t/SeqFeature/Generic.t: fix typo on required module for testing
[bioperl-live.git] / lib / Bio / Species.pm
blob3e7045a667ad31405abca856bf9305ec2f02a4fd
2 # BioPerl module for Bio::Species
4 # Please direct questions and support issues to <bioperl-l@bioperl.org>
6 # Cared for by James Gilbert <jgrg@sanger.ac.uk>
7 # Reimplemented by Sendu Bala <bix@sendu.me.uk>
8 # Re-reimplemented by Chris Fields <cjfields - at - bioperl dot org>
10 # You may distribute this module under the same terms as perl itself
12 # POD documentation - main docs before the code
14 =head1 NAME
16 Bio::Species - Generic species object.
18 =head1 SYNOPSIS
20 $species = Bio::Species->new(-classification => [@classification]);
21 # Can also pass classification
22 # array to new as below
24 $species->classification(qw( sapiens Homo Hominidae
25 Catarrhini Primates Eutheria
26 Mammalia Vertebrata Chordata
27 Metazoa Eukaryota ));
29 $genus = $species->genus();
31 $bi = $species->binomial(); # $bi is now "Homo sapiens"
33 # For storing common name
34 $species->common_name("human");
36 # For storing subspecies
37 $species->sub_species("accountant");
39 =head1 DESCRIPTION
41 B<NOTE: This class is planned for deprecation in favor of the simpler Bio::Taxon.
42 Please use that class instead.>
44 Provides a very simple object for storing phylogenetic information. The
45 classification is stored in an array, which is a list of nodes in a phylogenetic
46 tree. Access to getting and setting species and genus is provided, but not to
47 any of the other node types (eg: "phylum", "class", "order", "family"). There's
48 plenty of scope for making the model more sophisticated, if this is ever needed.
50 A methods are also provided for storing common names, and subspecies.
52 =head1 FEEDBACK
54 =head2 Mailing Lists
56 User feedback is an integral part of the evolution of this and other
57 Bioperl modules. Send your comments and suggestions preferably to
58 the Bioperl mailing list. Your participation is much appreciated.
60 bioperl-l@bioperl.org - General discussion
61 http://bioperl.org/wiki/Mailing_lists - About the mailing lists
63 =head2 Support
65 Please direct usage questions or support issues to the mailing list:
67 I<bioperl-l@bioperl.org>
69 rather than to the module maintainer directly. Many experienced and
70 reponsive experts will be able look at the problem and quickly
71 address it. Please include a thorough description of the problem
72 with code and data examples if at all possible.
74 =head2 Reporting Bugs
76 Report bugs to the Bioperl bug tracking system to help us keep track
77 of the bugs and their resolution. Bug reports can be submitted via the
78 web:
80 https://github.com/bioperl/bioperl-live/issues
82 =head1 AUTHOR
84 James Gilbert email B<jgrg@sanger.ac.uk>
86 =head1 CONTRIBUTORS
88 Sendu Bala, bix@sendu.me.uk
89 Chris Fields, cjfields at bioperl dot org
91 =head1 APPENDIX
93 The rest of the documentation details each of the object
94 methods. Internal methods are usually preceded with a _
96 =cut
98 #' Let the code begin...
100 package Bio::Species;
101 use strict;
102 use warnings;
104 use Bio::DB::Taxonomy;
105 use Bio::Tree::Tree;
106 use Bio::Taxon;
107 use base qw(Bio::Root::Root Bio::Tree::NodeI);
109 =head2 new
111 Title : new
112 Usage : my $obj = Bio::Species->new(-classification => \@class)
113 Function: Build a new Species object
114 Returns : Bio::Species object
115 Args : -ncbi_taxid => NCBI taxonomic ID (optional)
116 -classification => arrayref of classification
118 =cut
120 sub new {
121 my($class, @args) = @_;
123 my $self = $class->SUPER::new(@args);
125 # Bio::Species is now just a proxy object that just observes the NodeI
126 # interface methods but delegates them to the proper classes (Bio::Taxon and
127 # Bio::Tree::Tree). This will be surplanted by the much simpler
128 # Bio::Taxon/Bio::DB::Taxonomy modules in the future.
130 # Using a proxy allows proper GC w/o using weaken(). This just wraps the
131 # older instances, which have no reciprocal refs (thus no circular refs).
132 # This can then run proper cleanup
134 $self->taxon(Bio::Taxon->new(@args));
136 my ($org, $sp, $var, $classification) =
137 $self->_rearrange([qw(ORGANELLE
138 SUB_SPECIES
139 VARIANT
140 CLASSIFICATION)], @args);
142 if (defined $classification && ref($classification) eq "ARRAY" && @{$classification}) {
143 $self->classification(@$classification);
145 else {
146 $self->tree(Bio::Tree::Tree->new());
149 defined $org && $self->organelle($org);
150 defined $sp && $self->sub_species($sp);
151 defined $var && $self->variant($var);
153 return $self;
156 =head2 classification
158 Title : classification
159 Usage : $self->classification(@class_array);
160 @classification = $self->classification();
161 Function: Get/set the lineage of this species. The array provided must be in
162 the order ... ---> SPECIES, GENUS ---> KINGDOM ---> etc.
163 Example : $obj->classification(qw( 'Homo sapiens' Homo Hominidae
164 Catarrhini Primates Eutheria Mammalia Vertebrata
165 Chordata Metazoa Eukaryota));
166 Returns : Classification array
167 Args : Classification array
169 A reference to the classification array. In the latter case
170 if there is a second argument and it evaluates to true,
171 names will not be validated. NB: in any case, names are never
172 validated anyway.
174 =cut
176 sub classification {
177 my ($self, @vals) = @_;
179 my $taxon = $self->taxon;
181 if (@vals) {
182 if (ref($vals[0]) eq 'ARRAY') {
183 @vals = @{$vals[0]};
186 $vals[1] ||= '';
187 # make sure the lineage contains us as first or second element
188 # (lineage may have subspecies, species, genus ...)
189 my $name = $taxon->node_name;
190 my ($genus, $species) = (quotemeta($vals[1]), quotemeta($vals[0]));
191 if ($name &&
192 ($name !~ m{$species}i && $name !~ m{$genus}i) &&
193 $name !~ m{$genus $species}i) {
194 if ($name =~ /^$genus $species\s*(.+)/) {
195 # just assume the problem is someone tried to make a Bio::Species starting at subspecies
196 #*** no idea if this is appropriate! just a possible fix related to bug 2092
197 $self->sub_species($1);
198 $name = $taxon->node_name("$vals[1] $vals[0]");
200 else {
201 $self->warn("The supplied lineage does not start near '$name' (I was supplied '".join(" | ", @vals)."')");
205 # create a lineage for ourselves
206 my $db = Bio::DB::Taxonomy->new(-source => 'list', -names => [reverse @vals]);
207 unless ($taxon->scientific_name) {
208 # assume we're supposed to be the leaf of the supplied lineage
209 $self->taxon->scientific_name($vals[0]);
211 unless ($taxon->rank) {
212 # and that we are rank species
213 $taxon->rank('species');
216 $taxon->db_handle($db);
218 $self->tree(Bio::Tree::Tree->new(-node => $taxon));
221 @vals = ();
222 foreach my $node ($self->tree->get_lineage_nodes($taxon), $taxon) {
223 unshift(@vals, $node->scientific_name || next);
225 return @vals;
228 =head2 ncbi_taxid
230 Title : ncbi_taxid
231 Usage : $obj->ncbi_taxid($newval)
232 Function: Get/set the NCBI Taxon ID
233 Returns : the NCBI Taxon ID as a string
234 Args : newvalue to set or undef to unset (optional)
236 =cut
238 =head2 common_name
240 Title : common_name
241 Usage : $self->common_name( $common_name );
242 $common_name = $self->common_name();
243 Function: Get or set the common name of the species
244 Example : $self->common_name('human')
245 Returns : The common name in a string
246 Args : String, which is the common name (optional)
248 =cut
250 =head2 division
252 Title : division
253 Usage : $obj->division($newval)
254 Function: Genbank Division for a species
255 Returns : value of division (a scalar)
256 Args : value of division (a scalar)
258 =cut
260 =head2 species
262 Title : species
263 Usage : $self->species( $species );
264 $species = $self->species();
265 Function: Get or set the species name.
266 Note that this is NOT genus and species
267 -- use $self->binomial() for that.
268 Example : $self->species('sapiens');
269 Returns : species name as string (NOT genus and species)
270 Args : species name as string (NOT genus and species)
272 =cut
274 sub species {
275 my ($self, $species) = @_;
277 if ($species) {
278 $self->{_species} = $species;
281 unless (defined $self->{_species}) {
282 # work it out from our nodes
283 my $species_taxon = $self->tree->find_node(-rank => 'species');
284 unless ($species_taxon) {
285 # just assume we are rank species
286 $species_taxon = $self->taxon;
289 $species = $species_taxon->scientific_name;
292 # munge it like the Bio::SeqIO modules used to do
293 # (more or less copy/pasted from old Bio::SeqIO::genbank, hence comments
294 # referring to 'ORGANISM' etc.)
297 my $root = $self->tree->get_root_node;
298 unless ($root) {
299 $self->tree(Bio::Tree::Tree->new(-node => $species_taxon));
300 $root = $self->tree->get_root_node;
303 my @spflds = split(' ', $species);
304 if (@spflds > 1 && $root->node_name ne 'Viruses') {
305 $species = undef;
307 # does the next term start with uppercase?
308 # yes: valid genus; no then unconventional
309 # e.g. leaf litter basidiomycete sp. Collb2-39
310 my $genus;
311 if ($spflds[0] =~ m/^[A-Z]/) {
312 $genus = shift(@spflds);
314 else {
315 undef $genus;
318 my $sub_species;
319 if (@spflds) {
320 while (my $fld = shift @spflds) {
321 $species .= "$fld ";
322 # does it have subspecies or varieties?
323 last if ($fld =~ m/(sp\.|var\.)/);
325 chop $species; # last space
326 $sub_species = join ' ',@spflds if(@spflds);
328 else {
329 $species = 'sp.';
332 # does ORGANISM start with any words which make its genus undefined?
333 # these are in @unkn_genus
334 # this in case species starts with uppercase so isn't caught above.
335 # alter common name if required
336 my $unconv = 0; # is it unconventional species name?
337 my @unkn_genus = ('unknown','unclassified','uncultured','unidentified');
338 foreach (@unkn_genus) {
339 if ($genus && $genus =~ m/$_/i) {
340 $species = $genus . " " . $species;
341 undef $genus;
342 $unconv = 1;
343 last;
345 elsif ($species =~ m/$_/i) {
346 $unconv = 1;
347 last;
350 if (!$unconv && !$sub_species && $species =~ s/^(\w+)\s(\w+)$/$1/) {
351 # need to extract subspecies from conventional ORGANISM format.
352 # Will the 'word' in a two element species name
353 # e.g. $species = 'thummi thummi' => $species='thummi' &
354 # $sub_species='thummi'
355 $sub_species = $2;
358 $self->genus($genus) if $genus;
359 $self->sub_species($sub_species) if $sub_species;
362 $self->{_species} = $species;
364 return $self->{_species};
367 =head2 genus
369 Title : genus
370 Usage : $self->genus( $genus );
371 $genus = $self->genus();
372 Function: Get or set the scientific genus name.
373 Example : $self->genus('Homo');
374 Returns : Scientific genus name as string
375 Args : Scientific genus name as string
377 =cut
379 sub genus {
380 my ($self, $genus) = @_;
382 # TODO: instead of caching the raw name, cache the actual node instance.
383 if ($genus) {
384 $self->{_genus} = $genus;
386 unless (defined $self->{_genus}) {
387 my $genus_taxon = $self->tree->find_node(-rank => 'genus');
388 unless ($genus_taxon) {
389 # just assume our ancestor is rank genus
390 $genus_taxon = $self->taxon->ancestor;
393 $self->{_genus} = $genus_taxon->scientific_name if $genus_taxon;
396 return $self->{_genus};
399 =head2 sub_species
401 Title : sub_species
402 Usage : $obj->sub_species($newval)
403 Function: Get or set the scientific subspecies name.
404 Returns : value of sub_species
405 Args : newvalue (optional)
407 =cut
409 sub sub_species {
410 my ($self, $sub) = @_;
412 # TODO: instead of caching the raw name, cache the actual node instance.
413 if (!defined $self->{'_sub_species'}) {
414 my $ss_taxon = $self->tree->find_node(-rank => 'subspecies');
415 if ($ss_taxon) {
416 if ($sub) {
417 $ss_taxon->scientific_name($sub);
419 # *** weakening ref to our root node in species() to solve a
420 # memory leak means that we have a subspecies taxon to set
421 # during the first call to species(), but it has vanished by
422 # the time a user subsequently calls sub_species() to get the
423 # value. So we 'cheat' and just store the subspecies name in
424 # our self hash, instead of the tree. Is this a problem for
425 # a Species object? Can't decide --sendu
427 # This can now be changed to deal with this information on the
428 # fly. For now, the caching remains, but maybe we should just
429 # let these things deal with mutable data as needed? -- cjfields
431 $self->{'_sub_species'} = $sub;
433 return $ss_taxon->scientific_name;
435 else {
436 # should we create a node here to be added to the tree?
440 # fall back to direct storage on self
441 $self->{'_sub_species'} = $sub if $sub;
442 return $self->{'_sub_species'};
445 =head2 variant
447 Title : variant
448 Usage : $obj->variant($newval)
449 Function: Get/set variant information for this species object (strain,
450 isolate, etc).
451 Example :
452 Returns : value of variant (a scalar)
453 Args : new value (a scalar or undef, optional)
455 =cut
457 sub variant{
458 my ($self, $var) = @_;
460 # TODO: instead of caching the raw name, cache the actual node instance.
461 if (!defined $self->{'_variant'}) {
462 my $var_taxon = $self->tree->find_node(-rank => 'variant');
463 if ($var_taxon) {
464 if ($var) {
465 $var_taxon->scientific_name($var);
467 return $var_taxon->scientific_name;
469 else {
470 # should we create a node here to be added to the tree?
474 # fall back to direct storage on self
475 $self->{'_variant'} = $var if $var;
476 return $self->{'_variant'};
479 =head2 binomial
481 Title : binomial
482 Usage : $binomial = $self->binomial();
483 $binomial = $self->binomial('FULL');
484 Function: Returns a string "Genus species", or "Genus species subspecies",
485 if the first argument is 'FULL' (and the species has a subspecies).
486 Args : Optionally the string 'FULL' to get the full name including
487 the subspecies.
488 Note : This is just munged from the taxon() name
490 =cut
492 sub binomial {
493 my ($self, $full) = @_;
494 my $rank = $self->taxon->rank || 'no rank';
496 my ($species, $genus) = ($self->species, $self->genus);
497 unless (defined $species) {
498 $species = 'sp.';
499 $self->warn("requested binomial but classification was not set");
501 $genus = '' unless( defined $genus);
503 $species =~ s/$genus\s+//;
505 my $bi = "$genus $species";
506 if (defined($full) && $full =~ /full/i) {
507 my $ssp = $self->sub_species;
508 if ($ssp) {
509 $ssp =~ s/$bi\s+//;
510 $ssp =~ s/$species\s+//;
511 $bi .= " $ssp";
514 return $bi;
517 =head2 validate_species_name
519 Title : validate_species_name
520 Usage : $result = $self->validate_species_name($string);
521 Function: Validate the species portion of the binomial
522 Args : string
523 Notes : The string following the "genus name" in the NCBI binomial is so
524 variable that it's not clear that this is a useful function. Consider
525 the binomials "Simian 11 rotavirus (serotype 3 / strain
526 SA11-Patton)", or "St. Thomas 3 rotavirus", straight from GenBank.
527 This is particularly problematic in microbes and viruses. As such,
528 this isn't actually used automatically by any Bio::Species method.
530 =cut
532 sub validate_species_name {
533 my( $self, $string ) = @_;
535 return 1 if $string eq "sp.";
536 return 1 if $string =~ /strain/;
537 return 1 if $string =~ /^[a-z][\w\s-]+$/i;
538 $self->throw("Invalid species name '$string'");
541 sub validate_name {
542 return 1;
545 =head2 organelle
547 Title : organelle
548 Usage : $self->organelle( $organelle );
549 $organelle = $self->organelle();
550 Function: Get or set the organelle name
551 Example : $self->organelle('Chloroplast')
552 Returns : The organelle name in a string
553 Args : String, which is the organelle name
554 Note : TODO: We currently do not know where the organelle definition will
555 eventually go. This is stored in the source seqfeature, though,
556 so the information isn't lost.
558 =cut
560 sub organelle {
561 my($self) = shift;
562 return $self->{'_organelle'} = shift if @_;
563 return $self->{'_organelle'};
566 =head2 Delegation
568 The following methods delegate to the internal Bio::Taxon instance. This is
569 mainly to allow code continue using older methods, with the mind to migrate to
570 using Bio::Taxon and related methods when this class is deprecated.
572 =cut
574 sub node_name {shift->taxon->node_name(@_)}
575 sub scientific_name {shift->taxon->node_name(@_)}
577 sub id {shift->taxon->id(@_)}
578 sub object_id {shift->taxon->id(@_)}
579 sub ncbi_taxid {shift->taxon->ncbi_taxid(@_)}
580 sub rank {shift->taxon->rank(@_)}
581 sub division {shift->taxon->division(@_)}
583 sub common_names {shift->taxon->common_names(@_)}
584 sub common_name {shift->taxon->common_names(@_)}
586 sub genetic_code {shift->taxon->genetic_code(@_)}
587 sub mitochondrial_genetic_code {shift->taxon->mitochondrial_genetic_code(@_)}
589 sub create_date { shift->taxon->create_date(@_)}
590 sub pub_date { shift->taxon->pub_date(@_)}
591 sub update_date { shift->taxon->update_date(@_)}
593 sub db_handle { shift->taxon->db_handle(@_)}
595 sub parent_id { shift->taxon->parent_id(@_)}
596 sub parent_taxon_id { shift->taxon->parent_id(@_)}
598 sub version { shift->taxon->version(@_)}
599 sub authority { shift->taxon->authority(@_)}
600 sub namespace { shift->taxon->namespace(@_)}
602 sub ancestor { shift->taxon->ancestor(@_)}
603 sub get_Parent_Node { shift->taxon->get_Parent_Node(@_)}
604 sub each_Descendent { shift->taxon->each_Descendent(@_)}
605 sub get_Children_Nodes { shift->taxon->get_Children_Nodes(@_)}
606 sub remove_Descendant { shift->taxon->remove_Descendant(@_)}
608 sub name { shift->taxon->name(@_)}
610 =head2 taxon
612 Title : taxon
613 Usage : $obj->taxon
614 Function : retrieve the internal Bio::Taxon instance
615 Returns : A Bio::Taxon. If one is not previously set,
616 an instance is created lazily
617 Args : Bio::Taxon (optional)
619 =cut
621 sub taxon {
622 my ($self, $taxon) = @_;
623 if (!$self->{taxon} || $taxon) {
624 $taxon ||= Bio::Taxon->new();
625 $self->{taxon} = $taxon;
627 $self->{taxon};
630 =head2 tree
632 Title : tree
633 Usage : $obj->tree
634 Function : Returns a Bio::Tree::Tree object
635 Returns : A Bio::Tree::Tree. If one is not previously set,
636 an instance is created lazily
637 Args : Bio::Tree::Tree (optional)
639 =cut
641 sub tree {
642 my ($self, $tree) = @_;
643 if (!$self->{tree} || $tree) {
644 $tree ||= Bio::Tree::Tree->new();
645 delete $tree->{_root_cleanup_methods};
646 $self->{tree} = $tree;
648 $self->{tree};
651 sub DESTROY {
652 my $self = shift;
653 $self->tree->cleanup_tree;
654 delete $self->{tree};
655 $self->taxon->node_cleanup;