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planemo upload for repository https://github.com/galaxyproject/tools-iuc/tree/master/tools/gtdbtk commit 6525c2141db269ee993dc79051525f97d3ecbab4
| author | iuc |
|---|---|
| date | Sat, 28 Sep 2024 16:26:12 +0000 |
| parents | 5c7ba3d85a01 |
| children |
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<tool id="gtdbtk_classify_wf" name="GTDB-Tk Classify genomes" version="@TOOL_VERSION@+galaxy@VERSION_SUFFIX@" profile="@PROFILE@"> <description>by placement in GTDB reference tree</description> <macros> <import>macros.xml</import> </macros> <xrefs> <xref type="bio.tools">GTDB-Tk</xref> </xrefs> <expand macro="requirements"/> <command detect_errors="exit_code"><![CDATA[ #import re mkdir input_dir && mkdir output_dir && #for $i in $input: ## gtdbtk uses the file extension to determine the input format. #set ext = "." + $i.ext #set input_identifier = re.sub('[^\s\w\-]', '_', str($i.element_identifier)) + $ext ln -s '${i}' input_dir/'${input_identifier}' && #end for export GTDBTK_DATA_PATH=$gtdbtk_db.fields.path && gtdbtk classify_wf --genome_dir input_dir --extension '$ext' --out_dir output_dir --cpus \${GALAXY_SLOTS:-4} --min_perc_aa $advanced.min_perc_aa $advanced.force --min_af $advanced.min_af ## Required unless mash_db is available: --skip_ani_screen #if str($advanced.output_process_log) == 'yes': && cat output_dir/gtdbtk.warnings.log output_dir/gtdbtk.log > '$process_log' #end if ]]></command> <inputs> <param name="input" type="data" format="fasta,fasta.gz" multiple="true" label="Fasta (Genome) files"/> <param name="gtdbtk_db" type="select" label="GTDB-Tk database" help="This version of GTDB-Tk requires GTDB version 207 or 214. Please contact your service administrator if this version is not available to select."> <options from_data_table="gtdbtk_database_versioned"> <filter type="regexp" column="version" value="^220$"/> <validator type="no_options" message="No locally cached GTDB-Tk database is available"/> </options> </param> <section name="advanced" title="Advanced options"> <param argument="--min_perc_aa" type="integer" min="0" max="100" value="10" label="Exclude genomes that do not have at least this percentage of AA in the MSA" help="Inclusive bound"/> <param argument="--force" type="boolean" truevalue="--force" falsevalue="" checked="false" label="Continue processing if an error occurs on a single genome?"/> <param argument="--min_af" type="float" min="0" max="1" value="0.65" label="Minimum alignment fraction to consider closest genome"/> <param name="output_process_log" type="boolean" truevalue="yes" falsevalue="no" checked="false" label="Output process log file?"/> </section> </inputs> <outputs> <data name="process_log" format="txt" label="${tool.name} on ${on_string} (process log)"> <filter>advanced['output_process_log']</filter> </data> <collection name="output_align" type="list" format="fasta.gz" label="${tool.name} on ${on_string} (align)"> <discover_datasets pattern="(?P<designation>.+)\.fasta.gz" ext="fasta.gz" directory="output_dir/align"/> </collection> <collection name="output_identfy" type="list" format="tsv" label="${tool.name} on ${on_string} (identify)"> <discover_datasets pattern="(?P<designation>.+)\.tsv" ext="tsv" directory="output_dir/identify"/> </collection> <collection name="output_classify" type="list" format="newick" label="${tool.name} on ${on_string} (classify)"> <discover_datasets pattern="(?P<designation>.+)\.tree" ext="newick" directory="output_dir/classify"/> </collection> <collection name="output_summary" type="list" format="tsv" label="${tool.name} on ${on_string} (summary)"> <discover_datasets pattern="(?P<designation>.+)\.tsv" ext="tsv" directory="output_dir"/> </collection> </outputs> <tests> <!-- The commented test here is valid if we could store the GTDB-Tk database --> <!-- <test expect_num_outputs="4"> <param name="input" value="genome_1.fna.gz" ftype="fasta.gz"/> <param name="gtdbtk_db" value="gtdbtk214"/> <output_collection name="output_summary" type="list" count="1"> <element name="gtdbtk.ar53.summary" ftype="tsv"> <assert_contents> <has_text text="user_genome"/> </assert_contents> </element> </output_collection> <output_collection name="output_identfy" type="list" count="4"> <element name="gtdbtk.ar53.markers_summary" ftype="tsv"> <assert_contents> <has_text text="number_unique_genes"/> </assert_contents> </element> <element name="gtdbtk.bac120.markers_summary" ftype="tsv"> <assert_contents> <has_text text="genome_1_fna_gz"/> </assert_contents> </element> <element name="gtdbtk.failed_genomes" ftype="tsv"> <assert_contents> <has_size value="0"/> </assert_contents> </element> <element name="gtdbtk.translation_table_summary" ftype="tsv"> <assert_contents> <has_text text="genome_1_fna_gz"/> </assert_contents> </element> </output_collection> <output_collection name="output_classify" type="list" count="1"> <element name="gtdbtk.ar53.classify" ftype="newick"> <assert_contents> <has_text text="GB_GCA_"/> </assert_contents> </element> </output_collection> <output_collection name="output_align" type="list" count="2"> <element name="gtdbtk.ar53.msa" ftype="fasta.gz" decompress="true"> <assert_contents> <has_text text="GB_GCA_000008085"/> </assert_contents> </element> <element name="gtdbtk.ar53.user_msa" ftype="fasta.gz" decompress="true"> <assert_contents> <has_text text="genome_1_fna_gz"/> </assert_contents> </element> </output_collection> </test> --> <!-- GTDB-Tk databases are far too large to test currently --> <test expect_failure="true"> <param name="input" value="genome_1.fna.gz" ftype="fasta.gz"/> <param name="gtdbtk_db" value="gtdbtk214"/> <assert_stderr> <has_text text="Fatal error: Exit code 1"/> </assert_stderr> </test> </tests> <help><![CDATA[ **What it does** GTDB-Tk is a software toolkit for assigning objective taxonomic classifications to bacterial and archaeal genomes based on the Genome Database Taxonomy GTDB. It is designed to work with recent advances that allow hundreds or thousands of metagenome-assembled genomes (MAGs) to be obtained directly from environmental samples. It can also be applied to isolate and single-cell genomes. This tool accepts one or more fasta (genome) files and determines taxonomic classification of genomes by maximum-likelihood (ML) placement. The classification workflow consists of three steps: identify, align, and classify. The identify step calls genes using Prodigal, and uses HMM models and the HMMER package to identify the 120 bacterial and 122 archaeal marker genes used for phylogenetic inference. Multiple sequence alignments (MSA) are obtained by aligning marker genes to their respective HMM model. The align step concatenates the aligned marker genes and filters the concatenated MSA to approximately 5,000 amino acids. Finally, the classify step uses pplacer to find the maximum-likelihood placement of each genome in the GTDB-Tk reference tree. GTDB-Tk classifies each genome based on its placement in the reference tree, its relative evolutionary divergence, and/or average nucleotide identity (ANI) to reference genomes. Results can be impacted by a lack of marker genes or contamination. ]]></help> <expand macro="citations"/> </tool>