C# (CSharp) RCPA.Proteomics.Deuterium DeuteriumCalculatorOptions.CopyProperties Beispiele

Programmiersprache: C# (CSharp)

Namespace / Paketname: RCPA.Proteomics.Deuterium

Klasse / Typ: DeuteriumCalculatorOptions

Methode / Funktion: CopyProperties

Beispiele auf hotexamples.com: 2

C# (CSharp) RCPA.Proteomics.Deuterium DeuteriumCalculatorOptions.CopyProperties - 2 Beispiele gefunden. Dies sind die am besten bewerteten C# (CSharp) Beispiele für die RCPA.Proteomics.Deuterium.DeuteriumCalculatorOptions.CopyProperties, die aus Open Source-Projekten extrahiert wurden. Sie können Beispiele bewerten, um die Qualität der Beispiele zu verbessern.

Häufig verwendete Methoden

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CopyProperties(2)

PrepareOptions(1)

Beispiel #1

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        public override IEnumerable <string> Process()
        {
            //Extract chromotagraph information
            var chroOptions = new ChromatographProfileBuilderOptions();

            options.CopyProperties(chroOptions);
            chroOptions.InputFile  = options.InputFile;
            chroOptions.OutputFile = options.BoundaryOutputFile;
            chroOptions.DrawImage  = false;
            var builder = new ChromatographProfileBuilder(chroOptions);

            if (!File.Exists(options.BoundaryOutputFile) || options.Overwrite)
            {
                Progress.SetMessage("Finding envelope ...");
                builder.Progress = this.Progress;
                builder.Process();
            }

            //Calculate deuterium enrichment for peptide
            if (!File.Exists(options.DeuteriumOutputFile) || options.Overwrite)
            {
                Progress.SetMessage("Calculating deuterium ...");
                var deuteriumOptions = new RTemplateProcessorOptions()
                {
                    InputFile      = options.BoundaryOutputFile,
                    OutputFile     = options.DeuteriumOutputFile,
                    RTemplate      = DeuteriumR,
                    RExecute       = SystemUtils.GetRExecuteLocation(),
                    CreateNoWindow = true
                };

                deuteriumOptions.Parameters.Add("outputImage<-" + (options.DrawImage ? "1" : "0"));
                deuteriumOptions.Parameters.Add("excludeIsotopic0<-" + (options.ExcludeIsotopic0 ? "1" : "0"));

                new RTemplateProcessor(deuteriumOptions)
                {
                    Progress = this.Progress
                }.Process();
            }

            var deuteriumMap = new AnnotationFormat().ReadFromFile(options.DeuteriumOutputFile).ToDictionary(m => m.Annotations["ChroFile"].ToString());

            //Read old spectra information
            var format  = new MascotPeptideTextFormat();
            var spectra = format.ReadFromFile(options.InputFile);

            foreach (var spec in spectra)
            {
                spec.Annotations.Remove("RetentionTime");
                spec.Annotations.Remove("TheoreticalDeuterium");
                spec.Annotations.Remove("ObservedDeuterium");
                spec.Annotations.Remove("NumDeuteriumIncorporated");
                spec.Annotations.Remove("NumExchangableHydrogen");
                spec.Annotations.Remove("DeuteriumEnrichmentPercent");
            }

            var calcSpectra = new List <IIdentifiedSpectrum>();
            var aas         = new Aminoacids();

            foreach (var pep in spectra)
            {
                var filename = Path.GetFileNameWithoutExtension(builder.GetTargetFile(pep));
                if (deuteriumMap.ContainsKey(filename))
                {
                    var numExchangeableHydrogens = aas.ExchangableHAtom(pep.Peptide.PureSequence);
                    var numDeuteriumIncorporated = double.Parse(deuteriumMap[filename].Annotations["NumDeuteriumIncorporated"] as string);

                    pep.Annotations["PeakRetentionTime"]          = deuteriumMap[filename].Annotations["RetentionTime"];
                    pep.Annotations["TheoreticalDeuterium"]       = deuteriumMap[filename].Annotations["TheoreticalDeuterium"];
                    pep.Annotations["ObservedDeuterium"]          = deuteriumMap[filename].Annotations["ObservedDeuterium"];
                    pep.Annotations["NumDeuteriumIncorporated"]   = deuteriumMap[filename].Annotations["NumDeuteriumIncorporated"];
                    pep.Annotations["NumExchangableHydrogen"]     = numExchangeableHydrogens;
                    pep.Annotations["DeuteriumEnrichmentPercent"] = numDeuteriumIncorporated / numExchangeableHydrogens;

                    calcSpectra.Add(pep);
                }
            }
            format.PeptideFormat.Headers = format.PeptideFormat.Headers + "\tPeakRetentionTime\tTheoreticalDeuterium\tObservedDeuterium\tNumDeuteriumIncorporated\tNumExchangableHydrogen\tDeuteriumEnrichmentPercent";
            format.NotExportSummary      = true;
            format.WriteToFile(GetPeptideDeteriumFile(), calcSpectra);

            var specGroup = calcSpectra.GroupBy(m => m.Peptide.PureSequence).OrderBy(l => l.Key).ToList();

            var times = options.ExperimentalTimeMap.Values.Distinct().OrderBy(m => m).ToArray();

            using (var sw = new StreamWriter(options.OutputFile))
            {
                sw.WriteLine("Peptide\t{0}", (from t in times select t.ToString()).Merge("\t"));

                foreach (var peptide in specGroup)
                {
                    var curSpectra = peptide.GroupBy(m => options.ExperimentalTimeMap[m.Query.FileScan.Experimental]).ToDictionary(l => l.Key, l => l.ToArray());
                    if (options.PeptideInAllTimePointOnly && times.Any(l => !curSpectra.ContainsKey(l)))
                    {
                        continue;
                    }

                    sw.Write(peptide.Key);

                    foreach (var time in times)
                    {
                        if (curSpectra.ContainsKey(time))
                        {
                            var deps      = (from spec in curSpectra[time] select double.Parse(spec.Annotations["DeuteriumEnrichmentPercent"].ToString())).ToArray();
                            var depMedian = Statistics.Median(deps);
                            sw.Write("\t{0:0.######}", depMedian);
                        }
                        else
                        {
                            sw.Write("\tNA");
                        }
                    }
                    sw.WriteLine();
                }
            }

            Progress.SetMessage("Peptide deuterium enrichment calculation finished ...");

            return(new string[] { options.OutputFile });
        }

Beispiel #2

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        public override IEnumerable <string> Process()
        {
            //Prepare unique peptide file
            var format   = new MascotResultTextFormat();
            var proteins = format.ReadFromFile(options.InputFile);

            proteins.RemoveAmbiguousSpectra();

            var spectra = proteins.GetSpectra();

            foreach (var spec in spectra)
            {
                spec.Annotations.Remove("TheoreticalDeuterium");
                spec.Annotations.Remove("ObservedDeuterium");
                spec.Annotations.Remove("NumDeuteriumIncorporated");
                spec.Annotations.Remove("NumExchangableHydrogen");
                spec.Annotations.Remove("DeuteriumEnrichmentPercent");
            }

            var peptideFile   = Path.ChangeExtension(options.InputFile, ".unique.peptides");
            var peptideFormat = new MascotPeptideTextFormat(format.PeptideFormat.Headers);

            peptideFormat.WriteToFile(peptideFile, spectra);

            //Calculate deterium enrichment at peptide level
            var pepOptions = new DeuteriumCalculatorOptions();

            options.CopyProperties(pepOptions);
            pepOptions.InputFile  = peptideFile;
            pepOptions.OutputFile = peptideFile + ".tsv";

            var pepCalc = new PeptideDeuteriumCalculator(pepOptions);

            pepCalc.Progress = this.Progress;
            pepCalc.Process();

            //Copy annotation from calculated peptide to original peptide
            var calcSpectra   = peptideFormat.ReadFromFile(pepCalc.GetPeptideDeteriumFile());
            var oldSpectraMap = spectra.ToDictionary(m => m.Query.FileScan.LongFileName);

            foreach (var calcSpec in calcSpectra)
            {
                var oldSpec = oldSpectraMap[calcSpec.Query.FileScan.LongFileName];
                foreach (var ann in calcSpec.Annotations)
                {
                    oldSpec.Annotations[ann.Key] = ann.Value;
                }
            }

            //Remove the peptide not contain calculation result
            for (int i = proteins.Count - 1; i >= 0; i--)
            {
                foreach (var protein in proteins[i])
                {
                    protein.Peptides.RemoveAll(l => !l.Spectrum.Annotations.ContainsKey("DeuteriumEnrichmentPercent"));
                }

                if (proteins[i][0].Peptides.Count == 0)
                {
                    proteins.RemoveAt(i);
                }
            }

            format.PeptideFormat = peptideFormat.PeptideFormat;

            var noredundantFile = Path.ChangeExtension(options.OutputFile, ".individual.tsv");

            format.WriteToFile(noredundantFile, proteins);

            var times    = options.ExperimentalTimeMap.Values.Distinct().OrderBy(m => m).ToArray();
            var timeFile = Path.ChangeExtension(options.OutputFile, ".times.tsv");

            using (var sw = new StreamWriter(timeFile))
            {
                sw.WriteLine("Protein\t{0}", (from t in times select t.ToString()).Merge("\t"));

                foreach (var protein in proteins)
                {
                    var curSpectra = protein[0].GetSpectra();
                    if (options.PeptideInAllTimePointOnly)
                    {
                        var curMap = curSpectra.ToGroupDictionary(l => l.Peptide.PureSequence);
                        curSpectra.Clear();
                        foreach (var peps in curMap.Values)
                        {
                            var pepMap = peps.ToGroupDictionary(m => options.ExperimentalTimeMap[m.Query.FileScan.Experimental]);
                            if (times.All(time => pepMap.ContainsKey(time)))
                            {
                                curSpectra.AddRange(peps);
                            }
                        }
                    }

                    if (curSpectra.Count == 0)
                    {
                        continue;
                    }

                    sw.Write((from p in protein select p.Name).Merge("/"));
                    var curTimeMap = curSpectra.ToGroupDictionary(m => options.ExperimentalTimeMap[m.Query.FileScan.Experimental]);

                    foreach (var time in times)
                    {
                        if (curTimeMap.ContainsKey(time))
                        {
                            var deps      = (from spec in curTimeMap[time] select double.Parse(spec.Annotations["DeuteriumEnrichmentPercent"].ToString())).ToArray();
                            var depMedian = Statistics.Median(deps);
                            sw.Write("\t{0:0.######}", depMedian);
                        }
                        else
                        {
                            sw.Write("\tNA");
                        }
                    }
                    sw.WriteLine();
                }
            }

            Progress.SetMessage("Calculating ratio consistant ...");
            var deuteriumOptions = new RTemplateProcessorOptions()
            {
                InputFile      = timeFile,
                OutputFile     = options.OutputFile,
                RTemplate      = RatioR,
                RExecute       = SystemUtils.GetRExecuteLocation(),
                CreateNoWindow = true
            };

            new RTemplateProcessor(deuteriumOptions)
            {
                Progress = this.Progress
            }.Process();

            Progress.SetMessage("Finished ...");

            return(new string[] { options.OutputFile });
        }