Abstract: Embodiments described herein provided for an instruction and associated logic to enable GPGPU program code to access special purpose hardware logic to accelerate dot product operations. One embodiment provides for a graphics processing unit comprising a fetch unit to fetch a single instruction for execution, a decode unit to decode the single instruction into a decoded instruction, wherein the decoded instruction is to cause the graphics processing unit to perform a set of parallel dot product operations on elements of input matrices, and a systolic dot product unit to execute the decoded instruction across one or more parallel processor lanes using multiple systolic layers associated with multiple pipeline stages. The multiple pipeline stages include one or more sets of interconnected multipliers and adders to compute multiple concurrent dot products.

Abstract: Embodiments described herein provided for an instruction and associated logic to enable GPGPU program code to access special purpose hardware logic to accelerate dot product operations. One embodiment provides for a graphics processing unit comprising a fetch unit to fetch an instruction for execution and a decode unit to decode the instruction into a decoded instruction. The decoded instruction is a matrix instruction to cause the graphics processing unit to perform a parallel dot product operation. The GPGPU also includes systolic dot product circuitry to execute the decoded instruction across one or more SIMD lanes using multiple systolic layers, wherein to execute the decoded instruction, a dot product computed at a first systolic layer is to be output to a second systolic layer, wherein each systolic layer includes one or more sets of interconnected multipliers and adders, each set of multipliers and adders to generate a dot product.

Abstract: Embodiments described herein provided for an instruction and associated logic to enable GPGPU program code to access special purpose hardware logic to accelerate dot product operations. One embodiment provides for a graphics processing unit comprising a fetch unit to fetch an instruction for execution and a decode unit to decode the instruction into a decoded instruction. The decoded instruction is a matrix instruction to cause the graphics processing unit to perform a parallel dot product operation. The GPGPU also includes systolic dot product circuitry to execute the decoded instruction across one or more SIMD lanes using multiple systolic layers, wherein to execute the decoded instruction, a dot product computed at a first systolic layer is to be output to a second systolic layer, wherein each systolic layer includes one or more sets of interconnected multipliers and adders, each set of multipliers and adders to generate a dot product.

Abstract: Embodiments described herein provided for an instruction and associated logic to enable GPGPU program code to access special purpose hardware logic to accelerate dot product operations. One embodiment provides for a graphics processing unit comprising a fetch unit to fetch an instruction for execution and a decode unit to decode the instruction into a decoded instruction. The decoded instruction is a matrix instruction to cause the graphics processing unit to perform a parallel dot product operation. The GPGPU also includes a systolic dot product unit to execute the decoded instruction across one or more SIMD lanes using multiple systolic layers, wherein to execute the decoded instruction, a dot product computed at a first systolic layer is to be output to a second systolic layer, wherein each systolic layer includes one or more sets of interconnected multipliers and adders, each set of multipliers and adders to generate a dot product.

Abstract: An processor to facilitate register sharing is disclosed. The processor includes a plurality of execution units (EUs), each including a General Purpose Register File (GRF) having a plurality of registers; and register sharing hardware to divide the plurality of registers into a first set of registers dedicated for execution of a first set of threads and a second set of registers shared for execution of a second set of threads.

Abstract: A mechanism is described for facilitating smart spill/fill data transfers in computing environments. A method of embodiments, as described herein, includes facilitating dividing a kernel into regions including low pressure regions and high pressure regions, where the low pressure regions are associated with low use of registers hosted by a processor of a computing device, while the high pressure regions are associated with high use of the registers. The method may further include transferring of data between memory and the registers based on at least one of the low pressure regions and the high pressure regions.

Abstract: An processor to facilitate register sharing is disclosed. The processor includes a plurality of execution units (EUs), each including a General Purpose Register File (GRF) having a plurality of registers; and register sharing hardware to divide the plurality of registers into a first set of registers dedicated for execution of a first set of threads and a second set of registers shared for execution of a second set of threads.

Abstract: A processor is disclosed. The processor includes an execution unit having a register file having one or more banks of registers to store operand values, an accumulator comprising a pool of registers to store operand values determined to cause a conflict at register banks within the register file and cache circuitry to control storage of the operand values determined to cause a conflict at the register banks from the register file to the pool of registers.

Abstract: A processor is disclosed. The processor includes an execution unit having a register file having one or more banks of registers to store operand values, an accumulator comprising a pool of registers to store operand values determined to cause a conflict at register banks within the register file and cache circuitry to control storage of the operand values determined to cause a conflict at the register banks from the register file to the pool of registers.

Abstract: Embodiments described herein provide a graphics processor in which dependency tracking hardware is simplified via the use of compiler provided software scoreboard information. In one embodiment the shader compiler for shader programs is configured to encode software scoreboard information into each instruction. Dependencies can be evaluated by the shader compiler and provided as scoreboard information with each instruction. The hardware can then use the provided information when scheduling instructions. In one embodiment, a software scoreboard synchronization instruction is provided to facilitate software dependency handling within a shader program. Using software to facilitate software dependency handling and synchronization can simplify hardware design, reducing the area consumed by the hardware. In one embodiment, dependencies can be evaluated by the shader compiler instead of the GPU hardware.

Abstract: Apparatus and method for widened SIMD execution on a limited register file. For example, one embodiment of an apparatus comprises: instruction dispatch circuitry to dispatch instructions of a thread for execution, including a first instruction to indicate a start of a double execution instruction sequence and a second instruction to indicate an end of a double execution instruction sequence; and execution circuitry including single instruction multiple data (SIMD) circuitry, the execution circuitry to execute the double execution instruction sequence in a first pass using a first set of lanes of the SIMD circuitry and to execute the double execution instruction sequence in a second pass following the first pass using a second set of lanes of the SIMD circuitry.

Abstract: Embodiments described herein provide a graphics processor in which dependency tracking hardware is simplified via the use of compiler provided software scoreboard information. In one embodiment the shader compiler for shader programs is configured to encode software scoreboard information into each instruction. Dependencies can be evaluated by the shader compiler and provided as scoreboard information with each instruction. The hardware can then use the provided information when scheduling instructions. In one embodiment, a software scoreboard synchronization instruction is provided to facilitate software dependency handling within a shader program. Using software to facilitate software dependency handling and synchronization can simplify hardware design, reducing the area consumed by the hardware. In one embodiment, dependencies can be evaluated by the shader compiler instead of the GPU hardware.

Abstract: Embodiments described herein provided for an instruction and associated logic to enable GPGPU program code to access special purpose hardware logic to accelerate dot product operations. One embodiment provides for a graphics processing unit comprising a fetch unit to fetch an instruction for execution and a decode unit to decode the instruction into a decoded instruction. The decoded instruction is a matrix instruction to cause the graphics processing unit to perform a parallel dot product operation. The GPGPU also includes a systolic dot product unit to execute the decoded instruction across one or more SIMD lanes using multiple systolic layers, wherein to execute the decoded instruction, a dot product computed at a first systolic layer is to be output to a second systolic layer, wherein each systolic layer includes one or more sets of interconnected multipliers and adders, each set of multipliers and adders to generate a dot product.

Abstract: Embodiments described herein provide a graphics processor in which dependency tracking hardware is simplified via the use of compiler provided software scoreboard information. In one embodiment the shader compiler for shader programs is configured to encode software scoreboard information into each instruction. Dependencies can be evaluated by the shader compiler and provided as scoreboard information with each instruction. The hardware can then use the provided information when scheduling instructions. In one embodiment, a software scoreboard synchronization instruction is provided to facilitate software dependency handling within a shader program. Using software to facilitate software dependency handling and synchronization can simplify hardware design, reducing the area consumed by the hardware. In one embodiment, dependencies can be evaluated by the shader compiler instead of the GPU hardware.

Abstract: A mechanism is described for facilitating smart spill/fill data transfers in computing environments. A method of embodiments, as described herein, includes facilitating dividing a kernel into regions including low pressure regions and high pressure regions, where the low pressure regions are associated with low use of registers hosted by a processor of a computing device, while the high pressure regions are associated with high use of the registers. The method may further include transferring of data between memory and the registers based on at least one of the low pressure regions and the high pressure regions.