Abstract: A voltage identifier (VID) sorting system is provided that optimizes processor power and operating voltage guardband at a constant processor frequency. The VID sorting system determines a voltage versus current curve for the processor. The VID sorting system then uses the voltage versus current characteristics to calculate the power for each VID to determine an acceptable range of VIDs within the maximum power criteria. The VID sorting system then tests VIDs in the range and selects a VID from the range to optimize for minimum power and/or maximum voltage guardband at a constant processor frequency.

Abstract: A system and method for reducing store latency in symmetrical multiprocessor systems are provided. Bus agents are provided which monitor reflected ownership requests (Dclaims) to determine if the reflected Dclaim is its own Dclaim. If so, the bus agent determines that it is the winner of the ownership request and can immediately perform data modification using its associated local cache. If the bus agent determines that the reflected Dclaim does not match its own Dclaim, it determines that it is the loser of the ownership request and invalidates the corresponding cache line in its own local cache. The loser bus agent may then send a Read With Intent to Modify request to obtain the data from another cache and place it into its own cache for modification. These operations are performed without the need for a Kill request and without having to perform retries of a losing ownership request.

Abstract: A method and system for mitigating the impact of voltage supply variations on logic built-in self-test (LBIST) results. The method includes, but is not limited to: creating a set of customized LBIST activation patterns during IC design; propagating the activation patterns from the scan-able latches through the non-scan latches to the device under test; propagating the data from the device under test through the non-scan latches to the scan-able latches; capturing the data in a scan-able latch; and performing each test cycle independently such that the impact of voltage supply variations between test cycles is eliminated.

Abstract: A system and method for providing a mediated external exception extension for a microprocessor are provided. With the system and method, in response to an external exception, a hypervisor determines if the associated external interrupt is directed to a logical partition (LPAR) that has external interrupt handling enabled. If so, the hypervisor sets appropriate state restore registers (SRRs) and passes control to an external interrupt handler of the LPAR. If external interrupt handling is not currently enabled by the LPAR, the hypervisor sets a mediated exception request and returns control to the LPAR. Once the operating system of the logical partition re-enables external interrupt handling, a mediated external interrupt occurs, state information for the LPAR is set in the SRRs, and the external interrupt handler of the LPAR is invoked. In this way, external interrupts may be received by the hypervisor even when external interrupt handling is disabled.

Abstract: A system and method for masking a hardware boot sequence are provided. With the system and method, one of the processors of a multiprocessor system is chosen to be a boot processor. The other processors of the multiprocessor system execute masking code that generates electromagnetic and/or thermal signatures that mask the electromagnetic and/or thermal signatures of the actual boot processor. Such masking may involve running the same boot code as the boot processor but without obtaining access to security information, such as the security key for accessing the system. The electromagnetic and/or thermal signatures generated by the execution of the masking code preferably approximate the electromagnetic and/or thermal signatures of the actual boot code executing on the boot processor. In this way, it is difficult to distinguish which processor is the actual boot processor.

Abstract: A system and method for masking a boot sequence by providing a dummy processor are provided. With the system and method, one of the processors of a multiprocessor system is chosen to be a boot processor. The other processors of the multiprocessor system execute masking code that generates electromagnetic and/or thermal signatures that mask the electromagnetic and/or thermal signatures of the actual boot processor. The execution of the masking code on the non-boot processors preferably generates electromagnetic and/or thermal signatures that approximate the signatures of the actual boot code execution on the boot processor. One of the non-boot processors is selected to execute masking code that is different from the other masking code sequence to thereby generate a electromagnetic and/or thermal signature that appears to be unique from an external monitoring perspective.

Abstract: A system and method for masking a boot sequence by running different code on each processor of a multiprocessor system are provided. With the system and method, one of the processors of a multiprocessor system is chosen to be a boot processor. The other processors of the multiprocessor system execute masking code that generates electromagnetic and/or thermal signatures that mask the electromagnetic and/or thermal signatures of the actual boot processor. The masking code executed by each of the non-boot processors may be different from each other and may be randomly selected from a plurality of masking code sequences stored in a masking code storage device. Each execution of masking code on each of the non-boot processors may generate a different electromagnetic and/or thermal signature such that none of the processors appear to be unique from an external monitoring perspective.

Abstract: A system and method for booting a multiprocessor device based on selection of encryption keys to be provided to the processors are provided. With the system and method, a security key and one or more randomly generated key values are provided to a selector mechanism of each processor of the multiprocessor device. A random selection mechanism is provided in pervasive logic that randomly selects one of the processors to be a boot processor and thereby, provides a select signal to the selector of the boot processor such that the boot processor selects the security key. All other processors select one of the one or more randomly generated key values. As a result, only the randomly selected boot processor is able to use the proper security key to decrypt the boot code for execution.

Abstract: A system and method for secure boot across a plurality of processors are provided. With the system and method, boot code is partitioned into a plurality of boot code partitions. Processors of a multiprocessor system are selected to be boot processors and are each provided with a boot code partition to execute in a predetermined boot code sequence. Each processor executes its boot code partition in accordance with the boot code sequence and signals to a next processor the successful and uncompromised execution of its boot code partition. If any of the processors does not signal successful completion and/or uncompromised execution of its boot code partition, the boot operation fails. The processors may be arranged, with regard to the boot operation, in a daisy chain, ring, or master/slave arrangement, for example.