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Berkeley, CA, United States

Gonina E.,University of California at Berkeley | Friedland G.,1947 Center Street | Battenberg E.,Soda Hall | Koanantakool P.,Soda Hall | And 3 more authors.
ACM Transactions on Multimedia Computing, Communications and Applications

In this new era dominated by consumer-produced media there is a high demand for web-scalable solutions to multimedia content analysis. A compelling approach to making applications scalable is to explicitly map their computation onto parallel platforms. However, developing efficient parallel implementations and fully utilizing the available resources remains a challenge due to the increased code complexity, limited portability and required low-level knowledge of the underlying hardware. In this article, we present PyCASP, a Python-based framework that automatically maps computation onto parallel platforms from Python application code to a variety of parallel platforms. PyCASP is designed using a systematic, pattern-oriented approach to offer a single software development environment for multimedia content analysis applications. Using PyCASP, applications can be prototyped in a couple hundred lines of Python code and automatically scale to modern parallel processors. Applications written with PyCASP are portable to a variety of parallel platforms and efficiently scale from a single desktop Graphics Processing Unit (GPU) to an entire cluster with a small change to application code. To illustrate our approach, we present three multimedia content analysis applications that use our framework: a state-of-the-art speaker diarization application, a content-based music recommendation system based on the Million Song Dataset, and a video event detection system for consumer-produced videos. We show that across this wide range of applications, our approach achieves the goal of automatic portability and scalability while at the same time allowing easy prototyping in a high-level language and efficient performance of low-level optimized code. © 2014 ACM. Source

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