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"planemo upload for repository https://github.com/galaxyproject/tools-iuc/tree/master/tools/art commit 7e2fa670ffad6bf9cd2411d7807c65db7c7e2f6b"
| author | iuc |
|---|---|
| date | Wed, 04 Dec 2019 06:19:06 -0500 |
| parents | bb7e0ccc0029 |
| children |
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<tool id="art_454" name="ART 454" version="2014.11.03.0"> <description>simulates pyrosequencing data</description> <macros> <import>macros.xml</import> </macros> <expand macro="requirements"/> <expand macro="stdio" /> <command><![CDATA[ art_454 $t $aln $sam #if $rndSeed and $rndSeed > -1: -r $rndSeed #end if #if $c -c $c #end if #if $generate.amplicon.use_amplicon == "amplicon_true": #if $generate.choice == "single_end": -A #else: -B #end if #end if $input_seq_file output #if $generate.choice == "single_end": $fold_coverage #else: $fold_coverage $generate.fragment_size $generate.fragment_sd #end if #if $generate.amplicon.use_amplicon == "amplicon_true": #if $generate.choice == "single_end": $generate.amplicon.reads_per_amplicon #else: $generate.amplicon.read_pairs_per_amplicon #end if #end if ; ]]></command> <inputs> <param label="DNA/RNA reference sequence" format="fasta" name="input_seq_file" type="data"/> <param label="the fold of read coverage over the reference sequences" name="fold_coverage" type="integer" value="20"/> <conditional name="generate"> <param name="choice" type="select" label="Type of data to generate"> <option value="single_end">Single-End</option> <option value="paired_end">Paired-End</option> </param> <when value="single_end"> <expand macro="amplicon" /> </when> <when value="paired_end"> <expand macro="frag_len_sd" /> <expand macro="amplicon_pair" /> </when> </conditional> <expand macro="sam" /> <expand macro="aln" /> <param type="boolean" label="indicate to simulate reads from the built-in GS FLX Titanium profile (-t)" name="t" truevalue="-t" falsevalue="" optional="true" /> <param label="specify the number of flow cycles by the sequencer [100 for GS-FLX, 200 for GS-FLX Titanium] (-c)" name="c" type="integer" value="100" optional="true" /> <expand macro="rndSeed" /> </inputs> <outputs> <!-- Single End --> <data format="fastq" name="output_fq1_single" from_work_dir="output.fq" label="Simulated of 454 sequencing of $input_seq_file.name"> <filter>generate['choice'] == "single_end"</filter> </data> <!-- Paired End --> <data format="fastq" name="output_fq1_paired" from_work_dir="output1.fq" label="Simulated of 454 sequencing of $input_seq_file.name (Forward)"> <filter>generate['choice'] != "single_end"</filter> </data> <data format="fastq" name="output_fq2_paired" from_work_dir="output2.fq" label="Simulated of 454 sequencing of $input_seq_file.name (Reverse)"> <filter>generate['choice'] != "single_end"</filter> </data> <data format="sam" name="output_sam" from_work_dir="output.sam" label="Mapping of Simulated 454 data to $input_seq_file.name"> <filter>sam</filter> </data> <!-- Single End --> <data format="aln" name="output_aln1_single" from_work_dir="output.aln" label="Alignment of Simulated 454 data to $input_seq_file.name"> <filter>aln and generate['choice'] == "single_end"</filter> </data> <!-- Paired End --> <data format="aln" name="output_aln1_paired" from_work_dir="output1.aln" label="Alignment of Simulated 454 data to $input_seq_file.name"> <filter>aln and generate['choice'] != "single_end"</filter> </data> <data format="aln" name="output_aln2_paired" from_work_dir="output2.aln" label="Alignment of Simulated 454 data to $input_seq_file.name"> <filter>generate['choice'] != "single_end" and generate['amplicon']['use_amplicon'] == "amplicon_true"</filter> </data> </outputs> <tests> <!-- Single End tests --> <test> <param name="rndSeed" value="42" /> <param name="input_seq_file" value="input.fa" /> <param name="fold_coverage" value="20" /> <param name="choice" value="single_end" /> <output name="output_fq1_single" file="art.454.01.fq" compare="sim_size" delta="5000" /> </test> <test> <param name="rndSeed" value="42" /> <param name="input_seq_file" value="input.fa" /> <param name="fold_coverage" value="20" /> <param name="choice" value="single_end" /> <param name="sam" value="True" /> <output name="output_fq1_single" file="art.454.01.fq" compare="sim_size" delta="5000" /> <output name="output_sam" file="art.454.01.sam" compare="sim_size" delta="5000"/> </test> <!-- Paired End tests --> <test> <param name="rndSeed" value="42" /> <param name="input_seq_file" value="input.fa" /> <param name="fold_coverage" value="20" /> <param name="choice" value="paired_end" /> <param name="fragment_size" value="105" /> <param name="fragment_sd" value="5" /> <param name="sam" value="True" /> <output name="output_fq1_paired" file="art.454.021.fq" compare="sim_size" delta="5000" /> <output name="output_fq2_paired" file="art.454.022.fq" compare="sim_size" delta="5000" /> <output name="output_sam" file="art.454.02.sam" compare="sim_size" delta="5000"/> </test> </tests> <help><![CDATA[ Art 454 Pyrosequencing Simulator ================================ ART_454 is a simulation program to generate sequence read data of Roche 454 Pyrosequencing sequencers. ART generates reads according to the empirical read quality profile and the calibrated error profile of uncall/overcall homopolymers from real 454 read data. ART has been using for testing or benchmarking a variety of method or tools for next-generation sequencing data analysis, including read alignment, de novo assembly, detection of SNP, CNV, or other structure variation. art_454 can generate both single-end and paired-end of 454 sequencing platform. Besides for regular genome DNA and cDNA sequencing simulation, art_454 also supports amplicon sequencing. The reference sequences can be either DNA or RNA. ]]></help> <expand macro="citation" /> </tool>