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Man Pages

Manual Reference Pages  -  OPENOFFICE::OODOC::INTRO (3)

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OpenOffice::OODoc::Intro - Introduction to the Open OpenDocument Connector



This introductory notice is intended to allow the user to understand the general principles and to learn some basic features of the OODoc module without browsing the whole reference manual.

The reference manual is a set of OpenOffice::OODoc::xxx separate documents, where xxx is the codename of a particular functional area. The present introduction, as well as the OpenOffice::OODoc main chapter, should be read in order to get the big picture before any attempt to dig in the detailed documentation.

Just before reading this intro, it’s a good idea to have a look at the short (and commented) examples provided in the distribution.

Another general introduction to this Perl OpenDocument Connector has been published in The Perl Review (issue #3.1, dec. 2006) <>

There is an alternative intro for french-reading users. It’s available in ODT (<>) or PDF (<>). In addition, a general presentation in French can be downloaded at <>


The main goal of the Open OpenDocument Connector (OODoc) is to allow quick application development in 2 areas:

- replacement of old-style, proprietary, client-based macros for intensive and non-interactive document processing;

- direct read/write operations by enterprise software on office documents, and/or document-driven applications.

OODoc provides an abstraction of the document objects and isolates the programmer from low level XML navigation, UTF8 encoding and file compression details. For example:

        use OpenOffice::OODoc;
        my $document = odfDocument(file => filename.odt);
                        text    => Some new text,
                        style   => Text body
        $document->appendTable("My Table", 6, 4);
        $document->cellValue("My Table", 2, 1, "New value");

The script above appends a new paragraph, with given text and style, and a table with 6 lines and 4 columns, to an existing document, then inserts a value at a given position in the table. It takes much less time than the opening of the document with your favourite text processor, and can be executed without any desktop software connection. A program using this library can run without any installation (and, practically, OODoc has been tested on platforms where is not available yet).

More generally, OpenOffice::OODoc provides a lot of methods (probably most of them are not useful for you) allowing create/search/update/delete operations with document elements such as:

- ordinary text containers (paragraphs, headings, item lists); - tables and cells; - user fields; - sections; - images; - styles; - bookmarks; - bibliography entries; - page layout; - metadata (i.e. title, subject, and other general properties).

Every document processing begins by the initialization of an object abstraction of the document. The most usual constructor for this object is the odfDocument() function. When an object is initialized using this function, it brings a lot of methods allowing allowing the application to retrieve, read, update, delete or create almost every content and style element. Another constructor, odfMeta() is available in order to allow metadata processing (see below). These odfXxx() methods (and others) are shortcuts for


where Xxx is generally Document, for full access to the content, but may be another specialized object such as Manifest or Meta. The long OpenOffice::OODoc::...->new() syntax can (and should) be avoided, and replaced by the odfDocument(), odfMeta() or odfManitest() functions.

A document object initialization requires one or more options. The most usual option is the file name, as in the first example. By default, this parameter is regarded as a previously existing file. It’s possible to instantiate a document object with a new, empty document, with an additional create option giving the content class of the document to be generated. So, in our first example, the constructor could be:

        my $document = odfDocument
                        file            => filename.odt,
                        create          => text

This instruction creates a new file containing a text (i.e. an OpenDocument Text) document (and replaces any previously existing file with the same name). However, the new file will be actually created by the $document->save instruction, not by the object initialization. If create is set, the documents are generated according to ODF templates. By default, OODoc uses a set of templates which are included in the CPAN package, but it’s possible to use custom templates instead.

When the ’create’ option is in use, the newly created document may be formatted either in the OASIS OpenDocument format (ODF) or in the primary 1.0 format. If an additional ’opendocument’ is provided and set to ’true’, then the new document will be ODF-compliant. If the same option is present and set to ’false’, the old OOo 1.0 format will be selected instead. Without the ’opendocument’ option, the format will depend on the installation default (in the CPAN distribution, the default is set to OpenDocument but it can be changed by the user at the install time). In the other hand, the provided filename is not used by OODoc in order to select the file format, so you are free to create an ODF file with an OOo-like .sxw extension, and so on. The only one filename suffix that is meaningful for OODoc is .xml (by default, a file whose name is like *.xml is processed as flat XML and not as a regular, compressed ODF file).

For existing files, the format (ODF or OOo) is automatically detected according to the real content of the file (whatever the filename).

The present version of OpenOffice::OODoc is based on the OpenDocument specification, which has been published (May 2005) as an OASIS standard under the following title:

Open Document Format for Office Applications (OpenDocument) v1.0

It works with ODF 1.1 and 1.2 documents as well, knowing that these newer versions use the same basic data structure as 1.0, and (hopefully) this library doesn’t depend on any particular feature which could be removed from the specification.


The OODoc toolbox is organized in 3 logical layers. It’s not necessary for you to remember the (annoying) details given in the next few paragraphs, but these details are described only to explain the general organisation of the modules. If you have only a few dozens of seconds for reading this document, please jump directly at the part III (practical examples) and come back later if you want to know more.

    OpenDocument packaging

The first layer consists of the OpenOffice::OODoc::File class (defined in the module). This class is responsible of read/write operations with the ODF physical files. It does every I/O and compression/uncompression processing. It’s mainly an easy-to-use, OpenDocument-oriented wrapper for the standard Archive::Zip Perl module (but it could be extended to encapsulate any other physical storage method for the ODF documents).

Every physical access to a document through the OpenOffice::OODoc API requires the use of one or more connectors, each one being associated to an ODF container. The appropriate constructor is the odfContainer() function, which requires a file name/path as its first (and mandatory) argument:

        my $resource = odfContainer("myfile.odt");

The instruction above creates an instance of ODF container, associated to a given filename. The returned object (assuming the specified file exists and is readable) is an OpenOffice::OODoc::File instance, i.e. an abstraction of the ODF physical file. However, it’s possible to associate a container with an ODF that doesn’t exist yet, provided that an additional ’create’ named parameter, whose value is the class of the new document, is set. The following example creates an instance of spreadsheet ODF package:

        my $container = odfContainer("accounts.ods", create => spreadsheet);

Note that no persistent resource is created at this time. Without the ’create’ option, the odfContainer() function attempts to load the structure of the specified ODF file (and fails if something is wrong). With the ’create’ option, the structure is loaded in memory according to defaut ODF templates that belong to the OpenOffice::OODoc installation. But any persistent change (including the creation of the new ODF file, if any) requires the save() method. As an example, the following code really created a new ODF presentation file (without content):

        my $container = odfContainer("show.odp", create => presentation);

Or, more concisely:

        odfContainer("show.odp", create => presentation)->save;

So, the most minimalistic OpenOffice::OODoc application is a one-liner that creates an empty document.

For an existing resource, an open IO::File is allowed instead of a file name.

Once initialized, such a container is typically used as a basis to instantiate one or more document-oriented connectors using odfDocument(), introduced later. However, for the users who know exactly what they do, an ODF container brings some low-level methods, such as physical export and/or import of document parts. The next example exports all the named persistent styles of doc1.odt then imports them in doc2.odt:

        my $p1 = odfContainer("doc1.odt");
        my $p2 = odfContainer("doc2.odt");

Caution: there is no consistency check with raw_import(), so the application may ensure that the imported part makes sense according to the remainder of the target container (so, in this example, it may ensure that all the styles needed in the document content are conveniently defined in the imported part). Note that the raw_import() method doesn’t produce any persistent effect before the save() method is issued from the importing container. All the changes are lost if the program ends or the objects goes out of scope before save().

    XML access

An OpenOffice::OODoc::File object which has been instantiated using odfContainer(), it becomes available for processing through document-oriented, XML-based connectors. A typical OpenOffice::OODoc user doesn’t need to be really XML-aware, and most applications will probably use the high-level, XML-free methods provided by the Document and Meta objects, introduced later. However, the present section could prove useful for the general knowledge of the API.

The second layer is made of the OpenOffice::OODoc::XPath class (, which is an ODF/XML-aware class. This class is generally not directly used by the applications; it’s mainly a common ancestor for more specialised (and more user-friendly) other classes. OpenOffice::OODoc::XPath is an object-oriented representation of an XML part of an OpenDocument file (ex: content.xml, meta.xml, styles.xml, etc.), using the XML::Twig Perl API to access individual XML elements. It provides an XPath-based syntax for advanced users who want to directly get or set any element or attribute in any part of a document. If you want to deal in the same time with several XML components of the same document, you can/must create several OpenOffice::OODoc::XPath against the document (ex: one OpenOffice::OODoc::XPath will be associated with ’meta.xml’ to represent the metadata, another one will be associated with ’content.xml’ to give access to the content. OpenOffice::OODoc::XPath accepts and provides only XML strings from/to the application; but it’s able to connect with an OpenOffice::OODoc::File object for file I/O operation, so you can use it without explicit file management coding.

For an example, if you want to get access to the content of any ODF file (say ’foo.odt’), you have to write something like:

        use OpenOffice::OODoc;
        my $container = odfContainer("foo.odt");
        my $doc = odfDocument
                        container => $container,
                        part      => content

then $doc becomes an abstraction of the ’content’ part of the document (corresponding to the document body and some automatic styles). This new object brings a lot of methods allowing the applications to retrieve, read, modify, delete and creates elements in the documents.

An element is a consistent piece of content or style definition. Any element may contain a text and/or one or more attributes. As an example, the following example selects a paragraph, then gets its text content and the name of its style:

        my $element = $doc->getElement(//text:p, 2);
        my $text = $doc->getText($element);
        my $style = $doc->getAttribute($element, style name);

Note that the getElement() method works with XPath expressions. According to the ODF specification, text:p specifies a paragraph. The double slash (//) means everything from the root of the document. The second argument of getElement() is the position of the needed element in the list (knowing that //text:p designates all the paragraphs); this position is zero-based, so in this example the third paragraph is selected. The search space of getElement() is the whole document by default, but it’s possible to restrict it to a given context, specified through a additional argument. A context is a particular element, previously selected. As an example, the following code selects the 3rd paragraph in the 4th section (if any):

        my $section = $doc->getElement(//text:section, 3);
        my $paragraph = $doc->getElement(//text:p, 2, $section);

(Of course, there is a getSection() method that allows you to forget the XPath expression and to retrieve a section by name instead of number.)

In a real application, the user doesn’t need to known such an XPath expression, because there is a more convenient getParagraph() method that just requires the paragraph number. However, the generic, XPath-based getElement() method remains available in order to retrieve any element that is not covered by a specialized accessor.

The getText() method is self-documented in the example. The getAttribute() method requires, after the element itself, the name of the attribute whose value is needed. The real ODF name of the style attribute of a paragraph is text:style-name; however, the application may use the style name simplified form knowing that getAttribute() is able to translate the attribute names according to a simple logic: every space in the given name is replaced by a - and, if no prefix is specified, the prefix of the element itself is used, so style name is automatically interpreted as text:style-name in this particular context.

You don’t need to remember the path of such usual objects as paragraphs, headings, lists, images, ..., and other well known document components, because the 3rd layer (see below) provides easy-to-use, predefined accessors for these objects.

The text content and the attributes of a selected element may be changed. The following sequence puts a new text content and affects a new style to our previously selected paragraph:

        $doc->setText($element, "A new text content");
        $doc->setAttribute($element, style name => "Text Body Style");

The same layer of the API allows to append of insert new elements. The next example demonstrates the use of appendElement(); it creates a new paragraph with given text and style and appends it to the existing content:

                text            => "Hello world",
                attributes      => {
                        style name    => "Text Body Style"

For those who hate complex instructions, the 3 lines below do the same job as the example above:

        my $new_element = $doc->appendElement(text:p);
        $doc->setText($new_element, "Hello world");
        $doc->setAttribute($new_element, style name => "Text Body Style");

Remember that the changes above are done in the volatile content of document object; up to now; nothing is changed in the corresponding file. In order to commit the changes and make them persistent, we need to call the save() method of the container that has been used to instantiate the document.

The API allows the user, in simple situations, to forget the ODF container behind the document. The following hello world example, that creates and saves a new document, works without explicit use of the odfContainer() constructor:

        my $doc = odfDocument(
                        file => "foo.odt",
                        create => text,
                        part => content
                text            => "Hello World !",
                attributes      => {
                        style name    => "Text Body Style"

Note that odfDocument() is used here with a ’file’ parameter, whose value is a file name, instead of a ’container’. At the end, save() is called from the document instance itself instead of a container. However, a container is always instantiated, but it’s just hidden; and save() is only a stub method, the real job being done by the save() method of the container. Such a shortcut is useful in this example because the program processes one part only, i.e. the content; for applications that uses more than one part (content, styles, meta- data), two or more document connectors must be instantiated in association with the same container connector, and, as a consequence, the explicit use of odfContainer() is recommended.

OpenOffice::OODoc::XPath allows some quick element manipulation and exchange, and can operate on several documents in the same session. For example:

        my $doc1 = odfDocument(file => file1.odt, part => content);
        my $doc2 = odfDocument(file => file2.odt, part => content);
        my $paragraph = $doc1->getElement(//text:p, 15);
                (//text:h, 0, $paragraph, position => after);

This sequence takes an arbitrary paragraph (the 16th one) of a document and inserts it immediately after an arbitrary heading (the first one) in another document. Here, we used an insertElement() method to directly transfer an existing text element, but the same method (with different arguments) can create a new element according to application data, or from a well- formed XML string describing any document element in regular Open Document syntax. Example:

        # a program
        my $doc = odfDocument(file => file1.odt, part => content);
        open MYFILE, "> transfer.xml";
        print MYFILE $doc1->exportXMLElement(//text:p, 15);
        close MYFILE;
        # another program
        my $doc2 = odfDocument(file => file2.odt, part => content);
        open MYFILE, "< transfer.xml";
                (//text:h, 0, <MYFILE>, position => after);
        close MYFILE;

These last two short programs produce the same effect as the preceding one, but the target file can be processed later than the source one and in a different location, because there is no direct link in the two documents. The first program exports an XML description of the selected element, then the second program uses this description to create and insert a new element that is an exact replicate of the exported one. In the meantime, the XML intermediate file can be checked, processed and transmitted with any language and protocol.

The OpenOffice::OODoc::XPath manual page describes a lot more common features that may be used through the document-oriented API introduced below.

But it’s just a beginning, because, in the real world, you have to do much more sophisticated processing, and you have not a lot of time to learn the XML path of any kind of document element (paragraph, heading, item list, table, draw frame, style, ...).

    Document-oriented API

So there is a third, more user-friendly layer, that should be the only one visible for most of the applications.

The third layer is designed as a set of application-oriented classes, inherited from OpenOffice::OODoc::XPath. In this layer, the basic principle is allow the user to forget XML. Each document element is considered from the user’s point of view, and the XML path to get it is hidden. This approach works only if a specialized OpenOffice::OODoc::XPath class is defined for each kind of content. So, we ultimately need the following classes:

        OpenOffice::OODoc::Text for the textual content of any document;
        OpenOffice::OODoc::Image to deal with the graphic objects;
        OpenOffice::OODoc::Styles for page/style definitions;
        OpenOffice::OODoc::Meta for the metadata (meta.xml);

Fortunately, the 3 first ones should not be expressly used in real applications, knowing that the toolbox provides a compound OpenOffice::OODoc::Document class which inherits all their features. As a consequence, ordinary users have just to deal with OpenOffice::OODoc::Document to process any content (graphic or textual) or layout. An OpenOffice::OODoc::Document object is instantiated through the odfDocument() function, that is a shortcut for OpenOffice::OODoc::Document->new(). For other parts, such as the metadata or the file manifest, other constructors are available.

Simply put, a typical application will need OpenOffice::OODoc::Document in order to process the content and the layout, and OpenOffice::OODoc::Meta for a read/write access to the global properties.

However, the reference manual in organized according to the kind of features, in order to avoid a huge manual page for the Document class. As a consequence, the documentation of this compound class includes 4 chapters (::Text, ::Styles, ::Image and ::Document, the last one describing a few transverse methods. In addition, the user should remember that all the low-level attributes and methods described in the ::Xpath manual chapter are inherited by both ::Document and ::Meta.

The OpenOffice::OODoc::Text class brings some table processing methods (table creation, direct access to individual cells). These methods, (under some conditions) can be used with spreadsheets (ODF spreadsheet documents) as well as with tables included in text documents.

To illustrate the differences between the layers, the two following instructions are equivalent:

        print $doc->getText(//text:p, 2);
        print $doc->getParagraphText(2);

provided that $doc has been previously created through an odfDocument() call.

The difference looks tiny, but in fact OODoc::Text contains much more sophisticated text-aware methods that avoid a lot of coding and probably a lot of errors. For example, the following code puts the content of an ordinary perl list (@mydata) in an ODF document as an regular item list:

        my $list = $doc->appendItemList();
        $doc->setText($list, @mydata);

The first instruction creates an empty list at the end of the document body. The second one populates the new list with the content of an application- provided table. The setText() method automatically modify its behaviour according to the functional type of its first argument (with is not the same for a paragraph as for an itemlist or a table cell).

The same layer provides some global processing methods such as:

        my $result = $doc->selectTextContent($filter, \&myFunction);

that produces a double effect:

1) it scans the whole document body and extracts the content of every text element matching a given filter expression (that is an exact string or a conventional Perl regular expression);

2) it triggers automatically an application-provided function each time a matching content is found; the called function can execute any on-the-fly search/replace/delete operation on the current content and get data from any external database or communication channel; the return value of the function automatically replaces the matching string.

So such a method can be used in sophisticated conditional fusion- transformation scripts.

But you can use the same method to get a flat ASCII export of the whole document, without other processing, if you provide neither filter nor action:

        print $doc->getTextContent;

Of course, OODoc can process presentation and not only content. Example:

        $filter = Dear valued customer;
        foreach $element ($doc->selectElementsByContent($filter))
                $doc->setStyle($element, Welcome)
                        if $element->isParagraph;

After this last code sequence, every paragraph containing the string ’Dear valued customer’ has the ’Welcome’ style (assuming ’Welcome’ is a paragraph style, already defined or to be defined in the document).

A style (like any other document element) can be completely created by program, or imported (directly or through an XML string) from another document. The second way is generally the better because you need a lot of parameters to build a completely new style by program, but the creation of a simple style is not a headache with the OODoc::Styles module, provided that you have an ODF attributes glossary at hand. The following example show the way to build the Welcome style. This piece of code declares Welcome as a paragraph style, whith Standard as parent style, and with some private properties (Times 16 bold font and navy blue foreground).

                        family          => paragraph,
                        parent          => Standard,
                        properties      =>
                                area                  => text,
                                style:font-name       => Times,
                                fo:font-size          => 16pt,
                                fo:font-weight        => bold,
                                fo:color              => #000080

The color attributes are encoded in RGB hexadecimal format. It’s possible to use more mnemonic values or symbols, through conversion functions provided by the Styles module, and optional user-provided colour maps. For example, #000080 could be replaced by odfColor(’navy blue’), provided that an appropriate color table is available at the run time; see odfLoadColorMap() in the OpenOffice::OODoc::Styles manual chapter.

According to the application logic, each newly created style can be registered either as a named style (i.e. visible and reusable through a typical office software suite) or as an automatic style.

For an ordinary application that needs the best processing facility for any kind of content and presentation element, the OODoc::Document module is the best choice. This module defines a special class that inherits from Text, Image and Styles classes. It allows the programmer, for example, to simply insert a new paragraph, create an image object, anchor the image to the paragraph, then create the styles needed to control the presentation of both the paragraph and the image, all that in the same sequence and in any order.

Caution: In order to get a convenient translation between the user’s local character set and the common ODF encoding (utf8), the application must indicate the appropriate encoding. The default one is iso-8859-1 in the CPAN distribution; it can be set using the odfLocalEncoding() function. Example:

        use OpenOffice::OODoc;
        odfLocalEncoding iso-8859-15;

The default encoding can be selected by the user during the installation, and changed later by editing a configuration file. In addition, a program working with several documents in the same time can select a distinct character set for each one.

Some practical uses

To begin playing with the modules, you should before all see the self-documented sample scripts provided in the package. These scripts do nothing really useful, but they show the way to use the modules.

You should directly load the full library with the single use OpenOffice::OODoc in the beginning of your scripts. Then you should only use (in the beginning) the Document and/or Meta classes only. We encourage you, in the first time, to avoid any explicit OODoc::XPath basic method invocation, and to deal only with available intelligent modules (Text, Image, Styles, via Document, and Meta), in order to get immediate results with a minimal effort. And, if you use this stuff for evangelization purpose, you can show the code to prove that the OpenDocument format allows a lot of things with a few lines.

You can avoid the heavy object oriented notation such as:

        my $meta = OpenOffice::OODoc::Meta->new(file => "xxx.ods");

and use the shortcuts like:

        my $meta = odfMeta(file => "xxx.ods");

The first thing you have to do with a document is to create an object focused on the member you want to work with, and feed it with regular ODF XML. The most straightforward way to do that is to create the object in association with an ODF file.

    Dealing with metadata

We need metadata access, so we use OODoc::Meta

        use OpenOffice::OODoc;

        my $doc = odfMeta(file => myfile.odt);
        my $title = $doc->title;
        if ($title)     { print "The title is $title"; }
        else            { print "There is no title"; }

Here, because the constructor of OODoc::Meta is called with a ’file’ parameter, OODoc::Meta knows it needs a file access and it dynamically requires the OODoc::File module, instantiates a corresponding object using the file name, connects to it, and asks it for the ’meta.xml’ member of the file. All that annoying processing is hidden for the programmer. We have just to query for the useful object, the title.

In the same way, we could get (or even change) the document creation or last modification date registered by the editing software:

        my $d1 = $doc->creation_date;
        my $d2 = $doc->date;

The dates, in the ODF documents properties, are stored in ISO-8601 format (yyyy-mm-ddThh:mm:ss); this format is readable but not necessarily convenient for any application. But the API provides easy to use tools allowing conversion to or from the regular numeric time() format of the system, allowing any kind of formatting or calculation.

We could get more complex metadata structures, such as the user defined fields:

        my %ud  = $doc->user_defined;
        foreach my $name (keys %ud)
                { print $name . -> . $ud{$name} . "\n"; }

This code captures the user defined fields (names and values) in a hash table, which then is displayed in a name->value form. You could see the way to update the user defined fields in the ’set_fields’ script, provided with the distribution. The most usual metadata accessors have a symmetrical behaviour. To update the title, for example, you have to call the ’title’ method with a string argument:

        $doc->title("New title");

You can proceed in the same way with subject, description, keywords.

The ’keywords’ is an example of polymorphic behaviour (which is quite common for many OODoc methods):

        my $keywords = $doc->keywords;
        my @keywords = $doc->keywords;

In the first form, the keywords are returned concatenated and comma- separated in a single editable text line. In the second one, we get the keywords as a list. But if ’keywords’ is called to add new keywords, these ones must be provided as a list:

        $doc->keywords("kw1", "kw2", "kw3");

The program is automatically prevented from introducing redundancy in the keyword list (the ’keywords’ method deletes duplicates). While ’keywords’ can only add new keywords, you have to call removeKeyword to delete an existing keyword. If you want to destroy the entire list of keywords in a single call, you have just to write:


Well, we have done some updates in the metadata, but these updates apply only in memory. To make it persistent in the file, we have just to issue a:


I said OODoc::Meta (which is an OODoc::XPath) did not know anything about the OpenDocument compressed files. But in my example,the object has been created with a ’file’ argument and associated with an implicit OODoc::File object. So, the ’save’ method of OODoc::XPath is only a stub method which sends a ’save’ command to the connected OODoc::File object. With an object created with an ’xml’ parameter (providing the metadata through an XML string, without reference to a file), a ’save’ call generates a ’No archive object’ error. However, if the object had been created from an XML flat file (instead of a regular ODF compressed file), the output would be a flat XML file as well.

Note: A document is always saved in the same file format as it’s source. The save() can’t act as a format converter. So, you can’t save an OOo 1.0 file in OASIS OpenDocument format and vice versa, and you can’t directly (without intermediate processing) save in ODF compressed format a document loaded from XML data. However, thanks to the getXMLContent() method, you can write the flat XML to the standard output or a given file handle.

If you prefer to keep the original file unchanged, you can issue a


that produces the same thing as ’File/SaveAs’ in your favorite office software: if called with an argument, ’save’ creates a new file containing all the changed and unchanged members of the original one.

Of course, whatever the way you will use (or not use) the save() method, you will never process valuable documents without a backup copy...

    Example 2 - Manipulating text

Here we must read and update some text content elements. By text content, we mean not only flat text. While the most interesting module is named OpenOffice::OODoc::Text, it’s not fully dedicated to text documents. It can deal with the text content of presentations, as well as the sheets and cells of a spreadsheet.

Our program begins with something like that:

        use OpenOffice::OODoc;
        my $doc = odfDocument(file => myfile.odt);

The second line produces an OpenOffice::OODoc::Document object, which inherits from O::O::Text, O::O::Image and O::O::Styles. However, in the present example, we’ll use its O::O::Text features only.

To give a very high level abstract, we can say that OODoc::Text provides 2 kinds of read access methods: - the ’get’ methods that return data referred by unconditional addressing, like getParagraph(4); - the ’select’ methods that return data selected against a given filter, related to a text content or an attribute value, like selectParagraphsByStyle(’Text body’).

Some ’get’ or ’select’ methods return lists while other return individual elements or values.

Returned data may be elements or texts. Text data can be exported or displayed, but the application needs elements to do any read/write operation on the content. For example:

        my $text = $doc->getTextContent;

extracts the whole content of the document as a flat, editable text in the local character set, for immediate use (or display on a dumb terminal). Of course, there are more the one way to do the same thing, so you can get the same result with a ’select’ method as with a ’get’ one if you use a non-filtering filter. So:

        my $text = $doc->selectTextContent(.*);

will also return the whole text content. But this last method, with some additional arguments and an appropriate filter, is much more powerful, because it can do ’on-the-fly’ processing in each text element matching the filter (for example, insert values extracted from an enterprise database or resulting from complex calculations). The output of getTextContent can be tagged according to the type of each text element, so the application can easily use this method to export the text in an alternative (simple) markup language.

To do some intelligent processing in the text, we need to deal with individual text objects such as paragraphs, headings, list items or table cells. For example, to export the content of the 5th paragraph (paragraph numbering beginning with 0), we could directly get the text with:

        my $text = $doc->getParagraphText(4);

But in order to update the same paragraph, or change its style, I need the paragraph element, not only its text content:

        my $para = $doc->getParagraph(4);
        # text processing takes place here
        $doc->setText($para, $other_text);
        $doc->setStyle($para, $my_style);

Some methods can dynamically adapt to the text element type they have to process. For example, the getText method (exporting the text content of a given text element), can return the content of many kinds of element (paragraphs, headings, table cells, item lists or individuals list items). In addition, any text content extracted with an high-level OODoc method is transcoded in the local character set (UTF-8 issues are (we hope) hidden for the application). Optionally, the text output can be instrumented with begin and end application-provided tags according to the element type (so it’s possible to export the text in an alternative, simple XML dialect, or in LaTeX, or in an application-specific markup language).

In order to facilitate some kinds of massive document processing operations, OODoc::Text provides a few high level methods that do iterative processing upon whole sets of text elements. One example is selectElementsByContent: this method looks for any text container matching a given pattern (string or regular expression) and, each time an element is selected, it executes an application-provided callback function. An example of use is provided in the ’search’ demo script, which selects any text element in a document matching a given expression, and appends the selected content as a sequence of paragraphs in another document.

The more usual methods have explicit names, and can be used without their exhaustive documentation, provided that the programmer has a good understanding of the general philosophy. Heading and paragraph manipulations are quite simple. The situation is more complex with other text content such as item lists, tables and graphics.

To get an individual list item, you must point to it from a previously obtained list element:

        my $item_list = $doc->getList(2);
        my $item = $doc->getListItem($item_list, 4);

Here, $item contains the 5th item of the 3rd list of the document. The content of the item could then be exported by a generic method such as getText(), or processed using another method. Note that, if the application doesn’t need the $item_list object for any other use, it can directly get the list item with the same method with a list number (instead of s list object) as its first argument:

        my $item = $doc->getListItem(2, 4);

    Playing with tables and spreadsheets

Because the need of data capture within table structures is more evident, there is a direct accessor to get any individual table cell:

        my $value = $doc->getCellValue($table, $line, $col);

For example:

        my $value = $doc->getCellValue(0, 12, 0);

This code example returns the value of the 1st cell of the 13th row of the 1st table in the document. Note the ’cell value’ is simply the text content if the cell type is string; but if the cell type is any numeric type, getCellValuereturns the content of the value attribute and ignores the text. The first argument (the table) can be either the table number (zero-based, according to its sequential position in the document) or the logical table name (as it’s get or set by the end-user with OOo Writer or Calc).

A cell can be selected in a table using either it’s numeric (row, column) coordinates or a spreadsheet-like alphanumeric notation. So, the example above could be written as

        my $value = $doc->getCellValue(0, "A11");

Caution, in the classical spreadsheet notation, the column comes first while it comes last in the numeric coordinates. In addition, knowing that the numeric coordinates are zero-based, A1 corresponds to (0,0). Finally, remember that the alphanumeric coordinates must be provided in a single string while numeric coordinates require two arguments.

This alphanumeric notation is probably more user-friendly for OOo Calc documents, but it’s allowed by OODoc whatever the document class: you can use it with tables in text documents as well.

Caution: The direct cell addressing works only when the table XML storage is normalized, i.e. when every table object (row, column or cell) is mapped to an exclusive XML element. The application program can easily ensure this normalization thanks to the normalizeSheet() method, described in the OpenOffice::OODoc::Text manual page. However, up to now, the tables included in text document through Writer are normalized, so they are immediately available for direct addressing. In the other hand, with Calc spreadsheets, several contiguous objects are mapped to a single XML element as long as they have the same content, the same type and the same presentation. It’s not an issue; it’s a feature allowed by the OpenDocument specification in order to save storage space, knowing that typical large spreadsheets contain a lot of empty, or repetitive, cells. As a consequence, several cells may be located at the same coordinates. The normalizeSheet() method allows the application to define a safe area, sized according to its needs, where the direct object addressing works whatever the XML storage method in use.

The table-related methods can be used with spreadsheets (i.e. OOo Calc documents) as well as with tables included in text documents. However, before addressing cells in a spreadsheet document, a program must declare the size of the used area in each target sheet (this requirement is due to performance considerations, for Calc documents only).

You can also change the content of a cell:

        $doc->updateCell($table, $line, $col, $value);
        $doc->updateCell($table, $line, $col, $value, $string);
        $doc->updateCell($cell, $value);
        $doc->updateCell($cell, $value, $string);

The first form puts the $value in the target cell, assuming it’s a string cell or, if it’s a numeric one, your choice is to put the same content as the value and the displayable string. The second form (assuming the target cell is numeric) provides independent content for value and string (the programmer must know what (s)he does, for example in case of currency or date cell). The 3rd and 4th forms do respectively the same things, but use a previously obtained cell element in place of 3D coordinates (in order to avoid unnecessary low-level XPath recalculation).

For a flat text (non-numeric) cell whose the reference is already available, setText() produces the same result as updateCell():

        my $cell = $doc->getCell($table, $row, $col);
        $doc->setText($cell, "The text in the cell");

Both getCellValue() and updateCell() can be replaced by the cellValue() shortcut, that is a read/write accessor to indivudual cells. So:

        my $value = $doc->cellValue("Sheet4", "B12");
        $doc->cellValue("Sheet1", "P5", $value);

copies a value from one cell to another one in another table.

In this intro, the cells are assumed to be text-only. Of course, the code is more complex with numeric cells, because the program have to get or set some additional information, according to its data type.

OODoc::Text allows the program to create a new table, using the appendTable or insertTable method. The following example appends a new table with 8 lines and 5 columns to the document.

        my $table = $doc->appendTable("MyTable", 8, 5);

But this new table is (by default) a pure text table. It’s possible to build very sophisticated table structures, with an appropriate data type and a special presentation for each cell. But, to complete this task, the application must provide a lot of parameters. So, it’s recommended to avoid purely programmatic table construction, and to reuse existing table structures and styles in template documents previously created with an ODF compatible software.

    Sections, subdocuments and hyperlinks

For sophisticated document structures, paragraphs and other text containers may be included in sections. The API allows the applications to easily create or retrieve sections, whith the getSection(), appendSection(), and insertSection() methods. A given section may be either populated with a local content or provided with an external link (file path or URL) in order to include a subdocument. In addition, using lockSection() and unlockSection(), the programs can control the end-user write protection of any section.

The following example (working with OOo 2.0) appends to a master document a new, write-protected section including a new document which can be reached through an internet link:

        my $url = "";
                "Getting Started",
                link            => $url,
                protected       => "true"

And, if an unfortunate end-user is barred from updating a section by a lost password, the programmer can help with a single line such as:


Of course, a section can host any local content instead of an external link.

        my $section = $doc->appendSection("Section 1");
                attachment      => $section,
                text            => "The first paragraph in the section",
                style           => "Standard"

Here, a section is created and receives a paragraph as its first content.

An existing set of content elements could migrate under a section. The next example, more sophisticated, selects the list of all the elements that hierarchically depend on the first level 1 title of the document and moves these elements to a given section:

        my @content = $doc->getChapterContent(0, level => 1);
        $doc->moveElementsToSection("Section 1");

The sections are not the only places for using hyperlinks. The applications can associate hyperlinks to any portion of text. The following example puts a remote (http) link on every OpenDocument character string in a given paragraph:

                ($para, "OpenDocument", "");

The target of an hyperlink may be a bookmark or a heading in the current document or in another ODF document. For example, if the target is a bookmark included in the same document, the link is the name of the bookmark with a leading #:

        $doc->setHyperlink($para, "a string", "#MyMark");

When the target is a heading (i.e. a hierarchical title), the link is made of the text of the heading, prefixed with # and suffixed by |outline.

If an hyperlink is aimed at any target belonging to another document (in the local filesystem or elsewhere), you have just to concatenate the file path and the internal path. The example below puts an hyperlink to a particular heading located in a remote document:

                $para, "read the conclusion",

    Manipulating variables, bibliographic entries, bookmarks

The OODoc toolbox provides easy read/write accessors to some useful objects that can be included in OOo text documents.

If a text document contains a user-defined field, the corresponding value can be read and updated. For example, if the user needs to increase a numeric by a given value, the corresponding code could be:

        $old_value = $doc->userFieldValue("FieldName");
        $doc->userFieldValue("FieldName", $old_value + $added_value);

In addition, the OODoc API allows the user to declare new user-defined fields if needed (see setUserFieldDeclaration() in OpenOffice::OODoc::XPath).

Any OpenDocument-compliant variable text field may be inserted in a document through the textField() method. The next example appends a paragraph whose text content is This document contains <page-count> pages, knowing that the real page count will be dynamically displayed by the office software:

        my $p = $doc->appendParagraph
                (text => "This document contains ");
        $doc->appendElement($p, $doc->textField(page-count));
        $doc->extendText($p, " pages");

While the sequence above appends a text field at the end of a paragraph, the setTextField() method may insert a text field anywhere within an existing paragraph according to various positioning parameters. The example hereafter creates a date field immediately after the last occurrence of the substring the current date is ; the ’after’ option provides the search string while the ’way’ option specifies that it must be searched backward:

                $paragraph, date,
                after   => "the current date is ",
                way     => backward

It’s possible to get or set any property of a bibliography entry. An entry can be selected by its identifier (as it appears for the end-user). The first example below prints the title and the author of the first found occurrence of a [GEN99] entry, while the second one creates (or updates) its ISBN and pages properties:

        # 1
        my %properties = $doc->bibliographyEntryContent("GEN99");
        print "Title = $properties{title}\n";
        print "Author = $properties{author}\n";

        # 2
                        isbn    => xxxxyyyyzzzz,
                        pages   => 254

In addition, a getBibliographyEntries() method allows the user to retrieve the full list of the entries included in a document.

An additional bibliography entry may be inserted within a paragraph using setBibliographyMark(). As an example, the following instruction inserts a new bibliography mark as a replacement of the first substring reference needed that may occur after the 20th character in a given paragraph:

                $doc->setBibliographyMark (
                        offset     => 20,
                        replace    => "reference needed",
                        attributes => {
                            identifier  => "JDE",
                            title       => "OASIS OpenDocument Essentials",
                            author      => "J. David Eisenberg",
                            year        => 2005,
                            isbn        => "1-4116-6832-4"

We can put a bookmark in a paragraph containing a given string. Example:

        my $paragraph   = $doc->selectElementByContent("my search string");
        $doc->setBookmark($paragraph, "MyMark");

The instruction above puts the mark at the beginning of the paragraph; however, setBookmark() could put the mark at any position within the text, according to optional parameters. To illustrate the positioning logic, the following instruction puts the bookmark immediately after the first occurrence of xyz that appear after the first 20 characters:

                $paragraph, "MyMark",
                offset  => 20,
                after   => "xyz"

Note that there are many possible positioning parameter combinations for bookmarks and any other markup elements intended to be inserted within text containers; the various possibilities are inherited from the setChildElement() method, that is described in the OpenOffice::OODoc::XPath manual page.

A bookmark (created either through OpenOffice::OODoc or through this Perl API) can be used to retrieve a text element:

        my $paragraph = $doc->selectElementByBookmark("MyMark");

Note that the insert position of text fields, bibliography marks, bookmarks, and other markup elements may be specified using the same set of position parameters and according to the same logic, that are inherited from the common setChildElement() method, described in OpenOffice::OODoc::XPath.

    Dealing with text AND metadata

Sometimes we must access both the text content and the metadata. So, we need two OODoc::XPath objects : one OODoc::Document and one OODoc::Meta. And to avoid collisions and inefficient I/O operations, we need to connect the 2 objects with the same OODoc::File server.

        use OpenOffice::OODoc;
        my $archive     = odfContainer(myfile.odt);
        my $content     = odfDocument(container => $archive);
        my $meta        = odfMeta(container => $archive);
        # process content and metadata

In this case, the $content and $meta are explicitly linked to a common container. As a consequence, when the save() method of this container is triggered, all the changes through them are made persistent.

There is an example of simultaneous access to content and metadata in the script ’set_title’ (where some text content is used to generate a piece of metadata).

    Manipulating graphics

The module OODoc::Image brings some functionalities that can be used against any OO document. The following code (combining the capabilities of OODoc::Text and OODoc::Image) selects the first paragraph containing the string OpenOffice and attach an imported image to it.

        my $p = $doc->selectElementByContent("OpenOffice");
        die "Paragraph not found" unless $p;
                "Paris landscape",
                description     => "Montmartre in winter",
                attachment      => $p,
                import          => "C:\MyDocuments\montmartre.jpg",
                size            => "5cm, 3.5cm",
                style           => "graphics2"

In a spreadsheet document, the same image could be attached to a cell instead of a paragraph; to do so, the attachment option should be set to a cell element, previously obtained using getCell(). With the same syntax, in a presentation document, the attachment should be a draw page, previously selected using getDrawPage(). A page option allows the user to anchor an image to a page, instead of attaching it to a text container.

In this example, the image is physically imported. But I could replace the import parameter by a link one, in order to use the image as an external link (cf. the link option when you insert an image in This link could use a local filesystem path as well as a remote access path such as http://....

My new image needs a style (called graphics2 in my example) to be presented. This style could be an existing one, but my program could create it if needed, using an OODoc::Styles method (see below).

Any characteristic of an existing image can be read or updated using simple methods. For example, it’s easy to change the size and the position of my image:

        $doc->imageSize("Paris landscape", "10cm, 7cm");
        $doc->imagePosition("Paris landscape", "3cm, 0cm");

The size and position strings indicate the used length unit. OODoc doesn’t the provided unit, so the application should ensure that only ODF-compliant units are used. Possible units are, for example, cm (centimeter), mm (meter), in (inch), pt (point).

The logical name of the image (here Paris landscape) is the best way to retrieve an image object, so it’s a mandatory argument with the createImageElement method. With Writer, each image is created with an unique name (that is Image1, Image2, etc. if the user doesn’t provide a more significant one). But with Impress, the images are unnamed by default. We recommend you to give a significant name to each object that you want to process later by program, knowing that if an object can be easily caught by program, it’s potentially reusable.

An image can be selected by his description (i.e. the text the end-user can edit in the image properties dialog in So, the following sequence provides the list of images whose the description contains the string Montmartre:

        my @images = $doc->selectImageElementsByDescription("Montmartre");

If you have to store and process a graphical content out of the end user’s editing software, you can export it as an ordinary file:

        $doc->exportImage("Paris landscape", "/home/pictures/montmartre.jpg");

And you can use a symmetric importImage method to change the content of an image element.

    Managing styles

The OODoc::Styles allows the programmer to get any style definition, to change it and, if really needed, to create new styles. In the first part of this document, you can see an example of paragraph style creation. Unfortunately, createStyle could drive you to heavy coding efforts, because a very sophisticated style definition needs a lot of parameters and requires the knowledge of a lot of ODF attribute names. So we recommend you to systematically reuse existing styles (stored in ODF template documents used as style repositories or in XML databases). The createStyle method supports a prototype parameter that allows you to clone an existing style, contained in the same document or in another one.

The next code sequence selects the Text body style of a document, and uses it as a template to create a My Text body style in another document, changing the font size only:

        my $template = $doc1->getStyleElement("Text body");
                        "My Text Body",
                        family          => "paragraph",
                        prototype       => $template,
                        properties      =>
                                "area"          => "text",
                                "fo:font-size"  => "12pt",
                                "fo:color"      => odfColor("dark blue")

Here a dark blue color has been given to the text; but dark blue is an arbitrary string, that must be present in a user-provided, previously loaded color map; without this color map, the users must, at their choice, either directly provide an hexadecimal, six-digit color code, with a leading # (such as #00008b, that is the translation of dark blue in my installation), or get it through the odfColor() function with 3 decimal RGB values as arguments.

Because a style is required for each image in a document, the OODoc::Document brings a more user-friendly createImageStyle method. This method allows you to create an image style without any mandatory parameter (excepted the name). So, the graphics2 style I invoked in a previous createImage example could be simply created by:


Without other indication, the module automatically creates a style with reasonable values, so the image is really visible in the document. Of course, the application could provide explicit values for some parameters if needed. The following call, for example, provides specific values for contrast, luminance and gamma correction:

                        properties      =>
                                draw:contrast         => 2%,
                                draw:luminance        => -3%,
                                draw:gamma            => 1.1

Styles are not made only to control the presentation of individual elements. There are special styles for page layout. While these styles are described with very specific data structures, the OODoc::Styles module contains some methods dedicated to page styling.

    Dealing with styles AND content

While the OpenOffice::OODoc::Document methods can process both the content (text, complex structures and graphics) and the styles, it’s not always possible any style and any content through the same object in the same session.

Each individual instance of ::Document wraps an indivudual part of an ODF package. The default part is content.xml, but all the named style definitions are stored in the styles.xml part (in a few words, a named style is a style which was designed in order to be used by more than one content element; for example, any style which could be selected through the style dialog box of a typical user-oriented office software is a named style).

In order to avoid a lot of useless XML parsing, only one part at a time is loaded. As a consequence, if the application needs to process content and named styles during the same session, it must create 2 instances of ::Document objects, associated with the same ODF container. Each instance must be associated with the appropriate target. For example:

        use OpenOffice::OODoc;

        my $archive     = odfContainer(myfile.odt);
        my $content     = odfDocument
                        container => $archive,
                        part => content
        my $styles      = odfDocument
                        container => $archive,
                        part => styles

After this sequence, the $styles object gives access to any named style while all the document body can be processed through the $content object. Note that in this last example, we could avoid the part option for the content member of the package (because content is the default).

Knowing that its always possible to process content, named styles and metadata in the same session, we could instantiate a ::Meta object through odfMeta() as well. So up to 3 connecting objects can be used as interfaces for the same ODF file.

Of course, a single $archive->save() can make persistent all the changes made through all the connected objects.


Comments, questions and answers are welcome through the CPAN forum <>

Bug reports should be sent using <>


Developer/Maintainer: Jean-Marie Gouarne <>


Copyright 2004-2010 by Genicorp, S.A. <>

Initial English version of the reference manual by Graeme A. Hunter (

License: GNU Lesser General Public License v2.1

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