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<h1 align="center">The XML library for Gnome</h1>

<p>This document describes the <a href="http://www.w3.org/XML/">XML</a>
library provideed in the <a href="http://www.gnome.org/">Gnome</a> framework.
XML is a standard to build tag based structured documents/data. </p>

<p>The internal document repesentation is as close as possible to the <a
href="http://www.w3.org/DOM/">DOM</a> interfaces. </p>

<p>Libxml also has a <a href="http://www.megginson.com/SAX/index.html">SAX
interface</a>, <a href="mailto:james@daa.com.au">James Henstridge</a> made <a
href="http://www.daa.com.au/~james/gnome/xml-sax/xml-sax.html">a nice
documentation</a> expaining how to use it. The interface is as compatible as
possible with <a href="http://www.jclark.com/xml/expat.html">Expat</a>
one.</p>

<p>The code is commented in a <a href=""></a>way which allow <a
href="http://rpmfind.net/veillard/XML/libxml.html">extensive documentation</a>
to be automatically extracted.</p>

<p>There is also a mailing-list <a
href="xml@rufus.w3.org">xml@rufus.w3.org</a> for libxml, with an <a
href="http://rpmfind.net/veillard/XML/messages">on-line archive</a>. To
subscribe to this majordomo based list, send a mail to <a
href="majordomo@rufus.w3.org">majordomo@rufus.w3.org</a> with "subscribe xml"
in the <strong>content</strong> of the message.</p>

<p>This library is released both under the W3C Copyright and the GNU LGP,
basically everybody should be happy, if not, drop me a mail.</p>

<p>People are invited to use the <a
href="http://cvs.gnome.org/lxr/source/gdome/">gdome Gnome module to</a> get a
full DOM interface, thanks to <a href="mailto:raph@levien.com">Raph
Levien</a>, check his <a
href="http://www.levien.com/gnome/domination.html">DOMination paper</a>. He
uses it for his implementation of <a
href="http://www.w3.org/Graphics/SVG/">SVG</a> called <a
href="http://www.levien.com/svg/">gill</a>.</p>

<h2>xml</h2>

<p>XML is a standard for markup based structured documents, here is <a
name="example">an example</a>:</p>
<pre>&lt;?xml version="1.0"?>
&lt;EXAMPLE prop1="gnome is great" prop2="&amp;amp; linux too">
  &lt;head>
   &lt;title>Welcome to Gnome&lt;/title>
  &lt;/head>
  &lt;chapter>
   &lt;title>The Linux adventure&lt;/title>
   &lt;p>bla bla bla ...&lt;/p>
   &lt;image href="linus.gif"/>
   &lt;p>...&lt;/p>
  &lt;/chapter>
&lt;/EXAMPLE></pre>

<p>The first line specify that it's an XML document and gives useful
informations about it's encoding. Then the document is a text format whose
structure is specified by tags between brackets. <strong>Each tag opened have
to be closed</strong> XML is pedantic about this, not that for example the
image tag has no content (just an attribute) and is closed by ending up the
tag with <code>/></code>.</p>

<h2>The tree output</h2>

<p>The parser returns a tree built during the document analysis. The value
returned is an <strong>xmlDocPtr</strong> (i.e. a pointer to an
<strong>xmlDoc</strong> structure). This structure contains informations like
the file  name, the document type, and a <strong>root</strong> pointer which
is the root of the document (or more exactly the first child under the root
which is the document). The tree is made of <strong>xmlNode</strong>s, chained
in double linked lists of siblings and with childs&lt;->parent relationship.
An xmlNode can also carry properties (a chain of xmlAttr structures). An
attribute may have a value which is a list of TEXT or ENTITY_REF nodes.</p>

<p>Here is an example (erroneous w.r.t. the XML spec since there should be
only one ELEMENT under the root):</p>

<p><img src="structure.gif" alt=" structure.gif "></p>

<p>In the source package there is a small program (not installed by default)
called <strong>tester</strong> which parses XML files given as argument and
prints them back as parsed, this is useful to detect errors both in XML code
and in the XML parser itself. It has an option <strong>--debug</strong> which
prints the actual in-memory structure of the document, here is the result with
the <a href="#example">example</a> given before:</p>
<pre>DOCUMENT
version=1.0
standalone=true
  ELEMENT EXAMPLE
    ATTRIBUTE prop1
      TEXT
      content=gnome is great
    ATTRIBUTE prop2
      ENTITY_REF
      TEXT
      content= too
    ELEMENT head
      ELEMENT title
        TEXT
        content=Welcome to Gnome
    ELEMENT chapter
      ELEMENT title
        TEXT
        content=The Linux adventure
      ELEMENT p
        TEXT
        content=bla bla bla ...
      ELEMENT image
        ATTRIBUTE href
          TEXT
          content=linus.gif
      ELEMENT p
        TEXT
        content=...</pre>

<p>This should be useful to learn the internal representation model.</p>

<h2>The XML library interfaces</h2>

<p>This section is directly intended to help programmers getting bootstrapped
using the XML library from the C language. It doesn't intent to be extensive,
I hope the automatically generated docs will provide the completeness
required, but as a separated set of documents. The interfaces of the XML
library are by principle low level, there is nearly zero abstration. Those
interested in a higher level API should <a href="#DOM">look at DOM</a>
(unfortunately not completed).</p>

<h3>Invoking the parser</h3>

<p>Usually, the first thing to do is to read an XML input, the parser accepts
to parse both memory mapped documents or direct files. The functions are
defined in "parser.h":</p>
<dl>
  <dt><code>xmlDocPtr xmlParseMemory(char *buffer, int size);</code></dt>
    <dd><p>parse a zero terminated string containing the document</p>
    </dd>
</dl>
<dl>
  <dt><code>xmlDocPtr xmlParseFile(const char *filename);</code></dt>
    <dd><p>parse an XML document contained in a file (possibly compressed)</p>
    </dd>
</dl>

<p>This returns a pointer to the document structure (or NULL in case of
failure).</p>

<p>A couple of comments can be made, first this mean that the parser is
memory-hungry, first to load the document in memory, second to build the tree.
Reading a document without building the tree will be possible in the future by
pluggin the code to the SAX interface (see SAX.c).</p>

<h3>Building a tree from scratch</h3>

<p>The other way to get an XML tree in memory is by building it. Basically
there is a set of functions dedicated to building new elements, those are also
described in "tree.h", here is for example the piece of code producing the
example used before:</p>
<pre>    xmlDocPtr doc;
    xmlNodePtr tree, subtree;

    doc = xmlNewDoc("1.0");
    doc->root = xmlNewDocNode(doc, NULL, "EXAMPLE", NULL);
    xmlSetProp(doc->root, "prop1", "gnome is great");
    xmlSetProp(doc->root, "prop2", "&amp;linux; too");
    tree = xmlNewChild(doc->root, NULL, "head", NULL);
    subtree = xmlNewChild(tree, NULL, "title", "Welcome to Gnome");
    tree = xmlNewChild(doc->root, NULL, "chapter", NULL);
    subtree = xmlNewChild(tree, NULL, "title", "The Linux adventure");
    subtree = xmlNewChild(tree, NULL, "p", "bla bla bla ...");
    subtree = xmlNewChild(tree, NULL, "image", NULL);
    xmlSetProp(subtree, "href", "linus.gif");</pre>

<p>Not really rocket science ...</p>

<h3>Traversing the tree</h3>

<p>Basically by including "tree.h" your code has access to the internal
structure of all the element of the tree. The names should be somewhat simple
like <strong>parent</strong>, <strong>childs</strong>, <strong>next</strong>,
<strong>prev</strong>, <strong>properties</strong>, etc... For example still
with the previous example:</p>
<pre><code>doc->root->childs->childs</code></pre>

<p>points to the title element,</p>
<pre>doc->root->childs->next->child->child</pre>

<p>points to the text node containing the chapter titlle "The Linux adventure"
and</p>
<pre>doc->root->properties->next->val</pre>

<p>points to the entity reference containing the value of "&amp;linux" at the
beginning of the second attribute of the root element "EXAMPLE".</p>

<h3>Modifying the tree</h3>

<p>functions are provided to read and write the document content:</p>
<dl>
  <dt><code>xmlAttrPtr xmlSetProp(xmlNodePtr node, const CHAR *name, const
  CHAR *value);</code></dt>
    <dd><p>This set (or change) an attribute carried by an ELEMENT node the
      value can be NULL</p>
    </dd>
</dl>
<dl>
  <dt><code>const CHAR *xmlGetProp(xmlNodePtr node, const CHAR
  *name);</code></dt>
    <dd><p>This function returns a pointer to the property content, note that
      no extra copy is made</p>
    </dd>
</dl>

<p>Two functions must be used to read an write the text associated to
elements:</p>
<dl>
  <dt><code>xmlNodePtr xmlStringGetNodeList(xmlDocPtr doc, const CHAR
  *value);</code></dt>
    <dd><p>This function takes an "external" string and convert it to one text
      node or possibly to a list of entity and text nodes. All non-predefined
      entity references like &amp;Gnome; will be stored internally as an
      entity node, hence the result of the function may not be a single
      node.</p>
    </dd>
</dl>
<dl>
  <dt><code>CHAR *xmlNodeListGetString(xmlDocPtr doc, xmlNodePtr list, int
  inLine);</code></dt>
    <dd><p>this is the dual function, which generate a new string containing
      the content of the text and entity nodes. Note the extra argument
      inLine, if set to 1 instead of returning the &amp;Gnome; XML encoding in
      the string it will substitute it with it's value say "GNU Network Object
      Model Environment". Set it if you want to use the string for non XML
      usage like User Interface.</p>
    </dd>
</dl>

<h3>Saving a tree</h3>

<p>Basically 3 options are possible:</p>
<dl>
  <dt><code>void xmlDocDumpMemory(xmlDocPtr cur, CHAR**mem, int
  *size);</code></dt>
    <dd><p>returns a buffer where the document has been saved</p>
    </dd>
</dl>
<dl>
  <dt><code>extern void xmlDocDump(FILE *f, xmlDocPtr doc);</code></dt>
    <dd><p>dumps a buffer to an open file descriptor</p>
    </dd>
</dl>
<dl>
  <dt><code>int xmlSaveFile(const char *filename, xmlDocPtr cur);</code></dt>
    <dd><p>save the document ot a file. In that case the compression interface
      is triggered if turned on</p>
    </dd>
</dl>

<h3>Compression</h3>

<p>The library handle transparently compression when doing file based
accesses, the level of compression on saves can be tuned either globally or
individually for one file:</p>
<dl>
  <dt><code>int  xmlGetDocCompressMode (xmlDocPtr doc);</code></dt>
    <dd><p>Get the document compression ratio (0-9)</p>
    </dd>
</dl>
<dl>
  <dt><code>void xmlSetDocCompressMode (xmlDocPtr doc, int mode);</code></dt>
    <dd><p>Set the document compression ratio</p>
    </dd>
</dl>
<dl>
  <dt><code>int  xmlGetCompressMode(void);</code></dt>
    <dd><p>Get the default compression ratio</p>
    </dd>
</dl>
<dl>
  <dt><code>void xmlSetCompressMode(int mode);</code></dt>
    <dd><p>set the default compression ratio</p>
    </dd>
</dl>

<h2><a name="DOM">DOM Principles</a></h2>

<p><a href="http://www.w3.org/DOM/">DOM</a> stands for the <em>Document Object
Model</em> this is an API for accessing XML or HTML structured documents.
Native support for DOM in Gnome is on the way (module gnome-dom), and it will
be based on gnome-xml. This will be a far cleaner interface to manipulate XML
files within Gnome since it won't expose the internal structure. DOM defiles a
set of IDL (or Java) interfaces allowing to traverse and manipulate a
document. The DOM library will allow accessing and modifying "live" documents
presents on other programs like this:</p>

<p><img src="DOM.gif" alt=" DOM.gif "></p>

<p>This should help greatly doing things like modifying a gnumeric spreadsheet
embedded in a GWP document for example.</p>

<h3><a name="Example">A real example</a></h3>

<p>Here is a real size example, where the actual content of the application
data is not kept in the DOM tree but uses internal structures. It is based on
a proposal to keep a database of jobs related to Gnome, with an XML based
storage structure. Here is an <a href="gjobs.xml">XML encoded jobs
base</a>:</p>
<pre>&lt;?xml version="1.0"?>
&lt;gjob:Helping xmlns:gjob="http://www.gnome.org/some-location">
  &lt;gjob:Jobs>

    &lt;gjob:Job>
      &lt;gjob:Project ID="3"/>
      &lt;gjob:Application>GBackup&lt;/gjob:Application>
      &lt;gjob:Category>Development&lt;/gjob:Category>

      &lt;gjob:Update>
        &lt;gjob:Status>Open&lt;/gjob:Status>
        &lt;gjob:Modified>Mon, 07 Jun 1999 20:27:45 -0400 MET DST&lt;/gjob:Modified>
        &lt;gjob:Salary>USD 0.00&lt;/gjob:Salary>
      &lt;/gjob:Update>

      &lt;gjob:Developers>
        &lt;gjob:Developer>
        &lt;/gjob:Developer>
      &lt;/gjob:Developers>

      &lt;gjob:Contact>
        &lt;gjob:Person>Nathan Clemons&lt;/gjob:Person>
        &lt;gjob:Email>nathan@windsofstorm.net&lt;/gjob:Email>
        &lt;gjob:Company>
        &lt;/gjob:Company>
        &lt;gjob:Organisation>
        &lt;/gjob:Organisation>
        &lt;gjob:Webpage>
        &lt;/gjob:Webpage>
        &lt;gjob:Snailmail>
        &lt;/gjob:Snailmail>
        &lt;gjob:Phone>
        &lt;/gjob:Phone>
      &lt;/gjob:Contact>

      &lt;gjob:Requirements>
      The program should be released as free software, under the GPL.
      &lt;/gjob:Requirements>

      &lt;gjob:Skills>
      &lt;/gjob:Skills>

      &lt;gjob:Details>
      A GNOME based system that will allow a superuser to configure 
      compressed and uncompressed files and/or file systems to be backed 
      up with a supported media in the system.  This should be able to 
      perform via find commands generating a list of files that are passed 
      to tar, dd, cpio, cp, gzip, etc., to be directed to the tape machine 
      or via operations performed on the filesystem itself. Email 
      notification and GUI status display very important.
      &lt;/gjob:Details>

    &lt;/gjob:Job>

  &lt;/gjob:Jobs>
&lt;/gjob:Helping>
</pre>

<p>While loading the XML file into an internal DOM tree is a matter of calling
only a couple of functions, browsing the tree to gather the informations and
generate the internals structures is harder, and more error prone.</p>

<p>The suggested principle is to be tolerant with respect to the input
structure. For example the ordering of the attributes is not significant, Cthe
XML specification is clear about it. It's also usually a good idea to not be
dependant of the orders of the childs of a given node, unless it really makes
things harder. Here is some code to parse the informations for a person:</p>
<pre>/*
 * A person record
 */
typedef struct person {
    char *name;
    char *email;
    char *company;
    char *organisation;
    char *smail;
    char *webPage;
    char *phone;
} person, *personPtr;

/*
 * And the code needed to parse it
 */
personPtr parsePerson(xmlDocPtr doc, xmlNsPtr ns, xmlNodePtr cur) {
    personPtr ret = NULL;

DEBUG("parsePerson\n");
    /*
     * allocate the struct
     */
    ret = (personPtr) malloc(sizeof(person));
    if (ret == NULL) {
        fprintf(stderr,"out of memory\n");
        return(NULL);
    }
    memset(ret, 0, sizeof(person));

    /* We don't care what the top level element name is */
    cur = cur->childs;
    while (cur != NULL) {
        if ((!strcmp(cur->name, "Person")) &amp;&amp; (cur->ns == ns))
            ret->name = xmlNodeListGetString(doc, cur->childs, 1);
        if ((!strcmp(cur->name, "Email")) &amp;&amp; (cur->ns == ns))
            ret->email = xmlNodeListGetString(doc, cur->childs, 1);
        cur = cur->next;
    }

    return(ret);
}</pre>

<p>Here is a couple of things to notice:</p>
<ul>
  <li>Usually a recursive parsing style is the more convenient one, XML data
    being by nature subject to repetitive constructs and usualy exibit highly
    stuctured patterns.</li>
  <li>The two arguments of type <em>xmlDocPtr</em> and <em>xmlNsPtr</em>, i.e.
    the pointer to the global XML document and the namespace reserved to the
    application. Document wide information are needed for example to decode
    entities and it's a good coding practice to define a namespace for your
    application set of data and test that the element and attributes you're
    analyzing actually pertains to your application space. This is done by a
    simple equality test (cur->ns == ns).</li>
  <li>To retrieve text and attributes value, it is suggested to use the
    function <em>xmlNodeListGetString</em> to gather all the text and entity
    reference nodes generated by the DOM output and produce an single text
    string.</li>
</ul>

<p>Here is another piece of code used to parse another level of the
structure:</p>
<pre>/*
 * a Description for a Job
 */
typedef struct job {
    char *projectID;
    char *application;
    char *category;
    personPtr contact;
    int nbDevelopers;
    personPtr developers[100]; /* using dynamic alloc is left as an exercise */
} job, *jobPtr;

/*
 * And the code needed to parse it
 */
jobPtr parseJob(xmlDocPtr doc, xmlNsPtr ns, xmlNodePtr cur) {
    jobPtr ret = NULL;

DEBUG("parseJob\n");
    /*
     * allocate the struct
     */
    ret = (jobPtr) malloc(sizeof(job));
    if (ret == NULL) {
        fprintf(stderr,"out of memory\n");
        return(NULL);
    }
    memset(ret, 0, sizeof(job));

    /* We don't care what the top level element name is */
    cur = cur->childs;
    while (cur != NULL) {
        
        if ((!strcmp(cur->name, "Project")) &amp;&amp; (cur->ns == ns)) {
            ret->projectID = xmlGetProp(cur, "ID");
            if (ret->projectID == NULL) {
                fprintf(stderr, "Project has no ID\n");
            }
        }
        if ((!strcmp(cur->name, "Application")) &amp;&amp; (cur->ns == ns))
            ret->application = xmlNodeListGetString(doc, cur->childs, 1);
        if ((!strcmp(cur->name, "Category")) &amp;&amp; (cur->ns == ns))
            ret->category = xmlNodeListGetString(doc, cur->childs, 1);
        if ((!strcmp(cur->name, "Contact")) &amp;&amp; (cur->ns == ns))
            ret->contact = parsePerson(doc, ns, cur);
        cur = cur->next;
    }

    return(ret);
}</pre>

<p>One can notice that once used to it, writing this kind of code is quite
simple, but boring. Ultimately, it could be possble to write stubbers taking
either C data structure definitions, a set of XML examples or an XML DTD and
produce the code needed to import and export the content between C data and
XML storage. This is left as an exercise to the reader :-)</p>

<p>Feel free to use <a href="gjobread.c">the code for the full C parsing
example</a> as a template,</p>

<p> <a href="mailto:Daniel.Veillard@w3.org">Daniel Veillard</a></p>
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