Mercurial > repos > dereeper > sniplay
view hapmap2mlmm/HapmapToMLMMFiles.xml @ 15:31c23d943c29 draft default tip
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author | dereeper |
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date | Tue, 08 Jan 2019 08:47:56 -0500 |
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<tool id="hapmap_to_mlmm_files" name="HapmapToMLMMFiles" version="2.0.0"> <description>Converts a hapmap file into MLMM input files</description> <!-- [STRONGLY RECOMMANDED] Exit code rules --> <requirements> <requirement type="package" version="4.1.3">gawk</requirement> </requirements> <stdio> <!-- [HELP] If no exit code rule is defined, the tool will stop if anything is written to STDERR --> <exit_code range="1:" level="fatal" /> </stdio> <command interpreter="bash">./HapmapToMLMMFiles.sh $input $snp_info $genot </command> <inputs> <param format="txt" name="input" type="data" label="Allelic file in Hapmap format" help="Allelic file in Hapmap format"/> </inputs> <outputs> <data format="txt" name="snp_info" label="SNP Info file"/> <data format="txt" name="genot" label="Genotyping file for MLMM"/> </outputs> <!-- [OPTIONAL] Tests to be run manually by the Galaxy admin --> <tests> <!-- [HELP] Test files have to be in the ~/test-data directory --> <!-- [HELP] Multiple tests can be defined with different parameters --> <test> <param name="input" value="hapmap2mlmm-hapmap" /> <output name="snp_info" file="hapmap2mlmm-result_snp.hapmap" /> <output name="genot" file="hapmap2mlmm-result_genot" /> </test> </tests> <help><![CDATA[ .. class:: infomark **Authors** Dereeper Alexis (alexis.dereeper@ird.fr), IRD, South Green platform | **Please cite** "SNiPlay3: a web-based application for exploration and large scale analyses of genomic variations", **Dereeper A. et al.**, Nucl. Acids Res. (1 july 2015) 43 (W1). .. class:: infomark **Galaxy integration** Provided by Southgreen & Dereeper Alexis (IRD) & Marcon Valentin (IFB & INRA) .. class:: infomark **Support** For any questions about Galaxy integration, please send an e-mail to alexis.dereeper@ird.fr --------------------------------------------------- ================= HapmapToMLMMFiles ================= ----------- Description ----------- | HapmapToMLMMFiles converts a hapmap file into input files compatible with the MLMM software. ------------ Dependencies ------------ GAWK gawk_ 4.1.3, Conda version .. _gawk: https://anaconda.org/bioconda/gawk ---------- Input file ---------- Hapmap file Allelic file in Hapmap format ------------ Output files ------------ SNP Info file Genotyping file for MLMM --------------------------------------------------- --------------- Working example --------------- Input files =========== Hapmap file ----------- :: rs# alleles chrom pos strand assembly# center protLSID assayLSID panel QCcode Ind1 Ind2 SNP1 A/T 1 3102 + assembly NA NA NA speciesname NA AA AA AA SNP2 A/T 1 4648 + assembly NA NA NA speciesname NA AA AA AA Output files ============ SNP Info file ------------- :: SNP Chr Pos SNP1 1 3102 SNP2 1 4648 SNP3 1 7601 Genotyping file for MLMM ------------------------ :: Ind_id SNP1 SNP2 SNP3 SNP4 SNP5 SNP6 SNP7 SNP8 SNP9 SNP10 SNP11 SNP12 SNP13 SNP14 Ind1 0 0 0 0 0 0 2 0 2 0 0 0 2 0 Ind2 0 0 0 0 0 2 2 0 0 0 0 0 0 0 ]]></help> <citations> <!-- [HELP] As DOI or BibTex entry --> <citation type="bibtex">@article{Dereeper03062015, author = {Dereeper, Alexis and Homa, Felix and Andres, Gwendoline and Sempere, Guilhem and Sarah, Gautier and Hueber, Yann and Dufayard, Jean-François and Ruiz, Manuel}, title = {SNiPlay3: a web-based application for exploration and large scale analyses of genomic variations}, year = {2015}, doi = {10.1093/nar/gkv351}, abstract ={SNiPlay is a web-based tool for detection, management and analysis of genetic variants including both single nucleotide polymorphisms (SNPs) and InDels. Version 3 now extends functionalities in order to easily manage and exploit SNPs derived from next generation sequencing technologies, such as GBS (genotyping by sequencing), WGRS (whole gre-sequencing) and RNA-Seq technologies. Based on the standard VCF (variant call format) format, the application offers an intuitive interface for filtering and comparing polymorphisms using user-defined sets of individuals and then establishing a reliable genotyping data matrix for further analyses. Namely, in addition to the various scaled-up analyses allowed by the application (genomic annotation of SNP, diversity analysis, haplotype reconstruction and network, linkage disequilibrium), SNiPlay3 proposes new modules for GWAS (genome-wide association studies), population stratification, distance tree analysis and visualization of SNP density. Additionally, we developed a suite of Galaxy wrappers for each step of the SNiPlay3 process, so that the complete pipeline can also be deployed on a Galaxy instance using the Galaxy ToolShed procedure and then be computed as a Galaxy workflow. SNiPlay is accessible at http://sniplay.southgreen.fr.}, URL = {http://nar.oxfordjournals.org/content/early/2015/06/03/nar.gkv351.abstract}, eprint = {http://nar.oxfordjournals.org/content/early/2015/06/03/nar.gkv351.full.pdf+html}, journal = {Nucleic Acids Research} } </citation> </citations> </tool>