Bio::Phylo::Manual - Bio::Phylo user guide.


This is the manual for Bio::Phylo. Bio::Phylo is a perl5 package for phylogenetic analysis. For installation instructions, read the README file in the root directory of the distribution. The stable URL for the most recent distribution is

More documentation can be found as embedded perldoc in the classes of this release. Note that Bio::Phylo uses inheritance to a great extent, such that any one object may inherit additional methods from a number of superclasses. In such cases, this will be noted in the "SEE ALSO" section of that class's documentation. The Bio::Phylo documentation system rewards the methodical reader who follows these document links.


The following sections will demonstrate some of the basic functionality, with immediate, useful results.


One-liners are commands run immediately from the command line, using the -e '...command...' switch, invoking the interpreter directly. Often, you'll include the -MFoo::Bar switch to include Foo::Bar at runtime. (See perlrun for more info on executing the interpreter.) NOTE FOR WINDOWS USERS: in the following examples, switch the quotes around, i.e. use double quotes where single quotes are used and vice versa.

First steps

No concept is valid in Perl if it cannot be expressed in a one-liner. For the Bio::Phylo package, some operations can be performed using a single expression from the command line. This is a rather long one-liner, but it serves to demonstrate.

 perl -MBio::Phylo::IO=parse -e 'print \

The -MModule switch includes a module the way you would use use Module; in a script. Here we use the Bio::Phylo::IO module, which is Bio::Phylo's entry point into file parsing and file writing.

The -e switch is used to evaluate the subsequent expression. We parse a string, ((A,B),C);, of format newick. The parser returns a Bio::Phylo::Forest object (i.e. a set of trees, in this case a set of one). From this set we retrieve the first (and only) tree, and calculate Colless' imbalance, which returns a number, which we print to standard out. This would print "1", because the tree is a ladder, and therefore completely unbalanced.

Sets of trees

You want a one-liner to iterate over a set of trees:

 perl -MBio::Phylo::IO=parse -lne 'print \
 parse(-format=>"newick",-string=>$_)->first->calc_i2' <file>

The -n switch wraps a while(<) { ... }> around the program, so the trees from file (that is, if they are one newick tree description per line) are copied into $_ one tree at a time. The -l switch appends a line break to the printed output.

Stringifying trees

You don't want a number printed to STDOUT, you want a tree:

 perl -MBio::Phylo::IO=parse -e 'print \

If you try to print a tree object, what's written is something like Bio::Phylo::Forest::Tree=SCALAR(0x1a337dc) (that is, the memory address that the object references). This is probably not what you want, so the tree object has a $tree-to_newick> method that stringifies the object to a newick string. Likewise, matrices can write a simple nexus data block using $matrix-to_nexus>.


The Bio::Phylo::IO module is the unified front end for parsing and unparsing phylogenetic data objects. It is a non-OO module that optionally exports the parse and unparse subroutines into the caller's namespace, using the use Bio::Phylo::IO qw(parse unparse); directive. Alternatively, you can call the subroutines as class methods. The parse and unparse subroutines load and dispatch the appropriate sub-modules at runtime, depending on the -format argument.

Parsing trees

You want to create a Bio::Phylo::Forest::Tree object from a newick string.

 use Bio::Phylo::IO;

 # get a newick string from some source
 my $tree_string = '(((A,B),C),D);';

 # Call class method parse from Bio::Phylo::IO
 my $tree = Bio::Phylo::IO->parse(
    -string => $tree_string,
    -format => 'newick'

 # note: newick parser returns 'Bio::Phylo::Forest'
 # Call ->first to retrieve the first tree of the forest.

 print ref $tree, "\n"; # prints 'Bio::Phylo::Forest::Tree'

The Bio::Phylo::IO module invokes specific parser modules. It is essentially the front door for the parsers. In the solution the Bio::Phylo::Parsers::Newick parser turns a tree description into a Bio::Phylo::Forest object.

The returned forest object subclasses Bio::Phylo::Listable, as a forest models a list of trees that you can iterate over. By calling the -first> method, we get the first tree in the forest - a Bio::Phylo::Forest::Tree object (in the example it's a very small forest, consisting of just this single tree).

Parsing tables

You want to create a Bio::Phylo::Matrices::Matrix object from a string.

 use Bio::Phylo::IO;

 # parsing a table
 my $table_string = qq(A,1,2|B,1,2|C,2,2|D,2,1);
 my $matrix = Bio::Phylo::IO->parse(
    -string   => $table_string,
    -format   => 'table',     # See Bio::Phylo::Parsers::Table
    -type     => 'STANDARD',  # Data type
    -fieldsep => ',',         # field separator
    -linesep  => '|'          # line separator

 print ref $matrix, "\n"; # prints 'Bio::Phylo::Matrices::Matrix'

Here the Bio::Phylo::Parsers::Table module parses a string A,1,2|B,1,2|C,2,2|D,2,1, where the | is considered a record or line separator, and the , as a field separator. The default field and line separators are the tabstop character "\t" and the line break "\n".

Parsing taxa

You want to create a Bio::Phylo::Taxa object from a string.

 use Bio::Phylo::IO;

 # parsing a list of taxa
 my $taxa_string = 'A:B:C:D';
 my $taxa = Bio::Phylo::IO->parse(
    -string   => $taxa_string,
    -format   => 'taxlist',
    -fieldsep => ':'

 print ref $taxa, "\n"; # prints 'Bio::Phylo::Taxa'

Here the Bio::Phylo::Parsers::Taxlist module parses a string A:B:C:D, where the : is considered a field separator. The parser returns a Bio::Phylo::Taxa object. Note that the same result can be obtained by building the taxa object from scratch (a more feasible proposition than building trees or matrices from scratch):

 use Bio::Phylo::Taxa;
 use Bio::Phylo::Taxa::Taxon;

 my $taxa = Bio::Phylo::Taxa->new;
 for ( 'A', 'B', 'C', 'D' ) {
     $taxa->insert( Bio::Phylo::Taxa::Taxon->new( -name => $_ ) );

 print ref $taxa, "\n"; # prints 'Bio::Phylo::Taxa';


The Bio::Phylo::Listable module is the superclass of all container objects. Container objects are objects that contain a set of objects of the same type. For example, a Bio::Phylo::Forest::Tree object is a container for Bio::Phylo::Forest::Node objects. Hence, the Bio::Phylo::Forest::Tree inherits from the Bio::Phylo::Listable class. You can therefore iterate over the nodes in a tree using the methods defined by Bio::Phylo::Listable.

Iterating over trees and nodes.

You want to access trees and nodes contained in a Bio::Phylo::Forest object.

  use Bio::Phylo::IO qw(parse);

  my $string = '((A,B),(C,D));(((A,B),C)D);';
  my $forest = parse( -format => 'newick', -string => $string );

  print ref $forest; # prints 'Bio::Phylo::Forest'

  # access trees in $forest
  foreach my $tree ( @{ $forest->get_entities } ) {
      print ref $tree; # prints 'Bio::Phylo::Forest::Tree';

      # access nodes in $tree
      foreach my $node ( @{ $tree->get_entities } ) {
          print ref $node; # prints 'Bio::Phylo::Forest::Node';


Bio::Phylo::Forest and Bio::Phylo::Forest::Tree are nested subclasses of the iterator class Bio::Phylo::Listable. Nested iterator calls (such as -get_entities>) can be invoked on the objects.

Iterating over taxa.

You want to access the individual taxa in a Bio::Phylo::Taxa object.

 use Bio::Phylo::IO qw(parse);

 my $string = 'A|B|C|D|E|F|G|H';
 my $taxa = parse(
     -string => $string,
     -format => 'taxlist',
     -fieldsep => '|'
 print ref $taxa; # prints 'Bio::Phylo::Taxa';

 while ( my $taxon = $taxa->next ) {
     print ref $taxon; # prints 'Bio::Phylo::Taxa::Taxon'

A Bio::Phylo::Taxa object is a subclass of the Bio::Phylo::Listable class. Hence, you could also call -get_entities> on the taxa object, which returns a reference to an array of taxon objects contained by the taxa object. Note however the shorthand:

 while ( my $taxon = $taxa->next ) { ... }
Iterating over datum objects.

You want to access the datum objects contained by a Bio::Phylo::Matrices::Matrix object.

 use Bio::Phylo::IO;

 # parsing a table
 my $table_string = qq(A,1,2|B,1,2|C,2,2|D,2,1);
 my $matrix = Bio::Phylo::IO->parse(
    -string   => $table_string,
    -format   => 'table',     # See Bio::Phylo::Parsers::Table
    -type     => 'STANDARD',  # Data type
    -fieldsep => ',',         # field separator
    -linesep  => '|'          # line separator

 print ref $matrix, "\n"; # prints 'Bio::Phylo::Matrices::Matrix'

 my $datum = $matrix->get_by_index( 0, -1 );
 print ref $datum; # NOTE: prints 'ARRAY'! 

The Bio::Phylo::Matrices::Matrix object subclasses the Bio::Phylo::Listable object. Hence, its iterator methods are applicable here as well. In the above example, the get_by_index method is used. With a single argument it returns a Bio::Phylo object. With multiple arguments the semantics are nearly identical to array slicing (see perldata), except that an array reference is returned. Bio::Phylo generally passes by reference (see perlref).


The Bio::Phylo::Generator module simulates trees under various models of clade growth.

Generating Yule trees.

Here's how to generate a forest of ten trees with ten tips:

  use Bio::Phylo::Generator;
  my $gen = Bio::Phylo::Generator->new;
  my $trees = $gen->gen_rand_pure_birth(
      -trees => 10,
      -tips  => 10,
      -model => 'yule'
  print ref $trees; # prints 'Bio::Phylo::Forest'
Expected versus randomly drawn waiting times.

The generator object simulates trees under the Yule or the Hey model, returning. The -gen_rand_pure_birth> method call returns branch lengths drawn from the appropriate distribution, while -gen_exp_pure_birth> returns the expected waiting times (e.g. 1/n where n=number of lineages for the Yule model).


Filtering objects by numerical value.

To retrieve, for example, the nodes from a tree that are close to the root, call:

 my @deep_nodes = @{ $tree->get_by_value(
    -value => 'calc_nodes_to_root',
    -le    => 2
 ) };

Which retrieves the nodes no more than 2 ancestors away from the root. Any method that returns a numerical value can be specified with the -value flag. The -le flag specifies that the returned value is less-than-or-equal to 2.

Filtering objects by regular expression.

String values that are returned by objects can be filtered using a compiled regular expression. For example:

 my @lemurs = @{ $tree->get_by_regular_expression(
      -value => 'get_name',
      -match => qr/[Ll]emur_.+$/
 ) };

Retrieves all nodes whose genus name matches Eulemur, Lemur or Hapalemur.


You can create SVG drawings of tree objects using the Bio::Phylo::Treedrawer module:

  use Bio::Phylo::Treedrawers;
  use Bio::Phylo::IO;

  my $treedrawer = Bio::Phylo::Treedrawers->new(
     -width  => 400,
     -height => 600,
     -shape  => 'CURVY',
     -mode   => 'CLADO',
     -format => 'SVG'

  my $tree = Bio::Phylo::IO->parse(
     -format => 'newick',
     -string => '((A,B),C);'


  my $string = $treedrawer->draw;

Read the Bio::Phylo::Treedrawer perldoc for more info.


Generic metadata

You can append generic key/value pairs to any object, by calling $obj-set_generic( 'key' => 'value');>. Subsequently calling $obj-get_generic('key');> returns 'value'. This is a very useful feature in many situations where you may want to attach, for example, results from analyses by outside programs (e.g. likelihood scores) to the tree objects they refer to. Likewise, multiple numbers (e.g. bootstrap values, posteriors, bremer values) can be attached to the same node in this way.


Perl objects

Object-oriented perl is a massive subject. To learn about the basic syntax of OO-perl, the following perldocs might be of interest:


Introduction to OO perl. Read at least this one if you have no experience with OO perl.


Details about perl objects.


Class data.


Advanced objects: "Tom's object-oriented tutorial for perl"


The "Bag'o Object Tricks" (the BOT).

The Bio::Phylo object model

The following sections discuss the nested objects that model phylogenetic information and entities.

The Bio::Phylo root object.

The Bio::Phylo object is never used directly. However, all other objects inherit from it, which means that all objects have getters and setters for their name, description, score. They can all return a globally unique ID, log messages, and keep track of more administrative things such as the version number of the release.

The Bio::Phylo::Forest::* namespace

According to Bio::Phylo, there is a Forest (which is modelled by the Bio::Phylo::Forest object), which contains Bio::Phylo::Forest::Tree objects, which contain Bio::Phylo::Forest::Node objects.

The Bio::Phylo::Forest::Node object

A node 'knows' a couple of things: its name, its branch length (i.e. the length of the branch connecting it and its parent), who its parent is, its next sister (on its right), its previous sister (on the left), its first daughter and its last daughter. Also, a taxon can be specified that the node refers to (this makes most sense when the node is terminal). These properties can be retrieved and modified by methods classified as ACCESSORS and MUTATORS.

From this set of properties follows a number of things which must be either true or false. For example, if a node has no children it is a terminal node. By asking a node whether it "is_terminal", it replies either with true (i.e. 1) or false (undef). Methods such as this are classified as TESTS.

Likewise, based on the properties of an individual node we can perform a query to retrieve nodes related to it. For example, by asking the node to "get_ancestors" it returns a list of its ancestors, being all the nodes and the path from its parent to, and including, the root. These methods are QUERIES.

Lastly, some CALCULATIONS can be performed by the node. By asking the node to "calc_path_to_root" it calculates the sum of the lengths of the branches connecting it and the root. Of course, in order to make all this possible, a node has to exist, so it needs to be constructed. The CONSTRUCTOR is the Bio::Phylo::Node->new() method.

Once a node has served its purpose it can be destroyed. For this purpose there is a DESTRUCTOR, which cleans up once we're done with the node. However, in most cases you don't have to worry about constructing and destroying nodes as this is handled by Bio::Phylo and perl for you.

For a detailed description of all the node methods, their arguments and return values, consult the node documentation, which, after install, can be viewed by issuing the "perldoc Bio::Phylo::Forest::Node" command.

The Bio::Phylo::Forest::Tree object

A tree knows very little. All it really holds is a set of nodes, which are there because of TREE POPULATION, i.e. the process of inserting nodes in the tree. The tree can be queried in a number of ways, for example, we can ask the tree to "get_entities", to which the tree replies with a list of all the nodes it holds. Be advised that this doesn't mean that the nodes are connected in a meaningful way, if at all. The tree doesn't care, the nodes are supposed to know who their parents, sisters, and daughters are. But, we can still get, for example, all the terminal nodes (i.e. the tips) in the tree by retrieving all the nodes in the tree and asking each one of them whether it "is_terminal", discarding the ones that aren't.

Based on the set of nodes the tree holds it can perform calculations, such as "calc_tree_length", which simply means that the tree iterates over all its nodes, summing their branch lengths, and returning the total.

The tree object also has a constructor and a destructor, but normally you don't have to worry about that. All the tree methods can be viewed by issuing the "perldoc Bio::Phylo::Forest::Tree" command.

The Bio::Phylo::Forest object

The object containing all others is the Forest object. It serves merely as a container to hold multiple trees, which are inserted in the Forest object using the "insert()" method, and retrieved using the "get_entities" method. More information can be found in the Bio::Phylo::Forest perldoc page.

The Bio::Phylo::Matrices::* namespace

Objects in the Bio::Phylo::Matrices namespace are used to handle comparative data, as single observations, and in larger container objects.

The Bio::Phylo::Matrices::Datum object

The datum object holds observations of a predefined type, such as molecular data, or continuous character states. The Datum object can be linked to a taxon object, to specify which OTU the observation refers to.

The Bio::Phylo::Matrices::Matrix object

The matrix object is used to aggregate datum objects into a larger, iterator object, which can be accessed using the methods of the Bio::Phylo::Listable class.

The Bio::Phylo::Matrices object

The top level opject in the Bio::Phylo::Matrices namespace is used to contain multiple matrix or alignment objects, again implementing an iterator interface.

The Bio::Phylo::Taxa::* namespace

Sets of taxa are modelled by the Bio::Phylo::Taxa object. It is a container that holds Bio::Phylo::Taxa::Taxon objects. The taxon objects at present provide no other functionality than to serve as a means of crossreferencing nodes in trees, and datum or sequence objects. This, however, is a very important feature. In order to be able to write, for example, files formatted for Mark Pagel's Discrete, Continuous and Multistate programs a taxa object, a matrix and a tree object must be crossreferenced.

The Bio::Phylo::Taxa object

The taxa object is analogous to a taxa block as implemented by Mesquite ( Multiple matrix objects and forests can be linked to a single taxa object, using $taxa-set_matrix( $matrix )>. Conversely, the relationship from matrix to taxa and from forest to taxa is a one-to-one relationship.

The Bio::Phylo::Taxa::Taxon object

Just as forests can be linked to taxa objects, so too can indidividual node and datum objects be linked to individual taxon objects. Again, the taxon can hold references to multiple nodes or multiple datum objects, but conversely there is a one-to-one relationship. There is a constraint on these relationships: a node can only refer to a taxon that belongs to a taxa object that the forest object that contains the node references:

 |FOREST        |  The taxon and node objects can
 |  __________  |  link to each other, because
 | |TREE      | |  their containers do also.
 | |  ______  | |  
 | | |NODE  | | |  
 | | |______| | |  
 | |_____^____| |                 
 |_______|______|              NO!       
      ^  |               ______________  
  ____|__|__            |FOREST 'B'    |  The taxon object 
 |TAXA   |  |           |  __________  |  cannot reference
 |  _____|  |           | |TREE      | |  forest 'A' while
 | |TAXON | |           | |  ______  | |  its container 
 | |______| |           | | |NODE  | | |  references forest
 |__________|           | | |______| | |  'B'. 
                        | |__________| |  
                        |______________|    ______________   
                             ^             |FOREST 'A'    |   
                         ____|_____        |  __________  |  
                        |TAXA      |       | |TREE      | |  
                        |  ______  |       | |  ______  | |  
                        | |TAXON |_|______ |_|_|NODE  | | |  
                        | |______| |       | | |______| | |  
                        |__________|       | |__________| |  

Trying to set the links in the example on the right will result in errors: "Attempt to link X to taxon from wrong block". So what happens if a taxon already links to a node in forest 'A', and you link its enclosing taxa block to forest 'B'? The links at the taxon and node level will be removed, and the link between forest and taxa object will be enforced, yielding the warning "Reset X references from node objects to taxa outside taxa block".


Unlike most other implementations of tree structures (or any other perl objects) the Bio::Phylo objects are truly encapsulated: Most perl objects are hash references, so in most cases you can do $obj-{'key'} = 'value'>. Not so for Bio::Phylo. The objects are implemented as 'InsideOut' objects. How they work exactly is outside of the scope of this document, but the upshot as that the state of an object can only be changed through its methods. This is a feature that helps keep the code base maintainable as this project grows. Also, the way it is implemented is more memory-efficient and faster than the standard approach. The encapsulation forces users of this module to use the documented interfaces of the objects. This, however, is a good thing: as long as the interfaces stay the same, any code using Bio::Phylo will continue to work, regardless of the implementation under the surface.

'Is-a' relationships: Inheritance

The objects in Bio::Phylo are related in various ways. Some objects inherit from superclasses. Hence the object is a special case of the superclass. This has important implications for the API: the documentation for each class only lists the methods defined locally in that class, not the methods of the superclasses. Therefore, many objects can do much more than would seem from their local POD. Always inspect the "SEE ALSO" section of any class's documentation to see if there are superclasses where more functionality might be defined.

'Has-a' relationships

Some objects contain other objects. For example, a Bio::Phylo::Forest::Tree contains Bio::Phylo::Forest::Node objects, a matrix object holds datum objects, and so on. The container objects all behave like Bio::Phylo::Listable objects: you can iterate over them (also recursively). The contains / container relationships implemented by Bio::Phylo are shown below:


      ______________     ________________
     |FOREST        |   |MATRICES        |
     |  __________  |   |  __________    |
     | |TREE      | |   | |MATRIX    |   |
     | |  ______  | |   | |  ______  |   |
     | | |NODE  | | |   | | |DATUM | |   |
     | | |______| | |   | | |______| |   |
     | |__________| |   | |__________|   |
     |______________|   |________________|
     |TAXA      |      
     |  ______  |     
     | |TAXON | |     
     | |______| |    


Named arguments when number of arguments >= 2.

When the number of arguments to a method call exceeds 1, named arguments are used. The order in which the arguments are specified doesn't matter, but the arguments must be all lower case and preceded by a dash:

  use Bio::Phylo::Forest::Tree;

  my $node = Bio::Phylo::Forest::Tree->new(
      -name  => 'PHYLIP_1',
      -score => 123,

Type checking

Argument type is always checked. Numbers are checked for being numbers, names are checked for being sane strings, without '():;,'. Objects are checked for type. Internally, Bio::Phylo never checks type based on class name, for example using $obj-isa('Some::Class')>. Instead, object identity is validated using a system of constants defined in Bio::Phylo::Util::CONSTANT. If Bio::Phylo needs to test validate object type, it'll do something like:

 use Bio::Phylo::Util::CONSTANT qw(:objecttypes);
 use Bio::Phylo::Forest::Node;
 my $node = Bio::Phylo::Forest::Node->new;
 print "It's a node!" if $node->_type == _NODE_;

Hence, Bio::Phylo uses a form of "duck typing" ("if it walks like a duck, and quacks like a duck, it probably is a duck"), as opposed to one that is based on inheritance from a java-like interface, as is the convention in bioperl. Both systems have their advantages and drawbacks, but luckily they can coexist side by without problems.

Constructor arguments

All mutators (i.e. setters, methods called set_*) for a class and its superclasses can be accessed from the constructor. E.g. because the Bio::Phylo superclasses of object Bio::Phylo::Forest::Node has a "set_name" method, you can pass the following to the constructor:

 use Bio::Phylo::Forest::Node;
 my $node = Bio::Phylo::Forest::Node->new( -name => "node1" );


Retun values

Apart from scalar variables, all other return values are passed by reference, either as a reference to an object or to an array.

Lists returned as array references

Multiple return values are never returned as a list, always as an array reference:

 my $nodes = $tree->get_entities;
 print ref $nodes;

 #prints ARRAY.

To receive nodes in @nodes, dereference the returned array reference (for clarity, all array dereferencing in this document is indicated by using braces in addition to this sigil):

 my @nodes = @{ $tree->get_entities };
Returns self on mutators

Mutator method calls always return the modified object, and so they can be chained:

False but defined return values

When a value requested through an Accessor hasn't been set, the return value is undef. Here you should take care how you test. For example:

 if ( ! $node->get_parent ) {
        $root = $node;

This works as expected. $node has no parent, hence it must be the root. However:

 if ( ! $node->get_branch_length ) {

        # is there really no branch length?
        if ( defined $node->get_branch_length ) {

                # perhaps there is, but of length 0.

...warrants caution. Zero is evaluated as false-but-defined.


The Bio::Phylo modules throw exceptions that subclass Exception::Class. Exceptions are thrown when something exceptional has happened. Not when the value requested through an accessor method is undefined. If a node has no parent, undef is returned. Usually, you will encounter exceptions in response to invalid input.

Trying/Catching exceptions

If some method call returns an exception, wrap the call inside an eval block. The error now becomes non-fatal:

 # try something:
 eval { $node->set_branch_length('a bad value'); };

 # handle exception, if any
 if ($@) {
    # do something, e.g.:
    print $@->trace->as_string; # <- $@ is an object!
Stack traces

If an exception of a particular type is caught, you can print a stack trace and find out what might have gone wrong starting from your script drilling into the module code.

 # exception caught.
 if ( UNIVERSAL::isa( $@, 'Bio::Phylo::Util::Exceptions::BadNumber' ) ) {

    # prints stack trace in addition to error
    warn $@->error, "\n, $@->trace->as_string, "\n";

    # further metadata from exception object
    warn join ' ',  $@->euid, $@->egid, $@->uid, $@->gid, $@->pid, $@->time;
Exception types

Several exception classes are defined. The type of the thrown exception should give you a hint as to what might be wrong. The types are specified in the Bio::Phylo::Util::Exceptions perldoc.


Below is a list of things that hopefully will be implemented in future versions of Bio::Phylo.


Change the utility scripts, add to them.

More DNA sequence methods

Such as $seq-complement;>. This would imply larger constant translation tables, including various tables for mtDNA and so on. Will probably be implemented, must likely using BioPerl tools.


Implement access to TreeBase, Pandit, TolWeb and other databases. This could probably be done most elegantly by expanding the mediator system (Bio::Phylo::Mediators::* classes).


Test coverage is reasonable, but some of the newer features need to be exercised more.

Interoperability with BioPerl and CIPRES

The eventual aim of the Bio::Phylo project is to glue together the phylogenetics aspects of BioPerl (, Bio::NEXUS and the CIPRES project ( Refer to the Bio::ObjectCompat document for discussion on this issue.


CPAN hosts a discussion forum for Bio::Phylo. If you have trouble using this module the discussion forum is a good place to start posting questions (NOT bug reports, see below):


Please report any bugs or feature requests to, or through the web interface at I will be notified, and then you'll automatically be notified of progress on your bug as I make changes. If you can localize the bug to particular package file (i.e. a *.pm file from this release), please include the REVISION tag for that file in your bug report. It is a string such as this one:

  $Id: Manual.pod 4213 2007-07-15 03:11:27Z rvosa $


Rutger Vos, Aki Mimoto, Klaas Hartmann, Jason Caravas

web page:


We would like to thank Jason Stajich for many ideas borrowed from BioPerl, and CIPRES and FAB* for comments and requests.


Copyright 2005 Rutger A. Vos, All Rights Reserved. This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself.