Abstract: Within a processor, speculative finishes of load instructions only are tracked in a speculative finish table by maintaining an oldest load instruction of a thread in the speculative finish table after data is loaded for the oldest load instruction, wherein a particular queue index tag assigned to the oldest load instruction by an execution unit points to a particular entry in the speculative finish table, wherein the oldest load instruction is waiting to be finished dependent upon an error check code result. Responsive to a flow unit receiving the particular queue index tag with an indicator that the error check code result for data retrieved for the oldest load instruction is good, finishing the oldest load instruction in the particular entry pointed to by the queue index tag and writing an instruction tag stored in the entry for the oldest load instruction out of the speculative finish table for completion.

Abstract: Handling unaligned load operations, including: receiving a request to load data stored within a range of addresses; determining that the range of addresses includes addresses associated with a plurality of caches, wherein each of the plurality of caches are associated with a distinct processor slice; issuing, to each distinct processor slice, a request to load data stored within a cache associated with the distinct processor slice, wherein the request to load data stored within the cache associated with the distinct processor slice includes a portion of the range of addresses; executing, by each distinct processor slice, the request to load data stored within the cache associated with the distinct processor slice; and receiving, over a plurality of data communications busses, execution results from each distinct processor slice, wherein each data communications busses is associated with one of the distinct processor slices.

Abstract: Handling unaligned load operations, including: receiving a request to load data stored within a range of addresses; determining that the range of addresses includes addresses associated with a plurality of caches, wherein each of the plurality of caches are associated with a distinct processor slice; issuing, to each distinct processor slice, a request to load data stored within a cache associated with the distinct processor slice, wherein the request to load data stored within the cache associated with the distinct processor slice includes a portion of the range of addresses; executing, by each distinct processor slice, the request to load data stored within the cache associated with the distinct processor slice; and receiving, over a plurality of data communications busses, execution results from each distinct processor slice, wherein each data communications busses is associated with one of the distinct processor slices.

Abstract: Managing an issue queue for fused instructions and paired instructions in a microprocessor including dispatching a fused instruction to a first entry in a double issue queue; dispatching two paired instructions to a second entry in the double issue queue; issuing the fused instruction during a single cycle to an execution unit in response to determining, by the issue queue logic, that the fused instruction is ready to issue; and issuing, by the issue queue logic, the first instruction of the two paired instructions to the execution unit in response to determining, by the issue queue logic, that the first instruction of the two paired instructions is ready to issue.

Abstract: Managing an issue queue for fused instructions and paired instructions in a microprocessor including dispatching a fused instruction to a first entry in a double issue queue; dispatching two paired instructions to a second entry in the double issue queue; issuing the fused instruction during a single cycle to an execution unit in response to determining, by the issue queue logic, that the fused instruction is ready to issue; and issuing, by the issue queue logic, the first instruction of the two paired instructions to the execution unit in response to determining, by the issue queue logic, that the first instruction of the two paired instructions is ready to issue.

Abstract: Managing an issue queue for fused instructions and paired instructions in a microprocessor including dispatching a fused instruction to a first entry in a double issue queue; dispatching two paired instructions to a second entry in the double issue queue; issuing the fused instruction during a single cycle to an execution unit in response to determining, by the issue queue logic, that the fused instruction is ready to issue; and issuing, by the issue queue logic, the first instruction of the two paired instructions to the execution unit in response to determining, by the issue queue logic, that the first instruction of the two paired instructions is ready to issue.

Abstract: Managing an issue queue for fused instructions and paired instructions in a microprocessor including dispatching a fused instruction to a first entry in a double issue queue; dispatching two paired instructions to a second entry in the double issue queue; issuing the fused instruction during a single cycle to an execution unit in response to determining, by the issue queue logic, that the fused instruction is ready to issue; and issuing, by the issue queue logic, the first instruction of the two paired instructions to the execution unit in response to determining, by the issue queue logic, that the first instruction of the two paired instructions is ready to issue.

Abstract: A processor includes a first level register file, second level register file, and register file mapper. The first and second level register files are comprised of physical registers, with the first level register file more efficiently accessed relative to the second level register file. The register file mapper is coupled with the first and second level register files. The register file mapper comprises a mapping structure and register file mapper controller. The mapping structure hosts mappings between logical registers and physical registers of the first level register file. The register file mapper controller determines whether to map a destination logical register of an instruction to a physical register in the first level register file. The register file mapper controller also determines, based on metadata associated with the instruction, whether to write data associated with the destination logical register to one of the physical registers of the second level register file.

Abstract: A system and process for managing thread execution includes providing two data register sets coupled to a processor and using, by the processor, the two register sets as first-level registers for thread execution. A portion of main memory or cache memory is assigned as second-level registers where the second-level registers serve as registers of at least one of the two data register sets for executing the threads. Data for the threads may be moved between the first-level registers and second-level registers for different modes of thread processing.

Abstract: Techniques are disclosed for performing a flush and restore of a history buffer (HB) in a processing unit. One technique includes identifying one or more entries of the HB to restore to a register file in the processing unit. For each of the one or more HB entries, a determination is made whether to send the HB entry to the register file via a first restore bus or via a second restore bus, different from the first restore bus, based on contents of the HB entry. Each of the one or more HB entries is then sent to the register file via one of the first restore bus or the second restore bus, based on the determination.

Abstract: Operation of a multi-slice processor that includes execution slices and a dispatch network of the multi-slice processor implementing a hardware level transfer of an execution thread between execution slices. Operation of such a multi-slice processor includes responsive to a thread switch signal: halting dispatch of one or more instructions retrieved from an instruction cache; generating a plurality of instructions to transfer an execution thread from a first execution slice to a second execution slice; and dispatching the plurality of instructions instead of the one or more instructions retrieved from the instruction cache; and transferring, in dependence upon execution of the plurality of instructions from the thread switching instruction generator, the execution thread from the first execution slice to the second execution slice.

Abstract: Techniques are disclosed for performing issue queue snooping for an asynchronous flush and restore of a history buffer (HB) in a processing unit. One technique includes identifying an entry of the HB to restore to a register file in the processing unit. A restore ITAG of the HB entry is sent to the register file via a first restore bus, and restore data of the HB entry and the restore ITAG is sent to the register file via a second restore bus. After the restore ITAG and restore data are sent, an instruction is dispatched before the register file obtains the restore data. After it is determined that the restore data is still available via the second restore bus, a snooping operation is performed to obtain the restore data from the second restore bus for the dispatched instruction.

Abstract: A microprocessor has a data-less history buffer. Operands associated with a program instructions are stored in logical registers (LREGs) which are resolvable to physical registers that are not part of the history buffer. Register re-naming maintains integrity of data dependencies for instructions processed out of program order. The history buffer has pointers (RTAGs) to the LREGs. Entries in the history buffer are grouped into ranges. A mapper has a single port associated with each LREG, and each port receives data, from a single range of entries in the history buffer. Multiple entries, one from each range, may be restored concurrently from the history buffer to the mapper.

Abstract: A simultaneous multithreading processor and related method of operating are disclosed. The method comprises dispatching portions of a first instruction to be executed by a respective plurality of execution units of the processor; receiving, at an instruction completion table of the processor, respective finish reports responsive to execution of the portions of the first instruction; determining, using the received finish reports, that all of the portions of the first instruction have been executed; and updating the instruction completion table to indicate that the first instruction is ready for completion.

Abstract: Implementations are disclosed for a simultaneous multithreading processor configured to execute a plurality of threads. In one implementation, the simultaneous multithreading processor is configured to select a first thread of the plurality of threads according to a predefined scheme, and access an instruction completion table to determine whether the first thread is eligible to have a first instruction prioritized. Responsive to determining that the first thread is eligible to have the first instruction prioritized, the simultaneous multithreading processor is further configured to execute the first instruction of the first thread using a dedicated prioritization resource.

Abstract: Techniques are disclosed for performing a flush and restore of a history buffer (HB) in a processing unit. One technique inludes identifying one or more entries of the HB to restore to a register file in the processing unit. For each of the one or more HB entries, a determination is made whether to send the HB entry to the register file via a first restore bus or via a second restore bus, different from the first restore bus, based on contents of the HB entry. Each of the one or more HB entries is then sent to the register file via one of the first restore bus or the second restore bus, based on the determination.

Abstract: Operation of a multi-slice processor that includes execution slices and a dispatch network of the multi-slice processor implementing a hardware level transfer of an execution thread between execution slices. Operation of such a multi-slice processor includes responsive to a thread switch signal: halting dispatch of one or more instructions retrieved from an instruction cache; generating a plurality of instructions to transfer an execution thread from a first execution slice to a second execution slice; and dispatching the plurality of instructions instead of the one or more instructions retrieved from the instruction cache; and transferring, in dependence upon execution of the plurality of instructions from the thread switching instruction generator, the execution thread from the first execution slice to the second execution slice.

Abstract: Operation of a multi-slice processor that includes a plurality of execution slices. Operation of such a multi-slice processor includes: receiving a first instruction indicating a first target register; receiving a second instruction indicating the first target register as a source operand; responsive to the second instruction indicating the first target register as a source operand, updating a dependent count corresponding to the first instruction; and issuing, in dependence upon the dependent count for the first instruction being greater than a dependent count for another instruction, the first instruction to an execution slice of the plurality of execution slices.

Abstract: Embodiments include systems, methods, and computer program products for using a multi-tier hang buster for detecting and breaking out of hang conditions in a processor. One method includes determining a plurality of actions available at each of a plurality of tiers used for breaking out of the hang condition in the processor. The method also includes, after detecting the hang condition on a first thread of the processor, performing one or more actions available at a first tier of the plurality of tiers to break out of the hang condition. The method further includes, after performing the one or more actions at the first tier and determining that the hang condition is still present, performing one or more actions available at one or more second tiers of the plurality of tiers to break out of the hang condition.

Abstract: A multi-slice processor comprising a high-level structure and history buffer. Write backs are no longer associated with the history buffer and the history buffer comprises slices determined by logical register allocation. The history buffer receives a register pointer entry and either releases or restores the entry with functional units comprised in the history buffer.