391 research outputs found

    From Parallel Programs to Customized Parallel Processors

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    The need for fast time to market of new embedded processor-based designs calls for a rapid design methodology of the included processors. The call for such a methodology is even more emphasized in the context of so called soft cores targeted to reconfigurable fabrics where per-design processor customization is commonplace. The C language has been commonly used as an input to hardware/software co-design flows. However, as C is a sequential language, its potential to generate parallel operations to utilize naturally parallel hardware constructs is far from optimal, leading to a customized processor design space with limited parallel resource scalability. In contrast, when utilizing a parallel programming language as an input, a wider processor design space can be explored to produce customized processors with varying degrees of utilized parallelism. This Thesis proposes a novel Multicore Application-Specific Instruction Set Processor (MCASIP) co-design methodology that exploits parallel programming languages as the application input format. In the methodology, the designer can explicitly capture the parallelism of the algorithm and exploit specialized instructions using a parallel programming language in contrast to being on the mercy of the compiler or the hardware to extract the parallelism from a sequential input. The Thesis proposes a multicore processor template based on the Transport Triggered Architecture, compiler techniques involved in static parallelization of computation kernels with barriers and a datapath integrated hardware accelerator for low overhead software synchronization implementation. These contributions enable scaling the customized processors both at the instruction and task levels to efficiently exploit the parallelism in the input program up to the implementation constraints such as the memory bandwidth or the chip area. The different contributions are validated with case studies, comparisons and design examples

    Cross-Layer Rapid Prototyping and Synthesis of Application-Specific and Reconfigurable Many-accelerator Platforms

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    Technological advances of recent years laid the foundation consolidation of informatisationof society, impacting on economic, political, cultural and socialdimensions. At the peak of this realization, today, more and more everydaydevices are connected to the web, giving the term ”Internet of Things”. The futureholds the full connection and interaction of IT and communications systemsto the natural world, delimiting the transition to natural cyber systems and offeringmeta-services in the physical world, such as personalized medical care, autonomoustransportation, smart energy cities etc. . Outlining the necessities of this dynamicallyevolving market, computer engineers are required to implement computingplatforms that incorporate both increased systemic complexity and also cover awide range of meta-characteristics, such as the cost and design time, reliabilityand reuse, which are prescribed by a conflicting set of functional, technical andconstruction constraints. This thesis aims to address these design challenges bydeveloping methodologies and hardware/software co-design tools that enable therapid implementation and efficient synthesis of architectural solutions, which specifyoperating meta-features required by the modern market. Specifically, this thesispresents a) methodologies to accelerate the design flow for both reconfigurableand application-specific architectures, b) coarse-grain heterogeneous architecturaltemplates for processing and communication acceleration and c) efficient multiobjectivesynthesis techniques both at high abstraction level of programming andphysical silicon level.Regarding to the acceleration of the design flow, the proposed methodologyemploys virtual platforms in order to hide architectural details and drastically reducesimulation time. An extension of this framework introduces the systemicco-simulation using reconfigurable acceleration platforms as co-emulation intermediateplatforms. Thus, the development cycle of a hardware/software productis accelerated by moving from a vertical serial flow to a circular interactive loop.Moreover the simulation capabilities are enriched with efficient detection and correctiontechniques of design errors, as well as control methods of performancemetrics of the system according to the desired specifications, during all phasesof the system development. In orthogonal correlation with the aforementionedmethodological framework, a new architectural template is proposed, aiming atbridging the gap between design complexity and technological productivity usingspecialized hardware accelerators in heterogeneous systems-on-chip and networkon-chip platforms. It is presented a novel co-design methodology for the hardwareaccelerators and their respective programming software, including the tasks allocationto the available resources of the system/network. The introduced frameworkprovides implementation techniques for the accelerators, using either conventionalprogramming flows with hardware description language or abstract programmingmodel flows, using techniques from high-level synthesis. In any case, it is providedthe option of systemic measures optimization, such as the processing speed,the throughput, the reliability, the power consumption and the design silicon area.Finally, on addressing the increased complexity in design tools of reconfigurablesystems, there are proposed novel multi-objective optimization evolutionary algo-rithms which exploit the modern multicore processors and the coarse-grain natureof multithreaded programming environments (e.g. OpenMP) in order to reduce theplacement time, while by simultaneously grouping the applications based on theirintrinsic characteristics, the effectively explore the design space effectively.The efficiency of the proposed architectural templates, design tools and methodologyflows is evaluated in relation to the existing edge solutions with applicationsfrom typical computing domains, such as digital signal processing, multimedia andarithmetic complexity, as well as from systemic heterogeneous environments, suchas a computer vision system for autonomous robotic space navigation and manyacceleratorsystems for HPC and workstations/datacenters. The results strengthenthe belief of the author, that this thesis provides competitive expertise to addresscomplex modern - and projected future - design challenges.Οι τεχνολογικές εξελίξεις των τελευταίων ετών έθεσαν τα θεμέλια εδραίωσης της πληροφοριοποίησης της κοινωνίας, επιδρώντας σε οικονομικές,πολιτικές, πολιτιστικές και κοινωνικές διαστάσεις. Στο απόγειο αυτής τη ςπραγμάτωσης, σήμερα, ολοένα και περισσότερες καθημερινές συσκευές συνδέονται στο παγκόσμιο ιστό, αποδίδοντας τον όρο «Ίντερνετ των πραγμάτων».Το μέλλον επιφυλάσσει την πλήρη σύνδεση και αλληλεπίδραση των συστημάτων πληροφορικής και επικοινωνιών με τον φυσικό κόσμο, οριοθετώντας τη μετάβαση στα συστήματα φυσικού κυβερνοχώρου και προσφέροντας μεταυπηρεσίες στον φυσικό κόσμο όπως προσωποποιημένη ιατρική περίθαλψη, αυτόνομες μετακινήσεις, έξυπνες ενεργειακά πόλεις κ.α. . Σκιαγραφώντας τις ανάγκες αυτής της δυναμικά εξελισσόμενης αγοράς, οι μηχανικοί υπολογιστών καλούνται να υλοποιήσουν υπολογιστικές πλατφόρμες που αφενός ενσωματώνουν αυξημένη συστημική πολυπλοκότητα και αφετέρου καλύπτουν ένα ευρύ φάσμα μεταχαρακτηριστικών, όπως λ.χ. το κόστος σχεδιασμού, ο χρόνος σχεδιασμού, η αξιοπιστία και η επαναχρησιμοποίηση, τα οποία προδιαγράφονται από ένα αντικρουόμενο σύνολο λειτουργικών, τεχνολογικών και κατασκευαστικών περιορισμών. Η παρούσα διατριβή στοχεύει στην αντιμετώπιση των παραπάνω σχεδιαστικών προκλήσεων, μέσω της ανάπτυξης μεθοδολογιών και εργαλείων συνσχεδίασης υλικού/λογισμικού που επιτρέπουν την ταχεία υλοποίηση καθώς και την αποδοτική σύνθεση αρχιτεκτονικών λύσεων, οι οποίες προδιαγράφουν τα μετα-χαρακτηριστικά λειτουργίας που απαιτεί η σύγχρονη αγορά. Συγκεκριμένα, στα πλαίσια αυτής της διατριβής, παρουσιάζονται α) μεθοδολογίες επιτάχυνσης της ροής σχεδιασμού τόσο για επαναδιαμορφούμενες όσο και για εξειδικευμένες αρχιτεκτονικές, β) ετερογενή αδρομερή αρχιτεκτονικά πρότυπα επιτάχυνσης επεξεργασίας και επικοινωνίας και γ) αποδοτικές τεχνικές πολυκριτηριακής σύνθεσης τόσο σε υψηλό αφαιρετικό επίπεδο προγραμματισμού,όσο και σε φυσικό επίπεδο πυριτίου.Αναφορικά προς την επιτάχυνση της ροής σχεδιασμού, προτείνεται μια μεθοδολογία που χρησιμοποιεί εικονικές πλατφόρμες, οι οποίες αφαιρώντας τις αρχιτεκτονικές λεπτομέρειες καταφέρνουν να μειώσουν σημαντικά το χρόνο εξομοίωσης. Παράλληλα, εισηγείται η συστημική συν-εξομοίωση με τη χρήση επαναδιαμορφούμενων πλατφορμών, ως μέσων επιτάχυνσης. Με αυτόν τον τρόπο, ο κύκλος ανάπτυξης ενός προϊόντος υλικού, μετατεθειμένος από την κάθετη σειριακή ροή σε έναν κυκλικό αλληλεπιδραστικό βρόγχο, καθίσταται ταχύτερος, ενώ οι δυνατότητες προσομοίωσης εμπλουτίζονται με αποδοτικότερες μεθόδους εντοπισμού και διόρθωσης σχεδιαστικών σφαλμάτων, καθώς και μεθόδους ελέγχου των μετρικών απόδοσης του συστήματος σε σχέση με τις επιθυμητές προδιαγραφές, σε όλες τις φάσεις ανάπτυξης του συστήματος. Σε ορθογώνια συνάφεια με το προαναφερθέν μεθοδολογικό πλαίσιο, προτείνονται νέα αρχιτεκτονικά πρότυπα που στοχεύουν στη γεφύρωση του χάσματος μεταξύ της σχεδιαστικής πολυπλοκότητας και της τεχνολογικής παραγωγικότητας, με τη χρήση συστημάτων εξειδικευμένων επιταχυντών υλικού σε ετερογενή συστήματα-σε-ψηφίδα καθώς και δίκτυα-σε-ψηφίδα. Παρουσιάζεται κατάλληλη μεθοδολογία συν-σχεδίασης των επιταχυντών υλικού και του λογισμικού προκειμένου να αποφασισθεί η κατανομή των εργασιών στους διαθέσιμους πόρους του συστήματος/δικτύου. Το μεθοδολογικό πλαίσιο προβλέπει την υλοποίηση των επιταχυντών είτε με συμβατικές μεθόδους προγραμματισμού σε γλώσσα περιγραφής υλικού είτε με αφαιρετικό προγραμματιστικό μοντέλο με τη χρήση τεχνικών υψηλού επιπέδου σύνθεσης. Σε κάθε περίπτωση, δίδεται η δυνατότητα στο σχεδιαστή για βελτιστοποίηση συστημικών μετρικών, όπως η ταχύτητα επεξεργασίας, η ρυθμαπόδοση, η αξιοπιστία, η κατανάλωση ενέργειας και η επιφάνεια πυριτίου του σχεδιασμού. Τέλος, προκειμένου να αντιμετωπισθεί η αυξημένη πολυπλοκότητα στα σχεδιαστικά εργαλεία επαναδιαμορφούμενων συστημάτων, προτείνονται νέοι εξελικτικοί αλγόριθμοι πολυκριτηριακής βελτιστοποίησης, οι οποίοι εκμεταλλευόμενοι τους σύγχρονους πολυπύρηνους επεξεργαστές και την αδρομερή φύση των πολυνηματικών περιβαλλόντων προγραμματισμού (π.χ. OpenMP), μειώνουν το χρόνο επίλυσης του προβλήματος της τοποθέτησης των λογικών πόρων σε φυσικούς,ενώ ταυτόχρονα, ομαδοποιώντας τις εφαρμογές βάση των εγγενών χαρακτηριστικών τους, διερευνούν αποτελεσματικότερα το χώρο σχεδίασης.Η αποδοτικότητά των προτεινόμενων αρχιτεκτονικών προτύπων και μεθοδολογιών επαληθεύτηκε σε σχέση με τις υφιστάμενες λύσεις αιχμής τόσο σε αυτοτελής εφαρμογές, όπως η ψηφιακή επεξεργασία σήματος, τα πολυμέσα και τα προβλήματα αριθμητικής πολυπλοκότητας, καθώς και σε συστημικά ετερογενή περιβάλλοντα, όπως ένα σύστημα όρασης υπολογιστών για αυτόνομα διαστημικά ρομποτικά οχήματα και ένα σύστημα πολλαπλών επιταχυντών υλικού για σταθμούς εργασίας και κέντρα δεδομένων, στοχεύοντας εφαρμογές υψηλής υπολογιστικής απόδοσης (HPC). Τα αποτελέσματα ενισχύουν την πεποίθηση του γράφοντα, ότι η παρούσα διατριβή παρέχει ανταγωνιστική τεχνογνωσία για την αντιμετώπιση των πολύπλοκων σύγχρονων και προβλεπόμενα μελλοντικών σχεδιαστικών προκλήσεων

    Mitosis based speculative multithreaded architectures

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    In the last decade, industry made a right-hand turn and shifted towards multi-core processor designs, also known as Chip-Multi-Processors (CMPs), in order to provide further performance improvements under a reasonable power budget, design complexity, and validation cost. Over the years, several processor vendors have come out with multi-core chips in their product lines and they have become mainstream, with the number of cores increasing in each processor generation. Multi-core processors improve the performance of applications by exploiting Thread Level Parallelism (TLP) while the Instruction Level Parallelism (ILP) exploited by each individual core is limited. These architectures are very efficient when multiple threads are available for execution. However, single-thread sections of code (single-thread applications and serial sections of parallel applications) pose important constraints on the benefits achieved by parallel execution, as pointed out by Amdahl’s law. Parallel programming, even with the help of recently proposed techniques like transactional memory, has proven to be a very challenging task. On the other hand, automatically partitioning applications into threads may be a straightforward task in regular applications, but becomes much harder for irregular programs, where compilers usually fail to discover sufficient TLP. In this scenario, two main directions have been followed in the research community to take benefit of multi-core platforms: Speculative Multithreading (SpMT) and Non-Speculative Clustered architectures. The former splits a sequential application into speculative threads, while the later partitions the instructions among the cores based on data-dependences but avoid large degree of speculation. Despite the large amount of research on both these approaches, the proposed techniques so far have shown marginal performance improvements. In this thesis we propose novel schemes to speed-up sequential or lightly threaded applications in multi-core processors that effectively address the main unresolved challenges of previous approaches. In particular, we propose a SpMT architecture, called Mitosis, that leverages a powerful software value prediction technique to manage inter-thread dependences, based on pre-computation slices (p-slices). Thanks to the accuracy and low cost of this technique, Mitosis is able to effectively parallelize applications even in the presence of frequent dependences among threads. We also propose a novel architecture, called Anaphase, that combines the best of SpMT schemes and clustered architectures. Anaphase effectively exploits ILP, TLP and Memory Level Parallelism (MLP), thanks to its unique finegrain thread decomposition algorithm that adapts to the available parallelism in the application

    Software/Hardware Co-Design to Improve Productivity, Portability, and Performance of Loop-Task Parallel Applications

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    Computer architects are increasingly turning to programmable accelerators tailored for narrower classes of applications in order to achieve high performance and energy efficiency. A continuing challenge with accelerators is enabling the programmer to easily extract maximum performance without intimate knowledge of the underlying microarchitecture. It is important to consider productivity and portability, in addition to performance, as first-class metrics when developing and evaluating modern computing platforms. Software-centric approaches to achieving 3P computing platforms are compelling, but sacrifice efficiency and flexibility by hiding parallel abstractions from hardware and limiting the scope of the application domain. This thesis proposes a new software/hardware co-design approach to achieving 3P platforms, called the loop-task accelerator (LTA) platform, that provides high productivity and portability without sacrificing performance or efficiency across a wide range of applications. The LTA platform addresses the weaknesses of existing approaches that are identified through detailed experimentation with and analysis of modern application development. Discussion of an early attempt at a hardware-centric approach to achieving 3P platforms provides insight into area-efficient accelerator designs and highlights the need for innovations in both software and hardware. The LTA platform focuses on exploiting loop-task parallelism by exposing loop-tasks as a common parallel abstraction at the programming API, runtime, ISA, and microarchitectural levels. The LTA programming API uses the parallel_for construct to express loop-tasks that can be exploited both across cores and within a core, the LTA runtime distributes loop-tasks across cores, and a new xpfor instruction explicitly encodes loop-tasks as functions applied to a range of loop iterations. This thesis introduces a novel task-coupling taxonomy that captures how tasks can be coupled in both space and time. The LTA engine template can be configured at design time with variable spatial and temporal task coupling to accelerate the execution of both regular and irregular loop-tasks within a core. The LTA platform is evaluated with respect to the 3P’s using a vertically integrated research methodology. Compared to an in-order multi-core baseline, the LTA platform yields average improvements of 5.5× in raw performance, 2.5× in performance per area, and 1.2× in energy efficiency, while offering high productivity and portability

    Mitosis based speculative multithreaded architectures

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    In the last decade, industry made a right-hand turn and shifted towards multi-core processor designs, also known as Chip-Multi-Processors (CMPs), in order to provide further performance improvements under a reasonable power budget, design complexity, and validation cost. Over the years, several processor vendors have come out with multi-core chips in their product lines and they have become mainstream, with the number of cores increasing in each processor generation. Multi-core processors improve the performance of applications by exploiting Thread Level Parallelism (TLP) while the Instruction Level Parallelism (ILP) exploited by each individual core is limited. These architectures are very efficient when multiple threads are available for execution. However, single-thread sections of code (single-thread applications and serial sections of parallel applications) pose important constraints on the benefits achieved by parallel execution, as pointed out by Amdahl’s law. Parallel programming, even with the help of recently proposed techniques like transactional memory, has proven to be a very challenging task. On the other hand, automatically partitioning applications into threads may be a straightforward task in regular applications, but becomes much harder for irregular programs, where compilers usually fail to discover sufficient TLP. In this scenario, two main directions have been followed in the research community to take benefit of multi-core platforms: Speculative Multithreading (SpMT) and Non-Speculative Clustered architectures. The former splits a sequential application into speculative threads, while the later partitions the instructions among the cores based on data-dependences but avoid large degree of speculation. Despite the large amount of research on both these approaches, the proposed techniques so far have shown marginal performance improvements. In this thesis we propose novel schemes to speed-up sequential or lightly threaded applications in multi-core processors that effectively address the main unresolved challenges of previous approaches. In particular, we propose a SpMT architecture, called Mitosis, that leverages a powerful software value prediction technique to manage inter-thread dependences, based on pre-computation slices (p-slices). Thanks to the accuracy and low cost of this technique, Mitosis is able to effectively parallelize applications even in the presence of frequent dependences among threads. We also propose a novel architecture, called Anaphase, that combines the best of SpMT schemes and clustered architectures. Anaphase effectively exploits ILP, TLP and Memory Level Parallelism (MLP), thanks to its unique finegrain thread decomposition algorithm that adapts to the available parallelism in the application.Postprint (published version

    Proceedings of the 5th International Workshop on Reconfigurable Communication-centric Systems on Chip 2010 - ReCoSoC\u2710 - May 17-19, 2010 Karlsruhe, Germany. (KIT Scientific Reports ; 7551)

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    ReCoSoC is intended to be a periodic annual meeting to expose and discuss gathered expertise as well as state of the art research around SoC related topics through plenary invited papers and posters. The workshop aims to provide a prospective view of tomorrow\u27s challenges in the multibillion transistor era, taking into account the emerging techniques and architectures exploring the synergy between flexible on-chip communication and system reconfigurability
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