1066


which, when read from indicates valid and dirty bits of the current bank, and when written to clears valid and sets dirty bits of the current bank.




CPU Interface





FIG. 38

shows a block diagram of coprocessor CPU interface


202


in this example. CPU interface


202


comprises a FIFO buffer


1102


and a control block


1104


. FIFO buffer


1102


provides bidirectional buffering between the CPU SysAD multiplexed address/data bus


102




a


and the coprocessor multiplexed address/data bus


214


D. Control block


1104


receives addresses asserted by the main processor


100


and places them onto the coprocessor address bus


214


C. Control block


1104


also receives interrupt signals from the other parts of coprocessor


200


, and receives command control signals from the main processor


100


via SysCMD bus


102




b.






Example CPU Interface Registers





FIGS. 39A-39D

show the registers contained within CPU interface


303


in this example.

FIG. 39

shows a CPU interface status/control register


1152


that controls coprocessor


200


when main processor


100


writes to the register and indicates overall coprocessor status when the main processor reads from the register. Main processor


100


can write to register


1152


to specify initialization code length, set or clear initialization mode, set or clear internal coprocessor bus test mode, clear display processor


400


interrupt, and set or clear main memory register mode. When main processor


100


reads from this register


1152


, it can determine initialization code length, initialization mode, internal coprocessor bus test mode, and whether the coprocessor is operating in the main memory register mode.





FIG. 39



b


shows a version register


1154


that main processor


100


can read from to determine version information pertaining to various components within coprocessor


200


.





FIG. 39



c


shows an interrupt register


1156


that main processor


100


can read from to determine the source of an interrupt it has received from coprocessor


200


. In this example, a single line connects between coprocessor


200


and main processor


100


is used for interrupt purposes. Upon receiving a coprocessor interrupt, main processor


100


can read interrupt register (which contains an interrupt vector) to ascertain what component within coprocessor


200


(i.e., signal processor


400


, serial interface


204


, audio interface


208


, video interface


210


, parallel interface


206


, or display processor


500


) cause the interrupt.

FIG. 39



d


shows an interrupt mask register


1158


which main processor


100


can write to to set or clear an interrupt mask for any of the interrupts specified in interrupt register


1156


, and may read to determine interrupts are masked and which are not.




AUDIO INTERFACE





FIG. 40

shows an overall block diagram architecture of audio interface


208


in this example. Audio interface


208


includes DMA logic


1200


, a state machine/controller


1202


, an audio clock generator


1204


, audio data buffers


1206


and a serializer


1208


. In this example, DMA logic


1200


fetches digital audio sample data from audio buffer


114


within main memory


300


. DMA logic


1200


writes this audio sample data, 8 bytes at a time, into audio data buffers


1206


. There are multiple audio data buffers


1206


arranged in a FIFO so that DMA logic


1200


can be prefetching some audio sample data while serializer


1208


serializes other, previously fetched-and-buffered audio sample data. Thus, buffers


1206


store enough data to supply serializer


1208


between block reads by DMA logic


1200


. Since the output rate of serializer


1208


is relatively slow (e.g., on the order of 4 bytes at 50 kHz, a single 64-bit buffer


1206




b


can store enough digitized audio samples to last a relatively long time in terms of real time audio output.




As discussed above, serializer converts the parallel contents of audio buffers


1206


into serial format, and places the resulting serial digital audio data stream onto bus


209


for communication to audio DAC


140


. Digital audio bus


209


in this example includes a single serial data line


209




a


multiplexed between left channel data and right channel data. In this example, serializer


1208


outputs a 16-bit long word for each stereo channel, alternating between the channels. The output bit rate of serializer


1208


is specified by audio clock generator


1204


. Audio clock generator


1204


produces an audio clock output on


209




b


to synchronize audio DAC


140


to the serializer


1208


output bit rate, and produces an audio L/R clock on line


209




c


specifying whether the current serializer output


1208


is for the left or right stereo channel.





FIG. 40

shows a number of registers and counters used to control audio interface


208


. DMA controllers


1200


receives a starting main memory address from an address register


1210


. Main processor


100


writes to this address register


1210


(see

FIG. 41A

) to point audio interface


208


to the locations in main memory


300


providing the audio buffer


114


for the current audio to be played. A counter


1212


increments this address for each fetch by DMA controller


1200


—thereby sequencing the DMA controller through the entire audio buffer


114


. Main process


100


writes the length of audio buffer


114


into a transfer length register


1214


(see FIG.


41


B). An additional counter


1216


associated with length register


1214


sequences state machine


1202


through an appropriate number of control states corresponding to the length of audio buffer


114


. State machine


1202


generates control signals that synchronize the operations of the other parts of audio interface


208


relative to one another. In this example, main processor


100


can enable audio interface


208


to begin fetching data from the main memory


300


by writing to a DMA enable register location


1217


(not shown in

FIG. 40

; see FIG.


41


C). Main processor


100


may also determine the state of audio interface


200


by reading an audio interface status register


1218


(not shown in

FIG. 40

; see FIG.


41


D). In this example, state machine


1202


generates a main processor interrupt when it reaches the end of audio buffer


114


as specified by length register


1214


, and the main processor


100


can clear this interrupt by writing to the status register


1218


location (see FIG.


41


D).




In this example, main processor


100


may also control the rate of the clocking signals generated by audio clock generator


1204


. Main processor


100


can program these rates by writing to audio rate registers


1218


,


1220


(see

FIGS. 41E

,


41


F). A counter


1222


may provide a programmable dividing function based on the rate values main processor


100


as written into audio rate registers


1218


,


1220


.




SERIAL INTERFACE





FIG. 42

shows an overall high level block diagram of serial interface


204


in this example.




In this example, serial interface


204


moves blocks of data between coprocessor


200


and serial peripheral interface


138


. Serial interface


204


can either read a 64-byte data block from serial peripheral interface


138


and transfer it to a specified location in main memory


300


or alternatively, it can read a 64-byte block of data stored in the main memory and transfer it serially to the serial peripheral interface. In this example, serial interface


204


comprises primarily direct memory access logic


1300


, control logic


1302


, and a parallel/serial converter


1304


. Parallel/serial converter


1304


in this example comprises a shift register that converts serial data sent by serial peripheral interface


138


over a read data/acknowledge bus


205




a


into parallel data for application to latch


1308


. The contents of latch


1308


is then applied to coprocessor data bus


214




d


for writing into main memory


300


. Alternatively, in a parallel-to-serial conversion mode, shift register


1304


receives parallel data from the coprocessor data bus


214




d


via a latch


1310


and converts that data into serial for transmission to serial peripheral interface


138


via a command and write data bus


205




b.






Main processor


100


specifies the address within main memory


300


that serial interface


204


is to read from or write to, by writing this address into an address register


1312


(see FIG.


43


A). Address register


1312


contents specify the main memory address to be loaded in DMA address counter


1314


. Part of the contents of address register


1312


may also be used to specify “address” information within serial peripheral interface


138


. Such serial peripheral interface “address” information is loaded into a latch


1316


, the contents of which are provided to shift register


1304


for transmission to the serial peripheral interface. This serial peripheral interface “address” information may be used, for example, to specify a location within the serial peripheral interface


138


(i.e., a boot ROM location


158


, a RAM buffer or a status register).




In this example, serial interface


204


has the ability to place the shift register


1304


parallel output onto the coprocessor address bus


214




c


via register


1308


, a multiplexer


1318


, and a latch


1320


.




As shown in

FIGS. 43B

,


43


C, main processor


100


in this example specifies the direction of serial transfer by writing to a location


1322


or


1324


. A write to location


1322


causes serial interface


204


to read a 64-byte data block from the serial peripheral interface


138


and write it to the main memory


300


location specified by address register


1312


. A write by main processor


100


to register location


1324


causes serial interface


204


to read a 64-byte block of data from the main memory


300


location specified by address register


1312


, and to write the data in serial form to the serial peripheral interface


138


.





FIG. 43D

shows the serial interface status register


1326


. Main processor


100


can read status register


1326


to determine the status of serial interface


204


(e.g., whether the serial interface is busy with a DMA or I/O operation (fields


1328


(


1


)


1328


(


2


), respectively); whether there has been a DMA error (field


1328


(


3


); or whether the serial interface has caused a main processor interrupt (field


1328


(


4


)). Serial interface


204


may generate a main processor interrupt each time it has completed a data transfer to/from serial peripheral interface


138


. Main processor


100


can clear the serial interface interrupt by writing to register


1326


.




PARALLEL PERIPHERAL INTERFACE





FIG. 44

shows an example block diagram of parallel peripheral interface


206


. In this example, parallel interface


206


transfers blocks of data between main memory


300


and storage device


54


. Although storage device


54


described above includes only a read-only memory


76


connected to parallel bus


104


, system


50


can accommodate different configurations of peripherals for connection to connector


154


. For example, two different types of peripheral devices (e.g., a ROM and a RAM) may be connected to peripheral connector


154


. Peripheral interface


206


is designed to support communications between two different types of peripheral devices connected to the same parallel bus


104


without requiring any time-consuming reconfiguration between writes.




Some such peripheral devices may be read-only (e.g., ROM


76


), other such peripheral devices may be read/write (e.g., a random access memory or a modem), and still other such peripheral devices could be write only. Peripheral interface


206


supports bidirectional, parallel transfer over parallel bus


104


between connector


154


and main memory


300


.




Parallel peripheral interface


206


in this example includes a DAM controller


1400


, a control/register block


1402


, and a register file


1404


. Register file


1404


buffers blocks of data being transferred by peripheral interface


206


between a peripheral device connected to connector


154


and a block of storage locations within main memory


300


. In this example, register file


1404


comprises a small RAM that stores 16 64-bit words. Register file


1404


operates as a FIFO, and is addressed by control/register block


1402


. The output of register file


1404


is multiplexed into 16-bit portions by multiplexer


1406


. These 16-bit-wide values are latched by a latch


1408


for application to the peripheral device connected to connector


154


via a multiplexed address/data bus


104




ad


. Data read from the peripheral device via the multiplexed address/data bus


104




ad


is temporarily stored in a latch


1410


before being applied (via a multiplexer


1412


that also positions the 16-bit read value within an appropriate quarter of a 64-bit word) into register file


1404


. Multiplexer


1412


also receives data from coprocessor data bus


214




d


via latch


1414


, and can route this received data into register file


1404


for storage. The register file


1404


output can also be coupled to coprocessor data bus


214




d


via latch


1416


. In this example, the register file


1404


output may also be coupled to the coprocessor address bus


214




c


via a multiplexer


1418


and a latch


1420


.




Main processor


100


controls the parameters of a DAM transfer performed by peripheral interface


206


by writing parameters into control/register block


1402


. For example, main processor


100


can write a starting main memory address into a DRAM address register


1422


(see

FIG. 45A

) and can write a starting address space of a peripheral device connected to connector


154


by writing a peripheral bus address starting address into the peripheral bus register


1424


(see FIG.


45


B). In this example, main processor


100


specifies the length and direction of transfer by writing to one of registers


1426


,


1428


shown in

FIGS. 45C

,


45


D, respectively. A write to read length register


1426


shown in

FIG. 45C

controls the peripheral interface


206


to transfer in one direction, whereas writing a length value into register


1428


shown in

FIG. 45D

causes the peripheral interface to transfer in the opposite direction. In this example, the main processor


100


can read the status of peripheral interface


206


by reading from a status register location


1430


(R) (See FIG.


45


B). This status register


1430


(R) contains fields


1432


indicating DMA transfer in progress (field


1432


(


1


)), I/O operation in process (field


1432


(#)), an error condition (field


1432


(


3


)). By writing to the same register


1430


(W) location, main processor


100


can clear an interrupt peripheral interface


206


generates when it has completed a requested transfer. Writing to status register location


1430


(W) also allows main processor


100


to both clear and interrupt and abort a transfer in progress (see

FIG. 45A

field


1434


(


1


)).





FIGS. 45F

,


45


G,


45


H,


45


I show additional registers main processor


100


can write to in order to control timing and other parameters of the peripheral interface bus


104


. These registers permit main processor


100


to configure the bus


104


for particular types of peripheral devices—all under control of software within game program


108


. In this example, peripheral interface


44


supports duplicate sets of registers


1436


,


1438


,


1440


and


1442


shown in FIGS.


45


F-


45


I—allowing different peripheral bus


104


protocols to be used for different peripheral devices connected simultaneously to the bus without requiring the main processor


100


to re-write the configuration registers each time it request access to a different device. In this example, one set of configuration registers


1436


,


1438


,


1440


and


1442


are used to configure the bus


104


protocol whenever the peripheral interface


206


accesses a “region


1


” address space within the 16-bit peripheral address space, in the other set of register parameters are used whenever the peripheral interface accesses a “region


2


” address space within the peripheral bus address range (see

FIG. 5D

memory map). The configurations specified by these two sets of registers are invoked simply by main processor


100


writing to the appropriate region.




The various ones of control registers shown in

FIGS. 45A-45I

may, in this example, be located within the control/register block


1402


of FIG.


44


. The configuration values stored in registers


1436


,


1438


,


1442


are used in this example to control the timing of the access control signals control/register block


1402


produces on bus control line


1404


C. A latch


1434


is used to temporarily latch addresses on the co-processor address bus


214


C for application to control/register block


1402


(e.g., to select between the various registers). Control/register block


1402


in this example includes appropriate counters and the like to automatically increment DMA addresses.




While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.



Claims
  • 1. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one set color command including:a command identifier field having a six-bit binary value within the range of 110111 to 111011, a red component parameter, a green component parameter, and a blue component parameter.
  • 2. A system for generating at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and circuitry coupled to the processor and to the memory for generating at least one set color command including: a command identifier field having a six-bit binary value within the range of 110111 to 111011, a red component parameter, a green component parameter, and a blue component parameter.
  • 3. In a 3D graphics system , a process for interpreting at least one set color command including:(a) interpreting a command identifier field having a six-bit binary value within the range of 110111 to 111011, (b) interpreting a red component parameter, (c) interpreting a green component parameter, (d) interpreting a blue component parameter, and (e) generating an image based at least in part on steps (a)-(e).
  • 4. A 3D graphics system for interpreting at least one set color command having a command identifier field having a six-bit binary value within the range of 110111 to 111011, the system including:means for interpreting a command identifier field having a six-bit binary value within the range of 110111 to 111011, means for interpreting a red component parameter, means for interpreting a green component parameter, means for interpreting a blue component parameter, and a display circuit that generates an image based at least in part on the parameters.
  • 5. A storage medium for use with a 3D graphics system, the storage medium storing at least one set color command including:a command identifier field having a six-bit binary value within the range of 110111 to 111011, a red component parameter, a green component parameter, and a blue component parameter.
  • 6. A process for generating at least one display mode control command for processing by a 3D graphics system, the process including the step of generating at least one set mode command having:a command identifier field including a six-bit binary value of 111100, and at least one of the following additional fields: at least one combiner subtract mode control field that specifies subtracting at least one color space value from a color combiner, at least one combiner multiply mode control field that specifies multiplying a color combiner input by at least one color space value, and at least one combiner add control field that specifies a color combiner adder input.
  • 7. A process as in claim 6 further including the step of generating the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a subtract Source A, (2) a subtract source control field specifying a subtract Source B, (3) a multiply source control field specifying a multiply source C, and (4) an add source control field specifying an add source D.
  • 8. A process as in claim 6 further including the step of generating the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A, (2) a subtract source control field specifying an alpha component subtract Source A, (3) a subtract source control field specifying a RGB component subtract Source B, (4) a subtract source control field specifying an alpha component subtract Source B, (5) a multiply source control field specifying an RGB component multiply source C, (6) a multiply source control field specifying an alpha component multiply source C, (7) an add source control field specifying an RGB component add source D, and (8) an add source control field specifying an alpha component add source D.
  • 9. A process as in claim 6 further including the step of generating the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 0; (2) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 1; (3) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 0; (4) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 1; (5) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 0; (6) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 1; (7) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 0; (8) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 1; (9) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 0; (10) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 0; (11) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 1; (12) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 1; (13) an add source control field specifying an RGB component add source D for pipeline cycle 0; (14) an add source control field specifying an alpha component add source D for pipeline cycle 0; (15) an add source control field specifying an RGB component add source D for pipeline cycle 1; and (16) an add source control field specifying an alpha component add source D for pipeline cycle 1.
  • 10. A process as in claim 6 further including:generating at least first, second, third and fourth multiplexer select values specifying corresponding inputs for an RGB color combiner channel; and generating at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for an alpha color combiner channel.
  • 11. A process as in claim 6 further including:generating at least first, second, third and fourth multiplexer select values specifying corresponding inputs for a pipeline cycle 0 color combine operation; and generating at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for a pipeline cycle 1 color combine operation.
  • 12. A system for generating at least one display mode control command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and circuitry coupled to the processor and to the memory for providing at least one set mode command having: a command identifier field including a six-bit binary value of 111100, and at least one of the following additional fields: at least one combiner subtract mode control field that specifies subtracting at least one color space value from a color combiner, at least one combiner multiply mode control field that specifies multiplying a color combiner input by at least one color space value, and at least one combiner add control field that specifies a color combiner adder input.
  • 13. A system as in claim 12 further including means for providing the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a subtract Source A, (2) a subtract source control field specifying a subtract Source B, (3) a multiply source control field specifying a multiply source C, and (4) an add source control field specifying an add source D.
  • 14. A system as in claim 12 further including means for generating the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A, (2) a subtract source control field specifying an alpha component subtract Source A, (3) a subtract source control field specifying a RGB component subtract Source B, (4) a subtract source control field specifying an alpha component subtract Source B, (5) a multiply source control field specifying an RGB component multiply source C, (6) a multiply source control field specifying an alpha component multiply source C, (7) an add source control field specifying an RGB component add source D, and (8) an add source control field specifying an alpha component add source D.
  • 15. A system as in claim 12 further including circuitry for generating the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 0; (2) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 1; (3) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 0; (4) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 1; (5) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 0; (6) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 1; (7) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 0; (8) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 1; (9) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 0; (10) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 0; (11) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 1; (12) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 1; (13) an add source control field specifying an RGB component add source D for pipeline cycle 0; (14) an add source control field specifying an alpha component add source D for pipeline cycle 0; (15) an add source control field specifying an RGB component add source D for pipeline cycle 1; and (16) an add source control field specifying an alpha component add source D for pipeline cycle 1.
  • 16. A system as in claim 12 further including:circuitry for providing at least first, second, third and fourth multiplexer select values specifying corresponding inputs for an RGB color combiner channel; and means for providing at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for an alpha color combiner channel.
  • 17. A system as in claim 12 further including:circuitry for generating at least first, second, third and fourth multiplexer select values specifying corresponding inputs for a pipeline cycle 0 color combine operation; and circuitry for generating at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for a pipeline cycle 1 color combine operation.
  • 18. In a 3D graphics display system, a process for interpreting at least one set mode command comprising:(a) interpreting a command identifier field including a six-bit binary value of 111100, (b) interpreting at least one of the following additional fields: at least one combiner subtract mode control field that specifies subtracting at least one color space value from a color combiner, at least one combiner multiply mode control field that specifies multiplying a color combiner input by at least one color space value, and at least one combiner add control field that specifies a color combiner adder input, and (c) generating an image based at least in part on step (b).
  • 19. A process as in claim 18 further including the step of interpreting the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a subtract Source A, (2) a subtract source control field specifying a subtract Source B, (3) a multiply source control field specifying a multiply source C, and (4) an add source control field specifying an add source D.
  • 20. A process as in claim 18 further including the step of interpreting the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A, (2) a subtract source control field specifying an alpha component subtract Source A, (3) a subtract source control field specifying a RGB component subtract Source B, (4) a subtract source control field specifying an alpha component subtract Source B, (5) a multiply source control field specifying an RGB component multiply source C, (6) a multiply source control field specifying an alpha component multiply source C, (7) an add source control field specifying an RGB component add source D, and (8) an add source control field specifying an alpha component add source D.
  • 21. A process as in claim 18 further including the step of interpreting the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 0; (2) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 1; (3) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 0; (4) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 1; (5) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 0; (6) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 1; (7) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 0; (8) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 1; (9) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 0; (10) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 0; (11) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 1; (12) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 1; (13) an add source control field specifying an RGB component add source D for pipeline cycle 0; (14) an add source control field specifying an alpha component add source D for pipeline cycle 0; (15) an add source control field specifying an RGB component add source D for pipeline cycle 1; and (16) an add source control field specifying an alpha component add source D for pipeline cycle 1.
  • 22. A process as in claim 18 further including:interpreting at least first, second, third and fourth multiplexer select values specifying corresponding inputs for an RGB color combiner channel; and interpreting at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for an alpha color combiner channel.
  • 23. A process as in claim 18 further including:interpreting at least first, second, third and fourth multiplexer select values specifying corresponding inputs for a pipeline cycle 0 color combine operation; and interpreting at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for a pipeline cycle 1 color combine operation.
  • 24. A 3D graphics display system for interpreting at least one set mode command including a six-bit binary value of 111100, the system comprising:(a) means for interpreting a command identifier field including a six-bit binary value of 111100, (b) means for generating at least one control signal based on at least one of the following additional fields: at least one combiner subtract mode control field that specifies subtracting at least one color space value from a color combiner, at least one combiner multiply mode control field that specifies multiplying a color combiner input by at least one color space value, and at least one combiner add control field that specifies a color combiner adder input, and (c) means for generating an image based at least in part on the control signal.
  • 25. An apparatus as in claim 24 further including a combiner circuit that interprets the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a subtract Source A, (2) a subtract source control field specifying a subtract Source B, (3) a multiply source control field specifying a multiply source C, and (4) an add source control field specifying an add source D.
  • 26. An apparatus as in claim 24 further including a combiner that interprets the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A, (2) a subtract source control field specifying an alpha component subtract Source A, (3) a subtract source control field specifying a RGB component subtract Source B, (4) a subtract source control field specifying an alpha component subtract Source B, (5) a multiply source control field specifying an RGB component multiply source C, (6) a multiply source control field specifying an alpha component multiply source C, (7) an add source control field specifying an RGB component add source D, and (8) an add source control field specifying an alpha component add source D.
  • 27. An apparatus as in claim 24 further including a combiner that combines color signals based on the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 0; (2) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 1; (3) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 0; (4) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 1; (5) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 0; (6) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 1; (7) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 0; (8) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 1; (9) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 0; (10) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 0; (11) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 1; (12) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 1; (13) an add source control field specifying an RGB component add source D for pipeline cycle 0; (14) an add source control field specifying an alpha component add source D for pipeline cycle 0; (15) an add source control field specifying an RGB component add source D for pipeline cycle 1; and (16) an add source control field specifying an alpha component add source D for pipeline cycle 1.
  • 28. An apparatus as in claim 24 further including:means for interpreting at least first, second, third and fourth multiplexer select values specifying corresponding inputs for an RGB color combiner channel; and means for interpreting at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for an alpha color combiner channel.
  • 29. An apparatus as in claim 27 further including:means for interpreting at least first, second, third and fourth multiplexer select values specifying corresponding inputs for a pipeline cycle 0 color combine operation; and means for interpreting at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for a pipeline cycle 1 color combine operation.
  • 30. A storage medium for use with a 3D graphics system, the storage medium storing at least one display mode control command having:a command identifier field including a six-bit binary value of 111100, and at least one of the following additional fields: at least one combiner subtract mode control field that specifies subtracting at least one color space value from a color combiner, at least one combiner multiply mode control field that specifies multiplying a color combiner input by at least one color space value, and at least one combiner add control field that specifies a color combiner adder input.
  • 31. A storage medium as in claim 30 further including means for storing the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a subtract Source A, (2) a subtract source control field specifying a subtract Source B, (3) a multiply source control field specifying a multiply source C, and (4) an add source control field specifying an add source D.
  • 32. A storage medium as in claim 30 further including means for storing the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A, (2) a subtract source control field specifying an alpha component subtract Source A, (3) a subtract source control field specifying a RGB component subtract Source B, (4) a subtract source control field specifying an alpha component subtract Source B, (5) a multiply source control field specifying an RGB component multiply source C, (6) a multiply source control field specifying an alpha component multiply source C, (7) an add source control field specifying an RGB component add source D, and (8) an add source control field specifying an alpha component add source D.
  • 33. A storage medium as in claim 30 further including means for storing the following combiner subtract mode control fields to specify multiplexer sources for implementing the function (A−B)*C+D:(1) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 0; (2) a subtract source control field specifying a RGB component subtract Source A for pipeline cycle 1; (3) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 0; (4) a subtract source control field specifying an alpha component subtract Source A for pipeline cycle 1; (5) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 0; (6) a subtract source control field specifying a RGB component subtract Source B for pipeline cycle 1; (7) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 0; (8) a subtract source control field specifying an alpha component subtract Source B for pipeline cycle 1; (9) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 0; (10) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 0; (11) a multiply source control field specifying an RGB component multiply source C for pipeline cycle 1; (12) a multiply source control field specifying an alpha component multiply source C for pipeline cycle 1; (13) an add source control field specifying an RGB component add source D for pipeline cycle 0; (14) an add source control field specifying an alpha component add source D for pipeline cycle 0; (15) an add source control field specifying an RGB component add source D for pipeline cycle 1; and (16) an add source control field specifying an alpha component add source D for pipeline cycle 1.
  • 34. A storage medium as in claim 30 further including:means for storing at least first, second, third and fourth multiplexer select values specifying corresponding inputs for an RGB color combiner channel; and means for storing at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for an alpha color combiner channel.
  • 35. A storage medium as in claim 30 further including:means for storing at least first, second, third and fourth multiplexer select values specifying corresponding inputs for a pipeline cycle 0 color combine operation; and means for storing at least fifth, sixth, seventh and eighth multiplexer select values specifying corresponding inputs for a pipeline cycle 1 color combine operation.
  • 36. A process for generating at least one color image mode command for processing by a 3D graphics system, the process including the step of generating at least one command including:a command identifier field including a six-bit binary value within the set of 111111 and 111101; an image data format parameter; a color element size parameter; an image width parameter; and a base address parameter.
  • 37. A process as in claim 36 further including the step of generating the image data format parameter selecting between the following:(a) rgba, (b) yuv, (c) color index, (d) intensity alpha, and (e) alpha.
  • 38. The process as in claim 36 further including the step of generating the color element size parameter selecting between the following:(a) 4 bit wide color element value, (b) 8 bit wide color element value, (c) 16 bit wide color element value, and (d) 32 bit wide color element value.
  • 39. The process as in claim 36 further including the step of generating the image width parameter value specifying the width in pixels of an image stored in memory.
  • 40. The process as in claim 36 further including the step of generating the base address parameter specifying the base address in main memory of the top left corner of the image.
  • 41. A system for providing at least one color image mode command for processing by a 3D graphics system, the system includingat least one processor, at least one memory, and circuitry coupled to the processor and to the memory for generating at least one command including: a command identifier field including a six-bit binary value within the set of 111111 and 111101; an image data format parameter; a color element size parameter; an image width parameter; and a base address parameter.
  • 42. A system as in claim 41 further including means for providing the image data format parameter selecting between the following:(a) rgba, (b) yuv, (c) color index, (d) intensity alpha, and (e) alpha.
  • 43. The system as in claim 42 further including means for providing the color element size parameter selecting between the following:(a) 4 bit wide color element value, (b) 8 bit wide color element value, (c) 16 bit wide color element value, and (d) 32 bit wide color element value.
  • 44. The system as in claim 41 further including means for providing the image width parameter value specifying the width in pixels of an image stored in memory.
  • 45. The system as in claim 41 further including means for generating the base address parameter specifying the base address in main memory of the top left corner of the image.
  • 46. In a 3D graphics system, a process of executing at least one color image mode command including:(a) interpreting a command identifier field including a six-bit binary value within the set of 111111 and 111101 as corresponding to color image mode; (b) interpreting at least one of the following: an image data format parameter; a color element size parameter; an image width parameter; and a base address parameter; and (c) generating a color image display based at least in part on step (b).
  • 47. A process as in claim 46 further including the steps of selecting between the following based on the image data format parameter:(a) rgba, (b) yuv, (c) color index, (d) intensity alpha, and (e) alpha.
  • 48. The process as in claim 46 further including the step of selecting between the following based on the color element size parameter:(a) 4 bit wide color element value, (b) 8 bit wide color element value, (c) 16 bit wide color element value, and (d) 32 bit wide color element value.
  • 49. The process as in claim 46 further including the step of setting the width in pixels of an.image stored in memory based on the image width parameter value.
  • 50. The process as in claim 46 further including the step of setting the base address in main memory of the top left corner of the image based on the base address parameter.
  • 51. A 3D graphics system for executing at least one color image mode command having a command identifier field including a six-bit binary value within the set of 111111 and 111101 as corresponding to color image mode, the system including:a command identifier decoder for interpreting a command identifier field including a six-bit binary value within the set of 111111 and 111101 as corresponding to color image mode; a command parameter decoder for interpreting at least one of the following: an image data format parameter; a color element size parameter; an image width parameter; and a base address parameter; and a display circuit that generates a color image display based at least in part on parameters.
  • 52. An apparatus as in claim 51 further including structure for selecting between the following based on the image data format parameter:(a) rgba, (b) yuv, (c) color index, (d) intensity alpha, and (e) alpha.
  • 53. The process as in claim 51 further including structure for selecting between the following based on the color element size parameter:(a) 4 bit wide color element value, (b) 8 bit wide color element value, (c) 16 bit wide color element value, and (d) 32 bit wide color element value.
  • 54. The process as in claim 51 further including means for setting the width in pixels of an image stored in memory based on the image width parameter value.
  • 55. The process as in claim 51 further including a circuit for setting the base address in main memory of the top left corner of the image based on the base address parameter.
  • 56. A storage medium for use with a 3D graphics system, the storage medium for storing at least one color image mode command including:a command identifier field including a six-bit binary value within the set of 111111 and 111101; an image data format parameter; a color element size parameter; an image width parameter; and a base address parameter.
  • 57. A storage medium as in claim 56 further including means for storing an image data format parameter selecting between the following:(a) rgba, (b) yuv, (c) color index, (d) intensity alpha, and (e) alpha.
  • 58. The storage medium as in claim 56 further including means for storing a color element size parameter selecting between the following:(a) 4 bit wide color element value, (b) 8 bit wide color element value, (c) 16 bit wide color element value, and (d) 32 bit wide color element value.
  • 59. The storage medium as in claim 56 further including means for storing an image width parameter value specifying the width in pixels of an image stored in memory.
  • 60. The storage medium as in claim 56 further including means for storing the base address parameter specifying the base address in main memory of the top left corner of the image.
  • 61. A process for generating at least one mask image mode command for processing by a 3D graphics system, the process including the step of generating at least one set mask image command including:a command identifier field including a six-bit binary value of 111110, and a base address specifying the memory address of a top left corner of at least one depth image.
  • 62. A system for providing at least one mask image mode command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and means coupled to the processor and to the memory for providing at least one set mask image command including: a command identifier field including a six-bit binary value of 111110, and a base address specifying the memory address of a top left corner of at least one depth image.
  • 63. In a 3D graphics system, a process for interpreting at least one mask image mode command including:interpreting a command identifier field including a six-bit binary value of 111110, and interpreting a base address specifying the memory address of a top left corner of at least one depth image.
  • 64. In a 3D graphics system, a decoder for interpreting at least one mask image mode command including a six-bit binary value of 111110, the system including:means for interpreting a command identifier field including a six-bit binary value of 111110, and means for interpreting a base address specifying the memory address of a top left corner of at least one depth image.
  • 65. A storage medium for use with a 3D graphics system, the storage medium for storing at least one mask image mode command including:a command identifier field including a six-bit binary value of 111110, and a base address specifying the memory address of a top left corner of at least one depth image.
  • 66. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one triangle drawing command having a command identifier field including a six-bit binary value within the range of 001000 to 001111 followed by at least x and y position values, the triangle drawing command format specifying at least one triangle at the x and y positions corresponding to the x and y position values.
  • 67. A system for generating at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and means coupled to the processor and to the memory for providing at least one triangle drawing command having a command identifier field including a six-bit binary value within the range of 001000 to 001111 followed by at least x and y position values, the triangle drawing command format specifying at least one triangle at the x and y positions corresponding to the x and y position values.
  • 68. In a 3D graphics system, a process for executing at least one display command for processing including the steps of:(a) interpreting at least one triangle drawing command having a command identifier field including a six-bit binary value within the range of 001000 to 001111 followed by at least x and y position values, and (b) rendering at least one primitive at the x and y positions corresponding to the x and y position values.
  • 69. A 3D graphics system for executing at least one display command including a six-bit binary value within the range of 001000 to 001111 followed by at least x and y position values, the system including:a decoder that interprets at least one triangle drawing command having a command identifier field including a six-bit binary value within the range of 001000 to 001111 followed by at least x and y position values, and a display processor that renders at least one primitive at the x and y positions corresponding to the x and y position values.
  • 70. A storage medium for use with a 3D graphics system, the storage medium storing at least one display command having a command identifier field including a six-bit binary value within the range of 001000 to 001111 followed by at least x and y position values, the triangle drawing command format specifying at least one triangle at the x and y positions corresponding to the x and y position values.
  • 71. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one triangle drawing command including:a command identifier field having a six-bit binary value of at least one of 001111 and 001011, a set of edge coefficients, a set of texture coefficients, and a set of z buffer coefficients, the triangle drawing command format specifying at least one triangle to be drawn in accordance with the set of edge coefficients, filled with a texture based at least in part on the set of texture coefficients, and z buffered based at least in part on the set of z buffer coefficients.
  • 72. A system for providing at least one display command for processing by a 3D graphics system, the system includingat least one processor, at least one memory, and circuitry coupled to the processor and to the memory for providing at least one triangle drawing command including: a command identifier field having a six-bit binary value of at least one of 001111 and 001011, a set of edge coefficients, a set of texture coefficients, and a set of z buffer coefficients, the triangle drawing command format specifying at least one triangle to be drawn in accordance with the set of edge coefficients, filled with a texture based at least in part on the set of texture coefficients, and z buffered based at least in part on the set of z buffer coefficients.
  • 73. In a 3D graphics system, a process for executing at least one triangle drawing command including:(a) interpreting a command identifier field having a six-bit binary value of at least one of 001111 and 001011, (b) interpreting a set of edge coefficients, (c) interpreting a set of texture coefficients, (c) interpreting a set of z buffer coefficients, and (e) rendering at least one triangle in accordance with the set of edge coefficients, filled with a texture based at least in part on the set of texture coefficients, and z buffered based at least in part on the set of z buffer coefficients.
  • 74. A 3D graphics system for executing at least one triangle drawing command having a command identifier field having a six-bit binary value of at least one of 001111 and 001011, the system including:(a) means for interpreting a command identifier field having a six-bit binary value of at least one of 001111 and 001011, (b) means for interpreting a set of edge coefficients, (c) means for interpreting a set of texture coefficients, (c) means for interpreting a set of z buffer coefficients, and means coupled to the above-mentioned means for rendering at least one triangle in accordance with the set of edge coefficients, filled with a texture based at least in part on the set of texture coefficients, and z buffered based at least in part on the set of z buffer coefficients.
  • 75. A storage medium for use with a 3D graphics system, the storage medium for storing at least one triangle drawing command including:a command identifier field having a six-bit binary value of at least one of 001111 and 001011, a set of edge coefficients, a set of texture coefficients, and a set of z buffer coefficients, the triangle drawing command format specifying at least one triangle to be drawn in accordance with the set of edge coefficients, filled with a texture based at least in part on the set of texture coefficients, and z buffered based at least in part on the set of z buffer coefficients.
  • 76. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one triangle drawing command including:a command identifier field having a six-bit binary value selected from the set of 001010 and 001110, a set of edge coefficients, and a set of texture coefficients, the triangle drawing command format specifying at least one triangle to be drawn in accordance with the set of edge coefficients, and filled with a texture based at least in part on the set of texture coefficients.
  • 77. A system for generating at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and circuitry coupled to the processor and to the memory for generating at least one triangle drawing command including: a command identifier field having a six-bit binary value selected from the set of 001010 and 001110, a set of edge coefficients, and a set of texture coefficients, the triangle drawing command format specifying at least one triangle to be drawn in accordance with the set of edge coefficients, and filled with a texture based at least in part on the set of texture coefficients.
  • 78. In a 3D graphics system, a process for executing at least one triangle drawing command including:(a) interpreting a command identifier field having a six-bit binary value selected from the set of 001010 and 001110, (b) interpreting a set of edge coefficients, (c) interpreting a set of texture coefficients, and (d) drawing at least one triangle in accordance with the set of edge coefficients, and filled with a texture based at least in part on the set of texture coefficients.
  • 79. A 3D graphics system for executing at least one triangle drawing command having a command identifier field having a six-bit binary value selected from the set of 001010 and 001110, the system including:a command identifier field decoder that interprets a command identifier field having a six-bit binary value selected from the set of 001010 and 001110, a rasterizer that interprets a set of edge coefficients, a texture coordinate unit that interprets a set of texture coefficients, and a display processor that draws at least one triangle in accordance with the set of edge coefficients, and filled with a texture based at least in part on the set of texture coefficients.
  • 80. A storage medium for use with a 3D graphics system, the storage medium for storing at least one triangle drawing command including:a command identifier field having a six-bit binary value selected from the set of 001010 and 001110, a set of edge coefficients, and a set of texture coefficients, the triangle drawing command format specifying at least one triangle to be drawn in accordance with the set of edge coefficients, and filled with a texture based at least in part on the set of texture coefficients.
  • 81. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one triangle drawing command including:a command identifier field having a six-bit binary value of a value selected from the set of 001001, a set of edge coefficients, and a set of z buffer coefficients, the triangle drawing command format specifying at least one non-shaded triangle to be drawn in accordance with the set of edge coefficients and z buffered based at least in part on the set of z buffer coefficients.
  • 82. A system for providing at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and circuitry coupled to the processor and to the memory for providing at least one triangle drawing command including: a command identifier field having a six-bit binary value of a value selected from the set of 001001, a set of edge coefficients, and a set of z buffer coefficients, the triangle drawing command format specifying at least one non-shaded triangle to be drawn in accordance with the set of edge coefficients and z buffered based at least in part on the set of z buffer coefficients.
  • 83. In a 3D graphics system, a process for executing at least one triangle drawing command including:(a) interpreting a command identifier field having a six-bit binary value of a value selected from the set of 001001, (b) interpreting a set of edge coefficients, (c) interpreting a set of z buffer coefficients, and (d) drawing at least one non-shaded triangle in accordance with the set of edge coefficients and z buffered based at least in part on the set of z buffer coefficients.
  • 84. A 3D graphics system for executing at least one triangle drawing command having a command identifier field having a six-bit binary value of a value selected from the set of 001001, the system including:a decoder that interprets a command identifier field having a six-bit binary value of a value selected from the set of 001001, an edge walker that interprets a set of edge coefficients, a z buffer controller that interprets a set of z buffer coefficients, and a display processor that draws at least one non-shaded triangle in accordance with the set of edge coefficients and z buffered based at least in part on the set of z buffer coefficients.
  • 85. A storage medium for use with a 3D graphics system, the storage medium storing at least one triangle drawing command including:a command identifier field having a six-bit binary value of a value selected from the set of 001001, a set of edge coefficients, and a set of z buffer coefficients, the triangle drawing command format specifying at least one non-shaded triangle to be drawn in accordance with the set of edge coefficients and z buffered based at least in part on the set of z buffer coefficients.
  • 86. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one textured rectangle drawing command including:a command identifier field having a six-bit binary value within the range of 100100 and 100101, at least two x coordinate values, at least two y coordinate values, a set of texture coefficients, and a tile descriptor index value, the textured rectangle drawing command format specifying at least one rectangle to be drawn in accordance with the x and y coordinate values, and filled with a texture based at least in part on the set of texture coefficients and the tile descriptor index value.
  • 87. A system for providing at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and means coupled to the processor and to the memory for providing at least one textured rectangle drawing command including: a command identifier field having a six-bit binary value within the range of 100100 and 100101, at least two x coordinate values, at least two y coordinate values, a set of texture coefficients, and a tile descriptor index value, the textured rectangle drawing command format specifying at least one rectangle to be drawn in accordance with the x and y coordinate values, and filled with a texture based at least in part on the set of texture coefficients and the tile descriptor index value.
  • 88. In a 3D graphics system, a process for executing at least one textured rectangle drawing command including:(a) interpreting a command identifier field having a six-bit binary value within the range of 100100 and 100101, (b) interpreting at least two x coordinate values, (c) interpreting at least two y coordinate values, (d) interpreting a set of texture coefficients, (e) interpreting a tile descriptor index value, and (f) rendering at least one rectangle in accordance with the x and y coordinate values, and filled with a texture based at least in part on the set of texture coefficients and the tile descriptor index value.
  • 89. A 3D graphics system for executing at least one textured rectangle drawing command having a command identifier field having a six-bit binary value within the range of 100100 and 100101, the system including:a decoder that interprets a command identifier field having a six-bit binary value within the range of 100100 and 100101, a processor that interprets at least two x coordinate values and at least two y coordinate values, a texture coordinate unit that interprets a set of texture coefficients, and a tile descriptor index value, and a display processor that renders at least one rectangle in accordance with the x and y coordinate values, and filled with a texture based at least in part on the set of texture coefficients and the tile descriptor index value.
  • 90. A storage medium for use with a 3D graphics system, the storage medium for storing at least one textured rectangle drawing command including:a command identifier field having a six-bit binary value within the range of 100100 and 100101, at least two x coordinate values, at least two y coordinate values, a set of texture coefficients, and a tile descriptor index value, the textured rectangle drawing command format specifying at least one rectangle to be drawn in accordance with the x and y coordinate values, and filled with a texture based at least in part on the set of texture coefficients and the tile descriptor index value.
  • 91. A process for generating at least one display command for processing by a 3D graphics system, the process including the steps of:(a) generating at least one set primitive color command including: a command identifier field having a six-bit binary value of 111010, and a set of color coordinates; and (b) generating at least one filled rectangle drawing command including: a command identifier field having a six-bit binary value of 110110, at least two x coordinate values, and at least two y coordinate values, the filled rectangle drawing command format specifying at least one rectangle to be drawn in accordance with the x and y coordinate values, and filled with a color based at least in part on the color coordinates.
  • 92. A system for generating at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and means coupled to the processor and to the memory for generating: (a) at least one set primitive color command including: a command identifier field having a six-bit binary value of 111010, and a set of color coordinates; and (b) at least one filled rectangle drawing command including: a command identifier field having a six-bit binary value of 110110, at least two x coordinate values, and at least two y coordinate values, the filled rectangle drawing command format specifying at least one rectangle to be drawn in accordance with the x and y coordinate values, and filled with a color based at least in part on the color coordinates.
  • 93. In a 3D graphics system, a process for executing at least one display command for processing by a 3D graphics system, the process including the steps of:(a) interpreting at least one set primitive color command including: a command identifier field having a six-bit binary value of 111010, and a set of color coordinates; (b) interpreting at least one filled rectangle drawing command including: a command identifier field having a six-bit binary value of 110110, at least two x coordinate values, and at least two y coordinate values; and (c) drawing at least one rectangle in accordance with the x and y coordinate values, and filled with a color based at least in part on the color coordinates.
  • 94. In a 3D graphics system, an apparatus for executing at least one display command having a command identifier field having a six-bit binary value of 111010, the apparatus including the following structures:means for interpreting at least one set primitive color command including: a command identifier field having a six-bit binary value of 111010, and a set of color coordinates; means for interpreting at least one filled rectangle drawing command including: a command identifier field having a six-bit binary value of 110110, at least two x coordinate values, and at least two y coordinate values; and means for drawing at least one rectangle in accordance with the x and y coordinate values, and filled with a color based at least in part on the color coordinates.
  • 95. A storage medium for use with a 3D graphics system, the storage medium for storing:(a) at least one set primitive color command including: a command identifier field having a six-bit binary value of 111010, and a set of color coordinates; and (b) at least one filled rectangle drawing command including: a command identifier field having a six-bit binary value of 110110, at least two x coordinate values, and at least two y coordinate values, the filled rectangle drawing command format specifying at least one rectangle to be drawn in accordance with the x and y coordinate values, and filled with a color based at least in part on the color coordinates.
  • 96. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one texture defining command including:a command identifier field having a six-bit binary value of a value of 110101, an image data format parameter, a color element size parameter, a tile line size parameter, a starting texture memory address, a tile descriptor index, a palette number, at least one texture coordinate clamp enable parameter, at least one texture coordinate mirror enable parameter, at least one texture coordinate wrapping/mirroring mask, and at least one texture coordinate level of detail shift parameter.
  • 97. A system for providing at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and means coupled to the processor and to the memory for providing at least one texture defining command including: a command identifier field having a six-bit binary value of a value of 110101, an image data format parameter, a color element size parameter, a tile line size parameter, a starting texture memory address, a tile descriptor index, a palette number, at least one texture coordinate clamp enable parameter, at least one texture coordinate mirror enable parameter, at least one texture coordinate wrapping/mirroring mask, and at least one texture coordinate level of detail shift parameter.
  • 98. In a 3D graphics system, a process for processing at least one texture defining command including:(a) interpreting a command identifier field having a six-bit binary value of a value of 110101, (b) interpreting an image data format parameter, (c) interpreting a color element size parameter, (d) interpreting a tile line size parameter, (e) interpreting a starting texture memory address, (f) interpreting a tile descriptor index, (g) interpreting a palette number, (h) interpreting at least one texture coordinate clamp enable parameter, (i) interpreting at least one texture coordinate mirror enable parameter, (j) interpreting at least one texture coordinate wrapping/mirroring mask, (k) interpreting at least one texture coordinate level of detail shift parameter, and (l) generating at least one image based at least in part on the above-mentioned steps.
  • 99. A 3D graphics apparatus for processing at least one texture defining command having a command identifier field having a six-bit binary value of a value of 110101, the apparatus including:means for interpreting a command identifier field having a six-bit binary value of a value of 110101, a circuit that interprets an image data format parameter, a color element size parameter, a tile line size parameter, a starting texture memory address, a tile descriptor index, a palette number, at least one texture coordinate clamp enable parameter, at least one texture coordinate mirror enable parameter, at least one texture coordinate wrapping/mirroring mask, and at least one texture coordinate level of detail shift parameter, and a display processor that generates at least one image based at least in part on the above-mentioned structures.
  • 100. A storage medium for use with a 3D graphics system, the storage medium for storing at least one texture defining command including:a command identifier field having a six-bit binary value of a value of 110101, an image data format parameter, a color element size parameter, a tile line size parameter, a starting texture memory address, a tile descriptor index, a palette number, at least one texture coordinate clamp enable parameter, at least one texture coordinate mirror enable parameter, at least one texture coordinate wrapping/mirroring mask, and at least one texture coordinate level of detail shift parameter.
  • 101. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one texture tile command including:a command identifier field having a six-bit binary value of a value within the set of 110100 and 110010, low and high tile S coordinates, low and high tile T coordinates, and a tile descriptor index.
  • 102. A system for providing at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and circuitry coupled to the processor and to the memory for providing at least one texture tile command including: a command identifier field having a six-bit binary value of a value within the set of 110100 and 110010, low and high tile S coordinates, low and high tile T coordinates, and a tile descriptor index.
  • 103. In a 3D graphics system, a process for executing at least one texture tile command including:(a) interpreting a command identifier field having a six-bit binary value of a value within the set of 110100 and 110010, (b) interpreting low and high tile S coordinates, (c) interpreting low and high tile T coordinates, (d) interpreting a tile descriptor index, and (e) generating a display based at least in part on steps (a)-(d).
  • 104. A 3D graphics system for executing at least one texture tile command having a command identifier field having a six-bit binary value of a value within the set of 110100 and 110010, the system including:a decoder that interprets a command identifier field having a six-bit binary value of a value within the set of 110100 and 110010, a texture unit that interprets low and high tile S coordinates, low and high tile T coordinates, a tile descriptor index; and a display processor circuit that generates a display based at least in part on the coordinates identifier and command identifier.
  • 105. A storage medium for use with a 3D graphics system, the storage medium for storing at least one texture tile command including:a command identifier field having a six-bit binary value of a value within the set of 110100 and 110010, low and high tile S coordinates, low and high tile T coordinates, and a tile descriptor index.
  • 106. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one texture memory block loading command including:a command identifier field having a six-bit binary value of 110011, low and high tile S coordinate parameters, a low tile T coordinate parameter, a T increment value, and a tile descriptor index.
  • 107. A system for generating at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and means coupled to the processor and to the memory for generating at least one texture memory block loading command including: a command identifier field having a six-bit binary value of 110011, low and high tile S coordinate parameters, a low tile T coordinate parameter, a T increment value, and a tile descriptor index.
  • 108. In a 3D graphics system, a process for executing at least one texture memory block loading command including:(a) interpreting a command identifier field having a six-bit binary value of 110011, (b) interpreting low and high tile S coordinate parameters, (c) interpreting a low tile T coordinate parameter, (d) interpreting a T increment value, (e) interpreting a tile descriptor index, and (f) displaying at least one textured primitive based at least in part on steps (a)-(e).
  • 109. A 3D graphics system for executing at least one texture memory block loading command having a command identifier field having a six-bit binary value of 110011, the system including:means for interpreting a command identifier field having a six-bit binary value of 110011, means for interpreting low and high tile S coordinate parameters, means for interpreting a low tile T coordinate parameter, means for interpreting a T increment value, means for interpreting a tile descriptor index, and a display circuit for displaying at least one textured primitive based at least in part on the S and T coordinate parameters, the T increment value, and the tile descriptor index.
  • 110. A storage medium for use with a 3D graphics system, the storage medium for storing at least one texture memory block loading command including:a command identifier field having a six-bit binary value of 110011, low and high tile S coordinate parameters, a low tile T coordinate parameter, a T increment value, and a tile descriptor index.
  • 111. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one load texture look up table command including:a command identifier field having a six-bit binary value of 110000, low and high indices into the table, and a tile descriptor index.
  • 112. A system for providing at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and circuitry coupled to the processor and to the memory for providing at least one load texture look up table command including: a command identifier field having a six-bit binary value of 110000, low and high indices into the table, and a tile descriptor index.
  • 113. In a 3D graphics system, a process for executing at least one load texture look up table command including:(a) interpreting a command identifier field having a six-bit binary value of 110000, (b) interpreting low and high indices into the table, (c) a tile descriptor index, and (d) loading a texture look up table into a memory based at least in part on steps (a)-(c).
  • 114. A 3D graphics system for executing at least one load texture look up table command having a command identifier field having a six-bit binary value of 110000, the system including:a texture memory means for interpreting a command identifier field having a six-bit binary value of 110000, means for interpreting low and high indices into the table, means for interpreting a tile descriptor index, and means for loading a texture look up table into the texture memory based at least in part on the command identifier field and the indices.
  • 115. A storage medium for use with a 3D graphics system, the storage medium for storing at least one load texture look up table command including:a command identifier field having a six-bit binary value of 110000, low and high indices into the table, and a tile descriptor index.
  • 116. A process for generating at least one display command for processing by a 3D graphics system, the process including the step of generating at least one set primitive depth command including:a command identifier field having a six-bit binary value of 101110, a primitive depth parameter, and a primitive delta depth parameter.
  • 117. A system for providing at least one display command for processing by a 3D graphics system, the system including:at least one processor, at least one memory, and means coupled to the processor and to the memory for providing at least one set primitive depth command including: a command identifier field having a six-bit binary value of 101110, a primitive depth parameter, and a primitive delta depth parameter.
  • 118. In a 3D graphics system, a process for processing at least one set primitive depth command including:(a) interpreting a command identifier field having a six-bit binary value of 101110, (b) interpreting a primitive depth parameter, (c) interpreting a primitive delta depth parameter, and (d) generating at least one image based at least in part on steps (a)-(c).
  • 119. A 3D graphics system for processing at least one set primitive depth command having a command identifier field having a six-bit binary value of 101110, the system including:means for interpreting a command identifier field having a six-bit binary value of 101110, means for interpreting a primitive depth parameter, means for interpreting a primitive delta depth parameter, and a display circuit that generates at least one image based at least in part on the parameters.
  • 120. A storage medium for use with a 3D graphics system, the storage medium storing at least one set primitive depth command including:a command identifier field having a six-bit binary value of 101110, a primitive depth parameter, and a primitive delta depth parameter.
CROSS-REFERENCE TO RELATED APPLICATIONS

This is a continuing application of U.S. application Ser. No. 09/251,350 filed Feb. 17, 1999, now U.S. Pat. No. 6,239,810, which is a divisional of U.S. application Ser. No. 08/990,133 filed Dec. 12, 1997, now U.S. Pat. No. 6,166,748, which is a divisional of U.S. application Ser. No. 08/561,718 filed Nov. 22, 1995 now U.S. Pat. No. 6,331,856.

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Continuations (1)
Number Date Country
Parent 09/251350 Feb 1999 US
Child 09/663617 US