private PiscesOptionsParser GetParsedApplicationOptions(string arguments)
{
var parsedOptions = new PiscesOptionsParser();
parsedOptions.ParseArgs(arguments.Split(' '), false);
return(parsedOptions);
}
public void InvalidVcfOutputFolder()
{
Assert.False(Directory.Exists("56:\\Illumina\\OutputFolder"));
var outputFolder = Path.Combine("56:\\Illumina\\OutputFolder");
string bamChr19 = Path.Combine(TestPaths.LocalTestDataDirectory, "Chr19.bam");
string bamChr17Chr19 = Path.Combine(TestPaths.LocalTestDataDirectory, "Chr17Chr19.bam");
string bamChr17Chr19Dup = Path.Combine(TestPaths.LocalTestDataDirectory, "Chr17Chr19_removedSQlines.bam");
string intervalsChr19 = Path.Combine(TestPaths.LocalTestDataDirectory, "Chr19.picard");
string intervalsChr17 = Path.Combine(TestPaths.LocalTestDataDirectory, "chr17only.picard");
string genomeChr19 = Path.Combine(TestPaths.SharedGenomesDirectory, "chr19");
var appOptions = new PiscesApplicationOptions
{
BAMPaths = new[] { bamChr19, bamChr17Chr19, bamChr17Chr19Dup },
IntervalPaths = new[] { intervalsChr17, intervalsChr19, null },
GenomePaths = new[] { genomeChr19 },
OutputDirectory = outputFolder
};
var parser = new PiscesOptionsParser()
{
Options = appOptions
};
Assert.Throws <ArgumentException>(() => parser.ValidateAndSetDerivedValues());
}
public void PopulateBAMPaths()
{
var BAMFolder = TestPaths.SharedBamDirectory;
//Happy Path
var options_1 = new PiscesApplicationOptions()
{
BAMPaths = BamProcessorParsingUtils.UpdateBamPathsWithBamsFromFolder(BAMFolder),
GenomePaths = new[] { _existingGenome },
IntervalPaths = new[] { _existingInterval }
};
Assert.NotNull(options_1.BAMPaths);
Assert.True(options_1.BAMPaths.Length > 0);
//no bam files found
var options_3 = new PiscesApplicationOptions()
{
GenomePaths = new[] { _existingGenome },
};
var parser = new PiscesOptionsParser()
{
Options = options_3
};
Assert.Null(options_3.BAMPaths);
Assert.Throws <ArgumentException>(() => parser.ValidateAndSetDerivedValues());
}
//if I was not in a hurry, we could refactor this into the Config class and let it be re-used by Scylla and VQR...
private static VcfWriterConfig GetWriterConfigToMatchInputVcf(string vcfIn)
{
List <string> vcfHeaderLines;
using (var reader = new VcfReader(vcfIn))
{
vcfHeaderLines = reader.HeaderLines;
}
PiscesOptionsParser piscesOptionsParser = VcfConsumerAppParsingUtils.GetPiscesOptionsFromVcfHeader(vcfHeaderLines);
if (piscesOptionsParser.ParsingFailed)
{
Logger.WriteToLog("Unable to parse the original Pisces commandline");
throw new ArgumentException("Unable to parse the input vcf header: " + vcfIn);
}
VariantCallingParameters variantCallingParams = piscesOptionsParser.PiscesOptions.VariantCallingParameters;
VcfWritingParameters vcfWritingParams = piscesOptionsParser.PiscesOptions.VcfWritingParameters;
BamFilterParameters bamFilterParams = piscesOptionsParser.PiscesOptions.BamFilterParameters;
var config = new VcfWriterConfig(variantCallingParams, vcfWritingParams, bamFilterParams, null, false, false);
return(config);
}
public Program(string programDescription, string commandLineExample, string programAuthors, string programName,
IVersionProvider versionProvider = null) : base(programDescription, commandLineExample,
programAuthors, programName, versionProvider = null)
{
_options = new PiscesApplicationOptions();
_appOptionParser = new PiscesOptionsParser();
}
private static void CheckHeader(AlleleReader reader)
{
string piscesCmd = reader.HeaderLines.FirstOrDefault(str => str.Contains("##Pisces_cmdline")).Split("\"\"")[1];
var appOptionParser = new PiscesOptionsParser();
appOptionParser.ParseArgs(piscesCmd.Split(null));
// Check if VCF is diploid
if (appOptionParser.PiscesOptions.VariantCallingParameters.PloidyModel == PloidyModel.DiploidByAdaptiveGT ||
appOptionParser.PiscesOptions.VariantCallingParameters.PloidyModel == PloidyModel.DiploidByThresholding)
{
throw new VariantReaderException("Adaptive Genotyper should be used with VCFs that are called as somatic " +
"VCFs by Pisces. Please check the input VCF file.");
}
// Check if VCF is crushed
else if (appOptionParser.PiscesOptions.VcfWritingParameters.ForceCrush == true)
{
throw new VariantReaderException("Adaptive Genotyper should be used with uncrushed VCFs. Please check the input VCF file.");
}
// Check if GVCF or --minvq 0
else if (!appOptionParser.PiscesOptions.VcfWritingParameters.OutputGvcfFile &&
(appOptionParser.PiscesOptions.VariantCallingParameters.MinimumVariantQScore > 0 ||
appOptionParser.PiscesOptions.VariantCallingParameters.MinimumFrequency > 0.02))
{
throw new VariantReaderException("Adaptive Genotyper should be used with GVCFs or with option -minvq 0. Please" +
" check in the input VCF file.");
}
}
private void ExecuteValidationTest(Action <PiscesApplicationOptions> testSetup, bool shouldPass)
{
var options = GetBasicOptions();
testSetup(options);
var parser = new PiscesOptionsParser()
{
Options = options
};
if (shouldPass)
{
parser.ValidateAndSetDerivedValues();
}
else
{
Assert.Throws <ArgumentException>(() => parser.ValidateAndSetDerivedValues());
}
}
public void Validate()
{
// ---------------------
// verify default should be valid
// ---------------------
var option = GetBasicOptions();
var parser = new PiscesOptionsParser()
{
Options = option
};
parser.ValidateAndSetDerivedValues();
// ---------------------
// verify log folder
// ---------------------
Assert.Equal(Path.Combine(TestPaths.SharedBamDirectory, "PiscesLogs"), option.LogFolder);
// ---------------------------------------------------
// BAMPath(s) should be specified.
// ---------------------------------------------------
ExecuteValidationTest((o) => { o.BAMPaths = new[] { _existingBamPath }; }, true);
ExecuteValidationTest((o) => { o.BAMPaths = new[] { "bampath1.bam" }; }, false);
ExecuteValidationTest((o) => { o.BAMPaths = null; }, false);
// ---------------------------------------------------
// BAMFolder
// Folder should exist (given as the first string in BAMPaths)
// 1 Genome Path should be specified when BAMFolder is specified.
// Atmost 1 Interval Path should be specified when BAMFolder is specified.
// Threading by chromosome is not supported when BAMFolder is specified.
// ---------------------------------------------------
ExecuteValidationTest(o =>
{
o.BAMPaths = new string[] { @"C:\NonexistantBAMFolder" };
o.GenomePaths = new[] { _existingGenome };
}, false);
ExecuteValidationTest(o =>
{
o.BAMPaths = new string[] { TestPaths.SharedBamDirectory };
o.GenomePaths = new[] { "folder1", "folder2" };
}, false);
ExecuteValidationTest(o =>
{
o.BAMPaths = new string[] { TestPaths.SharedBamDirectory };
o.GenomePaths = new[] { _existingGenome };
o.IntervalPaths = new[] { "file1.intervals", "file2.intervals" };
}, false);
ExecuteValidationTest(o =>
{
o.BAMPaths = BamProcessorParsingUtils.UpdateBamPathsWithBamsFromFolder(TestPaths.SharedBamDirectory);
o.GenomePaths = new[] { _existingGenome };
o.IntervalPaths = new[] { _existingInterval };
}, true);
// ---------------------
// BAM Paths
// Duplicate BAMPaths detected.
// BAM Path does not exist.
// ---------------------
ExecuteValidationTest((o) => { o.BAMPaths = new string[0]; }, false);
ExecuteValidationTest((o) => { o.BAMPaths = new[] { _existingBamPath, _existingBamPath }; }, false);
ExecuteValidationTest((o) => { o.BAMPaths = new[] { "nonexistant.bam" }; }, false);
// genome paths
ExecuteValidationTest((o) => { o.GenomePaths = null; }, false);
ExecuteValidationTest((o) => { o.GenomePaths = new string[0]; }, false);
ExecuteValidationTest((o) => { o.GenomePaths = new[] { _existingGenome, _existingGenome }; }, false);
ExecuteValidationTest((o) => { o.GenomePaths = new[] { "nonexistant" }; }, false);
ExecuteValidationTest((o) =>
{
o.BAMPaths = new[] { _existingBamPath, _existingBamPath2 };
o.GenomePaths = new[] { _existingGenome, _existingGenome };
}, true); // dup genomes ok
// intervals
ExecuteValidationTest((o) => { o.IntervalPaths = new[] { _existingInterval, _existingInterval }; }, false);
ExecuteValidationTest((o) => { o.IntervalPaths = new[] { "nonexistant.picard" }; }, false);
ExecuteValidationTest((o) =>
{
o.BAMPaths = new[] { _existingBamPath, _existingBamPath2 };
o.IntervalPaths = new[] { _existingInterval, _existingInterval };
}, true); // dup intervals ok
ExecuteValidationTest((o) =>
{
o.BAMPaths = new[] { _existingBamPath, _existingBamPath2 };
o.IntervalPaths = new[] { _existingInterval, _existingInterval, _existingInterval };
}, false);
// ---------------------
// verify parameters
// ---------------------
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumVariantQScore = 0; }, true);
ExecuteValidationTest((o) =>
{
o.VariantCallingParameters.MinimumVariantQScore = 100;
o.VariantCallingParameters.MinimumVariantQScoreFilter = 100;
}, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumVariantQScore = -1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumVariantQScore = 101; }, false);
ExecuteValidationTest((o) =>
{
o.VariantCallingParameters.MaximumVariantQScore = 0;
o.VariantCallingParameters.MinimumVariantQScore = 0;
o.VariantCallingParameters.MinimumVariantQScoreFilter = 0;
}, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MaximumVariantQScore = 100; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MaximumVariantQScore = -1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MaximumVariantQScore = 101; }, true);
ExecuteValidationTest((o) =>
{
o.VariantCallingParameters.MinimumVariantQScore = 50;
o.VariantCallingParameters.MaximumVariantQScore = 49;
}, false);
ExecuteValidationTest((o) =>
{
o.VariantCallingParameters.MinimumVariantQScore = 50;
o.VariantCallingParameters.MaximumVariantQScore = 50;
o.VariantCallingParameters.MinimumVariantQScoreFilter = 50;
}, true);
ExecuteValidationTest((o) => { o.BamFilterParameters.MinimumBaseCallQuality = 0; }, true);
ExecuteValidationTest((o) => { o.BamFilterParameters.MinimumBaseCallQuality = -1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumFrequency = 0f; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumFrequency = 1f; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumFrequency = -0.99f; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumFrequency = 1.01f; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumVariantQScoreFilter = o.VariantCallingParameters.MinimumVariantQScore; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumVariantQScoreFilter = o.VariantCallingParameters.MaximumVariantQScore; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumVariantQScoreFilter = o.VariantCallingParameters.MinimumVariantQScore - 1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumVariantQScoreFilter = o.VariantCallingParameters.MaximumVariantQScore + 1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.ForcedNoiseLevel = 0; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.ForcedNoiseLevel = -50; }, false);
ExecuteValidationTest((o) => { o.MaxSizeMNV = 0; }, true); // ok if not calling mnv
ExecuteValidationTest((o) => { o.MaxGapBetweenMNV = -1; }, true); // ok if not calling mnv
ExecuteValidationTest((o) => { o.OutputDirectory = TestPaths.LocalTestDataDirectory; }, true); // True for valid path
ExecuteValidationTest((o) =>
{
o.CallMNVs = true;
o.MaxSizeMNV = 1;
}, true);
ExecuteValidationTest((o) =>
{
o.CallMNVs = true;
o.MaxSizeMNV = 0;
}, false);
ExecuteValidationTest((o) =>
{
o.CallMNVs = true;
o.MaxSizeMNV = GlobalConstants.RegionSize;
}, true);
ExecuteValidationTest((o) =>
{
o.CallMNVs = true;
o.MaxSizeMNV = GlobalConstants.RegionSize + 1;
}, false);
ExecuteValidationTest((o) =>
{
o.CallMNVs = true;
o.MaxGapBetweenMNV = 0;
}, true);
ExecuteValidationTest((o) =>
{
o.CallMNVs = true;
o.MaxGapBetweenMNV = -1;
}, false);
ExecuteValidationTest((o) => { o.BamFilterParameters.MinimumMapQuality = 0; }, true);
ExecuteValidationTest((o) => { o.BamFilterParameters.MinimumMapQuality = -1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.StrandBiasAcceptanceCriteria = 0f; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.StrandBiasAcceptanceCriteria = -0.01f; }, false);
ExecuteValidationTest((o) => { o.MaxNumThreads = 1; }, true);
ExecuteValidationTest((o) => { o.MaxNumThreads = 0; }, false);
//FilteredVariantFrequency Scenarios
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumFrequencyFilter = 0; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumFrequencyFilter = 1f; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumFrequencyFilter = -1; o.VariantCallingParameters.MinimumFrequency = -1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.MinimumFrequencyFilter = 1.1f; }, false);
//FilteredLowGenomeQuality Scenarios
ExecuteValidationTest((o) =>
{
o.VariantCallingParameters.PloidyModel = PloidyModel.DiploidByThresholding;
o.VariantCallingParameters.LowGenotypeQualityFilter = 0;
}, true);
ExecuteValidationTest((o) =>
{
o.VariantCallingParameters.PloidyModel = PloidyModel.DiploidByThresholding;
o.VariantCallingParameters.LowGenotypeQualityFilter = 100;
}, true);
ExecuteValidationTest((o) =>
{
o.VariantCallingParameters.PloidyModel = PloidyModel.DiploidByThresholding;
o.VariantCallingParameters.LowGenotypeQualityFilter = -1;
}, false);
ExecuteValidationTest((o) =>
{
o.VariantCallingParameters.PloidyModel = PloidyModel.DiploidByThresholding;
o.VariantCallingParameters.LowGenotypeQualityFilter = 101;
}, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.LowGenotypeQualityFilter = 0; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.LowGenotypeQualityFilter = 100; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.LowGenotypeQualityFilter = -1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.LowGenotypeQualityFilter = 101; }, true);
//FilteredIndelRepeats Scenarios
ExecuteValidationTest((o) => { o.VariantCallingParameters.IndelRepeatFilter = 0; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.IndelRepeatFilter = 10; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.IndelRepeatFilter = -1; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.IndelRepeatFilter = 11; }, false);
//FilteredLowDepth Scenarios
ExecuteValidationTest(o =>
{
o.VariantCallingParameters.LowDepthFilter = 0;
o.VariantCallingParameters.MinimumCoverage = 0;
}, true);
ExecuteValidationTest(o =>
{
o.VariantCallingParameters.LowDepthFilter = 1;
o.VariantCallingParameters.MinimumCoverage = 0;
}, true);
ExecuteValidationTest(o =>
{
o.VariantCallingParameters.LowDepthFilter = -1;
o.VariantCallingParameters.MinimumCoverage = 0;
}, false);
//Priors path
ExecuteValidationTest((o) => { o.PriorsPath = _existingBamPath; }, true);
ExecuteValidationTest((o) => { o.PriorsPath = Path.Combine(TestPaths.LocalTestDataDirectory, "Nonexistant.txt"); }, false);
// Thread by chr
ExecuteValidationTest(o =>
{
o.ThreadByChr = true;
o.ChromosomeFilter = "chr1";
}, false);
// Validate ncfilter
ExecuteValidationTest((o) => { o.VariantCallingParameters.NoCallFilterThreshold = 0f; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.NoCallFilterThreshold = 1f; }, true);
ExecuteValidationTest((o) => { o.VariantCallingParameters.NoCallFilterThreshold = -1f; }, false);
ExecuteValidationTest((o) => { o.VariantCallingParameters.NoCallFilterThreshold = 2f; }, false);
}
