Patent application number | Description | Published |
20080263350 | UPDATE IN-USE FLASH MEMORY WITHOUT EXTERNAL INTERFACES - A method, apparatus and program storage device for updating a non-volatile memory in an embedded system is provided. The invention includes detaching the non-volatile memory from all expectable non-volatile memory references, creating a temporary, volatile-memory file system for allocation of volatile memory space as needed for the non-volatile memory update process, copying all procedural code required to perform the non-volatile memory update into the volatile memory, changing the system search path definitions temporarily to point to the volatile memory, and performing the non-volatile memory update. | 10-23-2008 |
20130031419 | Collecting Debug Data in a Secure Chip Implementation - Mechanisms, in a processor chip, are provided for obtaining debug data from on-chip logic of the processor chip while the processor chip is in a secure mode of operation. The processor chip is placed into a secure mode of operation in which access to internal logic of the processor chip to control the internal logic of the processor chip, by mechanisms external to the processor chip, is disabled on a debug interface of the processor chip. A triggering condition of the processor chip is detected that is a trigger for initiated debug data collection from the on-chip logic. Debug data collection is performed from the on-chip logic to generate debug data. Data is output, by the processor chip to an external mechanism, on the debug interface based on the debug data. | 01-31-2013 |
20130031420 | Collecting Debug Data in a Secure Chip Implementation - Mechanisms, in a processor chip, are provided for obtaining debug data from on-chip logic of the processor chip while the processor chip is in a secure mode of operation. The processor chip is placed into a secure mode of operation in which access to internal logic of the processor chip to control the internal logic of the processor chip, by mechanisms external to the processor chip, is disabled on a debug interface of the processor chip. A triggering condition of the processor chip is detected that is a trigger for initiated debug data collection from the on-chip logic. Debug data collection is performed from the on-chip logic to generate debug data. Data is output, by the processor chip to an external mechanism, on the debug interface based on the debug data. | 01-31-2013 |
20130060978 | INTEGRATED LINK CALIBRATION AND MULTI-PROCESSOR TOPOLOGY DISCOVERY - Integrating link calibration and dynamic topology discovery in a multi-processor system establishes a first of a plurality of processors in the multi-processor system as a director of integrated link calibration and dynamic topology discovery. A plurality of high speed interconnects connects the plurality of processors with each other. The director processor directs calibration of each of the plurality of high speed interconnects via a shared hardware resource. The shared hardware resource is shared among the plurality of processors. Topology of the multi-processor system is incrementally discovered as each of the plurality of high speed interconnects is calibrated based on a result of each of the plurality of high speed interconnects being calibrated. | 03-07-2013 |
20130060986 | INTEGRATED LINK CALIBRATION AND MULTI-PROCESSOR TOPOLOGY DISCOVERY - Integrating link calibration and dynamic topology discovery in a multi-processor system establishes a first of a plurality of processors in the multi-processor system as a director of integrated link calibration and dynamic topology discovery. A plurality of high speed interconnects connects the plurality of processors with each other. The director processor directs calibration of each of the plurality of high speed interconnects via a shared hardware resource. The shared hardware resource is shared among the plurality of processors. Topology of the multi-processor system is incrementally discovered as each of the plurality of high speed interconnects is calibrated based on a result of each of the plurality of high speed interconnects being calibrated. | 03-07-2013 |
20130111071 | Self-healing and reconfiguration in an integrated circuit | 05-02-2013 |
20130151829 | Multi-Chip Initialization Using a Parallel Firmware Boot Process - Mechanisms, in a multi-chip data processing system, for performing a boot process for booting each of a plurality of processor chips of the multi-chip data processing system are provided. With these mechanisms, a multi-chip agnostic isolated boot phase operation is performed, in parallel, to perform an initial boot of each of the plurality of processor chips as if each of the processor chips were an only processor chip in the multi-chip data processing system. A multi-chip aware isolated boot phase operation of each of the processor chips is performed in parallel, where each of the processor chips has its own separately configured address space. In addition, a unified configuration phase operation is performed to select a master processor chip from the plurality of processor chips and configure other processor chips in the plurality of processor chips to operate as slave processor chips that are controlled by the master processor chip. | 06-13-2013 |
20140279969 | COMPRESSION/DECOMPRESSION ACCELERATOR PROTOCOL FOR SOFTWARE/HARDWARE INTEGRATION - Embodiments relate to providing a data stream interface for offloading the inflation/deflation processing of data to a stateless compression accelerator. An aspect includes transmitting a request to inflate or deflate a data stream to a compression accelerator. The request may include references to an input buffer for storing input data from the data stream, an output buffer for storing processed input data, and a state data control block for storing a stream state. The stream state is provided to the compression accelerator to continue processing the data stream responsive to the request being a subsequent request. The compression accelerator is instructed to store a current stream state in the state data control block responsive to the request being a non-final request. Accordingly, the current stream state is received from the compression accelerator responsive to the request being a non-final request. The processed input data is received from the compression accelerator. | 09-18-2014 |
20140380319 | ADDRESS TRANSLATION/SPECIFICATION FIELD FOR HARDWARE ACCELERATOR - Embodiments relate an address translation/specification (ATS) field. An aspect includes receiving a work queue entry from a work queue in a main memory by a hardware accelerator, the work queue entry corresponding to an operation of the hardware accelerator that is requested by user-space software, the work queue entry comprising a first ATS field that describes a structure of the work queue entry. Another aspect includes, based on determining that the first ATS field is consistent with the operation corresponding to the work queue entry and the structure of the work queue entry, executing the operation corresponding to the work queue entry by the hardware accelerator. Another aspect includes, based on determining that the first ATS field is not consistent with the operation corresponding to the work queue entry and the structure of the work queue entry, rejecting the work queue entry by the hardware accelerator. | 12-25-2014 |
20150058495 | COMPRESSION/DECOMPRESSION ACCELERATOR PROTOCOL FOR SOFTWARE/HARDWARE INTEGRATION - Embodiments relate to providing a data stream interface for offloading the inflation/deflation processing of data to a stateless compression accelerator. An aspect includes transmitting a request to inflate or deflate a data stream to a compression accelerator. The request may include references to an input buffer for storing input data from the data stream, an output buffer for storing processed input data, and a state data control block for storing a stream state. The stream state is provided to the compression accelerator to continue processing the data stream responsive to the request being a subsequent request. The compression accelerator is instructed to store a current stream state in the state data control block responsive to the request being a non-final request. Accordingly, the current stream state is received from the compression accelerator responsive to the request being a non-final request. The processed input data is received from the compression accelerator. | 02-26-2015 |