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    • 2. 发明授权
    • Processor and method providing instruction support for instructions that utilize multiple register windows
    • 处理器和方法为使用多个寄存器窗口的指令提供指令支持
    • US08555038B2
    • 2013-10-08
    • US12790074
    • 2010-05-28
    • Christopher H. OlsonPaul J. JordanJama I. Barreh
    • Christopher H. OlsonPaul J. JordanJama I. Barreh
    • G06F9/00
    • G06F9/30127G06F7/5324G06F9/30032G06F9/30043G06F9/30145G06F9/3824G06F9/384G06F9/3844G06F9/3851G06F9/3867G06F21/556
    • A processor including instruction support for large-operand instructions that use multiple register windows may issue, for execution, programmer-selectable instructions from a defined instruction set architecture (ISA). The processor may also include an instruction execution unit that, during operation, receives instructions for execution from the instruction fetch unit and executes a large-operand instruction defined within the ISA, where execution of the large-operand instruction is dependent upon a plurality of registers arranged within a plurality of register windows. The processor may further include control circuitry (which may be included within the fetch unit, the execution unit, or elsewhere within the processor) that determines whether one or more of the register windows depended upon by the large-operand instruction are not present. In response to determining that one or more of these register windows are not present, the control circuitry causes them to be restored.
    • 包括对使用多个寄存器窗口的大操作数指令的指令支持的处理器可以从定义的指令集架构(ISA)发出用于执行编程器可选择指令的指令。 处理器还可以包括指令执行单元,其在操作期间从指令获取单元接收执行指令,并执行在ISA内定义的大操作数指令,其中大操作数指令的执行取决于多个寄存器 布置在多个寄存器窗口内。 处理器还可以包括控制电路(其可以包括在提取单元,执行单元或处理器内的其他地方),其确定不存在大操作数指令所依赖的寄存器窗口中的一个或多个。 响应于确定这些寄存器窗口中的一个或多个不存在,控制电路使它们被恢复。
    • 5. 发明授权
    • Minimal address state in a fine grain multithreaded processor
    • 细粒度多线程处理器中的最小地址状态
    • US07343474B1
    • 2008-03-11
    • US10881616
    • 2004-06-30
    • Paul J. JordanRobert T. GollaJama I. Barreh
    • Paul J. JordanRobert T. GollaJama I. Barreh
    • G06F9/30
    • G06F9/3867G06F9/3802G06F9/3851
    • In one embodiment, a processor comprises a plurality of pipeline stages and a first circuit operable at a first pipeline stage of the plurality of pipeline stages. The first circuit is configured to maintain a plurality of program counters (PCs), each of which corresponds to one of a plurality of threads that the processor is configured to have concurrently in process with respect to the plurality of pipeline stages. The first circuit is configured to provide a first PC to a second pipeline stage of the plurality of pipeline stages. The first PC is derived from one of the plurality of PCs that corresponds to a first thread of the plurality of threads, and a first instruction entering the second pipeline stage is from the first thread.
    • 在一个实施例中,处理器包括多个流水线级和在多个流水线级的第一流水线级可工作的第一电路。 第一电路被配置为维持多个程序计数器(PC),每个程序计数器(PC)对应于处理器被配置为相对于多个流水线级并行处理的多个线程中的一个。 第一电路被配置为向多个流水线级的第二流水线级提供第一PC。 第一个PC是从与多个线程中的第一个线程相对应的多个PC中的一个导出的,并且进入第二流水线级的第一指令来自第一线程。
    • 6. 发明授权
    • Processor operating mode for mitigating dependency conditions between instructions having different operand sizes
    • 用于缓解具有不同操作数大小的指令之间的依赖条件的处理器操作模式
    • US08504805B2
    • 2013-08-06
    • US12428464
    • 2009-04-22
    • Robert T. GollaPaul J. JordanJama I. BarrehMatthew B. SmittleYuan C. ChouJared C. Smolens
    • Robert T. GollaPaul J. JordanJama I. BarrehMatthew B. SmittleYuan C. ChouJared C. Smolens
    • G06F7/483
    • G06F9/3838G06F9/30032G06F9/30109G06F9/30189
    • Various techniques for mitigating dependencies between groups of instructions are disclosed. In one embodiment, such dependencies include “evil twin” conditions, in which a first floating-point instruction has as a destination a first portion of a logical floating-point register (e.g., a single-precision write), and in which a second, subsequent floating-point instruction has as a source the first portion and a second portion of the same logical floating-point register (e.g., a double-precision read). The disclosed techniques may be applicable in a multithreaded processor implementing register renaming. In one embodiment, a processor may enter an operating mode in which detection of evil twin “producers” (e.g., single-precision writes) causes the instruction sequence to be modified to break potential dependencies. Modification of the instruction sequence may continue until one or more exit criteria are reached (e.g., committing a predetermined number of single-precision writes). This operating mode may be employed on a per-thread basis.
    • 公开了用于减轻指令组之间依赖性的各种技术。 在一个实施例中,这种依赖性包括“恶双”条件,其中第一浮点指令具有作为目的地的逻辑浮点寄存器的第一部分(例如,单精度写入),并且其中第二浮点指令 后续浮点指令作为源的相同逻辑浮点寄存器的第一部分和第二部分(例如,双精度读取)。 所公开的技术可以适用于实现寄存器重命名的多线程处理器。 在一个实施例中,处理器可以进入操作模式,在该操作模式中,恶意孪生“生产者”(例如,单精度写入)的检测导致指令序列被修改以破坏潜在依赖性。 指令序列的修改可以继续,直到达到一个或多个退出标准(例如,提交预定数量的单精度写入)。 该操作模式可以在每个线程的基础上使用。
    • 8. 发明申请
    • PROCESSOR OPERATING MODE FOR MITIGATING DEPENDENCY CONDITIONS
    • 处理器操作模式以减轻依赖性条件
    • US20100274994A1
    • 2010-10-28
    • US12428464
    • 2009-04-22
    • Robert T. GollaPaul J. JordanJama I. BarrehMatthew B. SmittelYuan C. ChouJared C. Smolens
    • Robert T. GollaPaul J. JordanJama I. BarrehMatthew B. SmittelYuan C. ChouJared C. Smolens
    • G06F9/30
    • G06F9/3838G06F9/30032G06F9/30109G06F9/30189
    • Various techniques for mitigating dependencies between groups of instructions are disclosed. In one embodiment, such dependencies include “evil twin” conditions, in which a first floating-point instruction has as a destination a first portion of a logical floating-point register (e.g., a single-precision write), and in which a second, subsequent floating-point instruction has as a source the first portion and a second portion of the same logical floating-point register (e.g., a double-precision read). The disclosed techniques may be applicable in a multithreaded processor implementing register renaming. In one embodiment, a processor may enter an operating mode in which detection of evil twin “producers” (e.g., single-precision writes) causes the instruction sequence to be modified to break potential dependencies. Modification of the instruction sequence may continue until one or more exit criteria are reached (e.g., committing a predetermined number of single-precision writes). This operating mode may be employed on a per-thread basis.
    • 公开了用于减轻指令组之间依赖性的各种技术。 在一个实施例中,这种依赖性包括“恶双”条件,其中第一浮点指令具有作为目的地的逻辑浮点寄存器的第一部分(例如,单精度写入),并且其中第二浮点指令 后续浮点指令作为源的相同逻辑浮点寄存器的第一部分和第二部分(例如,双精度读取)。 所公开的技术可以适用于实现寄存器重命名的多线程处理器。 在一个实施例中,处理器可以进入操作模式,在该操作模式中,恶意孪生“生产者”(例如,单精度写入)的检测导致指令序列被修改以破坏潜在依赖性。 指令序列的修改可以继续,直到达到一个或多个退出标准(例如,提交预定数量的单精度写入)。 该操作模式可以在每个线程的基础上使用。
    • 9. 发明申请
    • Register Error Correction of Speculative Data in an Out-of-Order Processor
    • 在乱序处理器中对投机数据进行寄存器误差校正
    • US20120060057A1
    • 2012-03-08
    • US13295554
    • 2011-11-14
    • Paul J. JordanChristopher H. Olson
    • Paul J. JordanChristopher H. Olson
    • G06F11/14
    • G06F11/10
    • In one embodiment, a processor comprises a first register file configured to store speculative register state, a second register file configured to store committed register state, a check circuit and a control unit. The first register file is protected by a first error protection scheme and the second register file is protected by a second error protection scheme. A check circuit is coupled to receive a value and corresponding one or more check bits read from the first register file to be committed to the second register file in response to the processor selecting a first instruction to be committed. The check circuit is configured to detect an error in the value responsive to the value and the check bits. Coupled to the check circuit, the control unit is configured to cause reexecution of the first instruction responsive to the error detected by the check circuit.
    • 在一个实施例中,处理器包括被配置为存储推测寄存器状态的第一寄存器文件,被配置为存储提交寄存器状态的第二寄存器文件,检查电路和控制单元。 第一个寄存器文件由第一个错误保护方案保护,第二个寄存器文件由第二个错误保护方案保护。 耦合检查电路以响应于处理器选择要提交的第一指令,接收从第一寄存器文件读取的值和对应的一个或多个校验位以提交给第二寄存器堆。 检查电路被配置为响应于该值和校验位来检测该值中的错误。 耦合到检查电路,控制单元被配置为响应于由检查电路检测到的错误而引起第一指令的再次执行。
    • 10. 发明申请
    • Register Error Correction of Speculative Data in an Out-of-Order Processor
    • 在乱序处理器中对投机数据进行寄存器误差校正
    • US20090063899A1
    • 2009-03-05
    • US11849749
    • 2007-09-04
    • Paul J. JordanChristopher H. Olson
    • Paul J. JordanChristopher H. Olson
    • G06F11/07
    • G06F11/10
    • In one embodiment, a processor comprises a first register file configured to store speculative register state, a second register file configured to store committed register state, a check circuit and a control unit. The first register file is protected by a first error protection scheme and the second register file is protected by a second error protection scheme. A check circuit is coupled to receive a value and corresponding one or more check bits read from the first register file to be committed to the second register file in response to the processor selecting a first instruction to be committed. The check circuit is configured to detect an error in the value responsive to the value and the check bits. Coupled to the check circuit, the control unit is configured to cause reexecution of the first instruction responsive to the error detected by the check circuit.
    • 在一个实施例中,处理器包括被配置为存储推测寄存器状态的第一寄存器文件,被配置为存储提交寄存器状态的第二寄存器文件,检查电路和控制单元。 第一个寄存器文件由第一个错误保护方案保护,第二个寄存器文件由第二个错误保护方案保护。 耦合检查电路以响应于处理器选择要提交的第一指令,接收从第一寄存器文件读取的值和对应的一个或多个校验位以提交给第二寄存器堆。 检查电路被配置为响应于该值和校验位来检测该值中的错误。 耦合到检查电路,控制单元被配置为响应于由检查电路检测到的错误而引起第一指令的再次执行。