目前微处理器系统结构设计已经进入线程级并行的时代。
The microprocessor architecture design has entered the era of thread level parallelism.
对于通用串行应用程序,高效的线程控制方法是实现线程级前瞻、挖据线程级并行性的一个重要组成部分。
The thread control method is an important component to implement thread-level speculation (TLS) and extract thread-level parallelism (TLP) when running general-purpose sequential applications on SCMP.
多年来,处理器制造厂商在不断提高时钟速度和指令级并行性,因此单线程代码不需要修改就可在新的处理器上更快运行。
For years, processor makers consistently delivered increases in clock rates and instruction-level parallelism, so that single-threaded code executed faster on newer processors with no modification.
通过分析影响嵌入式系统性能的主要因素,采用了基于线程概念的嵌入式系统并行设计方法,利用指令级并行来改善系统性能。
By analyzing factors impacting upon the embedded system performance, an embedded system design method based on thread ideas is used, performance is improved with instruction level parallelism.
如果进程希望创建一个系统级调度的线程,会为这个线程创建一个新的并行级别为一的KSEG。
If a thread with system-level scheduling contention is desired, a new KSEG with a concurrency level of one can be created for that thread.
如果进程希望创建一个系统级调度的线程,会为这个线程创建一个新的并行级别为一的KSEG。
If a thread with system-level scheduling contention is desired, a new KSEG with a concurrency level of one can be created for that thread.
应用推荐