high performance computing on graphics processing units: hgpu.org

Despite deployment of FPGAs at the edge and cloud data centers due to their performance and energy advantage, FPGA runtime systems commonly tend to support only one-application-at-a-time and cannot adapt to dynamic workloads with reasonable response times. Therefore, this paper proposes the concepts and theory of resource elasticity for FPGA systems to allow a task […]

Multi-tenant GPU clusters are common nowadays due to the huge success of deep learning and training jobs are usually conducted with multiple distributed GPUs. These GPU clusters are managed with various goals including short JCT, high resource utilization and quick response to small jobs. In this paper, we show that elasticity, which is the ability […]

Increasing model size when pretraining natural language representations often results in improved performance on downstream tasks. However, at some point further model increases become harder due to GPU/TPU memory limitations, longer training times, and unexpected model degradation. To address these problems, we present two parameter-reduction techniques to lower memory consumption and increase the training speed […]

Recent work in unsupervised language modeling demonstrates that training large neural language models advances the state of the art in Natural Language Processing applications. However, for very large models, memory constraints limit the size of models that can be practically trained. Model parallelism allows us to train larger models, because the parameters can be split […]

Deep neural networks (DNNs) have become widely used in many AI applications. Yet, training a DNN requires a huge amount of calculations and it takes a long time and energy to train a satisfying model. Nowadays, many-core AI accelerators (e.g., GPUs and TPUs) play a key role in training DNNs. However, different many-core processors from […]

The efficient execution of image processing pipelines on GPUs is an area of active research. The state-of-art involves 1) dividing portions of an image into overlapped tiles, where each tile can be processed by a single thread block and 2) fusing loops together to improve memory locality. However, the state-of-the-art has two limitations: 1) synchronization […]

We present ALPyNA, an automatic loop parallelization framework for Python, which analyzes data dependences within nested loops and dynamically generates CUDA kernels for GPU execution. The ALPyNA system applies classical dependence analysis techniques to discover and exploit potential parallelism. The skeletal structure of the dependence graph is determined statically (if possible) or at runtime; this […]

We present Espresso, an open-source, modular, extensible end-to-end neural automatic speech recognition (ASR) toolkit based on the deep learning library PyTorch and the popular neural machine translation toolkit fairseq. Espresso supports distributed training across GPUs and computing nodes, and features various decoding approaches commonly employed in ASR, including look-ahead word-based language model fusion, for which […]

Modern high performance processor architectures tackle performance issues by heavily relying on increased vector lengths and advanced memory hierarchies to deliver high performance. Manual optimization is became a difficult task. Developers usually trust compilers to automatically address these performance issues, but they deploy static performance models and heuristics that force them to remain conservative. On […]

Watershed analysis, as a fundamental component of digital terrain analysis, is based on the Digital Elevation Model (DEM), which is a grid (raster) model of the Earth surface and topography. Watershed analysis consists of computationally and data intensive computing algorithms that need to be implemented by leveraging parallel and high-performance computing methods and techniques. In […]

The next-generation of supercomputers will feature a diverse mix of accelerator devices. The increase in heterogeneity is explained by the nature of supercomputing workloads – certain devices offer acceleration, or a shorter time to completion, for particular application programs. Certain characteristics of these programs are fixed and impose fundamental limitations on the workloads regardless of […]

PySPH is a Python-based framework for particle methods in general and Smoothed Particle Hydrodynamics (SPH) in particular. PySPH allows a user to define a complete SPH simulation using pure Python. High-performance code is generated from this high-level Python code and executed on either multiple cores, or on GPUs, seamlessly. It also supports distributed execution using […]