The pressure of openness : the hybrid work of linux free/open source kernel developers /

Ratto, Matt.

January 2003

Thesis (Ph. D.)--University of California, San Diego, 2003. / Vita. Includes bibliographical references (leaves 227-238).

Operating System Techniques for Reducing Processor State Pollution

Soares, Livio

31 August 2012

Application performance on modern processors has become increasingly dictated by the use of on-chip structures, such as caches and look-aside buffers. The hierarchical (multi-leveled) design of processor structures, the ubiquity of multicore processor architectures, as well as the increasing relative cost of accessing memory have all contributed to this condition. Our thesis is that operating systems should provide services and mechanisms for applications to more efficiently utilize on-chip processor structures. As such, this dissertation demonstrates how the operating system can improve processor efficiency of applications through specific techniques. Two operating system services are investigated: (1) improving secondary and last-level cache utilization through a run-time cache filtering technique, and (2) improving the processor efficiency of system intensive applications through a new exception-less system call mechanism. With the first mechanism, we introduce the concept of a software pollute buffer and show that it can be used effectively at run-time, with assistance from commodity hardware performance counters, to reduce pollution of secondary on-chip caches. In the second mechanism, we are able to decouple application and operating system execution, showing the benefits of the reduced interference in various processor components such as the first level instruction and data caches, second level caches and branch predictor. We show that exception-less system calls are particularly effective on modern multicore processors. We explore two ways for applications to use exception-less system calls. The first way, which is completely transparent to the application, uses multi-threading to hide asynchronous communication between the operating system kernel and the application. In the second way, we propose that applications can directly use the exception-less system call interface by designing programs that follow an event-driven architecture.

Operating Systems

Processors

Processor Caches

Multicore

0984

Operating System Techniques for Reducing Processor State Pollution

Soares, Livio

31 August 2012

Application performance on modern processors has become increasingly dictated by the use of on-chip structures, such as caches and look-aside buffers. The hierarchical (multi-leveled) design of processor structures, the ubiquity of multicore processor architectures, as well as the increasing relative cost of accessing memory have all contributed to this condition. Our thesis is that operating systems should provide services and mechanisms for applications to more efficiently utilize on-chip processor structures. As such, this dissertation demonstrates how the operating system can improve processor efficiency of applications through specific techniques. Two operating system services are investigated: (1) improving secondary and last-level cache utilization through a run-time cache filtering technique, and (2) improving the processor efficiency of system intensive applications through a new exception-less system call mechanism. With the first mechanism, we introduce the concept of a software pollute buffer and show that it can be used effectively at run-time, with assistance from commodity hardware performance counters, to reduce pollution of secondary on-chip caches. In the second mechanism, we are able to decouple application and operating system execution, showing the benefits of the reduced interference in various processor components such as the first level instruction and data caches, second level caches and branch predictor. We show that exception-less system calls are particularly effective on modern multicore processors. We explore two ways for applications to use exception-less system calls. The first way, which is completely transparent to the application, uses multi-threading to hide asynchronous communication between the operating system kernel and the application. In the second way, we propose that applications can directly use the exception-less system call interface by designing programs that follow an event-driven architecture.

Operating Systems

Processors

Processor Caches

Multicore

0984

Extreme dimensionality reduction for text learning : cluster-generated feature spaces

Boone, Gary Noel

January 2000

No description available.

Artificial intelligence

Operating system principles and constructs for dynamic multi-processor real-time control systems

Forbes, Harold C.

January 1996

No description available.

Computer programming Management

Operating systems (Computers)

Support for multi-weight object, invocations and atomicity in real-time systems

Gheith, Ahmed M.

January 1990

No description available.

Real-time data processing

Operating systems (Computers)

A framework for teaching learners to model by focusing complexity of modeling and simulation tools

Rappin, Noel

January 1998

No description available.

Modeling

Computer simulation

Dynamic management of computation and communication resources to enable secure high-performances applications

Schneck, Phyllis Adele

January 1999

No description available.

Operating systems (Computers)

Computer network protocols

A mixed-strategy page replacement algorithm for a multiprogramming, virtual memory computer

Spafford, Eugene Howard

January 1981

No description available.

Multiprogramming (Electronic computers)

Operating systems (Computers)

Real-time distributed simulation analysis : an application of temporal database and simulation systems research

McLean, Angus L. M. Thom, III

05 1900

No description available.

Operating systems (Computers)

Computer network protocols