A set-associative, fault-tolerant cache design

The design of a defect-tolerant control circuit for a set-associative cache memory is presented. The circuit maintains the stack ordering necessary for implementing the Least Recently Used (LRU) replacement algorithm. A discussion of programming techniques for bypassing defective blocks is included

Performance-effective operation below Vcc-min

Continuous circuit miniaturization and increased process variability point to a future with diminishing returns from dynamic voltage scaling. Operation below Vcc-min has been proposed recently as a mean to reverse this trend. The goal of this paper is to minimize the performance loss due to reduced cache capacity when operating below Vcc-min. A simple method is proposed: disable faulty blocks at low voltage. The method is based on observations regarding the distributions of faults in an array according to probability theory. The key lesson, from the probability analysis, is that as the number of uniformly distributed random faulty cells in an array increases the faults increasingly occur in already faulty blocks. The probability analysis is also shown to be useful for obtaining insight about the reliability implications of other cache techniques. For one configuration used in this paper, block disabling is shown to have on the average 6.6% and up to 29% better performance than a previously proposed scheme for low voltage cache operation. Furthermore, block-disabling is simple and less costly to implement and does not degrade performance at or above Vcc-min operation. Finally, it is shown that a victim-cache enables higher and more deterministic performance for a block-disabled cache

Cache memory organization to enhance the yield of high-performance VLSI processors

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Fault- and Yield-Aware On-Chip Memory Design and Management

Ever decreasing device size causes more frequent hard faults, which becomes a serious burden to processor design and yield management. This problem is particularly pronounced in the on-chip memory which consumes up to 70% of a processor' s total chip area. Traditional circuit-level techniques, such as redundancy and error correction code, become less effective in error-prevalent environments because of their large area overhead. In this work, we suggest an architectural solution to building reliable on-chip memory in the future processor environment. Our approaches have two parts, a design framework and architectural techniques for on-chip memory structures. Our design framework provides important architectural evaluation metrics such as yield, area, and performance based on low level defects and process variations parameters. Processor architects can quickly evaluate their designs' characteristics in terms of yield, area, and performance. With the framework, we develop architectural yield enhancement solutions for on-chip memory structures including L1 cache, L2 cache and directory memory. Our proposed solutions greatly improve yield with negligible area and performance overhead. Furthermore, we develop a decoupled yield model of compute cores and L2 caches in CMPs, which show that there will be many more L2 caches than compute cores in a chip. We propose efficient utilization techniques for excess caches. Evaluation results show that excess caches significantly improve overall performance of CMPs

Architectures for dependable modern microprocessors

Η εξέλιξη των ολοκληρωμένων κυκλωμάτων σε συνδυασμό με τους αυστηρούς χρονικούς περιορισμούς καθιστούν την επαλήθευση της ορθής λειτουργίας των επεξεργαστών μία εξαιρετικά απαιτητική διαδικασία. Με κριτήριο το στάδιο του κύκλου ζωής ενός επεξεργαστή, από την στιγμή κατασκευής των πρωτοτύπων και έπειτα, οι τεχνικές ελέγχου ορθής λειτουργίας διακρίνονται στις ακόλουθες κατηγορίες: (1) Silicon Debug: Τα πρωτότυπα ολοκληρωμένα κυκλώματα ελέγχονται εξονυχιστικά, (2) Manufacturing Testing: ο τελικό ποιοτικός έλεγχος και (3) In-field verification: Περιλαμβάνει τεχνικές, οι οποίες διασφαλίζουν την λειτουργία του επεξεργαστή σύμφωνα με τις προδιαγραφές του. Η διδακτορική διατριβή προτείνει τα ακόλουθα: (1) Silicon Debug: Η εργασία αποσκοπεί στην επιτάχυνση της διαδικασίας ανίχνευσης σφαλμάτων και στον αυτόματο εντοπισμό τυχαίων προγραμμάτων που δεν περιέχουν νέα -χρήσιμη- πληροφορία σχετικά με την αίτια ενός σφάλματος. Η κεντρική ιδέα αυτής της μεθόδου έγκειται στην αξιοποίηση της έμφυτης ποικιλομορφίας των αρχιτεκτονικών συνόλου εντολών και στην δυνατότητα από-διαμόρφωσης τμημάτων του κυκλώματος, (2) Manufacturing Testing: προτείνεται μία μέθοδο για την βελτιστοποίηση του έλεγχου ορθής λειτουργίας των πολυνηματικών και πολυπύρηνων επεξεργαστών μέσω της χρήση λογισμικού αυτοδοκιμής, (3) Ιn-field verification: Αναλύθηκε σε βάθος η επίδραση που έχουν τα μόνιμα σφάλματα σε μηχανισμούς αύξησης της απόδοσης. Επιπρόσθετα, προτάθηκαν τεχνικές για την ανίχνευση και ανοχή μόνιμων σφαλμάτων υλικού σε μηχανισμούς πρόβλεψης διακλάδωσης.Technology scaling, extreme chip integration and the compelling requirement to diminish the time-to-market window, has rendered microprocessors more prone to design bugs and hardware faults. Microprocessor validation is grouped into the following categories, based on where they intervene in a microprocessor’s lifecycle: (a) Silicon debug: the first hardware prototypes are exhaustively validated, (b) Μanufacturing testing: the final quality control during massive production, and (c) In-field verification: runtime error detection techniques to guarantee correct operation. The contributions of this thesis are the following: (1) Silicon debug: We propose the employment of deconfigurable microprocessor architectures along with a technique to generate self-checking random test programs to avoid the simulation step and triage the redundant debug sessions, (2) Manufacturing testing: We propose a self-test optimization strategy for multithreaded, multicore microprocessors to speedup test program execution time and enhance the fault coverage of hard errors; and (3) In-field verification: We measure the effect of permanent faults performance components. Then, we propose a set of low-cost mechanisms for the detection, diagnosis and performance recovery in the front-end speculative structures. This thesis introduces various novel methodologies to address the validation challenges posed throughout the life-cycle of a chip

The 1992 4th NASA SERC Symposium on VLSI Design

Papers from the fourth annual NASA Symposium on VLSI Design, co-sponsored by the IEEE, are presented. Each year this symposium is organized by the NASA Space Engineering Research Center (SERC) at the University of Idaho and is held in conjunction with a quarterly meeting of the NASA Data System Technology Working Group (DSTWG). One task of the DSTWG is to develop new electronic technologies that will meet next generation electronic data system needs. The symposium provides insights into developments in VLSI and digital systems which can be used to increase data systems performance. The NASA SERC is proud to offer, at its fourth symposium on VLSI design, presentations by an outstanding set of individuals from national laboratories, the electronics industry, and universities. These speakers share insights into next generation advances that will serve as a basis for future VLSI design

The 1991 3rd NASA Symposium on VLSI Design

Papers from the symposium are presented from the following sessions: (1) featured presentations 1; (2) very large scale integration (VLSI) circuit design; (3) VLSI architecture 1; (4) featured presentations 2; (5) neural networks; (6) VLSI architectures 2; (7) featured presentations 3; (8) verification 1; (9) analog design; (10) verification 2; (11) design innovations 1; (12) asynchronous design; and (13) design innovations 2