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| author | deepakjadmin |
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| date | Wed, 20 Jan 2016 09:23:18 -0500 |
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#!/usr/bin/perl -w # # $RCSfile: TopologicalAtomTorsionsFingerprints.pl,v $ # $Date: 2015/02/28 20:46:22 $ # $Revision: 1.32 $ # # Author: Manish Sud <msud@san.rr.com> # # Copyright (C) 2015 Manish Sud. All rights reserved. # # This file is part of MayaChemTools. # # MayaChemTools is free software; you can redistribute it and/or modify it under # the terms of the GNU Lesser General Public License as published by the Free # Software Foundation; either version 3 of the License, or (at your option) any # later version. # # MayaChemTools is distributed in the hope that it will be useful, but without # any warranty; without even the implied warranty of merchantability of fitness # for a particular purpose. See the GNU Lesser General Public License for more # details. # # You should have received a copy of the GNU Lesser General Public License # along with MayaChemTools; if not, see <http://www.gnu.org/licenses/> or # write to the Free Software Foundation Inc., 59 Temple Place, Suite 330, # Boston, MA, 02111-1307, USA. # use strict; use FindBin; use lib "$FindBin::Bin/../lib"; use Getopt::Long; use File::Basename; use Text::ParseWords; use Benchmark; use FileUtil; use TextUtil; use SDFileUtil; use MoleculeFileIO; use FileIO::FingerprintsSDFileIO; use FileIO::FingerprintsTextFileIO; use FileIO::FingerprintsFPFileIO; use AtomTypes::AtomicInvariantsAtomTypes; use AtomTypes::FunctionalClassAtomTypes; use Fingerprints::TopologicalAtomTorsionsFingerprints; my($ScriptName, %Options, $StartTime, $EndTime, $TotalTime); # Autoflush STDOUT $| = 1; # Starting message... $ScriptName = basename($0); print "\n$ScriptName: Starting...\n\n"; $StartTime = new Benchmark; # Get the options and setup script... SetupScriptUsage(); if ($Options{help} || @ARGV < 1) { die GetUsageFromPod("$FindBin::Bin/$ScriptName"); } my(@SDFilesList); @SDFilesList = ExpandFileNames(\@ARGV, "sdf sd"); # Process options... print "Processing options...\n"; my(%OptionsInfo); ProcessOptions(); # Setup information about input files... print "Checking input SD file(s)...\n"; my(%SDFilesInfo); RetrieveSDFilesInfo(); # Process input files.. my($FileIndex); if (@SDFilesList > 1) { print "\nProcessing SD files...\n"; } for $FileIndex (0 .. $#SDFilesList) { if ($SDFilesInfo{FileOkay}[$FileIndex]) { print "\nProcessing file $SDFilesList[$FileIndex]...\n"; GenerateTopologicalAtomTorsionsFingerprints($FileIndex); } } print "\n$ScriptName:Done...\n\n"; $EndTime = new Benchmark; $TotalTime = timediff ($EndTime, $StartTime); print "Total time: ", timestr($TotalTime), "\n"; ############################################################################### # Generate fingerprints for a SD file... # sub GenerateTopologicalAtomTorsionsFingerprints { my($FileIndex) = @_; my($CmpdCount, $IgnoredCmpdCount, $SDFile, $MoleculeFileIO, $Molecule, $TopologicalAtomTorsionsFingerprints, $NewFPSDFileIO, $NewFPTextFileIO, $NewFPFileIO); $SDFile = $SDFilesList[$FileIndex]; # Setup output files... # ($NewFPSDFileIO, $NewFPTextFileIO, $NewFPFileIO) = SetupAndOpenOutputFiles($FileIndex); $MoleculeFileIO = new MoleculeFileIO('Name' => $SDFile); $MoleculeFileIO->Open(); $CmpdCount = 0; $IgnoredCmpdCount = 0; COMPOUND: while ($Molecule = $MoleculeFileIO->ReadMolecule()) { $CmpdCount++; # Filter compound data before calculating fingerprints... if ($OptionsInfo{Filter}) { if (CheckAndFilterCompound($CmpdCount, $Molecule)) { $IgnoredCmpdCount++; next COMPOUND; } } $TopologicalAtomTorsionsFingerprints = GenerateMoleculeFingerprints($Molecule); if (!$TopologicalAtomTorsionsFingerprints) { $IgnoredCmpdCount++; ProcessIgnoredCompound('FingerprintsGenerationFailed', $CmpdCount, $Molecule); next COMPOUND; } WriteDataToOutputFiles($FileIndex, $CmpdCount, $Molecule, $TopologicalAtomTorsionsFingerprints, $NewFPSDFileIO, $NewFPTextFileIO, $NewFPFileIO); } $MoleculeFileIO->Close(); if ($NewFPSDFileIO) { $NewFPSDFileIO->Close(); } if ($NewFPTextFileIO) { $NewFPTextFileIO->Close(); } if ($NewFPFileIO) { $NewFPFileIO->Close(); } WriteFingerprintsGenerationSummaryStatistics($CmpdCount, $IgnoredCmpdCount); } # Process compound being ignored due to problems in fingerprints geneation... # sub ProcessIgnoredCompound { my($Mode, $CmpdCount, $Molecule) = @_; my($CmpdID, $DataFieldLabelAndValuesRef); $DataFieldLabelAndValuesRef = $Molecule->GetDataFieldLabelAndValues(); $CmpdID = SetupCmpdIDForOutputFiles($CmpdCount, $Molecule, $DataFieldLabelAndValuesRef); MODE: { if ($Mode =~ /^ContainsNonElementalData$/i) { warn "\nWarning: Ignoring compound record number $CmpdCount with ID $CmpdID: Compound contains atom data corresponding to non-elemental atom symbol(s)...\n\n"; next MODE; } if ($Mode =~ /^ContainsNoElementalData$/i) { warn "\nWarning: Ignoring compound record number $CmpdCount with ID $CmpdID: Compound contains no atom data...\n\n"; next MODE; } if ($Mode =~ /^FingerprintsGenerationFailed$/i) { warn "\nWarning: Ignoring compound record number $CmpdCount with ID $CmpdID: Fingerprints generation didn't succeed...\n\n"; next MODE; } warn "\nWarning: Ignoring compound record number $CmpdCount with ID $CmpdID: Fingerprints generation didn't succeed...\n\n"; } } # Check and filter compounds.... # sub CheckAndFilterCompound { my($CmpdCount, $Molecule) = @_; my($ElementCount, $NonElementCount); ($ElementCount, $NonElementCount) = $Molecule->GetNumOfElementsAndNonElements(); if ($NonElementCount) { ProcessIgnoredCompound('ContainsNonElementalData', $CmpdCount, $Molecule); return 1; } if (!$ElementCount) { ProcessIgnoredCompound('ContainsNoElementalData', $CmpdCount, $Molecule); return 1; } return 0; } # Write out compounds fingerprints generation summary statistics... # sub WriteFingerprintsGenerationSummaryStatistics { my($CmpdCount, $IgnoredCmpdCount) = @_; my($ProcessedCmpdCount); $ProcessedCmpdCount = $CmpdCount - $IgnoredCmpdCount; print "\nNumber of compounds: $CmpdCount\n"; print "Number of compounds processed successfully during fingerprints generation: $ProcessedCmpdCount\n"; print "Number of compounds ignored during fingerprints generation: $IgnoredCmpdCount\n"; } # Open output files... # sub SetupAndOpenOutputFiles { my($FileIndex) = @_; my($NewFPSDFile, $NewFPFile, $NewFPTextFile, $NewFPSDFileIO, $NewFPTextFileIO, $NewFPFileIO, %FingerprintsFileIOParams); ($NewFPSDFileIO, $NewFPTextFileIO, $NewFPFileIO) = (undef) x 3; # Setup common parameters for fingerprints file IO objects... # %FingerprintsFileIOParams = ('Mode' => 'Write', 'Overwrite' => $OptionsInfo{OverwriteFiles}, 'FingerprintsStringMode' => 'FingerprintsVectorString', 'VectorStringFormat' => $OptionsInfo{VectorStringFormat}); if ($OptionsInfo{SDOutput}) { $NewFPSDFile = $SDFilesInfo{SDOutFileNames}[$FileIndex]; print "Generating SD file $NewFPSDFile...\n"; $NewFPSDFileIO = new FileIO::FingerprintsSDFileIO('Name' => $NewFPSDFile, %FingerprintsFileIOParams, 'FingerprintsFieldLabel' => $OptionsInfo{FingerprintsLabel}); $NewFPSDFileIO->Open(); } if ($OptionsInfo{FPOutput}) { $NewFPFile = $SDFilesInfo{FPOutFileNames}[$FileIndex]; print "Generating FP file $NewFPFile...\n"; $NewFPFileIO = new FileIO::FingerprintsFPFileIO('Name' => $NewFPFile, %FingerprintsFileIOParams); $NewFPFileIO->Open(); } if ($OptionsInfo{TextOutput}) { my($ColLabelsRef); $NewFPTextFile = $SDFilesInfo{TextOutFileNames}[$FileIndex]; $ColLabelsRef = SetupFPTextFileCoulmnLabels($FileIndex); print "Generating text file $NewFPTextFile...\n"; $NewFPTextFileIO = new FileIO::FingerprintsTextFileIO('Name' => $NewFPTextFile, %FingerprintsFileIOParams, 'DataColLabels' => $ColLabelsRef, 'OutDelim' => $OptionsInfo{OutDelim}, 'OutQuote' => $OptionsInfo{OutQuote}); $NewFPTextFileIO->Open(); } return ($NewFPSDFileIO, $NewFPTextFileIO, $NewFPFileIO); } # Write fingerpritns and other data to appropriate output files... # sub WriteDataToOutputFiles { my($FileIndex, $CmpdCount, $Molecule, $TopologicalAtomTorsionsFingerprints, $NewFPSDFileIO, $NewFPTextFileIO, $NewFPFileIO) = @_; my($DataFieldLabelAndValuesRef); $DataFieldLabelAndValuesRef = undef; if ($NewFPTextFileIO || $NewFPFileIO) { $DataFieldLabelAndValuesRef = $Molecule->GetDataFieldLabelAndValues(); } if ($NewFPSDFileIO) { my($CmpdString); $CmpdString = $Molecule->GetInputMoleculeString(); $NewFPSDFileIO->WriteFingerprints($TopologicalAtomTorsionsFingerprints, $CmpdString); } if ($NewFPTextFileIO) { my($ColValuesRef); $ColValuesRef = SetupFPTextFileCoulmnValues($FileIndex, $CmpdCount, $Molecule, $DataFieldLabelAndValuesRef); $NewFPTextFileIO->WriteFingerprints($TopologicalAtomTorsionsFingerprints, $ColValuesRef); } if ($NewFPFileIO) { my($CompoundID); $CompoundID = SetupCmpdIDForOutputFiles($CmpdCount, $Molecule, $DataFieldLabelAndValuesRef); $NewFPFileIO->WriteFingerprints($TopologicalAtomTorsionsFingerprints, $CompoundID); } } # Generate approriate column labels for FPText output file... # sub SetupFPTextFileCoulmnLabels { my($FileIndex) = @_; my($Line, @ColLabels); @ColLabels = (); if ($OptionsInfo{DataFieldsMode} =~ /^All$/i) { push @ColLabels, @{$SDFilesInfo{AllDataFieldsRef}[$FileIndex]}; } elsif ($OptionsInfo{DataFieldsMode} =~ /^Common$/i) { push @ColLabels, @{$SDFilesInfo{CommonDataFieldsRef}[$FileIndex]}; } elsif ($OptionsInfo{DataFieldsMode} =~ /^Specify$/i) { push @ColLabels, @{$OptionsInfo{SpecifiedDataFields}}; } elsif ($OptionsInfo{DataFieldsMode} =~ /^CompoundID$/i) { push @ColLabels, $OptionsInfo{CompoundIDLabel}; } # Add fingerprints label... push @ColLabels, $OptionsInfo{FingerprintsLabel}; return \@ColLabels; } # Generate column values FPText output file.. # sub SetupFPTextFileCoulmnValues { my($FileIndex, $CmpdCount, $Molecule, $DataFieldLabelAndValuesRef) = @_; my(@ColValues); @ColValues = (); if ($OptionsInfo{DataFieldsMode} =~ /^CompoundID$/i) { push @ColValues, SetupCmpdIDForOutputFiles($CmpdCount, $Molecule, $DataFieldLabelAndValuesRef); } elsif ($OptionsInfo{DataFieldsMode} =~ /^All$/i) { @ColValues = map { exists $DataFieldLabelAndValuesRef->{$_} ? $DataFieldLabelAndValuesRef->{$_} : ''} @{$SDFilesInfo{AllDataFieldsRef}[$FileIndex]}; } elsif ($OptionsInfo{DataFieldsMode} =~ /^Common$/i) { @ColValues = map { exists $DataFieldLabelAndValuesRef->{$_} ? $DataFieldLabelAndValuesRef->{$_} : ''} @{$SDFilesInfo{CommonDataFieldsRef}[$FileIndex]}; } elsif ($OptionsInfo{DataFieldsMode} =~ /^Specify$/i) { @ColValues = map { exists $DataFieldLabelAndValuesRef->{$_} ? $DataFieldLabelAndValuesRef->{$_} : ''} @{$OptionsInfo{SpecifiedDataFields}}; } return \@ColValues; } # Generate compound ID for FP and FPText output files.. # sub SetupCmpdIDForOutputFiles { my($CmpdCount, $Molecule, $DataFieldLabelAndValuesRef) = @_; my($CmpdID); $CmpdID = ''; if ($OptionsInfo{CompoundIDMode} =~ /^MolNameOrLabelPrefix$/i) { my($MolName); $MolName = $Molecule->GetName(); $CmpdID = $MolName ? $MolName : "$OptionsInfo{CompoundID}${CmpdCount}"; } elsif ($OptionsInfo{CompoundIDMode} =~ /^LabelPrefix$/i) { $CmpdID = "$OptionsInfo{CompoundID}${CmpdCount}"; } elsif ($OptionsInfo{CompoundIDMode} =~ /^DataField$/i) { my($SpecifiedDataField); $SpecifiedDataField = $OptionsInfo{CompoundID}; $CmpdID = exists $DataFieldLabelAndValuesRef->{$SpecifiedDataField} ? $DataFieldLabelAndValuesRef->{$SpecifiedDataField} : ''; } elsif ($OptionsInfo{CompoundIDMode} =~ /^MolName$/i) { $CmpdID = $Molecule->GetName(); } return $CmpdID; } # Generate fingerprints for molecule... # sub GenerateMoleculeFingerprints { my($Molecule) = @_; my($TopologicalAtomTorsionsFingerprints); if ($OptionsInfo{KeepLargestComponent}) { $Molecule->KeepLargestComponent(); } if (!$Molecule->DetectRings()) { return undef; } $Molecule->SetAromaticityModel($OptionsInfo{AromaticityModel}); $Molecule->DetectAromaticity(); $TopologicalAtomTorsionsFingerprints = new Fingerprints::TopologicalAtomTorsionsFingerprints('Molecule' => $Molecule, 'AtomIdentifierType' => $OptionsInfo{AtomIdentifierType}); SetAtomIdentifierTypeValuesToUse($TopologicalAtomTorsionsFingerprints); # Generate fingerprints... $TopologicalAtomTorsionsFingerprints->GenerateFingerprints(); # Make sure fingerprints generation is successful... if (!$TopologicalAtomTorsionsFingerprints->IsFingerprintsGenerationSuccessful()) { return undef; } return $TopologicalAtomTorsionsFingerprints; } # Set atom identifier type to use for generating fingerprints... # sub SetAtomIdentifierTypeValuesToUse { my($TopologicalAtomTorsionsFingerprints) = @_; if ($OptionsInfo{AtomIdentifierType} =~ /^AtomicInvariantsAtomTypes$/i) { $TopologicalAtomTorsionsFingerprints->SetAtomicInvariantsToUse(\@{$OptionsInfo{AtomicInvariantsToUse}}); } elsif ($OptionsInfo{AtomIdentifierType} =~ /^FunctionalClassAtomTypes$/i) { $TopologicalAtomTorsionsFingerprints->SetFunctionalClassesToUse(\@{$OptionsInfo{FunctionalClassesToUse}}); } elsif ($OptionsInfo{AtomIdentifierType} =~ /^(DREIDINGAtomTypes|EStateAtomTypes|MMFF94AtomTypes|SLogPAtomTypes|SYBYLAtomTypes|TPSAAtomTypes|UFFAtomTypes)$/i) { # Nothing to do for now... } else { die "Error: The value specified, $Options{atomidentifiertype}, for option \"-a, --AtomIdentifierType\" is not valid. Supported atom identifier types in current release of MayaChemTools: AtomicInvariantsAtomTypes, DREIDINGAtomTypes, EStateAtomTypes, FunctionalClassAtomTypes, MMFF94AtomTypes, SLogPAtomTypes, SYBYLAtomTypes, TPSAAtomTypes, UFFAtomTypes\n"; } } # Retrieve information about SD files... # sub RetrieveSDFilesInfo { my($SDFile, $Index, $FileDir, $FileExt, $FileName, $OutFileRoot, $TextOutFileExt, $SDOutFileExt, $FPOutFileExt, $NewSDFileName, $NewFPFileName, $NewTextFileName, $CheckDataField, $CollectDataFields, $AllDataFieldsRef, $CommonDataFieldsRef); %SDFilesInfo = (); @{$SDFilesInfo{FileOkay}} = (); @{$SDFilesInfo{OutFileRoot}} = (); @{$SDFilesInfo{SDOutFileNames}} = (); @{$SDFilesInfo{FPOutFileNames}} = (); @{$SDFilesInfo{TextOutFileNames}} = (); @{$SDFilesInfo{AllDataFieldsRef}} = (); @{$SDFilesInfo{CommonDataFieldsRef}} = (); $CheckDataField = ($OptionsInfo{TextOutput} && ($OptionsInfo{DataFieldsMode} =~ /^CompoundID$/i) && ($OptionsInfo{CompoundIDMode} =~ /^DataField$/i)) ? 1 : 0; $CollectDataFields = ($OptionsInfo{TextOutput} && ($OptionsInfo{DataFieldsMode} =~ /^(All|Common)$/i)) ? 1 : 0; FILELIST: for $Index (0 .. $#SDFilesList) { $SDFile = $SDFilesList[$Index]; $SDFilesInfo{FileOkay}[$Index] = 0; $SDFilesInfo{OutFileRoot}[$Index] = ''; $SDFilesInfo{SDOutFileNames}[$Index] = ''; $SDFilesInfo{FPOutFileNames}[$Index] = ''; $SDFilesInfo{TextOutFileNames}[$Index] = ''; $SDFile = $SDFilesList[$Index]; if (!(-e $SDFile)) { warn "Warning: Ignoring file $SDFile: It doesn't exist\n"; next FILELIST; } if (!CheckFileType($SDFile, "sd sdf")) { warn "Warning: Ignoring file $SDFile: It's not a SD file\n"; next FILELIST; } if ($CheckDataField) { # Make sure data field exists in SD file.. my($CmpdString, $SpecifiedDataField, @CmpdLines, %DataFieldValues); @CmpdLines = (); open SDFILE, "$SDFile" or die "Error: Couldn't open $SDFile: $! \n"; $CmpdString = ReadCmpdString(\*SDFILE); close SDFILE; @CmpdLines = split "\n", $CmpdString; %DataFieldValues = GetCmpdDataHeaderLabelsAndValues(\@CmpdLines); $SpecifiedDataField = $OptionsInfo{CompoundID}; if (!exists $DataFieldValues{$SpecifiedDataField}) { warn "Warning: Ignoring file $SDFile: Data field value, $SpecifiedDataField, using \"--CompoundID\" option in \"DataField\" \"--CompoundIDMode\" doesn't exist\n"; next FILELIST; } } $AllDataFieldsRef = ''; $CommonDataFieldsRef = ''; if ($CollectDataFields) { my($CmpdCount); open SDFILE, "$SDFile" or die "Error: Couldn't open $SDFile: $! \n"; ($CmpdCount, $AllDataFieldsRef, $CommonDataFieldsRef) = GetAllAndCommonCmpdDataHeaderLabels(\*SDFILE); close SDFILE; } # Setup output file names... $FileDir = ""; $FileName = ""; $FileExt = ""; ($FileDir, $FileName, $FileExt) = ParseFileName($SDFile); $TextOutFileExt = "csv"; if ($Options{outdelim} =~ /^tab$/i) { $TextOutFileExt = "tsv"; } $SDOutFileExt = $FileExt; $FPOutFileExt = "fpf"; if ($OptionsInfo{OutFileRoot} && (@SDFilesList == 1)) { my ($RootFileDir, $RootFileName, $RootFileExt) = ParseFileName($OptionsInfo{OutFileRoot}); if ($RootFileName && $RootFileExt) { $FileName = $RootFileName; } else { $FileName = $OptionsInfo{OutFileRoot}; } $OutFileRoot = $FileName; } else { $OutFileRoot = "${FileName}TopologicalAtomTorsionsFP"; } $NewSDFileName = "${OutFileRoot}.${SDOutFileExt}"; $NewFPFileName = "${OutFileRoot}.${FPOutFileExt}"; $NewTextFileName = "${OutFileRoot}.${TextOutFileExt}"; if ($OptionsInfo{SDOutput}) { if ($SDFile =~ /$NewSDFileName/i) { warn "Warning: Ignoring input file $SDFile: Same output, $NewSDFileName, and input file names.\n"; print "Specify a different name using \"-r --root\" option or use default name.\n"; next FILELIST; } } if (!$OptionsInfo{OverwriteFiles}) { # Check SD and text outout files... if ($OptionsInfo{SDOutput}) { if (-e $NewSDFileName) { warn "Warning: Ignoring file $SDFile: The file $NewSDFileName already exists\n"; next FILELIST; } } if ($OptionsInfo{FPOutput}) { if (-e $NewFPFileName) { warn "Warning: Ignoring file $SDFile: The file $NewFPFileName already exists\n"; next FILELIST; } } if ($OptionsInfo{TextOutput}) { if (-e $NewTextFileName) { warn "Warning: Ignoring file $SDFile: The file $NewTextFileName already exists\n"; next FILELIST; } } } $SDFilesInfo{FileOkay}[$Index] = 1; $SDFilesInfo{OutFileRoot}[$Index] = $OutFileRoot; $SDFilesInfo{SDOutFileNames}[$Index] = $NewSDFileName; $SDFilesInfo{FPOutFileNames}[$Index] = $NewFPFileName; $SDFilesInfo{TextOutFileNames}[$Index] = $NewTextFileName; $SDFilesInfo{AllDataFieldsRef}[$Index] = $AllDataFieldsRef; $SDFilesInfo{CommonDataFieldsRef}[$Index] = $CommonDataFieldsRef; } } # Process option values... sub ProcessOptions { %OptionsInfo = (); ProcessAtomIdentifierTypeOptions(); $OptionsInfo{AromaticityModel} = $Options{aromaticitymodel}; $OptionsInfo{CompoundIDMode} = $Options{compoundidmode}; $OptionsInfo{CompoundIDLabel} = $Options{compoundidlabel}; $OptionsInfo{DataFieldsMode} = $Options{datafieldsmode}; my(@SpecifiedDataFields); @SpecifiedDataFields = (); @{$OptionsInfo{SpecifiedDataFields}} = (); $OptionsInfo{CompoundID} = ''; if ($Options{datafieldsmode} =~ /^CompoundID$/i) { if ($Options{compoundidmode} =~ /^DataField$/i) { if (!$Options{compoundid}) { die "Error: You must specify a value for \"--CompoundID\" option in \"DataField\" \"--CompoundIDMode\". \n"; } $OptionsInfo{CompoundID} = $Options{compoundid}; } elsif ($Options{compoundidmode} =~ /^(LabelPrefix|MolNameOrLabelPrefix)$/i) { $OptionsInfo{CompoundID} = $Options{compoundid} ? $Options{compoundid} : 'Cmpd'; } } elsif ($Options{datafieldsmode} =~ /^Specify$/i) { if (!$Options{datafields}) { die "Error: You must specify a value for \"--DataFields\" option in \"Specify\" \"-d, --DataFieldsMode\". \n"; } @SpecifiedDataFields = split /\,/, $Options{datafields}; push @{$OptionsInfo{SpecifiedDataFields}}, @SpecifiedDataFields; } $OptionsInfo{Filter} = ($Options{filter} =~ /^Yes$/i) ? 1 : 0; $OptionsInfo{FingerprintsLabel} = $Options{fingerprintslabel} ? $Options{fingerprintslabel} : 'TopologicalAtomTorsionsFingerprints'; $OptionsInfo{KeepLargestComponent} = ($Options{keeplargestcomponent} =~ /^Yes$/i) ? 1 : 0; $OptionsInfo{Output} = $Options{output}; $OptionsInfo{SDOutput} = ($Options{output} =~ /^(SD|All)$/i) ? 1 : 0; $OptionsInfo{FPOutput} = ($Options{output} =~ /^(FP|All)$/i) ? 1 : 0; $OptionsInfo{TextOutput} = ($Options{output} =~ /^(Text|All)$/i) ? 1 : 0; $OptionsInfo{OutDelim} = $Options{outdelim}; $OptionsInfo{OutQuote} = ($Options{quote} =~ /^Yes$/i) ? 1 : 0; $OptionsInfo{OverwriteFiles} = $Options{overwrite} ? 1 : 0; $OptionsInfo{OutFileRoot} = $Options{root} ? $Options{root} : 0; $OptionsInfo{VectorStringFormat} = $Options{vectorstringformat}; } # Process atom identifier type and related options... # sub ProcessAtomIdentifierTypeOptions { $OptionsInfo{AtomIdentifierType} = $Options{atomidentifiertype}; if ($Options{atomidentifiertype} =~ /^AtomicInvariantsAtomTypes$/i) { ProcessAtomicInvariantsToUseOption(); } elsif ($Options{atomidentifiertype} =~ /^FunctionalClassAtomTypes$/i) { ProcessFunctionalClassesToUse(); } elsif ($OptionsInfo{AtomIdentifierType} =~ /^(DREIDINGAtomTypes|EStateAtomTypes|MMFF94AtomTypes|SLogPAtomTypes|SYBYLAtomTypes|TPSAAtomTypes|UFFAtomTypes)$/i) { # Nothing to do for now... } else { die "Error: The value specified, $Options{atomidentifiertype}, for option \"-a, --AtomIdentifierType\" is not valid. Supported atom identifier types in current release of MayaChemTools: AtomicInvariantsAtomTypes, DREIDINGAtomTypes, EStateAtomTypes, FunctionalClassAtomTypes, MMFF94AtomTypes, SLogPAtomTypes, SYBYLAtomTypes, TPSAAtomTypes, UFFAtomTypes\n"; } } # Process specified atomic invariants to use... # sub ProcessAtomicInvariantsToUseOption { my($AtomicInvariant, $AtomSymbolSpecified, @AtomicInvariantsWords); @{$OptionsInfo{AtomicInvariantsToUse}} = (); if (IsEmpty($Options{atomicinvariantstouse})) { die "Error: Atomic invariants value specified using \"--AtomicInvariantsToUse\" option is empty\n"; } $AtomSymbolSpecified = 0; @AtomicInvariantsWords = split /\,/, $Options{atomicinvariantstouse}; for $AtomicInvariant (@AtomicInvariantsWords) { if (!AtomTypes::AtomicInvariantsAtomTypes::IsAtomicInvariantAvailable($AtomicInvariant)) { die "Error: Atomic invariant specified, $AtomicInvariant, using \"--AtomicInvariantsToUse\" option is not valid...\n "; } if ($AtomicInvariant =~ /^(AS|AtomSymbol)$/i) { $AtomSymbolSpecified = 1; } push @{$OptionsInfo{AtomicInvariantsToUse}}, $AtomicInvariant; } if (!$AtomSymbolSpecified) { die "Error: Atomic invariant, AS or AtomSymbol, must be specified as using \"--AtomicInvariantsToUse\" option...\n "; } } # Process specified functional classes invariants to use... # sub ProcessFunctionalClassesToUse { my($FunctionalClass, @FunctionalClassesToUseWords); @{$OptionsInfo{FunctionalClassesToUse}} = (); if (IsEmpty($Options{functionalclassestouse})) { die "Error: Functional classes value specified using \"--FunctionalClassesToUse\" option is empty\n"; } @FunctionalClassesToUseWords = split /\,/, $Options{functionalclassestouse}; for $FunctionalClass (@FunctionalClassesToUseWords) { if (!AtomTypes::FunctionalClassAtomTypes::IsFunctionalClassAvailable($FunctionalClass)) { die "Error: Functional class specified, $FunctionalClass, using \"--FunctionalClassesToUse\" option is not valid...\n "; } push @{$OptionsInfo{FunctionalClassesToUse}}, $FunctionalClass; } } # Setup script usage and retrieve command line arguments specified using various options... sub SetupScriptUsage { # Retrieve all the options... %Options = (); $Options{aromaticitymodel} = 'MayaChemToolsAromaticityModel'; $Options{atomidentifiertype} = 'AtomicInvariantsAtomTypes'; $Options{atomicinvariantstouse} = 'AS,X,BO,H,FC'; $Options{functionalclassestouse} = 'HBD,HBA,PI,NI,Ar,Hal'; $Options{compoundidmode} = 'LabelPrefix'; $Options{compoundidlabel} = 'CompoundID'; $Options{datafieldsmode} = 'CompoundID'; $Options{filter} = 'Yes'; $Options{keeplargestcomponent} = 'Yes'; $Options{output} = 'text'; $Options{outdelim} = 'comma'; $Options{quote} = 'yes'; $Options{vectorstringformat} = 'IDsAndValuesString'; if (!GetOptions(\%Options, "aromaticitymodel=s", "atomidentifiertype|a=s", "atomicinvariantstouse=s", "functionalclassestouse=s", "compoundid=s", "compoundidlabel=s", "compoundidmode=s", "datafields=s", "datafieldsmode|d=s", "filter|f=s", "fingerprintslabel=s", "help|h", "keeplargestcomponent|k=s", "outdelim=s", "output=s", "overwrite|o", "quote|q=s", "root|r=s", "vectorstringformat|v=s", "workingdir|w=s")) { die "\nTo get a list of valid options and their values, use \"$ScriptName -h\" or\n\"perl -S $ScriptName -h\" command and try again...\n"; } if ($Options{workingdir}) { if (! -d $Options{workingdir}) { die "Error: The value specified, $Options{workingdir}, for option \"-w --workingdir\" is not a directory name.\n"; } chdir $Options{workingdir} or die "Error: Couldn't chdir $Options{workingdir}: $! \n"; } if (!Molecule::IsSupportedAromaticityModel($Options{aromaticitymodel})) { my(@SupportedModels) = Molecule::GetSupportedAromaticityModels(); die "Error: The value specified, $Options{aromaticitymodel}, for option \"--AromaticityModel\" is not valid. Supported aromaticity models in current release of MayaChemTools: @SupportedModels\n"; } if ($Options{atomidentifiertype} !~ /^(AtomicInvariantsAtomTypes|DREIDINGAtomTypes|EStateAtomTypes|FunctionalClassAtomTypes|MMFF94AtomTypes|SLogPAtomTypes|SYBYLAtomTypes|TPSAAtomTypes|UFFAtomTypes)$/i) { die "Error: The value specified, $Options{atomidentifiertype}, for option \"-a, --AtomIdentifierType\" is not valid. Supported atom identifier types in current release of MayaChemTools: AtomicInvariantsAtomTypes, DREIDINGAtomTypes, EStateAtomTypes, FunctionalClassAtomTypes, MMFF94AtomTypes, SLogPAtomTypes, SYBYLAtomTypes, TPSAAtomTypes, UFFAtomTypes\n"; } if ($Options{compoundidmode} !~ /^(DataField|MolName|LabelPrefix|MolNameOrLabelPrefix)$/i) { die "Error: The value specified, $Options{compoundidmode}, for option \"--CompoundIDMode\" is not valid. Allowed values: DataField, MolName, LabelPrefix or MolNameOrLabelPrefix\n"; } if ($Options{datafieldsmode} !~ /^(All|Common|Specify|CompoundID)$/i) { die "Error: The value specified, $Options{datafieldsmode}, for option \"-d, --DataFieldsMode\" is not valid. Allowed values: All, Common, Specify or CompoundID\n"; } if ($Options{filter} !~ /^(Yes|No)$/i) { die "Error: The value specified, $Options{filter}, for option \"-f, --Filter\" is not valid. Allowed values: Yes or No\n"; } if ($Options{keeplargestcomponent} !~ /^(Yes|No)$/i) { die "Error: The value specified, $Options{keeplargestcomponent}, for option \"-k, --KeepLargestComponent\" is not valid. Allowed values: Yes or No\n"; } if ($Options{output} !~ /^(SD|FP|text|all)$/i) { die "Error: The value specified, $Options{output}, for option \"--output\" is not valid. Allowed values: SD, FP, text, or all\n"; } if ($Options{quote} !~ /^(Yes|No)$/i) { die "Error: The value specified, $Options{quote}, for option \"-q --quote\" is not valid. Allowed values: Yes or No\n"; } if ($Options{outdelim} =~ /semicolon/i && $Options{quote} =~ /^No$/i) { die "Error: The value specified, $Options{quote}, for option \"-q --quote\" is not allowed with, semicolon value of \"--outdelim\" option: Fingerprints string use semicolon as delimiter for various data fields and must be quoted.\n"; } if ($Options{vectorstringformat} !~ /^(IDsAndValuesString|IDsAndValuesPairsString|ValuesAndIDsString|ValuesAndIDsPairsString)$/i) { die "Error: The value specified, $Options{vectorstringformat}, for option \"-v, --VectorStringFormat\" is not valid. Allowed values: IDsAndValuesString, IDsAndValuesPairsString, ValuesAndIDsString or ValuesAndIDsPairsString\n"; } } __END__ =head1 NAME TopologicalAtomTorsionsFingerprints.pl - Generate topological atom torsions fingerprints for SD files =head1 SYNOPSIS TopologicalAtomTorsionsFingerprints.pl SDFile(s)... TopologicalAtomTorsionsFingerprints.pl [B<--AromaticityModel> I<AromaticityModelType>] [B<-a, --AtomIdentifierType> I<AtomicInvariantsAtomTypes>] [B<--AtomicInvariantsToUse> I<"AtomicInvariant,AtomicInvariant...">] [B<--FunctionalClassesToUse> I<"FunctionalClass1,FunctionalClass2...">] [B<--CompoundID> I<DataFieldName or LabelPrefixString>] [B<--CompoundIDLabel> I<text>] [B<--CompoundIDMode>] [B<--DataFields> I<"FieldLabel1,FieldLabel2,...">] [B<-d, --DataFieldsMode> I<All | Common | Specify | CompoundID>] [B<-f, --Filter> I<Yes | No>] [B<--FingerprintsLabel> I<text>] [B<-h, --help>] [B<-k, --KeepLargestComponent> I<Yes | No>] [B<--OutDelim> I<comma | tab | semicolon>] [B<--output> I<SD | FP | text | all>] [B<-o, --overwrite>] [B<-q, --quote> I<Yes | No>] [B<-r, --root> I<RootName>] [B<-v, --VectorStringFormat>] [B<-w, --WorkingDir> dirname] SDFile(s)... =head1 DESCRIPTION Generate topological atom torsions fingerprints [ Ref 58, Ref 72 ] for I<SDFile(s)> and create appropriate SD, FP or CSV/TSV text file(s) containing fingerprints vector strings corresponding to molecular fingerprints. Multiple SDFile names are separated by spaces. The valid file extensions are I<.sdf> and I<.sd>. All other file names are ignored. All the SD files in a current directory can be specified either by I<*.sdf> or the current directory name. The current release of MayaChemTools supports generation of topological atom torsions fingerprints corresponding to following B<-a, --AtomIdentifierTypes>: AtomicInvariantsAtomTypes, DREIDINGAtomTypes, EStateAtomTypes, FunctionalClassAtomTypes, MMFF94AtomTypes, SLogPAtomTypes, SYBYLAtomTypes, TPSAAtomTypes, UFFAtomTypes Based on the values specified for B<-a, --AtomIdentifierType> and B<--AtomicInvariantsToUse>, initial atom types are assigned to all non-hydrogen atoms in a molecule. All unique atom torsions are identified and an atom torsion identifier is generated; the format of atom torsion identifier is: <AtomType1>-<AtomType2>-<AtomType3>-<AtomType4> AtomType1, AtomType2, AtomType3, AtomTyp4: Assigned atom types where AtomType1 <= AtomType2 <= AtomType3 <= AtomType4 The atom torsion identifiers for all unique atom torsions corresponding to non-hydrogen atoms constitute topological atom torsions fingerprints of the molecule. Example of I<SD> file containing topological atom torsions fingerprints string data: ... ... ... ... $$$$ ... ... ... ... ... ... 41 44 0 0 0 0 0 0 0 0999 V2000 -3.3652 1.4499 0.0000 C 0 0 0 0 0 0 0 0 0 0 0 0 ... ... 2 3 1 0 0 0 0 ... ... M END > <CmpdID> Cmpd1 > <TopologicalAtomTorsionsFingerprints> FingerprintsVector;TopologicalAtomTorsions:AtomicInvariantsAtomTypes;33 ;NumericalValues;IDsAndValuesString;C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4-C. X3.BO4 C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4-N.X3.BO3 C.X2.BO2.H2-C.X2.BO2.H 2-C.X3.BO3.H1-C.X2.BO2.H2 C.X2.BO2.H2-C.X2.BO2.H2-C.X3.BO3.H1-O.X1....; 2 2 1 1 2 2 1 1 3 4 4 8 4 2 2 6 2 2 1 2 1 1 2 1 1 2 6 2 4 2 1 3 1 $$$$ ... ... ... ... Example of I<FP> file containing topological atom torsions fingerprints string data: # # Package = MayaChemTools 7.4 # Release Date = Oct 21, 2010 # # TimeStamp = Fri Mar 11 15:17:20 2011 # # FingerprintsStringType = FingerprintsVector # # Description = TopologicalAtomTorsions:AtomicInvariantsAtomTypes # VectorStringFormat = IDsAndValuesString # VectorValuesType = NumericalValues # Cmpd1 33;C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4-C.X3.BO4...;2 2 1 1 2 2 ... Cmpd2 23;C.X1.BO1.H3-C.X2.BO2.H2-C.X3.BO3.H1-C.X2.BO2.H2...;2 2 1 5 ... ... ... ... .. Example of CSV I<Text> file containing topological atom torsions fingerprints string data: "CompoundID","TopologicalAtomTorsionsFingerprints" "Cmpd1","FingerprintsVector;TopologicalAtomTorsions:AtomicInvariantsAto mTypes;33;NumericalValues;IDsAndValuesString;C.X1.BO1.H3-C.X3.BO3.H1-C. X3.BO4-C.X3.BO4 C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4-N.X3.BO3 C.X2.BO2.H2-C .X2.BO2.H2-C.X3.BO3.H1-C.X2.BO2.H2 C.X2.BO2.H2-C.X2.BO2.H2-C.X3.BO3....; 2 2 1 1 2 2 1 1 3 4 4 8 4 2 2 6 2 2 1 2 1 1 2 1 1 2 6 2 4 2 1 3 1 ... ... ... ... The current release of MayaChemTools generates the following types of topological atom torsions fingerprints vector strings: FingerprintsVector;TopologicalAtomTorsions:AtomicInvariantsAtomTypes;3 3;NumericalValues;IDsAndValuesString;C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4- C.X3.BO4 C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4-N.X3.BO3 C.X2.BO2.H2-C.X2.BO 2.H2-C.X3.BO3.H1-C.X2.BO2.H2 C.X2.BO2.H2-C.X2.BO2.H2-C.X3.BO3.H1-O...; ;2 2 1 1 2 2 1 1 3 4 4 8 4 2 2 6 2 2 1 2 1 1 2 1 1 2 6 2 4 2 1 3 1 FingerprintsVector;TopologicalAtomTorsions:AtomicInvariantsAtomTypes;3 3;NumericalValues;IDsAndValuesPairsString;C.X1.BO1.H3-C.X3.BO3.H1-C.X3 .BO4-C.X3.BO4 2 C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4-N.X3.BO3 2 C.X2.BO2.H 2-C.X2.BO2.H2-C.X3.BO3.H1-C.X2.BO2.H2 1 C.X2.BO2.H2-C.X2.BO2.H2-C.X3.B O3.H1-O.X1.BO1.H1 1 C.X2.BO2.H2-C.X2.BO2.H2-N.X3.BO3-C.X3.BO4 2 C.X2.B O2.H2-C.X3.BO3.H1-C.X2.BO2.H2-C.X3.BO3.H1 2 C.X2.BO2.H2-C.X3.BO3.H1... FingerprintsVector;TopologicalAtomTorsions:DREIDINGAtomTypes;27;Numeri calValues;IDsAndValuesString;C_2-C_3-C_3-C_3 C_2-C_3-C_3-O_3 C_2-C_R-C _R-C_3 C_2-C_R-C_R-C_R C_2-C_R-C_R-N_R C_2-N_3-C_R-C_R C_3-C_3-C_2-O_2 C_3-C_3-C_2-O_3 C_3-C_3-C_3-C_3 C_3-C_3-C_3-N_R C_3-C_3-C_3-O_3 C_...; 1 1 1 2 1 2 1 1 3 1 3 2 2 2 1 1 1 3 1 2 2 32 2 2 5 3 1 FingerprintsVector;TopologicalAtomTorsions:EStateAtomTypes;36;Numerica lValues;IDsAndValuesString;aaCH-aaCH-aaCH-aaCH aaCH-aaCH-aaCH-aasC aaC H-aaCH-aasC-aaCH aaCH-aaCH-aasC-aasC aaCH-aaCH-aasC-sF aaCH-aaCH-aasC- ssNH aaCH-aasC-aasC-aasC aaCH-aasC-aasC-aasN aaCH-aasC-ssNH-dssC a...; 4 4 8 4 2 2 6 2 2 2 4 3 2 1 3 3 2 2 2 1 2 1 1 1 2 1 1 1 1 1 1 1 2 1 1 2 FingerprintsVector;TopologicalAtomTorsions:FunctionalClassAtomTypes;26 ;NumericalValues;IDsAndValuesString;Ar-Ar-Ar-Ar Ar-Ar-Ar-Ar.HBA Ar-Ar- Ar-HBD Ar-Ar-Ar-Hal Ar-Ar-Ar-None Ar-Ar-Ar.HBA-Ar Ar-Ar-Ar.HBA-None Ar -Ar-HBD-None Ar-Ar-None-HBA Ar-Ar-None-HBD Ar-Ar-None-None Ar-Ar.H...; 32 5 2 2 3 3 3 2 2 2 2 1 2 1 1 1 2 1 1 1 1 3 1 1 1 3 FingerprintsVector;TopologicalAtomTorsions:MMFF94AtomTypes;43;Numerica lValues;IDsAndValuesString;C5A-C5B-C5B-C5A C5A-C5B-C5B-C=ON C5A-C5B-C5 B-CB C5A-C5B-C=ON-NC=O C5A-C5B-C=ON-O=CN C5A-C5B-CB-CB C5A-CB-CB-CB C5 A-N5-C5A-C5B C5A-N5-C5A-CB C5A-N5-C5A-CR C5A-N5-CR-CR C5B-C5A-CB-C...; 1 1 1 1 1 2 2 2 1 1 2 2 2 2 1 1 2 1 1 2 1 2 1 1 1 2 1 1 1 2 18 2 2 1 1 1 1 2 1 1 3 1 3 FingerprintsVector;TopologicalAtomTorsions:SLogPAtomTypes;49;Numerical Values;IDsAndValuesPairsString;C1-C10-N11-C20 1 C1-C10-N11-C21 1 C1-C1 1-C21-C21 2 C1-C11-C21-N11 2 C1-CS-C1-C10 1 C1-CS-C1-C5 1 C1-CS-C1-CS 2 C10-C1-CS-O2 1 C10-N11-C20-C20 2 C10-N11-C21-C11 1 C10-N11-C21-C21 1 C11-C21-C21-C20 1 C11-C21-C21-C5 1 C11-C21-N11-C20 1 C14-C18-C18-C20 2 C18-C14-C18-C18 2 C18-C18-C14-F 2 C18-C18-C18-C18 4 C18-C18-C18-C... FingerprintsVector;TopologicalAtomTorsions:SYBYLAtomTypes;26;Numerical Values;IDsAndValuesPairsString;C.2-C.3-C.3-C.3 1 C.2-C.3-C.3-O.3 1 C.2 -C.ar-C.ar-C.3 1 C.2-C.ar-C.ar-C.ar 2 C.2-C.ar-C.ar-N.ar 1 C.2-N.am-C. ar-C.ar 2 C.3-C.3-C.2-O.co2 2 C.3-C.3-C.3-C.3 3 C.3-C.3-C.3-N.ar 1 C.3 -C.3-C.3-O.3 3 C.3-C.3-C.ar-C.ar 2 C.3-C.3-C.ar-N.ar 2 C.3-C.3-N.ar-C. ar 2 C.3-C.ar-C.ar-C.ar 1 C.3-C.ar-N.ar-C.3 1 C.3-C.ar-N.ar-C.ar 1 ... FingerprintsVector;TopologicalAtomTorsions:TPSAAtomTypes;8;NumericalVa lues;IDsAndValuesPairsString;N21-None-None-None 9 N7-None-None-None 4 None-N21-None-None 10 None-N7-None-None 3 None-N7-None-O3 1 None-None- None-None 44 None-None-None-O3 3 None-None-None-O4 5 FingerprintsVector;TopologicalAtomTorsions:UFFAtomTypes;27;NumericalVa lues;IDsAndValuesPairsString;C_2-C_3-C_3-C_3 1 C_2-C_3-C_3-O_3 1 C_2-C _R-C_R-C_3 1 C_2-C_R-C_R-C_R 2 C_2-C_R-C_R-N_R 1 C_2-N_3-C_R-C_R 2 C_3 -C_3-C_2-O_2 1 C_3-C_3-C_2-O_3 1 C_3-C_3-C_3-C_3 3 C_3-C_3-C_3-N_R 1 C _3-C_3-C_3-O_3 3 C_3-C_3-C_R-C_R 2 C_3-C_3-C_R-N_R 2 C_3-C_3-N_R-C_R 2 C_3-C_R-C_R-C_R 1 C_3-C_R-N_R-C_3 1 C_3-C_R-N_R-C_R 1 C_3-N_R-C_R-... =head1 OPTIONS =over 4 =item B<--AromaticityModel> I<MDLAromaticityModel | TriposAromaticityModel | MMFFAromaticityModel | ChemAxonBasicAromaticityModel | ChemAxonGeneralAromaticityModel | DaylightAromaticityModel | MayaChemToolsAromaticityModel> Specify aromaticity model to use during detection of aromaticity. Possible values in the current release are: I<MDLAromaticityModel, TriposAromaticityModel, MMFFAromaticityModel, ChemAxonBasicAromaticityModel, ChemAxonGeneralAromaticityModel, DaylightAromaticityModel or MayaChemToolsAromaticityModel>. Default value: I<MayaChemToolsAromaticityModel>. The supported aromaticity model names along with model specific control parameters are defined in B<AromaticityModelsData.csv>, which is distributed with the current release and is available under B<lib/data> directory. B<Molecule.pm> module retrieves data from this file during class instantiation and makes it available to method B<DetectAromaticity> for detecting aromaticity corresponding to a specific model. =item B<-a, --AtomIdentifierType> I<AtomicInvariantsAtomTypes | DREIDINGAtomTypes | EStateAtomTypes | FunctionalClassAtomTypes | MMFF94AtomTypes | SLogPAtomTypes | SYBYLAtomTypes | TPSAAtomTypes | UFFAtomTypes> Specify atom identifier type to use for assignment of initial atom identifier to non-hydrogen atoms during calculation of topological atom torsions fingerprints. Possible values in the current release are: I<AtomicInvariantsAtomTypes, DREIDINGAtomTypes, EStateAtomTypes, FunctionalClassAtomTypes, MMFF94AtomTypes, SLogPAtomTypes, SYBYLAtomTypes, TPSAAtomTypes, UFFAtomTypes>. Default value: I<AtomicInvariantsAtomTypes>. =item B<--AtomicInvariantsToUse> I<"AtomicInvariant,AtomicInvariant..."> This value is used during I<AtomicInvariantsAtomTypes> value of B<a, --AtomIdentifierType> option. It's a list of comma separated valid atomic invariant atom types. Possible values for atomic invariants are: I<AS, X, BO, LBO, SB, DB, TB, H, Ar, RA, FC, MN, SM>. Default value: I<AS,X,BO,H,FC>. The atomic invariants abbreviations correspond to: AS = Atom symbol corresponding to element symbol X<n> = Number of non-hydrogen atom neighbors or heavy atoms BO<n> = Sum of bond orders to non-hydrogen atom neighbors or heavy atoms LBO<n> = Largest bond order of non-hydrogen atom neighbors or heavy atoms SB<n> = Number of single bonds to non-hydrogen atom neighbors or heavy atoms DB<n> = Number of double bonds to non-hydrogen atom neighbors or heavy atoms TB<n> = Number of triple bonds to non-hydrogen atom neighbors or heavy atoms H<n> = Number of implicit and explicit hydrogens for atom Ar = Aromatic annotation indicating whether atom is aromatic RA = Ring atom annotation indicating whether atom is a ring FC<+n/-n> = Formal charge assigned to atom MN<n> = Mass number indicating isotope other than most abundant isotope SM<n> = Spin multiplicity of atom. Possible values: 1 (singlet), 2 (doublet) or 3 (triplet) Atom type generated by AtomTypes::AtomicInvariantsAtomTypes class corresponds to: AS.X<n>.BO<n>.LBO<n>.<SB><n>.<DB><n>.<TB><n>.H<n>.Ar.RA.FC<+n/-n>.MN<n>.SM<n> Except for AS which is a required atomic invariant in atom types, all other atomic invariants are optional. Atom type specification doesn't include atomic invariants with zero or undefined values. In addition to usage of abbreviations for specifying atomic invariants, the following descriptive words are also allowed: X : NumOfNonHydrogenAtomNeighbors or NumOfHeavyAtomNeighbors BO : SumOfBondOrdersToNonHydrogenAtoms or SumOfBondOrdersToHeavyAtoms LBO : LargestBondOrderToNonHydrogenAtoms or LargestBondOrderToHeavyAtoms SB : NumOfSingleBondsToNonHydrogenAtoms or NumOfSingleBondsToHeavyAtoms DB : NumOfDoubleBondsToNonHydrogenAtoms or NumOfDoubleBondsToHeavyAtoms TB : NumOfTripleBondsToNonHydrogenAtoms or NumOfTripleBondsToHeavyAtoms H : NumOfImplicitAndExplicitHydrogens Ar : Aromatic RA : RingAtom FC : FormalCharge MN : MassNumber SM : SpinMultiplicity I<AtomTypes::AtomicInvariantsAtomTypes> module is used to assign atomic invariant atom types. =item B<--FunctionalClassesToUse> I<"FunctionalClass1,FunctionalClass2..."> This value is used during I<FunctionalClassAtomTypes> value of B<a, --AtomIdentifierType> option. It's a list of comma separated valid functional classes. Possible values for atom functional classes are: I<Ar, CA, H, HBA, HBD, Hal, NI, PI, RA>. Default value [ Ref 24 ]: I<HBD,HBA,PI,NI,Ar,Hal>. The functional class abbreviations correspond to: HBD: HydrogenBondDonor HBA: HydrogenBondAcceptor PI : PositivelyIonizable NI : NegativelyIonizable Ar : Aromatic Hal : Halogen H : Hydrophobic RA : RingAtom CA : ChainAtom Functional class atom type specification for an atom corresponds to: Ar.CA.H.HBA.HBD.Hal.NI.PI.RA I<AtomTypes::FunctionalClassAtomTypes> module is used to assign functional class atom types. It uses following definitions [ Ref 60-61, Ref 65-66 ]: HydrogenBondDonor: NH, NH2, OH HydrogenBondAcceptor: N[!H], O PositivelyIonizable: +, NH2 NegativelyIonizable: -, C(=O)OH, S(=O)OH, P(=O)OH =item B<--CompoundID> I<DataFieldName or LabelPrefixString> This value is B<--CompoundIDMode> specific and indicates how compound ID is generated. For I<DataField> value of B<--CompoundIDMode> option, it corresponds to datafield label name whose value is used as compound ID; otherwise, it's a prefix string used for generating compound IDs like LabelPrefixString<Number>. Default value, I<Cmpd>, generates compound IDs which look like Cmpd<Number>. Examples for I<DataField> value of B<--CompoundIDMode>: MolID ExtReg Examples for I<LabelPrefix> or I<MolNameOrLabelPrefix> value of B<--CompoundIDMode>: Compound The value specified above generates compound IDs which correspond to Compound<Number> instead of default value of Cmpd<Number>. =item B<--CompoundIDLabel> I<text> Specify compound ID column label for CSV/TSV text file(s) used during I<CompoundID> value of B<--DataFieldsMode> option. Default value: I<CompoundID>. =item B<--CompoundIDMode> I<DataField | MolName | LabelPrefix | MolNameOrLabelPrefix> Specify how to generate compound IDs and write to FP or CSV/TSV text file(s) along with generated fingerprints for I<FP | text | all> values of B<--output> option: use a I<SDFile(s)> datafield value; use molname line from I<SDFile(s)>; generate a sequential ID with specific prefix; use combination of both MolName and LabelPrefix with usage of LabelPrefix values for empty molname lines. Possible values: I<DataField | MolName | LabelPrefix | MolNameOrLabelPrefix>. Default value: I<LabelPrefix>. For I<MolNameAndLabelPrefix> value of B<--CompoundIDMode>, molname line in I<SDFile(s)> takes precedence over sequential compound IDs generated using I<LabelPrefix> and only empty molname values are replaced with sequential compound IDs. This is only used for I<CompoundID> value of B<--DataFieldsMode> option. =item B<--DataFields> I<"FieldLabel1,FieldLabel2,..."> Comma delimited list of I<SDFiles(s)> data fields to extract and write to CSV/TSV text file(s) along with generated fingerprints for I<text | all> values of B<--output> option. This is only used for I<Specify> value of B<--DataFieldsMode> option. Examples: Extreg MolID,CompoundName =item B<-d, --DataFieldsMode> I<All | Common | Specify | CompoundID> Specify how data fields in I<SDFile(s)> are transferred to output CSV/TSV text file(s) along with generated fingerprints for I<text | all> values of B<--output> option: transfer all SD data field; transfer SD data files common to all compounds; extract specified data fields; generate a compound ID using molname line, a compound prefix, or a combination of both. Possible values: I<All | Common | specify | CompoundID>. Default value: I<CompoundID>. =item B<-f, --Filter> I<Yes | No> Specify whether to check and filter compound data in SDFile(s). Possible values: I<Yes or No>. Default value: I<Yes>. By default, compound data is checked before calculating fingerprints and compounds containing atom data corresponding to non-element symbols or no atom data are ignored. =item B<--FingerprintsLabel> I<text> SD data label or text file column label to use for fingerprints string in output SD or CSV/TSV text file(s) specified by B<--output>. Default value: I<TopologicalAtomTorsionsFingerprints>. =item B<-h, --help> Print this help message. =item B<-k, --KeepLargestComponent> I<Yes | No> Generate fingerprints for only the largest component in molecule. Possible values: I<Yes or No>. Default value: I<Yes>. For molecules containing multiple connected components, fingerprints can be generated in two different ways: use all connected components or just the largest connected component. By default, all atoms except for the largest connected component are deleted before generation of fingerprints. =item B<--OutDelim> I<comma | tab | semicolon> Delimiter for output CSV/TSV text file(s). Possible values: I<comma, tab, or semicolon> Default value: I<comma>. =item B<--output> I<SD | FP | text | all> Type of output files to generate. Possible values: I<SD, FP, text, or all>. Default value: I<text>. =item B<-o, --overwrite> Overwrite existing files. =item B<-q, --quote> I<Yes | No> Put quote around column values in output CSV/TSV text file(s). Possible values: I<Yes or No>. Default value: I<Yes> =item B<-r, --root> I<RootName> New file name is generated using the root: <Root>.<Ext>. Default for new file names: <SDFileName><TopologicalAtomTorsionsFP>.<Ext>. The file type determines <Ext> value. The sdf, fpf, csv, and tsv <Ext> values are used for SD, FP, comma/semicolon, and tab delimited text files, respectively.This option is ignored for multiple input files. =item B<-v, --VectorStringFormat> I<IDsAndValuesString | IDsAndValuesPairsString | ValuesAndIDsString | ValuesAndIDsPairsString> Format of fingerprints vector string data in output SD, FP or CSV/TSV text file(s) specified by B<--output> option. Possible values: I<IDsAndValuesString | IDsAndValuesPairsString | ValuesAndIDsString | ValuesAndIDsPairsString>. Defaultvalue: I<IDsAndValuesString>. Examples: FingerprintsVector;TopologicalAtomTorsions:AtomicInvariantsAtomTypes;3 3;NumericalValues;IDsAndValuesString;C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4- C.X3.BO4 C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4-N.X3.BO3 C.X2.BO2.H2-C.X2.BO 2.H2-C.X3.BO3.H1-C.X2.BO2.H2 C.X2.BO2.H2-C.X2.BO2.H2-C.X3.BO3.H1-O...; 2 2 1 1 2 2 1 1 3 4 4 8 4 2 2 6 2 2 1 2 1 1 2 1 1 2 6 2 4 2 1 3 1 FingerprintsVector;TopologicalAtomTorsions:AtomicInvariantsAtomTypes;3 3;NumericalValues;IDsAndValuesPairsString;C.X1.BO1.H3-C.X3.BO3.H1-C.X3 .BO4-C.X3.BO4 2 C.X1.BO1.H3-C.X3.BO3.H1-C.X3.BO4-N.X3.BO3 2 C.X2.BO2.H 2-C.X2.BO2.H2-C.X3.BO3.H1-C.X2.BO2.H2 1 C.X2.BO2.H2-C.X2.BO2.H2-C.X3.B O3.H1-O.X1.BO1.H1 1 C.X2.BO2.H2-C.X2.BO2.H2-N.X3.BO3-C.X3.BO4 2 C.X2.B O2.H2-C.X3.BO3.H1-C.X2.BO2.H2-C.X3.BO3.H1 2 C.X2.BO2.H2-C.X3.BO3.H1... =item B<-w, --WorkingDir> I<DirName> Location of working directory. Default value: current directory. =back =head1 EXAMPLES To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesString format and create SampleTATFP.sdf, SampleTATFP.fpf and SampleTATFP.csv files containing sequential compound IDs in CSV file along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl --output all -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesPairsString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl --VectorStringFormat IDsAndValuesPairsString -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using DREIDING atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a DREIDINGAtomTypes -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using E-state atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a EStateAtomTypes -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using functional class atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a FunctionalClassAtomTypes -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using MMFF94 atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a MMFF94AtomTypes -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using SLogP atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a SLogPAtomTypes -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using SYBYL atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a SYBYLAtomTypes -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using TPSA atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a TPSAAtomTypes -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using UFF atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a UFFAtomTypes -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using only AS,X atomic invariants atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing sequential compound IDs along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a AtomicInvariantsAtomTypes --AtomicInvariantsToUse "AS,X" -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing compoundID from molecule name line along with fingerprints vector strings, type: % TopologicalAtomTorsionsFingerprints.pl -a AtomicInvariantsAtomTypes --DataFieldsMode CompoundID -CompoundIDMode MolName -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing compound IDs using specified data field along with fingerprints vector strings, type: % TopologicalAtomTorsionsFingerprints.pl -a AtomicInvariantsAtomTypes --DataFieldsMode CompoundID -CompoundIDMode DataField --CompoundID Mol_ID -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing compound ID using combination of molecule name line and an explicit compound prefix along with fingerprints vector strings data, type: % TopologicalAtomTorsionsFingerprints.pl -a AtomicInvariantsAtomTypes --DataFieldsMode CompoundID -CompoundIDMode MolnameOrLabelPrefix --CompoundID Cmpd --CompoundIDLabel MolID -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing specific data fields columns along with fingerprints vector strings, type: % TopologicalAtomTorsionsFingerprints.pl -a AtomicInvariantsAtomTypes --DataFieldsMode Specify --DataFields Mol_ID -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesString format and create a SampleTATFP.csv file containing common data fields columns along with fingerprints vector strings, type: % TopologicalAtomTorsionsFingerprints.pl -a AtomicInvariantsAtomTypes --DataFieldsMode Common -r SampleTATFP -o Sample.sdf To generate topological atom torsions fingerprints using atomic invariants atom types in IDsAndValuesString format and create SampleTATFP.sdf, SampleTATFP.fpf and SampleTATFP.csv files containing all data fields columns in CSV file along with fingerprints data, type: % TopologicalAtomTorsionsFingerprints.pl -a AtomicInvariantsAtomTypes --DataFieldsMode All --output all -r SampleTATFP -o Sample.sdf =head1 AUTHOR Manish Sud <msud@san.rr.com> =head1 SEE ALSO InfoFingerprintsFiles.pl, SimilarityMatricesFingerprints.pl, AtomNeighborhoodsFingerprints.pl, ExtendedConnectivityFingerprints.pl, MACCSKeysFingerprints.pl, PathLengthFingerprints.pl, TopologicalAtomPairsFingerprints.pl, TopologicalPharmacophoreAtomPairsFingerprints.pl, TopologicalPharmacophoreAtomTripletsFingerprints.pl =head1 COPYRIGHT Copyright (C) 2015 Manish Sud. All rights reserved. This file is part of MayaChemTools. MayaChemTools is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. =cut