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Introduction to XML

Introduction to XML. Leonidas Fegaras. Traditional DB Applications. Typically business oriented Large amount of data Data is well-structured, normalized, with predefined schema Large number of concurrent users (transactions) ‏ Simple data, simple queries, and simple updates

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Introduction to XML

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  1. Introduction to XML Leonidas Fegaras

  2. Traditional DB Applications Typically business oriented Large amount of data Data is well-structured, normalized, with predefined schema Large number of concurrent users (transactions)‏ Simple data, simple queries, and simple updates Typically update intensive Small transactions High performance, high availability, scalability Data integrity and security are of major importance Good administrative support, nice GUIs

  3. Document Applications Human friendly: what-you-see-is-what-you-get paradigm Focus on presentation Information is divided into multiple small documents Mostly static Implicit structure: section, subsection, paragraph, etc Meta-data: title, author, date, indexing keywords, etc Content structure: form/layout, inter-relationships, references Tagging: eg, <p> for new paragraph Operations: retrieving, editing, spell-checking, printing, etc Information retrieval: keyword queries most successful in web search engines (eg, Google)‏

  4. Internet Applications Internet applications use heterogeneous, complex, hierarchical, fast-evolving, unstructured/semistructured data access mostly read-only data need 100% availability manage millions of users world-wide have high-performance requirements are concerned with security (encryption)‏ like to customize data in a personalized manner expect to gain user’s trust for business-to-consumer transactions. Internet users choose speed and availability over correctness

  5. Electronic Commerce Currently, mostly business-to-business (B2B) rather than business-to-consumer (B2C) interactions Focus on selling and buying: Order management Product catalogs Product configuration Sales and marketing Education and training Web services Communities

  6. Other Web Applications Web services Many standards: SOAP, WSDL, UDDI Web integration Heterogeneous data sources and types Thousands of web-accessible data sources Dynamic data Data warehouses Web publishing Access different types of content from browsers (PDF, HTML, XML)‏ Structured, dynamic, customized/personalized content Integration with application Accessible via major gateways and search engines Application integration Transformation between different data formats (eg, XML, HTML)‏ Integration of multiple applications

  7. Current Internet Application Architectures Architecture: Server-Tier: relational databases and gateways to diverse data sources, such as, files, OLE/DB etc. Use of enterprise servers Middle-Tier: provides data integration & distribution, query, etc. Consists of a web server and an application server Client-Tier: mostly a web browser, may use CGI scripts or Java Characteristics: Customization is achieved at the server site (customer data in a database) with some data at the client site (cookies)‏ Load balancing is typically hardware based (multiple servers, DNS routers)‏

  8. HTML <html> <head><title>My Web Page</title></head> <body> <h1>Introduction</h1> Look at <a href=”http://lambda.uta.edu/index.html”>this document</a> <img src=”image.jpg” width=100 height=50> </body> </html> It is very simple: human readable, can be edited by any editor It reflects document presentation, not the semantics or structure of data Universal: portable to any platform HTML pages are connected through hypertext links HTML pages can be located using web search engines hypertext link opening tag closing tag attribute name attribute value

  9. XML XML (eXtensible Markup Language) is a textual language for representing and exchanging data on the web It is designed to improve the functionality of the Web by providing more flexible and adaptable information identification Based on SGML It was developed around 1996 It is called extensible because it is not a fixed format like HTML (a single, predefined markup language)‏ it is actually a metalanguage (a language for describing other languages) which lets you design your own customized markup languages for limitless different types of documents

  10. XML (cont.)‏ XML can be untyped (semistructured), but there are standards now for schema conformance DTD XML Schema Without schema, an XML document is well-formed if it satisfies simple syntactic constraints: proper nesting of start and end tags With a schema, an XML document is valid if its structure conforms to a DTD or an XML Schema

  11. Example <people> <person> <name> Leonidas Fegaras </name> <tel> (817) 272-3629 </tel> <email> fegaras@cse.uta.edu </email> </person> <person> <name> Ramez Elmasri </name> <tel> (817) 272-2348 </tel> <email> elmasri@cse.uta.edu </email> </person> </people>

  12. Why XML is so Popular? It looks like HTML simple, human-readable, easy to learn, universal Flexible & extensible, since you can represent any kind of data unlike HTML HTML describes the presentation while XML describes the content Precise well-formed: properly nested XML tags valid: its structure may conform to a DTD or an XML Schema Supported by the W3C trusted and adopted by industry Many standards around XML: schemas, query languages, etc

  13. What XML has to do with Databases? XML is an important standardization for data representation and exchange, but still needs to store and query large repositories of XML documents data models and schema representations query languages, data indexing, query optimizers updates, view maintenance concurrency, distribution, security, etc Example application: an XML data repository distributed in a peer-to-peer network answer queries, such as: find all books whose author is Smith and whose title contains the word “Web” much like a web search engine, but for XML, ... and for more precise querying

  14. XML Syntax XML consists of tags and text XML documents conform to the following grammar: XMLdocument ::= Pi* Element Pi* Element ::= Stag (char | Pi | Element)* Etag Stag ::= '<' Name Attributes '>' Etag ::= '</' Name '>' Pi ::= '<?' char* '?>' Attributes ::= ( Name '=' String )* String ::= '"' char* '"' Tags come in pairs <date>8/25/2004</date> and must be properly nested: <person> <name> ... </name> ... </person> --- valid nesting <person> <name> ... </person> ... </name> --- invalid nesting Text is bounded by tags. PCDATA: parsed character data. eg, <title> The Big Sleep </title> <year> 1935 </ year>

  15. XML Elements An element is a segment of an XML document between an opening and the matching closing tags <person> <name> Ramez Elmasri </name> <tel> (817) 272-2348 </tel> <email> elmasri@cse.uta.edu </email> </person> An element may contain a mixture of sub-elements and PCDATA <title>An <em>element</em> is a segment</title> An abbreviation: for an element with empty content, we can use: <tagname ... /> instead of: <tagname ...></tagname>

  16. Representing Data Using XML Nesting tags can be used to express various structures, such as a record: <person> <name> Ramez Elmasri </name> <tel> (817) 272-2348 </tel> <email> elmasri@cse.uta.edu </email> </person> We can represent a list by using the same tag repeatedly: <addresses> <person> ... </person> <person> ... </person> <person> ... </person> ... </addresses>

  17. XML structure XML: <person> <name> Ramez Elmasri </name> <tel> (817) 272-2348 </tel> <email> elmasri@cse.uta.edu </email> </person> is Lisp-like: (person (name “Ramez Elmasri”)‏ (tel “(817) 272-2348”)‏ (email “elmasri@cse.uta.edu”))‏ and tree-like: person name tel email Ramez Elmasri (817) 272-2348 elmasri@cse.uta.edu

  18. Attributes An opening tag may contain attributes typically used to describe the content of an element <author ssn="2787901"> <name>Ramez Elmasri</name> <email> elmasri@cse.uta.edu </email> </author> It's not always clear when to use attributes <author> <ssn>2787901</ssn> <name>Ramez Elmasri</name> <email> elmasri@cse.uta.edu </email> </author> ID attributes are special: must be unique within the document An IDref attribute must refer to an existing ID in the same doc

  19. Referencing Elements Using IDs/IDrefs <family> <person id="jane" mother="mary" father="john"> <name> Jane Doe </name> </person> <person id="john" children="jane jack"> <name> John Doe </name> <mother/> </person> <person id="mary" children="jane jack"> <name> Mary Doe </name> </person> <person id="jack" mother=”mary" father="john"> <name> Jack Doe </name> </person> </family>

  20. A Complete Example <?xml version="1.0"?> <!DOCTYPE bib SYSTEM "bib.dtd"> <bib> <vendor id="id0_1"> <name>Amazon</name> <email>webmaster@amazon.com</email> <phone>1-800-555-9999</phone> <book> <title>Unix Network Programming</title> <publisher>Addison Wesley</publisher> <year>1995</year> <author> <firstname>Richard</firstname> <lastname>Stevens</lastname> </author> <price>38.68</price> </book> <book> <title>An Introduction to Object-Oriented Design</title> <publisher>Addison Wesley</publisher> <year>1996</year> <author> <firstname>Jo</firstname> <lastname>Levin</lastname> </author> <author> <firstname>Harold</firstname> <lastname>Perry</lastname> </author> <price>11.55</price> </book> </vendor> </bib>

  21. OODB Schema class Movie ( extent Movies, key title )‏ { attribute string title; attribute string director; relationship set<Actor> casts inverse Actor::acted_In; attribute int budget; } ; class Actor ( extent Actors, key name )‏ { attribute string name; relationship set<Movie> acted_In inverse Movie::casts; attribute int age; attribute set<string> directed; } ;

  22. In XML … <db> <movie id=“m1” casts=“a1 a3”> <title>Waking Ned Divine</title> <director>Kirk Jones III</director> <budget>100,000</budget> </movie> <movie id=“m2” casts=“a2 a9 a21”> <title>Dragonheart</title> <director>Rob Cohen</director> <budget>110,000</budget> </movie> <movie id=“m3” casts=“a1 a8”> <title>Moondance</title> <director>Dagmar Hirtz</director> <budget>90,000</budget> </movie> <actor id=“a1” acted_in=“m1 m3 m78”> <name>David Kelly</name> <age>55</age> </actor> <actor id=“a2” acted_in=“m2 m9 m11”> <name>Sean Connery</name> <age>68</age> </actor> <actor id=“a3” acted_in=“m1 m35”> <name>Ian Bannen</name> <age>45</age> </actor> : </db>

  23. DTD: Document Type Descriptor A DTD imposes a structure on an XML document Not quite a typing system it is purely syntactic now replaced by XML Schema Uses regular expressions to specify structure firstname an element with tag name firstname book* zero or more books year? an optional year firstname,lastname a firstname followed by lastname book | journal either a book or a journal

  24. Example of XML Data <bib> <vendor id="id0_1"> <name>Amazon</name> <email>webmaster@amazon.com</email> <phone>1-800-555-9999</phone> <book> <title>Unix Network Programming</title> <publisher>Addison Wesley</publisher> <year>1995</year> <author> <firstname>Richard</firstname> <lastname>Stevens</lastname> </author> <price>38.68</price> </book> ... </vendor> </bib>

  25. DTD Example <?xml encoding="ISO-8859-1"?> <!ELEMENT bib (vendor)*> <!ELEMENT vendor (name, email, book*)> <!ATTLIST vendor id ID #REQUIRED> <!ELEMENT book (title, publisher?, year?, author+, price)> <!ELEMENT author (firstname?, lastname)> <!ELEMENT name (#PCDATA)> <!ELEMENT email (#PCDATA)> <!ELEMENT title (#PCDATA)> <!ELEMENT publisher (#PCDATA)> <!ELEMENT year (#PCDATA)> <!ELEMENT firstname (#PCDATA)> <!ELEMENT lastname (#PCDATA)> <!ELEMENT price (#PCDATA)>

  26. Summary of the DTD Syntax A tagged element in a DTD is defined by <!ELEMENT name e> where e is a DTD expression If e, e1, e2 are DTD expressions, then so are: EMPTY empty content #PCDATA any text A an element with tag name A e1,e2 e1 followed by e2 e1 | e2 either e1 or e2 e* zero or more occurrences of e e+ one or more occurrences of e e? optional e (zero or one occurrences)‏ (e)‏ Note: tagged elements are global must be defined once in a DTD

  27. DTD Syntax (cont.)‏ Attribute specification: <!ATTLIST name (attribute-name type accuracy?)+> type is: ID must be unique within the document IDREF a reference to an existing ID IDREFS multiple IDREFs CDATA any string accuracy is #REQUIRED, #IMPLIED, #FIXED 'value', value 'v1 ... vn' ID, IDref, and IDrefs attributes are not typed! Example: <!ELEMENT person (#PCDATA)> <!ATTLIST person id ID #REQUIRED children IDrefs #IMPLIED > the id attribute is required while the children attribute is optional

  28. Connecting an XML document to a DTD In-line the DTD into the XML file: <?xml version=”1.0”?> <!DOCTYPE db [ <!ELEMENT person ...> ... ]> <db> <person> ... </person> ... </db> Better: put the DTD in a separate file and reference it by URL: <!DOCTYPE db SYSTEM “http://lambda.uta.edu/person.dtd”> Documents are validated against their DTD before they are used DTD XML data

  29. Recursive DTDs We want to capture a person with a mother and a father First attempt: <!ELEMENT person (name, address, person, person)> where the first person is the mother while the second is the father Second attempt: <!ELEMENT person (name, address, person?, person?)> Third attempt: <!ELEMENT person (name, address)> <!ATTLIST person id ID #REQUIRED mother IDREF #IMPLIED father IDREF #IMPLIED>

  30. Back to the OODB Schema class Movie ( extent Movies, key title )‏ { attribute string title; attribute string director; relationship set<Actor> casts inverse Actor::acted_In; attribute int budget; } ; class Actor ( extent Actors, key name )‏ { attribute string name; relationship set<Movie> acted_In inverse Movie::casts; attribute int age; attribute set<string> directed; } ;

  31. DTD <!ELEMENT db (movie+, actor+)> <!ELEMENT movie (title, director, budget)> <!ATTLIST movie id ID #REQUIRED casts IDREFS #REQUIRED> <!ELEMENT title (#PCDATA)> <!ELEMENT director (#PCDATA)> <!ELEMENT budget (#PCDATA)> <!ELEMENT actor (name, age, directed*)> <!ATTLIST actor id ID #REQUIRED acted_in IDREFS #REQUIRED> <!ELEMENT name (#PCDATA)> <!ELEMENT age (#PCDATA)> <!ELEMENT directed (#PCDATA)>

  32. XML Namespaces When merging multiple docs together, name collisions may occur A namespace is a mechanism for uniquely naming tagnames and attribute names to avoid name conflicts Tag/attribute names are now qualified names (QNames)‏ (namespace ':')? localname example: bib:author A document may use multiple namespaces A DTD has its own namespace in which all names are unique A namespace in an XML doc is defined as an attribute: xmlns:bib=“http://lambda.uta.edu/biblio.dtd” where bib is the namespace name and the URL is the location of the DTD The default namespace is defined as xmlns=“URL” If not defined, it is the global namespace

  33. Example <item xmlns=“http://www.acme.com/jp#supplies” xmlns:toy= “http://www.acme.com/jp#toys”> <name>backpack</name> <feature> <toy:item> <toy:name>cyberpet</toy:name> </toy:item> </feature> </item>

  34. XPath • Describes a single navigation path in an XML document • Selects a sequence of nodes reachable by the path • the order of nodes is the document order (which is the preorder of the XML tree: every node occurs before its children)‏ • Main construct: axis navigation • The / step returns the document root (the entire document)‏ • An XPath consists of one or more navigation steps separated by / • A navigation step is a triplet axis :: node-test [ predicate ]* • Each navigation path is evaluated relative to a context node • Examples: / child::bib / descendant::author / descendant::book [ child::author / child::name = 'Smith' ] / child::title • Most people use shorthands /bib//author //book[author/name='Smith']/title

  35. Axis • Forward axes • child • descendant • attribute • self • descendant-or-self • following-sibling • following • Reverse axes • parent • ancestor • preceding-sibling • preceding • ancestor-or-self

  36. Node Test • person any element node whose name is person • * any element node regardless of its name • @price any attribute whose name is price • @* any attribute, regardless of its name • node() any node • text() any text node • element() any element node • element(person) any element node whose tagname is person • element(person, surgeon) any element node whose tagname is person, and whose type annotation is surgeon • element(*, surgeon) any element node whose type annotation is surgeon, regardless of its name • attribute() any attribute node • attribute(price) any attribute whose name is price • attribute(*, xs:decimal) any attribute whose type annotation is xs:decimal, regardless of its name.

  37. Abbreviated Syntax • The attribute axis child:: can be omitted • section/para is an abbreviation for child::section/child::para, • section/@id is an abbreviation for child::section/attribute::id • … unless the axis step contains an attribute test, … then the default axis is attribute • section/attribute(id) is shorthand for child::section/attribute::attribute(id)‏ • The attribute axis attribute:: can be abbreviated by @ • para[@type="warning"] is shorthand for child::para[attribute::type="warning"] • // is replaced by /descendant-or-self::node()/ • div//para is shorthand for child::div/descendant-or-self::node()/child::para • .. is short for parent::node()‏ • ../title is short for parent::node()/child::title

  38. Most Common Steps XPath step full XPath syntax /tagname / child::tagname /* / child::any //tagname / descendant::taganme //* / descendant::any /@attrname / attribute::attrname /@* / attribute::any . self::node()‏ .. parent::node()‏ • Examples: /book/chapter/section //chapter/* //book/author/@*

  39. Example 1 bib <?xml version=”1.0” encoding=”UTF-8”?> <bib> <vendor id="id0_1"> <name>Amazon</name> <email>webmaster@amazon.com</email> <book> <title>Unix Network Programming</title> <publisher>Addison Wesley</publisher> <year>1995</year> <author> <firstname>Richard</firstname> <lastname>Stevens</lastname> </author> <price>38.68</price> </book> <book> <title>An Introduction to Object-Oriented Design</title> <publisher>Addison Wesley</publisher> <year>1996</year> <author> <firstname>Jo</firstname> <lastname>Levin</lastname> </author> <author> <firstname>Harold</firstname> <lastname>Perry</lastname> </author> <price>11.55</price> </book> </vendor> </bib> vendor @id name email book book title publisher year author price title publisher year author author price firstname lastname firstname lastname firstname lastname XPath: /bib/vendor Result: vendor name @id email book book title publisher year author price title publisher year author author price firstname lastname firstname lastname firstname lastname

  40. Example 2 bib <?xml version=”1.0” encoding=”UTF-8”?> <bib> <vendor id="id0_1"> <name>Amazon</name> <email>webmaster@amazon.com</email> <book> <title>Unix Network Programming</title> <publisher>Addison Wesley</publisher> <year>1995</year> <author> <firstname>Richard</firstname> <lastname>Stevens</lastname> </author> <price>38.68</price> </book> <book> <title>An Introduction to Object-Oriented Design</title> <publisher>Addison Wesley</publisher> <year>1996</year> <author> <firstname>Jo</firstname> <lastname>Levin</lastname> </author> <author> <firstname>Harold</firstname> <lastname>Perry</lastname> </author> <price>11.55</price> </book> </vendor> </bib> vendor @id name email book book title publisher year author price title publisher year author author price firstname lastname firstname lastname firstname lastname XPath: /bib/vendor/book Result: book book title publisher year author price title publisher year author price author firstname lastname firstname lastname firstname lastname

  41. Example 3 bib <?xml version=”1.0” encoding=”UTF-8”?> <bib> <vendor id="id0_1"> <name>Amazon</name> <email>webmaster@amazon.com</email> <book> <title>Unix Network Programming</title> <publisher>Addison Wesley</publisher> <year>1995</year> <author> <firstname>Richard</firstname> <lastname>Stevens</lastname> </author> <price>38.68</price> </book> <book> <title>An Introduction to Object-Oriented Design</title> <publisher>Addison Wesley</publisher> <year>1996</year> <author> <firstname>Jo</firstname> <lastname>Levin</lastname> </author> <author> <firstname>Harold</firstname> <lastname>Perry</lastname> </author> <price>11.55</price> </book> </vendor> </bib> vendor @id name email book book title publisher year author price title publisher year author author price firstname lastname firstname lastname firstname lastname XPath: /bib/vendor/book/author Result: author author author firstname lastname firstname lastname firstname lastname

  42. Functions • XPath operators • arithmetic and boolean + - * div mod = != < > <= >= and or • selecting multiple tagnames • Example: return the author names and prices of all books //book(author/name | price)‏ • XPath functions • They are all from namespace fn fn:function_name(arg1,...,argn)‏ • See: http://www.w3schools.com/xpath/xpath_functions.asp • Examples: //book[contains(title,'XML')]/price distinct-values(//book/author/lastname)‏ //book[count(author) > 1]/title //book[position() > 10]/title //book[last()-2]/price

  43. Predicates • Existential semantics: true, if the resulting sequence is not empty • Many variations //book[10] the tenth child node of the context node (tenth book)‏ same as //book[position()=10] //book[last()] the last child node of the context node (last book)‏ //book[author] all books that have at least one author //book[author/name] all books that have at least one author/name //book[author/name='Smith'] all books authored by Smith //book[price>35.0] all books that have price more than 35.0 • Examples /bib/book[@price < 100]/title /bib/book[author/text()] //author[name/firstname='John'][name/lastname='Smith']/title /bib/*/author[name/firstname][address[zip=12345][city]]/name/lastname

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