File Coverage

blib/lib/Bio/Tools/Run/TigrAssembler.pm

Criterion	Covered	Total	%
statement	17	65	26.1
branch	2	20	10.0
condition	0	3	0.0
subroutine	4	6	66.6
pod	1	1	100.0
total	24	95	25.2

line	stmt	bran	cond	sub	pod	time	code
1							# BioPerl module for Bio::Tools::Run::TigrAssembler
2							#
3							# Copyright Florent E Angly
4							#
5							# You may distribute this module under the same terms as perl itself
6							#
7							# POD documentation - main docs before the code
8
9							=head1 NAME
10
11							Bio::Tools::Run::TigrAssembler - Wrapper for local execution of TIGR Assembler
12							v2
13
14							=head1 SYNOPSIS
15
16							use Bio::Tools::Run::TigrAssembler;
17							# Run TIGR Assembler using an input FASTA file
18							my $factory = Bio::Tools::Run::TigrAssembler->new( -minimum_overlap_length => 35 );
19							my $asm_obj = $factory->run($fasta_file, $qual_file);
20							# An assembly object is returned by default
21							for my $contig ($assembly->all_contigs) {
22							... do something ...
23							}
24
25							# Read some sequences
26							use Bio::SeqIO;
27							my $sio = Bio::SeqIO->new(-file => $fasta_file, -format => 'fasta');
28							my @seqs;
29							while (my $seq = $sio->next_seq()) {
30							push @seqs,$seq;
31							}
32
33							# Run TIGR Assembler with input sequence objects and return an assembly file
34							my $asm_file = 'results.tigr';
35							$factory->out_type($asm_file);
36							$factory->run(\@seqs);
37
38							# Use LIGR Assembler instead
39							my $ligr = Bio::Tools::Run::TigrAssembler->new(
40							-program_name => 'LIGR_Assembler',
41							-trimmed_seq => 1
42							);
43							$ligr->run(\@seqs);
44
45							=head1 DESCRIPTION
46
47							Wrapper module for the local execution of the DNA assembly program TIGR
48							Assembler v2.0. TIGR Assembler is open source software under The Artistic
49							License and available at: http://www.tigr.org/software/assembler/
50
51							This module runs TIGR Assembler by feeding it a FASTA file or sequence objects
52							and returning an assembly file or assembly and IO objects. When the input is
53							Bioperl object, sequences less than 39 bp long are filtered out since they are
54							not supported by TIGR Assembler.
55
56							If provided in the following way, TIGR Assembler will use additional
57							information present in the sequence descriptions for assembly:
58							>seq_name minimum_clone_length maximum_clone_length median_clone_length
59							clear_end5 clear_end3
60							or
61							>db\|seq_name minimum_clone_length maximum_clone_length median_clone_length
62							clear_end5 clear_end3
63							e.g.
64							>GHIBF57F 500 3000 1750 33 587
65
66							This module also supports LIGR Assembler, a variant of TIGR Assembler:
67							http://sourceforge.net/projects/ligr-assembler/
68
69							=head1 FEEDBACK
70
71							=head2 Mailing Lists
72
73							User feedback is an integral part of the evolution of this and other Bioperl
74							modules. Send your comments and suggestions preferably to one of the Bioperl
75							mailing lists. Your participation is much appreciated.
76
77							bioperl-l@bioperl.org - General discussion
78							http://bioperl.org/wiki/Mailing_lists - About the mailing lists
79
80							=head2 Support
81
82							Please direct usage questions or support issues to the mailing list:
83
84							I
85
86							rather than to the module maintainer directly. Many experienced and
87							reponsive experts will be able look at the problem and quickly
88							address it. Please include a thorough description of the problem
89							with code and data examples if at all possible.
90
91							=head2 Reporting Bugs
92
93							Report bugs to the Bioperl bug tracking system to help us keep track the bugs
94							and their resolution. Bug reports can be submitted via the web:
95
96							http://redmine.open-bio.org/projects/bioperl/
97
98							=head1 AUTHOR - Florent E Angly
99
100							Email: florent-dot-angly-at-gmail-dot-com
101
102							=head1 APPENDIX
103
104							The rest of the documentation details each of the object methods. Internal
105							methods are usually preceded with a _
106
107							=cut
108
109
110							package Bio::Tools::Run::TigrAssembler;
111
112	1			1		130566	use strict;
	1					2
	1					25
113	1			1		5	use IPC::Run;
	1					2
	1					34
114
115	1			1		5	use base qw( Bio::Root::Root Bio::Tools::Run::AssemblerBase );
	1					2
	1					296
116
117							our $program_name = 'TIGR_Assembler'; # name of the executable
118							our @program_params = (qw( minimum_percent minimum_length max_err_32 quality_file
119							maximum_end resort_after ));
120							our @program_switches = (qw( include_singlets consider_low_scores safe_merging_stop
121							ignore_tandem_32mers use_tandem_32mers not_random incl_bad_seq trimmed_seq ));
122							our %param_translation = (
123							'quality_file' => 'q',
124							'minimum_percent' => 'p',
125							'minimum_length' => 'l',
126							'include_singlets' => 's',
127							'max_err_32' => 'g',
128							'consider_low_scores' => 'L',
129							'maximum_end' => 'e',
130							'ignore_tandem_32mers' => 't',
131							'use_tandem_32mers' => 'u',
132							'safe_merging_stop' => 'X',
133							'not_random' => 'N',
134							'resort_after' => 'r',
135							'incl_bad_seq' => 'b',
136							'trimmed_seq' => 'i'
137							);
138							our $qual_param = 'quality_file';
139							our $use_dash = 1;
140							our $join = ' ';
141							our $asm_format = 'tigr';
142							our $min_len = 39;
143
144
145							=head2 new
146
147							Title : new
148							Usage : $factory->new( -minimum_percent => 95,
149							-minimum_length => 50,
150							-include_singlets => 1 );
151							Function: Create a TIGR Assembler factory
152							Returns : A Bio::Tools::Run::TigrAssembler object
153							Args :
154
155							TIGR Assembler options available in this module:
156
157							minimum_percent / minimum_overlap_similarity: the minimum percent identity
158							that two DNA fragments must achieve over their entire region of overlap in
159							order to be considered as a possible assembly. Adjustments are made by the
160							program to take into account that the ends of sequences are lower quality
161							and doubled base calls are the most frequent sequencing error.
162							minimum_length / minimum_overlap_length: the minimum length two DNA fragments
163							must overlap to be considered as a possible assembly (warning: this option
164							is not strictly respected by TIGR Assembler...)
165							include_singlets: a flag which indicates that singletons (assemblies made up
166							of a single DNA fragment) should be included in the lassie output_file - the
167							default is to not include singletons.
168							max_err_32: the maximum number + 1 of alignment errors (mismatches or gaps)
169							allowed within any contiguous 32 base pairs in the overlap region between
170							two DNA fragments in the same assembly. This is meant to split apart splice
171							variants which have short splice differences and would not be disqualified
172							by the -p minimum_percent parameter.
173							consider_low_scores: a flag which causes even very LOW pairwise scores to be
174							considered - caution using this flag may cause longer run time and a worse
175							assembly.
176							maximum_end: the maximum length at the end of a DNA fragment that does not
177							match another overlapping DNA fragment (sometimes referred to as overhang)
178							that will not disqualify a DNA fragment from becoming part of an assembly.
179							ignore_tandem_32mers: a flag which causes tandem 32mers (a tandem 32mer is a
180							32mer which occurs more than once in at least one sequence read) to be
181							ignored (this is now the default behavior and this flag is for backward
182							compatibility)
183							use_tandem_32mers: a flag which causes tandem 32mers to be used for pairwise
184							comparison opposite of the -t flag which is now the default).
185							safe_merging_stop: a flag which causes merging to stop when only sequences
186							which appear to be repeats are left and these cannot be merged based on
187							clone length constraints.
188							not_random: a flag which indicates that the DNA fragments in the input_file
189							should not be treated as random genomic fragments for the purpose of
190							determining repeat regions.
191							resort_after: specifies how many sequences should be merged before resorting
192							the possible merges based on clone constraints.
193
194							LIGR Assembler has the same options as TIGR Assembler, and the following:
195
196							incl_bad_seq: keep all sequences including potential chimeras and splice variants
197							trimmed_seq: indicates that the sequences are trimmed. High quality scores will be
198							given on the whole sequence length instead of just in the middle)
199
200							=cut
201
202							sub new {
203	2			2	1	17226	my ($class,@args) = @_;
204	2					20	my $self = $class->SUPER::new(@args);
205	2					70	$self->_set_program_options(\@args, \@program_params, \@program_switches,
206							\%param_translation, $qual_param, $use_dash, $join);
207	2					7	*minimum_overlap_length = \&minimum_length;
208	2					5	*minimum_overlap_similarity = \&minimum_percent;
209	2	100				7	$self->program_name($program_name) if not defined $self->program_name();
210	2					13	$self->_assembly_format($asm_format);
211	2					18	return $self;
212							}
213
214
215							=head2 out_type
216
217							Title : out_type
218							Usage : $factory->out_type('Bio::Assembly::ScaffoldI')
219							Function: Get/set the desired type of output
220							Returns : The type of results to return
221							Args : Desired type of results to return (optional):
222							'Bio::Assembly::IO' object
223							'Bio::Assembly::ScaffoldI' object (default)
224							The name of a file to save the results in
225
226							=cut
227
228
229							=head2 run
230
231							Title : run
232							Usage : $factory->run($fasta_file);
233							Function: Run TIGR Assembler
234							Returns : - a Bio::Assembly::ScaffoldI object, a Bio::Assembly::IO
235							object, a filename, or undef if all sequences were too small to
236							be usable
237							Returns : Assembly results (file, IO object or assembly object)
238							Args : - sequence input (FASTA file or sequence object arrayref)
239							- optional quality score input (QUAL file or quality score object
240							arrayref)
241							=cut
242
243
244							=head2 _run
245
246							Title : _run
247							Usage : $assembler->_run()
248							Function: Make a system call and run Newbler
249							Returns : An assembly file
250							Args : - FASTA file, SFF file and MID, or analysis dir and MID
251							- optional QUAL file
252
253							=cut
254
255							sub _run {
256	0			0			my ($self, $fasta_file, $qual_file) = @_;
257
258							# Setup needed files and filehandles first
259	0						my ($output_fh, $output_file ) = $self->_prepare_output_file( );
260	0						my ($scratch_fh, $scratch_file) = $self->io->tempfile( -dir => $self->tempdir() );
261	0						my ($stderr_fh, $stderr_file ) = $self->io->tempfile( -dir => $self->tempdir() );
262
263							# Get program executable
264	0						my $exe = $self->executable;
265
266							# Get command-line options
267	0						my $options = $self->_translate_params();
268
269							# Usage: TIGR_Assembler [options] scratch_file < input_file > output_file
270	0						my @program_args = ( $exe, @$options, $scratch_file );
271	0						my $stdin = $fasta_file;
272	0						my $stdout = $output_file;
273	0						my $stderr = $stderr_file;
274
275	0						my @ipc_args = ( \@program_args,
276							'<', $fasta_file,
277							'>', $output_file,
278							'2>', $stderr_file );
279
280							# Print command for debugging
281	0	0					if ($self->verbose() >= 0) {
282	0						my $cmd = '';
283	0						$cmd .= join ( ' ', @program_args );
284	0						for ( my $i = 1 ; $i < scalar @ipc_args ; $i++ ) {
285	0						my $element = $ipc_args[$i];
286	0						my $ref = ref($element);
287	0						my $value;
288	0	0	0				if ( $ref && $ref eq 'SCALAR') {
289	0						$value = $$element;
290							} else {
291	0						$value = $element;
292							}
293	0						$cmd .= " $value";
294							}
295	0						$self->debug( "$exe command = $cmd\n" );
296							}
297
298							# Execute command
299	0						eval {
300	0	0					IPC::Run::run(@ipc_args) \|\| die("There was a problem running $exe: $!");
301							};
302	0	0					if ($@) {
303	0						$self->throw("$exe call crashed: $@");
304							}
305	0	0					$self->debug(join("\n", "$exe STDERR", $stderr_file)) if $stderr_file;
306							# TIGR Assembler's stderr reports a lot more than just errors
307
308							# Close filehandles
309	0						close($scratch_fh);
310	0						close($output_fh);
311	0						close($stderr_fh);
312
313							# Import assembly
314	0						return $output_file;
315							}
316
317
318							=head2 _remove_small_sequences
319
320							Title : _remove_small_sequences
321							Usage : $assembler->_remove_small_sequences(\@seqs, \@quals)
322							Function: Remove sequences below a threshold length
323							Returns : a new sequence object array reference
324							a new quality score object array reference
325							Args : sequence object array reference
326							quality score object array reference (optional)
327
328							=cut
329
330							# Aliasing function _prepare_input_sequences to _remove_small_sequences
331							*_prepare_input_sequences = \&_remove_small_sequences;
332
333							sub _remove_small_sequences {
334	0			0			my ($self, $seqs, $quals) = @_;
335							# The threshold length, $min_len, has been registered as a global variable
336	0						my @new_seqs;
337							my @new_quals;
338
339	0	0					if (ref($seqs) =~ m/ARRAY/i) {
340	0						my @removed;
341	0						my $nof_seqs = scalar @$seqs;
342	0						for my $i (1 .. $nof_seqs) {
343	0						my $seq = $$seqs[$i-1];
344	0	0					if ($seq->length >= $min_len) {
345	0						push @new_seqs, $seq;
346	0	0					if ($quals) {
347	0						my $qual = $$quals[$i-1];
348	0						push @new_quals, $qual;
349							}
350							} else {
351	0						push @removed, $seq->id;
352							}
353							}
354	0	0					if (scalar @removed > 0) {
355	0						$self->warn("The following sequences were removed because they are smaller".
356							" than $min_len bp: @removed\n");
357							}
358							}
359	0						return \@new_seqs, \@new_quals;
360							}
361
362							1;