Patent application number | Description | Published |
20080263321 | Universal Register Rename Mechanism for Targets of Different Instruction Types in a Microprocessor - A unified register rename mechanism for targets of different instruction types is provided in a microprocessor. The universal rename mechanism renames destinations of different instruction types using a single rename structure. Thus, an instruction that is updating a floating point register (FPR) can be renamed along with an instruction that is updating a general purpose register (GPR) or vector multimedia extensions (VMX) instructions register (VR) using the same rename structure because the number of architected states for GPR is the same as the number of architected states for FPR and VR. Each destination tag (DTAG) is assigned to one destination. A floating point instruction may be assigned to a DTAG, and then a fixed point instruction may be assigned to the next DTAG and so forth. With a universal rename mechanism, significant silicon and power can be saved by having only one rename structure for all instruction types. | 10-23-2008 |
20080263331 | Universal Register Rename Mechanism for Instructions with Multiple Targets in a Microprocessor - A universal register rename mechanism for instructions with multiple targets using a common destination tag. For each instruction that updates multiple destinations, a single rename entry is allocated to handle all destinations associated with it. A rename entry now consists of a DTAG and a vector to indicate the type of destination(s) that is/are being updated by such a particular instruction. For example, a common DTAG can be assigned to a fixed point unit instruction (FXU) that updates general purpose register (GPR), fixed point exception register (XER), and condition code register (CR) destinations. During flush time, the DTAGs in the recovery link may be used to restore the information indicating that the youngest instruction updates a particular architected register. By using a single, universal rename structure for all types of destinations, a large saving in silicon and power can be realized without the need to sacrifice performance. | 10-23-2008 |
20080313422 | Enhanced Single Threaded Execution in a Simultaneous Multithreaded Microprocessor - A method, system, and computer program product are provided for enhancing the execution of independent loads in a processing unit. The processing unit dispatches a first set of instructions in order from a first buffer for execution. The processing unit receives updated results from the execution of the first set of instructions. The processing unit updates, in a first register, at least one register entry associated with each instruction in the first set of instructions, with the updated results. The processing unit determines if the first set of instructions from the first buffer have completed execution. Responsive to the completed execution of the first set of instructions from the first buffer, the processing unit copies the set of entries from the first register to a second register. | 12-18-2008 |
20080313425 | Enhanced Load Lookahead Prefetch in Single Threaded Mode for a Simultaneous Multithreaded Microprocessor - A method, system, and computer program product are provided for enhancing the execution of independent loads in a processing unit. A processing unit detects if a long-latency miss associated with a load instruction has been encountered. Responsive to a long-latency miss, the processing unit enters a load lookahead mode. Responsive to entering the load lookahead mode, the processing unit dispatches each instruction from a first set of instructions from a first buffer with an associated vector. The processing unit determines if the first set of instructions from the first buffer have completed execution. Responsive to completed execution of the first set of instructions from the first buffer, the processing unit copies the set of vectors from a first vector array to a second vector array. Then the processing unit dispatches a second set of instructions from a second buffer with an associated vector from the second vector array. | 12-18-2008 |
20090037698 | ADAPTIVE ALLOCATION OF RESERVATION STATION ENTRIES TO AN INSTRUCTION SET WITH VARIABLE OPERANDS IN A MICROPROCESSOR - A method and device for adaptively allocating reservation station entries to an instruction set with variable operands in a microprocessor. The device includes logic for determining free reservation station queue positions in a reservation station. The device allocates an issue queue to an instruction and writes the instruction into the issue queue as an issue queue entry. The device reads an operand corresponding to the instruction from a general purpose register and writes the operand into a reservation station using one of the free reservations station positions as a write address. The device writes each reservation station queue position corresponding to said instruction into said issue queue entry. When the instruction is ready for issue to an execution unit, the device reads out the instruction from the issue queue entry the reservation station queue positions to the execution unit. | 02-05-2009 |
20090106534 | System and Method for Implementing a Software-Supported Thread Assist Mechanism for a Microprocessor - A system and computer-implementable method for implementing software-supported thread assist within a data processing system, wherein the data processing system supports processing instructions within at least a first thread and a second thread. An instruction dispatch unit (IDU) places the first thread into a sleep mode. The IDU separates an instruction stream for the second thread into at least a first independent instruction stream and a second independent instruction stream. The first independent instruction stream is processed utilizing facilities allocated to the first thread and the second independent instruction stream is processed utilizing facilities allocated to the second thread. In response to determining a result of the processing in the first independent instruction stream requires write back to registers allocated to the second thread, the IDU sets at least one selection bit to enable selective copying of content within registers allocated to the first thread to registers allocated to the second thread. | 04-23-2009 |
20090106538 | System and Method for Implementing a Hardware-Supported Thread Assist Under Load Lookahead Mechanism for a Microprocessor - The present invention includes a system and method for implementing a hardware-supported thread assist under load lookahead mechanism for a microprocessor. According to an embodiment of the present invention, hardware thread-assist mode can be activated when one thread of the microprocessor is in a sleep mode. When load lookahead mode is activated, the fixed point unit copies the content of one or more architected facilities from an active thread to corresponding architected facilities in the first inactive thread. The load-store unit performs at least one speculative load in load lookahead mode and writes the results of the at least one speculative load to a duplicated architected facility in the first inactive thread. | 04-23-2009 |
20100251016 | Issuing Instructions In-Order in an Out-of-Order Processor Using False Dependencies - A mechanism is provided for issuing instructions. An instruction dispatch unit receives an instruction for dispatch to one of a plurality of execution units. The instruction dispatch unit analyzes a tag register to determine whether a previous tag associated with a previous instruction has been stored in the tag register. Responsive to the previous tag associated with the previous instruction failing to be stored in the tag register, the instruction dispatch unit storing a tag corresponding to the instruction in the tag register. The instruction dispatch unit dispatches the instruction to an issue queue for issue to the one of the plurality of execution units. | 09-30-2010 |
20100262807 | Partial Flush Handling with Multiple Branches Per Group - Mechanisms are provided for partial flush handling with multiple branches per instruction group. The instruction fetch unit sorts instructions into groups. A group may include a floating branch instruction and a boundary branch instruction. For each group of instructions, the instruction sequencing unit creates an entry in a global completion table (GCT), which may also be referred to herein as a group completion table. The instruction sequencing unit uses the GCT to manage completion of instructions within each outstanding group. Because each group may include up to two branches, the instruction sequencing unit may dispatch instructions beyond the first branch, i.e. the floating branch. Therefore, if the floating branch results in a misprediction, the processor performs a partial flush of that group, as well as a flush of every group younger than that group. | 10-14-2010 |
20100262967 | Completion Arbitration for More than Two Threads Based on Resource Limitations - A mechanism is provided for thread completion arbitration. The mechanism comprises executing more than two threads of instructions simultaneously in the processor, selecting a first thread from a first subset of threads, in the more than two threads, for completion of execution within the processor, and selecting a second thread from a second subset of threads, in the more than two threads, for completion of execution within the processor. The mechanism further comprises completing execution of the first and second threads by committing results of the execution of the first and second threads to a storage device associated with the processor. At least one of the first subset of threads or the second subset of threads comprise two or more threads from the more than two threads. The first subset of threads and second subset of threads have different threads from one another. | 10-14-2010 |
20110283096 | REGISTER FILE SUPPORTING TRANSACTIONAL PROCESSING - A processor includes an instruction sequencing unit, execution unit, and multi-level register file including a first level register file having a lower access latency and a second level register file having a higher access latency. Responsive to the processor processing a second instruction in a transactional code section to obtain as an execution result a second register value of the logical register, the mapper moves a first register value of the logical register to the second level register file, places the second register value in the first level register file, marks the second register value as speculative, and replaces a first mapping for the logical register with a second mapping. Responsive to unsuccessful termination of the transactional code section, the mapper designates the second register value in the first level register file as invalid so that the first register value in the second level register file becomes the working value. | 11-17-2011 |
20110302392 | INSTRUCTION TRACKING SYSTEM FOR PROCESSORS - A method and apparatus for tracking instructions in a processor. A completion unit in the processor receives an instruction group to add to a table to form a received instruction group. In response to receiving the received instruction group, the completion unit determines whether an entry is present that contains a previously stored instruction group in a first location and has space for storing the received instruction group. In response to the entry being present, the completion unit stores the received instruction group in a second location in the entry to form a stored instruction group. | 12-08-2011 |
20120072700 | MULTI-LEVEL REGISTER FILE SUPPORTING MULTIPLE THREADS - A processor includes an instruction fetch unit, an issue queue coupled to the instruction fetch unit, an execution unit coupled to the issue queue, and a multi-level register file including a first level register file having lower access latency and a second level register file having higher access latency. Each of the first and second level register files includes a plurality of physical registers for holding operands that is concurrently shared by a plurality of threads. The processor further includes a mapper that, at dispatch of an instruction specifying a source logical register from the instruction fetch unit to the issue queue, initiates a swap of a first operand associated with the source logical register that is in the second level register file with a second operand held in the first level register file. The issue queue, following the swap, issues the instruction to the execution unit for execution. | 03-22-2012 |
20120204009 | MULTI-LEVEL REGISTER FILE SUPPORTING MULTIPLE THREADS - A processor includes an instruction fetch unit, an issue queue coupled to the instruction fetch unit, an execution unit coupled to the issue queue, and a multi-level register file including a first level register file having lower access latency and a second level register file having higher access latency. Each of the first and second level register files includes a plurality of physical registers for holding operands that is concurrently shared by a plurality of threads. The processor further includes a mapper that, at dispatch of an instruction specifying a source logical register from the instruction fetch unit to the issue queue, initiates a swap of a first operand associated with the source logical register that is in the second level register file with a second operand held in the first level register file. The issue queue, following the swap, issues the instruction to the execution unit for execution. | 08-09-2012 |
20120216004 | THREAD TRANSITION MANAGEMENT - Various systems, processes, products, and techniques may be used to manage thread transitions. In particular implementations, a system and process for managing thread transitions may include the ability to determine that a transition is to be made regarding the relative use of two data register sets and determine, based on the transition determination, whether to move thread data in at least one of the data register sets to second-level registers. The system and process may also include the ability to move the thread data from at least one data register set to second-level registers based on the move determination. | 08-23-2012 |
20130305022 | Speeding Up Younger Store Instruction Execution after a Sync Instruction - Mechanisms are provided, in a processor, for executing instructions that are younger than a previously dispatched synchronization (sync) instruction is provided. An instruction sequencer unit of the processor dispatches a sync instruction. The sync instruction is sent to a nest of one or more devices outside of the processor. The instruction sequencer unit dispatches a subsequent instruction after dispatching the sync instruction. The dispatching of the subsequent instruction after dispatching the sync instruction is performed prior to receiving a sync acknowledgement response from the nest. The instruction sequencer unit performs a completion of the subsequent instruction based on whether completion of the subsequent instruction is dependent upon receiving the sync acknowledgement from the nest and completion of the sync instruction. | 11-14-2013 |
20130346731 | INSTRUCTION TRACKING SYSTEM FOR PROCESSORS - Instructions are tracked in a processor. A completion unit in the processor receives an instruction group to add to a table to form a received instruction group. In response to receiving the received instruction group, the completion unit determines whether an entry is present that contains a previously stored instruction group in a first location and has space for storing the received instruction group. In response to the entry being present, the completion unit stores the received instruction group in a second location in the entry to form a stored instruction group. | 12-26-2013 |
20140122840 | EFFICIENT USAGE OF A MULTI-LEVEL REGISTER FILE UTILIZING A REGISTER FILE BYPASS - A processor includes an execution unit, a first level register file, a second level register file, a plurality of storage locations and a register file bypass controller. 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 bypass controller is coupled with the execution unit and second level register file. The register file bypass controller determines whether an instruction indicates a logical register is unmapped from a physical register in the first level register file. The register file controller also loads data into one of the storage locations and selects one of the storage locations as input to the execution unit, without mapping the logical register to one of the physical registers in the first level register file. | 05-01-2014 |
20140122841 | EFFICIENT USAGE OF A REGISTER FILE MAPPER AND FIRST-LEVEL DATA REGISTER FILE - 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. | 05-01-2014 |
20140122842 | EFFICIENT USAGE OF A REGISTER FILE MAPPER MAPPING STRUCTURE - A processor with a register file mapper can use a hasher to improve the distribution of mappings within a mapping structure. The hasher generates a value based, at least in part, on a thread identifier and logical register identifier. The hash value is used as an index value into the mapping structure. The hashing algorithm is chosen to provide a more even distribution of mappings within the mapping structure, reducing the amount of data written from a first level register file to a second level register file. | 05-01-2014 |
20140143523 | SPECULATIVE FINISH OF INSTRUCTION EXECUTION IN A PROCESSOR CORE - In a processor core, high latency operations are tracked in entries of a data structure associated with an execution unit of the processor core. In the execution unit, execution of an instruction dependent on a high latency operation tracked by an entry of the data structure is speculatively finished prior to completion of the high latency operation. Speculatively finishing the instruction includes reporting an identifier of the entry to completion logic of the processor core and removing the instruction from an execution pipeline of the execution unit. The completion logic records dependence of the instruction on the high latency operation and commits execution results of the instruction to an architected state of the processor only after successful completion of the high latency operation. | 05-22-2014 |
20140258691 | THREAD TRANSITION MANAGEMENT - Various systems, processes, products, and techniques may be used to manage thread transitions. In particular implementations, a system and process for managing thread transitions may include the ability to determine that a transition is to be made regarding the relative use of two data register sets and determine, based on the transition determination, whether to move thread data in at least one of the data register sets to second-level registers. The system and process may also include the ability to move the thread data from at least one data register set to second-level registers based on the move determination. | 09-11-2014 |