Flavio M. De Paula scite author profile

Abstract-Post-silicon debug is the problem of determining what's wrong when the fabricated chip of a new design behaves incorrectly. This problem now consumes over half of the overall verification effort on large designs, and the problem is growing worse. We introduce a new paradigm for using formal analysis, augmented with some on-chip hardware support, to automatically compute error traces that lead to an observed buggy state, thereby greatly simplifying the post-silicon debug problem. Our preliminary simulation experiments demonstrate the potential of our approach: we can "backspace" hundreds of cycles from randomly selected states of some sample designs. Our preliminary architectural studies propose some possible implementations and show that the on-chip overhead can be reasonable. We conclude by surveying future research directions.

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Industrial Strength Distributed Explicit State Model Checking

Bingham

Paula³

et al. 2010

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An Effective Guidance Strategy for Abstraction-Guided Simulation

Paula¹,

Hu²

2007

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Despite major advances in formal verification, simulation continues to be the dominant workhorse for functional verification. Abstraction-guided simulation has long been a promising framework for leveraging the power of formal techniques to help simulation reach difficult target states (assertion violations or coverage targets): model checking a smaller, abstracted version of the design avoids complexity blowup, yet computes approximate distances from any state of the actual design to the target; these approximate distances are used during random simulation to guide the simulator. Unfortunately, the promise has.yet to be realized, as the performance of previous work has been unreliable-sometimes great, sometimes poor. The problem is the guidance strategy. In this thesis, we first develop a platform to enable flexible exploration of abstraction-guided simulation-different guidance heuristics and formal tools are easily inserted-while providing the capacity, speed, and Verilog compatibility of a leading industry-standard (logic-simulation) tool, Synopsys VCS. Then, we start by exploring some greedy heuristics and find that they tend to perform poorly, adding too much search overhead for limited ability to escape dead ends (local optima). Based on these experiments, we propose a new guidance strategy, which pursues a more global search and is better able to avoid getting stuck. Experimental results show that our new guidance strategy is highly effective in most cases that are hard for random simulation and beyond the capacity of formal verification.

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An effective guidance strategy for abstraction-guided simulation

Paula

2007

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Despite major advances in formal verification, simulation continues to be the dominant workhorse for functional verification. Abstraction-guided simulation has long been a promising framework for leveraging the power of formal techniques to help simulation reach difficult target states (assertion violations or coverage targets): model checking a smaller, abstracted version of the design avoids complexity blow-up, yet computes approximate distances from any state of the actual design to the target; these approximate distances are used during random simulation to guide the simulator. Unfortunately, the performance of previous work has been unreliable -sometimes great, sometimes poor.The problem is the guidance strategy. Because the abstract distances are approximate, a greedy strategy will get stuck in local optima. Previous works expanded the search horizon to try to avoid dead-ends. We explore such heuristics and find that they tend to perform poorly, adding too much search overhead for limited ability to escape dead-ends. Based on these experiments, we propose a new guidance strategy, which pursues a more global search and is better able to avoid getting stuck. Experiments show that our new guidance strategy is highly effective in most cases that are hard for random simulation and beyond the capacity of formal verification.

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Flavio M. De Paula

Clinical consequences of an individualized dialysate sodium prescription in hemodialysis patients

BackSpace: Formal Analysis for Post-Silicon Debug

Industrial Strength Distributed Explicit State Model Checking

An Effective Guidance Strategy for Abstraction-Guided Simulation

An effective guidance strategy for abstraction-guided simulation

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