Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Various embodiments are generally directed to an apparatus, method and other techniques to determine a secure memory region for a transaction, the secure memory region associated with a security association context to perform one or more of an encryption/decryption operation and an authentication operation for the transaction, perform one or more of the encryption/decryption operation and the authentication operation for the transaction based on the security association context, and cause communication of the transaction.

Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Various embodiments are generally directed to an apparatus, method and other techniques to determine a secure memory region for a transaction, the secure memory region associated with a security association context to perform one or more of an encryption/decryption operation and an authentication operation for the transaction, perform one or more of the encryption/decryption operation and the authentication operation for the transaction based on the security association context, and cause communication of the transaction.

Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Various embodiments are generally directed to an apparatus, method and other techniques to de determine a secure memory region for a transaction, the secure memory region associated with a security association context to perform one or more of an encryption/decryption operation and an authentication operation for the transaction, perform one or more of the encryption/decryption operation and the authentication operation for the transaction based on the security association context, and cause communication of the transaction.

Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Technologies for data compression include a computing device having multiple search agents. Each search agent searches a history of an input stream in parallel for a match to the input stream starting at a position based on an index of the search agent. Each search agent generates in parallel a weight value associated with the corresponding match. The weight value is indicative of a length associated with the match and an encoded length associated with the match. The encoded length is indicative of a number of bits to encode the match. The computing device selects a match based on the weight values. The computing device may output a token for the selected match and encode the token using a Huffman coding. Each search agent may be embodied as a hardware component or a software component such as a thread or process. Other embodiments are described and claimed.

Abstract: Embodiments of systems, methods, and apparatuses for heterogeneous computing are described. In some embodiments, a hardware heterogeneous scheduler dispatches instructions for execution on one or more plurality of heterogeneous processing elements, the instructions corresponding to a code fragment to be processed by the one or more of the plurality of heterogeneous processing elements, wherein the instructions are native instructions to at least one of the one or more of the plurality of heterogeneous processing elements.

Abstract: Various embodiments are generally directed to an apparatus, method and other techniques to de determine a secure memory region for a transaction, the secure memory region associated with a security association context to perform one or more of an encryption/decryption operation and an authentication operation for the transaction, perform one or more of the encryption/decryption operation and the authentication operation for the transaction based on the security association context, and cause communication of the transaction.

Abstract: Technologies for data compression include a computing device having multiple search agents. Each search agent searches a history of an input stream in parallel for a match to the input stream starting at a position based on an index of the search agent. Each search agent generates in parallel a weight value associated with the corresponding match. The weight value is indicative of a length associated with the match and an encoded length associated with the match. The encoded length is indicative of a number of bits to encode the match. The computing device selects a match based on the weight values. The computing device may output a token for the selected match and encode the token using a Huffman coding. Each search agent may be embodied as a hardware component or a software component such as a thread or process. Other embodiments are described and claimed.

Abstract: A multi-threaded processor may support efficient pattern matching techniques. An input data buffer may be provided, which may be shared between a fast path and a slow path. The processor may retire the data units in the input data buffer that is not required and thus avoids copying the data unit used by the slow path. The data management and the execution efficiency may be enhanced as multiple threads may be created to verify potential pattern matches in the input data stream. Also, the threads, which may stall may exit the execution units allowing other threads to run. Further, the problem of state explosion may be avoided by allowing the creation of parallel threads, using the fork instruction, in the slow path.

Abstract: Described are apparatuses, methods and storage media associated with performing deflate decompression using multiple parallel content addressable memory cells.

Abstract: Described are apparatuses, methods and storage media associated with performing deflate decompression using multiple parallel content addressable memory cells.

Abstract: A multi-threaded processor may support efficient pattern matching techniques. An input data buffer may be provided, which may be shared between a fast path and a slow path. The processor may retire the data units in the input data buffer that is not required and thus avoids copying the data unit used by the slow path. The data management and the execution efficiency may be enhanced as multiple threads may be created to verify potential pattern matches in the input data stream. Also, the threads, which may stall may exit the execution units allowing other threads to run. Further, the problem of state explosion may be avoided by allowing the creation of parallel threads, using the fork instruction, in the slow path.

Abstract: A multi-threaded processor may support efficient pattern matching techniques. An input data buffer may be provided, which may be shared between a fast path and a slow path. The processor may retire the data units in the input data buffer that is not required and thus avoids copying the data unit used by the slow path. The data management and the execution efficiency may be enhanced as multiple threads may be created to verify potential pattern matches in the input data stream. Also, the threads, which may stall may exit the execution units allowing other threads to run. Further, the problem of state explosion may be avoided by allowing the creation of parallel threads, using the fork instruction, in the slow path.