NAME

Data::Stag - Structured Tags datastructures

SYNOPSIS

# PROCEDURAL USAGE
use Data::Stag qw(:all);
$doc = stag_parse($file);
@persons = stag_find($doc, "person");
foreach $p (@persons) {
  printf "%s, %s phone: %s\n",
    stag_sget($p, "family_name"),
    stag_sget($p, "given_name"),
    stag_sget($p, "phone_no"),
  ;
} 

# OBJECT-ORIENTED USAGE
use Data::Stag;
$doc = Data::Stag->parse($file);
@persons = $doc->find("person");
foreach $p (@person) {
  printf "%s, %s phone:%s\n",
    $p->sget("family_name"),
    $p->sget("given_name"),
    $p->sget("phone_no"),
  ;
}

DESCRIPTION

This module is for manipulating data as hierarchical tag/value pairs (Structured TAGs or Simple Tree AGgreggates). These datastructures can be represented as nested arrays, which have the advantage of being native to perl. A simple example is shown below:

[ person=> [  [ family_name => $family_name ],
              [ given_name  => $given_name  ],
              [ phone_no    => $phone_no    ] ] ],

Data::Stag uses a subset of XML for import and export. This means the module can also be used as a general XML parser/writer (with certain caveats).

The above set of structured tags can be represented in XML as

<person>
  <family_name>...</family_name>
  <given_name>...</given_name>
  <phone_no>...</phone_no>
</person>

This datastructure can be examined, manipulated and exported using Stag functions or methods:

$document = Data::Stag->parse($file);
@persons = $document->find('person');
foreach my $person (@person) {
  $person->set('full_name',
               $person->sget('given_name') . ' ' .
               $person->sget('family_name'));
}

Advanced querying is performed by passing functions, for example:

# get all people in dataset with name starting 'A'
@persons = 
  $document->where('person',
                   sub {shift->sget('family_name') =~ /^A/});

One of the things that marks this module out against other XML modules is this emphasis on a functional approach as an obect-oriented or procedural approach.

PROCEDURAL VS OBJECT-ORIENTED USAGE

Depending on your preference, this module can be used a set of procedural subroutine calls, or as method calls upon Data::Stag objects, or both.

In procedural mode, all the subroutine calls are prefixed "stag_" to avoid namespace clashes. The following three calls are equivalent:

$person = stag_find($doc, "person");
$person = $doc->find("person");
$person = $doc->find_person;

In object mode, you can treat any tree element as if it is an object with automatically defined methods for getting/setting the tag values.

USE OF XML

Nested arrays can be imported and exported as XML, as well as other formats. XML can be slurped into memory all at once (using less memory than an equivalent DOM tree), or a simplified SAX style event handling model can be used. Similarly, data can be exported all at once, or as a series of events.

Although this module can be used as a general XML tool, it is intended primarily as a tool for manipulating hierarchical data using nested tag/value pairs.

By using a simpler subset of XML equivalent to a basic data tree structure, we can write simpler, cleaner code. This simplicity comes at a price - this module is not very suitable for XML with attributes or mixed content.

All attributes are turned into elements. This means that it will not round-trip a piece of xml with attributes in it. For some applications this is acceptable, for others it is not.

Mixed content cannot be represented in a simple tree format, so this is also expanded.

The following piece of XML

<paragraph id="1">
  example of <bold>mixed</bold>content
</paragraph>

gets parsed as if it were actually:

<paragraph>
  <paragraph-id>1</paragraph-id>
  <paragraph-text>example of</paragraph-text>
  <bold>mixed</bold>
  <paragraph-text>content</paragraph-text>
</paragraph>

This module is more suited to dealing with data-oriented documents than text-oriented documents.

It can also be used as part of a SAX-style event generation / handling framework - see Data::Stag::BaseHandler

Because nested arrays are native to perl, we can specify an XML datastructure directly in perl without going through multiple object calls.

For example, instead of the lengthy

$obj->startTag("record");
$obj->startTag("field1");
$obj->characters("foo");
$obj->endTag("field1");
$obj->startTag("field2");
$obj->characters("bar");
$obj->endTag("field2");
$obj->end("record");

We can instead write

$struct = [ record => [
            [ field1 => 'foo'],
            [ field2 => 'bar']]];

PARSING

The following example is for parsing out subsections of a tree and changing sub-elements

use Data::Stag qw(:all);
my $tree = stag_parse($xmlfile);
my ($subtree) = stag_findnode($tree, $element);
stag_set($element, $sub_element, $new_val);
print stag_xml($subtree);

OBJECT ORIENTED

The same can be done in a more OO fashion

use Data::Stag qw(:all);
my $tree = Data::Stag->parse($xmlfile);
my ($subtree) = $tree->findnode($element);
$element->set($sub_element, $new_val);
print $subtree->xml;

IN A STREAM

Rather than parsing in a whole file into memory all at once (which may not be suitable for very large files), you can take an event handling approach. The easiest way to do this to register which nodes in the file you are interested in using the makehandler method. The parser will sweep through the file, building objects as it goes, and handing the object to a subroutine that you specify.

For example:

use Data::Stag;
# catch the end of 'person' elements
my $h = Data::Stag->makehandler( person=> sub {
                                             my ($self, $person) = @_;
                                             printf "name:%s phone:%s\n",
                                               $person->get_name,
                                               $person->get_phone;
                                             return;   # clear node
                                              });
Data::Stag->parse(-handler=>$h,
                  -file=>$f);

see Data::Stag::BaseHandler for writing handlers

See the Stag website at http://stag.sourceforge.net for more examples.

STRUCTURED TAGS TREE DATA STRUCTURE

A tree of structured tags is represented as a recursively nested array, the elements of the array represent nodes in the tree.

A node is a name/data pair, that can represent tags and values. A node is represented using a reference to an array, where the first element of the array is the tagname, or element, and the second element is the data

This can be visualised as a box:

+-----------+
|Name | Data|
+-----------+

In perl, we represent this pair as a reference to an array

[ Name => $Data ]

The Data can either be a list of child nodes (subtrees), or a data value.

The terminal nodes (leafs of the tree) contain data values; this is represented in perl using primitive scalars.

For example:

[ Name => 'Fred' ]

For non-terminal nodes, the Data is a reference to an array, where each element of the the array is a new node.

+-----------+
|Name | Data|
+-----------+
        |||   +-----------+
        ||+-->|Name | Data|
        ||    +-----------+
        ||    
        ||    +-----------+
        |+--->|Name | Data|
        |     +-----------+
        |     
        |     +-----------+
        +---->|Name | Data|
              +-----------+

In perl this would be:

[ Name => [
            [Name1 => $Data1],
            [Name2 => $Data2],
            [Name3 => $Data3],
          ]
];

The extra level of nesting is required to be able to store any node in the tree using a single variable. This representation has lots of advantages over others, eg hashes and mixed hash/array structures.

MANIPULATION AND QUERYING

The following example is taken from biology; we have a list of species (mouse, human, fly) and a list of genes found in that species. These are cross-referenced by an identifier called tax_id. We can do a relational-style inner join on this identifier, as follows -

use Data::Stag qw(:all);
my $tree =
Data::Stag->new(
  'db' => [
  [ 'species_set' => [
    [ 'species' => [
      [ 'common_name' => 'house mouse' ],
      [ 'binomial' => 'Mus musculus' ],
      [ 'tax_id' => '10090' ]]],
    [ 'species' => [
      [ 'common_name' => 'fruit fly' ],
      [ 'binomial' => 'Drosophila melanogaster' ],
      [ 'tax_id' => '7227' ]]],
    [ 'species' => [
      [ 'common_name' => 'human' ],
      [ 'binomial' => 'Homo sapiens' ],
      [ 'tax_id' => '9606' ]]]]],
  [ 'gene_set' => [
    [ 'gene' => [
      [ 'symbol' => 'HGNC' ],
      [ 'tax_id' => '9606' ],
      [ 'phenotype' => 'Hemochromatosis' ],
      [ 'phenotype' => 'Porphyria variegata' ],
      [ 'GO_term' => 'iron homeostasis' ],
      [ 'map' => '6p21.3' ]]],
    [ 'gene' => [
      [ 'symbol' => 'Hfe' ],
      [ 'synonym' => 'MR2' ],
      [ 'tax_id' => '10090' ],
      [ 'GO_term' => 'integral membrane protein' ],
      [ 'map' => '13 A2-A4' ]]]]]]
 );

# inner join of species and gene parts of tree,
# based on 'tax_id' element
my $gene_set = $tree->find("gene_set");       # get <gene_set> element
my $species_set = $tree->find("species_set"); # get <species_set> element
$gene_set->ijoin("gene", "tax_id", $species_set);   # INNER JOIN

print "Reorganised data:\n";
print $gene_set->xml;

# find all genes starting with letter 'H' in where species/common_name=human
my @genes =
  $gene_set->where('gene',
                   sub { my $g = shift;
                         $g->get_symbol =~ /^H/ &&
                         $g->findval("common_name") eq ('human')});

print "Human genes beginning 'H'\n";
print $_->xml foreach @genes;

S-Expression (Lisp) representation

The data represented using this module can be represented as Lisp-style S-Expressions.

See Data::Stag::SxprParser and Data::Stag::SxprWriter

If we execute this code on the XML from the example above

$stag = Data::Stag->parse($xmlfile);
print $stag->sxpr;

The following S-Expression will be printed:

'(db
  (species_set
    (species
      (common_name "house mouse")
      (binomial "Mus musculus")
      (tax_id "10090"))
    (species
      (common_name "fruit fly")
      (binomial "Drosophila melanogaster")
      (tax_id "7227"))
    (species
      (common_name "human")
      (binomial "Homo sapiens")
      (tax_id "9606")))
  (gene_set
    (gene
      (symbol "HGNC")
      (tax_id "9606")
      (phenotype "Hemochromatosis")
      (phenotype "Porphyria variegata")
      (GO_term "iron homeostasis")
      (map
        (cytological
          (chromosome "6")
          (band "p21.3"))))
    (gene
      (symbol "Hfe")
      (synonym "MR2")
      (tax_id "10090")
      (GO_term "integral membrane protein")))
  (similarity_set
    (pair
      (symbol "HGNC")
      (symbol "Hfe"))
    (pair
      (symbol "WNT3A")
      (symbol "Wnt3a"))))

TIPS FOR EMACS USERS AND LISP PROGRAMMERS

If you use emacs, you can save this as a file with the ".el" suffix and get syntax highlighting for editing this file. Quotes around the terminal node data items are optional.

If you know emacs lisp or any other lisp, this also turns out to be a very nice language for manipulating these datastructures. Try copying and pasting the above s-expression to the emacs scratch buffer and playing with it in lisp.

INDENTED TEXT REPRESENTATION

Data::Stag has its own text format for writing data trees. Again, this is only possible because we are working with a subset of XML (no attributes, no mixed elements). The data structure above can be written as follows -

db:
  species_set:
    species:
      common_name: house mouse
      binomial: Mus musculus
      tax_id: 10090
    species:
      common_name: fruit fly
      binomial: Drosophila melanogaster
      tax_id: 7227
    species:
      common_name: human
      binomial: Homo sapiens
      tax_id: 9606
  gene_set:
    gene:
      symbol: HGNC
      tax_id: 9606
      phenotype: Hemochromatosis
      phenotype: Porphyria variegata
      GO_term: iron homeostasis
      map: 6p21.3
    gene:
      symbol: Hfe
      synonym: MR2
      tax_id: 10090
      GO_term: integral membrane protein
      map: 13 A2-A4
  similarity_set:
    pair:
      symbol: HGNC
      symbol: Hfe
    pair:
      symbol: WNT3A
      symbol: Wnt3a

See Data::Stag::ITextParser and Data::Stag::ITextWriter

NESTED ARRAY SPECIFICATION II

To avoid excessive square bracket usage, you can specify a structure like this:

use Data::Stag qw(:all);

*N = \&stag_new;
my $tree =
  N(top=>[
          N('personset'=>[
                          N('person'=>[
                                       N('name'=>'davey'),
                                       N('address'=>'here'),
                                       N('description'=>[
                                                         N('hair'=>'green'),
                                                         N('eyes'=>'two'),
                                                         N('teeth'=>5),
                                                        ]
                                        ),
                                       N('pets'=>[
                                                  N('petname'=>'igor'),
                                                  N('petname'=>'ginger'),
                                                 ]
                                        ),
                                                                        
                                      ],
                           ),
                          N('person'=>[
                                       N('name'=>'shuggy'),
                                       N('address'=>'there'),
                                       N('description'=>[
                                                         N('hair'=>'red'),
                                                         N('eyes'=>'three'),
                                                         N('teeth'=>1),
                                                        ]
                                        ),
                                       N('pets'=>[
                                                  N('petname'=>'thud'),
                                                  N('petname'=>'spud'),
                                                 ]
                                        ),
                                      ]
                           ),
                         ]
           ),
          N('animalset'=>[
                          N('animal'=>[
                                       N('name'=>'igor'),
                                       N('class'=>'rat'),
                                       N('description'=>[
                                                         N('fur'=>'white'),
                                                         N('eyes'=>'red'),
                                                         N('teeth'=>50),
                                                        ],
                                        ),
                                      ],
                           ),
                         ]
           ),

         ]
   );

# find all people
my @persons = stag_find($tree, 'person');

# write xml for all red haired people
foreach my $p (@persons) {
  print stag_xml($p)
    if stag_tmatch($p, "hair", "red");
} ;

# find all people that have name == shuggy
my @p =
  stag_qmatch($tree, 
              "person",
              "name",
              "shuggy");

NODES AS DATA OBJECTS

As well as the methods listed below, a node can be treated as if it is a data object of a class determined by the element.

For example, the following are equivalent.

$node->get_name;
$node->get('name');

$node->set_name('fred');
$node->set('name', 'fred');

This is really just syntactic sugar. The autoloaded methods are not checked against any schema, although this may be added in future.

STAG METHODS

All method calls are also available as procedural subroutine calls; unless otherwise noted, the subroutine call is the same as the method call, but with the string stag_ prefixed to the method name. The first argument should be a Data::Stag datastructure.

To import all subroutines into the current namespace, use this idiom:

use Data::Stag qw(:all);
$doc = stag_parse($file);
@persons = stag_find($doc, 'person');

If you wish to use this module procedurally, and you are too lazy to prefix all calls with stag_, use this idiom:

use Data::Stag qw(:lazy);
$doc = parse($file);
@persons = find($doc, 'person');

But beware of clashes!

Most method calls also have a handy short mnemonic. Use of these is optional. Software engineering types prefer longer names, in the belief that this leads to clearer code. Hacker types prefer shorter names, as this requires less keystrokes, and leads to a more compact representation of the code. It is expected that if you do use this module, then its usage will be fairly ubiquitous within your code, and the mnemonics will become familiar, much like the qw and s/ operators in perl. As always with perl, the decision is yours.

Some methods take a single parameter or list of parameters; some have large lists of parameters that can be passed in any order. If the documentation states:

Args: [x str], [y int], [z ANY]

Then the method can be called like this:

$stag->foo("this is x", 55, $ref);

or like this:

$stag->foo(-z=>$ref, -x=>"this is x", -y=>55);

INITIALIZATION METHODS

new

  Title: new

   Args: element str, data STAG-DATA
Returns: Data::Stag node
Example: $node = stag_new();
Example: $node = Data::Stag->new;
Example: $node = Data::Stag->new(person => [[name=>$n], [phone=>$p]]);

creates a new instance of a Data::Stag node

stagify (nodify)

  Title: stagify
Synonym: nodify
   Args: data ARRAY-REF
Returns: Data::Stag node
Example: $node = stag_stagify([person => [[name=>$n], [phone=>$p]]]);

turns a perl array reference into a Data::Stag node.

similar to new

parse

  Title: parse

   Args: [file str], [format str], [handler obj], [fh FileHandle]
Returns: Data::Stag node
Example: $node = stag_parse($fn);
Example: $node = stag_parse(-fh=>$fh, -handler=>$h, -errhandler=>$eh);
Example: $node = Data::Stag->parse(-file=>$fn, -handler=>$myhandler);

slurps a file or string into a Data::Stag node structure. Will guess the format (xml, sxpr, itext) from the suffix if it is not given.

The format can also be the name of a parsing module, or an actual parser object;

The handler is any object that can take nested Stag events (start_event, end_event, evbody) which are generated from the parse. If the handler is omitted, all events will be cached and the resulting tree will be returned.

See Data::Stag::BaseHandler for writing your own handlers

See Data::Stag::BaseGenerator for details on parser classes, and error handling

parsestr

  Title: parsestr

   Args: [str str], [format str], [handler obj]
Returns: Data::Stag node
Example: $node = stag_parsestr('(a (b (c "1")))');
Example: $node = Data::Stag->parsestr(-str=>$str, -handler=>$myhandler);

Similar to parse(), except the first argument is a string

from

  Title: from

   Args: format str, source str
Returns: Data::Stag node
Example: $node = stag_from('xml', $fn);
Example: $node = stag_from('xmlstr', q[<top><x>1</x></top>]);
Example: $node = Data::Stag->from($parser, $fn);

Similar to parse

slurps a file or string into a Data::Stag node structure.

The format can also be the name of a parsing module, or an actual parser object

unflatten

  Title: unflatten

   Args: data array
Returns: Data::Stag node
Example: $node = stag_unflatten(person=>[name=>$n, phone=>$p, address=>[street=>$s, city=>$c]]);

Creates a node structure from a semi-flattened representation, in which children of a node are represented as a flat list of data rather than a list of array references.

This means a structure can be specified as:

person=>[name=>$n,
         phone=>$p, 
         address=>[street=>$s, 
                   city=>$c]]

Instead of:

[person=>[ [name=>$n],
           [phone=>$p], 
           [address=>[ [street=>$s], 
                       [city=>$c] ] ]
         ]
]

The former gets converted into the latter for the internal representation

makehandler

  Title: makehandler

   Args: hash of CODEREFs keyed by element name
         OR a string containing the name of a module
Returns: L<Data::Stag::BaseHandler>
Example: $h = Data::Stag->makehandler(%subs);
Example: $h = Data::Stag->makehandler("My::FooHandler");

This creates a Stag event handler. The argument is a hash of subroutines keyed by element/node name. After each node is fired by the parser/generator, the subroutine is called, passing the handler object and the stag node as arguments. whatever the subroutine returns is placed back into the tree

For example, for a a parser/generator that fires events with the following tree form

<person>
  <name>foo</name>
  ...
</person>

we can create a handler that writes person/name like this:

$h = Data::Stag->makehandler(
                             person => sub { my ($self,$stag) = @_;
                                             print $stag->name;
                                             return $stag; # dont change tree
                                           });
$stag = Data::Stag->parse(-str=>"(...)", -handler=>$h)

See Data::Stag::BaseHandler for details on handlers

getformathandler

  Title: getformathandler

   Args: format str OR L<Data::Stag::BaseHandler>
Returns: L<Data::Stag::BaseHandler>
Example: $h = Data::Stag->getformathandler('xml');
         $h->file("my.xml");
         Data::Stag->parse(-fn=>$fn, -handler=>$h);

Creates a Stag event handler - this handler can be passed to an event generator / parser. Built in handlers include:

xml

Generates xml tags from events

sxpr

Generates S-Expressions from events

itext

Generates indented text from events

All the above are kinds of Data::Stag::Writer

chainhandler

  Title: chainhandler

   Args: blocked events - str or str[]
         initial handler - handler object
         final handler - handler object
Returns: 
Example: $h = Data::Stag->chainhandler('foo', $processor, 'xml')

chains handlers together - for example, you may want to make transforms on an event stream, and then pass the event stream to another handler - for example, and xml handler

  $processor = Data::Stag->makehandler(
				       a => sub { my ($self,$stag) = @_;
						  $stag->set_foo("bar");
                                                  return $stag
                                                },
				       b => sub { my ($self,$stag) = @_;
						  $stag->set_blah("eek");
                                                  return $stag
                                                },
                                       );
  $chainh = Data::Stag->chainhandler(['a', 'b'], $processor, 'xml');
  $stag = Data::Stag->parse(-str=>"(...)", -handler=>$chainh)

chains together two handlers (see also the script stag-handle.pl)

RECURSIVE SEARCHING

find (f)

  Title: find
Synonym: f

   Args: element str
Returns: node[] or ANY
Example: @persons = stag_find($struct, 'person');
Example: @persons = $struct->find('person');

recursively searches tree for all elements of the given type, and returns all nodes or data elements found.

if the element found is a non-terminal node, will return the node if the element found is a terminal (leaf) node, will return the data value

the element argument can be a path

@names = $struct->find('department/person/name');

will find name in the nested structure below:

(department
 (person
  (name "foo")))

findnode (fn)

  Title: findnode
Synonym: fn

   Args: element str
Returns: node[]
Example: @persons = stag_findnode($struct, 'person');
Example: @persons = $struct->findnode('person');

recursively searches tree for all elements of the given type, and returns all nodes found.

paths can also be used (see find)

findval (fv)

  Title: findval
Synonym: fv

   Args: element str
Returns: ANY[] or ANY
Example: @names = stag_findval($struct, 'name');
Example: @names = $struct->findval('name');
Example: $firstname = $struct->findval('name');

recursively searches tree for all elements of the given type, and returns all data values found. the data values could be primitive scalars or nodes.

paths can also be used (see find)

sfindval (sfv)

  Title: sfindval
Synonym: sfv

   Args: element str
Returns: ANY
Example: $name = stag_sfindval($struct, 'name');
Example: $name = $struct->sfindval('name');

as findval, but returns the first value found

paths can also be used (see find)

findvallist (fvl)

  Title: findvallist
Synonym: fvl

   Args: element str[]
Returns: ANY[]
Example: ($name, $phone) = stag_findvallist($personstruct, 'name', 'phone');
Example: ($name, $phone) = $personstruct->findvallist('name', 'phone');

recursively searches tree for all elements in the list

DEPRECATED

DATA ACCESSOR METHODS

these allow getting and setting of elements directly underneath the current one

get (g)

  Title: get
Synonym: g

   Args: element str
 Return: node[] or ANY
Example: $name = $person->get('name');
Example: @phone_nos = $person->get('phone_no');

gets the value of the named sub-element

if the sub-element is a non-terminal, will return a node(s) if the sub-element is a terminal (leaf) it will return the data value(s)

the examples above would work on a data structure like this:

[person => [ [name => 'fred'],
             [phone_no => '1-800-111-2222'],
             [phone_no => '1-415-555-5555']]]

will return an array or single value depending on the context

[equivalent to findval(), except that only direct children (as opposed to all descendents) are checked]

paths can also be used, like this:

@phones_nos = $struct->get('person/phone_no')

sget (sg)

  Title: sget
Synonym: sg

   Args: element str
 Return: ANY
Example: $name = $person->sget('name');
Example: $phone = $person->sget('phone_no');
Example: $phone = $person->sget('department/person/name');

as get but always returns a single value

[equivalent to sfindval(), except that only direct children (as opposed to all descendents) are checked]

getl (gl getlist)

  Title: gl
Synonym: getl
Synonym: getlist

   Args: element str[]
 Return: node[] or ANY[]
Example: ($name, @phone) = $person->getl('name', 'phone_no');

returns the data values for a list of sub-elements of a node

[equivalent to findvallist(), except that only direct children (as opposed to all descendents) are checked]

getn (gn getnode)

  Title: getn
Synonym: gn
Synonym: getnode

   Args: element str
 Return: node[]
Example: $namestruct = $person->getn('name');
Example: @pstructs = $person->getn('phone_no');

as get but returns the whole node rather than just the data value

[equivalent to findnode(), except that only direct children (as opposed to all descendents) are checked]

sgetmap (sgm)

  Title: sgetmap
Synonym: sgm

   Args: hash
 Return: hash
Example: %h = $person->sgetmap('social-security-no'=>'id', 
                               'name'              =>'label',
                               'job'               =>0,
                               'address'           =>'location');

returns a hash of key/val pairs based on the values of the data values of the subnodes in the current element; keys are mapped according to the hash passed (a value of '' or 0 will map an identical key/val).

no multivalued data elements are allowed

set (s)

  Title: set
Synonym: s

   Args: element str, datavalue ANY (list)
 Return: ANY
Example: $person->set('name', 'fred');    # single val
Example: $person->set('phone_no', $cellphone, $homephone);

sets the data value of an element for any node. if the element is multivalued, all the old values will be replaced with the new ones specified.

ordering will be preserved, unless the element specified does not exist, in which case, the new tag/value pair will be placed at the end.

for example, if we have a stag node $person

person:
  name: shuggy
  job:  bus driver

if we do this

$person->set('name', ());

we will end up with

person:
  job:  bus driver

then if we do this

$person->set('name', 'shuggy');

the 'name' node will be placed as the last attribute

person:
  job:  bus driver
  name: shuggy

You can also use magic methods, for example

$person->set_name('shuggy');
$person->set_job('bus driver', 'poet');
print $person->itext;

will print

person:
  name: shuggy
  job:  bus driver
  job:  poet

note that if the datavalue is a non-terminal node as opposed to a primitive value, then you have to do it like this:

$people  = Data::Stag->new(people=>[
                                    [person=>[[name=>'Sherlock Holmes']]],
                                    [person=>[[name=>'Moriarty']]],
                                   ]);
$address = Data::Stag->new(address=>[
                                     [address_line=>"221B Baker Street"],
                                     [city=>"London"],
                                     [country=>"Great Britain"]]);
($person) = $people->qmatch('person', (name => "Sherlock Holmes"));
$person->set("address", $address->data);

unset (u)

  Title: unset
Synonym: u

   Args: element str, datavalue ANY
 Return: ANY
Example: $person->unset('name');
Example: $person->unset('phone_no');

prunes all nodes of the specified element from the current node

You can use magic methods, like this

$person->unset_name;
$person->unset_phone_no;

free

  Title: free
Synonym: u

   Args: 
 Return: 
Example: $person->free;

removes all data from a node. If that node is a subnode of another node, it is removed altogether

for instance, if we had the data below:

<person>
  <name>fred</name>
  <address>
  ..
  </address>
</person>

and called

$person->get_address->free

then the person node would look like this:

<person>
  <name>fred</name>
</person>

add (a)

  Title: add
Synonym: a

   Args: element str, datavalues ANY[]
         OR
         Data::Stag
 Return: ANY
Example: $person->add('phone_no', $cellphone, $homephone);
Example: $person->add_phone_no('1-555-555-5555');
Example: $dataset->add($person)

adds a datavalue or list of datavalues. appends if already existing, creates new element value pairs if not already existing.

if the argument is a stag node, it will add this node under the current one

element (e name)

  Title: element
Synonym: e
Synonym: name

   Args:
 Return: element str
Example: $element = $struct->element

returns the element name of the current node.

This is illustrated in the different representation formats below

sxpr
(element "data")

or

(element
 (sub_element "..."))
xml
<element>data</element>

or

<element>
  <sub_element>...</sub_element>
</element>
perl
[element => $data ]

or

[element => [
              [sub_element => "..." ]]]
itext
element: data

or

element:
  sub_element: ...

kids (k children)

  Title: kids
Synonym: k
Synonym: children

   Args:
 Return: ANY or ANY[]
Example: @nodes = $person->kids
Example: $name = $namestruct->kids

returns the data value(s) of the current node; if it is a terminal node, returns a single value which is the data. if it is non-terminal, returns an array of nodes

addkid (ak addchild)

  Title: addkid
Synonym: ak
Synonym: addchild

   Args: kid node
 Return: ANY
Example: $person->addkid('job', $job);

adds a new child node to a non-terminal node, after all the existing child nodes

subnodes

  Title: subnodes

   Args: 
 Return: ANY[]
Example: @nodes = $person->subnodes

returns the non-terminal data value(s) of the current node;

QUERYING AND ADVANCED DATA MANIPULATION

ijoin (j)

  Title: ijoin
Synonym: j
Synonym: ij

   Args: element str, key str, data Node
 Return: undef

does a relational style inner join - see previous example in this doc

key can either be a single node name that must be shared (analagous to SQL INNER JOIN .. USING), or a key1=key2 equivalence relation (analagous to SQL INNER JOIN ... ON)

qmatch (qm)

  Title: qmatch
Synonym: qm

   Args: return-element str, match-element str, match-value str
 Return: node[]
Example: @persons = $s->qmatch('person', 'name', 'fred');
Example: @persons = $s->qmatch('person', (job=>'bus driver'));

queries the node tree for all elements that satisfy the specified key=val match - see previous example in this doc

for those inclined to thinking relationally, this can be thought of as a query that returns a stag object:

SELECT <return-element> FROM <stag-node> WHERE <match-element> = <match-value>

this always returns an array; this means that calling in a scalar context will return the number of elements; for example

$n = $s->qmatch('person', (name=>'fred'));

the value of $n will be equal to the number of persons called fred

tmatch (tm)

  Title: tmatch
Synonym: tm

   Args: element str, value str
 Return: bool
Example: @persons = grep {$_->tmatch('name', 'fred')} @persons

returns true if the the value of the specified element matches - see previous example in this doc

tmatchhash (tmh)

  Title: tmatchhash
Synonym: tmh

   Args: match hashref
 Return: bool
Example: @persons = grep {$_->tmatchhash({name=>'fred', hair_colour=>'green'})} @persons

returns true if the node matches a set of constraints, specified as hash.

tmatchnode (tmn)

  Title: tmatchnode
Synonym: tmn

   Args: match node
 Return: bool
Example: @persons = grep {$_->tmatchnode([person=>[[name=>'fred'], [hair_colour=>'green']]])} @persons

returns true if the node matches a set of constraints, specified as node

cmatch (cm)

  Title: cmatch
Synonym: cm

   Args: element str, value str
 Return: bool
Example: $n_freds = $personset->cmatch('name', 'fred');

counts the number of matches

where (w)

  Title: where
Synonym: w

   Args: element str, test CODE
 Return: Node[]
Example: @rich_persons = $data->where('person', sub {shift->get_salary > 100000});

the tree is queried for all elements of the specified type that satisfy the coderef (must return a boolean)

my @rich_dog_or_cat_owners =
  $data->where('person',
               sub {my $p = shift;
                    $p->get_salary > 100000 &&
                    $p->where('pet',
                              sub {shift->get_type =~ /(dog|cat)/})});

iterate (i)

       Title: iterate
     Synonym: i

        Args: CODE
      Return: Node[]
     Example: $data->iterate(sub {
				 my $stag = shift;
				 my $parent = shift;
				 if ($stag->element eq 'pet') {
				     $parent->set_pet_name($stag->get_name);
				 }
			     });

iterates through whole tree calling the specified subroutine.

the first arg passed to the subroutine is the stag node representing the tree at that point; the second arg is for the parent.

for instance, the example code above would turn this

(person
 (name "jim")
 (pet
  (name "fluffy")))

into this

(person
 (name "jim")
 (pet_name "fluffy")
 (pet
  (name "fluffy")))

MISCELLANEOUS METHODS

duplicate (d)

  Title: duplicate
Synonym: d

   Args:
 Return: Node
Example: $node2 = $node->duplicate;

does a deep copy of a stag structure

isanode

  Title: isanode

   Args:
 Return: bool
Example: if (stag_isanode($node)) { ... }

hash

  Title: hash

   Args:
 Return: hash
Example: $h = $node->hash;

turns a tree into a hash. all data values will be arrayrefs

pairs

Title: pairs

turns a tree into a hash. all data values will be scalar (IMPORTANT: this means duplicate values will be lost)

write

  Title: write

   Args: filename str, format str[optional]
 Return:
Example: $node->write("myfile.xml");
Example: $node->write("myfile", "itext");

will try and guess the format from the extension if not specified

xml

  Title: xml

   Args: filename str, format str[optional]
 Return:
Example: $node->write("myfile.xml");
Example: $node->write("myfile", "itext");


   Args:
 Return: xml str
Example: print $node->xml;

XML METHODS

sax

  Title: sax

   Args: saxhandler SAX-CLASS
 Return:
Example: $node->sax($mysaxhandler);

turns a tree into a series of SAX events

xpath (xp tree2xpath)

  Title: xpath
Synonym: xp
Synonym: tree2xpath

   Args:
 Return: xpath object
Example: $xp = $node->xpath; $q = $xp->find($xpathquerystr);

xpquery (xpq xpathquery)

  Title: xpquery
Synonym: xpq
Synonym: xpathquery

   Args: xpathquery str
 Return: Node[]
Example: @nodes = $node->xqp($xpathquerystr);

STAG SCRIPTS

The following scripts come with the stag module

stag-autoschema.pl

writes the implicit stag-schema for a stag file

stag-db.pl

persistent storage and retrieval for stag data (xml, sxpr, itext)

stag-diff.pl

finds the difference between two stag files

stag-drawtree.pl

draws a stag file (xml, itext, sxpr) as a PNG diagram

stag-filter.pl

filters a stag file (xml, itext, sxpr) for nodes of interest

stag-findsubtree.pl

finds nodes in a stag file

stag-flatten.pl

turns stag data into a flat table

stag-grep.pl

filters a stag file (xml, itext, sxpr) for nodes of interest

stag-handle.pl

streams a stag file through a handler into a writer

stag-join.pl

joins two stag files together based around common key

stag-mogrify.pl

mangle stag files

stag-parse.pl

parses a file and fires events (e.g. sxpr to xml)

stag-query.pl

aggregare queries

stag-split.pl

splits a stag file (xml, itext, sxpr) into multiple files

stag-splitter.pl

splits a stag file into multiple files

stag-view.pl

draws an expandable Tk tree diagram showing stag data

To get more documentation, type

stag_<script> -h

BUGS

none known so far, possibly quite a few undocumented features!

Not a bug, but the underlying default datastructure of nested arrays is more heavyweight than it needs to be. More lightweight implementations are possible. Some time I will write a C implementation.

WEBSITE

http://stag.sourceforge.net

WEBSITE

http://stag.sourceforge.net

AUTHOR

Chris Mungall <cjm AT fruitfly DOT org>

COPYRIGHT

Copyright (c) 2004 Chris Mungall

This module is free software. You may distribute this module under the same terms as perl itself