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414 results on '"Multiprocessadors"'

1. GenArchBench: A genomics benchmark suite for arm HPC processors

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament de Ciències de la Computació, Barcelona Supercomputing Center, Universitat Politècnica de Catalunya. ALBCOM - Algorísmia, Bioinformàtica, Complexitat i Mètodes Formals, López Villellas, Lorien, Langarita Benítez, Rubén, Badouh, Asaf, Soria Pardos, Víctor, Aguado Puig, Quim, López Paradís, Guillem, Doblas Font, Max, Setoain, Javier, Kim, Chulho, Ono, Makoto, Armejach Sanosa, Adrià, Marco Sola, Santiago, Alastruey Benedé, Jesús, Ibáñez Marín, Pablo, Moretó Planas, Miquel, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament de Ciències de la Computació, Barcelona Supercomputing Center, Universitat Politècnica de Catalunya. ALBCOM - Algorísmia, Bioinformàtica, Complexitat i Mètodes Formals, López Villellas, Lorien, Langarita Benítez, Rubén, Badouh, Asaf, Soria Pardos, Víctor, Aguado Puig, Quim, López Paradís, Guillem, Doblas Font, Max, Setoain, Javier, Kim, Chulho, Ono, Makoto, Armejach Sanosa, Adrià, Marco Sola, Santiago, Alastruey Benedé, Jesús, Ibáñez Marín, Pablo, and Moretó Planas, Miquel
Abstract: Arm usage has substantially grown in the High-Performance Computing (HPC) community. Japanese supercomputer Fugaku, powered by Arm-based A64FX processors, held the top position on the Top500 list between June 2020 and June 2022, currently sitting in the fourth position. The recently released 7th generation of Amazon EC2 instances for compute-intensive workloads (C7 g) is also powered by Arm Graviton3 processors. Projects like European Mont-Blanc and U.S. DOE/NNSA Astra are further examples of Arm irruption in HPC. In parallel, over the last decade, the rapid improvement of genomic sequencing technologies and the exponential growth of sequencing data has placed a significant bottleneck on the computational side. While most genomics applications have been thoroughly tested and optimized for x86 systems, just a few are prepared to perform efficiently on Arm machines. Moreover, these applications do not exploit the newly introduced Scalable Vector Extensions (SVE). This paper presents GenArchBench, the first genome analysis benchmark suite targeting Arm architectures. We have selected computationally demanding kernels from the most widely used tools in genome data analysis and ported them to Arm-based A64FX and Graviton3 processors. Overall, the GenArch benchmark suite comprises 13 multi-core kernels from critical stages of widely-used genome analysis pipelines, including base-calling, read mapping, variant calling, and genome assembly. Our benchmark suite includes different input data sets per kernel (small and large), each with a corresponding regression test to verify the correctness of each execution automatically. Moreover, the porting features the usage of the novel Arm SVE instructions, algorithmic and code optimizations, and the exploitation of Arm-optimized libraries. We present the optimizations implemented in each kernel and a detailed performance evaluation and comparison of their performance on four different HPC machines (i.e., A64FX, Graviton3, Intel Xeon, This work has been partially supported by the Spanish Ministry of Science and Innovation MCIN/AEI/10.13039/501100011033 (contracts PID2019-107255GB-C21, PID2019-105660RB-C21, PID2022136454NB-C22, and TED2021-132634A-I00), by the Generalitat de Catalunya, Spain (contract 2021-SGR-763), by the Gobierno de Aragón (T58_23R research group), by the European Union NextGenerationEU/ PRTR, and by Lenovo BSC Contract-Framework Contract (2020)., Peer Reviewed, Postprint (published version)
Published: 2024

2. Modelización hardware de la jerarquía de memoria en un multiprocesador

Author: Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Llaberia Griñó, José M., Azcárate Sánchez, Albert, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Llaberia Griñó, José M., and Azcárate Sánchez, Albert
Abstract: El problema de la Coherencia de Cache es uno de los retos principales en el diseño de nuevas arquitecturas y microprocesadores. Así mismo, es uno de los mayores obstáculos en el proceso de aprendizaje de los estudiantes de Ingeniería Informática. Para formar a los estudiantes y que puedan comprender los distintos protocolos de coherencia se usan simulaciones de distintas arquitecturas y sistemas. En la Facultad de Informática de Barcelona se simula un multiprocesador con distintas jerarquías de memoria, donde cada cual usa protocolos y arquitecturas progresivamente más cercanas a las usadas actualmente. Este proyecto continua la progresión de los estudios y sustituye la escritura inmediata de las caches por escritura retardada, se introducen conexiones punto a punto y una memoria principal con directorio. There are only two hard things in Computer Science: cache invalidation and naming things. -- Phil Karlton, The Cache Coherence problem is one of the main challenges in the design of new architectures and microprocessors. Likewise, it is one of the biggest hurdles in the learning process of Computer Engineering students. Simulations of different architectures and systems are used to train students to understand the different coherence protocols. At the Faculty of Informatics of Barcelona, a multiprocessor is simulated with different memory hierarchies, where each one uses protocols and architectures progressively closer to those currently used. This project continues the progression of the studies. It replaces the write-through writing policy of the caches with write-back, introducing point-to-point connections and a main memory with a directory. There are only two hard things in Computer Science: cache invalidation and naming things. -- Phil Karlton
Published: 2024

3. Evaluation of SYCL’s suitability for high-performance critical systems

Author: Barcelona Supercomputing Center, Peralta Quesada, Cristina, Trompouki, Matina Maria, Kosmidis, Leonidas, Barcelona Supercomputing Center, Peralta Quesada, Cristina, Trompouki, Matina Maria, and Kosmidis, Leonidas
Abstract: Upcoming safety critical systems require high performance processing, which can be provided by multi-cores and embedded GPUs found in several Systems-on-chip (SoC) targeting these domains. So far, only low-level programming models and APIs, such as CUDA or OpenCL have been evaluated. In this paper, we evaluate the effectiveness of a higher level programming model, SYCL, for critical applications executed in such embedded platforms. In particular, we are interested in two aspects: performance and programmability. In order to conduct our study, we use the open source GPU4S Bench benchmarking suite for space and an open source pedestrian detection application representing the automotive sector, which we port into SYCL and analyse their behavior. We perform our evaluation on a high-performance platform featuring an NVIDIA GTX 1080Ti as well as a representative embedded platform, the NVIDIA Xavier AGX which is considered a good candidate for future safety critical systems in both domains and we compare our results with other programming models. Our results show that in several cases SYCL is able to obtain performance close to highly optimised code using CUDA or NVIDIA libraries, with significantly lower development effort and complexity, which confirms the suitability of SYCL for programming high-performance safety critical systems., This work was funded by the Ministerio de Ciencia e Innovacion - Agencia Estatal de Investigacion (PID2019-107255GB-C21 and IJC-2020-045931-I MCIN/AEI/10.13039/501100011033), the European Commission’s Horizon 2020 programme under the UP2DATE project (grant agreement 871465) and the HiPEAC Network of Excellence., Peer Reviewed, Postprint (author's final draft)
Published: 2023

4. Isolation QoS Setups to Control Memory Contention on MPSoCs

Author: Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Barcelona Supercomputing Center, Moretó Planas, Miquel, Cazorla Almeida, Francisco Javier, Serrano Cases, Alejandro, García Esteban, Sergio, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Barcelona Supercomputing Center, Moretó Planas, Miquel, Cazorla Almeida, Francisco Javier, Serrano Cases, Alejandro, and García Esteban, Sergio
Abstract: In critical systems such as avionics and automotive domains, ensuring timely task execution is crucial to prevent catastrophic situations. The increasing trend towards autonomous operation demands higher performance and efficiency, leading to the adoption of Multiprocessor System-on-Chips (MPSoCs). However, the challenge arises in meeting timing requirements due to contention in accessing shared resources and the complexity of these resources. This work introduces Quasi-Isolation QoS Setups (QIQoS), a novel approach for efficiently managing Quality of Service (QoS) mechanisms in MPSoCs. QIQoS aims to make the behavior of MPSoCs more predictable, precise, and adaptable to the specific timing constraints of critical applications. By selecting different QoS solutions, QIQoS mitigates timing interference, minimizes execution time variability, and ensures a high degree of isolation for applications, regardless of contention from co-running applications. The evaluation of QIQoS on a Xilinx Zynq UltraScale+ MPSoC demonstrates its effectiveness in achieving high isolation and minimal variability between critical tasks. This success is attributed to the management of DDR memory controller QoS mechanisms and the mitigation of memory contention among computing elements. Overall, QIQoS proves to be a valuable solution for enhancing predictability in MPSoC-based systems in real deployment scenarios.
Published: 2023

5. Ethernet emulation over PCIe for RISC-V software development vehicles

Author: Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. PM - Programming Models, Castells Rufas, David, Martorell Bofill, Xavier, Roca Nonell, Aleix, Kropotov, Alexander, Teruel García, Xavier, Cervero García, Teresa, Davis, John D., Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. PM - Programming Models, Castells Rufas, David, Martorell Bofill, Xavier, Roca Nonell, Aleix, Kropotov, Alexander, Teruel García, Xavier, Cervero García, Teresa, and Davis, John D.
Abstract: This paper describes two different approaches to emulate an Ethernet communication link between a host computer and a RISC-V multiprocessor system running on a FPGA accelerator by using PCIe as the real communication link. Two approaches are tested, one based on user-level applications using TUN/TAP drivers and another based on implemented kernel-mode drivers on the Linux Operation System. We have functionally validated the approaches in multiple RISC-V systems and measured the achieved performance. A maximum bandwidth of 32.5 Mbps has been achieved in a Lagarto Hun system running at 100 Mhz., The MEEP project has received funding from the European High-Performance Computing Joint Undertaking (JU) under grant agreement No 946002. The JU receives support from the European Union’s Horizon 2020 research and innovation programme and Spain, Croatia, Turkey. This project is also partly funded by the Catalan Government Research groups 2021-SGR-01623., Peer Reviewed, Postprint (author's final draft)
Published: 2023

6. End-to-End QoS for the Open Source Safety-Relevant RISC-V SELENE Platform

Author: Andreu, Pablo, Hernandez, Carles, Picornell, Tomas, Lopez, Pedro, Alcaide, Sergi, Bas, Francisco, Benedicte, Pedro, Cabo, Guillem, Chang, Feng, Fuentes, Francisco, Abella, Jaume, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, and Barcelona Supercomputing Center
Subjects: FOS: Computer and information sciences, Hardware Architecture (cs.AR), Real-time data processing, Multiprocessors, High performance computing, Multiprocessadors, Computer Science - Hardware Architecture, Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC], Càlcul intensiu (Informàtica), Temps real (Informàtica)
Abstract: This paper presents the end-to-end QoS approach to provide performance guarantees followed in the SELENE platform, a high-performance RISC-V based heterogeneous SoC for safety-related real-time systems. Our QoS approach includes smart interconnect solutions for buses and NoCs, along with multicore interference-aware statistics units to, cooperatively, achieve end-to-end QoS., 4 pages, 3 figures, work presented on FORECAST workshop of HIPEAC 2022
Published: 2022

7. Heuristic-based Task-to-Thread Mapping in Multi-Core Processors

Author: Samadi Gharajeh, Mohammad, Royuela Alcázar, Sara, Pinho, Luis Miguel, Carvalho, Tiago, Quiñones Moreno, Eduardo, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, and Barcelona Supercomputing Center
Subjects: Idle time, Scheduling time, Multiprocessors, Real-time data processing, OpenMP, Multiprocessadors, Ordinadors immersos, Sistemes d', Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC], Embedded computer systems, Real-time systems, Temps real (Informàtica), Task-to-thread mapping
Abstract: OpenMP can be used in real-time applications to enhance system performance. However, predictability of OpenMP applications is still a challenge. This paper investigates heuristics for the mapping of OpenMP task graphs in underlying threads, for the development of time-predictable OpenMP programs. These approaches are based on a global scheduling queue, as well as per-thread allocation queues. The proposed method is divided into scheduling and allocation phases. In the former phase, OpenMP task-parts are discovered from OpenMP graph and placed in the scheduling queue. Afterwards, an appropriate allocation queue is selected for each task-part using four heuristic algorithms. In the latter phase, the best task-part is selected from the allocation queue to be allocated to and executed by an idle thread. Preliminary simulation results show that the new method overcomes BFS and WFS in terms of scheduling time and idle time. This work has been co-funded by the European commission through the AMPERE (H2020 grant agreement N° 745601) project.
Published: 2022

8. Heuristic-based task-to-thread mapping in multi-core processors

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Samadi Gharajeh, Mohammad, Royuela Alcázar, Sara, Pinho, Luis Miguel, Carvalho, Tiago, Quiñones Moreno, Eduardo, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Samadi Gharajeh, Mohammad, Royuela Alcázar, Sara, Pinho, Luis Miguel, Carvalho, Tiago, and Quiñones Moreno, Eduardo
Abstract: OpenMP can be used in real-time applications to enhance system performance. However, predictability of OpenMP applications is still a challenge. This paper investigates heuristics for the mapping of OpenMP task graphs in underlying threads, for the development of time-predictable OpenMP programs. These approaches are based on a global scheduling queue, as well as per-thread allocation queues. The proposed method is divided into scheduling and allocation phases. In the former phase, OpenMP task-parts are discovered from OpenMP graph and placed in the scheduling queue. Afterwards, an appropriate allocation queue is selected for each task-part using four heuristic algorithms. In the latter phase, the best task-part is selected from the allocation queue to be allocated to and executed by an idle thread. Preliminary simulation results show that the new method overcomes BFS and WFS in terms of scheduling time and idle time., This work has been co-funded by the European commission through the AMPERE (H2020 grant agreement N° 745601) project., Peer Reviewed, Postprint (author's final draft)
Published: 2022

9. SafeSoftDR: A library to enable software-based diverse redundancy for safety-critical tasks

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Mazzocchetti, Fabio, Alcaide Portet, Sergi, Bas Jalón, Francisco, Benedicte Illescas, Pedro, Cabo Pitarch, Guillem, Chang, Feng, Fuentes Díaz, Francisco Javier, Abella Ferrer, Jaume, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Mazzocchetti, Fabio, Alcaide Portet, Sergi, Bas Jalón, Francisco, Benedicte Illescas, Pedro, Cabo Pitarch, Guillem, Chang, Feng, Fuentes Díaz, Francisco Javier, and Abella Ferrer, Jaume
Abstract: Applications with safety requirements have become ubiquitous nowadays and can be found in edge devices of all kinds. However, microcontrollers in those devices, despite offering moderate performance by implementing multicores and cache hierarchies, may fail to offer adequate support to implement some safety measures needed for the highest integrity levels, such as lockstepped execution to avoid so-called common cause failures (i.e., a fault affecting redundant components causing the same error in all of them). To respond to this limitation, an approach based on a software monitor enforcing some sort of software-based lockstepped execution across cores has been proposed recently in [2], providing a proof of concept. This paper presents SafeSoftDR, a library providing a standard interface to deploy software-based lockstepped execution across non-natively lockstepped cores relieving end-users from having to manage the burden to create redundant processes, copying input/output data, and performing result comparison. Our library has been tested on x86-based Linux and is currently being integrated on top of an open-source RISC-V platform targeting safety-related applications, hence offering a convenient environment for safety-critical applications., This work is part of the project PCI2020-112010, funded by MCIN/AEI/10.13039/501100011033 and the European Union “NextGenerationEU”/PRTR, and the European Union’s Horizon 2020 Programme under project ECSEL Joint Undertaking (JU) under grant agreement No 877056. This workhasalsobeen partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB-C21 funded by MCIN/AEI/10.13039/501100011033., Peer Reviewed, Postprint (published version)
Published: 2022

10. End-to-end QoS for the open source safety-relevant RISC-V SELENE platform

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Andreu Cerezo, Pablo, Hernández Luz, Carles, Picornell Sanjuan, Tomás, López Rodríguez, Pedro, Alcaide Portet, Sergi, Bas Jalón, Francisco, Benedicte Illescas, Pedro, Chang, Feng, Cabo Pitarch, Guillem, Fuentes Díaz, Francisco Javier, Abella Ferrer, Jaume, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Andreu Cerezo, Pablo, Hernández Luz, Carles, Picornell Sanjuan, Tomás, López Rodríguez, Pedro, Alcaide Portet, Sergi, Bas Jalón, Francisco, Benedicte Illescas, Pedro, Chang, Feng, Cabo Pitarch, Guillem, Fuentes Díaz, Francisco Javier, and Abella Ferrer, Jaume
Abstract: This paper presents the end-to-end QoS approach to provide performance guarantees followed in the SELENEplatform, a high-performance RISC-V based heterogeneous SoC for safety-related real-time systems. Our QoS approach includes smart interconnect solutions for buses and NoCs, along with multicore interference-aware statistics units to, cooperatively, achieve end-to-end QoS., This work has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement no. 871467. BSC work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB-C21/AEI/10.13039/501100011033., Peer Reviewed, Postprint (published version)
Published: 2022

11. De-RISC: A complete RISC-V based space-grade platform

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Wessman, Nils-Johan, Malatesta, Fabio, Ribes, Stefano, Andersson, Jan, García Vilanova, Antonio, Masmano Tello, Miguel, Nicolau Gallego, Vicente, Gómez Molinero, Paco, Le Rhun, Jimmy, Alcaide Portet, Sergi, Cabo Pitarch, Guillem, Bas Jalón, Francisco, Benedicte Illescas, Pedro, Mazzocchetti, Fabio, Abella Ferrer, Jaume, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Wessman, Nils-Johan, Malatesta, Fabio, Ribes, Stefano, Andersson, Jan, García Vilanova, Antonio, Masmano Tello, Miguel, Nicolau Gallego, Vicente, Gómez Molinero, Paco, Le Rhun, Jimmy, Alcaide Portet, Sergi, Cabo Pitarch, Guillem, Bas Jalón, Francisco, Benedicte Illescas, Pedro, Mazzocchetti, Fabio, and Abella Ferrer, Jaume
Abstract: The H2020 EIC-FTI De-RISC project develops a RISC-V space-grade platform to jointly respond to several emerging, as well as longstanding needs in the space domain such as: (1) higher performance than that of monocore and basic multicore space-grade processors in the market; (2) access to an increasingly rich software ecosystem rather than sticking to the slowly fading SPARC and PowerPC-based ones; (3) freedom (or drastic reduction) of export and license restrictions imposed by commercial ISAs such as Arm; and (4) improved support for the design and validation of safety-related real-time applications, (5) being the platform with software qualified and hardware designed per established space industry standards. De-RISC partners have set up the different layers of the platform during the first phases of the project. However, they have recently boosted integration and assessment activities. This paper introduces the De-RISC space platform, presents recent progress such as enabling virtualization and software qualification, new MPSoC features, and use case deployment and evaluation, including a comparison against other commercial platforms. Finally, this paper introduces the ongoing activities that will lead to the hardware and fully qualified software platform at TRL8 on FPGA by September 2022., This project has received funding from the European Union’s Horizon 2020 Research and Innovation programme under Grant Agreement EIC-FTI 869945. BSC work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-07255GBC21/AEI/10.13039/501100011033., Peer Reviewed, Postprint (author's final draft)
Published: 2022

12. Testbench development and performance bottleneck analysis of the cache coherence protocols in multiprocessor systems based on the RISC-V Lagarto architecture

Author: Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Cristal Kestelman, Adrián, Ramírez Salinas, Marco Antonio, Bustamante Peralta, Noé, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Cristal Kestelman, Adrián, Ramírez Salinas, Marco Antonio, and Bustamante Peralta, Noé
Abstract: The Lagarto project constitutes the basis of some important processor designs; some tapeouts with different versions and refactors have been done by collaboration. The first integration of the processor has been done using the Lowrisc SoC, which is a functional system, but being a project also under development, it has too many bugs, some of them are known by the nature of the design, and some others have been found by doing a more intensive verification. At the end of the day, the collaboration aims to have a functional SoC with most of the integration done in-house, so it is convenient to know well the operation of the system under the characteristics and configurations that are required to have a system capable of providing computational power for HPC. Studies in recent years have evaluated that as Moore's law has reached an unprecedented limit, so multicore systems would solve the performance problem, which is why this work focuses on studying and stressing the hierarchy of the memory side of the coherence protocols. Overall our work represents a extensive study and analysis of the coherence protocols stressed by running specific testbenches in different cases. Results demonstrate that trends are as we expected, but with more detail in which areas of the system are more bottlenecks depending on the testbench and its data size.
Published: 2022

13. De-RISC: A complete RISC-V based space-grade platform

Author: Nils-Johan Wessman, Fabio Malatesta, Stefano Ribes, Jan Andersson, Antonio Garcia-Vilanova, Miguel Masmano, Vicente Nicolau, Paco Gomez, Jimmy Le Rhun, Sergi Alcaide, Guillem Cabo, Francisco Bas, Pedro Benedicte, Fabio Mazzocchetti, Jaume Abella, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, and Barcelona Supercomputing Center
Subjects: Multicore processing, Licenses, Hardware, Real-time data processing, Multiprocessors, Multiprocessadors, Program processors, Ordinadors immersos, Sistemes d', Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC], Embedded computer systems, Industries, Temps real (Informàtica), Software
Abstract: The H2020 EIC-FTI De-RISC project develops a RISC-V space-grade platform to jointly respond to several emerging, as well as longstanding needs in the space domain such as: (1) higher performance than that of monocore and basic multicore space-grade processors in the market; (2) access to an increasingly rich software ecosystem rather than sticking to the slowly fading SPARC and PowerPC-based ones; (3) freedom (or drastic reduction) of export and license restrictions imposed by commercial ISAs such as Arm; and (4) improved support for the design and validation of safety-related real-time applications, (5) being the platform with software qualified and hardware designed per established space industry standards. De-RISC partners have set up the different layers of the platform during the first phases of the project. However, they have recently boosted integration and assessment activities. This paper introduces the De-RISC space platform, presents recent progress such as enabling virtualization and software qualification, new MPSoC features, and use case deployment and evaluation, including a comparison against other commercial platforms. Finally, this paper introduces the ongoing activities that will lead to the hardware and fully qualified software platform at TRL8 on FPGA by September 2022. This project has received funding from the European Union’s Horizon 2020 Research and Innovation programme under Grant Agreement EIC-FTI 869945. BSC work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-07255GBC21/AEI/10.13039/501100011033.
Published: 2022

14. SafeSoftDR: A Library to Enable Software-based Diverse Redundancy for Safety-Critical Tasks

Author: Mazzocchetti, Fabio, Alcaide Portet, Sergi, Bas Jalón, Francisco, Benedicte Illescas, Pedro, Cabo Pitarch, Guillem, Chang, Feng, Fuentes Díaz, Francisco Javier, Abella Ferrer, Jaume, and Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors
Subjects: FOS: Computer and information sciences, Informàtica::Seguretat informàtica [Àrees temàtiques de la UPC], Computer security, Hardware Architecture (cs.AR), Multiprocessors, Seguretat informàtica, Multiprocessadors, Computer Science - Hardware Architecture, Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC]
Abstract: Applications with safety requirements have become ubiquitous nowadays and can be found in edge devices of all kinds. However, microcontrollers in those devices, despite offering moderate performance by implementing multicores and cache hierarchies, may fail to offer adequate support to implement some safety measures needed for the highest integrity levels, such as lockstepped execution to avoid so-called common cause failures (i.e., a fault affecting redundant components causing the same error in all of them). To respond to this limitation, an approach based on a software monitor enforcing some sort of software-based lockstepped execution across cores has been proposed recently, providing a proof of concept. This paper presents SafeSoftDR, a library providing a standard interface to deploy software-based lockstepped execution across non-natively lockstepped cores relieving end-users from having to manage the burden to create redundant processes, copying input/output data, and performing result comparison. Our library has been tested on x86-based Linux and is currently being integrated on top of an open-source RISC-V platform targeting safety-related applications, hence offering a convenient environment for safety-critical applications., Comment: FORECAST 2022 Functional Properties and Dependability in Cyber-Physical Systems Workshop (held jointly with HiPEAC Conference)
Published: 2022
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15. Testbench development and performance bottleneck analysis of the cache coherence protocols in multiprocessor systems based on the RISC-V Lagarto architecture

Author: Bustamante Peralta, Noé, Cristal Kestelman, Adrián, Ramírez Salinas, Marco Antonio, and Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors
Subjects: RISC microprocessors, shared memory, edge computing, Microprocessadors RISC, Multiprocessors, Multiprocessor, cache coherence, Multiprocessadors, memory systems, Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC]
Abstract: The Lagarto project constitutes the basis of some important processor designs; some tapeouts with different versions and refactors have been done by collaboration. The first integration of the processor has been done using the Lowrisc SoC, which is a functional system, but being a project also under development, it has too many bugs, some of them are known by the nature of the design, and some others have been found by doing a more intensive verification. At the end of the day, the collaboration aims to have a functional SoC with most of the integration done in-house, so it is convenient to know well the operation of the system under the characteristics and configurations that are required to have a system capable of providing computational power for HPC. Studies in recent years have evaluated that as Moore's law has reached an unprecedented limit, so multicore systems would solve the performance problem, which is why this work focuses on studying and stressing the hierarchy of the memory side of the coherence protocols. Overall our work represents a extensive study and analysis of the coherence protocols stressed by running specific testbenches in different cases. Results demonstrate that trends are as we expected, but with more detail in which areas of the system are more bottlenecks depending on the testbench and its data size.
Published: 2022

16. Enhancing OpenMP tasking model: performance and portability

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Yu, Chenle, Royuela Alcázar, Sara, Quiñones Moreno, Eduardo, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Yu, Chenle, Royuela Alcázar, Sara, and Quiñones Moreno, Eduardo
Abstract: OpenMP, as the de-facto standard programming model in symmetric multiprocessing for HPC, has seen its performance boosted continuously by the community, either through implementation enhancements or specification augmentations. Furthermore, the language has evolved from a prescriptive nature, as defined by the thread-centric model, to a descriptive behavior, as defined by the task-centric model. However, the overhead related to the orchestration of tasks is still relatively high. Applications exploiting very fine-grained parallelism and systems with a large number of cores available might fail on scaling. In this work, we propose to include the concept of Task Dependency Graph (TDG) in the specification by introducing a new clause, named taskgraph, attached to task or target directives. By design, the TDG allows alleviating the overhead associated with the OpenMP tasking model, and it also facilitates linking OpenMP with other programming models that support task parallelism. According to our experiments, a GCC implementation of the taskgraph is able to significantly reduce the execution time of fine-grained task applications and increase their scalability with regard to the number of threads., This work has been supported by the EU H2020 project AMPERE under the grant agreement no. 871669., Peer Reviewed, Postprint (author's final draft)
Published: 2021

17. SafeDE: a flexible Diversity Enforcement hardware module for light-lockstepping

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Bas Jalón, Francisco, Alcaide Portet, Sergi, Lorenzo Ortega, Rubén, Cabo Pitarch, Guillem, Gil Rodríguez, Guillermo, Sala Sucarrats, Oriol, Mazzocchetti, Fabio, Trilla Rodríguez, David, Abella Ferrer, Jaume, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Bas Jalón, Francisco, Alcaide Portet, Sergi, Lorenzo Ortega, Rubén, Cabo Pitarch, Guillem, Gil Rodríguez, Guillermo, Sala Sucarrats, Oriol, Mazzocchetti, Fabio, Trilla Rodríguez, David, and Abella Ferrer, Jaume
Abstract: Safety-related systems, such as those in automotive, avionics and space, impose the existence of appropriate safety measures to meet the safety requirements of the system. In the case of the highest integrity level functionalities (e.g. ASIL-D in automotive), diverse redundancy must be deployed to avoid unreasonable risk of a single fault leading the system to a failure (e.g. using lockstepped cores). However, existing lockstep solutions are either (1) highly intrusive and inflexible coupling two cores with hardware means, or (2) costly in terms of execution time and monitoring if a software monitor thread checks that cores running redundantly preserve sufficient staggering. This paper presents SafeDE, a Diversity Enforcement hardware module providing light-lockstep support by means of a non-intrusive and flexible hardware module that preserves staggering across cores running redundant threads, thus bringing time diversity. SafeDE reconciles the lightness and flexibility of software-only solutions, even allowing using the cores without any lockstepping, as well as the tighter staggering of hardware-only solutions that allow using staggering values of few cycles, instead of hundreds of microseconds, as for software-only solutions. Our integration of SafeDE in a RISC-V FPGA-based space multicore from Cobham Gaisler shows that staggering is effectively preserved, and SafeDE overheads are negligible in terms of area and performance due to staggering., This work has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement no. 871467. This work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB., Peer Reviewed, Postprint (author's final draft)
Published: 2021

18. De-RISC: the First RISC-V space-grade platform for safety-critical systems

Author: Barcelona Supercomputing Center, Wessman, Nils-Johan, Malatesta, Fabio, Andersson, Jan, Gómez Molinero, Paco, Masmano Tello, Miguel, Nicolau Gallego, Vicente, Le Rhun, Jimmy, Cabo Pitarch, Guillem, Bas Jalón, Francisco, Lorenzo Ortega, Rubén, Sala Sucarrats, Oriol, Trilla Rodríguez, David, Abella Ferrer, Jaume, Barcelona Supercomputing Center, Wessman, Nils-Johan, Malatesta, Fabio, Andersson, Jan, Gómez Molinero, Paco, Masmano Tello, Miguel, Nicolau Gallego, Vicente, Le Rhun, Jimmy, Cabo Pitarch, Guillem, Bas Jalón, Francisco, Lorenzo Ortega, Rubén, Sala Sucarrats, Oriol, Trilla Rodríguez, David, and Abella Ferrer, Jaume
Abstract: The increasing needs for performance in the space domain for highly autonomous systems calls for more powerful space MPSoCs and appropriate hypervisors to master them. These platforms must adhere to strict reliability, verifiability and validation requirements since spacecraft for deep space missions are exposed to a harsh environment. Systems must undergo screening and tests against standards for electronic components and software. Unfortunately, currently available space-grade processor components do not meet requirements related to safety that are becoming increasingly important in space applications. This paper presents the De-RISC platform, consisting of Cobham Gaisler’s RISC-V based SoC, and fentISS’ XtratuM Next Generation hypervisor. The platform implements the open RISC-V Instruction Set Architecture, and leverages space SoC IP by Cobham Gaisler, space hypervisor technology by fentISS, multicore interference management solutions by the Barcelona Supercomputing Center, and end user experience and requirement guidance by Thales Research and Technology. At its current state, the platform is already complete and integrated, and starting its validation phase prior to reaching commercial maturity by early 2022. In this paper, we provide details of the platform and some preliminary evidence of its operation., This project has received funding from the European Union’s Horizon 2020 Research and Innovation programme under Grant Agreement EIC-FTI 869945. BSC work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB., Peer Reviewed, Postprint (author's final draft)
Published: 2021

19. SafeTI: a hardware traffic injector for MPSoC functional and timing validation

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Sala Sucarrats, Oriol, Alcaide Portet, Sergi, Cabo Pitarch, Guillem, Bas Jalón, Francisco, Lorenzo Ortega, Rubén, Benedicte Illescas, Pedro, Trilla Rodríguez, David, Gil Rodríguez, Guillermo, Mazzocchetti, Fabio, Abella Ferrer, Jaume, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Sala Sucarrats, Oriol, Alcaide Portet, Sergi, Cabo Pitarch, Guillem, Bas Jalón, Francisco, Lorenzo Ortega, Rubén, Benedicte Illescas, Pedro, Trilla Rodríguez, David, Gil Rodríguez, Guillermo, Mazzocchetti, Fabio, and Abella Ferrer, Jaume
Abstract: Functional and timing validation of safety-related MPSoCs requires testing specific traffic patterns in the on-chip interconnects. Generally, testing needs to be performed by using software tests whose degree of control on the traffic generated is indirect, and limited to behavior that can be triggered by software, thus often unable to produce traffic generated by peripherals. Therefore, untested traffic scenarios can be abundant and, to a large extent, it is hard to know what traffic scenarios have been effectively tested. This paper presents the safe traffic injector, SafeTI, which allows injecting programmable traffic in AMBA AHB interconnects with high flexibility and degree of control, thus easing achieving high coverage in terms of traffic scenarios tested, and mitigating the uncertainty due to the difficulties to relate software tests with actual traffic scenarios tested. We also integrate successfully the SafeTI in an industrial MPSoC for the space domain proving the effectiveness of the proposed traffic injector., This work has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement no. 871467. This work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB., Peer Reviewed, Postprint (author's final draft)
Published: 2021

20. WiDir: A Wireless-Enabled Directory cache coherence protocol

Author: Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CBA - Sistemes de Comunicacions i Arquitectures de Banda Ampla, Franques, Antonio, Kokolis, Apostolos, Abadal Cavallé, Sergi, Fernando, Vimuth, Misailovic, Sasa, Torrellas, Josep, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CBA - Sistemes de Comunicacions i Arquitectures de Banda Ampla, Franques, Antonio, Kokolis, Apostolos, Abadal Cavallé, Sergi, Fernando, Vimuth, Misailovic, Sasa, and Torrellas, Josep
Abstract: As the core count in shared-memory manycores keeps increasing, it is becoming increasingly harder to design cache-coherence protocols that deliver high performance without an inordinate increase in complexity and cost. In particular, sharing patterns where a group of cores frequently reads and writes a shared variable are hard to support efficiently. Hence, programmers end up tuning their applications to avoid these patterns, hurting the programmability of shared memory. To address this problem, this paper uses the recently-proposed on-chip wireless network technology to augment a conventional invalidation-based directory cache coherence protocol. We call the resulting protocol WiDir. WiDir seamlessly transitions between wired and wireless coherence transactions for a given line based on the access patterns in a programmer-transparent manner. In this paper, we describe the protocol transitions in detail. Further, an evaluation using SPLASH and PARSEC applications shows that WiDir substantially reduces the memory stall time of applications. As a result, for 64-core runs, WiDir reduces the execution time of applications by an average of 22% compared to a conventional directory protocol. Moreover, WiDir is more scalable. These benefits are obtained with a very modest power cost., This work was funded in part by NSF Grant No. CCF1629431 and by EU’s Horizon 2020 Research and Innovation Programme Grant No. 863337 (WiPLASH)., Peer Reviewed, Postprint (author's final draft)
Published: 2021

21. MUCH: exploiting pairwise hardware event monitor correlations for improved timing analysis of complex MPSoCs

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Vilardell Moreno, Sergi, Serra Mochales, Isabel, Mezzetti, Enrico, Abella Ferrer, Jaume, Cazorla Almeida, Francisco Javier, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Vilardell Moreno, Sergi, Serra Mochales, Isabel, Mezzetti, Enrico, Abella Ferrer, Jaume, and Cazorla Almeida, Francisco Javier
Abstract: Measurement-based timing analysis techniques increasingly rely on the Performance Monitoring Units (PMU) of MPSoCs, as these units implement specialized Hardware Event Monitors (HEMs) that convey detailed information about multicore interference in hardware shared resources. Unfortunately, there is an evident mismatch between the large number of HEMs (typically several hundreds) and the comparatively small number (normally less than ten) of Performance Monitoring Counters (PMCs) that can be configured to track HEMs in the PMU. Timing analysis normally require to observe a non-negligible number of HEMs per task from the same execution. However, due to the small number of PMCs, HEMs are necessarily collected across multiple runs that, despite intended to repeat the same experiment, carry out some significant variability (above 50% for some HEMs in relevant MPSoCs) caused by platform-intrinsic execution conditions. Therefore, blindly merging HEMs from different runs is not acceptable since they may easily correspond to significantly different conditions. To tackle this issue, the HRM approach has been proposed recently to merge HEMs from different runs accurately preserving their correlation w.r.t. one anchor HEM (i.e. processor cycles) building on order statistics. However, HRM do not always preserves the correlation between other pairs of HEMs that might be lost to a large extent. This paper copes with HRM limitations by proposing the MUlti-Correlation HEM reading and merging approach (MUCH). MUCH builds on multivariate Gaussian distributions to merge HEMs from different runs while preserving pairwise correlations across each individual pair of HEMs simultaneously. Our results on an NXP T2080 MPSoC used for avionics systems show that MUCH largely outperforms HRM for an identical number of input runs., This work has been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB, the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement No. 772773) and the HiPEAC Network of Excellence., Peer Reviewed, Postprint (author's final draft)
Published: 2021

22. Advanced synchronization techniques for task-based runtime systems

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Álvarez Robert, David, Sala Penadés, Kevin, Maroñas Bravo, Marcos, Roca Nonell, Aleix, Beltran Querol, Vicenç, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Álvarez Robert, David, Sala Penadés, Kevin, Maroñas Bravo, Marcos, Roca Nonell, Aleix, and Beltran Querol, Vicenç
Abstract: Task-based programming models like OmpSs-2 and OpenMP provide a flexible data-flow execution model to exploit dynamic, irregular and nested parallelism. Providing an efficient implementation that scales well with small granularity tasks remains a challenge, and bottlenecks can manifest in several runtime components. In this paper, we analyze the limiting factors in the scalability of a task-based runtime system and propose individual solutions for each of the challenges, including a wait-free dependency system and a novel scalable scheduler design based on delegation. We evaluate how the optimizations impact the overall performance of the runtime, both individually and in combination. We also compare the resulting runtime against state of the art OpenMP implementations, showing equivalent or better performance, especially for fine-grained tasks., This project is supported by the European Union’s Horizon 2020 Research and Innovation programme under grant agreement No.s 754304 (DEEP-EST), by the Spanish Ministry of Science and Innovation (contract PID2019-107255GB and TIN2015-65316P) and by the Generalitat de Catalunya (2017-SGR-1414)., Peer Reviewed, Postprint (author's final draft)
Published: 2021

23. SafeSU: an extended statistics unit for multicore timing interference

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Barcelona Supercomputing Center, Universitat Politècnica de Catalunya. CAP - Grup de Computació d'Altes Prestacions, Cabo Pitarch, Guillem, Bas Jalón, Francisco, Lorenzo Ortega, Rubén, Trilla Rodríguez, David, Alcaide Portet, Sergi, Moretó Planas, Miquel, Hernández Luz, Carles, Abella Ferrer, Jaume, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Barcelona Supercomputing Center, Universitat Politècnica de Catalunya. CAP - Grup de Computació d'Altes Prestacions, Cabo Pitarch, Guillem, Bas Jalón, Francisco, Lorenzo Ortega, Rubén, Trilla Rodríguez, David, Alcaide Portet, Sergi, Moretó Planas, Miquel, Hernández Luz, Carles, and Abella Ferrer, Jaume
Abstract: Statistics units (SUs) in MPSoCs are becoming increasingly used for the (1) verification and (2) validation of multicore timing interference, as well as for (3) deploying safety measures in safety-related real-time systems. However, existing SU extensions to manage multicore timing interference have neither been integrated together nor deployed in commercial MPSoCs.This paper presents the realization of the Safe Statistics Unit (SafeSU for short), which smartly integrates existing solutions for multicore timing interference verification, validation and monitoring, and is in turn integrated in commercial space-graded RISC-V and SparcV8 MPSoCs. Our evaluation illustrates the operation of the SafeSU, and paves the way for a thorough validation prior to reaching commercialization and being offered as open source IP., This work has received funding from the European Union’s Horizon 2020 Research and Innovation programme under Grant Agreement EICFTI 869945., Peer Reviewed, Postprint (author's final draft)
Published: 2021

24. Improving multitask performance and energy consumption with partial-ISA multicores

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Dellagostin Souza, Jeckson, Exenberger Becker, Pedro Henrique, Schneider Beck, Antonio Carlos, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Dellagostin Souza, Jeckson, Exenberger Becker, Pedro Henrique, and Schneider Beck, Antonio Carlos
Abstract: Modern GPPs implement specialized instructions in the form of ISA extensions aiming to increase the performance of emerging applications. These extensions impose a significant overhead in the area and power of the processor because of their specific datapaths (e.g. hardware for SIMD and FP instructions may represent more than half of the core area). Considering that some devices (e.g., edge computing), must be as energy- and area-efficient as possible, and the sporadic usage of specialized instructions in many applications, we propose PHISA multicores. PHISA is composed of heterogeneous cores of the same single base ISA, but asymmetric functionality: some of the cores do not fully implement the costly instruction extensions, making room for the designers to add more efficient cores. We show that PHISA increases performance in (32%) and reduces energy consumption in (82%) compared to full-ISA systems with the same power budget, in multi-workload environments., This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, Brasil (CAPES) - Finance Code 001, the Fundação de Amparo à Pesquisa do Estado do RS (FAPERGS), Brazil and the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Brazil., Peer Reviewed, Postprint (author's final draft)
Published: 2021

25. Empirical evidence for MPSoCs in critical systems: The case of NXP’s T2080 cache coherence

Author: Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Pujol Torramorell, Roger, Tabani, Hamid, Abella Ferrer, Jaume, Hassan, Mohamed, Cazorla Almeida, Francisco Javier, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Barcelona Supercomputing Center, Pujol Torramorell, Roger, Tabani, Hamid, Abella Ferrer, Jaume, Hassan, Mohamed, and Cazorla Almeida, Francisco Javier
Abstract: The adoption of complex MPSoCs in critical real-time embedded systems mandates a detailed analysis their architecture to facilitate certification. This analysis is hindered by the lack of a thorough understanding of the MPSoC system due to the unobvious and/or insufficiently documented behavior of some key hardware features. Confidence on those features can only be regained by building specific tests to both, assess whether their behavior matches specifications and unveil their behavior when it is not fully known a priori. In this work, we introduce a systematic approach that constructs this thorough understanding of the MPSoC architecture-- and assess against its specification in processor documentation -- with a focus on the cache coherence protocol in the avionics-relevant NXP T2080 architecture as our use-case. Our approach covers all transitions in the MESI cache coherence protocol, with emphasis on the coherence between DMA and processing cores. We build evidence of their behavior based on available debug support and performance monitors. Our analysis discloses unexpected behavior for coherence-related notifications as well as some hardware monitors., This work has been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB; the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 878752 (MASTECS) and the European Research Council (ERC) grant agreement No. 772773 (SuPerCom); the HiPEAC Network of Excellence; and the Natural Sciences and Engineering Research Council of Canada (NSERC)., Peer Reviewed, Postprint (author's final draft)
Published: 2021

26. On the definition of resource sharing levels to understand and control the impact of contention in multicore processors

Author: Barcelona Supercomputing Center, Mezzetti, Enrico, Abella Ferrer, Jaume, Cazorla Almeida, Francisco Javier, Tabani, Hamid, Kosmidis, Leonidas, Barcelona Supercomputing Center, Mezzetti, Enrico, Abella Ferrer, Jaume, Cazorla Almeida, Francisco Javier, Tabani, Hamid, and Kosmidis, Leonidas
Abstract: The trend toward the adoption of a multiprocessor system on a chip (MPSoC) in critical real-time domains, like avionics or automotive, responds to the demand for increased computing performance to support advanced software functionalities. The other side of the coin is that MPSoCs challenge software timing analysis. This is so as co-running applications affect each other’s timing behavior on account of the interference incurred when accessing shared hardware resources, with the latter steadily increasing in number and complexity in every new generation of MPSoCs. For a solid and cost-contained software-timing validation approach, we contend that a taxonomy has to be developed to capture the different levels at which processors’ resources can be shared. Those levels are to be related to the conventional run-time software abstractions (e.g., task, thread, runnable) and the particular abstraction used to carry out contention analysis. From the standpoint of contention analysis, only the resources in those levels shared by the different run-time software entities need to be mastered and addressed by timing analysis, whereas the remaining resources can be safely disregarded. We tailor this approach to two of NVIDIA’s embedded platforms, TX2 and AGX Xavier, of particular relevance for the automotive domain. For the identified shared resources, we also characterize the contention that tasks can suffer and discuss the limitations and early approaches for modeling timing interference in shared hardware resources., This work has been partially supported by the SpanishMinistry of Science and Innovation under grants PID2019-107255GB and FJCI-2017 -34095; and the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 878752 (MASTECS) and the European Research Council (ERC) grant agreement No. 772773 (SuPerCom)., Peer Reviewed, Postprint (published version)
Published: 2021

27. Near-optimal replacement policies for shared caches in multicore processors

Author: Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CAP - Grup de Computació d'Altes Prestacions, Díaz Maag, Javier, Ibáñez Marín, Pablo, Monreal Arnal, Teresa, Viñals Yúfera, Victor, Llaberia Griñó, José M., Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Universitat Politècnica de Catalunya. CAP - Grup de Computació d'Altes Prestacions, Díaz Maag, Javier, Ibáñez Marín, Pablo, Monreal Arnal, Teresa, Viñals Yúfera, Victor, and Llaberia Griñó, José M.
Abstract: An optimal replacement policy that minimizes the miss rate in a private cache was proposed several decades ago. It requires knowing the future access sequence the cache will receive. There is no equivalent for shared caches because replacement decisions alter this future sequence. We present a novel near-optimal policy for minimizing the miss rate in a shared cache that approaches the optimal execution iteratively. During each iteration, the future access sequence is reconstructed on every miss interleaving the future per-core sequences, taken from the previous iteration. This single sequence feeds a classical private-cache optimum replacement policy. Our evaluation on a shared last-level cache shows that our proposal iteratively converges to a near-optimal miss rate that is independent of the initial conditions, within a margin of 0.1%. The best state-of-the-art online policies achieve around 65% of the miss rate reduction obtained by our near-optimal proposal. In a shared cache, miss rate optimization does not imply the optimization of other metrics. Therefore, we also propose a new near-optimal policy to maximize fairness between cores. The best state-of-the-art online policy achieves 60% of the improvement in fairness seen with our near-optimal policy. Our proposals are useful both for setting upper performance bounds and inspiring implementable mechanisms for shared caches., The authors acknowledge support from grants (1) PID2019-105660RB-C21 and PID2019-107255GB-C22 from Agencia Estatal de Investigación (AEI) from Spain and European Regional Development Fund (ERDF); (2) gaZ: T58_20R research group from Aragón Government and European Social Fund (ESF); and (3) 2014-2020 "Construyendo Europa desde Aragón" from European Regional Development Fund (ERDF)., Peer Reviewed, Postprint (author's final draft)
Published: 2021

28. Design and implementation of a traffic injector for a bus-based space multicore

Author: Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Moll Echeto, Francisco de Borja, Abella Ferrer, Jaume, Sala I Sucarrats, Oriol, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Moll Echeto, Francisco de Borja, Abella Ferrer, Jaume, and Sala I Sucarrats, Oriol
Abstract: Real-time multiprocessor systems have particular needs related to their design, verification, and validation. In particular, they have stringent requirements to prove that they will correctly perform their functionalities, on-time and minimizing system failures. Leading industrial applications such as aerospace vehicles or low orbit satellites require an increase of computing power while pursuing fast certification and a short time to market. These performance demands push for the adoption of multicore processors, generally with limited core counts, and connected with low-complexity interconnects, such as buses, to keep design complexity low and have some degree of isolation by construction among cores connected to different buses. The need for appropriate multicore interference timing verification and validation grows as those multicores are adopted for safety-relevant systems since evidence on the deadlines being met is needed. In particular, verification means are needed to assess whether deadlines can be met, and validation means are required in order to test that execution time bounds are not exceeded even under stress conditions. The lack of control and observability channels when using software-only interference generation tools leads to the overwhelming design and validation costs and inefficiencies since testing effort needs to increase to achieve some high coverage of realistic stressing conditions. However, still, there is not an easy way to assess whether such coverage is effectively achieved. All these barriers lead to less powerful and more expensive systems, as well as lower confidence in the guarantees achieved, and gives us a motivation to design a fully integrated hardware module that focuses on the generation of critical corner-cases traffic scenarios and eases the verification and validation of system interference bounds. This thesis's work focuses on implementing and integrating a hardware traffic injector that aims to go one step further into t
Published: 2021

29. SafeDE: a flexible Diversity Enforcement hardware module for light-lockstepping

Author: David Trilla, Sergi Alcaide, Jaume Abella, Oriol Sala, Francisco Bas, Fabio Mazzocchetti, Ruben Lorenzo, Guillem Cabo, Guillermo Gil, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, and Barcelona Supercomputing Center
Subjects: Flexibility (engineering), Multi-core processor, Computer science, business.industry, Aerospace electronics, Multiprocessadors, Seguretat informàtica, Lockstep, Thread (computing), Avionics, Multicore processing, Redundancy, Hardware, Software, Computer security, Task analysis, Redundancy (engineering), Multiprocessors, Safety, business, Field-programmable gate array, Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC], Computer hardware
Abstract: Safety-related systems, such as those in automotive, avionics and space, impose the existence of appropriate safety measures to meet the safety requirements of the system. In the case of the highest integrity level functionalities (e.g. ASIL-D in automotive), diverse redundancy must be deployed to avoid unreasonable risk of a single fault leading the system to a failure (e.g. using lockstepped cores). However, existing lockstep solutions are either (1) highly intrusive and inflexible coupling two cores with hardware means, or (2) costly in terms of execution time and monitoring if a software monitor thread checks that cores running redundantly preserve sufficient staggering. This paper presents SafeDE, a Diversity Enforcement hardware module providing light-lockstep support by means of a non-intrusive and flexible hardware module that preserves staggering across cores running redundant threads, thus bringing time diversity. SafeDE reconciles the lightness and flexibility of software-only solutions, even allowing using the cores without any lockstepping, as well as the tighter staggering of hardware-only solutions that allow using staggering values of few cycles, instead of hundreds of microseconds, as for software-only solutions. Our integration of SafeDE in a RISC-V FPGA-based space multicore from Cobham Gaisler shows that staggering is effectively preserved, and SafeDE overheads are negligible in terms of area and performance due to staggering. This work has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement no. 871467. This work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB.
Published: 2021

30. SafeTI: a Hardware Traffic Injector for MPSoC Functional and Timing Validation

Author: David Trilla, Guillermo Gil, Francisco Bas, Oriol Sala, Guillem Cabo, Fabio Mazzocchetti, Pedro Benedicte, Sergi Alcaide, Jaume Abella, Ruben Lorenzo, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, and Barcelona Supercomputing Center
Subjects: Flexibility (engineering), Multiprocessing systems, business.industry, Computer science, Systems analysis, Multiprocessadors, Seguretat informàtica, Injector, MPSoC, High coverage, law.invention, Domain (software engineering), Integrated circuit interconnects, Software, Computer security, law, Safety testing, Embedded system, Timing circuits, Multiprocessors, System on a chip, business, Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC], System-on-chip
Abstract: Functional and timing validation of safety-related MPSoCs requires testing specific traffic patterns in the on-chip interconnects. Generally, testing needs to be performed by using software tests whose degree of control on the traffic generated is indirect, and limited to behavior that can be triggered by software, thus often unable to produce traffic generated by peripherals. Therefore, untested traffic scenarios can be abundant and, to a large extent, it is hard to know what traffic scenarios have been effectively tested. This paper presents the safe traffic injector, SafeTI, which allows injecting programmable traffic in AMBA AHB interconnects with high flexibility and degree of control, thus easing achieving high coverage in terms of traffic scenarios tested, and mitigating the uncertainty due to the difficulties to relate software tests with actual traffic scenarios tested. We also integrate successfully the SafeTI in an industrial MPSoC for the space domain proving the effectiveness of the proposed traffic injector. This work has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement no. 871467. This work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB.
Published: 2021

31. On the Definition of Resource Sharing Levels to Understand and Control the Impact of Contention in Multicore Processors

Author: Hamid Tabani, Leonidas Kosmidis, Enrico Mezzetti, Jaume Abella Ferrer, Francisco Javier Cazorla Almeida, and Barcelona Supercomputing Center
Subjects: Multi-core processor, Software timing, Horizon (archaeology), Operations research, Computer science, Freedom from interference, European research, Control (management), Real-time data processing, Multicore timing analysis, Interference channel, Multiprocessadors, Multicore contention, Shared resource, Work (electrical), Multiprocessors, media_common.cataloged_instance, European union, Embedded systems (Computer systems), Informàtica::Hardware [Àrees temàtiques de la UPC], media_common
Abstract: The trend toward the adoption of a multiprocessor system on a chip (MPSoC) in critical real-time domains, like avionics or automotive, responds to the demand for increased computing performance to support advanced software functionalities. The other side of the coin is that MPSoCs challenge software timing analysis. This is so as co-running applications affect each other’s timing behavior on account of the interference incurred when accessing shared hardware resources, with the latter steadily increasing in number and complexity in every new generation of MPSoCs. For a solid and cost-contained software-timing validation approach, we contend that a taxonomy has to be developed to capture the different levels at which processors’ resources can be shared. Those levels are to be related to the conventional run-time software abstractions (e.g., task, thread, runnable) and the particular abstraction used to carry out contention analysis. From the standpoint of contention analysis, only the resources in those levels shared by the different run-time software entities need to be mastered and addressed by timing analysis, whereas the remaining resources can be safely disregarded. We tailor this approach to two of NVIDIA’s embedded platforms, TX2 and AGX Xavier, of particular relevance for the automotive domain. For the identified shared resources, we also characterize the contention that tasks can suffer and discuss the limitations and early approaches for modeling timing interference in shared hardware resources. This work has been partially supported by the SpanishMinistry of Science and Innovation under grants PID2019-107255GB and FJCI-2017 -34095; and the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 878752 (MASTECS) and the European Research Council (ERC) grant agreement No. 772773 (SuPerCom).
Published: 2021

32. BST: A BookSim-based toolset to simulate NoCs with single- and multi-hop bypass

Author: Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Barcelona Supercomputing Center, Universitat Politècnica de Catalunya. CAP - Grup de Computació d'Altes Prestacions, Pérez Gallardo, Iván, Vallejo Gutiérrez, Enrique, Moreto Planas, Miquel, Beivide Palacio, Julio Ramon, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Barcelona Supercomputing Center, Universitat Politècnica de Catalunya. CAP - Grup de Computació d'Altes Prestacions, Pérez Gallardo, Iván, Vallejo Gutiérrez, Enrique, Moreto Planas, Miquel, and Beivide Palacio, Julio Ramon
Abstract: Network-on-Chips are a critical part of modern multiprocessors and their relevance will grow with the number of cores. The development of future NoC designs relies on detailed simulation models that accurately estimate their performance, power and hardware cost. Bypass routers are promising proposals due to their improved performance. Bypass routers reduce latency thanks to a combination of speculation, pre-routing (lookahead routing) and buffer bypass, which also reduce energy consumption by avoiding unnecessary buffer writes and reads. Multi-hop bypass NoCs, known as SMART, even bypass the crossbar of multiple routers in a single cycle. However, publicly available NoC simulators, such as BookSim or Garnet, do not implement bypass mechanisms or do not model them accurately. In this work, we present Bypass Simulation Toolset (BST), a set of tools to accurately simulate NoCs with single- and multi-hop bypass routers. BST combines and extends several simulation tools: an extension of BookSim with state-of-theart cycle-accurate bypass router models and additional flow control mechanisms; an RTL implementation of multi-hop bypass mechanisms based on OpenSMART; an API to ease a modular integration of the BST NoC simulator in full system simulators; and a set of scripts to automate simulation execution and data collection. To showcase BST, we i) validate BookSim SMART models with the RTL implementation; ii) compare bypass and traditional nonbypass router models; iii) integrate BookSim in gem5 using the proposed API and compare it with gem5’s Simple and Garnet 2.0 NoC models; and iv) present a case study evaluating different combinations of router types and topologies recently proposed for NoCs, highlighting the flexibility of the BST toolset., This work was supported by the Spanish Ministry of Science, Innovation and Universities, contracts TIN2015-65316- P, TIN2016-76635-C2-2-R (AEI/FEDER, UE) and PID2019- 105660RB-C22; the European Union’s Horizon 2020 research and innovation program under the Mont-Blanc 2020 project (grant agreement 779877); and the HiPEAC Network of Excellence. I. Perez is partially supported by an FPI grant, BES- ´ 2017-079971. M. Moreto has been partially supported by the Spanish Ministry of Economy, Industry and Competitiveness under Ramon y Cajal fellowship number RYC-2016-21104. Bluespec Inc. provided access to Bluespec tools., Peer Reviewed, Postprint (author's final draft)
Published: 2020

33. A multithreading RISC-V implementation for Lagarto Architecture

Author: Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Cristal Kestelman, Adrián, Ramírez Salinas, Marco Antonio, Mendoza Escobar, Jonnatan, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Cristal Kestelman, Adrián, Ramírez Salinas, Marco Antonio, and Mendoza Escobar, Jonnatan
Abstract: The development of computer architecture standards for many years was mainly delegated to a few groups of companies that define most of the popular Instructions Set Architectures (ISAs). While the Information Technologies field is constructed through many efforts of interfaces resulting in abstraction layers at several levels, the interaction between software and hardware that an ISA define has particular importance in the field. RISC-V emerges as a potential instrument that unbound the limitations of privates standards and committing to the goal of developing a sustainable model capable of supplying the actual needs of the computation requirements of our society for a broad set of technological end-nodes. This work comprehends the design and implementation of a multithreading RISC-V core based in the Lagarto 1 processor architecture and embedded in the preDRAC SoC inheriting the multicore capabilities of it; looking to contribute to the open-source hardware initiative.
Published: 2020

34. Design of an AXI-SDRAM interface IP in a RISC-V processor

Author: Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Moll Echeto, Francisco de Borja, Marimon Illana, Joan, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Moll Echeto, Francisco de Borja, and Marimon Illana, Joan
Abstract: PreDRAC is a RISC-V based SoC developed with the collaboration of the BSC, CIC-IPN, IMB-CNM (CSIC) and UPC. On its first version, sent to fabricate on May 2019, it used a custom interface to access main memory through an FPGA. Access to memory is critical to the performance of a processor and a AXI-SDRAM interface IP to be integrated into a future revision of the chip has been designed. No specific area, power or performance constraints are defined for AXI-SDRAM interface as the first step is to obtain a functional design with the required verification setup to ensure its proper operation once fabricated on silicon. The design of the IP covers different aspects in the ASIC design flow: the initial RTL implementation, synthesis, verification at RTL and gate-level simulations and a final power analysis. Final results show that this IP can successfully be integrated with the preDRAC SoC, replacing the custom interface, and obtaining better performance. However, the AXI-SDRAM interface IP can be further improved both in terms of performance and power.
Published: 2020

35. Design and implementation of a traffic injector for a bus-based space multicore

Author: Sala I Sucarrats, Oriol, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Moll Echeto, Francisco de Borja, and Abella Ferrer, Jaume
Subjects: traffic, AMBA, injector, multicore, interference, Real-time data processing, RISC-V, Multiprocessadors, Enginyeria de la telecomunicació [Àrees temàtiques de la UPC], NOEL-V, Multiprocessors, Real-time, Temps real (Informàtica), safety-critical, microarchitecture
Abstract: Real-time multiprocessor systems have particular needs related to their design, verification, and validation. In particular, they have stringent requirements to prove that they will correctly perform their functionalities, on-time and minimizing system failures. Leading industrial applications such as aerospace vehicles or low orbit satellites require an increase of computing power while pursuing fast certification and a short time to market. These performance demands push for the adoption of multicore processors, generally with limited core counts, and connected with low-complexity interconnects, such as buses, to keep design complexity low and have some degree of isolation by construction among cores connected to different buses. The need for appropriate multicore interference timing verification and validation grows as those multicores are adopted for safety-relevant systems since evidence on the deadlines being met is needed. In particular, verification means are needed to assess whether deadlines can be met, and validation means are required in order to test that execution time bounds are not exceeded even under stress conditions. The lack of control and observability channels when using software-only interference generation tools leads to the overwhelming design and validation costs and inefficiencies since testing effort needs to increase to achieve some high coverage of realistic stressing conditions. However, still, there is not an easy way to assess whether such coverage is effectively achieved. All these barriers lead to less powerful and more expensive systems, as well as lower confidence in the guarantees achieved, and gives us a motivation to design a fully integrated hardware module that focuses on the generation of critical corner-cases traffic scenarios and eases the verification and validation of system interference bounds. This thesis's work focuses on implementing and integrating a hardware traffic injector that aims to go one step further into the stress-testing state of the art multiprocessor bus-based SoCs in real-time safety-critical applications. Our hardware module offers fine-grained controllability on a range of traffic patterns. It features a transparent software layer capable of interruption-based control and monitoring while maintaining a small memory footprint. AMBA AHB interfaces are provided for a wide market range of hardware platforms. The unit has been integrated with industry-proven SoCs such as NOEL-V (Cobham Gaisler) on novel space-graded hardware platforms as De-RISC and SELENE.
Published: 2021

36. Alineamiento de secuencias genéticas en procesadores multicore

Subjects: Algorismes genètics, Multiprocessadors
Published: 2021

37. Análisis de rendimiento de aplicaciones paralelas de memoria compartida : problema N-body

Subjects: Problema dels cossos múltiples, Multiprocessadors
Published: 2021

38. Diseño y evaluación de un algoritmo paralelo para la eliminación gausiana en procesadores multi-core

Subjects: Programació paral·lela (Informàtica), Algorismes computacionals, Multiprocessadors
Published: 2021

39. Optimització del procés d'arrencada d'un sistema multiprocessador

Subjects: Sistemes incrustats (Informàtica), Multiprocessadors
Published: 2021

40. Simulación de modelos orientados al individuo

Subjects: Multiprocessadors, Ordinadors Arquitectura
Published: 2021

41. Near-optimal replacement policies for shared caches in multicore processors

Author: Teresa Monreal, Víctor Viñals, Javier Díaz, Pablo Ibáñez, José M. Llabería, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, and Universitat Politècnica de Catalunya. CAP - Grup de Computació d'Altes Prestacions
Subjects: Fairness, Interleaving, Computer science, Distributed computing, Cache memory, Memòria cau, 02 engineering and technology, Theoretical Computer Science, Reduction (complexity), Shared cache, Margin (machine learning), 0202 electrical engineering, electronic engineering, information engineering, Multiprocessors, Optimal replacement, Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC], Miss rate, 020203 distributed computing, Multi-core processor, Sequence, Hardware_MEMORYSTRUCTURES, Multiprocessadors, Chip multiprocessor, Shared memory, Hardware and Architecture, Cache, Software, Information Systems
Abstract: An optimal replacement policy that minimizes the miss rate in a private cache was proposed several decades ago. It requires knowing the future access sequence the cache will receive. There is no equivalent for shared caches because replacement decisions alter this future sequence. We present a novel near-optimal policy for minimizing the miss rate in a shared cache that approaches the optimal execution iteratively. During each iteration, the future access sequence is reconstructed on every miss interleaving the future per-core sequences, taken from the previous iteration. This single sequence feeds a classical private-cache optimum replacement policy. Our evaluation on a shared last-level cache shows that our proposal iteratively converges to a near-optimal miss rate that is independent of the initial conditions, within a margin of 0.1%. The best state-of-the-art online policies achieve around 65% of the miss rate reduction obtained by our near-optimal proposal. In a shared cache, miss rate optimization does not imply the optimization of other metrics. Therefore, we also propose a new near-optimal policy to maximize fairness between cores. The best state-of-the-art online policy achieves 60% of the improvement in fairness seen with our near-optimal policy. Our proposals are useful both for setting upper performance bounds and inspiring implementable mechanisms for shared caches. The authors acknowledge support from grants (1) PID2019-105660RB-C21 and PID2019-107255GB-C22 from Agencia Estatal de Investigación (AEI) from Spain and European Regional Development Fund (ERDF); (2) gaZ: T58_20R research group from Aragón Government and European Social Fund (ESF); and (3) 2014-2020 "Construyendo Europa desde Aragón" from European Regional Development Fund (ERDF).
Published: 2021

42. Enhancing OpenMP tasking model: performance and portability

Author: Sara Royuela, Chenle Yu, Eduardo Quinones, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, and Barcelona Supercomputing Center
Subjects: Tasking model, Computer science, Parallel programming (Computer science), 020206 networking & telecommunications, 02 engineering and technology, Parallel computing, Multiprocessadors, Programació en paral·lel (Informàtica), Supercomputers, OpenMP specification, 020202 computer hardware & architecture, Software portability, Supercomputadors, Symmetric multiprocessing, 0202 electrical engineering, electronic engineering, information engineering, Programming paradigm, Parallelism (grammar), Overhead (computing), Multiprocessors, Orchestration (computing), Informàtica::Arquitectura de computadors::Arquitectures paral·leles [Àrees temàtiques de la UPC], Runtime overhead, Scaling
Abstract: OpenMP, as the de-facto standard programming model in symmetric multiprocessing for HPC, has seen its performance boosted continuously by the community, either through implementation enhancements or specification augmentations. Furthermore, the language has evolved from a prescriptive nature, as defined by the thread-centric model, to a descriptive behavior, as defined by the task-centric model. However, the overhead related to the orchestration of tasks is still relatively high. Applications exploiting very fine-grained parallelism and systems with a large number of cores available might fail on scaling. In this work, we propose to include the concept of Task Dependency Graph (TDG) in the specification by introducing a new clause, named taskgraph, attached to task or target directives. By design, the TDG allows alleviating the overhead associated with the OpenMP tasking model, and it also facilitates linking OpenMP with other programming models that support task parallelism. According to our experiments, a GCC implementation of the taskgraph is able to significantly reduce the execution time of fine-grained task applications and increase their scalability with regard to the number of threads. This work has been supported by the EU H2020 project AMPERE under the grant agreement no. 871669.
Published: 2021

43. Improving multitask performance and energy consumption with partial-ISA multicores

Author: Jeckson Dellagostin Souza, Antonio Carlos Schneider Beck, Pedro Henrique Exenberger Becker, and Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors
Subjects: Computer Networks and Communications, Computer science, Energia -- Consum, Overhead (engineering), 02 engineering and technology, Power budget, Theoretical Computer Science, Scheduling (computing), Artificial Intelligence, 0202 electrical engineering, electronic engineering, information engineering, Multiprocessors, SIMD, Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC], Edge computing, business.industry, Scheduling, 020206 networking & telecommunications, Energy consumption, Multiprocessadors, Overlapping-ISA, Energy efficiency, Hardware and Architecture, Embedded system, 020201 artificial intelligence & image processing, Heterogeneity, business, Partial-ISA, Software, Energy (signal processing), Efficient energy use
Abstract: Modern GPPs implement specialized instructions in the form of ISA extensions aiming to increase the performance of emerging applications. These extensions impose a significant overhead in the area and power of the processor because of their specific datapaths (e.g. hardware for SIMD and FP instructions may represent more than half of the core area). Considering that some devices (e.g., edge computing), must be as energy- and area-efficient as possible, and the sporadic usage of specialized instructions in many applications, we propose PHISA multicores. PHISA is composed of heterogeneous cores of the same single base ISA, but asymmetric functionality: some of the cores do not fully implement the costly instruction extensions, making room for the designers to add more efficient cores. We show that PHISA increases performance in (32%) and reduces energy consumption in (82%) compared to full-ISA systems with the same power budget, in multi-workload environments. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, Brasil (CAPES) - Finance Code 001, the Fundação de Amparo à Pesquisa do Estado do RS (FAPERGS), Brazil and the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Brazil.
Published: 2021

44. Optimització del procés d'arrencada d'un sistema multiprocessador

Author: Lluelles Martínez, Hugo, Martinez Huerta, Borja, and Universitat Autònoma de Barcelona. Escola d'Enginyeria
Subjects: Sistemes incrustats (Informàtica), Multiprocessadors
Abstract: L'objectiu d'aquest projecte és el d'optimitzar l'arrencada d'un sistema encastat El objetivo de este proyecto es el de optimizar el arranque de un sistema empotrado The aim of this project is to optimaze the boot process with different computing
Published: 2021

45. Alineamiento de secuencias genéticas en procesadores multicore

Author: Pons Noguera, Carles, Moure, Juan C, and Universitat Autònoma de Barcelona. Escola d'Enginyeria
Subjects: Algorismes genètics, Multiprocessadors
Abstract: Este trabajo analiza el rendimiento del algoritmo de alineamiento de secuencias conocido como Needleman-Wunsch, sobre 3 sistemas de cómputo multiprocesador diferentes. Se analiza y se codifica el algoritmo serie usando el lenguaje de programación C y se plantean una serie de optimizaciones con la finalidad de minimizar el volumen y el tiempo de cómputo. Posteriormente, se realiza un análisis de las prestaciones del programa sobre los diferentes sistemas de cómputo. En la segunda parte del trabajo, se paraleliza el algoritmo serie y se codifica ayudándonos de OpenMP. El resultado son dos variantes del programa que difieren en la relación entre la cantidad de cómputo y la de comunicación. En la primera variante, la comunicación entre procesadores es poco frecuente y se realiza tras largos periodos de ejecución (granularidad gruesa). En cambio, en la segunda variante las tareas individuales son relativamente pequeñas en término de tiempo de ejecución y la comunicación entre los procesadores es frecuente (granularidad fina). Ambas variantes se ejecutan y analizan en arquitecturas multicore que explotan el paralelismo a nivel de thread. Los resultados obtenidos muestran la importancia de entender y saber analizar el efecto del multicore y multithreading en el rendimiento. Aquest treball analitza el rendiment de l'algorisme d'alineament de seqüències conegut com a Needleman-Wunsch sobre 3 sistemes de còmput multiprocessador diferents. S'analitza i es codifica l'algorisme sèrie emprant el llenguatge de programació C i es plantegen una sèrie d'optimitzacions amb la finalitat de minimitzar el volum i el temps de còmput. Posteriorment es realitza una anàlisi de les prestacions del programa sobre els diferents sistemes de còmput. En la segona part del treball, es paral·lelitza l'algorisme sèrie i es codifica ajudant-nos de OpenMP. El resultat són dues variants del programa que difereixen en la relació entre la quantitat de còmput i la de comunicació. En la primera variant, la comunicació entre processadors és poc habitual i es realitza després de llargs períodes d'execució (granularitat gruixuda). En canvi, en la segona variant les tasques individuals s'executen relativament ràpides i la comunicació entre els processadors és freqüent (granularitat fina). Ambdues variants s'executen i s'analitzen en arquitectures multicore que exploten el paral·lelisme a nivell de thread. Els resultats obtinguts ens mostren la importància d'entendre i saber analitzar l'efecte del multicore i el multithreading en el rendiment. This research analyzes the performance of three multiprocessor computing nodes solving the seqüence alignment algorithm known as Needleman-Wunsh. First of all, the algorithm is analyzed and coded using the C language. We raise a series of optimizations with a common goal: minimize memory requirements and reduce computation time. Right afterwards we analyze the program's performance over the three computation nodes. In the second part of the research the sequential algorithm is parallelized using OpenMP. Two program variations are designed, these two variations differs between them in the amount of computation and the comunication. On the first variation the comunication between processors is rarely common and only occurs after long time periods . On the second variation the tasks are processed rapidly and the communication between processors is common. Both variations have been implemented and executed in multicore architectures that exploits thread-level parallelism. The result shows the importance of understanding and knowing how to analyze the effect of multicore and multithreading performance.
Published: 2021

46. Análisis de rendimiento de aplicaciones paralelas de memoria compartida : problema N-body

Author: Doblado Ruesga, Héctor Manuel, Moure, Juan C, Universitat Autònoma de Barcelona. Departament d'Arquitectura de Computadors i Sistemes Operatius, and Universitat Autònoma de Barcelona. Escola d'Enginyeria
Subjects: Problema dels cossos múltiples, Multiprocessadors
Abstract: Este trabajo analiza el rendimiento de cuatro nodos de cómputo multiprocesador de memoria compartida para resolver el problema N-body. Se paraleliza el algoritmo serie, y se codifica usando el lenguaje C extendido con OpenMP. El resultado son dos variantes que obedecen a dos criterios de optimización diferentes: minimizar los requisitos de memoria y minimizar el volumen de cómputo. Posteriormente, se realiza un proceso de análisis de las prestaciones del programa sobre los nodos de cómputo. Se modela el rendimiento de las variantes secuenciales y paralelas de la aplicación, y de los nodos de cómputo; se instrumentan y ejecutan los programas para obtener resultados en forma de varias métricas; finalmente se muestran e interpretan los resultados, proporcionando claves que explican ineficiencias y cuellos de botella en el rendimiento y posibles líneas de mejora. La experiencia de este estudio concreto ha permitido esbozar una incipiente metodología de análisis de rendimiento, identificación de problemas y sintonización de algoritmos a nodos de cómputo multiprocesador de memoria compartida. Aquest treball analitza el rendiment de quatre nodes de còmput multiprocessador de memòria compartida per resoldre el problema N-body. Es paral·lelitza l'algoritme sèrie, i es codifica utilitzant el llenguatge C estès amb OpenMP. El resultat són dues variants que obeeixen a dos criteris d'optimització diferents: minimitzar els requisits de memòria i minimitzar el volum de còmput. Posteriorment, es realitza un procés d'anàlisis de les prestacions del programa sobre els nodes de còmput. Es modela el rendiment de les variants seqüencials i paral·leles de l'aplicació, i dels nodes de còmput; s'instrumenten i s'executen els programes per obtenir resultats en forma de diverses mètriques; finalment es mostren i s'interpreten els resultats, proporcionant claus que expliquen ineficiències i colls d'ampolla en el rendiment i possibles línies de millora. L'experiència d'aquest estudi concret ha permès esbossar una incipient metodologia d'anàlisis de rendiment, identificació de problemes i sintonització d'algoritmes a nodes de còmput multiprocessador de memòria compartida. This research analyzes the performance of four, shared-memory, multiprocessor, computing nodes solving the N-body problem. The sequential algorithm is parallelized and coded using the C language extended by OpenMP. Two program variations are designed, obeying two different optimization goals: minimize memory requirements and minimize the amount of computation. Subsequently, we analyze the program's performance over the computation nodes. We model the performance of the serial and parallel applications and the performance of the computing nodes; the programs are implemented and executed to obtain results in form of several metrics; finally, results are displayed and interpreted, providing keys to explain the performance inefficiencies and bottlenecks, and showing possible areas for improvement. The experience of this study has made possible an incipient methodology to analyze performance, to identify problems, and to tune an algorithm on shared memory multiprocessor nodes.
Published: 2021

47. SafeSU: an extended statistics unit for multicore timing interference

Author: Guillem Cabo, Ruben Lorenzo, Miquel Moreto, David Trilla, Jaume Abella, Sergi Alcaide, Francisco Bas, Carles Hernandez, Universitat Politècnica de Catalunya. Doctorat en Arquitectura de Computadors, Universitat Politècnica de Catalunya. Departament d'Arquitectura de Computadors, Barcelona Supercomputing Center, and Universitat Politècnica de Catalunya. CAP - Grup de Computació d'Altes Prestacions
Subjects: Controllability, Multi-core processor, Observability, Computer science, Real-time data processing, Multiprocessadors, MPSoC, Commercialization, Unit (housing), Interference (communication), Statistics, Multiprocessors, Safety, Realization (systems), Temps real (Informàtica), Informàtica::Arquitectura de computadors [Àrees temàtiques de la UPC]
Abstract: Statistics units (SUs) in MPSoCs are becoming increasingly used for the (1) verification and (2) validation of multicore timing interference, as well as for (3) deploying safety measures in safety-related real-time systems. However, existing SU extensions to manage multicore timing interference have neither been integrated together nor deployed in commercial MPSoCs.This paper presents the realization of the Safe Statistics Unit (SafeSU for short), which smartly integrates existing solutions for multicore timing interference verification, validation and monitoring, and is in turn integrated in commercial space-graded RISC-V and SparcV8 MPSoCs. Our evaluation illustrates the operation of the SafeSU, and paves the way for a thorough validation prior to reaching commercialization and being offered as open source IP. This work has received funding from the European Union’s Horizon 2020 Research and Innovation programme under Grant Agreement EICFTI 869945.
Published: 2021

48. Diseño y evaluación de un algoritmo paralelo para la eliminación gausiana en procesadores multi-core

Author: Almazán Sánchez, Sergi, Moure, Juan C, and Universitat Autònoma de Barcelona. Escola d'Enginyeria
Subjects: Programació paral·lela (Informàtica), Algorismes computacionals, Multiprocessadors
Published: 2021

49. De-RISC: the First RISC-V space-grade platform for safety-critical systems

Author: Fabio Malatesta, Miguel Masmano, Nils-Johan Wessman, David Trilla, Guillem Cabo, Jan Andersson, Ruben Lorenzo, Jimmy Le Rhun, Vicente Nicolau, Jaume Abella, Paco Gomez, Francisco Bas, Oriol Sala, and Barcelona Supercomputing Center
Subjects: Space technology, Computer science, Vehicles espacials, 7. Clean energy, Instruction set, User experience design, Multiprocessors, Multi-core processor, Spacecraft, User experience, business.industry, Hypervisor, Space vehicles, Virtual machine monitors, Multiprocessadors, Aeronàutica i espai::Astronàutica::Enginyeria aeroespacial [Àrees temàtiques de la UPC], Enginyeria aeroespacial, Multicore processing, Aerospace engineering, Life-critical system, Embedded system, RISC-V, business, Interference, Software
Abstract: The increasing needs for performance in the space domain for highly autonomous systems calls for more powerful space MPSoCs and appropriate hypervisors to master them. These platforms must adhere to strict reliability, verifiability and validation requirements since spacecraft for deep space missions are exposed to a harsh environment. Systems must undergo screening and tests against standards for electronic components and software. Unfortunately, currently available space-grade processor components do not meet requirements related to safety that are becoming increasingly important in space applications. This paper presents the De-RISC platform, consisting of Cobham Gaisler’s RISC-V based SoC, and fentISS’ XtratuM Next Generation hypervisor. The platform implements the open RISC-V Instruction Set Architecture, and leverages space SoC IP by Cobham Gaisler, space hypervisor technology by fentISS, multicore interference management solutions by the Barcelona Supercomputing Center, and end user experience and requirement guidance by Thales Research and Technology. At its current state, the platform is already complete and integrated, and starting its validation phase prior to reaching commercial maturity by early 2022. In this paper, we provide details of the platform and some preliminary evidence of its operation. This project has received funding from the European Union’s Horizon 2020 Research and Innovation programme under Grant Agreement EIC-FTI 869945. BSC work has also been partially supported by the Spanish Ministry of Science and Innovation under grant PID2019-107255GB.
Published: 2021

50. Simulación de modelos orientados al individuo

Author: Alberto Monferrer, Marta, Suppi Boldrito, Remo, Universitat Autònoma de Barcelona. Departament d'Arquitectura de Computadors i Sistemes Operatius, and Universitat Autònoma de Barcelona. Escola d'Enginyeria
Subjects: Multiprocessadors, Ordinadors Arquitectura
Abstract: Los bancos de peces es un grupo social organizado sin la presencia de un líder. Esta organización se atribuye a dos patrones de comportamiento: atracción biosocial y orientación paralela. Este sistema puede modelarse mediante la aproximación del Modelo orientado al Individuo, donde la conducta de cada individuo por separado define el comportamiento grupal de todos los individuos. El objetivo del trabajo es mejorar el rendimiento del simulador mediante una programación híbrida que aproveche las alternativas de paralelismo en el cómputo que ofrecen las recientes arquitecturas multicore en sistemas de altas prestaciones. Els bancs de peixos és un grup social organitzat sense la presència d'un líder. Aquesta organització s'atribueix a dos patrons de comportament: atracció biosocial i orientació paral·lela. Aquest sistema pot modelar mitjançant l'aproximació del model orientat a l'individu, on la conducta de cada individu per separat defineix el comportament grupal de tots els individus. L'objectiu del treball és millorar el rendiment del simulador mitjançant una programació híbrida que aprofiti les alternatives de paral·lelisme en el còmput que ofereixen les recents arquitectures multicore en sistemes d'altes prestacions.
Published: 2021

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