Ejemplo n.º 1
0
        protected override void DoTest()
        {
            // Skyline Targeted Method Refinement

            var folderMethodRefine = UseRawFiles ? "MethodRefine" : "MethodRefineMzml"; // Not L10N

            // Results Data, p. 2
            var doc = SkylineWindow.Document;

            RunUI(() => SkylineWindow.OpenFile(TestFilesDirs[1].GetTestPath(folderMethodRefine + @"\WormUnrefined.sky"))); // Not L10N
            WaitForDocumentChangeLoaded(doc);
            RunUI(() =>
            {
                // Adjust font sizes for better screen shots
                Settings.Default.ChromatogramFontSize = 14;
                Settings.Default.SpectrumFontSize     = 14;
                SkylineWindow.ChangeTextSize(TreeViewMS.LRG_TEXT_FACTOR);

                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.Nodes[0].Nodes[0];
                SkylineWindow.AutoZoomBestPeak();   // TODO: Mention this in the tutorial
                SkylineWindow.Size = new Size(1160, 660);

                Assert.AreEqual(SkylineWindow.SequenceTree.SelectedNode.Text, "YLGAYLLATLGGNASPSAQDVLK"); // Not L10N
            });
            PauseForScreenShot("Main window", 2);

            // TODO: Update tutorial to view b-ions.
            RunUI(() => SkylineWindow.GraphSpectrumSettings.ShowBIons = true);

            // Unrefined Methods, p. 3
            {
                var exportDlg = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                RunUI(() =>
                {
                    exportDlg.ExportStrategy = ExportStrategy.Buckets;
                    exportDlg.MethodType     = ExportMethodType.Standard;
                    exportDlg.OptimizeType   = ExportOptimize.NONE;
                    exportDlg.MaxTransitions = 59;
                });
                PauseForScreenShot("Export Transition List form", 3);                                                       // Not L10N
                OkDialog(exportDlg, () => exportDlg.OkDialog(TestFilesDirs[1].GetTestPath(folderMethodRefine + @"\worm"))); // Not L10N
            }

            for (int i = 1; i < 10; i++)
            {
                Assert.IsTrue(File.Exists(TestFilesDirs[1].GetTestPath(folderMethodRefine + @"\worm_000" + i + TextUtil.EXT_CSV))); // Not L10N
            }
            for (int i = 10; i < 40; i++)
            {
                Assert.IsTrue(File.Exists(TestFilesDirs[1].GetTestPath(folderMethodRefine + @"\worm_00" + i + TextUtil.EXT_CSV))); // Not L10N
            }

            // Importing Multiple Injection Data, p. 4

            Assert.IsTrue(SkylineWindow.Document.Settings.HasResults);
            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, manageResultsDlg =>
            {
                manageResultsDlg.RemoveReplicates();
                Assert.AreEqual(manageResultsDlg.Chromatograms.ToArray().Length, 0);
                manageResultsDlg.OkDialog();
            });

            RunUI(() => SkylineWindow.SaveDocument());
            Assert.IsFalse(SkylineWindow.Document.Settings.HasResults);

            const string replicateName = "Unrefined"; // Not L10N

            RunDlg <ImportResultsDlg>(SkylineWindow.ImportResults, importResultsDlg =>
            {
                importResultsDlg.RadioAddNewChecked = true;
                var namedPathSets = DataSourceUtil.GetDataSourcesInSubdirs(TestFilesDirs[0].FullPath).ToArray();
                importResultsDlg.NamedPathSets =
                    new[] { new KeyValuePair <string, MsDataFileUri[]>(replicateName, namedPathSets[0].Value.Take(15).ToArray()) };
                importResultsDlg.OkDialog();
            });
            WaitForOpenForm <AllChromatogramsGraph>();                                                        // To make the AllChromatogramsGraph form accessible to the SkylineTester forms tab
            PauseForScreenShot <AllChromatogramsGraph>("Loading Chromatograms: Take screenshot at about 25% loaded...", 5);
            WaitForCondition(15 * 60 * 1000, () => SkylineWindow.Document.Settings.MeasuredResults.IsLoaded); // 15 minutes

            Assert.IsTrue(SkylineWindow.Document.Settings.HasResults);
            Assert.AreEqual(15, SkylineWindow.Document.Settings.MeasuredResults.CachedFilePaths.ToArray().Length);

            RunDlg <ImportResultsDlg>(SkylineWindow.ImportResults, importResultsDlg =>
            {
                importResultsDlg.RadioAddExistingChecked = true;
                var namedPathSets = DataSourceUtil.GetDataSourcesInSubdirs(TestFilesDirs[0].FullPath).ToArray();
                importResultsDlg.NamedPathSets =
                    new[] { new KeyValuePair <string, MsDataFileUri[]>(replicateName, namedPathSets[0].Value.Skip(15).ToArray()) };
                importResultsDlg.OkDialog();
            });
            WaitForCondition(20 * 60 * 1000, () => SkylineWindow.Document.Settings.MeasuredResults.IsLoaded);  // 15 minutes

            Assert.AreEqual(39, SkylineWindow.Document.Settings.MeasuredResults.CachedFilePaths.ToArray().Length);

            RunUI(SkylineWindow.AutoZoomNone);
            RestoreViewOnScreen(7);
            PauseForScreenShot("Chromatogram graph metafile", 7);

            // Simple Manual Refinement, p. 6
            int startingNodeCount = SkylineWindow.SequenceTree.Nodes[0].GetNodeCount(false);

            Assert.AreEqual("YLGAYLLATLGGNASPSAQDVLK", SkylineWindow.SequenceTree.Nodes[0].Nodes[0].Text); // Not L10N

            RunUI(() =>
            {
                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.Nodes[0].Nodes[0];
                SkylineWindow.AutoZoomNone();
                SkylineWindow.AutoZoomBestPeak();
                SkylineWindow.EditDelete();
                SkylineWindow.ShowRTLinearRegressionGraph();
            });
            Assert.AreEqual(SkylineWindow.SequenceTree.Nodes[0].GetNodeCount(false), startingNodeCount - 1);
            Assert.AreEqual("VLEAGGLDCDMENANSVVDALK", SkylineWindow.SequenceTree.Nodes[0].Nodes[0].Text); // Not L10N
            PauseForScreenShot("Retention Times Regression plot metafile", 8);

            RunDlg <RegressionRTThresholdDlg>(SkylineWindow.ShowRegressionRTThresholdDlg, rtThresholdDlg =>
            {
                rtThresholdDlg.Threshold = 0.95;
                rtThresholdDlg.OkDialog();
            });
            WaitForConditionUI(() => SkylineWindow.RTGraphController.RegressionRefined != null);
            WaitForGraphs();
            PauseForScreenShot("Retention Times Regression plot metafile with 0.95 threshold", 9); // Not L10N

            TestRTResidualsSwitch();

            RunDlg <EditRTDlg>(SkylineWindow.CreateRegression, editRTDlg => editRTDlg.OkDialog());

            RunUI(() => SkylineWindow.ShowGraphRetentionTime(false));
            RunUI(SkylineWindow.AutoZoomNone);
            PauseForScreenShot("Chromatogram graph metafile zoomed out", 10); // Not L10N

            // Missing Data, p. 10
            RunUI(() =>
            {
                SkylineWindow.RTGraphController.SelectPeptide(SkylineWindow.Document.GetPathTo(1, 163));
                Assert.AreEqual("YLAEVASEDR", SkylineWindow.SequenceTree.SelectedNode.Text);     // Not L10N
            });
            RestoreViewOnScreen(11);
            //  Restoring the view changes the selection
            RunUI(SkylineWindow.CollapsePeptides);
            FindNode("YLAEVASEDR");
            RunUI(() => SkylineWindow.SequenceTree.TopNode = SkylineWindow.SequenceTree.Nodes[0].Nodes[153]);

            PauseForScreenShot("Targets view clipped from the main window", 11);

            RunUI(() =>
            {
                var nodePep = (PeptideDocNode)((SrmTreeNode)SkylineWindow.SequenceTree.SelectedNode).Model;
                Assert.AreEqual(null,
                                nodePep.GetPeakCountRatio(
                                    SkylineWindow.SequenceTree.GetDisplayResultsIndex(nodePep)));
                SkylineWindow.SequenceTree.SelectedPath = SkylineWindow.Document.GetPathTo(1, 157);
                Assert.AreEqual("VTVVDDQSVILK", SkylineWindow.SequenceTree.SelectedNode.Text);
            });
            WaitForGraphs();
            RunUI(() =>
            {
                SkylineWindow.ActivateReplicate("Unrefined");
                SkylineWindow.AutoZoomNone();
            });
            PauseForScreenShot("Unrefined chromatogram graph page clipped from main window", 12); // Not L10N

//            foreach (var peptideDocNode in SkylineWindow.Document.Peptides)
//            {
//                var nodeGroup = ((TransitionGroupDocNode)peptideDocNode.Children[0]);
//                Console.WriteLine("{0} - {1}", peptideDocNode.Peptide.Sequence,
//                    nodeGroup.GetDisplayText(SkylineWindow.SequenceTree.GetDisplaySettings(peptideDocNode)));
//            }
//            Console.WriteLine("---------------------------------");

            RunUI(() =>
            {
                var graphChrom = SkylineWindow.GetGraphChrom("Unrefined"); // Not L10N
                Assert.AreEqual(2, graphChrom.Files.Count);
                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.Nodes[0];

                // Picking Measurable Peptides and Transitions, p. 12
                SkylineWindow.ExpandPeptides();
                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.Nodes[0].Nodes[0];
            });

            RunUI(SkylineWindow.AutoZoomBestPeak);
            RestoreViewOnScreen(13);
            RunUI(() => SkylineWindow.ShowGraphSpectrum(false));
            PauseForScreenShot("Targets view clipped from the main window and chromatogram graph metafile", 13);

            RunUI(() => SkylineWindow.ShowGraphSpectrum(true));
            PauseForScreenShot("Library Match plot metafile", 14);

            RunUI(() =>
            {
                SkylineWindow.ShowGraphSpectrum(false);
                SkylineWindow.SelectedPath = SkylineWindow.Document.GetPathTo((int)SrmDocument.Level.Transitions, 0);
                SkylineWindow.SelectedNode.Expand();
                SkylineWindow.SelectedPath = SkylineWindow.Document.GetPathTo((int)SrmDocument.Level.Molecules, 0);
            });

            PauseForScreenShot("Targetes view clipped from the main window", 14); // Not L10N

            RunUI(() =>
            {
                double dotpExpect = Math.Round(Statistics.AngleToNormalizedContrastAngle(0.78), 2);  // 0.57
                AssertEx.Contains(SkylineWindow.SequenceTree.SelectedNode.Nodes[0].Text,
                                  dotpExpect.ToString(LocalizationHelper.CurrentCulture));
                SkylineWindow.EditDelete();

                dotpExpect = 0.34; // Math.Round(Statistics.AngleToNormalizedContrastAngle(0.633), 2);  // 0.44
                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.Nodes[0].Nodes[0];
                AssertEx.Contains(SkylineWindow.SequenceTree.SelectedNode.Nodes[0].Text,
                                  dotpExpect.ToString(LocalizationHelper.CurrentCulture));
                SkylineWindow.EditDelete();

                PeptideTreeNode nodePep;
                for (int i = 0; i < 2; i++)
                {
                    nodePep = (PeptideTreeNode)SkylineWindow.SequenceTree.Nodes[0].Nodes[i];
                    nodePep.ExpandAll();
                    foreach (TransitionTreeNode nodeTran in nodePep.Nodes[0].Nodes)
                    {
                        TransitionDocNode nodeTranDoc = (TransitionDocNode)nodeTran.Model;
                        Assert.AreEqual((int)SequenceTree.StateImageId.peak,
                                        TransitionTreeNode.GetPeakImageIndex(nodeTranDoc,
                                                                             (PeptideDocNode)nodePep.Model,
                                                                             SkylineWindow.SequenceTree));
                        var resultsIndex = SkylineWindow.SequenceTree.GetDisplayResultsIndex(nodePep);
                        var rank         = nodeTranDoc.GetPeakRank(resultsIndex);
                        if (rank == null || rank > 3)
                        {
                            SkylineWindow.SequenceTree.SelectedNode = nodeTran;
                        }
                        SkylineWindow.SequenceTree.KeysOverride = Keys.Control;
                    }
                }
                nodePep = (PeptideTreeNode)SkylineWindow.SequenceTree.Nodes[0].Nodes[2];
                nodePep.ExpandAll();
                foreach (TransitionTreeNode nodeTran in nodePep.Nodes[0].Nodes)
                {
                    TransitionDocNode nodeTranDoc = (TransitionDocNode)nodeTran.Model;
                    Assert.AreEqual((int)SequenceTree.StateImageId.peak,
                                    TransitionTreeNode.GetPeakImageIndex(nodeTranDoc,
                                                                         (PeptideDocNode)nodePep.Model,
                                                                         SkylineWindow.SequenceTree));
                    var name = ((TransitionDocNode)nodeTran.Model).FragmentIonName;
                    if (!(name == "y11" || name == "y13" || name == "y14")) // Not L10N
                    {
                        SkylineWindow.SequenceTree.SelectedNode = nodeTran;
                    }
                    SkylineWindow.SequenceTree.KeysOverride = Keys.Control;
                }
                SkylineWindow.SequenceTree.KeysOverride = Keys.None;
                SkylineWindow.EditDelete();
                for (int i = 0; i < 3; i++)
                {
                    Assert.IsTrue(SkylineWindow.SequenceTree.Nodes[0].Nodes[i].Nodes[0].Nodes.Count == 3);
                }
                SkylineWindow.AutoZoomNone();

                SkylineWindow.SelectedPath = SkylineWindow.Document.GetPathTo((int)SrmDocument.Level.Transitions, 5);
                SkylineWindow.Size         = new Size(722, 449);
            });

            RunUI(SkylineWindow.AutoZoomBestPeak);
            RestoreViewOnScreen(15);
            PauseForScreenShot("Targetes view clipped from main window and chromatogram graph metafile", 15);

            // Automated Refinement, p. 16
            RunDlg <RefineDlg>(SkylineWindow.ShowRefineDlg, refineDlg =>
            {
                refineDlg.MaxTransitionPeakRank = 3;
                refineDlg.PreferLargerIons      = true;
                refineDlg.RemoveMissingResults  = true;
                refineDlg.RTRegressionThreshold = 0.95;
                refineDlg.DotProductThreshold   = Statistics.AngleToNormalizedContrastAngle(0.95);  // Convert from original cos(angle) dot-product
                refineDlg.OkDialog();
            });
            WaitForCondition(() => SkylineWindow.Document.PeptideCount < 73);
//            foreach (var peptideDocNode in SkylineWindow.Document.Peptides)
//            {
//                var nodeGroup = ((TransitionGroupDocNode) peptideDocNode.Children[0]);
//                Console.WriteLine("{0} - {1}", peptideDocNode.Peptide.Sequence,
//                    nodeGroup.GetDisplayText(SkylineWindow.SequenceTree.GetDisplaySettings(peptideDocNode)));
//            }
            RunUI(() =>
            {
                Assert.AreEqual(72, SkylineWindow.Document.PeptideCount);
                Assert.AreEqual(216, SkylineWindow.Document.PeptideTransitionCount);
                SkylineWindow.CollapsePeptides();
                SkylineWindow.Undo();
            });
            RunDlg <RefineDlg>(SkylineWindow.ShowRefineDlg, refineDlg =>
            {
                refineDlg.MaxTransitionPeakRank = 6;
                refineDlg.RemoveMissingResults  = true;
                refineDlg.RTRegressionThreshold = 0.90;
                refineDlg.DotProductThreshold   = Statistics.AngleToNormalizedContrastAngle(0.90);  // Convert from original cos(angle) dot-product
                refineDlg.OkDialog();
            });

            WaitForCondition(() => SkylineWindow.Document.PeptideCount < 120);
            RunUI(() =>
            {
                Assert.AreEqual(113, SkylineWindow.Document.PeptideCount);

                // Scheduling for Efficient Acquisition, p. 17
                SkylineWindow.Undo();
            });

            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, mResults =>
            {
                Assert.AreEqual(1, mResults.Chromatograms.Count());

                mResults.SelectedChromatograms =
                    SkylineWindow.Document.Settings.MeasuredResults.Chromatograms.Where(
                        set => Equals("Unrefined", set.Name)); // Not L10N

                mResults.RemoveReplicates();

                Assert.AreEqual(0, mResults.Chromatograms.Count());
                mResults.OkDialog();
            });

            var importResultsDlg0 = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);

            RunUI(() =>
            {
                SkylineWindow.SequenceTree.SelectedNode           = SkylineWindow.SequenceTree.Nodes[0];
                importResultsDlg0.RadioCreateMultipleMultiChecked = true;
                importResultsDlg0.NamedPathSets =
                    DataSourceUtil.GetDataSourcesInSubdirs(Path.Combine(TestFilesDirs[1].FullPath,
                                                                        Path.GetFileName(TestFilesDirs[1].FullPath) ??
                                                                        string.Empty)).ToArray();
            });
            var importResultsNameDlg = ShowDialog <ImportResultsNameDlg>(importResultsDlg0.OkDialog);

            RunUI(importResultsNameDlg.NoDialog);
            WaitForCondition(15 * 60 * 1000, () => SkylineWindow.Document.Settings.HasResults && SkylineWindow.Document.Settings.MeasuredResults.IsLoaded); // 15 minutes

            var docCurrent = SkylineWindow.Document;

            RunUI(SkylineWindow.RemoveMissingResults);
            WaitForDocumentChange(docCurrent);
            Assert.AreEqual(86, SkylineWindow.Document.PeptideCount);
            Assert.AreEqual(255, SkylineWindow.Document.PeptideTransitionCount);

            TestRTResidualsSwitch();

            // Measuring Retention Times, p. 17
            {
                var exportDlg = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                RunUI(() => exportDlg.MaxTransitions = 130);
                PauseForScreenShot <ExportMethodDlg.TransitionListView>("Export Transition List form", 18);
                OkDialog(exportDlg, () => exportDlg.OkDialog(TestFilesDirs[1].FullPath + "\\unscheduled")); // Not L10N
            }
            ///////////////////////

            // Reviewing Retention Time Runs, p. 18
            RunUI(() =>
            {
                SkylineWindow.ShowGraphSpectrum(false);
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.AutoZoomNone();
                SkylineWindow.AutoZoomBestPeak();
            });
            FindNode("FWEVISDEHGIQPDGTFK");

            RunUI(() => SkylineWindow.Size = new Size(1060, 550));
            RestoreViewOnScreen(19);
            PauseForScreenShot("Main window", 19); // Not L10N

            RunUI(() => SkylineWindow.ShowRTSchedulingGraph());
            WaitForCondition(() => SkylineWindow.GraphRetentionTime != null);

            PauseForScreenShot("Retention Times - Scheduling graph metafile", 19);

            RestoreViewOnScreen(20);

            // Creating a Scheduled Transition List, p. 20
            {
                var peptideSettingsUI = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
                RunUI(() =>
                {
                    peptideSettingsUI.SelectedTab = PeptideSettingsUI.TABS.Prediction;
                    peptideSettingsUI.TimeWindow  = 4;
                });
                PauseForScreenShot <PeptideSettingsUI.PredictionTab>("Peptide Settings - Prediction tab", 21);
                OkDialog(peptideSettingsUI, peptideSettingsUI.OkDialog); // Not L10N
            }

            var exportMethodDlg1 = ShowDialog <ExportMethodDlg>(() =>
                                                                SkylineWindow.ShowExportMethodDialog(ExportFileType.List));

            RunUI(() =>
            {
                exportMethodDlg1.ExportStrategy = ExportStrategy.Single;
                exportMethodDlg1.MethodType     = ExportMethodType.Scheduled;
            });
            // TODO: Update tutorial to mention the scheduling options dialog.
            PauseForScreenShot("Export Transition List form", 22);                                              // Not L10N
            RunDlg <SchedulingOptionsDlg>(() =>
                                          exportMethodDlg1.OkDialog(TestFilesDirs[1].FullPath + "\\scheduled"), // Not L10N
                                          schedulingOptionsDlg => schedulingOptionsDlg.OkDialog());
            WaitForClosedForm(exportMethodDlg1);

            // Reviewing Multi-Replicate Data, p. 22
            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, manageResultsDlg =>
            {
                manageResultsDlg.RemoveAllReplicates();
                manageResultsDlg.OkDialog();
            });
            var importResultsDlg1 = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);

            RunDlg <OpenDataSourceDialog>(() => importResultsDlg1.NamedPathSets = importResultsDlg1.GetDataSourcePathsFile(null),
                                          openDataSourceDialog =>
            {
                openDataSourceDialog.SelectAllFileType(ExtThermoRaw);
                openDataSourceDialog.Open();
            });
            RunDlg <ImportResultsNameDlg>(importResultsDlg1.OkDialog, importResultsNameDlg0 =>
            {
                importResultsNameDlg0.Prefix = "Scheduled_"; // Not L10N
                importResultsNameDlg0.YesDialog();
            });
            WaitForCondition(15 * 60 * 1000, () => SkylineWindow.Document.Settings.HasResults && SkylineWindow.Document.Settings.MeasuredResults.IsLoaded); // 15 minutes
            Assert.AreEqual(5, SkylineWindow.GraphChromatograms.Count(graphChrom => !graphChrom.IsHidden));
            RunUI(() =>
            {
                SkylineWindow.RemoveMissingResults();
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.ShowGraphRetentionTime(false);
            });
            WaitForCondition(() => SkylineWindow.GraphRetentionTime.IsHidden);
            RunUI(() =>
            {
                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.Nodes[0].Nodes[0];
                SkylineWindow.ShowRTReplicateGraph();
                SkylineWindow.ShowPeakAreaReplicateComparison();
                SkylineWindow.CollapsePeptides();
                SkylineWindow.ShowChromatogramLegends(false);
                SkylineWindow.Size = new Size(1024, 768);
            });
            RestoreViewOnScreen(24);
            WaitForGraphs();
            PauseForScreenShot("Main window", 24); // Not L10N

            RunUI(() => SkylineWindow.SaveDocument());
            RunUI(SkylineWindow.NewDocument);
        }
Ejemplo n.º 2
0
        protected override void DoTest()
        {
            var folderAbsoluteQuant = UseRawFiles ? "AbsoluteQuant" : "AbsoluteQuantMzml";
            // Generating a Transition List, p. 4
            {
                var doc = SkylineWindow.Document;
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                RunUI(() =>
                {
                    // Predicition Settings
                    transitionSettingsUI.SelectedTab       = TransitionSettingsUI.TABS.Prediction;
                    transitionSettingsUI.PrecursorMassType = MassType.Monoisotopic;
                    transitionSettingsUI.FragmentMassType  = MassType.Monoisotopic;
                    transitionSettingsUI.RegressionCEName  = "Thermo TSQ Vantage";
                    transitionSettingsUI.RegressionDPName  = Resources.SettingsList_ELEMENT_NONE_None;
                });
                PauseForScreenShot <TransitionSettingsUI.PredictionTab>("Transition Settings - Prediction tab", 4);

                RunUI(() =>
                {
                    // Filter Settings
                    transitionSettingsUI.SelectedTab      = TransitionSettingsUI.TABS.Filter;
                    transitionSettingsUI.PrecursorCharges = "2";
                    transitionSettingsUI.ProductCharges   = "1";
                    transitionSettingsUI.FragmentTypes    = "y";
                    transitionSettingsUI.RangeFrom        = Resources.TransitionFilter_FragmentStartFinders_ion_3;
                    transitionSettingsUI.RangeTo          = Resources.TransitionFilter_FragmentEndFinders_last_ion_minus_1;
                    transitionSettingsUI.SpecialIons      = new string[0];
                });
                PauseForScreenShot <TransitionSettingsUI.FilterTab>("Transition Settings - Filter tab", 4);

                OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);
                WaitForDocumentChange(doc);
            }

            // Configuring Peptide settings p. 4
            PeptideSettingsUI peptideSettingsUI = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);

            RunUI(() => peptideSettingsUI.SelectedTab = PeptideSettingsUI.TABS.Modifications);
            PauseForScreenShot <PeptideSettingsUI.ModificationsTab>("Peptide Settings - Modification tab", 5);

            var modHeavyK = new StaticMod("Label:13C(6)15N(2) (C-term K)", "K", ModTerminus.C, false, null, LabelAtoms.C13 | LabelAtoms.N15,
                                          RelativeRT.Matching, null, null, null);

            AddHeavyMod(modHeavyK, peptideSettingsUI, "Edit Isotope Modification over Transition Settings", 5);
            RunUI(() => peptideSettingsUI.PickedHeavyMods = new[] { modHeavyK.Name });
            PauseForScreenShot <PeptideSettingsUI.ModificationsTab>("Peptide Settings - Modification tab with mod added", 5);

            OkDialog(peptideSettingsUI, peptideSettingsUI.OkDialog);

            // Inserting a peptide sequence p. 5
            using (new CheckDocumentState(1, 1, 2, 10))
            {
                RunUI(() => SetClipboardText("IEAIPQIDK\tGST-tag"));
                var pasteDlg = ShowDialog <PasteDlg>(SkylineWindow.ShowPastePeptidesDlg);
                RunUI(pasteDlg.PastePeptides);
                WaitForProteinMetadataBackgroundLoaderCompletedUI();
                PauseForScreenShot <PasteDlg.PeptideListTab>("Insert Peptide List", 6);

                OkDialog(pasteDlg, pasteDlg.OkDialog);
            }

            RunUI(SkylineWindow.ExpandPrecursors);
            RunUI(() => SkylineWindow.SaveDocument(TestFilesDir.GetTestPath(folderAbsoluteQuant + @"test_file.sky")));
            WaitForCondition(() => File.Exists(TestFilesDir.GetTestPath(folderAbsoluteQuant + @"test_file.sky")));
            PauseForScreenShot("Main window with Targets view", 6);

            // Exporting a transition list p. 6
            {
                var exportMethodDlg = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                RunUI(() =>
                {
                    exportMethodDlg.InstrumentType = ExportInstrumentType.THERMO;
                    exportMethodDlg.ExportStrategy = ExportStrategy.Single;
                    exportMethodDlg.OptimizeType   = ExportOptimize.NONE;
                    exportMethodDlg.MethodType     = ExportMethodType.Standard;
                });
                PauseForScreenShot <ExportMethodDlg.TransitionListView>("Export Transition List", 7);

                OkDialog(exportMethodDlg, () =>
                         exportMethodDlg.OkDialog(TestFilesDir.GetTestPath("Quant_Abs_Thermo_TSQ_Vantage.csv")));
            }

            // Importing RAW files into Skyline p. 7
            var importResultsDlg = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);

            PauseForScreenShot <ImportResultsDlg>("Import Results - click OK to get shot of Import Results Files and then cancel", 8);

            RunUI(() =>
            {
                var rawFiles      = DataSourceUtil.GetDataSources(TestFilesDirs[0].FullPath).First().Value.Skip(1);
                var namedPathSets = from rawFile in rawFiles
                                    select new KeyValuePair <string, MsDataFileUri[]>(
                    rawFile.GetFileNameWithoutExtension(), new[] { rawFile });
                importResultsDlg.NamedPathSets = namedPathSets.ToArray();
            });
            RunDlg <ImportResultsNameDlg>(importResultsDlg.OkDialog,
                                          importResultsNameDlg => importResultsNameDlg.NoDialog());

            WaitForGraphs();

            RunUI(() =>
            {
                SkylineWindow.SelectedPath             = SkylineWindow.Document.GetPathTo((int)SrmDocument.Level.Molecules, 0);
                Settings.Default.ArrangeGraphsOrder    = GroupGraphsOrder.Document.ToString();
                Settings.Default.ArrangeGraphsReversed = false;
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.AutoZoomBestPeak();
            });
            WaitForCondition(() => Equals(8, SkylineWindow.GraphChromatograms.Count(graphChrom => !graphChrom.IsHidden)),
                             "unexpected visible graphChromatogram count");

            WaitForCondition(10 * 60 * 1000,    // ten minutes
                             () => SkylineWindow.Document.Settings.HasResults && SkylineWindow.Document.Settings.MeasuredResults.IsLoaded);
            PauseForScreenShot("Main window with imported data", 9);

            // Analyzing SRM Data from FOXN1-GST Sample p. 9
            RunDlg <ImportResultsDlg>(SkylineWindow.ImportResults,
                                      importResultsDlg1 =>
            {
                var rawFiles      = DataSourceUtil.GetDataSources(TestFilesDirs[0].FullPath).First().Value.Take(1);
                var namedPathSets = from rawFile in rawFiles
                                    select new KeyValuePair <string, MsDataFileUri[]>(
                    rawFile.GetFileNameWithoutExtension(), new[] { rawFile });
                importResultsDlg1.NamedPathSets = namedPathSets.ToArray();
                importResultsDlg1.OkDialog();
            });
            WaitForGraphs();
            CheckReportCompatibility.CheckAll(SkylineWindow.Document);
            WaitForCondition(5 * 60 * 1000, // five minutes
                             () =>
                             SkylineWindow.Document.Settings.HasResults &&
                             SkylineWindow.Document.Settings.MeasuredResults.IsLoaded);

            RunUI(() =>
            {
                SkylineWindow.ToggleIntegrateAll();
                SkylineWindow.ArrangeGraphsTabbed();
                SkylineWindow.ShowRTReplicateGraph();
                SkylineWindow.ShowPeakAreaReplicateComparison();
                // Total normalization
                SkylineWindow.NormalizeAreaGraphTo(AreaNormalizeToView.area_percent_view);
            });

            RunUI(() => SkylineWindow.ActivateReplicate("FOXN1-GST"));
            WaitForGraphs();
            RunUI(() => SkylineWindow.SelectedPath = SkylineWindow.DocumentUI.GetPathTo((int)SrmDocument.Level.TransitionGroups, 0));
            WaitForGraphs();
            RunUI(() =>
            {
                Assert.AreEqual(SkylineWindow.SelectedResultsIndex, SkylineWindow.GraphPeakArea.ResultsIndex);
                Assert.AreEqual(SkylineWindow.SelectedResultsIndex, SkylineWindow.GraphRetentionTime.ResultsIndex);
            });

            RunUI(() =>
            {
                int transitionCount = SkylineWindow.DocumentUI.PeptideTransitionGroups.First().TransitionCount;
                CheckGstGraphs(transitionCount, transitionCount);
            });
            PauseForScreenShot("Main window with Peak Areas, Retention Times and FOXN1-GST for light", 10);

            RunUI(() => SkylineWindow.SelectedPath = SkylineWindow.DocumentUI.GetPathTo((int)SrmDocument.Level.TransitionGroups, 1));
            WaitForGraphs();

            RunUI(() =>
            {
                int transitionCount = SkylineWindow.DocumentUI.PeptideTransitionGroups.ToArray()[1].TransitionCount;
                CheckGstGraphs(transitionCount, transitionCount);
            });
            PauseForScreenShot("Main window with Peak Areas, Retention Times and FOXN1-GST for heavy", 10);

            RunUI(() => SkylineWindow.SelectedPath = SkylineWindow.DocumentUI.GetPathTo((int)SrmDocument.Level.Molecules, 0));
            WaitForGraphs();
            // Heavy normalization
            RunUI(() => SkylineWindow.NormalizeAreaGraphTo(AreaNormalizeToView.area_ratio_view));
            WaitForGraphs();
            RunUI(() =>
            {
                int transitionGroupCount = SkylineWindow.DocumentUI.Peptides.First().TransitionGroupCount;
                CheckGstGraphs(transitionGroupCount, transitionGroupCount - 1);
            });
            PauseForScreenShot("Main window with totals graphs for light and heavy and FOXN1-GST", 11);

            // Peptide Quantitification Settings p. 11
            var          peptideSettingsUi = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
            const string quantUnits        = "fmol/ul";

            RunUI(() =>
            {
                peptideSettingsUi.SelectedTab              = PeptideSettingsUI.TABS.Quantification;
                peptideSettingsUi.QuantRegressionFit       = RegressionFit.LINEAR;
                peptideSettingsUi.QuantNormalizationMethod = new NormalizationMethod.RatioToLabel(IsotopeLabelType.heavy);
                peptideSettingsUi.QuantUnits = quantUnits;
            });
            PauseForScreenShot("Peptide Settings Quantification Tab", 12);
            OkDialog(peptideSettingsUi, peptideSettingsUi.OkDialog);

            // Specify analyte concentrations of external standards
            RunUI(() => SkylineWindow.ShowDocumentGrid(true));
            var documentGridForm = FindOpenForm <DocumentGridForm>();

            RunUI(() =>
            {
                documentGridForm.ChooseView(Resources.SkylineViewContext_GetDocumentGridRowSources_Replicates);
            });
            WaitForConditionUI(() => documentGridForm.IsComplete);
            var concentrations = new[] { 40, 12.5, 5, 2.5, 1, .5, .25, .1 };

            for (int iRow = 0; iRow < concentrations.Length; iRow++)
            {
                // ReSharper disable AccessToModifiedClosure
                RunUI(() =>
                {
                    var colSampleType = documentGridForm.FindColumn(PropertyPath.Root.Property("SampleType"));
                    documentGridForm.DataGridView.Rows[iRow].Cells[colSampleType.Index].Value = SampleType.STANDARD;
                });
                WaitForConditionUI(() => documentGridForm.IsComplete);
                RunUI(() =>
                {
                    var colAnalyteConcentration =
                        documentGridForm.FindColumn(PropertyPath.Root.Property("AnalyteConcentration"));
                    var cell = documentGridForm.DataGridView.Rows[iRow].Cells[colAnalyteConcentration.Index];
                    documentGridForm.DataGridView.CurrentCell = cell;
                    cell.Value = concentrations[iRow];
                });
                // ReSharper restore AccessToModifiedClosure
                WaitForConditionUI(() => documentGridForm.IsComplete);
            }
            PauseForScreenShot("Document grid with concentrations filled in", 13);

            // View the calibration curve p. 13
            RunUI(() => SkylineWindow.ShowCalibrationForm());
            var calibrationForm = FindOpenForm <CalibrationForm>();

            PauseForScreenShot("View calibration curve", 14);

            Assert.AreEqual(CalibrationCurveFitter.AppendUnits(QuantificationStrings.Analyte_Concentration, quantUnits), calibrationForm.ZedGraphControl.GraphPane.XAxis.Title.Text);
            Assert.AreEqual(string.Format(QuantificationStrings.CalibrationCurveFitter_PeakAreaRatioText__0___1__Peak_Area_Ratio, IsotopeLabelType.light.Title, IsotopeLabelType.heavy.Title),
                            calibrationForm.ZedGraphControl.GraphPane.YAxis.Title.Text);
        }
Ejemplo n.º 3
0
        protected override void DoTest()
        {
            string skyFile = TestFilesDirs[0].GetTestPath(@"DriftTimePrediction\BSA-Training.sky");

            RunUI(() => SkylineWindow.OpenFile(skyFile));

            var document = WaitForDocumentLoaded(240 * 1000); // 4 minutes

            RunUI(() => SkylineWindow.Size = new Size(880, 560));
            RestoreViewOnScreen(2);
            PauseForScreenShot("Document open - full window", 2);
            AssertEx.IsDocumentState(document, null, 1, 34, 38, 404);

            {
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(() =>
                                                                             SkylineWindow.ShowTransitionSettingsUI(TransitionSettingsUI.TABS.FullScan));

                PauseForScreenShot <TransitionSettingsUI.FullScanTab>("Full-scan settings", 3);

                RunUI(() =>
                {
                    Assert.AreEqual(FullScanPrecursorIsotopes.Count, transitionSettingsUI.PrecursorIsotopesCurrent);
                    Assert.AreEqual(20 * 1000, transitionSettingsUI.PrecursorRes);
                    Assert.AreEqual(FullScanMassAnalyzerType.tof, transitionSettingsUI.PrecursorMassAnalyzer);
                    Assert.AreEqual(IsolationScheme.SpecialHandlingType.ALL_IONS, transitionSettingsUI.IsolationSchemeName);
                    Assert.AreEqual(20 * 1000, transitionSettingsUI.ProductRes);
                    Assert.AreEqual(FullScanMassAnalyzerType.tof, transitionSettingsUI.ProductMassAnalyzer);
                });

                OkDialog(transitionSettingsUI, transitionSettingsUI.CancelDialog);
            }

            {
                var importResults = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);
                RunUI(() => importResults.ImportSimultaneousIndex = 2);

                PauseForScreenShot <ImportResultsDlg>("Import results form", 4);

                // Importing raw data from a sample which is a mixture of yeast and BSA

                var openDataSourceDialog = ShowDialog <OpenDataSourceDialog>(importResults.OkDialog);

                RunUI(() =>
                {
                    openDataSourceDialog.CurrentDirectory = new MsDataFilePath(DataPath);
                    openDataSourceDialog.SelectAllFileType(".d");
                });
                PauseForScreenShot <OpenDataSourceDialog>("Import results files", 5);

                OkDialog(openDataSourceDialog, openDataSourceDialog.Open);
            }

            string yeastReplicateName = Path.GetFileNameWithoutExtension(Yeast_BSA);

            PauseForScreenShot <AllChromatogramsGraph>("Importing results form", 6);

            WaitForDocumentChangeLoaded(document, 1000 * 60 * 60 * 10); // 10 minutes

            // Arrange graphs tiled
            RunUI(() =>
            {
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.AutoZoomBestPeak();
                SkylineWindow.ShowSplitChromatogramGraph(true);
            });
            FindNode("R.FKDLGEEHFK.G");

            RunUI(() => SkylineWindow.Size = new Size(1075, 799));
            RestoreViewOnScreen(7);
            PauseForScreenShot("Zoomed split graph panes onely", 7);

            RunUI(() => SkylineWindow.AutoZoomNone());
            PauseForScreenShot("Unzoomed split graph panes onely", 8);

            RunUI(() =>
            {
                SkylineWindow.AutoZoomBestPeak();
                SkylineWindow.ShowRTReplicateGraph();
                SkylineWindow.ShowGraphPeakArea(true);
                SkylineWindow.ShowChromatogramLegends(false);
                SkylineWindow.ShowPeakAreaLegend(false);
                SkylineWindow.NormalizeAreaGraphTo(AreaNormalizeToView.area_percent_view);
                SkylineWindow.SynchronizeZooming(true);
                SkylineWindow.Size = new Size(1547, 855);
            });
            RestoreViewOnScreen(9);
            PauseForScreenShot("Full window", 9);

            FindNode("TCVADESHAGCEK");
            var noteDlg = ShowDialog <EditNoteDlg>(SkylineWindow.EditNote);

            RunUI(() => noteDlg.NoteText = "Lost in yeast samples");

            PauseForScreenShot("Peptide note", 10);
            OkDialog(noteDlg, noteDlg.OkDialog);

            FindNode("NECFLSHKDDSPDLPK");
            PauseForScreenShot("Yeast chromatograms and RT only - prtsc-paste-edit", 11);

            PauseForScreenShot("Hover over BSA in water chromatogram - prtsc-paste-edit", 12);

            RestoreViewOnScreen(13);
            PauseForScreenShot("Full scan 2D MS1 graph", 13);
            {
                const double clickTime1 = 41.06;
                ClickChromatogram(clickTime1, 1.62E+6, PaneKey.PRECURSORS);
                var fullScanGraph = FindOpenForm <GraphFullScan>();
                RunUI(() => fullScanGraph.SetSpectrum(false));
                PauseForScreenShot("Full scan 3D MS1 graph", 13);
                ValidateClickTime(fullScanGraph, clickTime1);

                RunUI(() => fullScanGraph.SetZoom(false));
                PauseForScreenShot("Full scan unzoomed 3D MS1 graph", 14);

                const double clickTime2 = 41.02;
                RunUI(() => fullScanGraph.SetZoom(true));
                ClickChromatogram(clickTime2, 5.8E+4, PaneKey.PRODUCTS);
                PauseForScreenShot("Full scan 3D MS/MS graph", 15);
                ValidateClickTime(fullScanGraph, clickTime2);

                RunUI(() => fullScanGraph.SetZoom(false));
                PauseForScreenShot("Full scan unzoomed 3D MS/MS graph", 14);

                const double clickTime3 = 41.48;
                ClickChromatogram(yeastReplicateName, clickTime3, 3.14E+4, PaneKey.PRODUCTS);
                PauseForScreenShot("Interference full scan unzoomed 3D MS/MS graph", 15);
                ValidateClickTime(fullScanGraph, clickTime3);

                RunUI(SkylineWindow.HideFullScanGraph);
            }

            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, dlg =>
            {
                dlg.SelectedChromatograms = SkylineWindow.Document.Settings.MeasuredResults.Chromatograms.Skip(1);
                dlg.RemoveReplicates();
                dlg.OkDialog();
            });
            RunUI(() => SkylineWindow.SaveDocument());

            {
                var peptideSettingsUI = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
                RunUI(() => peptideSettingsUI.SelectedTab = PeptideSettingsUI.TABS.Prediction);
                var          driftPredictor = ShowDialog <EditDriftTimePredictorDlg>(peptideSettingsUI.AddDriftTimePredictor);
                const string predictorName  = "BSA";
                RunUI(() =>
                {
                    driftPredictor.SetPredictorName(predictorName);
                    driftPredictor.SetResolvingPower(50);
                    driftPredictor.GetDriftTimesFromResults();
                });
                PauseForScreenShot("Edit predictor form", 18);

                OkDialog(driftPredictor, () => driftPredictor.OkDialog());

                PauseForScreenShot("Peptide Settings - Prediction", 19);

                RunUI(() =>
                {
                    Assert.IsTrue(peptideSettingsUI.IsUseMeasuredRT);
                    Assert.AreEqual(6, peptideSettingsUI.TimeWindow);
                    Assert.AreEqual(predictorName, peptideSettingsUI.SelectedDriftTimePredictor);
                });

                OkDialog(peptideSettingsUI, peptideSettingsUI.OkDialog);
            }

            {
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                RunUI(() =>
                {
                    transitionSettingsUI.SelectedTab = TransitionSettingsUI.TABS.FullScan;
                    transitionSettingsUI.SetRetentionTimeFilter(RetentionTimeFilterType.scheduling_windows, 3);
                });

                PauseForScreenShot("Transition Settings - Full-Scan", 20);

                OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);
            }

            using (new WaitDocumentChange(1, true, 1000 * 60 * 60 * 5))
            {
                var choosePredictionReplicates = ShowDialog <ChooseSchedulingReplicatesDlg>(SkylineWindow.ImportResults);
                PauseForScreenShot("Choose Replicates form", 21);

                RunUI(() => choosePredictionReplicates.SelectOrDeselectAll(true));
                var importResults = ShowDialog <ImportResultsDlg>(choosePredictionReplicates.OkDialog);
                RunDlg <OpenDataSourceDialog>(importResults.OkDialog, openDataSourceDialog =>
                {
                    openDataSourceDialog.CurrentDirectory = new MsDataFilePath(DataPath);
                    openDataSourceDialog.SelectAllFileType(Yeast_BSA);
                    openDataSourceDialog.Open();
                });
            }
            WaitForGraphs();

            // CONSIDER: Test the peak annotations to ensure the filtering happened

            PauseForScreenShot("Yeast chromatogram and RTs - prtsc-paste-edit", 22);

            {
                const double clickTime = 42.20;
                ClickChromatogram(yeastReplicateName, clickTime, 2.904E+4, PaneKey.PRODUCTS);
                var fullScanGraph = FindOpenForm <GraphFullScan>();
                RunUI(() => fullScanGraph.SetZoom(true));
                PauseForScreenShot("Full-scan graph zoomed", 23);
                RunUI(() => Assert.IsTrue(fullScanGraph.TitleText.Contains(clickTime.ToString(CultureInfo.CurrentCulture))));
                RunUI(SkylineWindow.HideFullScanGraph);
            }

            FindNode("FKDLGEEHFK");

            PauseForScreenShot("Chromatograms (copy metafile) and legend - prtsc-paste-edit", 23);

            PauseForScreenShot("Peak area percentages (copy metafile)", 24);

            var docFiltered = SkylineWindow.Document;

            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, manageDlg =>
            {
                manageDlg.SelectedChromatograms = SkylineWindow.Document.Settings.MeasuredResults.Chromatograms.Take(1);
                manageDlg.ReimportResults();
                manageDlg.OkDialog();
            });

            WaitForDocumentChangeLoaded(docFiltered, 1000 * 60 * 60 * 5); // 5 minutes

            // TODO: Check peak ranks before and after
        }
Ejemplo n.º 4
0
        protected override void DoTest()
        {
            // Check backward compatibility with 19.1.9.338 and 350 when combined IMS got written to MsDataFilePath
            string legacyFile_19_1_9 = TestFilesDirs[1].GetTestPath(@"BSA-Training.sky");

            RunUI(() => SkylineWindow.OpenFile(legacyFile_19_1_9));
            VerifyCombinedIonMobility(WaitForDocumentLoaded());
            RunUI(() =>
            {
                SkylineWindow.SaveDocument();
                SkylineWindow.NewDocument();
                SkylineWindow.OpenFile(legacyFile_19_1_9);
            });
            VerifyCombinedIonMobility(WaitForDocumentLoaded());
            var    oldDoc  = SkylineWindow.Document;
            string skyFile = TestFilesDirs[0].GetTestPath(@"IMSFiltering\BSA-Training.sky");

            RunUI(() => SkylineWindow.OpenFile(skyFile));

            var document = WaitForDocumentChangeLoaded(oldDoc, 240 * 1000); // 4 minutes

            RunUI(() => SkylineWindow.Size = new Size(880, 560));
            RestoreViewOnScreen(2);
            PauseForScreenShot("Document open - full window", 2);
            AssertEx.IsDocumentState(document, null, 1, 34, 38, 404);

            {
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(() =>
                                                                             SkylineWindow.ShowTransitionSettingsUI(TransitionSettingsUI.TABS.FullScan));

                PauseForScreenShot <TransitionSettingsUI.FullScanTab>("Full-scan settings", 3);

                RunUI(() =>
                {
                    Assert.AreEqual(FullScanPrecursorIsotopes.Count, transitionSettingsUI.PrecursorIsotopesCurrent);
                    Assert.AreEqual(20 * 1000, transitionSettingsUI.PrecursorRes);
                    Assert.AreEqual(FullScanMassAnalyzerType.tof, transitionSettingsUI.PrecursorMassAnalyzer);
                    Assert.AreEqual(IsolationScheme.SpecialHandlingType.ALL_IONS, transitionSettingsUI.IsolationSchemeName);
                    Assert.AreEqual(20 * 1000, transitionSettingsUI.ProductRes);
                    Assert.AreEqual(FullScanMassAnalyzerType.tof, transitionSettingsUI.ProductMassAnalyzer);
                });

                OkDialog(transitionSettingsUI, transitionSettingsUI.CancelDialog);
            }

            {
                var importResults = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);
                RunUI(() => importResults.ImportSimultaneousIndex = 2);

                PauseForScreenShot <ImportResultsDlg>("Import results form", 4);

                // Importing raw data from a sample which is a mixture of yeast and BSA

                var openDataSourceDialog = ShowDialog <OpenDataSourceDialog>(importResults.OkDialog);

                RunUI(() =>
                {
                    openDataSourceDialog.CurrentDirectory = new MsDataFilePath(DataPath);
                    openDataSourceDialog.SelectAllFileType(".d");
                });
                PauseForScreenShot <OpenDataSourceDialog>("Import results files", 5);

                OkDialog(openDataSourceDialog, openDataSourceDialog.Open);
            }

            string yeastReplicateName = Path.GetFileNameWithoutExtension(Yeast_BSA);

            PauseForScreenShot <AllChromatogramsGraph>("Importing results form", 6);

            WaitForDocumentChangeLoaded(document, 1000 * 60 * 60 * 10); // 10 minutes

            // Arrange graphs tiled
            RunUI(() =>
            {
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.AutoZoomBestPeak();
                SkylineWindow.ShowSplitChromatogramGraph(true);
            });
            FindNode("R.FKDLGEEHFK.G");

            RunUI(() => SkylineWindow.Size = new Size(1075, 799));
            RestoreViewOnScreen(7);
            PauseForScreenShot("Zoomed split graph panes only", 7);

            RunUI(() => SkylineWindow.AutoZoomNone());
            PauseForScreenShot("Unzoomed split graph panes only", 8);

            const int wideWidth = 1547;

            RunUI(() =>
            {
                SkylineWindow.AutoZoomBestPeak();
                SkylineWindow.ShowRTReplicateGraph();
                SkylineWindow.ShowGraphPeakArea(true);
                SkylineWindow.ShowChromatogramLegends(false);
                SkylineWindow.ShowPeakAreaLegend(false);
                SkylineWindow.NormalizeAreaGraphTo(NormalizeOption.TOTAL);
                SkylineWindow.SynchronizeZooming(true);
                SkylineWindow.Size = new Size(wideWidth, 855);
            });
            RestoreViewOnScreen(9);
            PauseForScreenShot("Full window", 9);

            FindNode("TCVADESHAGCEK");
            var noteDlg = ShowDialog <EditNoteDlg>(SkylineWindow.EditNote);

            RunUI(() => noteDlg.NoteText = "Lost in yeast samples");

            PauseForScreenShot("Peptide note", 10);
            OkDialog(noteDlg, noteDlg.OkDialog);

            FindNode("NECFLSHKDDSPDLPK");
            RestoreViewOnScreen(11);
            const int narrowWidth = 1350;

            RunUI(() => SkylineWindow.Width = narrowWidth);
            PauseForScreenShot("Yeast chromatograms and RT only - prtsc-paste-edit", 11);
            PauseForScreenShot("Hover over BSA in water chromatogram - prtsc-paste-edit", 12);
            RunUI(() => SkylineWindow.Width = wideWidth);
            RestoreViewOnScreen(13);
            {
                const double clickTime1 = 41.06;
                ClickChromatogram(clickTime1, 1.62E+6, PaneKey.PRECURSORS);
                PauseForScreenShot("Full scan 2D MS1 graph", 13);
                var fullScanGraph = FindOpenForm <GraphFullScan>();
                RunUI(() => fullScanGraph.SetSpectrum(false));
                PauseForScreenShot("Full scan 3D MS1 graph", 13);
                ValidateClickTime(fullScanGraph, clickTime1);

                RunUI(() => fullScanGraph.SetZoom(false));
                PauseForScreenShot("Full scan unzoomed 3D MS1 graph", 14);

                const double clickTime2 = 41.02;
                RunUI(() => fullScanGraph.SetZoom(true));
                ClickChromatogram(clickTime2, 5.8E+4, PaneKey.PRODUCTS);
                PauseForScreenShot("Full scan 3D MS/MS graph", 15);
                ValidateClickTime(fullScanGraph, clickTime2);

                RunUI(() => fullScanGraph.SetZoom(false));
                PauseForScreenShot("Full scan unzoomed 3D MS/MS graph", 15);

                if (IsCoverShotMode)
                {
                    RunUI(() =>
                    {
                        Settings.Default.ChromatogramFontSize = 14;
                        Settings.Default.AreaFontSize         = 14;
                        SkylineWindow.ChangeTextSize(TreeViewMS.LRG_TEXT_FACTOR);
                    });

                    RestoreCoverViewOnScreen();

                    ClickChromatogram(clickTime2, 5.8E+4, PaneKey.PRODUCTS);

                    var manageResultsDlg = ShowDialog <ManageResultsDlg>(SkylineWindow.ManageResults);
                    RenameReplicate(manageResultsDlg, 0, "BSA");
                    RenameReplicate(manageResultsDlg, 1, "Yeast_BSA");
                    OkDialog(manageResultsDlg, manageResultsDlg.OkDialog);

                    RunUI(SkylineWindow.FocusDocument);

                    TakeCoverShot();
                    return;
                }

                const double clickTime3 = 41.48;
                ClickChromatogram(yeastReplicateName, clickTime3, 3.14E+4, PaneKey.PRODUCTS);
                PauseForScreenShot("Interference full scan unzoomed 3D MS/MS graph", 16);
                ValidateClickTime(fullScanGraph, clickTime3);

                RunUI(SkylineWindow.HideFullScanGraph);
            }

            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, dlg =>
            {
                dlg.SelectedChromatograms = SkylineWindow.Document.Settings.MeasuredResults.Chromatograms.Skip(1);
                dlg.RemoveReplicates();
                dlg.OkDialog();
            });
            RunUI(() => SkylineWindow.SaveDocument());

            {
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                RunUI(() =>
                {
                    transitionSettingsUI.SelectedTab = TransitionSettingsUI.TABS.IonMobility;
                    transitionSettingsUI.IonMobilityControl.WindowWidthType = IonMobilityWindowWidthCalculator
                                                                              .IonMobilityWindowWidthType.resolving_power;
                    transitionSettingsUI.IonMobilityControl.IonMobilityFilterResolvingPower = 50;
                });
                PauseForScreenShot("Setting ion mobility filter width calculation values", 17);


                var          editIonMobilityLibraryDlg = ShowDialog <EditIonMobilityLibraryDlg>(transitionSettingsUI.IonMobilityControl.AddIonMobilityLibrary);
                const string libraryName  = "BSA";
                var          databasePath = TestFilesDirs[1].GetTestPath(libraryName + IonMobilityDb.EXT);

                RunUI(() =>
                {
                    editIonMobilityLibraryDlg.LibraryName = libraryName;
                    editIonMobilityLibraryDlg.CreateDatabaseFile(databasePath); // Simulate user click on Create button
                    editIonMobilityLibraryDlg.SetOffsetHighEnergySpectraCheckbox(true);
                    editIonMobilityLibraryDlg.GetIonMobilitiesFromResults();
                });
                PauseForScreenShot("Edit ion mobility library form", 18);

                // Check that a new value was calculated for all precursors
                RunUI(() => Assert.AreEqual(SkylineWindow.Document.MoleculeTransitionGroupCount, editIonMobilityLibraryDlg.LibraryMobilitiesFlatCount));

                OkDialog(editIonMobilityLibraryDlg, () => editIonMobilityLibraryDlg.OkDialog());

                PauseForScreenShot <TransitionSettingsUI.IonMobilityTab>("Transition Settings - Ion Mobility", 19);

                RunUI(() =>
                {
                    transitionSettingsUI.SelectedTab = TransitionSettingsUI.TABS.FullScan;
                    transitionSettingsUI.SetRetentionTimeFilter(RetentionTimeFilterType.scheduling_windows, 3);
                });

                PauseForScreenShot("Transition Settings - Full-Scan", 20);

                OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);
                var peptideSettingsUI = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
                RunUI(() => peptideSettingsUI.SelectedTab = PeptideSettingsUI.TABS.Prediction);
                PauseForScreenShot("Peptide Settings - Prediction", 21);
                RunUI(() =>
                {
                    Assert.IsTrue(peptideSettingsUI.IsUseMeasuredRT);
                    Assert.AreEqual(6, peptideSettingsUI.TimeWindow);
                });

                OkDialog(peptideSettingsUI, peptideSettingsUI.OkDialog);
            }

            using (new WaitDocumentChange(1, true, 1000 * 60 * 60 * 5))
            {
                var choosePredictionReplicates = ShowDialog <ChooseSchedulingReplicatesDlg>(SkylineWindow.ImportResults);
                PauseForScreenShot("Choose Replicates form", 22);

                RunUI(() => choosePredictionReplicates.SelectOrDeselectAll(true));
                var importResults = ShowDialog <ImportResultsDlg>(choosePredictionReplicates.OkDialog);
                RunDlg <OpenDataSourceDialog>(importResults.OkDialog, openDataSourceDialog =>
                {
                    openDataSourceDialog.CurrentDirectory = new MsDataFilePath(DataPath);
                    openDataSourceDialog.SelectAllFileType(Yeast_BSA);
                    openDataSourceDialog.Open();
                });
            }
            WaitForGraphs();

            // Test to ensure the filtering happened
            if (!IsPauseForScreenShots) // Don't bring up unexpected UI in a screenshot run
            {
                TestReports();
            }

            RestoreViewOnScreen(11);
            RunUI(() => SkylineWindow.Width = narrowWidth);
            PauseForScreenShot("Yeast chromatogram and RTs - prtsc-paste-edit", 23);
            RunUI(() => SkylineWindow.Width = wideWidth);
            RestoreViewOnScreen(13);
            {
                const double clickTime = 42.20;
                ClickChromatogram(yeastReplicateName, clickTime, 2.904E+4, PaneKey.PRODUCTS);
                var fullScanGraph = FindOpenForm <GraphFullScan>();
                RunUI(() => fullScanGraph.SetZoom(true));
                RunUI(() => fullScanGraph.Parent.Parent.Size = new Size(671, 332));
                PauseForScreenShot("Full-scan graph zoomed", 24);
                RunUI(() => Assert.IsTrue(fullScanGraph.TitleText.Contains(clickTime.ToString(CultureInfo.CurrentCulture))));
                RunUI(SkylineWindow.HideFullScanGraph);
            }

            FindNode("FKDLGEEHFK");

            RunUI(() =>
            {
                SkylineWindow.Size = new Size(1547, 689);
                SkylineWindow.ShowProductTransitions();
                SkylineWindow.ShowPeakAreaLegend(true);
            });
            RestoreViewOnScreen(25);
            PauseForScreenShot("Chromatograms and Peak Areas - prtsc-paste-edit", 25);

            var docFiltered = SkylineWindow.Document;

            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, manageDlg =>
            {
                manageDlg.SelectedChromatograms = SkylineWindow.Document.Settings.MeasuredResults.Chromatograms.Take(1);
                manageDlg.ReimportResults();
                manageDlg.OkDialog();
            });

            WaitForDocumentChangeLoaded(docFiltered, 1000 * 60 * 60 * 5); // 5 minutes

            // TODO: Check peak ranks before and after

            AssertEx.IsFalse(IsRecordMode); // Make sure we turn this off before commit!
        }
Ejemplo n.º 5
0
        protected override void DoTest()
        {
            // iRT Retention Time Prediction
            string standardDocumentFile = GetTestPath("iRT-C18 Standard.sky"); // Not L10N

            RunUI(() => SkylineWindow.OpenFile(standardDocumentFile));
            WaitForDocumentLoaded();                                                       // might have some updating to do for protein metadata
            RunUI(() => SkylineWindow.SaveDocument(GetTestPath("iRT-C18 Calibrate.sky"))); // Not L10N

            // Load raw files for iRT calculator calibration p. 2
            const string unschedHuman1Fileroot = "A_D110907_SiRT_HELA_11_nsMRM_150selected_1_30min-5-35"; // Not L10N
            string       unschedHuman1Name     = unschedHuman1Fileroot.Substring(41);
            const string unschedHuman2Fileroot = "A_D110907_SiRT_HELA_11_nsMRM_150selected_2_30min-5-35"; // Not L10N
            string       unschedHuman2Name     = unschedHuman2Fileroot.Substring(41);

            ImportNewResults(new[] { unschedHuman1Fileroot, unschedHuman2Fileroot }, 41, false, false);
            var       docCalibrate = WaitForProteinMetadataBackgroundLoaderCompletedUI();
            const int pepCount = 11, tranCount = 33;

            AssertEx.IsDocumentState(docCalibrate, null, 1, pepCount, pepCount, tranCount);
            AssertResult.IsDocumentResultsState(docCalibrate, unschedHuman1Name, pepCount, pepCount, 0, tranCount, 0);
            AssertResult.IsDocumentResultsState(docCalibrate, unschedHuman2Name, pepCount, pepCount, 0, tranCount, 0);

            RunUI(() =>
            {
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.ShowRTPeptideGraph();
                using (var enumLabels = SkylineWindow.RTGraphController.GraphSummary.Categories.GetEnumerator())
                {
                    foreach (var nodePep in docCalibrate.Peptides)
                    {
                        Assert.IsTrue(enumLabels.MoveNext() && enumLabels.Current != null);
                        Assert.IsTrue(nodePep.Peptide.Sequence.StartsWith(enumLabels.Current.Substring(0, 3)));
                    }
                }
            });

            // Page 3.
            PauseForScreenShot <GraphSummary.RTGraphView>("RT graph metafile", 3);   // Peptide RT graph

            RunUI(() =>
            {
                SkylineWindow.ShowRTReplicateGraph();
                SkylineWindow.AutoZoomBestPeak();
                SkylineWindow.SelectedPath = docCalibrate.GetPathTo((int)SrmDocument.Level.Molecules, 0);
            });
            // Ensure graphs look like p. 3 and 4
            WaitForGraphs();

            RestoreViewOnScreen(04);
            PauseForScreenShot("Main window showing chromatograms and RT graph", 4);   // Skyline window with docked RT replicate comparison graph

            RunUI(() =>
            {
                Assert.AreEqual(3, SkylineWindow.RTGraphController.GraphSummary.CurveCount);
                Assert.AreEqual(2, SkylineWindow.RTGraphController.GraphSummary.Categories.Count());
                var chromGraphs = SkylineWindow.GraphChromatograms.ToArray();
                Assert.AreEqual(2, chromGraphs.Length);
                Assert.AreEqual(11.3, chromGraphs[0].GraphItems.First().BestPeakTime, 0.05);
                Assert.AreEqual(11.2, chromGraphs[1].GraphItems.First().BestPeakTime, 0.05);
            });

            var listTimes = new List <double>();

            for (int i = 0; i < docCalibrate.PeptideCount; i++)
            {
                int iPeptide = i;
                RunUI(() =>
                {
                    SkylineWindow.SelectedPath = docCalibrate.GetPathTo((int)SrmDocument.Level.Molecules, iPeptide);
                });
                WaitForGraphs();
                RunUI(() =>
                {
                    var chromGraphs = SkylineWindow.GraphChromatograms.ToArray();
                    double time1    = chromGraphs[0].GraphItems.First(g => g.BestPeakTime > 0).BestPeakTime;
                    double time2    = chromGraphs[1].GraphItems.First(g => g.BestPeakTime > 0).BestPeakTime;
                    listTimes.Add((time1 + time2) / 2);
                    Assert.AreEqual(time1, time2, 0.2);
                });
            }

            // Calibrate a calculator p. 4-5
            const string irtCalcName        = "iRT-C18";
            var          peptideSettingsUI1 = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
            var          editIrtCalc1       = ShowDialog <EditIrtCalcDlg>(peptideSettingsUI1.AddCalculator);

            RunUI(() =>
            {
                editIrtCalc1.CalcName = irtCalcName;
                editIrtCalc1.CreateDatabase(GetTestPath("iRT-C18.irtdb"));           // Not L10N
            });
            {
                var calibrateDlg = ShowDialog <CalibrateIrtDlg>(editIrtCalc1.Calibrate);
                RunUI(() =>
                {
                    calibrateDlg.UseResults();
                    Assert.AreEqual(11, calibrateDlg.StandardPeptideCount);
                    calibrateDlg.SetFixedPoints(1, 10);
                    for (int i = 0; i < calibrateDlg.StandardPeptideCount; i++)
                    {
                        Assert.AreEqual(listTimes[i], calibrateDlg.StandardPeptideList[i].RetentionTime, 0.2);
                    }
                });

                PauseForScreenShot <CalibrateIrtDlg>("Calibrate iRT Calculator form", 5);   // Calibrate iRT Calculator form

                RunUI(calibrateDlg.OkDialog);
            }
            Assert.IsTrue(WaitForConditionUI(() => editIrtCalc1.StandardPeptideCount == 11));

            PauseForScreenShot <EditIrtCalcDlg>("Edit iRT Calculater form", 6);   // Edit iRT Caclulator form

            // Check iRT values and update to defined values p. 6-7
            var    irtDefinitionPath = GetTestPath("iRT definition.xlsx");                      // Not L10N
            string irtDefText        = GetExcelFileText(irtDefinitionPath, "iRT-C18", 2, true); // Not L10N

            RunUI(() =>
            {
                var standardPeptidesArray = editIrtCalc1.StandardPeptides.ToArray();
                Assert.AreEqual(11, standardPeptidesArray.Length);
                Assert.AreEqual(0, standardPeptidesArray[1].Irt, 0.00001);
                Assert.AreEqual(100, standardPeptidesArray[10].Irt, 0.00001);
                CheckIrtStandardPeptides(standardPeptidesArray, irtDefText, 6);

                SetClipboardText(irtDefText);
                editIrtCalc1.DoPasteStandard();

                standardPeptidesArray = editIrtCalc1.StandardPeptides.ToArray();
                Assert.AreEqual(11, standardPeptidesArray.Length);
                Assert.AreEqual(0, standardPeptidesArray[1].Irt, 0.001);
                Assert.AreEqual(100, standardPeptidesArray[10].Irt, 0.005);
                CheckIrtStandardPeptides(standardPeptidesArray, irtDefText, 0.00001);
            });
            OkDialog(editIrtCalc1, editIrtCalc1.OkDialog);
            OkDialog(peptideSettingsUI1, peptideSettingsUI1.OkDialog);

            // Inspect RT regression graph p. 8
            RunUI(SkylineWindow.ShowRTRegressionGraphScoreToRun);
            WaitForRegression();

            RestoreViewOnScreen(08);
            PauseForScreenShot <GraphSummary.RTGraphView>("Retention Times Regression graph metafile", 8);   // RT Regression graph

            RunUI(() =>
            {
                VerifyRTRegression(0.15, 15.09, 0.9991);

                SkylineWindow.ShowSingleReplicate();
                SkylineWindow.SequenceTree.Focus();             // If the focus is left on the results tab, then the next line does nothing
                SkylineWindow.SelectedResultsIndex = 0;
            });

            WaitForRegression();

            RunUI(() =>
            {
                VerifyRTRegression(0.15, 15.15, 0.9991);

                SkylineWindow.SelectedResultsIndex = 1;
            });

            WaitForRegression();

            RunUI(() => VerifyRTRegression(0.15, 15.04, 0.9991));
            RunUI(() => SkylineWindow.ShowAverageReplicates());
            RunUI(() => SkylineWindow.SaveDocument());

            // Create a document containing human and standard peptides, p. 9
            RunUI(() => SkylineWindow.OpenFile(GetTestPath("iRT Human.sky")));
            WaitForProteinMetadataBackgroundLoaderCompletedUI(); // let peptide metadata background loader do its work
            RunUI(() =>
            {
                SkylineWindow.SelectedPath = new IdentityPath(SequenceTree.NODE_INSERT_ID);
                SkylineWindow.ImportFiles(standardDocumentFile);
            });
            WaitForProteinMetadataBackgroundLoaderCompletedUI(); // let peptide metadata background loader do its work

            RestoreViewOnScreen(09);
            PauseForScreenShot("Targets tree clipped out of main winodw", 9);   // Target tree

            RunUI(() =>
            {
                Assert.AreEqual("iRT-C18 Standard Peptides", SkylineWindow.SelectedNode.Text);           // Not L10N
                Assert.AreEqual(1231, SkylineWindow.DocumentUI.PeptideTransitionCount);

                SkylineWindow.SaveDocument(GetTestPath("iRT Human+Standard.sky"));           // Not L10N
                SkylineWindow.SaveDocument(GetTestPath("iRT Human+Standard Calibrate.sky")); // Not L10N
            });

            // Remove heavy precursors, p. 10
            var docHumanAndStandard = SkylineWindow.Document;

            RunDlg <RefineDlg>(SkylineWindow.ShowRefineDlg, refineDlg =>
            {
                refineDlg.RefineLabelType = IsotopeLabelType.heavy;
                refineDlg.OkDialog();
            });
            var docLightOnly = WaitForDocumentChange(docHumanAndStandard);

            Assert.AreEqual(632, docLightOnly.PeptideTransitionCount);

            // Create auto-calculate regression RT predictor, p. 10
            const string irtPredictorName = "iRT-C18"; // Not L10N

            {
                var docPre             = SkylineWindow.Document;
                var peptideSettingsUI2 = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
                RunUI(() => peptideSettingsUI2.ChooseRegression(irtPredictorName));
                var regressionDlg = ShowDialog <EditRTDlg>(peptideSettingsUI2.EditRegression);
                RunUI(() =>
                {
                    Assert.AreEqual(irtPredictorName, regressionDlg.Regression.Name);
                    Assert.AreEqual(irtCalcName, regressionDlg.Regression.Calculator.Name);
                    regressionDlg.SetAutoCalcRegression(true);
                    regressionDlg.SetTimeWindow(5);
                });

                PauseForScreenShot("Edit Retention Time Predictor form", 10);   // Edit retention time predictor form

                OkDialog(regressionDlg, regressionDlg.OkDialog);
                OkDialog(peptideSettingsUI1, peptideSettingsUI2.OkDialog);
                // Make sure iRT calculator is loaded
                WaitForDocumentChangeLoaded(docPre);
            }

            // Export unscheduled transition list, p. 11
            {
                const string calibrateBasename = "iRT Human+Standard Calibrate"; // Not L10N
                var          exportMethodDlg   = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                RunUI(() =>
                {
                    exportMethodDlg.ExportStrategy = ExportStrategy.Buckets;
                    exportMethodDlg.IgnoreProteins = true;
                    exportMethodDlg.MaxTransitions = 335;
                });

                PauseForScreenShot <ExportMethodDlg.TransitionListView>("Export Transition List form", 11);

                RunUI(() => exportMethodDlg.OkDialog(GetTestPath(calibrateBasename + TextUtil.EXT_CSV)));
                WaitForClosedForm(exportMethodDlg);

                Assert.AreEqual(332, File.ReadAllLines(GetTestPath(calibrateBasename + "_0001.csv")).Length);                                // Not L10N
                Assert.AreEqual(333 + (TestSmallMolecules ? 2 : 0), File.ReadAllLines(GetTestPath(calibrateBasename + "_0002.csv")).Length); // Not L10N
            }

            // Import human peptide calibration results p. 12
            ImportNewResults(new[] { unschedHuman1Fileroot, unschedHuman2Fileroot }, -1, true);

            // Review iRT-C18 graph p. 12-13
            RunUI(() => SkylineWindow.ChooseCalculator(irtCalcName));
            RunUI(SkylineWindow.ShowRTRegressionGraphScoreToRun);
            WaitForRegression();

            PauseForScreenShot <GraphSummary.RTGraphView>("RT Regression graph metafile", 13);

            RunUI(() =>
            {
                VerifyRTRegression(0.15, 15.09, 0.9991);
                Assert.AreEqual(11, SkylineWindow.DocumentUI.PeptideCount -
                                SkylineWindow.RTGraphController.Outliers.Length);
            });

            // Find all unintegrated transitions, p. 13-14
            {
                var findDlg = ShowDialog <FindNodeDlg>(SkylineWindow.ShowFindNodeDlg);
                RunUI(() =>
                {
                    findDlg.FindOptions = new FindOptions().ChangeText(string.Empty)
                                          .ChangeCustomFinders(Finders.ListAllFinders().Where(f => f is UnintegratedTransitionFinder));
                });

                PauseForScreenShot <FindNodeDlg>("Find form", 14);

                RestoreViewOnScreen(15);

                RunUI(() =>
                {
                    findDlg.FindAll();
                    findDlg.Close();
                });
                WaitForClosedForm(findDlg);
            }

            PauseForScreenShot <FindResultsForm>("Find Results pane", 14);

            var findAllForm = WaitForOpenForm <FindResultsForm>();

            Assert.IsNotNull(findAllForm);
            const int expectedItems = 6;

            RunUI(() =>
            {
                Assert.AreEqual(expectedItems, findAllForm.ItemCount);

                SkylineWindow.ShowAllTransitions();
                SkylineWindow.AutoZoomBestPeak();
            });

            // Review peaks with missing transitions, p. 15
            for (int i = 0; i < expectedItems; i++)
            {
                int iItem = i;
                RunUI(() => findAllForm.ActivateItem(iItem));
                WaitForGraphs();
                RunUI(() => Assert.AreEqual((int)SequenceTree.StateImageId.no_peak,
                                            SkylineWindow.SelectedNode.StateImageIndex));

                if (i == 2)
                {
                    PauseForScreenShot <GraphChromatogram>("Chromatogram graph metafile (1 of 2)", 15);
                }
                if (i == 3)
                {
                    RunUI(() =>
                    {
                        var document  = SkylineWindow.DocumentUI;
                        var nodeGroup = document.FindNode(SkylineWindow.SelectedPath.Parent) as TransitionGroupDocNode;
                        Assert.IsNotNull(nodeGroup);
                        var nodeTran = document.FindNode(SkylineWindow.SelectedPath) as TransitionDocNode;
                        Assert.IsNotNull(nodeTran);
                        var graph = SkylineWindow.GetGraphChrom(Resources.ImportResultsDlg_DefaultNewName_Default_Name);
                        // New peak picking picks correct peak
                        Assert.AreEqual(19.8, graph.BestPeakTime.Value, 0.05);
//                        TransitionGroupDocNode nodeGroupGraph;
//                        TransitionDocNode nodeTranGraph;
//                        var scaledRT = graph.FindAnnotatedPeakRetentionTime(19.8, out nodeGroupGraph, out nodeTranGraph);
//                        Assert.AreSame(nodeGroup, nodeGroupGraph);
//                        Assert.AreNotSame(nodeTran, nodeTranGraph);
//                        Assert.AreEqual(7, nodeTranGraph.Transition.Ordinal);   // y7
//                        graph.FirePickedPeak(nodeGroupGraph, nodeTranGraph, scaledRT);
                    });
                }
                if (i == 4)
                {
                    PauseForScreenShot <GraphChromatogram>("Chromatogram graph metafile (2 of 2)", 15);   // Chromatogram graph
                }
            }

            // New peak picking picks correct peak
//            RunUI(() => findAllForm.ActivateItem(3));
//            PauseForScreenShot<GraphChromatogram>("Chromatogram graph metafile (3 of 3)", 15);

            RunUI(SkylineWindow.ToggleIntegrateAll);
            RunUI(findAllForm.Close);
            WaitForClosedForm(findAllForm);

            RestoreViewOnScreen(17);

            // Calculate new iRT values for human peptides, p. 16
            {
                var editIrtCalc2 = ShowDialog <EditIrtCalcDlg>(SkylineWindow.ShowEditCalculatorDlg);
                RunUI(() => Assert.AreEqual(0, editIrtCalc2.LibraryPeptideCount));
                var addPeptidesDlg = ShowDialog <AddIrtPeptidesDlg>(editIrtCalc2.AddResults);

                PauseForScreenShot <AddIrtPeptidesDlg>("Add Peptides form", 15);

                RunUI(() =>
                {
                    Assert.AreEqual(148, addPeptidesDlg.PeptidesCount);
                    Assert.AreEqual(2, addPeptidesDlg.RunsConvertedCount);
                    Assert.AreEqual(0, addPeptidesDlg.RunsFailedCount);
                });
                var recalibrateDlg = ShowDialog <MultiButtonMsgDlg>(addPeptidesDlg.OkDialog);
                OkDialog(recalibrateDlg, recalibrateDlg.Btn1Click);

                PauseForScreenShot <EditIrtCalcDlg>("Edit iRT Calculator form", 16);

                RunUI(() => Assert.AreEqual(148, editIrtCalc2.LibraryPeptideCount));
                RunUI(editIrtCalc2.OkDialog);
                WaitForClosedForm(editIrtCalc2);
            }

            // Check the RT regression, p. 17
            WaitForRegression();

            PauseForScreenShot <GraphSummary.RTGraphView>("RT Regression graph metafile", 17);

            RunUI(() =>
            {
                VerifyRTRegression(0.15, 15.09, 0.99985);
                Assert.AreEqual(0, SkylineWindow.RTGraphController.Outliers.Length);

                SkylineWindow.SaveDocument();
                SkylineWindow.HideFindResults();
            });

            // Recalibrate method to 90-minute gradient, p. 18
            RunUI(() => SkylineWindow.OpenFile(GetTestPath("iRT Human+Standard.sky"))); // Not L10N
            RunDlg <FindNodeDlg>(SkylineWindow.ShowFindNodeDlg, findDlg =>
            {
                findDlg.FindOptions = new FindOptions().ChangeText("NSAQ");         // Not L10N
                findDlg.FindNext();
                findDlg.Close();
            });
            RunUI(SkylineWindow.EditDelete);

            {
                var peptideSettingsUI = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
                RunUI(() =>
                {
                    peptideSettingsUI.SelectedTab = PeptideSettingsUI.TABS.Prediction;
                    peptideSettingsUI.ChooseRegression(irtPredictorName);
                    peptideSettingsUI.IsUseMeasuredRT = true;
                    peptideSettingsUI.TimeWindow      = 5;
                });

                PauseForScreenShot <PeptideSettingsUI.PredictionTab>("Peptide Settings - Prediction tab", 18);

                RunUI(peptideSettingsUI.OkDialog);
                WaitForClosedForm(peptideSettingsUI);
            }

            // Import 90-minute standard mix run, p. 19
            const string unsched90MinFileroot = "A_D110913_SiRT_HELA_11_nsMRM_150selected_90min-5-40_TRID2215_01"; // Not L10N

            ImportNewResults(new[] { unsched90MinFileroot }, -1, false);
            WaitForGraphs();

            // Verify regression graph, p. 19
            RunUI(SkylineWindow.ShowRTRegressionGraphScoreToRun);
            WaitForRegression();
            PauseForScreenShot <GraphSummary.RTGraphView>("RT Regression graph metafile", 19);
            RunUI(() =>
            {
                VerifyRTRegression(0.40, 24.77, 0.9998);
                Assert.AreEqual(147, SkylineWindow.RTGraphController.Outliers.Length);
            });

            // Check scheduling graph, p. 20
            RunUI(SkylineWindow.ShowRTSchedulingGraph);
            RunDlg <SchedulingGraphPropertyDlg>(() => SkylineWindow.ShowRTPropertyDlg(SkylineWindow.GraphRetentionTime), propertyDlg =>
            {
                propertyDlg.TimeWindows = new[] { 2.0, 5.0, 10.0 };
                propertyDlg.OkDialog();
            });
            WaitForGraphs();

            PauseForScreenShot <GraphSummary.RTGraphView>("RT Scheduling graph metafile", 20);

            // Export new 90-minute scheduled transition list, p. 22
            const string scheduledBasename = "iRT Human+Standard"; // Not L10N

            {
                var exportMethodDlg = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                RunUI(() =>
                {
                    exportMethodDlg.ExportStrategy = ExportStrategy.Buckets;
                    exportMethodDlg.MaxTransitions = 265;
                    exportMethodDlg.MethodType     = ExportMethodType.Scheduled;
                });

                PauseForScreenShot <ExportMethodDlg.TransitionListView>("Export Transition List form", 21);

                RunUI(() => exportMethodDlg.OkDialog(GetTestPath(scheduledBasename + TextUtil.EXT_CSV)));
                WaitForClosedForm(exportMethodDlg);
            }

            Assert.AreEqual(1223 + (TestSmallMolecules ? 4 : 0), File.ReadAllLines(GetTestPath(scheduledBasename + "_0001.csv")).Length); // Not L10N
            Assert.IsFalse(File.Exists(GetTestPath("iRT Human+Standard_0002.csv")));                                                      // Not L10N

            // Import scheduled data, p. 23
            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, manageResultsDlg =>
            {
                manageResultsDlg.RemoveAllReplicates();
                manageResultsDlg.OkDialog();
            });

            RunUI(() => SkylineWindow.SaveDocument());
            const string sched90MinFileroot = "A_D110913_SiRT_HELA_11_sMRM_150selected_90min-5-40_SIMPLE"; // Not L10N

            ImportNewResults(new[] { sched90MinFileroot }, -1, false);

            RunUI(SkylineWindow.ShowRTRegressionGraphScoreToRun);
            WaitForRegression();

            PauseForScreenShot <GraphSummary.RTGraphView>("RT Regression graph metafile", 23);

            // Review regression and outliers, p. 24
            RunUI(() =>
            {
                VerifyRTRegression(0.358, 25.920, 0.91606);
                Assert.AreEqual(0, SkylineWindow.RTGraphController.Outliers.Length);
            });

            RunDlg <RegressionRTThresholdDlg>(SkylineWindow.ShowRegressionRTThresholdDlg, thresholdDlg =>
            {
                thresholdDlg.Threshold = 0.998;
                thresholdDlg.OkDialog();
            });

            PauseForScreenShot <GraphSummary.RTGraphView>("RT Regression graph metafile", 24);

            // Verify 2 outliers highlighed and removed, p. 25
            WaitForConditionUI(() => SkylineWindow.RTGraphController.Outliers.Length == 2);
            RunUI(() =>
            {
                VerifyRTRegression(0.393, 24.85, 0.9989);

                SkylineWindow.RemoveRTOutliers();
            });
            WaitForRegression();

            PauseForScreenShot <GraphSummary.RTGraphView>("RT Regression graph metafile", 25);

            // Check outlier removal, p. 25
            RunUI(() =>
            {
                VerifyRTRegression(0.393, 24.85, 0.9989);
                Assert.AreEqual(0, SkylineWindow.RTGraphController.Outliers.Length);
            });

            // Review a peak and its predicted retention time, p. 26
            RunDlg <FindNodeDlg>(SkylineWindow.ShowFindNodeDlg, findDlg =>
            {
                findDlg.FindOptions = new FindOptions().ChangeText("DATNVG");         // Not L10N
                findDlg.FindNext();
                findDlg.Close();
            });
            WaitForGraphs();

            RestoreViewOnScreen(27);
            PauseForScreenShot <GraphChromatogram>("Chromatogram graph metafile", 26);   // Chromatogram graph

            RunUI(() =>
            {
                var graphChrom = SkylineWindow.GetGraphChrom(sched90MinFileroot);
                Assert.IsTrue(graphChrom.BestPeakTime.HasValue);
                Assert.AreEqual(47.3, graphChrom.BestPeakTime.Value, 0.05);
                Assert.IsTrue(graphChrom.PredictedRT.HasValue);
                Assert.AreEqual(47.6, graphChrom.PredictedRT.Value, 0.05);
            });

            // Import retention times from a spectral library, p. 27
            RestoreViewOnScreen(17); // get regression graph back
            {
                var editIrtCalc  = ShowDialog <EditIrtCalcDlg>(SkylineWindow.ShowEditCalculatorDlg);
                var addLibrayDlg = ShowDialog <AddIrtSpectralLibrary>(editIrtCalc.AddLibrary);
                RunUI(() =>
                {
                    addLibrayDlg.Source   = SpectralLibrarySource.file;
                    addLibrayDlg.FilePath = GetTestPath(Path.Combine("Yeast+Standard",               // Not L10N
                                                                     "Yeast_iRT_C18_0_00001.blib")); // Not L10N
                });

                PauseForScreenShot <AddIrtSpectralLibrary>("Add Spectral Library form", 27);

                // Verify converted peptide iRT values and OK dialogs, p. 28
                var addPeptidesDlg = ShowDialog <AddIrtPeptidesDlg>(addLibrayDlg.OkDialog);
                RunUI(() =>
                {
                    Assert.AreEqual(558, addPeptidesDlg.PeptidesCount);
                    Assert.AreEqual(1, addPeptidesDlg.RunsConvertedCount);  // Libraries now convert through internal alignment to single RT scale
                    Assert.AreEqual(3, addPeptidesDlg.KeepPeptidesCount);
                });

                PauseForScreenShot <AddIrtPeptidesDlg>("Add Peptides form", 28);

                var recalibrateDlg = ShowDialog <MultiButtonMsgDlg>(addPeptidesDlg.OkDialog);
                OkDialog(recalibrateDlg, recalibrateDlg.Btn1Click);

                Assert.IsTrue(WaitForConditionUI(() => editIrtCalc.LibraryPeptideCount == 706));
                RunUI(editIrtCalc.OkDialog);
                WaitForClosedForm(editIrtCalc);
            }

            // Inspect MS1 filtered Skyline file created from library DDA data, p. 29
            RunUI(() => SkylineWindow.OpenFile(GetTestPath(Path.Combine("Yeast+Standard", // Not L10N
                                                                        "Yeast+Standard (refined) - 2min.sky"))));
            WaitForDocumentLoaded();
            RunUI(() => SkylineWindow.SelectedPath = SkylineWindow.DocumentUI.GetPathTo((int)SrmDocument.Level.Molecules, 0));
            WaitForRegression();

            // Verify numbers that show up in the screenshot
            RunUI(() =>
            {
                // If the cache gets rebuilt, then because the chromatograms
                // were minimized, the peak picking is not exactly the same
                // using the minimized chromatograms.
                VerifyRTRegression(0.3, 19.37, 0.9998);
                var graphChrom = SkylineWindow.GetGraphChrom("Velos_2011_1110_RJ_16");           // Not L10N
                Assert.AreEqual(37.6, graphChrom.RetentionMsMs[0], 0.05);
                Assert.IsTrue(graphChrom.BestPeakTime.HasValue);
                Assert.AreEqual(37.6, graphChrom.BestPeakTime.Value, 0.05);
                graphChrom = SkylineWindow.GetGraphChrom("Velos_2011_1110_RJ_14");           // Not L10N
                Assert.AreEqual(37.3, graphChrom.RetentionMsMs[0], 0.05);
                Assert.AreEqual(37.6, graphChrom.RetentionMsMs[1], 0.05);
                Assert.IsTrue(graphChrom.BestPeakTime.HasValue);
                Assert.AreEqual(37.4, graphChrom.BestPeakTime.Value, 0.05);
            });

            PauseForScreenShot("Main window", 29);

            // Add results and verify add dialog counts, p. 29-30
            {
                var editIrtCalc    = ShowDialog <EditIrtCalcDlg>(SkylineWindow.ShowEditCalculatorDlg);
                var addPeptidesDlg = ShowDialog <AddIrtPeptidesDlg>(editIrtCalc.AddResults);
                RunUI(() =>
                {
                    Assert.AreEqual(0, addPeptidesDlg.PeptidesCount);
                    Assert.AreEqual(2, addPeptidesDlg.RunsConvertedCount);
                    Assert.AreEqual(558, addPeptidesDlg.OverwritePeptidesCount);
                    Assert.AreEqual(3, addPeptidesDlg.ExistingPeptidesCount);
                });

                PauseForScreenShot <AddIrtPeptidesDlg>("Add Peptides form", 30);

                var recalibrateDlg = ShowDialog <MultiButtonMsgDlg>(addPeptidesDlg.OkDialog);
                OkDialog(recalibrateDlg, recalibrateDlg.Btn1Click);
                RunUI(editIrtCalc.OkDialog);
                WaitForClosedForm(editIrtCalc);
            }

            RunUI(() => SkylineWindow.SaveDocument());
            RunUI(SkylineWindow.NewDocument);
        }
Ejemplo n.º 6
0
        protected override void DoTest()
        {
            TestSmallMolecules = false; // The presence of the extra test node without any results is incompatible with what's being tested here.

            // Clean-up before running the test
            RunUI(() => SkylineWindow.ModifyDocument("Set default settings",
                                                     d => d.ChangeSettings(SrmSettingsList.GetDefault())));

            SrmDocument doc = SkylineWindow.Document;

            const string documentBaseName = "Ms1FilterTutorial";
            string       documentFile     = GetTestPath(documentBaseName + SrmDocument.EXT);

            RunUI(() => SkylineWindow.SaveDocument(documentFile));

            // show the empty Transition Setting dialog
            var transitionSettingsDlg = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);

            RunUI(() => transitionSettingsDlg.SelectedTab = TransitionSettingsUI.TABS.FullScan);
            PauseForScreenShot <TransitionSettingsUI.FullScanTab>("Transition Settings - Full-Scan tab nothing set", 2);
            OkDialog(transitionSettingsDlg, transitionSettingsDlg.OkDialog);

            // Launch the wizard
            var importPeptideSearchDlg = ShowDialog <ImportPeptideSearchDlg>(SkylineWindow.ShowImportPeptideSearchDlg);

            // We're on the "Build Spectral Library" page of the wizard.
            // Add the test xml file to the search files list and try to
            // build the document library.
            string[] searchFiles =
            {
                GetTestPath("100803_0001_MCF7_TiB_L.group.xml"),      // Not L10N
                GetTestPath("100803_0005b_MCF7_TiTip3.group.xml")     // Not L10N
            };
            PauseForScreenShot <ImportPeptideSearchDlg.SpectraPage>("Import Peptide Search - Build Spectral Library empty page", 3);

            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage ==
                              ImportPeptideSearchDlg.Pages.spectra_page);
                importPeptideSearchDlg.BuildPepSearchLibControl.AddSearchFiles(searchFiles);
            });
            PauseForScreenShot <ImportPeptideSearchDlg.SpectraPage>("Import Peptide Search - Build Spectral Library populated page", 4);

            var ambiguousDlg = ShowDialog <MessageDlg>(importPeptideSearchDlg.ClickNextButtonNoCheck);

            OkDialog(ambiguousDlg, ambiguousDlg.OkDialog);

            // Verify document library was built
            string docLibPath          = BiblioSpecLiteSpec.GetLibraryFileName(documentFile);
            string redundantDocLibPath = BiblioSpecLiteSpec.GetRedundantName(docLibPath);

            Assert.IsTrue(File.Exists(docLibPath) && File.Exists(redundantDocLibPath));
            var librarySettings = SkylineWindow.Document.Settings.PeptideSettings.Libraries;

            Assert.IsTrue(librarySettings.HasDocumentLibrary);

            // We're on the "Extract Chromatograms" page of the wizard.
            // All the test results files are in the same directory as the
            // document file, so all the files should be found, and we should
            // just be able to move to the next page.
            WaitForConditionUI(() => importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.chromatograms_page);
            PauseForScreenShot <ImportPeptideSearchDlg.ChromatogramsPage>("Import Peptide Search - Extract Chromatograms page", 5);

            var importResultsNameDlg = ShowDialog <ImportResultsNameDlg>(() => importPeptideSearchDlg.ClickNextButton());

            PauseForScreenShot <ImportResultsNameDlg>("Import Results - Common prefix form", 6);

            OkDialog(importResultsNameDlg, importResultsNameDlg.YesDialog);

            // Wait for the "Add Modifications" page of the wizard.
            WaitForConditionUI(() => importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.match_modifications_page);

            List <string> modsToCheck = new List <string> {
                "Phospho (ST)", "Phospho (Y)", "Oxidation (M)"
            };                                                                                              // Not L10N

            RunUI(() =>
            {
                importPeptideSearchDlg.MatchModificationsControl.CheckedModifications = modsToCheck;
            });
            PauseForScreenShot <ImportPeptideSearchDlg.MatchModsPage>("Import Peptide Search - Add Modifications page", 7);
            RunUI(() => Assert.IsTrue(importPeptideSearchDlg.ClickNextButton()));

            // We're on the "Configure MS1 Full-Scan Settings" page of the wizard.
            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.full_scan_settings_page);
                importPeptideSearchDlg.FullScanSettingsControl.PrecursorCharges      = new[] { 2, 3, 4 };
                importPeptideSearchDlg.FullScanSettingsControl.PrecursorMassAnalyzer = FullScanMassAnalyzerType.tof;
                importPeptideSearchDlg.FullScanSettingsControl.PrecursorRes          = 10 * 1000;

                Assert.AreEqual(importPeptideSearchDlg.FullScanSettingsControl.PrecursorIsotopesCurrent, FullScanPrecursorIsotopes.Count);
                Assert.AreEqual(FullScanMassAnalyzerType.tof, importPeptideSearchDlg.FullScanSettingsControl.PrecursorMassAnalyzer);
                Assert.AreEqual(10 * 1000, importPeptideSearchDlg.FullScanSettingsControl.PrecursorRes);
                Assert.AreEqual(3, importPeptideSearchDlg.FullScanSettingsControl.Peaks);
                Assert.AreEqual(RetentionTimeFilterType.ms2_ids, importPeptideSearchDlg.FullScanSettingsControl.RetentionTimeFilterType);
                Assert.AreEqual(5, importPeptideSearchDlg.FullScanSettingsControl.TimeAroundMs2Ids);
            });
            PauseForScreenShot <ImportPeptideSearchDlg.Ms1FullScanPage>("Import Peptide Search - Configure MS1 Full-Scan Settings page", 8);

            RunUI(() => Assert.IsTrue(importPeptideSearchDlg.ClickNextButton()));

            // Last page of wizard - Import Fasta.
            string fastaPath = GetTestPath("12_proteins.062011.fasta");

            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.import_fasta_page);
                Assert.AreEqual("Trypsin [KR | P]", importPeptideSearchDlg.ImportFastaControl.Enzyme.GetKey());
                importPeptideSearchDlg.ImportFastaControl.MaxMissedCleavages = 2;
                importPeptideSearchDlg.ImportFastaControl.SetFastaContent(fastaPath);
                Assert.IsFalse(importPeptideSearchDlg.ImportFastaControl.DecoyGenerationEnabled);
            });
            PauseForScreenShot <ImportPeptideSearchDlg.FastaPage>("Import Peptide Search - Import FASTA page", 10);

            var peptidesPerProteinDlg = ShowDialog <PeptidesPerProteinDlg>(() => importPeptideSearchDlg.ClickNextButton());

            WaitForCondition(() => peptidesPerProteinDlg.DocumentFinalCalculated);
            RunUI(() =>
            {
                int proteinCount, peptideCount, precursorCount, transitionCount;
                peptidesPerProteinDlg.NewTargetsAll(out proteinCount, out peptideCount, out precursorCount, out transitionCount);
                Assert.AreEqual(11, proteinCount);
                Assert.AreEqual(51, peptideCount);
                Assert.AreEqual(52, precursorCount);
                Assert.AreEqual(156, transitionCount);
                peptidesPerProteinDlg.NewTargetsFinal(out proteinCount, out peptideCount, out precursorCount, out transitionCount);
                Assert.AreEqual(11, proteinCount);
                Assert.AreEqual(51, peptideCount);
                Assert.AreEqual(52, precursorCount);
                Assert.AreEqual(156, transitionCount);
            });
            OkDialog(peptidesPerProteinDlg, peptidesPerProteinDlg.OkDialog);
            PauseForScreenShot <AllChromatogramsGraph>("Loading chromatograms window", 11);
            WaitForDocumentChangeLoaded(doc, 8 * 60 * 1000); // 10 minutes

            var libraryExplorer   = ShowDialog <ViewLibraryDlg>(() => SkylineWindow.OpenLibraryExplorer(documentBaseName));
            var matchedPepModsDlg = WaitForOpenForm <AddModificationsDlg>();

            PauseForScreenShot <MultiButtonMsgDlg>("Add mods alert", 12);
            RunUI(() =>
            {
                Assert.AreEqual(13, matchedPepModsDlg.NumMatched);
                Assert.AreEqual(0, matchedPepModsDlg.NumUnmatched);
                matchedPepModsDlg.CancelDialog();
            });
            RunUI(() =>
            {
                libraryExplorer.GraphSettings.ShowBIons        = true;
                libraryExplorer.GraphSettings.ShowYIons        = true;
                libraryExplorer.GraphSettings.ShowCharge1      = true;
                libraryExplorer.GraphSettings.ShowCharge2      = true;
                libraryExplorer.GraphSettings.ShowPrecursorIon = true;
            });

            PauseForScreenShot <ViewLibraryDlg>("Spectral Library Explorer", 13);
            RunUI(() =>
            {
                const string sourceFirst = "100803_0005b_MCF7_TiTip3.wiff";
                const double timeFirst   = 35.2128;
                Assert.AreEqual(sourceFirst, libraryExplorer.SourceFile);
                Assert.AreEqual(timeFirst, libraryExplorer.RetentionTime, 0.0001);
                libraryExplorer.SelectedIndex++;
                Assert.AreNotEqual(sourceFirst, libraryExplorer.SourceFile);
                Assert.AreNotEqual(timeFirst, libraryExplorer.RetentionTime, 0.0001);
            });
            OkDialog(libraryExplorer, libraryExplorer.CancelDialog);

            const int TIB_L = 0; // index for Tib_L
            const int TIP3  = 1; // index for Tip3

            AssertEx.IsDocumentState(SkylineWindow.Document, null, 11, 51, 52, 156);
            AssertResult.IsDocumentResultsState(SkylineWindow.Document, GetFileNameWithoutExtension(searchFiles[TIB_L]), 51, 52, 0, 156, 0);
            AssertResult.IsDocumentResultsState(SkylineWindow.Document, GetFileNameWithoutExtension(searchFiles[TIP3]), 51, 52, 0, 156, 0);
            string Tib_LFilename = searchFiles[TIB_L].Replace(".group.xml", PreferedExtAbWiff);
            string Tip3Filename  = searchFiles[TIP3].Replace(".group.xml", PreferedExtAbWiff);

            // Select the first transition group.
            RunUI(() =>
            {
                SkylineWindow.SequenceTree.SelectedPath =
                    SkylineWindow.Document.GetPathTo((int)SrmDocument.Level.Molecules, 0);
                SkylineWindow.GraphSpectrumSettings.ShowAIons        = true;
                SkylineWindow.GraphSpectrumSettings.ShowBIons        = true;
                SkylineWindow.GraphSpectrumSettings.ShowYIons        = true;
                SkylineWindow.GraphSpectrumSettings.ShowPrecursorIon = true;
                SkylineWindow.ExpandPrecursors();
                SkylineWindow.ChangeTextSize(TreeViewMS.LRG_TEXT_FACTOR);
            });
            RunDlg <SpectrumChartPropertyDlg>(SkylineWindow.ShowSpectrumProperties, dlg =>
            {
                dlg.FontSize = GraphFontSize.NORMAL;
                dlg.OkDialog();
            });
            RunDlg <ChromChartPropertyDlg>(SkylineWindow.ShowChromatogramProperties, dlg =>
            {
                dlg.FontSize = GraphFontSize.NORMAL;
                dlg.OkDialog();
            });
            RunUI(() =>
            {
                // Make window screenshot size
                if (IsPauseForScreenShots && SkylineWindow.WindowState != FormWindowState.Maximized)
                {
                    SkylineWindow.Width  = 1160;
                    SkylineWindow.Height = 792;
                }
            });
            RestoreViewOnScreen(13);
            PauseForScreenShot("Main window with imported data", 14);

//            RunUIWithDocumentWait(() =>
//            {
//                SkylineWindow.ToggleIntegrateAll(); // TODO: No longer necessary.  Change in tutorial
//            });
            RunUI(() =>
            {
                SkylineWindow.ShowGraphPeakArea(true);
                SkylineWindow.ShowPeakAreaReplicateComparison();
                SkylineWindow.NormalizeAreaGraphTo(AreaNormalizeToView.none);
                Settings.Default.ShowDotProductPeakArea = true;
                Settings.Default.ShowLibraryPeakArea    = true;
            });
            PauseForScreenShot <GraphSummary.AreaGraphView>("Peak Areas view (show context menu)", 16);

            RestoreViewOnScreen(15);
            RunUI(() =>
            {
                SkylineWindow.AutoZoomBestPeak();
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.ShowChromatogramLegends(false);
            });
            PauseForScreenShot("Main window layout", 17);

            int atest = 0;

            CheckAnnotations(TIB_L, 0, atest++);
            int pepIndex = 3;

            RunUI(() => SkylineWindow.CollapsePeptides());
            RunUI(() => SkylineWindow.ShowAlignedPeptideIDTimes(true));
            ChangePeakBounds(TIB_L, pepIndex, 38.79, 39.385);
            PauseForScreenShot("Chromatogram graphs clipped from main window", 19);
            CheckAnnotations(TIB_L, pepIndex, atest++);

            var alignmentForm = ShowDialog <AlignmentForm>(() => SkylineWindow.ShowRetentionTimeAlignmentForm());

            RunUI(() =>
            {
                alignmentForm.Width  = 711;
                alignmentForm.Height = 561;
                alignmentForm.ComboAlignAgainst.SelectedIndex = 0;     // to match what's in the tutorial doc
            });
            PauseForScreenShot <AlignmentForm>("Retention time alignment form", 20);

            OkDialog(alignmentForm, alignmentForm.Close);
            PauseForScreenShot("Status bar clipped from main window - 4/51 pep 4/52 prec 10/156 tran", 21);

            pepIndex = JumpToPeptide("SSKASLGSLEGEAEAEASSPK");
            RunUI(() => SkylineWindow.ShowChromatogramLegends(true));
            Assert.IsTrue(8 == pepIndex);
            PauseForScreenShot("Chromatogram graph metafiles for 9th peptide", 21);
            CheckAnnotations(TIB_L, pepIndex, atest++);

            ZoomSingle(TIP3, 32.6, 41.4); // simulate the wheel scroll described in tutorial
            PauseForScreenShot("Chromatogram graph metafile showing all peaks for 1_MCF_TiB_L", 22);
            CheckAnnotations(TIB_L, pepIndex, atest++);

            // current TIB_L peak should have idotp .87 and ppm -6.9
            Assert.AreEqual(0.87, GetTransitionGroupChromInfo(TIB_L, pepIndex).IsotopeDotProduct ?? -1, .005);
            Assert.AreEqual(-10.8, GetTransitionChromInfo(TIB_L, pepIndex, 0).MassError ?? -1, .05);

            ChangePeakBounds(TIB_L, pepIndex, 36.5, 38.0);

            // now current TIB_L peak should have idotp .9 and ppm -6.5
            Assert.AreEqual(0.9, GetTransitionGroupChromInfo(TIB_L, pepIndex).IsotopeDotProduct ?? -1, .005);
            Assert.AreEqual(-9.4, GetTransitionChromInfo(TIB_L, pepIndex, 0).MassError ?? -1, .05);
            CheckAnnotations(TIB_L, pepIndex, atest++);

            var undoIndex = SkylineWindow.Document.RevisionIndex; // preserve for simulating ctrl-z

            PickPeakBoth(pepIndex, 40.471035, 40.8134);           // select peak for both chromatograms at these respective retention times
            PauseForScreenShot <GraphSummary.AreaGraphView>("Peak Areas graph metafile", 23);

            int[] m1Thru4 = { 1, 2, 3, 4, 5 };
            PickTransitions(pepIndex, m1Thru4, "Transition pick list filtered", 24, "Transition pick list unfiltered", 24); // turn on chromatograms
            PickPeakBoth(pepIndex, 36.992836, 37.3896027);                                                                  // select peak for both chromatograms at these respective retention times
            ZoomSingle(TIP3, 32.4, 39.6);                                                                                   // set the view for screenshot
            PauseForScreenShot("Chromatogram graph metafile comparing 33 and 37 minute peaks", 25);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            RevertDoc(undoIndex);                             // undo changes
            pepIndex = JumpToPeptide("ASLGSLEGEAEAEASSPKGK"); // Not L10N
            Assert.IsTrue(10 == pepIndex);
            PauseForScreenShot("Chhromatogram graph meta files for peptide ASLGSLEGEAEAEASSPKGK", 26);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            PickTransitions(pepIndex, m1Thru4); // turn on M+3 and M+4
            ChangePeakBounds(TIP3, pepIndex, 37.35, 38.08);
            ZoomSingle(TIP3, 36.65, 39.11);     // simulate the wheel scroll described in tutorial
            PauseForScreenShot("upper - Chromatogram graph metafile for peptide ASLGSLEGEAEAEASSPKGK with adjusted integration", 27);
            CheckAnnotations(TIP3, pepIndex, atest++);

            RevertDoc(undoIndex);                              // undo changes
            pepIndex = JumpToPeptide("AEGEWEDQEALDYFSDKESGK"); // Not L10N
            PauseForScreenShot("lower - Chromatogram graph metafiles for peptide AEGEWEDQEALDYFSDKESGK", 27);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            int[] m1Thru5 = { 1, 2, 3, 4, 5, 6 };
            PickTransitions(pepIndex, m1Thru5); // turn on M+3 M+4 and M+5
            PauseForScreenShot("Chromatogram graph metafiles with M+3, M+4 and M+5 added", 28);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            JumpToPeptide("ALVEFESNPEETREPGSPPSVQR"); // Not L10N
            PauseForScreenShot("Chromatogram graph metafiles for peptide ALVEFESNPEETREPGSPPSVQR", 29);

            pepIndex = JumpToPeptide("YGPADVEDTTGSGATDSKDDDDIDLFGSDDEEESEEAKR"); // Not L10N
            PauseForScreenShot("upper - Peak Areas graph metafile for peptide YGPADVEDTTGSGATDSKDDDDIDLFGSDDEEESEEAKR", 30);

            int[] m1Thru7 = { 1, 2, 3, 4, 5, 6, 7, 8 };
            PickTransitions(pepIndex, m1Thru7); // enable [M+3] [M+4] [M+5] [M+6] [M+7]
            PauseForScreenShot("lower - Peak Areas graph metafile with M+3 through M+7 added", 30);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            // page 32 zooming setup
            RunUI(() =>
            {
                SkylineWindow.SynchronizeZooming(true);
                SkylineWindow.LockYChrom(false);
                SkylineWindow.AlignToFile = SkylineWindow.GraphChromatograms.ToArray()[TIP3].GetChromFileInfoId(); // align to Tip3
            });
            ZoomBoth(36.5, 39.5, 1600);                                                                            // simulate the wheel scroll described in tutorial
            RunUI(() => SkylineWindow.ShowChromatogramLegends(false));
            PauseForScreenShot("Chromatogram graphs clipped from main window with synchronized zooming", 32);

            RestoreViewOnScreen(33);                                                                                                      // float the  Library Match window TODO this causes a crash at next call to ChangePeakBounds, in pwiz.Skyline.Controls.Graphs.GraphChromatogram.ChromGroupInfos.get() Line 492 , why?
            RunUI(() => SkylineWindow.GraphSpectrum.SelectSpectrum(new SpectrumIdentifier(MsDataFileUri.Parse(Tip3Filename), 37.6076f))); // set the Library Match view
            PauseForScreenShot <GraphSpectrum>("Library Match graph metafile - 5b_MCF7_TiTip3 (37.61 Min)", 33);

            RunUI(() => SkylineWindow.GraphSpectrum.SelectSpectrum(new SpectrumIdentifier(MsDataFileUri.Parse(Tib_LFilename), 37.0335f))); // set the Library Match view
            PauseForScreenShot <GraphSpectrum>("Library Match graph metafile - 1_MCF_TiB_L (37.03 min)", 33);

            RestoreViewOnScreen(34);                    // back to normal view

            pepIndex = JumpToPeptide("GVVDSEDLPLNISR"); // Not L10N
            RunUI(() => SkylineWindow.ShowChromatogramLegends(true));
            PauseForScreenShot("upper - Chromatogram graph metafiles for peptide GVVDSEDLPLNISR", 34);

            ZoomBoth(35.05, 36.9, 480);
            PauseForScreenShot("lower - Chromatogram graph metafile - effect of zoom ", 34);
            ChangePeakBounds(TIP3, pepIndex, 35.7, 36.5);  // adjust integration per tutorial
            CheckAnnotations(TIP3, pepIndex, atest++);     // check the new idotp values

            /* pepIndex = */ JumpToPeptide("DQVANSAFVER"); // Not L10N
            PauseForScreenShot("Chromatogram graph metafiles for peptide DQVANSAFVER", 35);

//            int[] m1 = {2};
//            PickTransitions(pepIndex, m1); // enable [M+1] only
//            // Measured times in TIB_L are different from displayed times, because of alignment
//            ChangePeakBounds(TIB_L, pepIndex, 23.99, 25.29);
//            ChangePeakBounds(TIP3, pepIndex, 23.81, 25.21);
//            // First transition selected for screenshot
//            RunUI(() =>
//            {
//                var pathPep = SkylineWindow.SelectedPath;
//                var nodePep = ((PeptideTreeNode)SkylineWindow.SelectedNode).DocNode;
//                var nodeGroup = nodePep.TransitionGroups.First();
//                var nodeTran = nodeGroup.Transitions.First();
//                SkylineWindow.SelectedPath = new IdentityPath(
//                    new IdentityPath(pathPep, nodeGroup.TransitionGroup), nodeTran.Transition);
//            });
//            PauseForScreenShot("page 36 - M+1 only, with adjusted integration");
//            CheckAnnotations(TIB_L, pepIndex, atest++);
//            CheckAnnotations(TIP3, pepIndex, EXPECTED_ANNOTATIONS[atest]);

            var docAfter = WaitForProteinMetadataBackgroundLoaderCompletedUI();

            // Minimizing a chromatogram cache file.
            RunUI(SkylineWindow.CollapsePeptides);
            for (int i = 0; i < 5; i++) // just do the first 5
            {
                int iPeptide = i;
                var path     = docAfter.GetPathTo((int)SrmDocument.Level.Molecules, iPeptide);
                RunUI(() =>
                {
                    SkylineWindow.SelectedPath = path;
                });
                WaitForGraphs();
            }

            // Eliminate extraneous chromatogram data.
            doc = WaitForProteinMetadataBackgroundLoaderCompletedUI();
            var minimizedFile = GetTestPath("Ms1FilteringTutorial-2min.sky"); // Not L10N
            var cacheFile     = Path.ChangeExtension(minimizedFile, ChromatogramCache.EXT);

            {
                // TODO: Figure out why the minimize fails to unlock the .skyd file, if not minimized to current file
                RunUI(() => SkylineWindow.SaveDocument(minimizedFile));

                var manageResultsDlg   = ShowDialog <ManageResultsDlg>(SkylineWindow.ManageResults);
                var minimizeResultsDlg = ShowDialog <MinimizeResultsDlg>(manageResultsDlg.MinimizeResults);
                RunUI(() =>
                {
                    minimizeResultsDlg.LimitNoiseTime = true;
                    minimizeResultsDlg.NoiseTimeRange = 2;                                                        // Not L10N
                });
                PauseForScreenShot <MinimizeResultsDlg>("Minimize Results form (percentages vary slightly)", 36); // old p. 23

                OkDialog(minimizeResultsDlg, () => minimizeResultsDlg.MinimizeToFile(minimizedFile));
                WaitForCondition(() => File.Exists(cacheFile));
                WaitForClosedForm(manageResultsDlg);
            }
            WaitForDocumentChange(doc);

            // Inclusion list method export for MS1 filtering
            doc = SkylineWindow.Document;
            RunDlg <PeptideSettingsUI>(() => SkylineWindow.ShowPeptideSettingsUI(PeptideSettingsUI.TABS.Prediction), dlg =>
            {
                dlg.IsUseMeasuredRT = true;
                dlg.TimeWindow      = 10;
                dlg.OkDialog();
            });
            WaitForDocumentChangeLoaded(doc);

            // Now deviating from the tutorial script for a moment to make sure we can choose a Scheduled export method.
            RunDlg <RefineDlg>(SkylineWindow.ShowRefineDlg, dlg =>
            {
                dlg.MinPeptides = 1; // Not L10N
                const double minPeakFoundRatio = 0.1;
                dlg.MinPeakFoundRatio          = minPeakFoundRatio;
                dlg.OkDialog();
            });

            // Ready to export, although we will just cancel out of the dialog.
            var exportMethodDlg = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.Method));

            RunUI(() =>
            {
                exportMethodDlg.InstrumentType = ExportInstrumentType.ABI_TOF; // Not L10N
                exportMethodDlg.MethodType     = ExportMethodType.Scheduled;
                exportMethodDlg.CancelButton.PerformClick();
            });
            WaitForClosedForm(exportMethodDlg);

            RunUI(() => SkylineWindow.SaveDocument());
            RunUI(SkylineWindow.NewDocument);
        }
        protected override void DoTest()
        {
            RunUI(() => SkylineWindow.SetUIMode(SrmDocument.DOCUMENT_TYPE.small_molecules));

            // Inserting a Transition List, p. 5
            {
                var doc = SkylineWindow.Document;

                SetCsvFileClipboardText(GetTestPath("Energy_TransitionList.csv"));
                RunUI(() =>
                {
                    SkylineWindow.Paste();
                    AdjustSequenceTreePanelWidth();
                });

                PauseForScreenShot <SkylineWindow>("Main window after paste from csv", 5);

                var docTargets = WaitForDocumentChange(doc);

                AssertEx.IsDocumentState(docTargets, null, 3, 18, 36, 36);
                Assert.IsFalse(docTargets.MoleculeTransitions.Any(t => t.Transition.IsPrecursor()));

                {
                    var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                    RunUI(() =>
                    {
                        // Predicition Settings
                        transitionSettingsUI.SelectedTab      = TransitionSettingsUI.TABS.Prediction;
                        transitionSettingsUI.RegressionCEName = "Waters Xevo"; // Collision Energy
                    });
                    PauseForScreenShot <TransitionSettingsUI.PredictionTab>("Transition Settings - Prediction tab", 6);


                    RunUI(() =>
                    {
                        // Filter Settings
                        transitionSettingsUI.SelectedTab = TransitionSettingsUI.TABS.Filter;
                        transitionSettingsUI.SmallMoleculePrecursorAdducts = Adduct.M_MINUS.AdductFormula;
                        transitionSettingsUI.SmallMoleculeFragmentAdducts  = Adduct.M_MINUS.AdductFormula;
                        transitionSettingsUI.SmallMoleculeFragmentTypes    = TransitionFilter.SMALL_MOLECULE_FRAGMENT_CHAR;
                    });
                    PauseForScreenShot <TransitionSettingsUI.PredictionTab>("Transition Settings -Filter tab", 7);

                    OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);
                    WaitForDocumentChange(docTargets);
                }

                RunUI(() => SkylineWindow.SaveDocument(GetTestPath("EnergyMet.sky")));


                // Export method - 2 minutes
                {
                    var exportMethodDlg2 = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.Method));
                    RunUI(() =>
                    {
                        exportMethodDlg2.InstrumentType = ExportInstrumentType.WATERS_XEVO_TQ;
                        exportMethodDlg2.MethodType     = ExportMethodType.Standard;
                        exportMethodDlg2.RunLength      = 2;
                        exportMethodDlg2.SetTemplateFile("VerifyETemplate.exp");
                    });
                    PauseForScreenShot <ExportMethodDlg>("Exporting 2 minute method", 9);
                    OkDialog(exportMethodDlg2, exportMethodDlg2.CancelDialog);
                }

                // Export transition list
                {
                    var exportTransitionList = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                    RunUI(() =>
                    {
                        exportTransitionList.InstrumentType = ExportInstrumentType.WATERS_XEVO_TQ;
                        exportTransitionList.MethodType     = ExportMethodType.Standard;
                        exportTransitionList.RunLength      = 2;
                    });
                    PauseForScreenShot <ExportMethodDlg>("Exporting transition list", 10);
                    OkDialog(exportTransitionList, exportTransitionList.CancelDialog);
                }

                using (new WaitDocumentChange(1, true))
                {
                    var importResultsDlg1     = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);
                    var openDataSourceDialog1 = ShowDialog <OpenDataSourceDialog>(() => importResultsDlg1.NamedPathSets =
                                                                                      importResultsDlg1.GetDataSourcePathsFile(null));
                    RunUI(() =>
                    {
                        openDataSourceDialog1.CurrentDirectory = new MsDataFilePath(GetTestPath("Unscheduled"));
                        openDataSourceDialog1.SelectAllFileType(ExtWatersRaw);
                    });
                    PauseForScreenShot <OpenDataSourceDialog>("Import Results Files form", 11);
                    OkDialog(openDataSourceDialog1, openDataSourceDialog1.Open);

                    var importResultsNameDlg = ShowDialog <ImportResultsNameDlg>(importResultsDlg1.OkDialog);
                    PauseForScreenShot <ImportResultsNameDlg>("Import Results common name form", 12);
                    OkDialog(importResultsNameDlg, importResultsNameDlg.OkDialog);
                    OkDialog(importResultsDlg1, importResultsDlg1.OkDialog);
                }

                SelectNode(SrmDocument.Level.Molecules, 0);
                SelectNode(SrmDocument.Level.MoleculeGroups, 0);

                PauseForScreenShot <SkylineWindow>("Skyline window multi-target graph", 13);

                // Renaming replicates
                {
                    var      manageResultsDlg = ShowDialog <ManageResultsDlg>(SkylineWindow.ManageResults);
                    string[] repNames         = new[] { "2 min", "5 min" };
                    RunUI(() => manageResultsDlg.Left = SkylineWindow.Right + 50);
                    for (var i = 0; i < 2; i++)
                    {
                        doc = SkylineWindow.Document;
                        var chromatograms = doc.Settings.MeasuredResults.Chromatograms;
                        var chrom         = chromatograms[i];
                        RunUI(() =>
                        {
                            manageResultsDlg.SelectedChromatograms = new[] { chrom };
                        });

                        var renameDlg = ShowDialog <RenameResultDlg>(manageResultsDlg.RenameResult);
                        RunUI(() => renameDlg.ReplicateName = repNames[i]);
                        if (i == 0)
                        {
                            PauseForScreenShot <SkylineWindow>("Manage Results and Rename Replicate (PrtScn and select in Paint)", 14);
                        }
                        OkDialog(renameDlg, renameDlg.OkDialog);
                    }
                    OkDialog(manageResultsDlg, manageResultsDlg.OkDialog);
                }

                PauseForScreenShot <SkylineWindow>("Skyline window (renamed)", 15);

                var docResults = SkylineWindow.Document;

                var msg = "";
                foreach (var chromatogramSet in docResults.Settings.MeasuredResults.Chromatograms)
                {
                    try
                    {
                        AssertResult.IsDocumentResultsState(docResults, chromatogramSet.Name, 18, 18, 18, 18, 18);
                    }
                    catch (Exception x)
                    {
                        msg += TextUtil.LineSeparate(x.Message);
                    }
                }
                if (!string.IsNullOrEmpty(msg))
                {
                    Assert.IsTrue(string.IsNullOrEmpty(msg), msg);
                }
                RunUI(() =>
                {
                    SkylineWindow.ShowPeakAreaReplicateComparison();
                    SkylineWindow.ShowRTReplicateGraph();
                    SkylineWindow.ArrangeGraphsTiled();
                });
                RestoreViewOnScreen(16);
                SelectNode(SrmDocument.Level.MoleculeGroups, 0);
                WaitForGraphs();
                RunUI(() =>
                {
                    SkylineWindow.Size = new Size(1054, 587);
                    AdjustSequenceTreePanelWidth(true);
                });

                PauseForScreenShot <SkylineWindow>("Skyline window multi-replicate layout", 16);

                // Set zoom to show better peak separation in 5 minute run
                for (var i = 0; i < 2; i++)
                {
                    WaitForGraphs();
                    RunUI(() => SkylineWindow.GraphChromatograms.ToArray()[i].ZoomTo(.8, 1.8, 1.39e+8));
                    WaitForGraphs();
                }
                PauseForScreenShot <SkylineWindow>("Skyline window showing relative peak separation", 17);

                // Set time window
                {
                    var peptideSettingsDlg = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
                    RunUI(() =>
                    {
                        // ReSharper disable once RedundantCast
                        peptideSettingsDlg.SelectedTab = (PeptideSettingsUI.TABS) 0; //regular enum does not work because of the hidden tabs in the Small Molecule mode.
                        peptideSettingsDlg.TimeWindow  = 1;
                    });
                    PauseForScreenShot <PeptideSettingsUI>("Setting scheduled transition list time window", 18);
                    OkDialog(peptideSettingsDlg, peptideSettingsDlg.OkDialog);
                }

                // Export transition list
                {
                    var exportTransitionList = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                    RunUI(() =>
                    {
                        exportTransitionList.InstrumentType = ExportInstrumentType.WATERS_XEVO_TQ;
                        exportTransitionList.MethodType     = ExportMethodType.Scheduled;
                        exportTransitionList.OptimizeType   = ExportOptimize.NONE;
                    });
                    PauseForScreenShot <ExportMethodDlg>("Exporting scheduled transition list", 19);

                    var schedulingOptionsDlg = ShowDialog <SchedulingOptionsDlg>(() => exportTransitionList.OkDialog(GetTestPath("EnergyMet_5minutes_scheduled.csv")));
                    RunUI(() =>
                    {
                        schedulingOptionsDlg.Algorithm    = ExportSchedulingAlgorithm.Single;
                        schedulingOptionsDlg.ReplicateNum = 1;  // 5 min
                    });
                    PauseForScreenShot <SchedulingOptionsDlg>("Exporting scheduled transition list - choose replicate", 19);
                    OkDialog(schedulingOptionsDlg, schedulingOptionsDlg.OkDialog);
                    WaitForClosedForm(exportTransitionList);
                }

                using (new WaitDocumentChange(1, true))
                {
                    var importResultsDlg1     = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);
                    var openDataSourceDialog1 = ShowDialog <OpenDataSourceDialog>(() => importResultsDlg1.NamedPathSets =
                                                                                      importResultsDlg1.GetDataSourcePathsFile(null));
                    RunUI(() =>
                    {
                        openDataSourceDialog1.CurrentDirectory = new MsDataFilePath(GetTestPath("Scheduled"));
                        openDataSourceDialog1.SelectAllFileType(ExtWatersRaw);
                    });
                    OkDialog(openDataSourceDialog1, openDataSourceDialog1.Open);

                    var importResultsNameDlg = ShowDialog <ImportResultsNameDlg>(importResultsDlg1.OkDialog);
                    RunUI(() => importResultsNameDlg.IsRemove = false);
                    PauseForScreenShot <ImportResultsNameDlg>("Import Results common name form, not changing names", 20);
                    OkDialog(importResultsNameDlg, importResultsNameDlg.OkDialog);
                }

                // Remove 2 minute gradient
                // Renaming replicates
                string[] newNames = { "1:1_1", "1:1_2", "2:1_2", "1:2_2" };
                {
                    var manageResultsDlg = ShowDialog <ManageResultsDlg>(SkylineWindow.ManageResults);
                    SelectReplicate(manageResultsDlg, 0);

                    PauseForScreenShot <SkylineWindow>("Manage Results removing 2 min", 21);

                    RunUI(manageResultsDlg.RemoveReplicates);

                    for (var i = 0; i < newNames.Length; i++)
                    {
                        SelectReplicate(manageResultsDlg, i + 1);
                        RunDlg <RenameResultDlg>(manageResultsDlg.RenameResult, renameDlg =>
                        {
                            renameDlg.ReplicateName = newNames[i];
                            renameDlg.OkDialog();
                        });
                    }

                    PauseForScreenShot <SkylineWindow>("Manage Results replicate renamed", 22);
                    OkDialog(manageResultsDlg, manageResultsDlg.OkDialog);
                }

                SelectNode(SrmDocument.Level.Molecules, 0);
                RunUI(() =>
                {
                    var molNode = SkylineWindow.SelectedNode;
                    molNode.Expand();
                    Assert.AreEqual(2, molNode.Nodes.Count);
                    molNode.Nodes[0].Expand();
                    molNode.Nodes[1].Expand();
                    SkylineWindow.ArrangeGraphsTabbed();
                });
                PauseForScreenShot <SkylineWindow>("Skyline window with calibration data", 23);

                // Linearity
                var documentGrid = ShowDialog <DocumentGridForm>(() => SkylineWindow.ShowDocumentGrid(true));
                RunUI(() => documentGrid.ChooseView(Resources.SkylineViewContext_GetDocumentGridRowSources_Replicates));

                double[] concentrations      = { 1, 1, 2, 0.5 };
                var      namedConcentrations = newNames.Select((n, i) => new Tuple <string, double?>(n, concentrations[i]));
                SetDocumentGridSampleTypesAndConcentrations(namedConcentrations.ToDictionary(t => t.Item1,
                                                                                             t => new Tuple <SampleType, double?>(SampleType.STANDARD, t.Item2)));
                RunUI(() =>
                {
                    var gridFloatingWindow  = documentGrid.Parent.Parent;
                    gridFloatingWindow.Size = new Size(370, 230);
                    gridFloatingWindow.Top  = SkylineWindow.Top;
                    gridFloatingWindow.Left = SkylineWindow.Right + 20;
                });
                PauseForScreenShot <DocumentGridForm>("Document Grid - sample types and concentrations ", 23);
                RunUI(() => SkylineWindow.ShowDocumentGrid(false));

                using (new WaitDocumentChange(1, true))
                {
                    // Quant settings
                    var peptideSettingsUI = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);

                    RunUI(() =>
                    {
                        // ReSharper disable once RedundantCast
                        peptideSettingsUI.SelectedTab              = (PeptideSettingsUI.TABS) 3;
                        peptideSettingsUI.QuantRegressionFit       = RegressionFit.LINEAR;
                        peptideSettingsUI.QuantNormalizationMethod =
                            new NormalizationMethod.RatioToLabel(IsotopeLabelType.heavy);
                        peptideSettingsUI.QuantUnits = "ratio to heavy";
                    });

                    PauseForScreenShot <PeptideSettingsUI.QuantificationTab>("Peptide Settings - Quantitation", 24);
                    OkDialog(peptideSettingsUI, peptideSettingsUI.OkDialog);
                }

                var calibrationForm = ShowDialog <CalibrationForm>(() => SkylineWindow.ShowCalibrationForm());
                RunUI(() =>
                {
                    var calibrationFloatingWindow   = calibrationForm.Parent.Parent;
                    calibrationFloatingWindow.Width = 565;
                    calibrationFloatingWindow.Top   = SkylineWindow.Top;
                    calibrationFloatingWindow.Left  = SkylineWindow.Right + 20;
                });
                PauseForScreenShot <CalibrationForm>("Calibration Curve ", 25);
                OkDialog(calibrationForm, calibrationForm.Close); // Hide the calibration window

                {
                    var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                    RunUI(() => transitionSettingsUI.SelectedTab = TransitionSettingsUI.TABS.Prediction);
                    var editCurrentCE = ShowDialog <EditCEDlg>(transitionSettingsUI.EditCECurrent);
                    RunUI(() =>
                    {
                        editCurrentCE.StepSize  = 2;
                        editCurrentCE.StepCount = 5;
                    });
                    PauseForScreenShot <EditCEDlg>("Edit Collision Energy Equation form", 26);

                    RunUI(() =>
                    {
                        editCurrentCE.OkDialog();
                        transitionSettingsUI.UseOptimized = true;
                        transitionSettingsUI.OptimizeType = OptimizedMethodType.Transition.GetLocalizedString();
                    });
                    PauseForScreenShot <TransitionSettingsUI.PredictionTab>("Transition Settings - Prediction tab", 27);
                    OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);
                }

                // Export transition lists
                {
                    var exportTransitionList = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                    RunUI(() =>
                    {
                        exportTransitionList.ExportStrategy = ExportStrategy.Buckets;
                        exportTransitionList.IgnoreProteins = true;
                        exportTransitionList.MaxTransitions = 100;
                        exportTransitionList.InstrumentType = ExportInstrumentType.WATERS_XEVO_TQ;
                        exportTransitionList.MethodType     = ExportMethodType.Scheduled;
                        exportTransitionList.OptimizeType   = ExportOptimize.CE;
                    });
                    PauseForScreenShot <ExportMethodDlg>("Exporting scheduled transition list", 28);

                    var scheduleDlg = ShowDialog <SchedulingOptionsDlg>(() => exportTransitionList.OkDialog(GetTestPath("EnergyMet_5minutes_ceopt.csv")));
                    PauseForScreenShot <SchedulingOptionsDlg>("Scheduling", 29);
                    OkDialog(scheduleDlg, scheduleDlg.OkDialog);
                }

                // Import CE optimization runs
                using (new WaitDocumentChange(1, true))
                {
                    var importResultsDlg1 = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);
                    RunUI(() =>
                    {
                        importResultsDlg1.RadioCreateMultipleChecked = true;
                        importResultsDlg1.OptimizationName           = ExportOptimize.CE;
                        importResultsDlg1.ReplicateName = "CE Optimization";
                    });
                    PauseForScreenShot <ImportResultsDlg>("Setting new replicate name to CE Optimization", 30);
                    var openDataSourceDialog1 = ShowDialog <OpenDataSourceDialog>(() => importResultsDlg1.OkDialog());
                    RunUI(() =>
                    {
                        openDataSourceDialog1.CurrentDirectory = new MsDataFilePath(GetTestPath("CE Optimization"));
                        openDataSourceDialog1.SelectAllFileType(ExtWatersRaw);
                    });
                    PauseForScreenShot <OpenDataSourceDialog>("Import Results Files form", 31);
                    OkDialog(openDataSourceDialog1, openDataSourceDialog1.Open);
                }

                PauseForScreenShot <SkylineWindow>("Skyline shows new replicate \"CE Optimization\"", 32);
                RunUI(() =>
                {
                    SkylineWindow.Size = new Size(1600, 960);
                    SkylineWindow.ShowGraphRetentionTime(false, GraphTypeSummary.replicate);
                    SkylineWindow.AutoZoomBestPeak();
                    AdjustSequenceTreePanelWidth();
                    SkylineWindow.ShowSingleTransition();
                    SkylineWindow.ShowSplitChromatogramGraph(true);
                });
                PauseForScreenShot <SkylineWindow>("Split graph", 33);

                RunUI(() =>
                {
                    SkylineWindow.ShowPeakAreaLegend(false);
                });
                PauseForScreenShot <SkylineWindow>("No legend", 34);

                // Show Pentose-P
                SelectNode(SrmDocument.Level.Molecules, 6);
                PauseForScreenShot <SkylineWindow>("Pentose-P", 35);

                if (IsCoverShotMode)
                {
                    RunUI(() =>
                    {
                        Settings.Default.ChromatogramFontSize = 14;
                        Settings.Default.AreaFontSize         = 14;
                        SkylineWindow.ChangeTextSize(TreeViewMS.LRG_TEXT_FACTOR);
                        SkylineWindow.ShowChromatogramLegends(false);
                    });

                    RestoreCoverViewOnScreen();
                    TakeCoverShot();
                    return;
                }

                // Export final transition list
                {
                    var exportTransitionList = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                    RunUI(() =>
                    {
                        exportTransitionList.ExportStrategy = ExportStrategy.Single;
                        exportTransitionList.IgnoreProteins = true;
                        exportTransitionList.MaxTransitions = 100;
                        exportTransitionList.InstrumentType = ExportInstrumentType.WATERS_XEVO_TQ;
                        exportTransitionList.MethodType     = ExportMethodType.Scheduled;
                    });
                    PauseForScreenShot <ExportMethodDlg>("Exporting final optimized transition list", 36);

                    var scheduleDlg = ShowDialog <SchedulingOptionsDlg>(() => exportTransitionList.OkDialog(GetTestPath("EnergyMet_5minutes_optimal.csv")));
                    PauseForScreenShot <SchedulingOptionsDlg>("Final Scheduling", 37);
                    OkDialog(scheduleDlg, scheduleDlg.OkDialog);
                }
            }
        }
Ejemplo n.º 8
0
 private void arrangeTiledMenuItem_Click(object sender, EventArgs e)
 {
     SkylineWindow.ArrangeGraphsTiled();
 }
Ejemplo n.º 9
0
        protected override void DoTest()
        {
            // DDA with IDs and alignment
            string filePathDda = TestFilesDir.GetTestPath(@"DDA\Bereman_5proteins_spikein_decoys.sky.zip");

            RunUI(() => SkylineWindow.OpenSharedFile(filePathDda));
            var doc            = WaitForDocumentLoaded();
            int expectedDecoys = RefinementSettings.SuggestDecoyCount(doc);

            RunDlg <GenerateDecoysDlg>(() => SkylineWindow.ShowGenerateDecoysDlg(), decoysDlg =>
            {
                decoysDlg.DecoysMethod = DecoyGeneration.SHUFFLE_SEQUENCE;
                decoysDlg.OkDialog();
            });
            doc = WaitForDocumentChange(doc);
            Assert.AreEqual(expectedDecoys, doc.Peptides.Count(p => p.IsDecoy));
            ImportResultsFiles(DDA_FILES.Select(s => GetDataFile("DDA", s)).Select(MsDataFileUri.Parse));
            RunUI(() =>
            {
                SkylineWindow.SaveDocument();
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.ShowAlignedPeptideIDTimes(true);
                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.SelectedNode.FirstNode;
            });
            // Random nature of decoys makes it hard to make this very deterministic
            // But eventually we should see some peptides without IDs of their own
            // All peptides should have aligned IDs, if they don't have a single ID,
            // since it might be the only ID
            int countWithIds = 0, countTotal = 0;

            while (countWithIds < 20 || countTotal - 4 < countWithIds)
            {
                WaitForGraphs();
                RunUI(() =>
                {
                    foreach (var graphChromatogram in SkylineWindow.GraphChromatograms)
                    {
                        countTotal++;
                        int countIds = graphChromatogram.RetentionMsMs != null
                            ? graphChromatogram.RetentionMsMs.Length
                            : 0;
                        if (countIds != 1)
                        {
                            Assert.IsNotNull(graphChromatogram.AlignedRetentionMsMs);
                            Assert.AreNotEqual(0, graphChromatogram.AlignedRetentionMsMs.Length);
                        }
                        if (countIds > 0)
                        {
                            ValidateTimeRange(graphChromatogram, graphChromatogram.RetentionMsMs, 6, 90);
                            countWithIds++;
                        }
                        else
                        {
                            ValidateTimeRange(graphChromatogram, graphChromatogram.AlignedRetentionMsMs, 6, 90);
                        }
                    }
                    var nextNode = SkylineWindow.SequenceTree.SelectedNode.NextNode;
                    if (nextNode != null)
                    {
                        SkylineWindow.SequenceTree.SelectedNode = nextNode;
                    }
                });
            }

            // DIA with DDA IDs
            string filePathDia = TestFilesDir.GetTestPath(@"DIA\Hoofnagle_QE_DIA_targeted_decoys.sky.zip");

            RunUI(() => SkylineWindow.OpenSharedFile(filePathDia));
            doc            = WaitForDocumentLoaded();
            expectedDecoys = RefinementSettings.SuggestDecoyCount(doc);
            RunDlg <GenerateDecoysDlg>(() => SkylineWindow.ShowGenerateDecoysDlg(), decoysDlg =>
            {
                decoysDlg.DecoysMethod = DecoyGeneration.REVERSE_SEQUENCE;
                decoysDlg.OkDialog();
            });
            doc = WaitForDocumentChange(doc);
            Assert.AreEqual(expectedDecoys, doc.Peptides.Count(p => p.IsDecoy));
            ImportResultsFiles(DIA_FILES.Select(s => GetDataFile("DIA", s)).Select(MsDataFileUri.Parse));
            RunUI(() =>
            {
                SkylineWindow.SaveDocument();
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.ShowOtherRunPeptideIDTimes(true);
                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.SelectedNode.FirstNode;
            });
            for (int i = 0; i < 6; i++)
            {
                WaitForGraphs();
                RunUI(() =>
                {
                    foreach (var graphChromatogram in SkylineWindow.GraphChromatograms)
                    {
                        Assert.IsNull(graphChromatogram.RetentionMsMs);
                        Assert.IsNull(graphChromatogram.AlignedRetentionMsMs);
                        Assert.IsNotNull(graphChromatogram.UnalignedRetentionMsMs);
                        Assert.AreNotEqual(0, graphChromatogram.UnalignedRetentionMsMs.Length);
                        ValidateTimeRange(graphChromatogram, graphChromatogram.UnalignedRetentionMsMs, 8, 120);
                    }
                    SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.SelectedNode.NextNode;
                });
            }

            // DIA with IRT values
            string filePathDiaIrt = TestFilesDir.GetTestPath(@"DIA-iRT\AQUA4_Human_picked_napedro2_full_rescore_iRT_decoys.sky.zip");

            RunUI(() => SkylineWindow.OpenSharedFile(filePathDiaIrt));
            doc            = WaitForDocumentLoaded();
            expectedDecoys = RefinementSettings.SuggestDecoyCount(doc);
            RunDlg <GenerateDecoysDlg>(() => SkylineWindow.ShowGenerateDecoysDlg(), decoysDlg =>
            {
                decoysDlg.DecoysMethod = DecoyGeneration.SHUFFLE_SEQUENCE;
                decoysDlg.OkDialog();
            });
            doc = WaitForDocumentChange(doc);
            Assert.AreEqual(expectedDecoys, doc.Peptides.Count(p => p.IsDecoy));
            ImportResultsFile(GetDataFile("DIA-iRT", IRT_FILES[0]));
            RunUI(() =>
            {
                SkylineWindow.SaveDocument();
                SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.SelectedNode.FirstNode;
            });

            for (int i = 0; i < 6; i++)
            {
                WaitForGraphs();
                RunUI(() =>
                {
                    foreach (var graphChromatogram in SkylineWindow.GraphChromatograms)
                    {
                        Assert.IsNull(graphChromatogram.RetentionMsMs);
                        Assert.IsNull(graphChromatogram.AlignedRetentionMsMs);
                        Assert.IsNull(graphChromatogram.UnalignedRetentionMsMs);
                        Assert.IsTrue(graphChromatogram.PredictedRT.HasValue);
                        ValidateTimeRange(graphChromatogram, new [] { graphChromatogram.PredictedRT.Value }, 8, 135);
                    }
                    SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.SelectedNode.NextNode;
                });
            }
        }
Ejemplo n.º 10
0
        protected override void DoTest()
        {
            // Clean-up before running the test
            RunUI(() => SkylineWindow.ModifyDocument("Set default settings",
                                                     d => d.ChangeSettings(SrmSettingsList.GetDefault())));

            SrmDocument doc = SkylineWindow.Document;

            const string documentBaseName = "Ms1FilterTutorial";
            string       documentFile     = GetTestPath(documentBaseName + SrmDocument.EXT);

            RunUI(() => SkylineWindow.SaveDocument(documentFile));

            // Launch the wizard
            var importPeptideSearchDlg = ShowDialog <ImportPeptideSearchDlg>(SkylineWindow.ShowImportPeptideSearchDlg);

            // We're on the "Build Spectral Library" page of the wizard.
            // Add the test xml file to the search files list and try to
            // build the document library.
            string[] searchFiles =
            {
                GetTestPath("100803_0001_MCF7_TiB_L.group.xml"),      // Not L10N
                GetTestPath("100803_0005b_MCF7_TiTip3.group.xml")     // Not L10N
            };
            foreach (var searchFile in searchFiles)
            {
                Assert.IsTrue(File.Exists(searchFile), string.Format("File {0} does not exist.", searchFile));
            }

            PauseForScreenShot <ImportPeptideSearchDlg.SpectraPage>("Import Peptide Search - Build Spectral Library empty page", 3);

            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.spectra_page);
                importPeptideSearchDlg.BuildPepSearchLibControl.AddSearchFiles(searchFiles);

                // Sanity check here, because of failure getting both files for results import below
                var searchNames = importPeptideSearchDlg.BuildPepSearchLibControl.SearchFilenames;
                Assert.AreEqual(searchFiles.Length, searchNames.Length,
                                PathsMessage("Unexpected search files found.", searchNames));
                var builder = importPeptideSearchDlg.BuildPepSearchLibControl.ImportPeptideSearch.GetLibBuilder(
                    SkylineWindow.DocumentUI, SkylineWindow.DocumentFilePath, false);
                Assert.IsTrue(ArrayUtil.EqualsDeep(searchFiles, builder.InputFiles),
                              PathsMessage("Unexpected BlibBuild input files.", builder.InputFiles));
                importPeptideSearchDlg.BuildPepSearchLibControl.DebugMode = true;
            });
            PauseForScreenShot <ImportPeptideSearchDlg.SpectraPage>("Import Peptide Search - Build Spectral Library populated page", 4);

            WaitForConditionUI(() => importPeptideSearchDlg.IsNextButtonEnabled);
            var ambiguousDlg = ShowDialog <MessageDlg>(() => importPeptideSearchDlg.ClickNextButton());

            RunUI(() => AssertEx.Contains(ambiguousDlg.Message,
                                          Resources.BiblioSpecLiteBuilder_AmbiguousMatches_The_library_built_successfully__Spectra_matching_the_following_peptides_had_multiple_ambiguous_peptide_matches_and_were_excluded_));
            OkDialog(ambiguousDlg, ambiguousDlg.OkDialog);

            // Verify document library was built
            string docLibPath          = BiblioSpecLiteSpec.GetLibraryFileName(documentFile);
            string redundantDocLibPath = BiblioSpecLiteSpec.GetRedundantName(docLibPath);

            Assert.IsTrue(File.Exists(docLibPath) && File.Exists(redundantDocLibPath));
            var librarySettings = SkylineWindow.Document.Settings.PeptideSettings.Libraries;

            Assert.IsTrue(librarySettings.HasDocumentLibrary);
            // Verify input paths sent to BlibBuild
            string buildArgs   = importPeptideSearchDlg.BuildPepSearchLibControl.LastBuildCommandArgs;
            string buildOutput = importPeptideSearchDlg.BuildPepSearchLibControl.LastBuildOutput;
            var    argLines    = buildArgs.Split(new[] { Environment.NewLine }, StringSplitOptions.None);
            var    dirCommon   = PathEx.GetCommonRoot(searchFiles);
            var    searchLines = searchFiles.Select(f => PathEx.RemovePrefix(f, dirCommon)).ToArray();

            Assert.IsTrue(ArrayUtil.EqualsDeep(searchLines, argLines.Skip(1).ToArray()), buildArgs);

            // Verify resulting .blib file contains the expected files
            var docLib                   = librarySettings.Libraries[0];
            int expectedFileCount        = searchFiles.Length;
            int expectedRedundantSpectra = 813; // 446 with TiTip only
            int expectedSpectra          = 552; // 428 with TiTip3 only

            if (expectedFileCount != docLib.FileCount)
            {
                var searchFileNames = searchFiles.Select(Path.GetFileName).ToArray();
                using (var blibDbRedundant = BlibDb.OpenBlibDb(redundantDocLibPath))
                {
                    VerifyLib(searchFileNames, expectedRedundantSpectra, blibDbRedundant.GetIdFilePaths(), blibDbRedundant.GetSpectraCount(),
                              "redundant library", buildArgs, buildOutput);
                }
                using (var blibDb = BlibDb.OpenBlibDb(docLibPath))
                {
                    VerifyLib(searchFileNames, expectedSpectra, blibDb.GetIdFilePaths(), blibDb.GetSpectraCount(),
                              "SQLite library", buildArgs, buildOutput);
                }
                VerifyLib(searchFileNames, expectedSpectra, docLib.LibraryDetails.DataFiles.Select(d => d.IdFilePath).ToArray(), docLib.SpectrumCount,
                          "in memory", buildArgs, buildOutput);
            }

            // We're on the "Extract Chromatograms" page of the wizard.
            // All the test results files are in the same directory as the
            // document file, so all the files should be found, and we should
            // just be able to move to the next page.
            WaitForConditionUI(() => importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.chromatograms_page &&
                               importPeptideSearchDlg.ImportResultsControl.FoundResultsFiles.Count > 0 &&
                               importPeptideSearchDlg.IsNextButtonEnabled);

            // Wait for extra for both source files in the list
            TryWaitForConditionUI(10 * 1000, () => importPeptideSearchDlg.ImportResultsControl.FoundResultsFiles.Count == searchFiles.Length);

            RunUI(() =>
            {
                // Check for missing files
                var missingFiles = importPeptideSearchDlg.ImportResultsControl.MissingResultsFiles.ToArray();
                Assert.AreEqual(0, missingFiles.Length,
                                PathsMessage("Unexpected missing file found.", missingFiles));
                // Check for expected results files
                var resultsNames = importPeptideSearchDlg.ImportResultsControl.FoundResultsFiles.Select(f => f.Name).ToArray();
                Assert.AreEqual(searchFiles.Length, importPeptideSearchDlg.ImportResultsControl.FoundResultsFiles.Count,
                                PathsMessage("Unexpected results files found.", resultsNames));
                // Check for expected common prefix
                var commonPrefix = ImportResultsDlg.GetCommonPrefix(resultsNames);
                Assert.IsFalse(string.IsNullOrEmpty(commonPrefix),
                               PathsMessage("File names do not have a common prefix.", resultsNames));
                Assert.AreEqual("100803_000", commonPrefix);
            });
            PauseForScreenShot <ImportPeptideSearchDlg.ChromatogramsPage>("Import Peptide Search - Extract Chromatograms page", 6);

            var importResultsNameDlg = ShowDialog <ImportResultsNameDlg>(() => importPeptideSearchDlg.ClickNextButton());

            PauseForScreenShot <ImportResultsNameDlg>("Import Results - Common prefix form", 7);

            OkDialog(importResultsNameDlg, importResultsNameDlg.YesDialog);

            // Wait for the "Add Modifications" page of the wizard.
            WaitForConditionUI(() => importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.match_modifications_page);

            List <string> modsToCheck = new List <string> {
                "Phospho (ST)", "Phospho (Y)", "Oxidation (M)"
            };                                                                                              // Not L10N

            RunUI(() =>
            {
                importPeptideSearchDlg.MatchModificationsControl.CheckedModifications = modsToCheck;
            });
            PauseForScreenShot <ImportPeptideSearchDlg.MatchModsPage>("Import Peptide Search - Add Modifications page", 8);
            RunUI(() => Assert.IsTrue(importPeptideSearchDlg.ClickNextButton()));

            // We're on the "Configure MS1 Full-Scan Settings" page of the wizard.
            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.full_scan_settings_page);
                importPeptideSearchDlg.FullScanSettingsControl.PrecursorCharges      = new[] { 2, 3, 4 };
                importPeptideSearchDlg.FullScanSettingsControl.PrecursorMassAnalyzer = FullScanMassAnalyzerType.tof;
                importPeptideSearchDlg.FullScanSettingsControl.PrecursorRes          = 10 * 1000;

                Assert.AreEqual(importPeptideSearchDlg.FullScanSettingsControl.PrecursorIsotopesCurrent, FullScanPrecursorIsotopes.Count);
                Assert.AreEqual(FullScanMassAnalyzerType.tof, importPeptideSearchDlg.FullScanSettingsControl.PrecursorMassAnalyzer);
                Assert.AreEqual(10 * 1000, importPeptideSearchDlg.FullScanSettingsControl.PrecursorRes);
                Assert.AreEqual(3, importPeptideSearchDlg.FullScanSettingsControl.Peaks);
                Assert.AreEqual(RetentionTimeFilterType.ms2_ids, importPeptideSearchDlg.FullScanSettingsControl.RetentionTimeFilterType);
                Assert.AreEqual(5, importPeptideSearchDlg.FullScanSettingsControl.TimeAroundMs2Ids);
            });
            PauseForScreenShot <ImportPeptideSearchDlg.Ms1FullScanPage>("Import Peptide Search - Configure MS1 Full-Scan Settings page", 9);

            RunUI(() => Assert.IsTrue(importPeptideSearchDlg.ClickNextButton()));

            // Last page of wizard - Import Fasta.
            string fastaPath = GetTestPath("12_proteins.062011.fasta");

            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.import_fasta_page);
                Assert.AreEqual("Trypsin [KR | P]", importPeptideSearchDlg.ImportFastaControl.Enzyme.GetKey());
                importPeptideSearchDlg.ImportFastaControl.MaxMissedCleavages = 2;
                importPeptideSearchDlg.ImportFastaControl.SetFastaContent(fastaPath);
                Assert.IsFalse(importPeptideSearchDlg.ImportFastaControl.DecoyGenerationEnabled);
            });
            PauseForScreenShot <ImportPeptideSearchDlg.FastaPage>("Import Peptide Search - Import FASTA page", 12);

            var peptidesPerProteinDlg = ShowDialog <PeptidesPerProteinDlg>(() => importPeptideSearchDlg.ClickNextButton());

            WaitForCondition(() => peptidesPerProteinDlg.DocumentFinalCalculated);
            RunUI(() =>
            {
                int proteinCount, peptideCount, precursorCount, transitionCount;
                peptidesPerProteinDlg.NewTargetsAll(out proteinCount, out peptideCount, out precursorCount, out transitionCount);
                Assert.AreEqual(11, proteinCount);
                Assert.AreEqual(51, peptideCount);
                Assert.AreEqual(52, precursorCount);
                Assert.AreEqual(156, transitionCount);
                peptidesPerProteinDlg.NewTargetsFinal(out proteinCount, out peptideCount, out precursorCount, out transitionCount);
                Assert.AreEqual(11, proteinCount);
                Assert.AreEqual(51, peptideCount);
                Assert.AreEqual(52, precursorCount);
                Assert.AreEqual(156, transitionCount);
            });
            OkDialog(peptidesPerProteinDlg, peptidesPerProteinDlg.OkDialog);

            var allChromGraph = WaitForOpenForm <AllChromatogramsGraph>();

            RunUI(() =>
            {
                allChromGraph.Left = SkylineWindow.Right + 20;
                allChromGraph.Activate();
            });

            PauseForScreenShot <AllChromatogramsGraph>("Loading chromatograms window", 13);
            WaitForDocumentChangeLoaded(doc, 8 * 60 * 1000); // 10 minutes

            var libraryExplorer   = ShowDialog <ViewLibraryDlg>(() => SkylineWindow.OpenLibraryExplorer(documentBaseName));
            var matchedPepModsDlg = WaitForOpenForm <AddModificationsDlg>();

            PauseForScreenShot <AddModificationsDlg>("Add mods alert", 14);
            RunUI(() =>
            {
                Assert.AreEqual(13, matchedPepModsDlg.NumMatched);
                Assert.AreEqual(0, matchedPepModsDlg.NumUnmatched);
                matchedPepModsDlg.CancelDialog();
            });
            RunUI(() =>
            {
                libraryExplorer.GraphSettings.ShowBIons        = true;
                libraryExplorer.GraphSettings.ShowYIons        = true;
                libraryExplorer.GraphSettings.ShowCharge1      = true;
                libraryExplorer.GraphSettings.ShowCharge2      = true;
                libraryExplorer.GraphSettings.ShowPrecursorIon = true;
            });

            PauseForScreenShot <ViewLibraryDlg>("Spectral Library Explorer", 15);
            RunUI(() =>
            {
                const string sourceFirst = "100803_0005b_MCF7_TiTip3.wiff";
                const double timeFirst   = 35.2128;
                Assert.AreEqual(sourceFirst, libraryExplorer.SourceFile);
                Assert.AreEqual(timeFirst, libraryExplorer.RetentionTime, 0.01);
                libraryExplorer.SelectedIndex++;
                Assert.AreNotEqual(sourceFirst, libraryExplorer.SourceFile);
                Assert.AreNotEqual(timeFirst, libraryExplorer.RetentionTime, 0.01);
            });
            OkDialog(libraryExplorer, libraryExplorer.CancelDialog);

            const int TIB_L = 0; // index for Tib_L
            const int TIP3  = 1; // index for Tip3

            AssertEx.IsDocumentState(SkylineWindow.Document, null, 11, 51, 52, 156);
            AssertResult.IsDocumentResultsState(SkylineWindow.Document, GetFileNameWithoutExtension(searchFiles[TIB_L]), 51, 52, 0, 156, 0);
            AssertResult.IsDocumentResultsState(SkylineWindow.Document, GetFileNameWithoutExtension(searchFiles[TIP3]), 51, 52, 0, 156, 0);
            string Tib_LFilename = searchFiles[TIB_L].Replace(".group.xml", PreferedExtAbWiff);
            string Tip3Filename  = searchFiles[TIP3].Replace(".group.xml", PreferedExtAbWiff);

            // Select the first transition group.
            RunUI(() =>
            {
                SkylineWindow.SequenceTree.SelectedPath =
                    SkylineWindow.Document.GetPathTo((int)SrmDocument.Level.Molecules, 0);
                SkylineWindow.GraphSpectrumSettings.ShowAIons        = true;
                SkylineWindow.GraphSpectrumSettings.ShowBIons        = true;
                SkylineWindow.GraphSpectrumSettings.ShowYIons        = true;
                SkylineWindow.GraphSpectrumSettings.ShowPrecursorIon = true;
                SkylineWindow.ExpandPrecursors();
                SkylineWindow.ChangeTextSize(TreeViewMS.LRG_TEXT_FACTOR);
            });
            RunDlg <SpectrumChartPropertyDlg>(SkylineWindow.ShowSpectrumProperties, dlg =>
            {
                dlg.FontSize = GraphFontSize.NORMAL;
                dlg.OkDialog();
            });
            RunDlg <ChromChartPropertyDlg>(SkylineWindow.ShowChromatogramProperties, dlg =>
            {
                dlg.FontSize = GraphFontSize.NORMAL;
                dlg.OkDialog();
            });
            const int skylineWindowWidth  = 1160;
            const int skylineWindowHeight = 792;

            RunUI(() =>
            {
                // Make window screenshot size
                if (IsPauseForScreenShots && SkylineWindow.WindowState != FormWindowState.Maximized)
                {
                    SkylineWindow.Width  = skylineWindowWidth;
                    SkylineWindow.Height = skylineWindowHeight;
                }
            });
            RestoreViewOnScreen(13);
            PauseForScreenShot("Main window with imported data", 16);

//            RunUIWithDocumentWait(() =>
//            {
//                SkylineWindow.ToggleIntegrateAll(); // TODO: No longer necessary.  Change in tutorial
//            });
            RunUI(() =>
            {
                SkylineWindow.ShowGraphPeakArea(true);
                SkylineWindow.ShowPeakAreaReplicateComparison();
                SkylineWindow.NormalizeAreaGraphTo(NormalizeOption.NONE);
                Settings.Default.ShowDotProductPeakArea = true;
                Settings.Default.ShowLibraryPeakArea    = true;
            });
            RunUI(() =>
            {
                SkylineWindow.Width    = 500;
                var peakAreas          = SkylineWindow.GraphPeakArea;
                var peakAreasFloating  = peakAreas.Parent.Parent;
                peakAreasFloating.Left = SkylineWindow.Right + 20;
                peakAreasFloating.Top  = SkylineWindow.Top;
                peakAreasFloating.Size = new Size(504, 643);
            });

            PauseForScreenShot <GraphSummary.AreaGraphView>("Peak Areas view (show context menu)", 18);

            RunUI(() => SkylineWindow.Width = skylineWindowWidth);
            RestoreViewOnScreen(15);
            RunUI(() =>
            {
                SkylineWindow.AutoZoomBestPeak();
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.ShowChromatogramLegends(false);
            });
            PauseForScreenShot("Main window layout", 19);

            int atest = 0;

            CheckAnnotations(TIB_L, 0, atest++);
            int pepIndex = 3;

            RunUI(() => SkylineWindow.CollapsePeptides());
            RunUI(() => SkylineWindow.ShowAlignedPeptideIDTimes(true));
            ChangePeakBounds(TIB_L, pepIndex, 38.79, 39.385);
            PauseForScreenShot("Chromatogram graphs clipped from main window", 21);
            CheckAnnotations(TIB_L, pepIndex, atest++);

            var       alignmentForm            = ShowDialog <AlignmentForm>(() => SkylineWindow.ShowRetentionTimeAlignmentForm());
            const int skylineWindowNarrowWidth = 788;

            RunUI(() =>
            {
                SkylineWindow.Width  = skylineWindowNarrowWidth;
                alignmentForm.Width  = 660;
                alignmentForm.Height = 561;
                alignmentForm.Left   = SkylineWindow.Right + 20;
                alignmentForm.Splitter.SplitterDistance       = 75;
                alignmentForm.ComboAlignAgainst.SelectedIndex = 0;     // to match what's in the tutorial doc
            });
            PauseForScreenShot <AlignmentForm>("Retention time alignment form", 22);

            OkDialog(alignmentForm, alignmentForm.Close);
            PauseForScreenShot("Status bar clipped from main window - 4/51 pep 4/52 prec 10/156 tran", 23);

            const string TIP_NAME = "5b_MCF7_TiTip3";

            if (IsCoverShotMode)
            {
                RestoreCoverViewOnScreen();
                ClickChromatogram(TIP_NAME, 34.5, 366);
                TreeNode selectedNode = null;
                RunUI(() => selectedNode = SkylineWindow.SequenceTree.SelectedNode);
                RunUI(() => SkylineWindow.SequenceTree.SelectedNode = SkylineWindow.SequenceTree.Nodes[0]);
                WaitForGraphs();
                RunUI(() => SkylineWindow.SequenceTree.SelectedNode = selectedNode);
                TakeCoverShot();
                return;
            }

            pepIndex = JumpToPeptide("SSKASLGSLEGEAEAEASSPK");
            RunUI(() => SkylineWindow.ShowChromatogramLegends(true));
            Assert.IsTrue(8 == pepIndex);
            PauseForScreenShot("Chromatogram graph metafiles for 9th peptide", 24);
            CheckAnnotations(TIB_L, pepIndex, atest++);

            ZoomSingle(TIP3, 31.8, 42.2, 280); // simulate the wheel scroll described in tutorial
            PauseForScreenShot("Chromatogram graph metafile showing all peaks for 1_MCF_TiB_L", 24);
            CheckAnnotations(TIB_L, pepIndex, atest++);

            // current TIB_L peak should have idotp .87 and ppm -6.9
            Assert.AreEqual(0.87, GetTransitionGroupChromInfo(TIB_L, pepIndex).IsotopeDotProduct ?? -1, .005);
            Assert.AreEqual(-10.8, GetTransitionChromInfo(TIB_L, pepIndex, 0).MassError ?? -1, .05);

            ChangePeakBounds(TIB_L, pepIndex, 36.5, 38.0);

            // now current TIB_L peak should have idotp .9 and ppm -6.5
            Assert.AreEqual(0.9, GetTransitionGroupChromInfo(TIB_L, pepIndex).IsotopeDotProduct ?? -1, .005);
            Assert.AreEqual(-9.4, GetTransitionChromInfo(TIB_L, pepIndex, 0).MassError ?? -1, .05);
            CheckAnnotations(TIB_L, pepIndex, atest++);

            var undoIndex = SkylineWindow.Document.RevisionIndex; // preserve for simulating ctrl-z

            RunUI(() => SkylineWindow.Width = skylineWindowWidth);
            PickPeakBoth(pepIndex, 40.471035, 40.8134); // select peak for both chromatograms at these respective retention times
            PauseForScreenShot <GraphSummary.AreaGraphView>("Peak Areas graph metafile", 25);

            int[] m1Thru4 = { 1, 2, 3, 4, 5 };
            PickTransitions(pepIndex, m1Thru4, "Transition pick list filtered", 26, "Transition pick list unfiltered", 26); // turn on chromatograms
            PickPeakBoth(pepIndex, 36.992836, 37.3896027);                                                                  // select peak for both chromatograms at these respective retention times
            ZoomSingle(TIP3, 32.4, 42.2, 520);                                                                              // set the view for screenshot
            RunUI(() =>
            {
                SkylineWindow.Height = 550;
                SkylineWindow.ArrangeGraphsTabbed();
            });
            ActivateReplicate(TIP_NAME);
            PauseForScreenShot("Chromatogram graph metafile comparing 33 and 37 minute peaks", 27);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            RevertDoc(undoIndex); // undo changes

            ActivateReplicate(TIP_NAME);
            ClickChromatogram(TIP_NAME, 37.3, 142);
            PauseForScreenShot("MS1 spectrum graph 37.32 minutes", 28);
            ClickChromatogram(TIP_NAME, 33.2, 328.1);
            PauseForScreenShot("MS1 spectrum graph 33.19 minutes", 29);
            RunUI(() => SkylineWindow.HideFullScanGraph());

            RunUI(() =>
            {
                SkylineWindow.Width  = skylineWindowNarrowWidth;
                SkylineWindow.Height = skylineWindowHeight;
                SkylineWindow.ArrangeGraphs(DisplayGraphsType.Column);
            });
            pepIndex = JumpToPeptide("ASLGSLEGEAEAEASSPKGK"); // Not L10N
            Assert.IsTrue(10 == pepIndex);
            PauseForScreenShot("Chromatogram graph meta files for peptide ASLGSLEGEAEAEASSPKGK", 30);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            PickTransitions(pepIndex, m1Thru4);  // turn on M+3 and M+4
            ChangePeakBounds(TIP3, pepIndex, 37.35, 38.08);
            ZoomSingle(TIP3, 36.65, 39.11, 300); // simulate the wheel scroll described in tutorial
            PauseForScreenShot("upper - Chromatogram graph metafile for peptide ASLGSLEGEAEAEASSPKGK with adjusted integration", 31);
            CheckAnnotations(TIP3, pepIndex, atest++);

            RevertDoc(undoIndex);                              // undo changes
            pepIndex = JumpToPeptide("AEGEWEDQEALDYFSDKESGK"); // Not L10N
            PauseForScreenShot("lower - Chromatogram graph metafiles for peptide AEGEWEDQEALDYFSDKESGK", 31);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            int[] m1Thru5 = { 1, 2, 3, 4, 5, 6 };
            PickTransitions(pepIndex, m1Thru5); // turn on M+3 M+4 and M+5
            PauseForScreenShot("Chromatogram graph metafiles with M+3, M+4 and M+5 added", 32);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            JumpToPeptide("ALVEFESNPEETREPGSPPSVQR"); // Not L10N
            PauseForScreenShot("Chromatogram graph metafiles for peptide ALVEFESNPEETREPGSPPSVQR", 33);

            pepIndex = JumpToPeptide("YGPADVEDTTGSGATDSKDDDDIDLFGSDDEEESEEAKR"); // Not L10N
            if (IsPauseForScreenShots)
            {
                RestoreViewOnScreen(34);
                PauseForScreenShot("upper - Peak Areas graph metafile for peptide YGPADVEDTTGSGATDSKDDDDIDLFGSDDEEESEEAKR", 34);
            }

            int[] m1Thru7 = { 1, 2, 3, 4, 5, 6, 7, 8 };
            PickTransitions(pepIndex, m1Thru7); // enable [M+3] [M+4] [M+5] [M+6] [M+7]
            PauseForScreenShot("lower - Peak Areas graph metafile with M+3 through M+7 added", 34);
            CheckAnnotations(TIB_L, pepIndex, atest++);
            CheckAnnotations(TIP3, pepIndex, atest++);

            RunUI(() => SkylineWindow.ShowGraphPeakArea(false));

            // page 36 zooming setup
            RunUI(() =>
            {
                SkylineWindow.SynchronizeZooming(true);
                SkylineWindow.LockYChrom(false);
                SkylineWindow.AlignToFile = GetGraphChromatogram(TIP3).GetChromFileInfoId(); // align to Tip3
            });
            ZoomBoth(36.5, 39.5, 1600);                                                      // simulate the wheel scroll described in tutorial
            RunUI(() =>
            {
                SkylineWindow.ShowChromatogramLegends(false);
                SkylineWindow.Width  = skylineWindowWidth;
                SkylineWindow.Height = 720;
            });
            PauseForScreenShot("Chromatogram graphs clipped from main window with synchronized zooming", 35);

            ClickChromatogram(TIP_NAME, 37.5, 1107.3);
            PauseForScreenShot("MS1 spectrum graph 37.50 minutes", 36);
            RunUI(() => SkylineWindow.HideFullScanGraph());

            RunUI(() =>
            {
                SkylineWindow.ShowChromatogramLegends(true);
                SkylineWindow.Width  = skylineWindowNarrowWidth;
                SkylineWindow.Height = skylineWindowHeight;
            });
            RestoreViewOnScreen(36);                                                                                                      // float the Library Match window
            RunUI(() => SkylineWindow.GraphSpectrum.SelectSpectrum(new SpectrumIdentifier(MsDataFileUri.Parse(Tip3Filename), 37.6076f))); // set the Library Match view
            PauseForScreenShot <GraphSpectrum>("Library Match graph metafile - 5b_MCF7_TiTip3 (37.61 Min)", 37);

            RunUI(() => SkylineWindow.GraphSpectrum.SelectSpectrum(new SpectrumIdentifier(MsDataFileUri.Parse(Tib_LFilename), 37.0335f))); // set the Library Match view
            PauseForScreenShot <GraphSpectrum>("Library Match graph metafile - 1_MCF_TiB_L (37.03 min)", 37);

            RestoreViewOnScreen(37);                       // back to normal view
            /* pepIndex = */ JumpToPeptide("DQVANSAFVER"); // Not L10N
            PauseForScreenShot("Chromatogram graph metafiles for peptide DQVANSAFVER", 38);

//            int[] m1 = {2};
//            PickTransitions(pepIndex, m1); // enable [M+1] only
//            // Measured times in TIB_L are different from displayed times, because of alignment
//            ChangePeakBounds(TIB_L, pepIndex, 23.99, 25.29);
//            ChangePeakBounds(TIP3, pepIndex, 23.81, 25.21);
//            // First transition selected for screenshot
//            RunUI(() =>
//            {
//                var pathPep = SkylineWindow.SelectedPath;
//                var nodePep = ((PeptideTreeNode)SkylineWindow.SelectedNode).DocNode;
//                var nodeGroup = nodePep.TransitionGroups.First();
//                var nodeTran = nodeGroup.Transitions.First();
//                SkylineWindow.SelectedPath = new IdentityPath(
//                    new IdentityPath(pathPep, nodeGroup.TransitionGroup), nodeTran.Transition);
//            });
//            PauseForScreenShot("page 36 - M+1 only, with adjusted integration");
//            CheckAnnotations(TIB_L, pepIndex, atest++);
//            CheckAnnotations(TIP3, pepIndex, EXPECTED_ANNOTATIONS[atest]);

            var docAfter = WaitForProteinMetadataBackgroundLoaderCompletedUI();

            // Minimizing a chromatogram cache file.
            RunUI(SkylineWindow.CollapsePeptides);
            for (int i = 0; i < 5; i++) // just do the first 5
            {
                int iPeptide = i;
                var path     = docAfter.GetPathTo((int)SrmDocument.Level.Molecules, iPeptide);
                RunUI(() =>
                {
                    SkylineWindow.SelectedPath = path;
                });
                WaitForGraphs();
            }

            // Eliminate extraneous chromatogram data.
            doc = WaitForProteinMetadataBackgroundLoaderCompletedUI();
            var minimizedFile = GetTestPath("Ms1FilteringTutorial-2min.sky"); // Not L10N
            var cacheFile     = Path.ChangeExtension(minimizedFile, ChromatogramCache.EXT);

            {
                // TODO: Figure out why the minimize fails to unlock the .skyd file, if not minimized to current file
                RunUI(() => SkylineWindow.SaveDocument(minimizedFile));

                var manageResultsDlg   = ShowDialog <ManageResultsDlg>(SkylineWindow.ManageResults);
                var minimizeResultsDlg = ShowDialog <MinimizeResultsDlg>(manageResultsDlg.MinimizeResults);
                RunUI(() =>
                {
                    minimizeResultsDlg.LimitNoiseTime = true;
                    minimizeResultsDlg.NoiseTimeRange = 2;                                                        // Not L10N
                });
                PauseForScreenShot <MinimizeResultsDlg>("Minimize Results form (percentages vary slightly)", 39); // old p. 23

                OkDialog(minimizeResultsDlg, () => minimizeResultsDlg.MinimizeToFile(minimizedFile));
                WaitForCondition(() => File.Exists(cacheFile));
                WaitForClosedForm(manageResultsDlg);
            }
            WaitForDocumentChange(doc);

            // Inclusion list method export for MS1 filtering
            doc = SkylineWindow.Document;
            RunDlg <PeptideSettingsUI>(() => SkylineWindow.ShowPeptideSettingsUI(PeptideSettingsUI.TABS.Prediction), dlg =>
            {
                dlg.IsUseMeasuredRT = true;
                dlg.TimeWindow      = 10;
                dlg.OkDialog();
            });
            doc = WaitForDocumentChangeLoaded(doc);

            // Now deviating from the tutorial script for a moment to make sure we can choose a Scheduled export method.
            // CONSIDER: This refinement seems to be a no-op. Not sure why it is here.
            RunDlg <RefineDlg>(SkylineWindow.ShowRefineDlg, dlg =>
            {
                dlg.MinPeptides = 1;                                // This would get rid of proteins with no peptides (none exist)
                const double minPeakFoundRatio = 0.1;
                dlg.MinPeakFoundRatio          = minPeakFoundRatio; // This would get rid of undetected transitions (none exist)
                dlg.OkDialog();                                     // Will not change the document or add an Undo entry
            });
            // Nothing should have changed on the UI thread
            RunUI(() => Assert.AreSame(doc, SkylineWindow.DocumentUI));

            // Ready to export, although we will just cancel out of the dialog.
            var exportMethodDlg = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.Method));

            RunUI(() =>
            {
                exportMethodDlg.InstrumentType = ExportInstrumentType.ABI_TOF; // Not L10N
                exportMethodDlg.MethodType     = ExportMethodType.Scheduled;
                exportMethodDlg.CancelButton.PerformClick();
            });
            WaitForClosedForm(exportMethodDlg);

            // Because this was showing up in the nightly test failures
            WaitForConditionUI(() => exportMethodDlg.IsDisposed);

            RunUI(() => SkylineWindow.SaveDocument());
            RunUI(SkylineWindow.NewDocument);
        }
Ejemplo n.º 11
0
        private void TofTest()
        {
            // Working wih High-Resolution Mass Spectra.

            // Import a new Document. High-Resolution Mass Spectra, working with TOF p22.
            string newDocumentFile = GetTestPath(@"TOF\BSA_Agilent.sky");

            WaitForCondition(() => File.Exists(newDocumentFile));
            RunUI(() => SkylineWindow.OpenFile(newDocumentFile));

            bool asSmallMolecules = AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.none;

            if (asSmallMolecules)
            {
                ConvertDocumentToSmallMolecules(AsSmallMoleculesTestMode);
            }
            var       docCalibrate1 = WaitForDocumentLoaded();
            const int pepCount1 = 5, preCount1 = 5, tranCount1 = 30;

            AssertEx.IsDocumentState(docCalibrate1, null, 1, pepCount1, preCount1, tranCount1);


            // Try to import a file to show it fails.
            ImportResultsDlg importResultsDlg3 = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);

            RunUI(() => importResultsDlg3.NamedPathSets = importResultsDlg3.GetDataSourcePathsFileReplicates(
                      new[] { MsDataFileUri.Parse(GetTestPath(@"TOF\6-BSA-500fmol" + ExtAgilentRaw)) }));
            var importProgress = ShowDialog <AllChromatogramsGraph>(importResultsDlg3.OkDialog);

            WaitForDocumentChangeLoaded(docCalibrate1);
            WaitForConditionUI(() => importProgress.Finished);
            string expectedErrorFormat = Resources.NoFullScanFilteringException_NoFullScanFilteringException_To_extract_chromatograms_from__0__full_scan_settings_must_be_enabled_;

            WaitForConditionUI(() => !string.IsNullOrEmpty(importProgress.Error), "Missing expected error text: " + expectedErrorFormat);
            RunUI(() => AssertEx.AreComparableStrings(expectedErrorFormat, importProgress.Error, 1));
            RunUI(() =>
            {
                importProgress.ClickClose();
                SkylineWindow.Undo();
            });

            var document = SkylineWindow.Document;

            // Fill out Transition Settings Menu
            int tranCount2 = (AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.masses_only) ? (tranCount1 + preCount1 * 3) : (tranCount1 + preCount1); // No iostopes for mass-only document

            using (new CheckDocumentState(1, pepCount1, preCount1, tranCount2))
            {
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                RunUI(() =>
                {
                    transitionSettingsUI.SelectedTab = TransitionSettingsUI.TABS.FullScan;
                    transitionSettingsUI.PrecursorIsotopesCurrent = FullScanPrecursorIsotopes.Count;
                    transitionSettingsUI.PrecursorMassAnalyzer    = FullScanMassAnalyzerType.tof;
                    transitionSettingsUI.Peaks               = 3;
                    transitionSettingsUI.AcquisitionMethod   = FullScanAcquisitionMethod.Targeted;
                    transitionSettingsUI.ProductMassAnalyzer = FullScanMassAnalyzerType.tof;
                });
                PauseForScreenShot <TransitionSettingsUI.FullScanTab>("Transition Settings - Full-Scan tab for TOF", 28);

                RunUI(() =>
                {
                    transitionSettingsUI.RetentionTimeFilterType = RetentionTimeFilterType.none;

                    transitionSettingsUI.SelectedTab    = TransitionSettingsUI.TABS.Filter;
                    transitionSettingsUI.FragmentTypes += ", p";
                });
                PauseForScreenShot <TransitionSettingsUI.FilterTab>("Transition Settings - Filter tab", 29);

                OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);
            }

            var docHighRes          = WaitForDocumentChange(document);
            var tranSettingsHighRes = docHighRes.Settings.TransitionSettings;

            Assert.AreEqual(FullScanPrecursorIsotopes.Count, tranSettingsHighRes.FullScan.PrecursorIsotopes);
            Assert.AreEqual(FullScanMassAnalyzerType.tof, tranSettingsHighRes.FullScan.PrecursorMassAnalyzer);
            Assert.AreEqual(FullScanAcquisitionMethod.Targeted, tranSettingsHighRes.FullScan.AcquisitionMethod);
            Assert.IsTrue(ArrayUtil.EqualsDeep(new[] { IonType.y, IonType.b, IonType.precursor },
                                               tranSettingsHighRes.Filter.IonTypes));
            RunUI(() => SkylineWindow.ExpandPrecursors());

            // Assert each peptide contains 3 precursors transitions (unless this is a masses-only small molecule doc).
            foreach (var nodeGroup in SkylineWindow.Document.MoleculeTransitionGroups)
            {
                for (int i = 0; i < nodeGroup.Children.Count; i++)
                {
                    var nodeTran = (TransitionDocNode)nodeGroup.Children[i];
                    if (i < ((AsSmallMoleculesTestMode == RefinementSettings.ConvertToSmallMoleculesMode.masses_only) ? 1 : 3))
                    {
                        Assert.AreEqual(IonType.precursor, nodeTran.Transition.IonType);
                    }
                    else
                    {
                        Assert.AreNotEqual(IonType.precursor, nodeTran.Transition.IonType);
                    }
                }
            }
            RestoreViewOnScreen(30);
            PauseForScreenShot("Targets View tree clipped from main window", 30);

            RunDlg <ImportResultsDlg>(SkylineWindow.ImportResults, importResultsDlg2 =>
            {
                string[] filePaths =
                {
                    GetTestPath(@"TOF\6-BSA-500fmol" + ExtAgilentRaw)
                };
                importResultsDlg2.NamedPathSets = importResultsDlg2.GetDataSourcePathsFileReplicates(filePaths.Select(MsDataFileUri.Parse));
                importResultsDlg2.OkDialog();
            });
            WaitForDocumentChangeLoaded(docHighRes);
            if (AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.masses_only)
            {
                FindNode(asSmallMolecules ? "LVNELTEFAK" : "K.LVNELTEFAK.T [65, 74]");
            }
            else
            {
                FindNode(document.MoleculeTransitionGroups.First().CustomIon.DisplayName);
            }
            RunUI(() =>
            {
                SkylineWindow.CollapsePrecursors();
                SkylineWindow.AutoZoomNone();
                SkylineWindow.ShowGraphPeakArea(false);
                SkylineWindow.ShowProductTransitions();
            });

            RestoreViewOnScreen(31);
            RunUI(() => SkylineWindow.Width = 1013);
            PauseForScreenShot("Main window full gradient import of high concentration and Targets tree clipped", 31);

            {
                var peptideSettingsUI = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);
                RunUI(() =>
                {
                    peptideSettingsUI.SelectedTab = PeptideSettingsUI.TABS.Prediction;
                    Assert.IsTrue(peptideSettingsUI.IsUseMeasuredRT);
                    Assert.AreEqual(2.0, peptideSettingsUI.TimeWindow);
                });

                PauseForScreenShot <PeptideSettingsUI.PredictionTab>("Peptide Settings - Prediction tab", 32);

                OkDialog(peptideSettingsUI, peptideSettingsUI.CancelDialog);
            }

            using (new CheckDocumentState(1, pepCount1, preCount1, tranCount2))
            {
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                RunUI(() =>
                {
                    transitionSettingsUI.SelectedTab = TransitionSettingsUI.TABS.FullScan;
                    transitionSettingsUI.SetRetentionTimeFilter(RetentionTimeFilterType.scheduling_windows, 1);
                });

                PauseForScreenShot <TransitionSettingsUI.FullScanTab>("Transition Settings - Full-Scan tab wtih scheduled extraction", 33);

                OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);
            }

            var chooseSchedulingReplicateDlg = ShowDialog <ChooseSchedulingReplicatesDlg>(SkylineWindow.ImportResults);

            RunUI(() =>
            {
                // Make sure UI is up to date to avoid race condition
                chooseSchedulingReplicateDlg.UpdateUi();
                chooseSchedulingReplicateDlg.SelectOrDeselectAll(true);
            });
            RunDlg <ImportResultsDlg>(chooseSchedulingReplicateDlg.OkDialog, importResultsDlg2 =>
            {
                string[] filePaths =
                {
                    GetTestPath(@"TOF\1-BSA-50amol" + ExtAgilentRaw),
                    GetTestPath(@"TOF\2-BSA-100amol" + ExtAgilentRaw),
                    GetTestPath(@"TOF\3-BSA-1fmol" + ExtAgilentRaw),
                    GetTestPath(@"TOF\4-BSA-10fmol" + ExtAgilentRaw),
                    GetTestPath(@"TOF\5-BSA-100fmol" + ExtAgilentRaw),
                };
                importResultsDlg2.NamedPathSets = importResultsDlg2.GetDataSourcePathsFileReplicates(filePaths.Select(MsDataFileUri.Parse));
                importResultsDlg2.OkDialog();
            });
            //Give the Raw files some time to be processed.
            WaitForCondition(15 * 60 * 1000, () => SkylineWindow.Document.Settings.HasResults && SkylineWindow.Document.Settings.MeasuredResults.IsLoaded); // 15 minutes
            WaitForClosedAllChromatogramsGraph();
            RunUI(() => SkylineWindow.ShowGraphSpectrum(false));
            WaitForGraphs();
            TryWaitForConditionUI(() => SkylineWindow.GraphChromatograms.Count(graphChrom => !graphChrom.IsHidden) == 6);
            RunUI(() =>
            {
                Assert.IsFalse(SkylineWindow.IsGraphSpectrumVisible);
                var listGraphs = SkylineWindow.GraphChromatograms.Where(graphChrom => !graphChrom.IsHidden).ToList();
                if (listGraphs.Count != 6)
                {
                    string hiddenGraphs = string.Empty;
                    var listHidden      = SkylineWindow.GraphChromatograms.Where(graphChrom => graphChrom.IsHidden).ToList();
                    if (listHidden.Count != 0)
                    {
                        hiddenGraphs = TextUtil.LineSeparate(string.Empty, "Hidden:", TextUtil.LineSeparate(listHidden.Select(g => g.TabText)));
                    }
                    Assert.Fail(TextUtil.LineSeparate(string.Format("Expecting 6 visible graphs but found {0}", listGraphs.Count),
                                                      TextUtil.LineSeparate(listGraphs.Select(g => g.TabText)), hiddenGraphs));
                }
                var chromGraphs = SkylineWindow.GraphChromatograms.ToArray();
                Assert.AreEqual(6, chromGraphs.Length);
            });

            RunDlg <ManageResultsDlg>(SkylineWindow.ManageResults, dlg =>
            {
                for (int i = 0; i < 5; i++)
                {
                    dlg.MoveDown();
                }
                dlg.OkDialog();
            });
            RunDlg <ArrangeGraphsGroupedDlg>(SkylineWindow.ArrangeGraphsGrouped, dlg =>
            {
                dlg.Groups     = 6;
                dlg.GroupOrder = GroupGraphsOrder.Document;
                dlg.OkDialog();
            });
            WaitForGraphs();

            RunUI(() => SkylineWindow.Height = 768);
            PauseForScreenShot("Chromatogram graphs clipped from main window", 34);

            RunUI(() =>
            {
                var graphChrom6 = SkylineWindow.GetGraphChrom("6-BSA-500fmol");
                var graphChrom5 = SkylineWindow.GetGraphChrom("5-BSA-100fmol");
                var graphChrom4 = SkylineWindow.GetGraphChrom("4-BSA-10fmol");
                var graphChrom3 = SkylineWindow.GetGraphChrom("3-BSA-1fmol");
                var graphChrom2 = SkylineWindow.GetGraphChrom("2-BSA-100amol");
                var graphChrom1 = SkylineWindow.GetGraphChrom("1-BSA-50amol");
                Assert.AreEqual(13.3, graphChrom6.BestPeakTime ?? 0, 0.05);
                Assert.AreEqual(13.5, graphChrom5.BestPeakTime ?? 0, 0.05);
                Assert.AreEqual(13.6, graphChrom4.BestPeakTime ?? 0, 0.05);
                Assert.AreEqual(13.6, graphChrom3.BestPeakTime ?? 0, 0.05);
                Assert.AreEqual(13.6, graphChrom2.BestPeakTime ?? 0, 0.05);
                Assert.AreEqual(13.6, graphChrom1.BestPeakTime ?? 0, 0.05);
            });

            RunUI(SkylineWindow.AutoZoomBestPeak);
            WaitForGraphs();

            PauseForScreenShot("Chromatogram graphs clipped from main window zoomed", 35);

            RunUI(() =>
            {
                SkylineWindow.ShowPeakAreaReplicateComparison();
                SkylineWindow.ShowPeptideLogScale(true);
            });

            // p. 28
            PauseForScreenShot <GraphSummary.AreaGraphView>("Peak Areas Replicate Comparison graph metafile", 36);
            WaitForDotProducts();
            RunUI(() =>
            {
                Assert.AreEqual((AsSmallMoleculesTestMode == RefinementSettings.ConvertToSmallMoleculesMode.none) ? 7 : 6, SkylineWindow.GraphPeakArea.Categories.Count());
                Assert.AreEqual(6, SkylineWindow.GraphPeakArea.CurveCount);
            });
            VerifyDotProducts(0.87, 0.67, 0.91, 0.90, 0.90, 0.90);

            RunUI(() =>
            {
                SkylineWindow.ShowAllTransitions();
                SkylineWindow.ShowSplitChromatogramGraph(false);
                SkylineWindow.ArrangeGraphsTabbed();
                SkylineWindow.ActivateReplicate("6-BSA-500fmol");
                SkylineWindow.Size = new Size(745, 545);
                SkylineWindow.ShowGraphPeakArea(false);
            });
            PauseForScreenShot("Chromatogram graph metafile for 500 fmol", 37);

            RunUI(() =>
            {
                SkylineWindow.ShowGraphPeakArea(true);
                SkylineWindow.ShowPrecursorTransitions();
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.ActivateReplicate("4-BSA-10fmol");
            });

            WaitForDotProducts();
            RunUI(() =>
            {
                Assert.AreEqual(7, SkylineWindow.GraphPeakArea.Categories.Count());
                Assert.AreEqual((AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.masses_only) ? 3 : 1, SkylineWindow.GraphPeakArea.CurveCount);
            });
            VerifyDotProducts(0.99, 0.52, 0.98, 1.00, 1.00, 1.00);
            RunUI(() =>
            {
                SkylineWindow.ShowGraphPeakArea(false);
                SkylineWindow.Size = new Size(1013, 768);
            });
            PauseForScreenShot("Main window", 38);
            RunUI(SkylineWindow.ShowPeakAreaReplicateComparison);
            PauseForScreenShot <GraphSummary.AreaGraphView>("Peak Areas Replicate Comparison graph metafile", 39);

            RunUI(() => SkylineWindow.SaveDocument());
            WaitForConditionUI(() => !SkylineWindow.Dirty);
        }
Ejemplo n.º 12
0
        private void LowResTest()
        {
            string documentFile = GetTestPath(@"Low Res\BSA_Protea_label_free_meth3.sky");

            WaitForCondition(() => File.Exists(documentFile));
            RunUI(() => SkylineWindow.OpenFile(documentFile));
            bool AsSmallMolecules = AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.none;

            const int expectedMoleculeCount        = 9;
            int       expectedTransitionGroupCount = 10;
            int       expectedTransitionCount      = 78;
            var       document = SkylineWindow.Document;

            if (AsSmallMolecules)
            {
                ConvertDocumentToSmallMolecules(AsSmallMoleculesTestMode);
                document = SkylineWindow.Document;
                Assert.AreEqual(document.PeptideTransitionGroupCount, 0);
                Assert.AreEqual(document.MoleculeTransitionGroupCount, expectedTransitionGroupCount);
                Assert.AreEqual(document.PeptideTransitionCount, 0);
                Assert.AreEqual(document.MoleculeTransitionCount, expectedTransitionCount);
            }
            AssertEx.IsDocumentState(document, null, 3, expectedMoleculeCount, expectedTransitionGroupCount, expectedTransitionCount);

            // p. 3 Select first peptide
            RunUI(() => SkylineWindow.SelectedPath = document.GetPathTo((int)SrmDocument.Level.Molecules, 0));
            PauseForScreenShot("Main window", 3);

            // p. 4 Configure Document for Thermo raw files
            {
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                RunUI(() => transitionSettingsUI.SelectedTab = TransitionSettingsUI.TABS.FullScan);
                PauseForScreenShot <TransitionSettingsUI.FullScanTab>("Peptide Settings - Full-Scan tab blank", 5);

                RunUI(() =>
                {
                    transitionSettingsUI.PrecursorIsotopesCurrent = FullScanPrecursorIsotopes.Count;
                    transitionSettingsUI.PrecursorMassAnalyzer    = FullScanMassAnalyzerType.qit;
                    transitionSettingsUI.AcquisitionMethod        = FullScanAcquisitionMethod.Targeted;
                });
                PauseForScreenShot <TransitionSettingsUI.FullScanTab>("Peptide Settings - Full-Scan tab low res", 6);

                RunUI(() =>
                {
                    transitionSettingsUI.SetRetentionTimeFilter(RetentionTimeFilterType.ms2_ids, 2);

                    // p.6 - library ion match tolerance same as extraction window
                    transitionSettingsUI.SelectedTab       = TransitionSettingsUI.TABS.Library;
                    transitionSettingsUI.IonMatchTolerance = 0.7;
                });
                PauseForScreenShot <TransitionSettingsUI.LibraryTab>("Transition Settings - Library tab match tolerance same as MS/MS resolution", 8);

                RunUI(() =>
                {
                    // p.6
                    transitionSettingsUI.SelectedTab    = TransitionSettingsUI.TABS.Filter;
                    transitionSettingsUI.FragmentTypes += ", p";
                });
                PauseForScreenShot <TransitionSettingsUI.FilterTab>("Transition Settings - Filter tab", 9);

                OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);

                var docFullScan          = WaitForDocumentChange(document);
                var tranSettingsFullScan = docFullScan.Settings.TransitionSettings;
                Assert.AreEqual(FullScanPrecursorIsotopes.Count, tranSettingsFullScan.FullScan.PrecursorIsotopes);
                Assert.AreEqual(FullScanMassAnalyzerType.qit, tranSettingsFullScan.FullScan.PrecursorMassAnalyzer);
                Assert.AreEqual(FullScanAcquisitionMethod.Targeted, tranSettingsFullScan.FullScan.AcquisitionMethod);
                Assert.IsTrue(ArrayUtil.EqualsDeep(new[] { IonType.y, IonType.b, IonType.precursor },
                                                   tranSettingsFullScan.Filter.IonTypes));
            }

            RunUI(() => SkylineWindow.ExpandPrecursors());

            // Check all the precursors on picklists
            bool pausedForScreenShot = false;

            foreach (PeptideGroupTreeNode node in SkylineWindow.SequenceTree.GetSequenceNodes())
            {
                foreach (TreeNode child in node.Nodes)
                {
                    foreach (SrmTreeNodeParent grandChild in child.Nodes)
                    {
                        // Because of RunUI must copy to local variable first.
                        SrmTreeNodeParent child1 = grandChild;
                        RunUI(() => SkylineWindow.SequenceTree.SelectedNode = child1);
                        var picklist = ShowDialog <PopupPickList>(() => SkylineWindow.SequenceTree.ShowPickList(false));
                        RunUI(() =>
                        {
                            picklist.SetItemChecked(0, true);
                            Assert.IsTrue(picklist.GetItemLabel(0).Contains(IonType.precursor.GetLocalizedString()));
                            Assert.IsTrue(picklist.GetItemChecked(0));
                        });
                        if (!pausedForScreenShot)
                        {
                            PauseForScreenShot <PopupPickList>("Transitions popup pick-list", 10);
                            pausedForScreenShot = true;
                        }
                        OkDialog(picklist, picklist.OnOk);
                    }
                }
            }
            WaitForDocumentLoaded();
            if (!AsSmallMolecules)  // No libraries for small molecules, yet
            {
                foreach (var nodeGroup in SkylineWindow.Document.MoleculeTransitionGroups)
                {
                    Assert.IsFalse(nodeGroup.HasLibInfo && nodeGroup.Transitions.All(nodeTran => !nodeTran.HasLibInfo));
                }
            }
            // All transition groups should now have a precursor transition
            foreach (var nodeGroup in SkylineWindow.Document.MoleculeTransitionGroups)
            {
                Assert.AreEqual(IonType.precursor, nodeGroup.Transitions.First().Transition.IonType);
            }

            // p.8
            ExportMethodDlg exportMethodDlg =
                ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.Method));

            RunUI(() =>
            {
                exportMethodDlg.SetInstrument("Thermo LTQ");
                Assert.AreEqual("Thermo LTQ", exportMethodDlg.InstrumentType);
                exportMethodDlg.SetMethodType(ExportMethodType.Standard);
                exportMethodDlg.SetTemplateFile(GetTestPath(@"Low Res\TargetedMSMS_template.meth"));
            });
            PauseForScreenShot <ExportMethodDlg.MethodView>("Export Method form", 11);

            // p. 10 Ok the error box.
            {
                var messageDlg = ShowDialog <MessageDlg>(() => exportMethodDlg.OkDialog(GetTestPath(@"Low Res\TargetedMSMS_BSA_Protea.meth")));
                PauseForScreenShot <MessageDlg>("Error message (expected)", 12);

                OkDialog(messageDlg, messageDlg.OkDialog);
            }

            // Making a report by hand p.11
            ExportLiveReportDlg exportReportDlg = ShowDialog <ExportLiveReportDlg>(() => SkylineWindow.ShowExportReportDialog());
            var editReportListDlg = ShowDialog <ManageViewsForm>(exportReportDlg.EditList);
            var viewEditor        = ShowDialog <ViewEditor>(editReportListDlg.AddView);

            RunUI(() =>
            {
                Assert.IsTrue(viewEditor.ChooseColumnsTab.TrySelect(PropertyPath.Parse("Proteins!*.Name")));
                viewEditor.ChooseColumnsTab.AddSelectedColumn();
                Assert.AreEqual(1, viewEditor.ChooseColumnsTab.ColumnCount);
                var columnsToAdd = new[]
                {
                    PropertyPath.Parse("Proteins!*.Peptides!*.Precursors!*.ModifiedSequence"),
                    PropertyPath.Parse("Proteins!*.Peptides!*.Precursors!*.Charge"),
                    PropertyPath.Parse("Proteins!*.Peptides!*.Precursors!*.Mz"),
                };
                foreach (var id in columnsToAdd)
                {
                    Assert.IsTrue(viewEditor.ChooseColumnsTab.TrySelect(id), "Unable to select {0}", id);
                    viewEditor.ChooseColumnsTab.AddSelectedColumn();
                }
                Assert.AreEqual(4, viewEditor.ChooseColumnsTab.ColumnCount);
            });
            PauseForScreenShot <ViewEditor>("Edit Report form", 13);

            {
                var previewReportDlg = ShowDialog <DocumentGridForm>(viewEditor.ShowPreview);
                var expectedRows     = 10 + (TestSmallMolecules ? 1 : 0);
                WaitForConditionUI(() => previewReportDlg.IsComplete && previewReportDlg.RowCount == expectedRows);
                RunUI(() =>
                {
                    Assert.AreEqual(4, previewReportDlg.ColumnCount);
                    var precursors =
                        SkylineWindow.Document.MoleculeTransitionGroups.ToArray();
                    const int precursorIndex = 3;
                    for (int i = 0; i < expectedRows; i++)
                    {
                        Assert.AreEqual(precursors[i].PrecursorMz, double.Parse(previewReportDlg.DataGridView.Rows[i].Cells[precursorIndex].Value.ToString()), 0.000001);
                    }
                    var precursorMzCol = previewReportDlg.DataGridView.Columns[precursorIndex];
                    Assert.IsNotNull(precursorMzCol);
                    previewReportDlg.DataGridView.Sort(precursorMzCol, ListSortDirection.Ascending);
                });
                PauseForScreenShot <DocumentGridForm>("Preview New Report window", 14);

                OkDialog(previewReportDlg, previewReportDlg.Close);
            }

            // Press the Esc key until all forms have been dismissed.
            RunUI(() =>
            {
                viewEditor.Close();
                editReportListDlg.Close();
                exportReportDlg.CancelClick();
            });
            WaitForClosedForm(viewEditor);
            WaitForClosedForm(editReportListDlg);
            WaitForClosedForm(exportReportDlg);

            //p. 12 Import Full-Scan Data
            // Launch import peptide search wizard
            var importPeptideSearchDlg = ShowDialog <ImportPeptideSearchDlg>(SkylineWindow.ShowImportPeptideSearchDlg);

            RunUI(() => importPeptideSearchDlg.BuildPepSearchLibControl.WorkflowType = ImportPeptideSearchDlg.Workflow.prm);

            PauseForScreenShot <ImportPeptideSearchDlg.SpectraPage>("Import Peptide Search Build Spectral Library blank page", 15);

            const int    prefixLen             = 35;
            const string lowResDir             = "Low Res";
            const string searchDir             = "search";
            const string lowRes20Base          = "klc_20100329v_Protea_Peptide_Curve_20fmol_uL_tech1";
            string       lowRes20File          = GetTestPath(Path.Combine(lowResDir, lowRes20Base + ExtThermoRaw));
            string       lowRes20FileRaw       = Path.ChangeExtension(lowRes20File, ExtThermoRaw);
            string       lowRes20Search        = GetTestPath(Path.Combine(lowResDir, Path.Combine(searchDir, lowRes20Base + BiblioSpecLiteBuilder.EXT_PERCOLATOR)));
            string       shortLowRes20FileName = (Path.GetFileNameWithoutExtension(lowRes20File) ?? "").Substring(prefixLen);
            const string lowRes80Base          = "klc_20100329v_Protea_Peptide_Curve_80fmol_uL_tech1";
            string       lowRes80File          = GetTestPath(Path.Combine(lowResDir, lowRes80Base + ExtThermoRaw));
            string       lowRes80Search        = GetTestPath(Path.Combine(lowResDir, Path.Combine(searchDir, lowRes80Base + BiblioSpecLiteBuilder.EXT_PERCOLATOR)));
            string       shortLowRes80FileName = (Path.GetFileNameWithoutExtension(lowRes80File) ?? "").Substring(prefixLen);

            string[] searchFiles = { lowRes20Search, lowRes80Search };
            var      doc         = SkylineWindow.Document;

            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage ==
                              ImportPeptideSearchDlg.Pages.spectra_page);
                importPeptideSearchDlg.BuildPepSearchLibControl.AddSearchFiles(searchFiles);
                importPeptideSearchDlg.BuildPepSearchLibControl.CutOffScore = 0.99;
                importPeptideSearchDlg.BuildPepSearchLibControl.FilterForDocumentPeptides = true;
            });
            PauseForScreenShot <ImportPeptideSearchDlg.SpectraPage>("Import Peptide Search Build Spectral Library with files page", 16);

            RunDlg <MessageDlg>(importPeptideSearchDlg.ClickNextButtonNoCheck, dlg => dlg.OkDialog());
            doc = WaitForDocumentChangeLoaded(doc);

            // Verify document library was built
            string docLibPath          = BiblioSpecLiteSpec.GetLibraryFileName(documentFile);
            string redundantDocLibPath = BiblioSpecLiteSpec.GetRedundantName(docLibPath);

            Assert.IsTrue(File.Exists(docLibPath) && File.Exists(redundantDocLibPath));
            var librarySettings = SkylineWindow.Document.Settings.PeptideSettings.Libraries;

            Assert.IsTrue(librarySettings.HasDocumentLibrary);

            PauseForScreenShot <ImportPeptideSearchDlg.ChromatogramsPage>("Import Peptide Search Extract Chromatograms page", 17);

            // We're on the "Extract Chromatograms" page of the wizard.
            // All the test results files are in the same directory as the
            // document file, so all the files should be found, and we should
            // just be able to move to the next page.
            TryWaitForConditionUI(() => importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.chromatograms_page);
            var correctPage = false;

            ImportPeptideSearchDlg.Pages currentPage = 0;
            RunUI(() => correctPage = ImportPeptideSearchDlg.Pages.chromatograms_page == (currentPage = importPeptideSearchDlg.CurrentPage));
            if (!correctPage)
            {
                WaitForConditionUI(1, // Immediate timeout - just want the richer error message that WaitForConditionUI provides
                                   () => importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.chromatograms_page,
                                   string.Format("Expected to be on chromatograms_page, on {0} instead", currentPage));
            }
            var importResultsNameDlg = ShowDialog <ImportResultsNameDlg>(() => importPeptideSearchDlg.ClickNextButton());

            OkDialog(importResultsNameDlg, importResultsNameDlg.YesDialog);

            // Modifications are already set up, so that page should get skipped.

            // We're on the "Configure Transition Settings" page of the wizard.
            // We've already set up these settings, so just click next.
            WaitForConditionUI(() => importPeptideSearchDlg.IsNextButtonEnabled);
            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.transition_settings_page);
                Assert.IsTrue(importPeptideSearchDlg.ClickNextButton());
            });

            // We're on the "Configure Full-Scan Settings" page of the wizard.
            // We've already set up these settings, so just click next.
            WaitForConditionUI(() => importPeptideSearchDlg.IsNextButtonEnabled);
            RunUI(() =>
            {
                Assert.IsTrue(importPeptideSearchDlg.CurrentPage == ImportPeptideSearchDlg.Pages.full_scan_settings_page);
                Assert.IsTrue(importPeptideSearchDlg.ClickNextButton());
            });
            doc = WaitForDocumentChange(doc);

            // Add FASTA also skipped because filter for document peptides was chosen.

            WaitForClosedForm(importPeptideSearchDlg);
            PauseForScreenShot <AllChromatogramsGraph>("Loading chromatograms window", 18);
            WaitForDocumentChangeLoaded(doc, 15 * 60 * 1000); // 15 minutes
            WaitForClosedAllChromatogramsGraph();

            expectedTransitionGroupCount = 10; // Expect this many with results
            expectedTransitionCount      = 87; // Expect this many with results
            AssertResult.IsDocumentResultsState(SkylineWindow.Document, shortLowRes20FileName, expectedMoleculeCount, expectedTransitionGroupCount, 0, expectedTransitionCount, 0);
            AssertResult.IsDocumentResultsState(SkylineWindow.Document, shortLowRes80FileName, expectedMoleculeCount, expectedTransitionGroupCount, 0, expectedTransitionCount, 0);

            RunUI(() =>
            {
                Assert.IsTrue(SkylineWindow.IsGraphSpectrumVisible);
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.CollapsePrecursors();
                SkylineWindow.Width = 1070;
            });

            // Select the first precursor.
            if (AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.masses_only)
            {
                FindNode(AsSmallMolecules ? "LVNELTEFAK" : "K.LVNELTEFAK.T [65, 74]");
            }
            else
            {
                FindNode(document.MoleculeTransitionGroups.First().CustomIon.DisplayName);
            }
            // Ensure Graphs look like p17. (checked)
            WaitForGraphs();
            RestoreViewOnScreen(18);
            PauseForScreenShot("Main window with data imported", 19);

            const double minDotp = 0.9;

            foreach (var nodeGroup in SkylineWindow.Document.PeptideTransitionGroups)
            {
                double dotp = nodeGroup.Results[0][0].LibraryDotProduct ?? 0;
                Assert.IsTrue(Math.Round(dotp, 2) >= minDotp, string.Format("Library dot-product {0} found below {1}", dotp, minDotp));
            }

            RunUI(() => SkylineWindow.AutoZoomBestPeak());
            // Ensure Graphs look like p18. (checked)
            WaitForGraphs();
            PauseForScreenShot("Chromatogram graphs clipped from main window with zoomed peaks", 20);

            RestoreViewOnScreen(21);
            RunUI(() => SkylineWindow.GraphSpectrum.SelectSpectrum(new SpectrumIdentifier(lowRes20FileRaw, 77.7722)));
            PauseForScreenShot <GraphSpectrum>("Library Match view clipped from main window with noisy spectrum", 21);

            RunUI(() =>
            {
                SkylineWindow.ShowGraphSpectrum(false);
                Assert.IsFalse(SkylineWindow.IsGraphSpectrumVisible);
                SkylineWindow.ShowPeptideIDTimes(false);
            });

            RunUI(() =>
            {
                var chromGraphs = SkylineWindow.GraphChromatograms.ToArray();
                Assert.AreEqual(2, chromGraphs.Length);
                Assert.AreEqual(46.8, chromGraphs[0].GraphItems.First().BestPeakTime, 0.05);
                Assert.AreEqual(46.8, chromGraphs[1].GraphItems.First().BestPeakTime, 0.05);

                SkylineWindow.ShowPeakAreaReplicateComparison();
                SkylineWindow.ShowProductTransitions();
            });
            WaitForCondition(() => !SkylineWindow.GraphPeakArea.IsHidden);
            if (!AsSmallMolecules)  // No libraries (yet?)
            {
                WaitForDotProducts();
            }
            RunUI(() =>
            {
                // Graph p.15
                Assert.AreEqual(AsSmallMolecules ? 2 : 3, SkylineWindow.GraphPeakArea.Categories.Count());
                Assert.AreEqual(6, SkylineWindow.GraphPeakArea.CurveCount);
            });
            PauseForScreenShot <GraphSummary.AreaGraphView>("Peak Areas Replicate Comparison graph metafile", 22);
            if (!AsSmallMolecules)  // No libraries (yet?)
            {
                VerifyDotProducts(0.99, 0.98);
            }

            // Check graph p15. (checked)
            RunUI(() =>
            {
                SkylineWindow.ShowAllTransitions();
                SkylineWindow.ShowSplitChromatogramGraph(true);
            });

            // p. 16 screenshot of full 5-point dilution curve

            // Select precursor
            if (AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.masses_only)
            {
                FindNode(AsSmallMolecules ? "DRVYIHPF" : "R.DRVYIHPF.- [34, 41]");  // May be localized " (missed 1)"
            }
            else
            {
                FindNode(Resources.CustomIon_DisplayName_Ion + " [1047");
            }
            WaitForGraphs();
            PauseForScreenShot <GraphSummary.AreaGraphView>("Peak Areas Replicate Comparison graph metafile with split graphs", 24);
            RunUI(() =>
            {
                SkylineWindow.Size = new Size(990, 620);
                SkylineWindow.ShowGraphPeakArea(false);
            });
            PauseForScreenShot("Chromatogram graphs clipped from main window with split graphs", 25);

            // PeakAreaGraph Normalize to total p.20.
            RunUI(() =>
            {
                SkylineWindow.ShowGraphPeakArea(true);
                SkylineWindow.ShowProductTransitions();
                SkylineWindow.NormalizeAreaGraphTo(AreaNormalizeToView.area_percent_view);
            });

            // Ensure graph looks like p20.
            if (AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.masses_only)
            {
                FindNode(AsSmallMolecules ? "KNLQSLDPSH" : "R.IKNLQSLDPSH.- [80, 90]");
                FindNode(AsSmallMolecules ? "KNLQSLDPSH" : "R.IKNLQSLDPSH.- [80, 90]"); // Phosphorylated
            }
            else
            {
                FindNode(Resources.CustomIon_DisplayName_Ion + " [1333");
            }
            WaitForGraphs();
            PauseForScreenShot <GraphSummary.AreaGraphView>("figure 1a - Area Replicate graph metafile for IKNLQSLDPSH", 26);
            RunUI(() =>
            {
                Assert.AreEqual(AsSmallMolecules ? 2 : 3, SkylineWindow.GraphPeakArea.Categories.Count());
                Assert.AreEqual(9, SkylineWindow.GraphPeakArea.CurveCount);
            });

            if (AsSmallMoleculesTestMode != RefinementSettings.ConvertToSmallMoleculesMode.masses_only)
            {
                FindNode(AsSmallMolecules ? "HLVDEPQNLIK" : "K.HLVDEPQNLIK.Q [401, 411]");
            }
            else
            {
                FindNode(Resources.CustomIon_DisplayName_Ion + " [1306");
            }
            WaitForGraphs();
            PauseForScreenShot("figure 1b - Area replicate graph metafile for HLVDEPQNLIK", 26);
            RunUI(() =>
            {
                Assert.AreEqual(AsSmallMolecules ? 2 : 3, SkylineWindow.GraphPeakArea.Categories.Count());
                Assert.AreEqual(7, SkylineWindow.GraphPeakArea.CurveCount);
            });

            RunUI(() => SkylineWindow.ShowGraphPeakArea(false));
            WaitForCondition(() => SkylineWindow.GraphPeakArea.IsHidden);
            RunUI(() => SkylineWindow.SaveDocument());
        }
        protected override void DoTest()
        {
            var folderAbsoluteQuant = UseRawFiles ? "AbsoluteQuant" : "AbsoluteQuantMzml";
            // Generating a Transition List, p. 4
            {
                var doc = SkylineWindow.Document;
                var transitionSettingsUI = ShowDialog <TransitionSettingsUI>(SkylineWindow.ShowTransitionSettingsUI);
                RunUI(() =>
                {
                    // Predicition Settings
                    transitionSettingsUI.SelectedTab       = TransitionSettingsUI.TABS.Prediction;
                    transitionSettingsUI.PrecursorMassType = MassType.Monoisotopic;
                    transitionSettingsUI.FragmentMassType  = MassType.Monoisotopic;
                    transitionSettingsUI.RegressionCEName  = "Thermo TSQ Vantage";
                    transitionSettingsUI.RegressionDPName  = Resources.SettingsList_ELEMENT_NONE_None;
                });
                PauseForScreenShot <TransitionSettingsUI.PredictionTab>("Transition Settings - Prediction tab", 4);

                RunUI(() =>
                {
                    // Filter Settings
                    transitionSettingsUI.SelectedTab      = TransitionSettingsUI.TABS.Filter;
                    transitionSettingsUI.PrecursorCharges = "2";
                    transitionSettingsUI.ProductCharges   = "1";
                    transitionSettingsUI.FragmentTypes    = "y";
                    transitionSettingsUI.RangeFrom        = Resources.TransitionFilter_FragmentStartFinders_ion_3;
                    transitionSettingsUI.RangeTo          = Resources.TransitionFilter_FragmentEndFinders_last_ion_minus_1;
                    transitionSettingsUI.SpecialIons      = new string[0];
                });
                PauseForScreenShot <TransitionSettingsUI.FilterTab>("Transition Settings - Filter tab", 4);

                OkDialog(transitionSettingsUI, transitionSettingsUI.OkDialog);
                WaitForDocumentChange(doc);
            }

            // Configuring Peptide settings p. 4
            PeptideSettingsUI peptideSettingsUI = ShowDialog <PeptideSettingsUI>(SkylineWindow.ShowPeptideSettingsUI);

            RunUI(() => peptideSettingsUI.SelectedTab = PeptideSettingsUI.TABS.Modifications);
            PauseForScreenShot <PeptideSettingsUI.ModificationsTab>("Peptide Settings - Modification tab", 5);

            var modHeavyK = new StaticMod("Label:13C(6)15N(2) (C-term K)", "K", ModTerminus.C, false, null, LabelAtoms.C13 | LabelAtoms.N15,
                                          RelativeRT.Matching, null, null, null);

            AddHeavyMod(modHeavyK, peptideSettingsUI, "Edit Isotope Modification over Transition Settings", 5);
            RunUI(() => peptideSettingsUI.PickedHeavyMods = new[] { modHeavyK.Name });
            PauseForScreenShot <PeptideSettingsUI.ModificationsTab>("Peptide Settings - Modification tab with mod added", 5);

            OkDialog(peptideSettingsUI, peptideSettingsUI.OkDialog);

            // Inserting a peptide sequence p. 5
            using (new CheckDocumentState(1, 1, 2, 10))
            {
                RunUI(() => SetClipboardText("IEAIPQIDK\tGST-tag"));
                var pasteDlg = ShowDialog <PasteDlg>(SkylineWindow.ShowPastePeptidesDlg);
                RunUI(pasteDlg.PastePeptides);
                WaitForProteinMetadataBackgroundLoaderCompletedUI();
                PauseForScreenShot <PasteDlg.PeptideListTab>("Insert Peptide List", 6);

                OkDialog(pasteDlg, pasteDlg.OkDialog);
            }

            RunUI(SkylineWindow.ExpandPrecursors);
            RunUI(() => SkylineWindow.SaveDocument(TestFilesDir.GetTestPath(folderAbsoluteQuant + @"test_file.sky")));
            WaitForCondition(() => File.Exists(TestFilesDir.GetTestPath(folderAbsoluteQuant + @"test_file.sky")));
            PauseForScreenShot("Main window with Targets view", 6);

            // Exporting a transition list p. 6
            {
                var exportMethodDlg = ShowDialog <ExportMethodDlg>(() => SkylineWindow.ShowExportMethodDialog(ExportFileType.List));
                RunUI(() =>
                {
                    exportMethodDlg.InstrumentType = ExportInstrumentType.THERMO;
                    exportMethodDlg.ExportStrategy = ExportStrategy.Single;
                    exportMethodDlg.OptimizeType   = ExportOptimize.NONE;
                    exportMethodDlg.MethodType     = ExportMethodType.Standard;
                });
                PauseForScreenShot <ExportMethodDlg.TransitionListView>("Export Transition List", 7);

                OkDialog(exportMethodDlg, () =>
                         exportMethodDlg.OkDialog(TestFilesDir.GetTestPath("Quant_Abs_Thermo_TSQ_Vantage.csv")));
            }

            // Importing RAW files into Skyline p. 7
            var importResultsDlg = ShowDialog <ImportResultsDlg>(SkylineWindow.ImportResults);

            PauseForScreenShot <ImportResultsDlg>("Import Results - click OK to get shot of Import Results Files and then cancel", 8);

            RunUI(() =>
            {
                var rawFiles      = DataSourceUtil.GetDataSources(TestFilesDirs[0].FullPath).First().Value.Skip(1);
                var namedPathSets = from rawFile in rawFiles
                                    select new KeyValuePair <string, MsDataFileUri[]>(
                    rawFile.GetFileNameWithoutExtension(), new[] { rawFile });
                importResultsDlg.NamedPathSets = namedPathSets.ToArray();
            });
            RunDlg <ImportResultsNameDlg>(importResultsDlg.OkDialog,
                                          importResultsNameDlg => importResultsNameDlg.NoDialog());

            WaitForGraphs();

            RunUI(() =>
            {
                SkylineWindow.SelectedPath             = SkylineWindow.Document.GetPathTo((int)SrmDocument.Level.Molecules, 0);
                Settings.Default.ArrangeGraphsOrder    = GroupGraphsOrder.Document.ToString();
                Settings.Default.ArrangeGraphsReversed = false;
                SkylineWindow.ArrangeGraphsTiled();
                SkylineWindow.AutoZoomBestPeak();
            });
            WaitForCondition(() => Equals(8, SkylineWindow.GraphChromatograms.Count(graphChrom => !graphChrom.IsHidden)),
                             "unexpected visible graphChromatogram count");

            WaitForCondition(10 * 60 * 1000,    // ten minutes
                             () => SkylineWindow.Document.Settings.HasResults && SkylineWindow.Document.Settings.MeasuredResults.IsLoaded);
            PauseForScreenShot("Main window with imported data", 9);

            // Analyzing SRM Data from FOXN1-GST Sample p. 9
            RunDlg <ImportResultsDlg>(SkylineWindow.ImportResults,
                                      importResultsDlg1 =>
            {
                var rawFiles      = DataSourceUtil.GetDataSources(TestFilesDirs[0].FullPath).First().Value.Take(1);
                var namedPathSets = from rawFile in rawFiles
                                    select new KeyValuePair <string, MsDataFileUri[]>(
                    rawFile.GetFileNameWithoutExtension(), new[] { rawFile });
                importResultsDlg1.NamedPathSets = namedPathSets.ToArray();
                importResultsDlg1.OkDialog();
            });
            WaitForGraphs();
            CheckReportCompatibility.CheckAll(SkylineWindow.Document);
            WaitForCondition(5 * 60 * 1000, // five minutes
                             () =>
                             SkylineWindow.Document.Settings.HasResults &&
                             SkylineWindow.Document.Settings.MeasuredResults.IsLoaded);

            RunUI(() =>
            {
                SkylineWindow.ToggleIntegrateAll();
                SkylineWindow.ArrangeGraphsTabbed();
                SkylineWindow.ShowRTReplicateGraph();
                SkylineWindow.ShowPeakAreaReplicateComparison();
                // Total normalization
                SkylineWindow.NormalizeAreaGraphTo(AreaNormalizeToView.area_percent_view);
            });

            RunUI(() => SkylineWindow.ActivateReplicate("FOXN1-GST"));
            WaitForGraphs();
            RunUI(() => SkylineWindow.SelectedPath = SkylineWindow.DocumentUI.GetPathTo((int)SrmDocument.Level.TransitionGroups, 0));
            WaitForGraphs();
            RunUI(() =>
            {
                Assert.AreEqual(SkylineWindow.SelectedResultsIndex, SkylineWindow.GraphPeakArea.ResultsIndex);
                Assert.AreEqual(SkylineWindow.SelectedResultsIndex, SkylineWindow.GraphRetentionTime.ResultsIndex);
            });

            RunUI(() =>
            {
                int transitionCount = SkylineWindow.DocumentUI.PeptideTransitionGroups.First().TransitionCount;
                CheckGstGraphs(transitionCount, transitionCount);
            });
            PauseForScreenShot("Main window with Peak Areas, Retention Times and FOXN1-GST for light", 10);

            RunUI(() => SkylineWindow.SelectedPath = SkylineWindow.DocumentUI.GetPathTo((int)SrmDocument.Level.TransitionGroups, 1));
            WaitForGraphs();

            RunUI(() =>
            {
                int transitionCount = SkylineWindow.DocumentUI.PeptideTransitionGroups.ToArray()[1].TransitionCount;
                CheckGstGraphs(transitionCount, transitionCount);
            });
            PauseForScreenShot("Main window with Peak Areas, Retention Times and FOXN1-GST for heavy", 10);

            RunUI(() => SkylineWindow.SelectedPath = SkylineWindow.DocumentUI.GetPathTo((int)SrmDocument.Level.Molecules, 0));
            WaitForGraphs();
            // Heavy normalization
            RunUI(() => SkylineWindow.NormalizeAreaGraphTo(AreaNormalizeToView.area_ratio_view));
            WaitForGraphs();

            RunUI(() =>
            {
                int transitionGroupCount = SkylineWindow.DocumentUI.Peptides.First().TransitionGroupCount;
                CheckGstGraphs(transitionGroupCount, transitionGroupCount - 1);
            });
            PauseForScreenShot("Main window with totals graphs for light and heavy and FOXN1-GST", 11);
            const int columnsToAddCount = 4;
            var       columnSeparator   = TextUtil.CsvSeparator;
            // Generating a Calibration Curve p. 11
            var          exportLiveReportDlg = ShowDialog <ExportLiveReportDlg>(SkylineWindow.ShowExportReportDialog);
            var          editReportListDlg   = ShowDialog <ManageViewsForm>(exportLiveReportDlg.EditList);
            const string reportName          = "Peptide Ratio Results Test";
            var          columnsToAdd        = new[]
            {
                PropertyPath.Parse("Proteins!*.Peptides!*.Sequence"),
                PropertyPath.Parse("Proteins!*.Name"),
                PropertyPath.Parse("Replicates!*.Name"),
                PropertyPath.Parse("Proteins!*.Peptides!*.Results!*.Value.RatioToStandard"),
            };

            Assert.AreEqual(columnsToAddCount, columnsToAdd.Length);
            {
                var viewEditor = ShowDialog <ViewEditor>(editReportListDlg.AddView);
                RunUI(() =>
                {
                    viewEditor.ViewName = reportName;
                    foreach (var id in columnsToAdd)
                    {
                        Assert.IsTrue(viewEditor.ChooseColumnsTab.TrySelect(id), "Unable to select {0}", id);
                        viewEditor.ChooseColumnsTab.AddSelectedColumn();
                    }
                    Assert.AreEqual(columnsToAdd.Length, viewEditor.ChooseColumnsTab.ColumnCount);
                });
                // TODO: MultiViewProvider not yet supported in Common
                PauseForScreenShot <ViewEditor>("Edit Report form", 12);

                OkDialog(viewEditor, viewEditor.OkDialog);
            }

            RunUI(editReportListDlg.OkDialog);
            WaitForClosedForm(editReportListDlg);
            RunUI(() =>
            {
                exportLiveReportDlg.ReportName = reportName;
                exportLiveReportDlg.OkDialog(TestFilesDir.GetTestPath("Calibration.csv"), columnSeparator);
            });

            // Check if export file is correct.
            string filePath = TestFilesDir.GetTestPath("Calibration.csv");

            Assert.IsTrue(File.Exists(filePath));
            string[] lines = File.ReadAllLines(filePath);
            string[] line0 = lines[0].Split(columnSeparator);
            int      count = line0.Length;

            Assert.IsTrue(lines.Count() == SkylineWindow.Document.Settings.MeasuredResults.Chromatograms.Count + 1);
            Assert.AreEqual(columnsToAddCount, count);

            // Check export file data
            double ratio1 = Double.Parse(lines[1].Split(new[] { columnSeparator }, 4)[3]);
            double ratio2 = Double.Parse(lines[2].Split(new[] { columnSeparator }, 4)[3]);
            double ratio3 = Double.Parse(lines[3].Split(new[] { columnSeparator }, 4)[3]);
            double ratio4 = Double.Parse(lines[4].Split(new[] { columnSeparator }, 4)[3]);
            double ratio5 = Double.Parse(lines[5].Split(new[] { columnSeparator }, 4)[3]);
            double ratio6 = Double.Parse(lines[6].Split(new[] { columnSeparator }, 4)[3]);
            double ratio7 = Double.Parse(lines[7].Split(new[] { columnSeparator }, 4)[3]);
            double ratio8 = Double.Parse(lines[8].Split(new[] { columnSeparator }, 4)[3]);
            double ratio9 = Double.Parse(lines[9].Split(new[] { columnSeparator }, 4)[3]);

            Assert.AreEqual(21.4513, ratio1, 0.1);
            Assert.AreEqual(6.2568, ratio2, 0.1);
            Assert.AreEqual(2.0417, ratio3, 0.1);
            Assert.AreEqual(0.8244, ratio4, 0.1);
            Assert.AreEqual(0.2809, ratio5, 0.1);
            Assert.AreEqual(0.1156, ratio6, 0.1);
            Assert.AreEqual(0.0819, ratio7, 0.1);
            Assert.AreEqual(0.0248, ratio8, 0.1);
            Assert.AreEqual(0.7079, ratio9, 0.1);
            CheckReportCompatibility.CheckAll(SkylineWindow.Document);
        }
Ejemplo n.º 14
0
        protected override void DoTest()
        {
            var testFilesDir = TestFilesDir;

            var    skyFile    = "test_b.sky";
            var    basename   = "289_97";
            var    sourceData = TestFilesDir.GetTestPath(basename + ExtensionTestContext.ExtMzml);
            string docPath;
            var    doc = InitHighReplicateCountDocument(testFilesDir, skyFile, out docPath);

            Settings.Default.ImportResultsSimultaneousFiles =
                (int)MultiFileLoader.ImportResultsSimultaneousFileOptions
                .many;     // use maximum threads for multiple file import

            var listChromatograms = new List <ChromatogramSet>();
            var filenames         = new List <string>();
            var TOO_MANY_FILES    = Skyline.SkylineWindow.MAX_GRAPH_CHROM * 2;
            int count;

            for (count = 0; count < TOO_MANY_FILES; count++)
            {
                var fname = TestFilesDir.GetTestPath(GetReplicateNameFromIndex(count));
                filenames.Add(fname);
                if (count != Skyline.SkylineWindow.MAX_GRAPH_CHROM)
                {
                    File.Copy(sourceData, fname);
                }
                var path = MsDataFileUri.Parse(fname);
                listChromatograms.Add(AssertResult.FindChromatogramSet(doc, path) ??
                                      new ChromatogramSet(path.GetFileName().Replace('.', '_'), new[] { path }));
            }

            var docResults = doc.ChangeMeasuredResults(new MeasuredResults(listChromatograms));

            Assert.IsTrue(SkylineWindow.SetDocument(docResults, doc));
            var document = WaitForDocumentLoaded();

            float tolerance = (float)document.Settings.TransitionSettings.Instrument.MzMatchTolerance;

            foreach (var pair in document.MoleculePrecursorPairs)
            {
                for (var f = 0; f < filenames.Count; f++)
                {
                    ChromatogramGroupInfo[] chromGroupInfo;
                    Assert.IsTrue(document.Settings.MeasuredResults.TryLoadChromatogram(f, pair.NodePep, pair.NodeGroup,
                                                                                        tolerance,
                                                                                        true, out chromGroupInfo));
                }
            }

            WaitForClosedAllChromatogramsGraph();

            // We expect 0th display to be R0, then as we move on to high undisplayed chromatograms we expect r0 to be replaced with R100, R1 with R101 etc
            var graphChromatograms = SkylineWindow.GraphChromatograms.ToList();

            Assert.IsTrue(graphChromatograms.Any(g => g.NameSet.Equals("R0_mzML")));
            var oldest = graphChromatograms[0].NameSet;
            var newest = "distinct_mzML"; // This replicate should have a different peak

            Assert.IsFalse(graphChromatograms.Any(g => g.NameSet.Equals(newest)));
            // Now select a graph not currently displayed
            RunUI(() => SkylineWindow.SelectedResultsIndex = Skyline.SkylineWindow.MAX_GRAPH_CHROM);
            WaitForGraphs();
            graphChromatograms = SkylineWindow.GraphChromatograms.ToList();
            Assert.IsFalse(graphChromatograms.Any(g => g.NameSet.Equals(oldest)));
            Assert.IsTrue(graphChromatograms.Any(g => g.NameSet.Equals(newest)));
            RunUI(() => SkylineWindow.ArrangeGraphsTiled()); // Arrange so that all are fully visible, so we can use .Visible in test below

            // Now close all, then open them back up again with ctrl-up/ctrl-down hotkeys, and verify that we see the ones we expect
            RunUI(() => SkylineWindow.CloseAllChromatograms());
            WaitForClosedAllChromatogramsGraph();
            // Now run through the replicates
            for (count = 0; count < TOO_MANY_FILES; count++)
            {
                RunUI(() => SkylineWindow.SelectedResultsIndex = count);
                var name = GetReplicateNameFromIndex(count).Replace(@".", @"_");
                WaitForConditionUI(() => SkylineWindow.GraphChromatograms.Any(g => g.NameSet.Equals(name) && g.Visible));
                graphChromatograms = SkylineWindow.GraphChromatograms.ToList();
                for (var index = 0; index < TOO_MANY_FILES; index++)
                {
                    name = GetReplicateNameFromIndex(index).Replace(@".", @"_");
                    var visible         = graphChromatograms.Any(g => g.NameSet.Equals(name) && g.Visible);
                    var shouldBeVisible = (index > count - Skyline.SkylineWindow.MAX_GRAPH_CHROM) && (index <= count);
                    Assert.IsTrue(visible == shouldBeVisible);
                    if (shouldBeVisible)
                    {
                        // Make sure it's showing the right data
                        Assert.IsTrue(graphChromatograms.First(g => g.NameSet.Equals(name)).FilePath.ToString().Contains(GetReplicateNameFromIndex(index)));
                    }
                }
            }
        }