DOIAbstract
In this chapter, we introduced three fundamental reasons why debugging a multi-processor SoC is intrinsically difficult; (1) limited internal observability, (2) asynchronicity, and (3) non-determinism
In this chapter, we introduced three fundamental reasons why debugging a multi-processor SoC is intrinsically difficult; (1) limited internal observability, (2) asynchronicity, and (3) non-determinism
Parallel programs are more difficult to debug than sequential programs because of their increase in ...
This paper describes the preliminary results of a project investigating approaches to dynamic debugg...
Traditional debug methodologies are limited in their ability to provide debugging support for many-c...
In this chapter, we introduced three fundamental reasons why debugging a multi-processor SoC is intr...
Post-silicon debugging of a system on chip (SOC) is complex due to (1) the intrinsic limits on the i...
Systems with elaborate multiple clock distributions are a necessity, and the authors address the pos...
Hardware vendors are currently transitioning from single-threaded microprocessors to chips that inte...
In this report, we will give an introduction to work presented in the area of debugging large softwa...
TODAY’S SOCS contain multiple programmable processor cores, hardware accelerators, and dedi-cated pe...
Problems in a new System on Chip (SOC) consisting of hardware and embedded software often only show ...
This book describes an approach and supporting infrastructure to facilitate debugging the silicon im...
The main problems associated with debugging concurrent programs are increased complexity, the “probe...
Continuous advances in VLSI technology have made implementation of very complicated systems possible...
International audienceThe prevalent use of systems-on-chip (SoCs) makes them prime targets for softw...
Multicore is here to stay. To keep up with the hardware innovation, software developers mustmove fro...
Parallel programs are more difficult to debug than sequential programs because of their increase in ...
This paper describes the preliminary results of a project investigating approaches to dynamic debugg...
Traditional debug methodologies are limited in their ability to provide debugging support for many-c...
In this chapter, we introduced three fundamental reasons why debugging a multi-processor SoC is intr...
Post-silicon debugging of a system on chip (SOC) is complex due to (1) the intrinsic limits on the i...
Systems with elaborate multiple clock distributions are a necessity, and the authors address the pos...
Hardware vendors are currently transitioning from single-threaded microprocessors to chips that inte...
In this report, we will give an introduction to work presented in the area of debugging large softwa...
TODAY’S SOCS contain multiple programmable processor cores, hardware accelerators, and dedi-cated pe...
Problems in a new System on Chip (SOC) consisting of hardware and embedded software often only show ...
This book describes an approach and supporting infrastructure to facilitate debugging the silicon im...
The main problems associated with debugging concurrent programs are increased complexity, the “probe...
Continuous advances in VLSI technology have made implementation of very complicated systems possible...
International audienceThe prevalent use of systems-on-chip (SoCs) makes them prime targets for softw...
Multicore is here to stay. To keep up with the hardware innovation, software developers mustmove fro...
Parallel programs are more difficult to debug than sequential programs because of their increase in ...
This paper describes the preliminary results of a project investigating approaches to dynamic debugg...
Traditional debug methodologies are limited in their ability to provide debugging support for many-c...
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