Mechanism for implementing Z-compression transparently

Abstract

The present invention provides a mechanism for implementing z-compression in a manner that is transparent to the user. Blocks of z-data are associated with storage locations in a z-data buffer in cleared, compressed, or uncompressed data states. Operations to the z-data buffer are monitored for selected operations. These operations may include clear or lock operations. If a selected operation is detected, a modified version of the selected operation is implemented to mask differences between the storage states of the data blocks.

Claims

We claim:

1. A method for processing data comprising:

storing blocks of data in entries of a first memory location, each of the blocks of data being stored in one of a cleared, compressed, or uncompressed data states;

monitoring operations to the first memory location for a selected operation; and

if the selected operation is detected, implementing a modified version of the selected operation that masks differences between the data states of the data blocks, wherein implementing the modified version of the selected operation includes

saving a current processor state;

reading one or more data blocks according to their data states in response to the selected operation; and

writing the read data back into the entries of the first memory location in an uncompressed state before performing the selected operation on the data in the uncompressed state.

2. The method of claim 1, wherein the selected operation is a read of specified data blocks, and implementing the modified read further comprises:

reading the converted data blocks according to their stored states.

3. The method of claim 1, wherein the selected operation is a clear of entries of the first memory location and implementing the clear comprises setting the states of the data blocks in the first set of entries of the first memory location to the cleared state.

4. The method of claim 3, further comprising updating a cleared state variable in a current processor state.

5. The method of claim 1, wherein the selected operation is a clear of data blocks at specified entries of the first memory location and implementing the clear comprises:

setting the data states of the data blocks to the cleared state if the specified entries include all of the data blocks; and

writing a primitive to the specified entries of the first memory location if the specified entries do not include all of the data blocks.

6. The method of claim 5, wherein the specified portion is a depth or a stencil portion of the data blocks.

7. A method for processing z-data comprising:

determining whether z-compression is implemented;

implementing a selected operation if z-compression is not implemented; and

implementing a modified form of the selected operation if z-compression is implemented, wherein implementing the modified form of the selected operation comprises

saving a current processor state;

reading data blocks from entries of a first memory according to status bits of the data blocks; and

writing the read data blocks back into the entries of the first memory in an uncompressed state before executing the selected operation on the data blocks in the uncompressed state.

8. The method of claim 7, wherein determining whether z-compression is implemented comprises:

allocating a first portion of memory to store z-data;

determining whether a memory system can support z-compression; and

allocating a second portion of the memory to store status bits for the z-data if the memory system can support depth-compression.

9. The method of claim 8, wherein the z-data is organized as a plurality of data blocks and the status bits indicate an associated data block is compressed, uncompressed, or cleared.

10. The method of claim 9, wherein the selected operation is a read of the entries of the first memory by an application.

11. The method of claim 9, wherein the selected operation is a clear of the first memory, and implementing a modified form of the clear comprises setting the status bits in a second portion of the memory to a value that indicates the associated data is in a cleared state.

12. A machine readable medium on which are stored instructions that are executable by an apparatus to implement a method comprising:

detecting a read or lock by an application on z-data blocks, each block of z-data having a data state indicated by an associated status field;

saving a processor state;

converting the z-data blocks to an uncompressed data state, wherein converting the z-data blocks to an uncompressed data state comprises

reading the z-data blocks according to their data states; and

writing the read z-data blocks in the uncompressed state before executing the read or lock;

restoring the processor state; and

executing the read or lock.

13. The machine readable medium of claim 12, wherein converting the z-data blocks to an uncompressed data state further comprises:

updating status fields of the z-data blocks accordingly.

14. A computer system comprising:

a processor core;

a data-buffer;

a status table associated with the data-buffer, to indicate a status value for each entry of the data-buffer; and

a machine-readable medium on which are stored instructions that are executable by the processor core to implement a method comprising:

intercepting a selected instruction that operates on the data-buffer;

saving a current state of the processor core;

modifying the data-buffer and the status table, as necessary, to place data in the data-buffer in a state expected by the selected instruction, wherein modifying the data buffer comprises

reading entries of the data buffer according to the status value associated with each of the entries,

decompressing the read entries, as necessary, and

writing the read entries to the data buffer in uncompressed form before executing the intercepted instruction on the read entries in uncompressed form; and

executing the intercepted instruction.

15. The computer system of claim 14, wherein the selected instruction is a clear instruction.

16. The computer system of claim 15, further comprising updating the status values of each of the read entries of the data-buffer in the status table.

17. The computer system of claim 15, wherein reading entries of the data buffer comprises reading a cleared value from a local register for an entry having a cleared status value.

18. The computer system of claim 17, further comprising writing the cleared value to the data buffer and updating the status table.

Description

BACKGROUND OF THE INVENTION

1. Technical Field

The present invention relates to graphics systems and, in particular, to mechanisms for processing depth or z-data for 3 dimensional (3D) graphics in a manner that is transparent to the user.

2. Background Art

Available computer systems typically include dedicated graphics resources to support the graphics-intensive applications that are prevalent today. Graphics applications, particularly those providing 3D effects, require rapid access to large amounts of graphics data.

A standard method for generating a 3D image begins with sets of primitives that represent the surfaces of each object in the image. Primitives are typically polygons such as triangles or rectangles that may be tiled to form a surface. An object that has a moderately complex shape may require thousands of primitives to represent its surface, and an image that includes multiple objects may require tens or even hundreds of thousands of primitives. Depth, color, texture, illumination and orientation data for each of these primitives must be processed and converted to pixel level data to generate a 3D image on a display device.

Image processing is often implemented through a 3D pipeline that includes a geometry or set-up phase and a rendering or scan-conversion phase. In the geometry phase, the orientation of each primitive and the location of any light sources that illuminate the primitive are determined with respect to a reference coordinate system and specified by vectors associated with the primitive's vertices. This vertex data is then transformed to a viewing or camera coordinate system and rotated to a desired orientation.

In the scan conversion phase, the graphics primitives for each object in an image are converted into a single set of pixel values that provide a 2D representation of the 3D image. The pixels that make up the 2D image are typically stored in the entries of a frame buffer from which the display is generated. A well-known mechanism for populating the frame buffer generates color values for each location of a primitive by interpolating the transformed vertex data for the primitive. Since primitive locations are specified in 3D space, multiple primitive locations may map to the same frame buffer entry (pixel) of the 2D display surface. The generated color value for a primitive location is stored in the frame buffer entry to which it maps or discarded, according to whether or not it is visible in the final image. During this phase, texture data may also be determined for the primitives.

One technique for determining which locations of each primitive are visible in the final image employs a z-buffer. The z-buffer includes an entry for each pixel in the frame buffer. Each z-buffer entry is initialized to zero or other reference value. Often, the reference value represents a back clipping plane of the image. During scan conversion, a z-value is determined for each location within the primitive and compared with the entry in the z-buffer to which the primitive location maps. If the value in the z-buffer is closer to the viewer than the z-value determined for the corresponding primitive location, the primitive location is not visible in the final image, and its color value is discarded. If the value in the z-buffer is further from the viewer than the z-value determined for the corresponding primitive location, the color value for the location is stored in the appropriate entry of the frame buffer. If the color value is not replaced before scan conversion completes, it is displayed in the final image.

Significant amounts of texture, color and z-data are transferred between memory and the graphics resources during the rendering stage. Since there may be tens to hundreds of pixels per primitive, these data transfers can place significant burdens on the bandwidth of the memory channel. The consequent reduction in memory bandwidth can reduce the performance of the graphics system. This is particularly true if the graphic system is implemented in a computer system that employs a unified memory architecture (UMA). For UMA-based computer systems, the central processor unit(s) (CPU) and graphics engine have equal access to main memory. Memory demands by the graphics engine can reduce CPU performance. In addition, memory demands by one unit of the graphics engine can reduce the performance of other units. For example, any bandwidth used to transfer z-data for z-testing is unavailable to the unit that determines pixel textures, and the loss in bandwidth can reduce its performance.

The present invention addresses these and other issues associated with memory bandwidth in graphics systems.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention may be understood with reference to the following drawings, in which like elements are indicated by like numbers. These drawings are provided to illustrate selected embodiments of the present invention and are not intended to limit the scope of the invention.

FIG. 1 is a diagram representing one mapping between the locations of a primitive and blocks of pixel-level data.

FIG. 2 is a schematic representation of a graphics pipeline suitable for scan converting primitive data into pixel data.

FIG. 3 is a block diagram of one embodiment of a computer system that implements a z-compression mechanism in accordance with the present invention.

FIG. 4 is a block diagram of one embodiment of a z-compression system in which blocks of z-data and their associated status data are distributed between a local cache and a main memory.

FIG. 5A is a block diagram of one embodiment of a local cache system to store both z-data values and associated status values.

FIG. 5B is a block diagram representing a mechanism for updating the local cache system of FIG. 5A on a TLB miss.

FIG. 6A is a schematic representation of another embodiment of a local cache system to store both z-data values and associated status values.

FIG. 6B is a state machine representing the state changes for the entries of the local cache of FIG. 6A.

FIG. 6C is a schematic representation of a mechanism for updating the local cache system of FIG. 6A on a TLB miss.

FIG. 7 is one embodiment of a memory map that is suitable for storing status values for data blocks in a linear memory region.

FIGS. 8A and 8B represent embodiments of 16-bit and 32-bit z-data formats that may be compressed using a mechanism in accordance with the present invention.

FIG. 9 represents one embodiment of compressed format for z-data that may be used by a system implementing the present invention.

FIGS. 10A-10C are flowcharts representing embodiments of methods for implementing memory reads, memory writes, and status updates for blocks of z-data.

FIG. 11 is a flowchart representing one embodiment of a method for implementing z-compression transparently

FIG. 12 is a flowchart representing one embodiment of a method for implementing accesses to the z-buffer transparently

FIGS. 13A-13C are flowcharts representing embodiments of different methods for clearing the z-buffer transparently.

DETAILED DESCRIPTION OF THE INVENTION

The following discussion sets forth numerous specific details to provide a thorough understanding of the invention. However, those of ordinary skill in the art, having the benefit of this disclosure, will appreciate that the invention may be practiced without these specific details. In addition, various well-known methods, procedures, components, and circuits have not been described in detail in order to focus attention on the features of the present invention.

FIG. 1 is a schematic representation of a graphics primitive 100 and a subset of data blocks 110(a), 110(b) (generically, "data blocks 110") to which corresponding locations (x, y) in primitive 100 are mapped in a viewing coordinate system. Multiple graphics primitives 100 are used to approximate the surface of an object that is to be represented in an image. While graphics primitive 100 is shown as a triangle, it is well know that any type of polygon may be used to represent the surface of an object. Similarly, embodiments of the present invention are illustrated with reference to data blocks 110 comprising 4.times.4 arrays of pixels (spans), but other data block configurations may also be used.

Colors, texture coordinates, and depths (c, t, z) are associated with vertices 120(a), 120(b), 120(c) of primitive 100. Other attributes, such as fog and alpha (not shown) may also be assigned to vertices. These vertex properties are then interpolated to provide values for all primitive locations (x, y), which may be mapped to the pixels of data blocks 110. For the disclosed representation, data blocks 110(b) are spans for which all component pixels are mapped from locations within primitive 100. Data blocks 110(a) are spans for which pixel values are mapped from locations that straddle one or more boundaries of primitive 100. That is, not all pixels of data blocks 110(a) correspond to locations within primitive 100.

FIG. 2 represents one embodiment of a graphics processing pipeline 200 to implement can conversion. Z-data is read 210 from the entries of a z-buffer to which a given primitive maps. Vertex data for the primitive is interpolated 220 to generate, e.g. color, texture, and z data for each primitive location. For example, z-data for each location (x, y) of a primitive may be generated from the primitive's vertex data, using a surface function of the form z=C.sub.0 +C.sub.x.multidot.x+C.sub.y.multidot.y, as discussed below. Color values and texture coordinates may be generated for each location during this stage as well.

In subsequent stages of pipeline 200, image-refining techniques, such as texture mapping, bump mapping, alpha-blending and the like, may be executed 230. A z-test 240 determines which locations of the primitive, if any, contribute their color values to the frame buffer, i.e. which portions of the primitive will be visible in the 2D image. If the z-value determined for a location passes the z-test, the appropriate entries in the frame and z-buffers are updated with the color and z-values, respectively, of the primitive location. Otherwise, the values are discarded.

The transfer of graphics-data between the graphics engine and memory locations in the frame and z-buffers, reduces the available memory bandwidth. For memory architectures like UMA, this reduction can have a detrimental effect on a computer system's overall performance. Various methods have been proposed for reducing the bandwidth impact of texture data transfers. The present invention provides a mechanism for reducing the impact of depth-buffering and its associated data transfers on system performance.

FIG. 3 is a block level diagram of one embodiment of a computer system 300 that implements z-compression in accordance with the present invention. Computer system 300 includes a processor core 310, a graphics core 320 and a memory system 330. Processor core 310 and graphics core 320 are coupled to a bus or memory channel 340 to transfer data to and from memory system 330. The dashed line indicates a boundary of an integrated circuit die 370 for an embodiment of computer system 300 in which processor core 310 and graphics core 320 are integrated on a single chip. This embodiment of computer system 300 is likely to implement a unified memory architecture (UMA), for which the features of the present invention may provide significant advantages. The present invention is not, however, limited to computer systems that employ integrated graphics and processor cores or UMA.

For the disclosed embodiment of computer system 300, memory system 330 is shown straddling a boundary of die 370 to indicate that it may include on-chip and off-chip components. For example, memory system 330 typically includes one or more caches located on circuit die 370 and a main memory that is located on a separate circuit die. Memory system 330 further comprises a z-buffer 350 and a z-status table (ZST) 360, portions of which may be distributed between on and off-chip memory structures (FIG. 4). As discussed below in greater detail, ZST 360 provides status information for associated entries in z-buffer 350. This status information may be used to reduce or eliminate data transfers on memory channel 340.

One embodiment of ZST 360 includes entries to track a current status for each block of z-data stored in z-buffer 350. The status indicates how the corresponding z-data block is stored and may be used to manage the transfer of data between graphics core 320 and memory 330. The status may indicate, for example, whether z-data for a particular span is in a compressed format or an uncompressed format, or whether it has a reference value that may be provided from a local storage location, such as a register. Compressed z-data may be transferred with significantly lower impact on the bandwidth of memory channel 340 than uncompressed data. Further, z-data that is available in, e.g., a local register, need not consume any memory bandwidth at all. One or more components of graphics core 320 use ZST 350 to manage z-data transfers more efficiently and with lower impact on the bandwidth of the memory channel.

For one embodiment of ZST 360, each entry stores a 2-bit status code to indicate a data status for a corresponding data block. Table 1 summarizes one set of 4-bit status codes that may be used.

      TABLE 1
       Code     Status          Access
        00      Cleared         Z-value remains at initialized value.
                                Retrieve from local register
        01      Uncompressed    Z-value stored in uncompressed
                                format.
        10      Compressed      Z-value stored in compressed
                                format. Decompress retrieved value
        11      Reserved        NA

    Hit         = Tag_Match & No_Blocking &
                [(UNC & QW_Match.vertline.CMP.vertline.CLEAR]
    Partial_Hit = Tag_Match & No_Blocking & (UNC & !QW_Match)
    Miss        = !Tag_Match

        Entry_Size        = 16-bit Z-mode?   32:16
        PageX             = 16-bit Z-mode?   X[8:5]:X[8:4]
        PageY             = Y[8:2]
        Byte_Index        = 16-bit Z-mode?   X[4:0]:X[3:0]

    TABLE 2
                                     Previous Status
                                                      Un-
            Data          Cleared       Compressed    compressed
    Updates Type/Value    (CLR)         (CMP)         (UNC)
    Stencil Single value  Retain CLRD   Retain CMP    Update
    Data    for block     IF value =    status        stencil only,
                          CLRD value    (update       (retain UNC
                          Update to     stencil       status)
                          CMP status    only)
                          otherwise
    Stencil Multiple      Update to     Update to     Retain UNC
    Data    values for    UNC status    UNC status    status,
            block         (update stencil, (update stencil, (update
                          update z      update z      stencil)
                          with cleared  with cleared
                          value)        value)
    Z Data  Compressible* Update to     Retain CMP    Update to
                          CMP status    status        CMP status
                                        (update       (update
                                        compressed z  compressed
                                        block only)   z-block
                                                      only)
    Z Data  Un-           Update to     Updated to    Retain UNC
            compressible  UNC status    UNC status    status
                          (update z-    (update z-    (update z-
                          values only)  values only)  values only)
    Z &     Compressible# Update to     Retain CMP    Update to
    Stencil               CMP status    status        CMP status
    Data                  (update       (update       (update
                          all values)   all values)   all values)
    Z &     Un-           Update to     Update to     Retain UNC
    Stencil compressible  UNC status    UNC status    status
    Data                  (update       (update       (update all
                          all values)   all values)   values)
    *Z-data compressibility may be determined using method of FIG.10C or a
     comparable method.
    #Both z-data & stencil data (if present) meet compressibility criteria
     Either z-data or stencil data or both fail to meet compressibility
     criteria

    TABLE 3
    State
    Variable      Description                             Bits
    Compression   If enabled (1), a valid data status       1
    Enable        array is assumed to exist.
    Status        Specifies the base address of the        12
    Bits Base     array in which the status bits are stored
    Address       (ZST). This may be, for example, the base
                  address of the memory map described in
                  conjunction with FIG. 7.
    Clearing      Provides a hook for performing fast clears   1
                  of all or a portion of the Z-buffer. If a
                  primitive with Z/stencil values identical
                  to those in the "cleared" SVs is
                  sent to the graphics system with this
                  bit set, the HW can eliminate the
                  corresponding accesses to the z/stencil
                  buffers altogether. The status of the
                  data block is updated to "cleared" and
                  subsequent accesses use the "cleared" value
                  stored in the SV.
    Force         Provides a hook for performing fast       1
    Decompression decompression of the Z-buffer or any part
                  of it. If enabled, the Z/stencil values
                  for pixels covered by the rendering
                  primitives will be read in their current
                  format and written back to memory in
                  uncompressed format.
    Cleared Stencil Specifies the reference stencil value.    8
    Value
    Cleared       Specifies the reference z-value for the z-buffer.  24
    Z-Value       This is the value to which all pixels are
                  initialized. It typically represents the z-location
                  (depth) of the back clipping plane for the
                  image space.

• Inventors
  Peled, Guy; Sperber, Zeev; Orenstein, Doron; Savranski, Guiliermo;
• Assignee
  Intel Corporation (Santa Clara, CA)
• Published
  Apr-20-2004
• Current US Classes:
  345/422
  345/555
  345/556
  718/108
• Application #
  608619
• International Classes
  G06T 009/00
• Field of Search
  345/555 345/422 345/530 345/561-563 345/501 345/421 345/522 345/556 382/232 382/234 710/264 710/260 712/228 709/107 709/108 709/103 709/100 709/102
• Examiner
  Tung; Kee M.
• Agent
  Blakely, Sokoloff, Taylor & Zafman LLP
• US Patent References:
  4612612
  4654790
  4910656
  5371849
  5428761
  5696927
  5729669
  5808618
  5812150
  5819017
  5864859
  5870095
  5875454
  6014728
  6104837
  6188394
  6240419
  6253287
  6348919
  6373482
  6407741