Abstract: A computing system to obtain an output includes a multi-plane rendering module includes a renderer receives a plurality of graphical objects to generate one or more image planes of object data, a resampler upscales lower resolution image planes to a higher resolution used by the output image, and a rasterizer combine pixels from a common location in the plurality of image planes after each image plane is upsampled to the higher resolution. The renderer receives one of the graphical objects having a location value along a z-axis of the scene, determines which of a plurality of image planes the graphical objects is located using the z-axis location for the graphical object, each of the planes possess a corresponding image resolution, and renders the graphical object into the image plane at the image resolution corresponding determined image plane.

Abstract: Systems, apparatuses and methods may provide away to render edges of an object defined by multiple tessellation triangles. More particularly, systems, apparatuses and methods may provide a way to perform anti-aliasing at the edges of the object based on a coarse pixel rate, where the coarse pixels may be based on a coarse Z value indicate a resolution or granularity of detail of the coarse pixel. The systems, apparatuses and methods may use a shader dispatch engine to dispatch raster rules to a pixel shader to direct the pixel shader to include, in a tile and/or tessellation triangle, one more finer coarse pixels based on a percent of coverage provided by a finer coarse pixel of a tessellation triangle at or along the edge of the object.

Abstract: Systems, apparatuses and methods may provide away to render edges of an object defined by multiple tessellation triangles. More particularly, systems, apparatuses and methods may provide a way to perform anti-aliasing at the edges of the object based on a coarse pixel rate, where the coarse pixels may be based on a coarse Z value indicate a resolution or granularity of detail of the coarse pixel. The systems, apparatuses and methods may use a shader dispatch engine to dispatch raster rules to a pixel shader to direct the pixel shader to include, in a tile and/or tessellation triangle, one more finer coarse pixels based on a percent of coverage provided by a finer coarse pixel of a tessellation triangle at or along the edge of the object.

Abstract: In one example, an apparatus comprises processing circuitry to analyze a program at compile time to determine a set of latency parameters associated with instruction sets implemented to execute the program and select a latency management technique based at least in part on the set of latency parameters associated with instruction sets implemented to execute the program. Other examples may be described and claimed.

Abstract: Systems, methods and apparatuses may provide for technology to reduce rendering overhead associated with light field displays. The technology may conduct data formatting, re-projection, foveation, tile binning and/or image warping operations with respect to a plurality of display planes in a light field display.

Abstract: In an example, an apparatus comprises a plurality of execution units comprising at least a first type of execution unit and a second type of execution unit and logic, at least partially including hardware logic, to analyze a workload and assign the workload to one of the first type of execution unit or the second type of execution unit. Other embodiments are also disclosed and claimed.

Abstract: One embodiment provides a graphics processor comprising a hardware graphics rendering pipeline configured to perform multisample anti-aliasing, the hardware graphics rendering pipeline including pixel processing logic to determine that each sample location of a pixel of a multisample surface is associated with a clear value and resolve a color value for the pixel to a non-multisample surface via a write of metadata to indicate that the pixel has the clear value. The resolve can be a stenciled resolve that automatically bypasses execution of a pixel shader for pixels having clear color data.

Abstract: Embodiments are generally directed to tile-based multiple resolution rendering of images. An embodiment of an apparatus includes one or more processor cores; a plurality of tiling bins, the plurality of tiling bins including a bin for each of a plurality of tiles in an image; and a memory to store data for rendering of an image in one or more of a plurality of resolutions. The apparatus is to generate, in the memory, storage for a resolution setting for each the plurality of tiling bins and storage for a final render target, each tile of the final render target being rendered based on a respective tiling bin in the plurality of tiling bins.

Abstract: Embodiments are generally directed to GPU mixed primitive topology type processing. An embodiment of an apparatus includes one or more processor cores; and a memory to store data for graphics processing, wherein the one or more processing cores are to generate in the memory a vertex buffer to store vertex data for a mesh to be rendered and an index buffer to index the vertex data stored in the vertex buffer, the index buffer being structured to include index data for multiple primitive topology types. The one or more processor cores are to process the index data for the plurality of primitive topology types from the index buffer and fetch vertex data from the vertex buffer; and are to set up each primitive topology type of the plurality of primitive topology types for processing in a single draw operation.

Abstract: A computing system to obtain an output includes a multi-plane rendering module includes a renderer receives a plurality of graphical objects to generate one or more image planes of object data, a resampler upscales lower resolution image planes to a higher resolution used by the output image, and a rasterizer combine pixels from a common location in the plurality of image planes after each image plane is upsampled to the higher resolution. The renderer receives one of the graphical objects having a location value along a z-axis of the scene, determines which of a plurality of image planes the graphical objects is located using the z-axis location for the graphical object, each of the planes possess a corresponding image resolution, and renders the graphical object into the image plane at the image resolution corresponding determined image plane.

Abstract: One embodiment provides a graphics processor comprising a hardware graphics rendering pipeline configured to perform multisample anti-aliasing, the hardware graphics rendering pipeline including pixel processing logic to determine that each sample location of a pixel of a multisample surface is associated with a clear value and resolve a color value for the pixel to a non-multisample surface via a write of metadata to indicate that the pixel has the clear value.

Abstract: A control surface tracks an individual cacheline in the original surface for frequent data values. If so, control surface bits are set. When reading a cacheline from memory, first the control surface bits are read. If they happen to be set, then the original memory read is skipped altogether and instead the bits from the control surface provide the value for the entire cacheline.

Abstract: In one example, an apparatus comprises processing circuitry to analyze a program at compile time to determine a set of latency parameters associated with instruction sets implemented to execute the program and select a latency management technique based at least in part on the set of latency parameters associated with instruction sets implemented to execute the program. Other examples may be described and claimed.

Abstract: An embodiment of a graphics apparatus may include a tile candidate identifier to determine if a compute kernel is a tile candidate, and a compute kernel tiler communicatively coupled to the tile candidate identifier to tile the compute kernel if the compute kernel is determined to be a tile candidate. Other embodiments are disclosed and claimed.

Abstract: An embodiment of a graphics command coordinator apparatus may include a commonality identifier to identify a commonality between a first graphics command corresponding to a first frame and a second graphics command corresponding to a second frame, a commonality analyzer communicatively coupled to the commonality identifier to determine if the first graphics command and the second graphics command can be processed together based on the commonality identified by the commonality identifier, and a commonality indicator communicatively coupled to the commonality analyzer to provide an indication that the first graphics command and the second graphics command are to be processed together. Other embodiments are disclosed and claimed.

Abstract: A control surface tracks an individual cacheline in the original surface for frequent data values. If so, control surface bits are set. When reading a cacheline from memory, first the control surface bits are read. If they happen to be set, then the original memory read is skipped altogether and instead the bits from the control surface provide the value for the entire cacheline.

Abstract: Systems, apparatuses and methods may provide away to render edges of an object defined by multiple tessellation triangles. More particularly, systems, apparatuses and methods may provide a way to perform anti-aliasing at the edges of the object based on a coarse pixel rate, where the coarse pixels may be based on a coarse Z value indicate a resolution or granularity of detail of the coarse pixel. The systems, apparatuses and methods may use a shader dispatch engine to dispatch raster rules to a pixel shader to direct the pixel shader to include, in a tile and/or tessellation triangle, one more finer coarse pixels based on a percent of coverage provided by a finer coarse pixel of a tessellation triangle at or along the edge of the object.

Abstract: An embodiment of a conditional shader apparatus may include a conditional pixel shader to determine if one or more pixels meet a shader condition, and a pixel regrouper communicatively coupled to the conditional pixel shader to regroup pixels based on whether the one or more pixels are determined to meet the shader condition. Another embodiment of a conditional shader apparatus may include a thread analyzer to determine if a set of threads meet a thread condition, and a conditional kernel loader communicatively coupled to the thread analyzer to load an appropriate kernel from a set of two or more kernels based on whether the set of threads are determined to meet the thread condition. Other embodiments are disclosed and claimed.

Abstract: An apparatus to facilitate compute optimization is disclosed. The apparatus includes a at least one processor to perform operations to implement a neural network and compute logic to accelerate neural network computations.

Abstract: A control surface tracks an individual cacheline in the original surface for frequent data values. If so, control surface bits are set. When reading a cacheline from memory, first the control surface bits are read. If they happen to be set, then the original memory read is skipped altogether and instead the bits from the control surface provide the value for the entire cacheline.