Συντάχθηκε 14-05-2014 14:56
από Balasi Panagiota
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ΠΟΛΥΤΕΧΝΕΙΟ ΚΡΗΤΗΣ
Σχολή Ηλεκτρονικών Μηχανικών και Μηχανικών Υπολογιστών
Πρόγραμμα Προπτυχιακών Σπουδών
ΠΑΡΟΥΣΙΑΣΗ ΔΙΠΛΩΜΑΤΙΚΗΣ ΕΡΓΑΣΙΑΣ
Δημητρίου Σκαρλάτου
με θέμα
Αξιόπιστη Αρχιτεκτονική Λειτουργικού Υποστρώματος Πολυπύρηνων Ολοκληρωμένων Συστημάτων
Reliable Runtime Architecture for Multiprocessor Systems on Chip
Δευτέρα 26 Μαΐου 2014, 12μμ
Αίθουσα 145.Π42, Κτίριο Επιστημών, Πολυτεχνειούπολη
Εξεταστική Επιτροπή
Καθηγητής Διονύσιος Πνευματικάτος (επιβλέπων)
Καθηγητής Απόστολος Δόλλας
Αναπληρωτής Καθηγητής Ιωάννης Παπαευσταθίου
Abstract
Mission critical applications rely on both hardware- and software-approaches for fault-tolerance. With the adoption of multiprocessor systems on chip (MPSoC), processor fault-tolerance with modular redundancy has become a major issue, cost and performance wise. In this thesis first, we augment a task-parallel runtime system with support for transparent checkpoints of task data that may be written during task execution and seamlessly rerun failed tasks. The system can recover from transient errors during task execution within a single core by rerunning the failed task, as well as from permanent errors that disable a worker core by redistributing work among remaining cores. We have evaluated our implementation using six benchmarks and found that checkpointing incurs a performance overhead of 8% on average, mainly due to the cost of memory copies, and only a negligible space overhead due to the recycling of checkpoint memory. Then, in order to protect the workers runtime system beyond the execution stage, we present ASGUARDIAN, a lightweight hardware mechanism based on a task-oriented model for general programmability. The ASGUARDIAN features both store-and-forward and cut-through capabilities to reliably transfer task descriptions and arguments between main memory and available worker cores. It also isolates the workers from accessing the main memory. A hardware prototype has been implemented on a Xilinx ML605 FPGA board using the widely-used ARM AMBA protocol. Introducing the ASGUARDIAN reliability features results in a 7.86% average overhead on hardware resources for a configuration with four Microblaze cores. The performance overhead for the store-and-forward and cut-through implementations were 2.3x and 1.2x respectively against an unprotected, shared memory system. When compared against an -unprotected- scratchpad-based memory system, the store-and-forward version showed an overhead of 1.7x, while the cut-through version showed a speedup of 6% on average.
