Abstract: Methods and apparatus are disclosed for handling fatal computer hardware errors on a computer that include halting data processing operations of the computer upon occurrence of a fatal hardware error; signaling by a source chip of a chipset to the programmable logic device the occurrence of a fatal hardware error; signaling by the programmable logic device to an embedded system microcontroller the occurrence of a fatal hardware error; reading by the embedded system microcontroller through at least one sideband bus from registers in chips of the chipset information regarding the cause of the fatal hardware error; and storing by the embedded system microcontroller the information in non-volatile random access memory of the embedded system microcontroller.

Abstract: A design structure embodied in a machine readable storage medium for designing, manufacturing, and/or testing a design for addressing deficiencies of the art in respect to hypertransport-based switching for multi-CPU systems and for flexibly configurable multi-CPU supported hypertransport switching is provided. The design structure can include a hypertransport switching data processing system. The system can include a CPU and at least two I/O bridges. Each I/O bridge can provide a communications path for data driven to a corresponding peripheral device from the CPU. Notably, the system can include a flexibly configurable hypertransport switch. The switch can include a first configuration adapting the CPU to both of the I/O bridges, and a second configuration adapting the CPU to a first one of the I/O bridges and a second CPU to a second one of the I/O bridges.

Abstract: Embodiments of the invention address deficiencies of the art in respect to hypertransport-based switching for multi-CPU systems and provide a method, system and computer program product for flexibly configurable multi-CPU supported hypertransport switching. In one embodiment of the invention, a hypertransport switching data processing system can be provided. The system can include a CPU and at least two I/O bridges. Each I/O bridge can provide a communications path for data driven to a corresponding peripheral device from the CPU. Notably, the system can include a flexibly configurable hypertransport switch. The switch can include a first configuration adapting the CPU to both of the I/O bridges, and a second configuration adapting the CPU to a first one of the I/O bridges and a second CPU to a second one of the I/O bridges.

Abstract: Methods and apparatus are disclosed for handling fatal computer hardware errors on a computer that include halting data processing operations of the computer upon occurrence of a fatal hardware error; signaling by a source chip of a chipset to the programmable logic device the occurrence of a fatal hardware error; signaling by the programmable logic device to an embedded system microcontroller the occurrence of a fatal hardware error; reading by the embedded system microcontroller through at least one sideband bus from registers in chips of the chipset information regarding the cause of the fatal hardware error; and storing by the embedded system microcontroller the information in non-volatile random access memory of the embedded system microcontroller.

Abstract: A communication bit pattern detection circuit that provides an output signal upon the occurrence of one of several predefined bit patterns for a series of a specified number of bits for a multiple of input signals where each input signal is a continuous stream of serial bit data. The communication bit pattern detection circuit includes a detection stage having combinational logic connected to receive the input signals and providing the logically combined bits to latches of a shift register. The number of latches in the shift register is less than the specified number of bits for the predefined bit patterns. The output of these latches are provided to a logic stage that includes additional combinational logic that provides a nondetection signal. This nondetection signal is provided to indicate that the bits received are not part of any of the predefined bit patterns. The nondetection signal is input to reset a counter.