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"planemo upload for repository https://github.com/galaxyproject/tools-iuc/tree/master/tools/bedtools commit fe3f54a0d3edb83fcf6752e3b1524c582b4febd5"
author | iuc |
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date | Fri, 06 Sep 2019 14:29:59 -0400 |
parents | dde39ba9c031 |
children | ce3c7f062223 |
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<tool id="bedtools_coveragebed" name="bedtools Compute both the depth and breadth of coverage" version="@TOOL_VERSION@"> <description>of features in file B on the features in file A (bedtools coverage)</description> <macros> <import>macros.xml</import> </macros> <expand macro="requirements"> <requirement type="package" version="@SAMTOOLS_VERSION@">samtools</requirement> </expand> <expand macro="stdio" /> <command><![CDATA[ bedtools coverage $d $hist $split $strandedness #if str($overlap_a): -f $overlap_a #end if #if str($overlap_b): -F $overlap_b #end if $reciprocal_overlap $a_or_b -a '$inputA' #if str($reduce_or_iterate.reduce_or_iterate_selector) == 'iterate': -b '$reduce_or_iterate.inputB' #if $reduce_or_iterate.inputB.is_of_type('bam'): -sorted -g <(samtools view -H $reduce_or_iterate.inputB | grep '^@SQ' | sed $'s/\tSN:/\tSN\t/' | sed $'s/\tLN:/\tLN\t/' | cut -f 3,5) #end if #else: -b #for $file in $reduce_or_iterate.inputB '$file' #end for #end if #if $inputA.is_of_type('gff'): | sort -k1,1 -k4,2n #else: | sort -k1,1 -k2,2n #end if > '$output' ]]></command> <inputs> <param name="inputA" argument="-a" type="data" format="bam,@STD_BEDTOOLS_INPUTS@" label="File A (on which coverage is calculated)" help="BAM/@STD_BEDTOOLS_INPUT_LABEL@ format" /> <conditional name="reduce_or_iterate"> <param name="reduce_or_iterate_selector" type="select" label="Combined or separate output files"> <option value="iterate" selected="true">One output file per 'input B' file</option> <option value="reduce">Single output containing results for all 'input B' files</option> </param> <when value="iterate"> <param name="inputB" argument="-b" type="data" format="bam,@STD_BEDTOOLS_INPUTS@" label="File B (for which coverage is calculated)" help="BAM/@STD_BEDTOOLS_INPUT_LABEL@ format"/> </when> <when value="reduce"> <param name="inputB" argument="-b" type="data" format="bam,@STD_BEDTOOLS_INPUTS@" multiple="true" label="File(s) B (for which coverage is calculated)" help="BAM/@STD_BEDTOOLS_INPUT_LABEL@ format"/> </when> </conditional> <expand macro="split" /> <param name="strandedness" argument="-s" type="boolean" label="Force strandedness" truevalue="-s" falsevalue="" checked="false" help="Only report hits in B that overlap A on the same strand. By default, overlaps are reported without respect to strand"/> <param argument="-d" type="boolean" truevalue="-d" falsevalue="" checked="false" label="Report the depth at each position in each A feature" help="Positions reported are one based. Each position and depth follow the complete B feature" /> <param argument="-hist" type="boolean" truevalue="-hist" falsevalue="" checked="false" label="Report a histogram of coverage for each feature in A as well as a summary histogram for all features in A" help="Additional columns after each feature in A: 1) depth 2) # bases at depth 3) size of A 4) % of A at depth" /> <expand macro="overlap" name="overlap_a" /> <expand macro="overlap" name="overlap_b" argument="-F" fracof="B" /> <param name="reciprocal_overlap" argument="-r" type="boolean" truevalue="-r" falsevalue="" checked="false" label="Require that the fraction overlap be reciprocal for A AND B." help="if -f is 0.90 and -r is used, this requires that B overlap 90% of A and A _also_ overlaps 90% of B" /> <param name="a_or_b" argument="-e" type="boolean" truevalue="-e" falsevalue="" checked="false" label="Require that the minimum fraction be satisfied for A OR B." help="If -e is used with -f 0.90 and -F 0.10 this requires that either 90% of A is covered OR 10% of B is covered. Without -e, both fractions would have to be satisfied" /> </inputs> <outputs> <data name="output" format="bed" metadata_source="inputA" label="Count of overlaps on ${inputA.name}"/> </outputs> <tests> <test> <param name="inputA" value="coverageBedA.bed" ftype="bed" /> <param name="inputB" value="coverageBedB.bed" ftype="bed" /> <output name="output" file="coverageBed_result1.bed" ftype="bed" /> </test> <test> <param name="inputA" value="multiCov1.bed" ftype="bed" /> <param name="inputB" value="srma_in3.bam" ftype="bam" /> <output name="output" file="multicov1_by_srma_in3.cov.bed" ftype="bed" /> </test> <test> <param name="inputA" value="multiCov1.bed" ftype="bed" /> <param name="reduce_or_iterate_selector" value="reduce" /> <param name="inputB" value="srma_in3.bam" ftype="bam" /> <output name="output" file="multicov1_by_srma_in3.cov.bed" ftype="bed" /> </test> <test> <param name="inputA" value="coverageBedA.bed" ftype="bed" /> <param name="inputB" value="coverageBedB.bed" ftype="bed" /> <param name="overlap_b" value="1" /> <output name="output" file="coverageBed_result2_F1.bed" ftype="bed" /> </test> <test> <param name="inputA" value="coverageBedA.bed" ftype="bed" /> <param name="inputB" value="coverageBedB.bed" ftype="bed" /> <param name="overlap_a" value="1E-5" /> <param name="reciprocal_overlap" value="true" /> <output name="output" file="coverageBed_result3_f1r.bed" ftype="bed" /> </test> </tests> <help><![CDATA[ **What it does** `bedtools coverage`_ computes both the *depth* and *breadth* of coverage of features in file B on the features in file A. For example, ``bedtools coverage`` can compute the coverage of sequence alignments (file B) across 1 kilobase (arbitrary) windows (file A) tiling a genome of interest. One advantage that ``bedtools coverage`` offers is that it not only *counts* the number of features that overlap an interval in file A, it also computes the fraction of bases in the interval in A that were overlapped by one or more features. Thus, ``bedtools coverage`` also computes the *breadth* of coverage for each interval in A. .. _bedtools coverage: http://bedtools.readthedocs.org/en/latest/content/tools/coverage.html .. class:: infomark The lines in the output will be comprised of each interval in A, followed by: 1. The number of features in B that overlapped (by at least one base pair) the A interval. 2. The number of bases in A that had non-zero coverage from features in B. 3. The length of the entry in A. 4. The fraction of bases in A that had non-zero coverage from features in B. @REFERENCES@ ]]></help> <expand macro="citations" /> </tool>