Semantic Query Optimization for Processing XML Streams with Minimized Memory Footprint Public
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XML streams have become increasingly prevalent in modern applications, ranging from network traffic monitoring to real-time information publishing. XQuery evaluation over XML streams require the temporary buffering of XML elements, which not only utilizes system buffer and CPU resources but also causes un-necessary output latency. This thesis presents a semantic query optimization solution to minimize memory footprint during XQuery evaluation by exploiting XML schema knowledge. In many practical applications, XML streams are generated conforming to pre-defined schema constraints typically expressed via a DTD or an XML schema specification. Utilizing such constraints enables us to on-the-fly predict the non-occurrence of a given pattern within a bound context. This helps us to avoid data buffering and to release buffered data at an earlier moment, thus achieving a minimized memory footprint. In this work, we focus on one particular class of constraints, namely, the Pattern Non-Occurrence (PNO) constraint. We develop an automaton-based technique to detect PNO constraints at runtime. For a given query, optimization opportunities which can be triggered by runtime PNO detection are explored for memory footprint minimization. Optimization decisions are encoded using our proposed Condition-Action Graph (CAG). The optimization-embedded execution strategy is then proposed to execute an optimized plan by detecting PNO constraints at run-time and then triggering the corresponding encoded actions when certain predefined conditions are satisfied. To ensure the efficiency of such PNO-triggered optimization, we propose optimization strategy on shrinking the CAGs by utilizing constraint knowledge during the query plan compiling phase. We implement our optimization technique within the Raindrop XQuery engine. Our system implementation processes XQuery utilizing the Raindrop algebra. It is efficiently augmented by our optimization module, which uses Glushkov automaton technique to capture and monitor PNO constraints in parallel with the query-driven pattern retrieval. Finally, we conduct experimental studies using both real and synthetic data streams to illustrate that our techniques bring significant performance improvement in both memory and CPU usage as well as improved output latency over state-of-the-art solutions, with little overhead.
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