IEEE VIS 2024 Content: MSz: An Efficient Parallel Algorithm for Correcting Morse-Smale Segmentations in Error-Bounded Lossy Compressors

MSz: An Efficient Parallel Algorithm for Correcting Morse-Smale Segmentations in Error-Bounded Lossy Compressors

Yuxiao Li - The Ohio State University, Columbus, United States

Xin Liang - University of California, Riverside, Riverside, United States

Bei Wang - University of Utah, Salt Lake City, United States

Yongfeng Qiu - The Ohio State University, Columbus, United States

Lin Yan - Argonne National Laboratory, Lemont, United States

Hanqi Guo - The Ohio State University, Columbus, United States

Screen-reader Accessible PDF

Room: Bayshore I

2024-10-17T14:15:00ZGMT-0600Change your timezone on the schedule page
2024-10-17T14:15:00Z
Exemplar figure, described by caption below
This figure compares SZ3 and ours (SZ3) in terms of feature preservation capability for MSS in combustion data. False cases are highlighted with boxes.
Fast forward
Full Video
Keywords

Lossy compression, feature-preserving compression, Morse-Smale segmentations, shared-memory parallelism.

Abstract

This research explores a novel paradigm for preserving topological segmentations in existing error-bounded lossy compressors. Today's lossy compressors rarely consider preserving topologies such as Morse-Smale complexes, and the discrepancies in topology between original and decompressed datasets could potentially result in erroneous interpretations or even incorrect scientific conclusions. In this paper, we focus on preserving Morse-Smale segmentations in 2D/3D piecewise linear scalar fields, targeting the precise reconstruction of minimum/maximum labels induced by the integral line of each vertex. The key is to derive a series of edits during compression time. These edits are applied to the decompressed data, leading to an accurate reconstruction of segmentations while keeping the error within the prescribed error bound. To this end, we develop a workflow to fix extrema and integral lines alternatively until convergence within finite iterations. We accelerate each workflow component with shared-memory/GPU parallelism to make the performance practical for coupling with compressors. We demonstrate use cases with fluid dynamics, ocean, and cosmology application datasets with a significant acceleration with an NVIDIA A100 GPU.