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Querying XML: XPath, XQuery, and XSLT

Querying XML: XPath, XQuery, and XSLT. Zachary G. Ives University of Pennsylvania CIS 550 – Database & Information Systems October 27, 2005. Some slide content courtesy of Susan Davidson, Dan Suciu, & Raghu Ramakrishnan. Reminders. Homework 4 due 11/3 XQuery Project plan due 11/3

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Querying XML: XPath, XQuery, and XSLT

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  1. Querying XML: XPath, XQuery, and XSLT Zachary G. Ives University of Pennsylvania CIS 550 – Database & Information Systems October 27, 2005 Some slide content courtesy of Susan Davidson, Dan Suciu, & Raghu Ramakrishnan

  2. Reminders • Homework 4 due 11/3 • XQuery • Project plan due 11/3 • Milestones • Division of responsibilities • For non-RSS projects: proposal including scope, milestones, and what you plan to demonstrate • Recitation: Friday 11:30-12:30, Levine 512

  3. Talks of Interest Today: • Anastassia Ailamaki, CMU, “FATES: Automatically-tuned Database Storage Management”, IRCS (3401 Walnut) Room 470 @ 3PM Tomorrow as part of “DB & Information Retrieval Day”: • Anastassia Ailamaki, CMU, “StagedDB: Designing Database Servers for New Hardware Trends”, Wu and Chen @ 11AM • Sam Madden, MIT, “Data Management for Next Generation Wireless Sensor Networks”, Wu and Chen @ 12:30PM • Andrei Broder, Yahoo!, “The next stage in Web IR: From query based Information Retrieval to context driven Information Supply ”, Wu and Chen @ 2:30PM

  4. Querying XML How do you query a directed graph? a tree? The standard approach used by many XML, semistructured-data, and object query languages: • Define some sort of a template describing traversals from the root of the directed graph • In XML, the basis of this template is called an XPath

  5. XPaths In its simplest form, an XPath is like a path in a file system: /mypath/subpath/*/morepath • The XPath returns a node set representing the XML nodes (and their subtrees) at the end of the path • XPaths can have node tests at the end, returning only particular node types, e.g., text(), processing-instruction(), comment(), element(), attribute() • XPath is fundamentally an ordered language: it can query in order-aware fashion, and it returns nodes in order

  6. Sample XML <?xml version="1.0" encoding="ISO-8859-1" ?> <dblp> <mastersthesis mdate="2002-01-03" key="ms/Brown92"> <author>Kurt P. Brown</author> <title>PRPL: A Database Workload Specification Language</title> <year>1992</year> <school>Univ. of Wisconsin-Madison</school> </mastersthesis> <article mdate="2002-01-03" key="tr/dec/SRC1997-018"> <editor>Paul R. McJones</editor> <title>The 1995 SQL Reunion</title> <journal>Digital System Research Center Report</journal> <volume>SRC1997-018</volume> <year>1997</year> <ee>db/labs/dec/SRC1997-018.html</ee> <ee>http://www.mcjones.org/System_R/SQL_Reunion_95/</ee> </article>

  7. XML Data Model Visualized attribute root p-i element Root text dblp ?xml mastersthesis article mdate mdate key key author title year school 2002… editor title journal volume year ee ee 2002… 1992 1997 The… ms/Brown92 tr/dec/… PRPL… Digital… db/labs/dec Univ…. Paul R. Kurt P…. SRC… http://www.

  8. Some Example XPath Queries • /dblp/mastersthesis/title • /dblp/*/editor • //title • //title/text()

  9. Context Nodes and Relative Paths XPath has a notion of a context node: it’s analogous to a current directory • “.” represents this context node • “..” represents the parent node • We can express relative paths: subpath/sub-subpath/../.. gets us back to the context node • By default, the document root is the context node

  10. Predicates – Selection Operations A predicate allows us to filter the node set based on selection-like conditions over sub-XPaths: /dblp/article[title = “Paper1”] which is equivalent to: /dblp/article[./title/text() = “Paper1”]

  11. Axes: More Complex Traversals Thus far, we’ve seen XPath expressions that go down the tree (and up one step) • But we might want to go up, left, right, etc. • These are expressed with so-called axes: • self::path-step • child::path-step parent::path-step • descendant::path-step ancestor::path-step • descendant-or-self::path-step ancestor-or-self::path-step • preceding-sibling::path-step following-sibling::path-step • preceding::path-step following::path-step • The previous XPaths we saw were in “abbreviated form”

  12. Querying Order • We saw in the previous slide that we could query for preceding or following siblings or nodes • We can also query a node for its position according to some index: • fn:first() , fn:last() return index of 0th & last element matching the last step: • fn:position() gives the relative count of the current node child::article[fn:position() = fn:last()]

  13. Users of XPath • XML Schema uses simple XPaths in defining keys and uniqueness constraints • XQuery • XSLT • XLink and XPointer, hyperlinks for XML

  14. XQuery A strongly-typed, Turing-complete XML manipulation language • Attempts to do static typechecking against XML Schema • Based on an object model derived from Schema Unlike SQL, fully compositional, highly orthogonal: • Inputs & outputs collections (sequences or bags) of XML nodes • Anywhere a particular type of object may be used, may use the results of a query of the same type • Designed mostly by DB and functional language people Attempts to satisfy the needs of data management and document management • The database-style core is mostly complete (even has support for NULLs in XML!!) • The document keyword querying features are still in the works – shows in the order-preserving default model

  15. XQuery’s Basic Form • Has an analogous form to SQL’s SELECT..FROM..WHERE..GROUPBY..ORDER BY • The model: bind nodes (or node sets) to variables; operate over each legal combination of bindings; produce a set of nodes • “FLWOR” statement [note case sensitivity!]: for {iterators that bind variables} let {collections} where {conditions} order by {order-conditions} (older version was “SORTBY”) return {output constructor}

  16. “Iterations” in XQuery A series of (possibly nested) FOR statements assigning the results of XPaths to variables for $root in document(“http://my.org/my.xml”) for $sub in $root/rootElement, $sub2 in $sub/subElement, … • Something like a template that pattern-matches, produces a “binding tuple” • For each of these, we evaluate the WHERE and possibly output the RETURN template • document() or doc() function specifies an input file as a URI • Old version was “document”; now “doc” but it depends on your XQuery implementation

  17. Two XQuery Examples <root-tag> { for $p in document(“dblp.xml”)/dblp/proceedings, $yr in $p/yr where $yr = “1999” return <proc> {$p} </proc> } </root-tag> for $i in document(“dblp.xml”)/dblp/inproceedings[author/text() = “John Smith”] return <smith-paper> <title>{ $i/title/text() }</title> <key>{ $i/@key }</key> { $i/crossref } </smith-paper>

  18. Nesting in XQuery Nesting XML trees is perhaps the most common operation In XQuery, it’s easy – put a subquery in the return clause where you want things to repeat! for $u in document(“dblp.xml”)/universities where $u/country = “USA” return <ms-theses-99> { $u/title } { for $mt in $u/../mastersthesis where $mt/year/text() = “1999” and ____________ return $mt/title } </ms-theses-99>

  19. Collections & Aggregation in XQuery In XQuery, many operations return collections • XPaths, sub-XQueries, functions over these, … • The let clause assigns the results to a variable Aggregation simply applies a function over a collection, where the function returns a value (very elegant!) let $allpapers := document(“dblp.xml”)/dblp/article return <article-authors> <count> { fn:count(fn:distinct-values($allpapers/authors)) } </count> { for $paper in doc(“dblp.xml”)/dblp/article let $pauth := $paper/author return <paper> {$paper/title} <count> { fn:count($pauth) } </count> </paper> } </article-authors>

  20. Collections, Ctd. Unlike in SQL, we can compose aggregations and create new collections from old: <result> { let $avgItemsSold := fn:avg(for $order in document(“my.xml”)/orders/orderlet $totalSold = fn:sum($order/item/quantity)return $totalSold)return $avgItemsSold } </result>

  21. Distinct-ness In XQuery, DISTINCT-ness happens as a function over a collection • But since we have nodes, we can do duplicate removal according to value or node • Can do fn:distinct-values(collection) to remove duplicate values, or fn:distinct-nodes(collection) to remove duplicate nodes for $years in fn:distinct-values(doc(“dblp.xml”)//year/text() return $years

  22. Sorting in XQuery • SQL actually allows you to sort its output, with a special ORDER BY clause (which we haven’t discussed, but which specifies a sort key list) • XQuery borrows this idea • In XQuery, what we order is the sequence of “result tuples” output by the return clause: for $x in document(“dblp.xml”)/proceedings order by $x/title/text() return $x

  23. What If Order Doesn’t Matter? By default: • SQL is unordered • XQuery is ordered everywhere! • But unordered queries are much faster to answer XQuery has a way of telling the query engine to avoid preserving order: • unordered { for $x in (mypath) …}

  24. Querying & Defining Metadata – Can’t Do This in SQL Can get a node’s name by querying node-name(): for $x in document(“dblp.xml”)/dblp/* return node-name($x) Can construct elements and attributes using computed names: for $x in document(“dblp.xml”)/dblp/*, $year in $x/year, $title in $x/title/text(), element node-name($x) { attribute {“year-” + $year} { $title } }

  25. XQuery Summary Very flexible and powerful language for XML • Clean and orthogonal: can always replace a collection with an expression that creates collections • DB and document-oriented (we hope) • The core is relatively clean and easy to understand Turing Complete – we’ll talk more about XQuery functions soon

  26. XSL(T): The Bridge Back to HTML • XSL (XML Stylesheet Language) is actually divided into two parts: • XSL:FO: formatting for XML • XSLT: a special transformation language • We’ll leave XSL:FO for you to read off www.w3.org, if you’re interested • XSLT is actually able to convert from XML  HTML, which is how many people do their formatting today • Products like Apache Cocoon generally translate XML  HTML on the server side

  27. A Different Style of Language • XSLT is based on a series of templates that match different parts of an XML document • There’s a policy for what rule or template is applied if more than one matches (it’s not what you’d think!) • XSLT templates can invoke other templates • XSLT templates can be nonterminating (beware!) • XSLT templates are based on XPath “match”es, and we can also apply other templates (potentially to “select”ed XPaths) • Within each template, we describe what should be output • (Matches to text default to outputting it)

  28. An XSLT Stylesheet <xsl:stylesheet version=“1.1”> <xsl:template match=“/dblp”> <html><head>This is DBLP</head> <body> <xsl:apply-templates /> </body> </html> </xsl:template> <xsl:template match=“inproceedings”> <h2><xsl:apply-templates select=“title” /></h2> <p><xsl:apply-templates select=“author”/></p> </xsl:template> … </xsl:stylesheet>

  29. <dblp> <inproceedings> <title>Paper1</title> <author>Smith</author> </inproceedings> <inproceedings> <author>Chakrabarti</author> <author>Gray</author> <title>Paper2</title> </inproceedings> </dblp> <html><head>This Is DBLP</head> <body> <h2>Paper1</h2> <p>Smith</p> <h2>Paper2</h2> <p>Chakrabarti</p> <p>Gray</p> </body> </html> Results of XSLT Stylesheet

  30. What XSLT Can and Can’t Do • XSLT is great at converting XML to other formats • XML  diagrams in SVG; HTML; LaTeX • … • XSLT doesn’t do joins (well), it only works on one XML file at a time, and it’s limited in certain respects • It’s not a query language, really • … But it’s a very good formatting language • Most web browsers (post Netscape 4.7x) support XSLT and XSL formatting objects • But most real implementations use XSLT with something like Apache Cocoon • You may want to use XSL/XSLT for your projects – see www.w3.org/TR/xslt for the spec

  31. Querying XML We’ve seen three XML manipulation formalisms today: • XPath: the basic language for “projecting and selecting” (evaluating path expressions and predicates) over XML • XQuery: a statically typed, Turing-complete XML processing language • XSLT: a template-based language for transforming XML documents • Each is extremely useful for certain applications!

  32. Views in SQL and XQuery • A view is a named query • We use the name of the view to invoke the query (treating it as if it were the relation it returns) SQL: CREATE VIEW V(A,B,C) AS SELECT A,B,C FROM R WHERE R.A = “123” XQuery:declare function V() as element(content)* { for $r in doc(“R”)/root/tree, $a in $r/a, $b in $r/b, $c in $r/c where $a = “123” return <content>{$a, $b, $c}</content> } Using the views: SELECT * FROM V, RWHERE V.B = 5 AND V.C = R.C for $v in V()/content, $r in doc(“r”)/root/treewhere $v/b = $r/breturn $v

  33. What’s Useful about Views Providing security/access control • We can assign users permissions on different views • Can select or project so we only reveal what we want! Can be used as relations in other queries • Allows the user to query things that make more sense Describe transformations from one schema (the base relations) to another (the output of the view) • The basis of converting from XML to relations or vice versa • This will be incredibly useful in data integration, discussed soon… Allow us to define recursive queries

  34. Materialized vs. Virtual Views • A virtual view is a named query that is actually re-computed every time – it is merged with the referencing query CREATE VIEW V(A,B,C) AS SELECT A,B,C FROM R WHERE R.A = “123” • A materialized view is one that is computed once and its results are stored as a table • Think of this as a cached answer • These are incredibly useful! • Techniques exist for using materialized views to answer other queries • Materialized views are the basis of relating tables in different schemas SELECT * FROM V, RWHERE V.B = 5 AND V.C = R.C

  35. Views Should Stay Fresh • Views (sometimes called intensional relations) behave, from the perspective of a query language, exactly like base relations (extensional relations) • But there’s an association that should be maintained: • If tuples change in the base relation, they should change in the view (whether it’s materialized or not) • If tuples change in the view, that should reflect in the base relation(s)

  36. View Maintenance and the View Update Problem • There exist algorithms to incrementally recompute a materialized view when the base relations change • We can try to propagate view changes to the base relations • However, there are lots of views that aren’t easily updatable: • We can ensure views are updatable by enforcing certain constraints (e.g., no aggregation),but this limits the kinds of views we can have! R R⋈S S delete?

  37. Next Time • Can we have views in XML over tables in relations? • … Or vice versa? • What other things can we use views for

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