Mercurial > repos > rnateam > viennarna_rnaeval
view rnaeval.xml @ 0:4d59d9c739a5 draft
planemo upload for repository https://github.com/bgruening/galaxytools/tree/master/tools/rna_tools/vienna_rna commit 0065dafe7bbd382bb995b28cc4089c9e4f4eeeb9
author | rnateam |
---|---|
date | Tue, 06 Dec 2016 12:32:16 -0500 |
parents | |
children | a3934747a65f |
line wrap: on
line source
<tool id="viennarna_rnaeval" name="@EXECUTABLE@" version="@VERSION@.0"> <description>Calculate energy of RNA sequences with given secondary structure</description> <macros> <token name="@EXECUTABLE@">RNAeval</token> <import>macros.xml</import> </macros> <expand macro="requirements" /> <expand macro="stdio" /> <expand macro="version_command" /> <command> <![CDATA[ RNAeval < '$input' > '$tabularFile' -T$temperature -d$dangling #if $varExists('$advancedOptions.noconversion') $advancedOptions.noconversion $advancedOptions.verbose $advancedOptions.gquad $advancedOptions.circ $advancedOptions.logml $advancedOptions.notetra #if str($advancedOptions.shapeOption.shapeSelector) == "isUsed" --shape='$advancedOptions.shapeOption.shapeFile' #if str($advancedOptions.shapeOption.shapeMethod.methodSelector) == "W" #set $s="W" --shapeMethod=$s #else if str($advancedOptions.shapeOption.shapeMethod.methodSelector) == "Z" #set $s="Zb"+str($advancedOptions.shapeOption.shapeMethod.b) --shapeMethod=$s #if str($advancedOptions.shapeOption.shapeMethod.shapeConversion.conversionSelector) == "C" #set $c="C"+str($advancedOptions.shapeOption.shapeMethod.shapeConversion.c) --shapeConversion=$c #else if str($advancedOptions.shapeOption.shapeMethod.shapeConversion.conversionSelector) == "L" #set $c="Ls"+str($advancedOptions.shapeOption.shapeMethod.shapeConversion.s)+"i"+ str($advancedOptions.shapeOption.shapeMethod.shapeConversion.i) --shapeConversion=$c #else if str($advancedOptions.shapeOption.shapeMethod.shapeConversion.conversionSelector) == "O" #set $c="Os"+str($advancedOptions.shapeOption.shapeMethod.shapeConversion.s)+"i"+ str($advancedOptions.shapeOption.shapeMethod.shapeConversion.i) --shapeConversion=$c #else #set $c=str($advancedOptions.shapeOption.shapeMethod.shapeConversion.conversionSelector) --shapeConversion=$c #end if #else if str($advancedOptions.shapeOption.shapeMethod.methodSelector) == "D" #set $s="Dm"+str($advancedOptions.shapeOption.shapeMethod.m)+"b"+str($advancedOptions.shapeOption.shapeMethod.b) --shapeMethod=$s #end if #end if #end if ]]> </command> <inputs> <param format="txt,dbn" name="input" type="data" label="Input file"/> <param name="temperature" type="float" value="37.0" label="temperature [°C]" help="-T"/> <param name="dangling" type="select" label="how to treat dangling end energies" help="-d"> <option value="0">0: ignore dangling ends</option> <option value="1">1: unpaired bases participate in one dangling end only</option> <option value="2" selected="True">2: unpaired bases participate in all dangling ends</option> <option value="3">3: allow coaxial stacking</option> </param> <conditional name="advancedOptions"> <param name="advancedSelector" type="select" label="advanced options"> <option value="basic">basic Options</option> <option value="advanced">advanced Options</option> </param> <when value="advanced"> <param name="verbose" type="boolean" truevalue="--verbose" falsevalue="" checked="false" label="Print out energy of each loop in the structure." help="--verbose"/> <param name="gquad" type="boolean" truevalue="--gquad" falsevalue="" checked="false" label="G-quadruplex formation prediction" help="--gquad"/> <param name="circ" type="boolean" truevalue="--circ" falsevalue="" checked="false" label="Assume circular RNA" help="--circ"/> <param name="logml" type="boolean" truevalue="--logML" falsevalue="" checked="false" label="Logarithmic energy functions for multi-loops" help="--logML"/> <param name="notetra" type="boolean" truevalue="" falsevalue="--noTetra" checked="true" label="Allow stabilization for loops, hairpins etc." help=" Include special tabulated stabilizing energies for tri-, tetra- and hexaloop hairpins. Mostly for testing. (--noTetra)"/> <param name="noconversion" type="boolean" truevalue="" falsevalue="--noconv" checked="true" label="Convert Thymine to Uracil (T -> U)" help="Avoids confusion with DNA sequences (--noconv)"/> <conditional name="shapeOption"> <param name="shapeSelector" type="select" label="Shape reactivity data"> <option value="isUsed">Use shape reactivity data</option> <option value="notUsed" selected="true">Don't use shape reactivity data</option> </param> <when value ="isUsed"> <param type="data" name="shapeFile" format="shape,*" label="Shape file" argument="--shape"/> <conditional name="shapeMethod"> <param name="methodSelector" type="select" label="Shape reactivity data" argument="--shapeMethod"> <option value="D" selected="true">D: Convert by using a linear equation according to Deigan et al 2009</option> <option value="Z">Z: Convert SHAPE reactivities to pseudo energies according to Zarringhalam et al 2012.</option> <option value="W">W: Apply a given vector of perturbation energies to unpaired nucleotides according to Washietl et al 2012</option> </param> <when value="D"> <param name="m" type="float" value="1.8" label="Slope m"/> <param name="b" type="float" value="-0.6" label="Intercept"/> </when> <when value="Z"> <param name="b" type="float" value="-0.6" label="Intercept"/> <conditional name="shapeConversion"> <param name="conversionSelector" type="select" label="shape reactivity data"> <option value="M">M: Use linear mapping according to Zarringhalam et al</option> <option value="C">C: Use a cutoff−approach to divide into paired and unpaired nucleotides</option> <option value="S">S: Skip the normalizing step since the input data already represents probabilities for being unpaired rather than raw reactivity values</option> <option value="L">L: Use a linear model to convert the reactivity into a probability for being unpaired</option> <option value="O" selected="true">O: Use a linear model to convert the log of the reactivity into a probability for being unpaired</option> </param> <when value="M"> </when> <when value="C"> <param name="c" type="float" value="0.25" label="Cutoff"/> </when> <when value="S"> </when> <when value="L"> <param name="s" type="float" value="0.68" label="Slope"/> <param name="i" type="float" value="0.2" label="Intercept"/> </when> <when value="O"> <param name="s" type="float" value="1.6" label="Slope s"/> <param name="i" type="float" value="-2.29" label="Intercept"/> </when> </conditional> </when> <when value="W"> </when> </conditional> </when> <when value="notUsed"> </when> </conditional> </when> <when value="basic"> </when> </conditional> </inputs> <outputs> <data format="txt" name="tabularFile"/> </outputs> <tests> <test> <param name="input" value="rnaeval_input1.dbn"/> <output name="out_file" file="rnaeval_result1.txt"/> </test> </tests> <help> <![CDATA[ **RNAeval** RNAeval evaluates the free energy of an RNA molecule in fixed secondary structure. Sequences and structures are read alternately from stdin. The energy in Kcal/Mol is written to stdout. ----- **Input format** RNAeval requires one input file in a format similar to the Fasta format. The secondary strucures should be added after the sequence in dot-bracket notation. Sequence and structure can be interupted by an '&' to calculate the co-folding of two RNA-strands. ------ **Outputs** First line: the sequence, second line: the structure with its corresponding energy ]]> </help> <expand macro="citations" /> </tool>