A Comparison of some recent Task-based Parallel Programming Models

The need for parallel programming models that are simple to use and at the same time efficient for current ant future parallel platforms has led to recent attention to task-based models such as Cilk++, Intel TBB and the task concept in OpenMP version 3.0. The choice of model and implementation can have a major impact on the final performance and in order to understand some of the trade-offs we have made a quantitative study comparing four implementations of OpenMP (gcc, Intel icc, Sun studio and the research compiler Mercurium/nanos mcc), Cilk++ and Wool, a high-performance task-based library developed at SICS. Abstract. We use microbenchmarks to characterize costs for task-creation and stealing and the Barcelona OpenMP Tasks Suite for characterizing application performance. By far Wool and Cilk++ have the lowest overhead in both spawning and stealing tasks. This is reflected in application performance when many tasks with small granularity are spawned where Cilk++ and, in particular, has the highest performance. For coarse granularity applications, the OpenMP implementations have quite similar performance as the more light-weight Cilk++ and Wool except for one application where mcc is superior thanks to a superior task scheduler. Abstract. The OpenMP implemenations are generally not yet ready for use when the task granularity becomes very small. There is no inherent reason for this, so we expect future implementations of OpenMP to focus on this issue

Dynamic Multiple Work Stealing Strategy for Flexible Load Balancing

Lazy-task creation is an efficient method of overcoming the overhead of the grain-size problem in parallel computing. Work stealing is an effective load balancing strategy for parallel computing. In this paper, we present dynamic work stealing strategies in a lazy-task creation technique for efficient fine-grain task scheduling. The basic idea is to control load balancing granularity depending on the number of task parents in a stack. The dynamic-length strategy of work stealing uses run-time information, which is information on the load of the victim, to determine the number of tasks that a thief is allowed to steal. We compare it with the bottommost first work stealing strategy used in StackThread/MP, and the fixed-length strategy of work stealing, where a thief requests to steal a fixed number of tasks, as well as other multithreaded frameworks such as Cilk and OpenMP task implementations. The experiments show that the dynamic-length strategy of work stealing performs well in irregular workloads such as in UTS benchmarks, as well as in regular workloads such as Fibonacci, Strassen\u27s matrix multiplication, FFT, and Sparse-LU factorization. The dynamic-length strategy works better than the fixed-length strategy because it is more flexible than the latter; this strategy can avoid load imbalance due to overstealing

MPI+X: task-based parallelization and dynamic load balance of finite element assembly

The main computing tasks of a finite element code(FE) for solving partial differential equations (PDE's) are the algebraic system assembly and the iterative solver. This work focuses on the first task, in the context of a hybrid MPI+X paradigm. Although we will describe algorithms in the FE context, a similar strategy can be straightforwardly applied to other discretization methods, like the finite volume method. The matrix assembly consists of a loop over the elements of the MPI partition to compute element matrices and right-hand sides and their assemblies in the local system to each MPI partition. In a MPI+X hybrid parallelism context, X has consisted traditionally of loop parallelism using OpenMP. Several strategies have been proposed in the literature to implement this loop parallelism, like coloring or substructuring techniques to circumvent the race condition that appears when assembling the element system into the local system. The main drawback of the first technique is the decrease of the IPC due to bad spatial locality. The second technique avoids this issue but requires extensive changes in the implementation, which can be cumbersome when several element loops should be treated. We propose an alternative, based on the task parallelism of the element loop using some extensions to the OpenMP programming model. The taskification of the assembly solves both aforementioned problems. In addition, dynamic load balance will be applied using the DLB library, especially efficient in the presence of hybrid meshes, where the relative costs of the different elements is impossible to estimate a priori. This paper presents the proposed methodology, its implementation and its validation through the solution of large computational mechanics problems up to 16k cores

Scalable Applications on Heterogeneous System Architectures: A Systematic Performance Analysis Framework

The efficient parallel execution of scientific applications is a key challenge in high-performance computing (HPC). With growing parallelism and heterogeneity of compute resources as well as increasingly complex software, performance analysis has become an indispensable tool in the development and optimization of parallel programs. This thesis presents a framework for systematic performance analysis of scalable, heterogeneous applications. Based on event traces, it automatically detects the critical path and inefficiencies that result in waiting or idle time, e.g. due to load imbalances between parallel execution streams. As a prerequisite for the analysis of heterogeneous programs, this thesis specifies inefficiency patterns for computation offloading. Furthermore, an essential contribution was made to the development of tool interfaces for OpenACC and OpenMP, which enable a portable data acquisition and a subsequent analysis for programs with offload directives. At present, these interfaces are already part of the latest OpenACC and OpenMP API specification. The aforementioned work, existing preliminary work, and established analysis methods are combined into a generic analysis process, which can be applied across programming models. Based on the detection of wait or idle states, which can propagate over several levels of parallelism, the analysis identifies wasted computing resources and their root cause as well as the critical-path share for each program region. Thus, it determines the influence of program regions on the load balancing between execution streams and the program runtime. The analysis results include a summary of the detected inefficiency patterns and a program trace, enhanced with information about wait states, their cause, and the critical path. In addition, a ranking, based on the amount of waiting time a program region caused on the critical path, highlights program regions that are relevant for program optimization. The scalability of the proposed performance analysis and its implementation is demonstrated using High-Performance Linpack (HPL), while the analysis results are validated with synthetic programs. A scientific application that uses MPI, OpenMP, and CUDA simultaneously is investigated in order to show the applicability of the analysis

Towards resource-aware computing for task-based runtimes and parallel architectures

Current large scale systems show increasing power demands, to the point that it has become a huge strain on facilities and budgets. The increasing restrictions in terms of power consumption of High Performance Computing (HPC) systems and data centers have forced hardware vendors to include power capping capabilities in their commodity processors. Power capping opens up new opportunities for applications to directly manage their power behavior at user level. However, constraining power consumption causes the individual sockets of a parallel system to deliver different performance levels under the same power cap, even when they are equally designed, which is an effect caused by manufacturing variability. Modern chips suffer from heterogeneous power consumption due to manufacturing issues, a problem known as manufacturing or process variability. As a result, systems that do not consider such variability caused by manufacturing issues lead to performance degradations and wasted power. In order to avoid such negative impact, users and system administrators must actively counteract any manufacturing variability. In this thesis we show that parallel systems benefit from taking into account the consequences of manufacturing variability, in terms of both performance and energy efficiency. In order to evaluate our work we have also implemented our own task-based version of the PARSEC benchmark suite. This allows to test our methodology using state-of-the-art parallelization techniques and real world workloads. We present two approaches to mitigate manufacturing variability, by power redistribution at runtime level and by power- and variability-aware job scheduling at system-wide level. A parallel runtime system can be used to effectively deal with this new kind of performance heterogeneity by compensating the uneven effects of power capping. In the context of a NUMA node composed of several multi core sockets, our system is able to optimize the energy and concurrency levels assigned to each socket to maximize performance. Applied transparently within the parallel runtime system, it does not require any programmer interaction like changing the application source code or manually reconfiguring the parallel system. We compare our novel runtime analysis with an offline approach and demonstrate that it can achieve equal performance at a fraction of the cost. The next approach presented in this theis, we show that it is possible to predict the impact of this variability on specific applications by using variability-aware power prediction models. Based on these power models, we propose two job scheduling policies that consider the effects of manufacturing variability for each application and that ensures that power consumption stays under a system wide power budget. We evaluate our policies under different power budgets and traffic scenarios, consisting of both single- and multi-node parallel applications.Los sistemas modernos de gran escala muestran crecientes demandas de energía, hasta el punto de que se ha convertido en una gran presión para las instalaciones y los presupuestos. Las restricciones crecientes de consumo de energía de los sistemas de alto rendimiento (HPC) y los centros de datos han obligado a los proveedores de hardware a incluir capacidades de limitación de energía en sus procesadores. La limitación de energía abre nuevas oportunidades para que las aplicaciones administren directamente su comportamiento de energía a nivel de usuario. Sin embargo, la restricción en el consumo de energía de sockets individuales de un sistema paralelo resulta en diferentes niveles de rendimiento, por el mismo límite de potencia, incluso cuando están diseñados por igual. Esto es un efecto causado durante el proceso de la fabricación. Los chips modernos sufren de un consumo de energía heterogéneo debido a problemas de fabricación, un problema conocido como variabilidad del proceso o fabricación. Como resultado, los sistemas que no consideran este tipo de variabilidad causada por problemas de fabricación conducen a degradaciones del rendimiento y desperdicio de energía. Para evitar dicho impacto negativo, los usuarios y administradores del sistema deben contrarrestar activamente cualquier variabilidad de fabricación. En esta tesis, demostramos que los sistemas paralelos se benefician de tener en cuenta las consecuencias de la variabilidad de la fabricación, tanto en términos de rendimiento como de eficiencia energética. Para evaluar nuestro trabajo, también hemos implementado nuestra propia versión del paquete de aplicaciones de prueba PARSEC, basada en tareas paralelos. Esto permite probar nuestra metodología utilizando técnicas avanzadas de paralelización con cargas de trabajo del mundo real. Presentamos dos enfoques para mitigar la variabilidad de fabricación, mediante la redistribución de la energía a durante la ejecución de las aplicaciones y mediante la programación de trabajos a nivel de todo el sistema. Se puede utilizar un sistema runtime paralelo para tratar con eficacia este nuevo tipo de heterogeneidad de rendimiento, compensando los efectos desiguales de la limitación de potencia. En el contexto de un nodo NUMA compuesto de varios sockets y núcleos, nuestro sistema puede optimizar los niveles de energía y concurrencia asignados a cada socket para maximizar el rendimiento. Aplicado de manera transparente dentro del sistema runtime paralelo, no requiere ninguna interacción del programador como cambiar el código fuente de la aplicación o reconfigurar manualmente el sistema paralelo. Comparamos nuestro novedoso análisis de runtime con los resultados óptimos, obtenidos de una análisis manual exhaustiva, y demostramos que puede lograr el mismo rendimiento a una fracción del costo. El siguiente enfoque presentado en esta tesis, muestra que es posible predecir el impacto de la variabilidad de fabricación en aplicaciones específicas mediante el uso de modelos de predicción de potencia conscientes de la variabilidad. Basados ​​en estos modelos de predicción de energía, proponemos dos políticas de programación de trabajos que consideran los efectos de la variabilidad de fabricación para cada aplicación y que aseguran que el consumo se mantiene bajo un presupuesto de energía de todo el sistema. Evaluamos nuestras políticas con diferentes presupuestos de energía y escenarios de tráfico, que consisten en aplicaciones paralelas que corren en uno o varios nodos

Towards resource-aware computing for task-based runtimes and parallel architectures

Current large scale systems show increasing power demands, to the point that it has become a huge strain on facilities and budgets. The increasing restrictions in terms of power consumption of High Performance Computing (HPC) systems and data centers have forced hardware vendors to include power capping capabilities in their commodity processors. Power capping opens up new opportunities for applications to directly manage their power behavior at user level. However, constraining power consumption causes the individual sockets of a parallel system to deliver different performance levels under the same power cap, even when they are equally designed, which is an effect caused by manufacturing variability. Modern chips suffer from heterogeneous power consumption due to manufacturing issues, a problem known as manufacturing or process variability. As a result, systems that do not consider such variability caused by manufacturing issues lead to performance degradations and wasted power. In order to avoid such negative impact, users and system administrators must actively counteract any manufacturing variability. In this thesis we show that parallel systems benefit from taking into account the consequences of manufacturing variability, in terms of both performance and energy efficiency. In order to evaluate our work we have also implemented our own task-based version of the PARSEC benchmark suite. This allows to test our methodology using state-of-the-art parallelization techniques and real world workloads. We present two approaches to mitigate manufacturing variability, by power redistribution at runtime level and by power- and variability-aware job scheduling at system-wide level. A parallel runtime system can be used to effectively deal with this new kind of performance heterogeneity by compensating the uneven effects of power capping. In the context of a NUMA node composed of several multi core sockets, our system is able to optimize the energy and concurrency levels assigned to each socket to maximize performance. Applied transparently within the parallel runtime system, it does not require any programmer interaction like changing the application source code or manually reconfiguring the parallel system. We compare our novel runtime analysis with an offline approach and demonstrate that it can achieve equal performance at a fraction of the cost. The next approach presented in this theis, we show that it is possible to predict the impact of this variability on specific applications by using variability-aware power prediction models. Based on these power models, we propose two job scheduling policies that consider the effects of manufacturing variability for each application and that ensures that power consumption stays under a system wide power budget. We evaluate our policies under different power budgets and traffic scenarios, consisting of both single- and multi-node parallel applications.Los sistemas modernos de gran escala muestran crecientes demandas de energía, hasta el punto de que se ha convertido en una gran presión para las instalaciones y los presupuestos. Las restricciones crecientes de consumo de energía de los sistemas de alto rendimiento (HPC) y los centros de datos han obligado a los proveedores de hardware a incluir capacidades de limitación de energía en sus procesadores. La limitación de energía abre nuevas oportunidades para que las aplicaciones administren directamente su comportamiento de energía a nivel de usuario. Sin embargo, la restricción en el consumo de energía de sockets individuales de un sistema paralelo resulta en diferentes niveles de rendimiento, por el mismo límite de potencia, incluso cuando están diseñados por igual. Esto es un efecto causado durante el proceso de la fabricación. Los chips modernos sufren de un consumo de energía heterogéneo debido a problemas de fabricación, un problema conocido como variabilidad del proceso o fabricación. Como resultado, los sistemas que no consideran este tipo de variabilidad causada por problemas de fabricación conducen a degradaciones del rendimiento y desperdicio de energía. Para evitar dicho impacto negativo, los usuarios y administradores del sistema deben contrarrestar activamente cualquier variabilidad de fabricación. En esta tesis, demostramos que los sistemas paralelos se benefician de tener en cuenta las consecuencias de la variabilidad de la fabricación, tanto en términos de rendimiento como de eficiencia energética. Para evaluar nuestro trabajo, también hemos implementado nuestra propia versión del paquete de aplicaciones de prueba PARSEC, basada en tareas paralelos. Esto permite probar nuestra metodología utilizando técnicas avanzadas de paralelización con cargas de trabajo del mundo real. Presentamos dos enfoques para mitigar la variabilidad de fabricación, mediante la redistribución de la energía a durante la ejecución de las aplicaciones y mediante la programación de trabajos a nivel de todo el sistema. Se puede utilizar un sistema runtime paralelo para tratar con eficacia este nuevo tipo de heterogeneidad de rendimiento, compensando los efectos desiguales de la limitación de potencia. En el contexto de un nodo NUMA compuesto de varios sockets y núcleos, nuestro sistema puede optimizar los niveles de energía y concurrencia asignados a cada socket para maximizar el rendimiento. Aplicado de manera transparente dentro del sistema runtime paralelo, no requiere ninguna interacción del programador como cambiar el código fuente de la aplicación o reconfigurar manualmente el sistema paralelo. Comparamos nuestro novedoso análisis de runtime con los resultados óptimos, obtenidos de una análisis manual exhaustiva, y demostramos que puede lograr el mismo rendimiento a una fracción del costo. El siguiente enfoque presentado en esta tesis, muestra que es posible predecir el impacto de la variabilidad de fabricación en aplicaciones específicas mediante el uso de modelos de predicción de potencia conscientes de la variabilidad. Basados ​​en estos modelos de predicción de energía, proponemos dos políticas de programación de trabajos que consideran los efectos de la variabilidad de fabricación para cada aplicación y que aseguran que el consumo se mantiene bajo un presupuesto de energía de todo el sistema. Evaluamos nuestras políticas con diferentes presupuestos de energía y escenarios de tráfico, que consisten en aplicaciones paralelas que corren en uno o varios nodos.Postprint (published version

Locality Awareness for Task Parallel Computation

The task parallel programming model allows programmers to express concurrency at a high level of abstraction and places the burden of scheduling parallel execution on the run time system. Efficient scheduling of tasks on multi-socket multicore shared memory systems requires careful consideration of an increasingly complex memory hierarchy, including shared caches and non-uniform memory access (NUMA) characteristics. In this dissertation, we study the performance impact of these issues and other performance factors that limit parallel speedup in task parallel program executions and propose new scheduling strategies to improve performance. Our performance model characterizes lost efficiency in terms of overhead time, idle time, and work time inflation due to increased data access costs. We introduce a hierarchical run time scheduler that combines the benefits of work stealing and parallel depth-first schedulers. Matching the scheduler design to the memory hierarchy of multicore NUMA systems limits costly remote data accesses while maintaining load balance and exploiting constructive data sharing among threads that share a cache. We also propose a locality- based scheduling framework based on locality domains and comprising an API for programmers to specify application locality and a scheduler that honors those specifications. Implementations of the hierarchical and locality-based schedulers in our OpenMP run time system exhibit performance improvements on several task parallel benchmark applications over existing scheduling strategies and production OpenMP run time systems.Doctor of Philosoph