Macroservers: An Execution Model for DRAM Processor-In-Memory Arrays

The emergence of semiconductor fabrication technology allowing a tight coupling between high-density DRAM and CMOS logic on the same chip has led to the important new class of Processor-In-Memory (PIM) architectures. Newer developments provide powerful parallel processing capabilities on the chip, exploiting the facility to load wide words in single memory accesses and supporting complex address manipulations in the memory. Furthermore, large arrays of PIMs can be arranged into a massively parallel architecture. In this report, we describe an object-based programming model based on the notion of a macroserver. Macroservers encapsulate a set of variables and methods; threads, spawned by the activation of methods, operate asynchronously on the variables' state space. Data distributions provide a mechanism for mapping large data structures across the memory region of a macroserver, while work distributions allow explicit control of bindings between threads and data. Both data and work distributuions are first-class objects of the model, supporting the dynamic management of data and threads in memory. This offers the flexibility required for fully exploiting the processing power and memory bandwidth of a PIM array, in particular for irregular and adaptive applications. Thread synchronization is based on atomic methods, condition variables, and futures. A special type of lightweight macroserver allows the formulation of flexible scheduling strategies for the access to resources, using a monitor-like mechanism

A load-sharing architecture for high performance optimistic simulations on multi-core machines

In Parallel Discrete Event Simulation (PDES), the simulation model is partitioned into a set of distinct Logical Processes (LPs) which are allowed to concurrently execute simulation events. In this work we present an innovative approach to load-sharing on multi-core/multiprocessor machines, targeted at the optimistic PDES paradigm, where LPs are speculatively allowed to process simulation events with no preventive verification of causal consistency, and actual consistency violations (if any) are recovered via rollback techniques. In our approach, each simulation kernel instance, in charge of hosting and executing a specific set of LPs, runs a set of worker threads, which can be dynamically activated/deactivated on the basis of a distributed algorithm. The latter relies in turn on an analytical model that provides indications on how to reassign processor/core usage across the kernels in order to handle the simulation workload as efficiently as possible. We also present a real implementation of our load-sharing architecture within the ROme OpTimistic Simulator (ROOT-Sim), namely an open-source C-based simulation platform implemented according to the PDES paradigm and the optimistic synchronization approach. Experimental results for an assessment of the validity of our proposal are presented as well

Load sharing for optimistic parallel simulations on multicore machines

Parallel Discrete Event Simulation (PDES) is based on the partitioning of the simulation model into distinct Logical Processes (LPs), each one modeling a portion of the entire system, which are allowed to execute simulation events concurrently. This allows exploiting parallel computing architectures to speedup model execution, and to make very large models tractable. In this article we cope with the optimistic approach to PDES, where LPs are allowed to concurrently process their events in a speculative fashion, and rollback/ recovery techniques are used to guarantee state consistency in case of causality violations along the speculative execution path. Particularly, we present an innovative load sharing approach targeted at optimizing resource usage for fruitful simulation work when running an optimistic PDES environment on top of multi-processor/multi-core machines. Beyond providing the load sharing model, we also define a load sharing oriented architectural scheme, based on a symmetric multi-threaded organization of the simulation platform. Finally, we present a real implementation of the load sharing architecture within the open source ROme OpTimistic Simulator (ROOT-Sim) package. Experimental data for an assessment of both viability and effectiveness of our proposal are presented as well. Copyright is held by author/owner(s)

Assessing load-sharing within optimistic simulation platforms

The advent of multi-core machines has lead to the need for revising the architecture of modern simulation platforms. One recent proposal we made attempted to explore the viability of load-sharing for optimistic simulators run on top of these types of machines. In this article, we provide an extensive experimental study for an assessment of the effects on run-time dynamics by a load-sharing architecture that has been implemented within the ROOT-Sim package, namely an open source simulation platform adhering to the optimistic synchronization paradigm. This experimental study is essentially aimed at evaluating possible sources of overheads when supporting load-sharing. It has been based on differentiated workloads allowing us to generate different execution profiles in terms of, e.g., granularity/locality of the simulation events. © 2012 IEEE

Reducing data movement on large shared memory systems by exploiting computation dependencies

Shared memory systems are becoming increasingly complex as they typically integrate several storage devices. That brings different access latencies or bandwidth rates depending on the proximity between the cores where memory accesses are issued and the storage devices containing the requested data. In this context, techniques to manage and mitigate non-uniform memory access (NUMA) effects consist in migrating threads, memory pages or both and are generally applied by the system software. We propose techniques at the runtime system level to further mitigate the impact of NUMA effects on parallel applications' performance. We leverage runtime system metadata expressed in terms of a task dependency graph, where nodes are pieces of serial code and edges are control or data dependencies between them, to efficiently reduce data transfers. Our approach, based on graph partitioning, adds negligible overhead and is able to provide performance improvements up to 1.52× and average improvements of 1.12× with respect to the best state-of-the-art approach when deployed on a 288-core shared-memory system. Our approach reduces the coherence traffic by 2.28× on average with respect to the state-of-the-art.This work has been supported by the RoMoL ERC Advanced Grant (GA 321253), by the European HiPEAC Network of Excellence, by the Spanish Ministry of Economy and Competitiveness (contract TIN2015-65316-P), by the Generalitat de Catalunya (contracts 2014-SGR-1051 and 2014-SGR-1272) and by the European Union’s Horizon 2020 research and innovation programme (grant agreements 671697 and 779877). I. Sánchez Barrera has been partially supported by the Spanish Ministry of Education, Culture and Sport under Formación del Profesorado Universitario fellowship number FPU15/03612. M. Moretó has been partially supported by the Spanish Ministry of Economy, Industry and Competitiveness under Ramón y Cajal fellowship number RYC-2016-21104.Peer ReviewedPostprint (published version

Performance counter-based strategies to improve data locality on multiprocessor systems: reordering and page migration techniques

In this dissertation we approach the study of Precise Event-Based Sampling (PEBS) techniques to improve the performance of applications on a NUMA, Itanium2-based system. We demonstrate that a low-cost, PEBS profiling can support strategies to improve the performance of an important group of computational and scientific codes in runtime. In addition, the accurate information provided by the new Event Adress Registers (EAR) of the Intel Itanium architecture helps foster the development of new data allocation strategies. Following this line, we have also developed a series of dynamic page migration PEBS strategies. Specifically, two problems are addressed: how to improve the performance of locality optimisation techniques for irregular codes in runtime, particularising for the Sparse Matrix-Vector product kernel, and how to develop strategies for dynamic page migration. To summarise, the main contributions of this dissertation are: 1. A study of the different factors that affect the performance, as well as data and thread allocation policies, in the FinisTerrae supercomputer, the target platform in which this thesis relies on. 2. The implementation of a performance model for FinisTerrae. 3. The development of hardware counter-based strategies to assist reordering techniques for irregular codes in order to reduce their cost and improve their behaviour. 4. The development of novel hardware counter-guided, dynamic page migration algorithms that take advantage of the new features provided by the PEBS. As a software contribution, we present a user-level page-migration framework to monitor, sample and control an application in runtime

Exploiting data locality in cache-coherent NUMA systems

The end of Dennard scaling has caused a stagnation of the clock frequency in computers.To overcome this issue, in the last two decades vendors have been integrating larger numbers of processing elements in the systems, interconnecting many nodes, including multiple chips in the nodes and increasing the number of cores in each chip. The speed of main memory has not evolved at the same rate as processors, it is much slower and there is a need to provide more total bandwidth to the processors, especially with the increase in the number of cores and chips. Still keeping a shared address space, where all processors can access the whole memory, solutions have come by integrating more memories: by using newer technologies like high-bandwidth memories (HBM) and non-volatile memories (NVM), by giving groups cores (like sockets, for example) faster access to some subset of the DRAM, or by combining many of these solutions. This has caused some heterogeneity in the access speed to main memory, depending on the CPU requesting access to a memory address and the actual physical location of that address, causing non-uniform memory access (NUMA) behaviours. Moreover, many of these systems are cache-coherent (ccNUMA), meaning that changes in the memory done from one CPU must be visible by the other CPUs and transparent for the programmer. These NUMA behaviours reduce the performance of applications and can pose a challenge to the programmers. To tackle this issue, this thesis proposes solutions, at the software and hardware levels, to improve the data locality in NUMA systems and, therefore, the performance of applications in these computer systems. The first contribution shows how considering hardware prefetching simultaneously with thread and data placement in NUMA systems can find configurations with better performance than considering these aspects separately. The performance results combined with performance counters are then used to build a performance model to predict, both offline and online, the best configuration for new applications not in the model. The evaluation is done using two different high performance NUMA systems, and the performance counters collected in one machine are used to predict the best configurations in the other machine. The second contribution builds on the idea that prefetching can have a strong effect in NUMA systems and proposes a NUMA-aware hardware prefetching scheme. This scheme is generic and can be applied to multiple hardware prefetchers with a low hardware cost but giving very good results. The evaluation is done using a cycle-accurate architectural simulator and provides detailed results of the performance, the data transfer reduction and the energy costs. Finally, the third and last contribution consists in scheduling algorithms for task-based programming models. These programming models help improve the programmability of applications in parallel systems and also provide useful information to the underlying runtime system. This information is used to build a task dependency graph (TDG), a directed acyclic graph that models the application where the nodes are sequential pieces of code known as tasks and the edges are the data dependencies between the different tasks. The proposed scheduling algorithms use graph partitioning techniques and provide a scheduling for the tasks in the TDG that minimises the data transfers between the different NUMA regions of the system. The results have been evaluated in real ccNUMA systems with multiple NUMA regions.La fi de la llei de Dennard ha provocat un estancament de la freqüència de rellotge dels computadors. Amb l'objectiu de superar aquest fet, durant les darreres dues dècades els fabricants han integrat més quantitat d'unitats de còmput als sistemes mitjançant la interconnexió de nodes diferents, la inclusió de múltiples xips als nodes i l'increment de nuclis de processador a cada xip. La rapidesa de la memòria principal no ha evolucionat amb el mateix factor que els processadors; és molt més lenta i hi ha la necessitat de proporcionar més ample de banda als processadors, especialment amb l'increment del nombre de nuclis i xips. Tot mantenint un adreçament compartit en el qual tots els processadors poden accedir a la memòria sencera, les solucions han estat al voltant de la integració de més memòries: amb tecnologies modernes com HBM (high-bandwidth memories) i NVM (non-volatile memories), fent que grups de nuclis (com sòcols sencers) tinguin accés més ràpid a una part de la DRAM o amb la combinació de solucions. Això ha provocat una heterogeneïtat en la velocitat d'accés a la memòria principal, en funció del nucli que sol·licita l'accés a una adreça en particular i la seva localització física, fet que provoca uns comportaments no uniformes en l'accés a la memòria (non-uniform memory access, NUMA). A més, sovint tenen memòries cau coherents (cache-coherent NUMA, ccNUMA), que implica que qualsevol canvi fet a la memòria des d'un nucli d'un processador ha de ser visible la resta de manera transparent. Aquests comportaments redueixen el rendiment de les aplicacions i suposen un repte. Per abordar el problema, a la tesi s'hi proposen solucions, a nivell de programari i maquinari, que milloren la localitat de dades als sistemes NUMA i, en conseqüència, el rendiment de les aplicacions en aquests sistemes. La primera contribució mostra que, quan es tenen en compte alhora la precàrrega d'adreces de memòria amb maquinari (hardware prefetching) i les decisions d'ubicació dels fils d'execució i les dades als sistemes NUMA, es poden trobar millors configuracions que quan es condieren per separat. Una combinació dels resultats de rendiment i dels comptadors disponibles al sistema s'utilitza per construir un model de rendiment per fer la predicció, tant per avançat com també en temps d'execució, de la millor configuració per aplicacions que no es troben al model. L'avaluació es du a terme a dos sistemes NUMA d'alt rendiment, i els comptadors mesurats en un sistema s'usen per predir les millors configuracions a l'altre sistema. La segona contribució es basa en la idea que el prefetching pot tenir un efecte considerable als sistemes NUMA i proposa un esquema de precàrrega a nivell de maquinari que té en compte els efectes NUMA. L'esquema és genèric i es pot aplicar als algorismes de precàrrega existents amb un cost de maquinari molt baix però amb molt bons resultats. S'avalua amb un simulador arquitectural acurat a nivell de cicle i proporciona resultats detallats del rendiment, la reducció de les comunicacions de dades i els costos energètics. La tercera i darrera contribució consisteix en algorismes de planificació per models de programació basats en tasques. Aquests simplifiquen la programabilitat de les aplicacions paral·leles i proveeixen informació molt útil al sistema en temps d'execució (runtime system) que en controla el funcionament. Amb aquesta informació es construeix un graf de dependències entre tasques (task dependency graph, TDG), un graf dirigit i acíclic que modela l'aplicació i en el qual els nodes són fragments de codi seqüencial (o tasques) i els arcs són les dependències de dades entre les tasques. Els algorismes de planificació proposats fan servir tècniques de particionat de grafs i proporcionen una planificació de les tasques del TDG que minimitza la comunicació de dades entre les diferents regions NUMA del sistema. Els resultats han estat avaluats en sistemes ccNUMA reals amb múltiples regions NUMA.El final de la ley de Dennard ha provocado un estancamiento de la frecuencia de reloj de los computadores. Con el objetivo de superar este problema, durante las últimas dos décadas los fabricantes han integrado más unidades de cómputo en los sistemas mediante la interconexión de nodos diferentes, la inclusión de múltiples chips en los nodos y el incremento de núcleos de procesador en cada chip. La rapidez de la memoria principal no ha evolucionado con el mismo factor que los procesadores; es mucho más lenta y hay la necesidad de proporcionar más ancho de banda a los procesadores, especialmente con el incremento del número de núcleos y chips. Aun manteniendo un sistema de direccionamiento compartido en el que todos los procesadores pueden acceder al conjunto de la memoria, las soluciones han oscilado alrededor de la integración de más memorias: usando tecnologías modernas como las memorias de alto ancho de banda (highbandwidth memories, HBM) y memorias no volátiles (non-volatile memories, NVM), haciendo que grupos de núcleos (como zócalos completos) tengan acceso más veloz a un subconjunto de la DRAM, o con la combinación de soluciones. Esto ha provocado una heterogeneidad en la velocidad de acceso a la memoria principal, en función del núcleo que solicita el acceso a una dirección de memoria en particular y la ubicación física de esta dirección, lo que provoca unos comportamientos no uniformes en el acceso a la memoria (non-uniform memory access, NUMA). Además, muchos de estos sistemas tienen memorias caché coherentes (cache-coherent NUMA, ccNUMA), lo que implica que cualquier cambio hecho en la memoria desde un núcleo de un procesador debe ser visible por el resto de procesadores de forma transparente para los programadores. Estos comportamientos NUMA reducen el rendimiento de las aplicaciones y pueden suponer un reto para los programadores. Para abordar dicho problema, en esta tesis se proponen soluciones, a nivel de software y hardware, que mejoran la localidad de datos en los sistemas NUMA y, en consecuencia, el rendimiento de las aplicaciones en estos sistemas informáticos. La primera contribución muestra que, cuando se tienen en cuenta a la vez la precarga de direcciones de memoria mediante hardware (o hardware prefetching ) y las decisiones de la ubicación de los hilos de ejecución y los datos en los sistemas NUMA, se pueden hallar mejores configuraciones que cuando se consideran ambos aspectos por separado. Con una combinación de los resultados de rendimiento y de los contadores disponibles en el sistema se construye un modelo de rendimiento, tanto por avanzado como en en tiempo de ejecución, de la mejor configuración para aplicaciones que no están incluidas en el modelo. La evaluación se realiza en dos sistemas NUMA de alto rendimiento, y los contadores medidos en uno de los sistemas se usan para predecir las mejores configuraciones en el otro sistema. La segunda contribución se basa en la idea de que el prefetching puede tener un efecto considerable en los sistemas NUMA y propone un esquema de precarga a nivel hardware que tiene en cuenta los efectos NUMA. Este esquema es genérico y se puede aplicar a diferentes algoritmos de precarga existentes con un coste de hardware muy bajo pero que proporciona muy buenos resultados. Dichos resultados se obtienen y evalúan mediante un simulador arquitectural preciso a nivel de ciclo y proporciona resultados detallados del rendimiento, la reducción de las comunicaciones de datos y los costes energéticos. Finalmente, la tercera y última contribución consiste en algoritmos de planificación para modelos de programación basados en tareas. Estos modelos simplifican la programabilidad de las aplicaciones paralelas y proveen información muy útil al sistema en tiempo de ejecución (runtime system) que controla su funcionamiento. Esta información se utiliza para construir un grafo de dependencias entre tareas (task dependency graph, TDG), un grafo dirigido y acíclico que modela la aplicación y en el ue los nodos son fragmentos de código secuencial, conocidos como tareas, y los arcos son las dependencias de datos entre las distintas tareas. Los algoritmos de planificación que se proponen usan técnicas e particionado de grafos y proporcionan una planificación de las tareas del TDG que minimiza la comunicación de datos entre las distintas regiones NUMA del sistema. Los resultados se han evaluado en sistemas ccNUMA reales con múltiples regiones NUMA.Postprint (published version