Doctor of Philosophy

dissertationElasticity is a design paradigm in which circuits can tolerate arbitrary latency/delay variations in their computation units as well as communication channels. Creating elastic (both synchronous and asynchronous) designs from clocked designs has potential benefits of increased modularity and robustness to variations. Several transformations have been suggested in the literature and each of these require a handshake control network (examples include synchronous elasticization and desynchronization). Elastic control network area and power overheads may become prohibitive. This dissertation investigates different optimization avenues to reduce these overheads without sacrificing the control network performance. First, an algorithm and a tool, CNG, is introduced that generates a control network with minimal total number of join and fork control steering units. Synchronous Elastic FLow (SELF) is a handshake protocol used over synchronous elastic designs. Comparing to its standard eager implementation (that uses eager forks - EForks), lazy SELF can consume less power and area. However, it typically suff ers from combinational cycles and can have inferior performance in some systems. Hence, lazy SELF has been rarely studied in the literature. This work formally and exhaustively investigates the specifi cations, diff erent implementations, and verifi cation of the lazy SELF protocol. Furthermore, several new and existing lazy designs are mapped to hybrid eager/lazy imple-mentations that retain the performance advantage of the eager design but have power and area advantages of lazy implementations, and are combinational-cycle free. This work also introduces a novel ultra simple fork (USFork) design. The USFork has two advantages over lazy forks: it is composed of simpler logic (just wires) and does not form combinational cycles. The conditions under which an EFork can be replaced by a USFork without any performance loss are formally derived. The last optimization avenue discussed in this dissertation is Elastic Bu er Controller (EBC) merging. In a typical synchronous elastic control network, some EBCs may activate their corresponding latches at similar schedules. This work provides a framework for fi nding and merging such controllers in any control network; including open networks (i.e., when the environment abstract is not available or required to be flexible) as well as networks incorporating variable latency units. Replacing EForks with USForks under some equivalence conditions as well as EBC merging have been fully automated in a tool, HGEN. The impact of this work will help achieve elasticity at a reduced cost. It will broaden the class of circuits that can be elasticized with acceptable overhead (circuits that designers would otherwise nd it too expensive to elasticize). In a MiniMIPS processor case study, comparing to a basic control network implementation, the optimization techniques of this dissertation accumulatively achieve reductions in the control network area, dynamic, and leakage power of 73.2%, 68.6%, and 69.1%, respectively

Liquid Clocks - Refinement Types for Time-Dependent Stream Functions

The concept of liquid clocks introduced in this paper is a significant step towards a more precise compile-time framework for the analysis of synchronous and polychromous languages. Compiling languages such as Lustre or SIGNAL indeed involves a number of static analyses of programs before they can be synthesized into executable code, e.g., synchronicity class characterization, clock assignment, static scheduling or causality analysis. These analyses are often equivalent to undecidable problems, necessitating abstracting such programs to provide sound yet incomplete analyses. Such abstractions unfortunately often lead to the rejection of programs that could very well be synthesized into deterministic code, provided abstraction refinement steps could be applied for more accurate analysis. To reduce the false negatives occurring during the compilation process, we leverage recent advances in type theory -- with the definition of decidable classes of value-dependent type systems -- and formal verification, linked to the development of efficient SAT/SMT solvers, to provide a type-theoretic approach that considers all the above analyses as type inference problems. In order to simplify the exposition of our new approach in this paper, we define a refinement type system for a minimalistic, synchronous, stream-processing language to concisely represent, analyse, and verify logical and quantitative properties of programs expressed as stream-processing data-flow networks. Our type system provides a new framework to represent logical time (clocks) and scheduling properties, and to describe their relations with stream values and, possibly, other quantas. We show how to analyze synchronous stream processing programs (à la Lustre, Signal) to enable previously described analyzes involved in compiling such programs. We also prove the soundness of our type system and elaborate on the adaptability of this core framework by outlining its extensibility to specific models of computations and other quantas

Correct-by-construction microarchitectural pipelining

This paper presents a method for correct-by-construction microarchitectural pipelining that handles cyclic systems with dependencies between iterations. Our method combines previously known bypass and retiming transformations with a few transformations valid only for elastic systems with early evaluation (namely, empty FIFO insertion, FIFO capacity sizing, insertion of anti-tokens, and introducing early evaluation multiplexors). By converting the design to a synchronous elastic form and then applying this extended set of transformations, one can pipeline a functional specification with an automatically generated distributed controller that implements stalling logic resolving data hazards off the critical path of the design. We have developed an interactive toolkit for exploring elastic microarchitectural transformations. The method is illustrated by pipelining a few simple examples of instruction set architecture ISA specifications.Peer ReviewedPostprint (published version

Liquid Clocks - Refinement Types for Time-Dependent Stream Functions

The concept of liquid clocks introduced in this paper is a significant step towards a more precise compile-time framework for the analysis of synchronous and polychromous languages. Compiling languages such as Lustre or SIGNAL indeed involves a number of static analyses of programs before they can be synthesized into executable code, e.g., synchronicity class characterization, clock assignment, static scheduling or causality analysis. These analyses are often equivalent to undecidable problems, necessitating abstracting such programs to provide sound yet incomplete analyses. Such abstractions unfortunately often lead to the rejection of programs that could very well be synthesized into deterministic code, provided abstraction refinement steps could be applied for more accurate analysis. To reduce the false negatives occurring during the compilation process, we leverage recent advances in type theory -- with the definition of decidable classes of value-dependent type systems -- and formal verification, linked to the development of efficient SAT/SMT solvers, to provide a type-theoretic approach that considers all the above analyses as type inference problems. In order to simplify the exposition of our new approach in this paper, we define a refinement type system for a minimalistic, synchronous, stream-processing language to concisely represent, analyse, and verify logical and quantitative properties of programs expressed as stream-processing data-flow networks. Our type system provides a new framework to represent logical time (clocks) and scheduling properties, and to describe their relations with stream values and, possibly, other quantas. We show how to analyze synchronous stream processing programs (à la Lustre, Signal) to enable previously described analyzes involved in compiling such programs. We also prove the soundness of our type system and elaborate on the adaptability of this core framework by outlining its extensibility to specific models of computations and other quantas

FICS 2010

International audienceInformal proceedings of the 7th workshop on Fixed Points in Computer Science (FICS 2010), held in Brno, 21-22 August 201

Fundamental Approaches to Software Engineering

computer software maintenance; computer software selection and evaluation; formal logic; formal methods; formal specification; programming languages; semantics; software engineering; specifications; verificatio

Design and analysis of SRAMs for energy harvesting systems

PhD ThesisAt present, the battery is employed as a power source for wide varieties of microelectronic systems ranging from biomedical implants and sensor net-works to portable devices. However, the battery has several limitations and incurs many challenges for the majority of these systems. For instance, the design considerations of implantable devices concern about the battery from two aspects, the toxic materials it contains and its lifetime since replacing the battery means a surgical operation. Another challenge appears in wire-less sensor networks, where hundreds or thousands of nodes are scattered around the monitored environment and the battery of each node should be maintained and replaced regularly, nonetheless, the batteries in these nodes do not all run out at the same time. Since the introduction of portable systems, the area of low power designs has witnessed extensive research, driven by the industrial needs, towards the aim of extending the lives of batteries. Coincidentally, the continuing innovations in the field of micro-generators made their outputs in the same range of several portable applications. This overlap creates a clear oppor-tunity to develop new generations of electronic systems that can be powered, or at least augmented, by energy harvesters. Such self-powered systems benefit applications where maintaining and replacing batteries are impossi-ble, inconvenient, costly, or hazardous, in addition to decreasing the adverse effects the battery has on the environment. The main goal of this research study is to investigate energy harvesting aware design techniques for computational logic in order to enable the capa- II bility of working under non-deterministic energy sources. As a case study, the research concentrates on a vital part of all computational loads, SRAM, which occupies more than 90% of the chip area according to the ITRS re-ports. Essentially, this research conducted experiments to find out the design met-ric of an SRAM that is the most vulnerable to unpredictable energy sources, which has been confirmed to be the timing. Accordingly, the study proposed a truly self-timed SRAM that is realized based on complete handshaking protocols in the 6T bit-cell regulated by a fully Speed Independent (SI) tim-ing circuitry. The study proved the functionality of the proposed design in real silicon. Finally, the project enhanced other performance metrics of the self-timed SRAM concentrating on the bit-line length and the minimum operational voltage by employing several additional design techniques.Umm Al-Qura University, the Ministry of Higher Education in the Kingdom of Saudi Arabia, and the Saudi Cultural Burea