private bool ExtractScanInfoWork(
XRawFileIO xcaliburAccessor,
clsScanList scanList,
clsSpectraCache spectraCache,
clsDataOutput dataOutputHandler,
clsSICOptions sicOptions,
ThermoRawFileReader.clsScanInfo thermoScanInfo)
{
if (thermoScanInfo.ParentIonMZ > 0 && Math.Abs(mOptions.ParentIonDecoyMassDa) > 0)
{
thermoScanInfo.ParentIonMZ += mOptions.ParentIonDecoyMassDa;
}
bool success;
// Determine if this was an MS/MS scan
// If yes, determine the scan number of the survey scan
if (thermoScanInfo.MSLevel <= 1)
{
// Survey Scan
success = ExtractXcaliburSurveyScan(xcaliburAccessor, scanList, spectraCache, dataOutputHandler,
sicOptions, thermoScanInfo);
}
else
{
// Fragmentation Scan
success = ExtractXcaliburFragmentationScan(xcaliburAccessor, scanList, spectraCache, dataOutputHandler,
sicOptions, mOptions.BinningOptions, thermoScanInfo);
}
return(success);
}
private bool ExtractScanInfoCheckRange(
XRawFileIO xcaliburAccessor,
ThermoRawFileReader.clsScanInfo thermoScanInfo,
clsScanList scanList,
clsSpectraCache spectraCache,
clsDataOutput dataOutputHandler,
double percentComplete)
{
bool success;
if (mScanTracking.CheckScanInRange(thermoScanInfo.ScanNumber, thermoScanInfo.RetentionTime, mOptions.SICOptions))
{
success = ExtractScanInfoWork(xcaliburAccessor, scanList, spectraCache, dataOutputHandler,
mOptions.SICOptions, thermoScanInfo);
}
else
{
mScansOutOfRange += 1;
success = true;
}
UpdateProgress((short)Math.Round(percentComplete, 0));
UpdateCacheStats(spectraCache);
if (mOptions.AbortProcessing)
{
scanList.ProcessingIncomplete = true;
return(false);
}
if (DateTime.UtcNow.Subtract(mLastLogTime).TotalSeconds >= 10 ||
thermoScanInfo.ScanNumber % 500 == 0 && (
thermoScanInfo.ScanNumber >= mOptions.SICOptions.ScanRangeStart &&
thermoScanInfo.ScanNumber <= mOptions.SICOptions.ScanRangeEnd))
{
ReportMessage("Reading scan: " + thermoScanInfo.ScanNumber.ToString());
Console.Write(".");
mLastLogTime = DateTime.UtcNow;
}
return(success);
}
public void TestScanInfoCopyFromStruct(string rawFileName, int scanStart, int scanEnd)
{
var dataFile = GetRawDataFile(rawFileName);
using (var reader = new XRawFileIO(dataFile.FullName))
{
Console.WriteLine("Checking clsScanInfo initializing from a struct using {0}", dataFile.Name);
for (var scanNumber = scanStart; scanNumber <= scanEnd; scanNumber++)
{
clsScanInfo scanInfo;
var success = reader.GetScanInfo(scanNumber, out scanInfo);
Assert.IsTrue(success, "GetScanInfo returned false for scan {0}", scanNumber);
#pragma warning disable 618
var udtScanHeaderInfo = new udtScanHeaderInfoType
{
MSLevel = scanInfo.MSLevel,
EventNumber = scanInfo.EventNumber,
SIMScan = scanInfo.SIMScan,
MRMScanType = scanInfo.MRMScanType,
ZoomScan = scanInfo.ZoomScan,
NumPeaks = scanInfo.NumPeaks,
RetentionTime = scanInfo.RetentionTime,
LowMass = scanInfo.LowMass,
HighMass = scanInfo.HighMass,
TotalIonCurrent = scanInfo.TotalIonCurrent,
BasePeakMZ = scanInfo.BasePeakMZ,
BasePeakIntensity = scanInfo.BasePeakIntensity,
FilterText = scanInfo.FilterText,
ParentIonMZ = scanInfo.ParentIonMZ,
ActivationType = scanInfo.ActivationType,
CollisionMode = scanInfo.CollisionMode,
IonMode = scanInfo.IonMode,
MRMInfo = scanInfo.MRMInfo,
NumChannels = scanInfo.NumChannels,
UniformTime = scanInfo.UniformTime,
Frequency = scanInfo.Frequency,
IsCentroidScan = scanInfo.IsCentroided,
ScanEventNames = new string[scanInfo.ScanEvents.Count],
ScanEventValues = new string[scanInfo.ScanEvents.Count],
StatusLogNames = new string[scanInfo.StatusLog.Count],
StatusLogValues = new string[scanInfo.StatusLog.Count]
};
#pragma warning restore 618
var targetIndex = 0;
foreach (var scanEvent in scanInfo.ScanEvents)
{
udtScanHeaderInfo.ScanEventNames[targetIndex] = scanEvent.Key;
udtScanHeaderInfo.ScanEventValues[targetIndex] = scanEvent.Value;
targetIndex++;
}
targetIndex = 0;
foreach (var scanEvent in scanInfo.StatusLog)
{
udtScanHeaderInfo.StatusLogNames[targetIndex] = scanEvent.Key;
udtScanHeaderInfo.StatusLogValues[targetIndex] = scanEvent.Value;
targetIndex++;
}
#pragma warning disable 618
var scanInfoFromStruct = new clsScanInfo(scanInfo.ScanNumber, udtScanHeaderInfo);
#pragma warning restore 618
Assert.AreEqual(scanInfoFromStruct.MSLevel, scanInfo.MSLevel);
Assert.AreEqual(scanInfoFromStruct.IsCentroided, scanInfo.IsCentroided);
Assert.AreEqual(scanInfoFromStruct.FilterText, scanInfo.FilterText);
Assert.AreEqual(scanInfoFromStruct.BasePeakIntensity, scanInfo.BasePeakIntensity, 0.0001);
Assert.AreEqual(scanInfoFromStruct.TotalIonCurrent, scanInfo.TotalIonCurrent, 0.0001);
}
}
}
private udtScanHeaderInfoType ScanInfoClassToStruct(clsScanInfo scanInfo)
{
var udtScanInfo = new udtScanHeaderInfoType
{
MSLevel = scanInfo.MSLevel,
EventNumber = scanInfo.EventNumber,
SIMScan = scanInfo.SIMScan,
MRMScanType = scanInfo.MRMScanType,
ZoomScan = scanInfo.ZoomScan,
NumPeaks = scanInfo.NumPeaks,
RetentionTime = scanInfo.RetentionTime,
LowMass = scanInfo.LowMass,
HighMass = scanInfo.HighMass,
TotalIonCurrent = scanInfo.TotalIonCurrent,
BasePeakMZ = scanInfo.BasePeakMZ,
BasePeakIntensity = scanInfo.BasePeakIntensity,
FilterText = scanInfo.FilterText,
ParentIonMZ = scanInfo.ParentIonMZ,
ActivationType = scanInfo.ActivationType,
CollisionMode = scanInfo.CollisionMode,
IonMode = scanInfo.IonMode,
MRMInfo = scanInfo.MRMInfo,
NumChannels = scanInfo.NumChannels,
UniformTime = scanInfo.UniformTime,
Frequency = scanInfo.Frequency,
IsCentroidScan = scanInfo.IsCentroided,
ScanEventNames = new string[scanInfo.ScanEvents.Count],
ScanEventValues = new string[scanInfo.ScanEvents.Count]
};
for (var i = 0; i < scanInfo.ScanEvents.Count; i++)
{
udtScanInfo.ScanEventNames[i] = scanInfo.ScanEvents[i].Key;
udtScanInfo.ScanEventValues[i] = scanInfo.ScanEvents[i].Value;
}
udtScanInfo.StatusLogNames = new string[scanInfo.StatusLog.Count];
udtScanInfo.StatusLogValues = new string[scanInfo.StatusLog.Count];
for (var i = 0; i < scanInfo.StatusLog.Count; i++)
{
udtScanInfo.StatusLogNames[i] = scanInfo.StatusLog[i].Key;
udtScanInfo.StatusLogValues[i] = scanInfo.StatusLog[i].Value;
}
return udtScanInfo;
}
private void CacheScanInfo(int scan, clsScanInfo scanInfo)
{
if (mCachedScanInfo.Count > MAX_SCANS_TO_CACHE_INFO)
{
// Remove the oldest entry in mCachedScanInfo
var minimumScanNumber = -1;
var dtMinimumCacheDate = DateTime.UtcNow;
foreach (var cachedInfo in mCachedScanInfo.Values)
{
if (minimumScanNumber < 0 || cachedInfo.CacheDateUTC < dtMinimumCacheDate)
{
minimumScanNumber = cachedInfo.ScanNumber;
dtMinimumCacheDate = cachedInfo.CacheDateUTC;
}
}
if (mCachedScanInfo.ContainsKey(minimumScanNumber))
{
mCachedScanInfo.Remove(minimumScanNumber);
}
}
if (mCachedScanInfo.ContainsKey(scan))
{
mCachedScanInfo.Remove(scan);
}
mCachedScanInfo.Add(scan, scanInfo);
}
public bool GetScanInfo(int scan, out clsScanInfo scanInfo)
{
// Check for the scan in the cache
if (mCachedScanInfo.TryGetValue(scan, out scanInfo))
{
return true;
}
if (scan < mFileInfo.ScanStart)
{
scan = mFileInfo.ScanStart;
}
else if (scan > mFileInfo.ScanEnd)
{
scan = mFileInfo.ScanEnd;
}
scanInfo = new clsScanInfo(scan);
try
{
if (mXRawFile == null)
return false;
// Make sure the MS controller is selected
if (!SetMSController())
return false;
// Initialize the values that will be populated using GetScanHeaderInfoForScanNum()
scanInfo.NumPeaks = 0;
scanInfo.TotalIonCurrent = 0;
scanInfo.SIMScan = false;
scanInfo.MRMScanType = MRMScanTypeConstants.NotMRM;
scanInfo.ZoomScan = false;
scanInfo.CollisionMode = string.Empty;
scanInfo.FilterText = string.Empty;
scanInfo.IonMode = IonModeConstants.Unknown;
var numPeaks = 0;
double retentionTime = 0;
double lowMass = 0;
double highMass = 0;
double totalIonCurrent = 0;
double basePeakMZ = 0;
double basePeakIntensity = 0;
var numChannels = 0;
double frequency = 0;
var booleanValue = 0;
var errorCode = 0;
mXRawFile.GetScanHeaderInfoForScanNum(
scan, ref numPeaks, ref retentionTime, ref lowMass, ref highMass,
ref totalIonCurrent, ref basePeakMZ, ref basePeakIntensity, ref numChannels, booleanValue, ref frequency);
scanInfo.NumPeaks = numPeaks;
scanInfo.RetentionTime = retentionTime;
scanInfo.LowMass = lowMass;
scanInfo.HighMass = highMass;
scanInfo.TotalIonCurrent = totalIonCurrent;
scanInfo.BasePeakMZ = basePeakMZ;
scanInfo.BasePeakIntensity = basePeakIntensity;
scanInfo.NumChannels = numChannels;
scanInfo.Frequency = frequency;
mXRawFile.IsError(ref errorCode);
// Unfortunately, .IsError() always returns 0, even if an error occurred
if (errorCode != 0)
{
CacheScanInfo(scan, scanInfo);
return false;
}
scanInfo.UniformTime = Convert.ToBoolean(booleanValue);
booleanValue = 0;
mXRawFile.IsCentroidScanForScanNum(scan, ref booleanValue);
scanInfo.IsCentroided = Convert.ToBoolean(booleanValue);
var arrayCount = 0;
object objLabels = null;
object objValues = null;
try
{
if (!mCorruptMemoryEncountered)
{
// Retrieve the additional parameters for this scan (including Scan Event)
mXRawFile.GetTrailerExtraForScanNum(scan, ref objLabels, ref objValues, ref arrayCount);
}
}
catch (AccessViolationException ex)
{
var msg = "Warning: Exception calling mXRawFile.GetTrailerExtraForScanNum for scan " + scan + ": " + ex.Message;
RaiseWarningMessage(msg);
arrayCount = 0;
}
catch (Exception ex)
{
var msg = "Warning: Exception calling mXRawFile.GetTrailerExtraForScanNum for scan " + scan + ": " + ex.Message;
RaiseWarningMessage(msg);
arrayCount = 0;
if (ex.Message.ToLower().Contains("memory is corrupt"))
{
mCorruptMemoryEncountered = true;
}
}
scanInfo.EventNumber = 1;
if (arrayCount > 0 && objLabels != null && objValues != null)
{
var scanEventNames =
((IEnumerable)objLabels).Cast<object>()
.Select(x => x.ToString())
.ToArray();
var scanEventValues =
((IEnumerable)objValues).Cast<object>()
.Select(x => x.ToString())
.ToArray();
scanInfo.StoreScanEvents(scanEventNames, scanEventValues);
// Look for the entry in strLabels named "Scan Event:"
// Entries for the LCQ are:
// Wideband Activation
// Micro Scan Count
// Ion Injection Time (ms)
// Scan Segment
// Scan Event
// Elapsed Scan Time (sec)
// API Source CID Energy
// Resolution
// Average Scan by Inst
// BackGd Subtracted by Inst
// Charge State
foreach (var scanEvent in from item in scanInfo.ScanEvents where item.Key.ToLower().StartsWith("scan event") select item)
{
try
{
scanInfo.EventNumber = Convert.ToInt32(scanEvent.Value);
}
catch (Exception)
{
// Ignore errors here
}
break;
}
}
// Lookup the filter text for this scan
// Parse out the parent ion m/z for fragmentation scans
// Must set filterText to Nothing prior to calling .GetFilterForScanNum()
string filterText = null;
mXRawFile.GetFilterForScanNum(scan, ref filterText);
scanInfo.FilterText = string.Copy(filterText);
scanInfo.IsFTMS = ScanIsFTMS(filterText);
if (string.IsNullOrWhiteSpace(scanInfo.FilterText))
scanInfo.FilterText = string.Empty;
if (scanInfo.EventNumber <= 1)
{
int msLevel;
// XRaw periodically mislabels a scan as .EventNumber = 1 when it's really an MS/MS scan; check for this
string mzText;
if (ExtractMSLevel(scanInfo.FilterText, out msLevel, out mzText))
{
scanInfo.EventNumber = msLevel;
}
}
if (scanInfo.EventNumber > 1)
{
// MS/MS data
scanInfo.MSLevel = 2;
if (string.IsNullOrWhiteSpace(scanInfo.FilterText))
{
// FilterText is empty; this indicates a problem with the .Raw file
// This is rare, but does happen (see scans 2 and 3 in QC_Shew_08_03_pt5_1_MAXPRO_27Oct08_Raptor_08-01-01.raw)
// We'll set the Parent Ion to 0 m/z and the collision mode to CID
scanInfo.ParentIonMZ = 0;
scanInfo.CollisionMode = "cid";
if (scanInfo.ActivationType == ActivationTypeConstants.Unknown)
{
scanInfo.ActivationType = ActivationTypeConstants.CID;
}
scanInfo.MRMScanType = MRMScanTypeConstants.NotMRM;
}
else
{
double parentIonMz;
int msLevel;
string collisionMode;
// Parse out the parent ion and collision energy from .FilterText
if (ExtractParentIonMZFromFilterText(scanInfo.FilterText, out parentIonMz, out msLevel, out collisionMode))
{
scanInfo.ParentIonMZ = parentIonMz;
scanInfo.CollisionMode = collisionMode;
if (msLevel > 2)
{
scanInfo.MSLevel = msLevel;
}
// Check whether this is an SRM MS2 scan
scanInfo.MRMScanType = DetermineMRMScanType(scanInfo.FilterText);
}
else
{
// Could not find "Full ms2" in .FilterText
// XRaw periodically mislabels a scan as .EventNumber > 1 when it's really an MS scan; check for this
bool simScan;
MRMScanTypeConstants eMRMScanType;
bool zoomScan;
if (ValidateMSScan(scanInfo.FilterText, out msLevel, out simScan, out eMRMScanType, out zoomScan))
{
// Yes, scan is an MS, SIM, or MRMQMS, or SRM scan
scanInfo.MSLevel = msLevel;
scanInfo.SIMScan = simScan;
scanInfo.MRMScanType = eMRMScanType;
scanInfo.ZoomScan = zoomScan;
}
else
{
// Unknown format for .FilterText; return an error
RaiseErrorMessage("Unknown format for Scan Filter: " + scanInfo.FilterText);
return false;
}
}
}
}
else
{
// MS1 data
// Make sure .FilterText contains one of the known MS1, SIM or MRM tags
if (scanInfo.FilterText == string.Empty)
{
// FilterText is empty; this indicates a problem with the .Raw file
// This is rare, but does happen (see scans 2 and 3 in QC_Shew_08_03_pt5_1_MAXPRO_27Oct08_Raptor_08-01-01.raw)
scanInfo.MSLevel = 1;
scanInfo.SIMScan = false;
scanInfo.MRMScanType = MRMScanTypeConstants.NotMRM;
}
else
{
int msLevel;
bool simScan;
MRMScanTypeConstants eMRMScanType;
bool zoomScan;
if (ValidateMSScan(scanInfo.FilterText, out msLevel, out simScan, out eMRMScanType, out zoomScan))
{
// Yes, scan is an MS, SIM, or MRMQMS, or SRM scan
scanInfo.MSLevel = msLevel;
scanInfo.SIMScan = simScan;
scanInfo.MRMScanType = eMRMScanType;
scanInfo.ZoomScan = zoomScan;
}
else
{
// Unknown format for .FilterText; return an error
RaiseErrorMessage("Unknown format for Scan Filter: " + scanInfo.FilterText);
return false;
}
}
}
scanInfo.IonMode = DetermineIonizationMode(scanInfo.FilterText);
// Now that we know MSLevel we can lookup the activation type (aka activation method)
scanInfo.ActivationType = GetActivationType(scan, scanInfo.MSLevel);
MRMInfo newMRMInfo;
if (scanInfo.MRMScanType != MRMScanTypeConstants.NotMRM)
{
// Parse out the MRM_QMS or SRM information for this scan
ExtractMRMMasses(scanInfo.FilterText, scanInfo.MRMScanType, out newMRMInfo);
}
else
{
newMRMInfo = new MRMInfo();
}
scanInfo.MRMInfo = newMRMInfo;
// Retrieve the Status Log for this scan using the following
// The Status Log includes numerous instrument parameters, including voltages, temperatures, pressures, turbo pump speeds, etc.
arrayCount = 0;
objLabels = null;
objValues = null;
try
{
if (!mCorruptMemoryEncountered)
{
double statusLogRT = 0;
mXRawFile.GetStatusLogForScanNum(scan, statusLogRT, ref objLabels, ref objValues, ref arrayCount);
}
}
catch (AccessViolationException ex)
{
var msg = "Warning: Exception calling mXRawFile.GetStatusLogForScanNum for scan " + scan + ": " + ex.Message;
RaiseWarningMessage(msg);
arrayCount = 0;
}
catch (Exception ex)
{
var msg = "Warning: Exception calling mXRawFile.GetStatusLogForScanNum for scan " + scan + ": " + ex.Message;
RaiseWarningMessage(msg);
arrayCount = 0;
if (ex.Message.ToLower().Contains("memory is corrupt"))
{
mCorruptMemoryEncountered = true;
}
}
if (arrayCount > 0)
{
var logNames =
((IEnumerable)objLabels).Cast<object>()
.Select(x => x.ToString())
.ToArray();
var logValues =
((IEnumerable)objValues).Cast<object>()
.Select(x => x.ToString())
.ToArray();
scanInfo.StoreStatusLog(logNames, logValues);
}
}
catch (Exception ex)
{
var msg = "Error: Exception in GetScanInfo: " + ex.Message;
RaiseWarningMessage(msg);
CacheScanInfo(scan, scanInfo);
return false;
}
CacheScanInfo(scan, scanInfo);
return true;
}
private bool ExtractXcaliburFragmentationScan(
XRawFileIO xcaliburAccessor,
clsScanList scanList,
clsSpectraCache spectraCache,
clsDataOutput dataOutputHandler,
clsSICOptions sicOptions,
clsBinningOptions binningOptions,
ThermoRawFileReader.clsScanInfo thermoScanInfo)
{
// Note that MinimumPositiveIntensity will be determined in LoadSpectraForThermoRawFile
var scanInfo = new clsScanInfo(thermoScanInfo.ParentIonMZ)
{
ScanNumber = thermoScanInfo.ScanNumber,
ScanTime = (float)thermoScanInfo.RetentionTime,
ScanHeaderText = XRawFileIO.MakeGenericThermoScanFilter(thermoScanInfo.FilterText),
ScanTypeName = XRawFileIO.GetScanTypeNameFromThermoScanFilterText(thermoScanInfo.FilterText),
BasePeakIonMZ = thermoScanInfo.BasePeakMZ,
BasePeakIonIntensity = thermoScanInfo.BasePeakIntensity,
TotalIonIntensity = thermoScanInfo.TotalIonCurrent,
MinimumPositiveIntensity = 0,
ZoomScan = thermoScanInfo.ZoomScan,
SIMScan = thermoScanInfo.SIMScan,
MRMScanType = thermoScanInfo.MRMScanType
};
// Typically .EventNumber is 1 for the parent-ion scan; 2 for 1st frag scan, 3 for 2nd frag scan, etc.
// This resets for each new parent-ion scan
scanInfo.FragScanInfo.FragScanNumber = thermoScanInfo.EventNumber - 1;
// The .EventNumber value is sometimes wrong; need to check for this
// For example, if the dataset only has MS2 scans and no parent-ion scan, .EventNumber will be 2 for every MS2 scan
if (scanList.FragScans.Count > 0)
{
var prevFragScan = scanList.FragScans[scanList.FragScans.Count - 1];
if (prevFragScan.ScanNumber == scanInfo.ScanNumber - 1)
{
if (scanInfo.FragScanInfo.FragScanNumber <= prevFragScan.FragScanInfo.FragScanNumber)
{
scanInfo.FragScanInfo.FragScanNumber = prevFragScan.FragScanInfo.FragScanNumber + 1;
}
}
}
scanInfo.FragScanInfo.MSLevel = thermoScanInfo.MSLevel;
if (scanInfo.MRMScanType != MRMScanTypeConstants.NotMRM)
{
// This is an MRM scan
scanList.MRMDataPresent = true;
scanInfo.MRMScanInfo = clsMRMProcessing.DuplicateMRMInfo(thermoScanInfo.MRMInfo, thermoScanInfo.ParentIonMZ);
if (scanList.SurveyScans.Count == 0)
{
// Need to add a "fake" survey scan that we can map this parent ion to
mLastNonZoomSurveyScanIndex = scanList.AddFakeSurveyScan();
}
}
else
{
scanInfo.MRMScanInfo.MRMMassCount = 0;
}
scanInfo.LowMass = thermoScanInfo.LowMass;
scanInfo.HighMass = thermoScanInfo.HighMass;
scanInfo.IsFTMS = thermoScanInfo.IsFTMS;
// Store the ScanEvent values in .ExtendedHeaderInfo
StoreExtendedHeaderInfo(dataOutputHandler, scanInfo, thermoScanInfo.ScanEvents);
// Store the collision mode and possibly the scan filter text
scanInfo.FragScanInfo.CollisionMode = thermoScanInfo.CollisionMode;
StoreExtendedHeaderInfo(dataOutputHandler, scanInfo, clsExtendedStatsWriter.EXTENDED_STATS_HEADER_COLLISION_MODE, thermoScanInfo.CollisionMode);
if (mOptions.WriteExtendedStatsIncludeScanFilterText)
{
StoreExtendedHeaderInfo(dataOutputHandler, scanInfo, clsExtendedStatsWriter.EXTENDED_STATS_HEADER_SCAN_FILTER_TEXT, thermoScanInfo.FilterText);
}
if (mOptions.WriteExtendedStatsStatusLog)
{
// Store the StatusLog values in .ExtendedHeaderInfo
StoreExtendedHeaderInfo(dataOutputHandler, scanInfo, thermoScanInfo.StatusLog, mOptions.StatusLogKeyNameFilterList);
}
scanList.FragScans.Add(scanInfo);
var fragScanIndex = scanList.FragScans.Count - 1;
scanList.AddMasterScanEntry(clsScanList.eScanTypeConstants.FragScan, fragScanIndex);
// Note: Even if keepRawSpectra = False, we still need to load the raw data so that we can compute the noise level for the spectrum
var msDataResolution = binningOptions.BinSize / sicOptions.CompressToleranceDivisorForDa;
var success = LoadSpectraForThermoRawFile(
xcaliburAccessor,
spectraCache,
scanInfo,
sicOptions.SICPeakFinderOptions.MassSpectraNoiseThresholdOptions,
clsMASIC.DISCARD_LOW_INTENSITY_MSMS_DATA_ON_LOAD,
sicOptions.CompressMSMSSpectraData,
msDataResolution,
mKeepRawSpectra && mKeepMSMSSpectra);
if (!success)
{
return(false);
}
SaveScanStatEntry(dataOutputHandler.OutputFileHandles.ScanStats, clsScanList.eScanTypeConstants.FragScan, scanInfo, sicOptions.DatasetID);
if (thermoScanInfo.MRMScanType == MRMScanTypeConstants.NotMRM)
{
// This is not an MRM scan
mParentIonProcessor.AddUpdateParentIons(scanList, mLastNonZoomSurveyScanIndex, thermoScanInfo.ParentIonMZ,
fragScanIndex, spectraCache, sicOptions);
}
else
{
// This is an MRM scan
mParentIonProcessor.AddUpdateParentIons(scanList, mLastNonZoomSurveyScanIndex, thermoScanInfo.ParentIonMZ,
scanInfo.MRMScanInfo, spectraCache, sicOptions);
}
if (mLastNonZoomSurveyScanIndex >= 0)
{
var precursorScanNumber = scanList.SurveyScans[mLastNonZoomSurveyScanIndex].ScanNumber;
// Compute the interference of the parent ion in the MS1 spectrum for this frag scan
scanInfo.FragScanInfo.InterferenceScore = ComputeInterference(xcaliburAccessor, thermoScanInfo, precursorScanNumber);
}
return(true);
}
private double ComputeInterference(
XRawFileIO xcaliburAccessor,
ThermoRawFileReader.clsScanInfo scanInfo,
int precursorScanNumber)
{
if (precursorScanNumber != mCachedPrecursorScan)
{
xcaliburAccessor.GetScanData(precursorScanNumber, out var centroidedIonsMz, out var centroidedIonsIntensity, 0, true);
UpdateCachedPrecursorScan(precursorScanNumber, centroidedIonsMz, centroidedIonsIntensity);
}
var chargeState = 0;
scanInfo.TryGetScanEvent(SCAN_EVENT_CHARGE_STATE, out var chargeStateText, true);
if (!string.IsNullOrWhiteSpace(chargeStateText))
{
if (!int.TryParse(chargeStateText, out chargeState))
{
chargeState = 0;
}
}
if (!scanInfo.TryGetScanEvent(SCAN_EVENT_MS2_ISOLATION_WIDTH, out var isolationWidthText, true))
{
if (scanInfo.MRMScanType == MRMScanTypeConstants.SRM)
{
// SRM data files don't have the MS2 Isolation Width event
return(0);
}
WarnIsolationWidthNotFound(
scanInfo.ScanNumber,
"Could not determine the MS2 isolation width (" + SCAN_EVENT_MS2_ISOLATION_WIDTH + ")");
return(0);
}
if (!double.TryParse(isolationWidthText, out var isolationWidth))
{
ReportWarning("MS2 isolation width (" + SCAN_EVENT_MS2_ISOLATION_WIDTH + ") was non-numeric (" + isolationWidthText + "); " +
"cannot compute interference for scan " + scanInfo.ScanNumber);
return(0);
}
double parentIonMz;
if (Math.Abs(scanInfo.ParentIonMZ) > 0)
{
parentIonMz = scanInfo.ParentIonMZ;
}
else
{
// ThermoRawFileReader could not determine the parent ion m/z value (this is highly unlikely)
// Use scan event "Monoisotopic M/Z" instead
if (!scanInfo.TryGetScanEvent(SCAN_EVENT_MONOISOTOPIC_MZ, out var monoMzText, true))
{
ReportWarning("Could not determine the parent ion m/z value (" + SCAN_EVENT_MONOISOTOPIC_MZ + "); " +
"cannot compute interference for scan " + scanInfo.ScanNumber);
return(0);
}
if (!double.TryParse(monoMzText, out var mz))
{
OnWarningEvent(string.Format("Skipping scan {0} since scan event {1} was not a number: {2}",
scanInfo.ScanNumber, SCAN_EVENT_MONOISOTOPIC_MZ, monoMzText));
return(0);
}
parentIonMz = mz;
}
if (Math.Abs(parentIonMz) < float.Epsilon)
{
ReportWarning("Parent ion m/z is 0; cannot compute interference for scan " + scanInfo.ScanNumber);
return(0);
}
var precursorInterference = ComputePrecursorInterference(
scanInfo.ScanNumber,
precursorScanNumber, parentIonMz, isolationWidth, chargeState);
return(precursorInterference);
}
private bool ExtractXcaliburSurveyScan(
XRawFileIO xcaliburAccessor,
clsScanList scanList,
clsSpectraCache spectraCache,
clsDataOutput dataOutputHandler,
clsSICOptions sicOptions,
ThermoRawFileReader.clsScanInfo thermoScanInfo)
{
var scanInfo = new clsScanInfo()
{
ScanNumber = thermoScanInfo.ScanNumber,
ScanTime = (float)thermoScanInfo.RetentionTime,
ScanHeaderText = XRawFileIO.MakeGenericThermoScanFilter(thermoScanInfo.FilterText),
ScanTypeName = XRawFileIO.GetScanTypeNameFromThermoScanFilterText(thermoScanInfo.FilterText),
BasePeakIonMZ = thermoScanInfo.BasePeakMZ,
BasePeakIonIntensity = thermoScanInfo.BasePeakIntensity,
TotalIonIntensity = thermoScanInfo.TotalIonCurrent,
MinimumPositiveIntensity = 0, // This will be determined in LoadSpectraForThermoRawFile
ZoomScan = thermoScanInfo.ZoomScan,
SIMScan = thermoScanInfo.SIMScan,
MRMScanType = thermoScanInfo.MRMScanType,
LowMass = thermoScanInfo.LowMass,
HighMass = thermoScanInfo.HighMass,
IsFTMS = thermoScanInfo.IsFTMS
};
// Survey scans typically lead to multiple parent ions; we do not record them here
scanInfo.FragScanInfo.ParentIonInfoIndex = -1;
if (scanInfo.MRMScanType != MRMScanTypeConstants.NotMRM)
{
// This is an MRM scan
scanList.MRMDataPresent = true;
}
if (scanInfo.SIMScan)
{
scanList.SIMDataPresent = true;
var simKey = scanInfo.LowMass + "_" + scanInfo.HighMass;
if (mSIMScanMapping.TryGetValue(simKey, out var simIndex))
{
scanInfo.SIMIndex = simIndex;
}
else
{
scanInfo.SIMIndex = mSIMScanMapping.Count;
mSIMScanMapping.Add(simKey, mSIMScanMapping.Count);
}
}
// Store the ScanEvent values in .ExtendedHeaderInfo
StoreExtendedHeaderInfo(dataOutputHandler, scanInfo, thermoScanInfo.ScanEvents);
// Store the collision mode and possibly the scan filter text
scanInfo.FragScanInfo.CollisionMode = thermoScanInfo.CollisionMode;
StoreExtendedHeaderInfo(dataOutputHandler, scanInfo, clsExtendedStatsWriter.EXTENDED_STATS_HEADER_COLLISION_MODE, thermoScanInfo.CollisionMode);
if (mOptions.WriteExtendedStatsIncludeScanFilterText)
{
StoreExtendedHeaderInfo(dataOutputHandler, scanInfo, clsExtendedStatsWriter.EXTENDED_STATS_HEADER_SCAN_FILTER_TEXT, thermoScanInfo.FilterText);
}
if (mOptions.WriteExtendedStatsStatusLog)
{
// Store the StatusLog values in .ExtendedHeaderInfo
StoreExtendedHeaderInfo(dataOutputHandler, scanInfo, thermoScanInfo.StatusLog, mOptions.StatusLogKeyNameFilterList);
}
scanList.SurveyScans.Add(scanInfo);
if (!scanInfo.ZoomScan)
{
mLastNonZoomSurveyScanIndex = scanList.SurveyScans.Count - 1;
}
scanList.AddMasterScanEntry(clsScanList.eScanTypeConstants.SurveyScan, scanList.SurveyScans.Count - 1);
double msDataResolution;
if (sicOptions.SICToleranceIsPPM)
{
// Define MSDataResolution based on the tolerance value that will be used at the lowest m/z in this spectrum, divided by sicOptions.CompressToleranceDivisorForPPM
// However, if the lowest m/z value is < 100, then use 100 m/z
if (thermoScanInfo.LowMass < 100)
{
msDataResolution = clsParentIonProcessing.GetParentIonToleranceDa(sicOptions, 100) /
sicOptions.CompressToleranceDivisorForPPM;
}
else
{
msDataResolution = clsParentIonProcessing.GetParentIonToleranceDa(sicOptions, thermoScanInfo.LowMass) /
sicOptions.CompressToleranceDivisorForPPM;
}
}
else
{
msDataResolution = sicOptions.SICTolerance / sicOptions.CompressToleranceDivisorForDa;
}
// Note: Even if mKeepRawSpectra = False, we still need to load the raw data so that we can compute the noise level for the spectrum
var success = LoadSpectraForThermoRawFile(
xcaliburAccessor,
spectraCache,
scanInfo,
sicOptions.SICPeakFinderOptions.MassSpectraNoiseThresholdOptions,
clsMASIC.DISCARD_LOW_INTENSITY_MS_DATA_ON_LOAD,
sicOptions.CompressMSSpectraData,
msDataResolution,
mKeepRawSpectra);
if (!success)
{
return(false);
}
SaveScanStatEntry(dataOutputHandler.OutputFileHandles.ScanStats, clsScanList.eScanTypeConstants.SurveyScan, scanInfo, sicOptions.DatasetID);
return(true);
}
