Metacat

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      <td colspan="7"><div class="title">KNB Software Development Guide: Metacat Query Caching and Indexing Mechanisms</div></td>

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  <div class="header1">Table of Contents</div>

  <div class="toc">

    <div class="toc1"><a href="#Overview">Overview</a></div>

    <div class="toc1"><a href="#XMLNodesIndex">All XML Path Indexing</a></div>

      <div class="toc2"><a href="#HowXMLNodesIndexWorks">How All XML Path Indexing Works</a></div>

      <div class="toc2"><a href="#XMLNodesIndexDrawbacks">Drawbacks to All XML Path Indexing</a></div>

    <div class="toc1"><a href="#MemoryCaching">Query Caching in Memory</a></div>

      <div class="toc2"><a href="#HowMemoryCachingWorks">How Memory Caching Works</a></div>

      <div class="toc2"><a href="#MemoryCachingDrawbacks">Memory Caching Drawbacks</a></div>

    <div class="toc1"><a href="#PathIndexing">Common XML Path Indexing</a></div>

      <div class="toc2"><a href="#HowPathIndexingWorks">How Common Path Indexing Works</a></div>

      <div class="toc2"><a href="#PathIndexingDrawbacks">Common Path Indexing Drawbacks</a></div>

    <div class="toc1"><a href="#UniqueResultset">Storing Unique Return Fields</a></div>

      <div class="toc2"><a href="#HowUniqueResultsetWorks">How Storing Unique Return Fields Works</a></div>

      <div class="toc2"><a href="#UniqueResultsetDrawbacks">Drawbacks to Storing Unique Return Fields</a></div>

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  <a name="Overview"></a><div class="header1">Overview</div>   

  <p>Unfortunately, the act of searching (querying) an xml document that has

  been deconstructed and put into a relational database is somewhat slow.  The table that 

  stores xml elements (xml_nodes) becomes very large, very fast. In an

  effort to speed up these queries, metacat has implemented several levels of query

  caching and indexing:</p>

  <ul>

    <li>All XML path indexing - store all xml paths in a separate table.</li>

    <li>Memory caching - recent query results are held in memory.</li>

    <li>Common XML path indexing - store predetermined xml paths in a separate table.</li>

    <li>Store unique resultset combinations - unique resultsets are stored in the

    database on a per-docid basis.</li>

  </ul>  

  <p>We will discuss each of these caching strategies in turn.</p>

  <a name="XMLNodesIndex"></a><div class="header1">All XML Path Indexing</div>

  <a name="HowXMLNodesIndexWorks"></a><div class="header2">How All XML Path Indexing Works</div>

  <p>Aside from the column indexing that is typical with performance tuning on any 

  database, an additional table named xml_index was created to improve search 

  performance against the xml_nodes table.  The xml_index table keeps track of the 

  xml paths for each node in the nodes table.  This includes subpaths, so if you

  had an element in the xml that looked like: </p>

  <div class="code">&lt;a&gt;&lt;b&gt;&lt;c&gt;value&lt;/c&gt;&lt;/b&gt;&lt;/a&gt;</div>

  <p>the paths that would get indexed for this node would be:</p>

  <div class="code">c<br>b/c<br>a/b/c</div>

  <p>When querying, the query path is first looked up in xml_index and then joined to

  the xml_nodes table via the nodeid.  

  <a name="XMLNodesIndexDrawbacks"></a><div class="header2">Drawbacks to All XML Path Indexing</div>

  <p>Indexing all paths improves performance, but is still relatively slow since a join 

  against the xml_nodes table takes time.</p>

  <a name="MemoryCaching"></a><div class="header1">Query Caching in Memory</div> 

    <a name="HowMemoryCachingWorks"></a><div class="header2">How Memory Caching Works</div>  

    <p>Metacat keeps a Hashtable of recent queries and their results.  This information is only

    held for queries that were run by the "public" user.  The key is the sql that

    that was run for the query.  The value is the html that was returned from the query.

    This cache is checked first to see if the current sql statement was already run.  If so,

    the associated result html is returned.</p>

    <a name="MemoryCachingDrawbacks"></a><div class="header2">Memory Caching Drawbacks</div>  

    <p>The first issue is that every time a document is inserted, updated or deleted, the 

    query cache is potentially out of sync.  So anytime any document is changed, the entire

    cache is cleared, and the process of filling the cache starts over.</p>

    <p>The second issue is that the cache could potentially become large, using a lot of

    memory.  This could be caused if a large number of different queries are performed 

    inbetween any documents being inserted, updated or deleted, and many of those queries

    return large result sets.  Note that this is a corner case, and the cache size is 

    configurable using the database.queryresultCacheSize property in metacat.properties.<p>

    <p>Third, as mentioned before, this caching is only done on searches performed by

    the "public" user.  Any logged in user searches will not be cached.</p>

  <a name="PathIndexing"></a><div class="header1">Common XML Path Indexing</div> 

    <a name="HowPathIndexingWorks"></a><div class="header2">How Common Path Indexing Works</div> 

    <p>Metacat queries work in two stages.  The first is to get the matching document IDs.  

    The second is to get the requested return fields for those IDs.  As discussed in the 

    <a href="#XMLNodesIndex">All XML Path Indexing</a> section above, some effort was made to 

    improve the first step, but it was still slow.  Metacat made use of the fact that 

    there are certain paths in EML that are frequently searched to further speed up queries.</p>

    <p>Paths that are determined to be searched frequently are entered as a comma delimited

    list in the xml.indexPaths property in metacat.properties.  At startup time, metacat determines

    if there are any changes to the xml.indexPaths property, scans the xml_nodes table and adds

    any nodes with matching paths to the xml_path_index table.  In this case, unlike the xml_index

    table, the node value is stored.  So if a desired value is found for the given path, the 

    docid is returned and the nodes table is never touched.

    <a name="PathIndexingDrawbacks"></a><div class="header2">Common Path Indexing Drawbacks</div> 

    <p>An obvious issue with the xml_path_index table is that is only holds values for predetermined

    paths.  Any other path will not benefit from this indexing.</p>

    <p>Also, if a wildcard has been used in the search value, the database index for the value 

    column will not be used.  This will slow down the search.</p>

  <a name="UniqueResultset"></a><div class="header1">Storing Unique Return Fields</div> 

    <a name="HowUniqueResultsetWorks"></a><div class="header2">How Storing Unique Return Fields Works</div> 

    <p>Once the matching docids have been retrieved, metacat makes a second pass and gets the desired

    return fields for each document. To help speed this up, metacat databases unique combinations of 

    query return fields for each document.</p>

    <p>This process involves two tables.  The first, xml_returnfield, keeps unique return field combinations.

    The return fields are a pipe (|) delimited string in the table. The second table, xml_queryresult, keeps 

    the id for the row in the xml_returnfield that has the appropriate return fields, the docid and the 

    query result.</p>

    <p>If the desired docid and result fields are found in these two tables, the query results are returned

    directly from the xml_queryresult table and the xml_indes and xml_nodes tables are never touched.</p>

    <a name="UniqueResultsetDrawbacks"></a><div class="header2">Drawbacks to Storing Unique Return Fields</div> 

    <p>The main issue with storing unique query results is that the query must be performed at least once for

    each unique set of results and docid before it is added to the xml_returnfield and xml_queryresult tables. 

    This first run goes against the xml_index and xml_nodes tables and is slow.</p>

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