// print our statistics void CMosaikAligner::PrintStatistics () { MosaikReadFormat::CReadReader in; string inputReadArchiveFilename = mSettings.InputReadArchiveFilename; in.Open(inputReadArchiveFilename); const uint64_t numReadArchiveReads = in.GetNumReads(); ReadStatus readStatus = in.GetStatus(); const bool isPairedEnd = (readStatus == RS_PAIRED_END_READ ? true : false); const uint64_t totalMates = isPairedEnd ? numReadArchiveReads * 2 : numReadArchiveReads; if ( mFlags.UseLowMemory ) { mStatisticsCounters.ShortMates = 0; mStatisticsCounters.FailedHashMates = 0; mStatisticsCounters.UnalignedReads = numReadArchiveReads - mStatisticsCounters.AlignedReads; mStatisticsCounters.FilteredOutMates = mStatisticsCounters.UnalignedReads; } const uint64_t totalAlignedMates = mStatisticsCounters.UniqueMates + mStatisticsCounters.NonUniqueMates; const uint64_t totalAlignedReads = mStatisticsCounters.AlignedReads; // print our alignment statistics (mates) if don't enable low-memory algorithm printf("\n"); CConsole::Heading(); printf("Alignment statistics (mates):\n"); CConsole::Reset(); printf("===================================\n"); if(mStatisticsCounters.ShortMates > 0) printf("# too short: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.ShortMates, (mStatisticsCounters.ShortMates / (double)totalMates) * 100.0); if(mStatisticsCounters.FailedHashMates > 0) printf("# failed hash: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.FailedHashMates, (mStatisticsCounters.FailedHashMates / (double)totalMates) * 100.0); if(mStatisticsCounters.FilteredOutMates > 0) printf("# filtered out: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.FilteredOutMates, (mStatisticsCounters.FilteredOutMates / (double)totalMates) * 100.0); if(mStatisticsCounters.UniqueMates > 0) printf("# unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.UniqueMates, (mStatisticsCounters.UniqueMates / (double)totalMates) * 100.0); if(mStatisticsCounters.NonUniqueMates > 0) printf("# non-unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.NonUniqueMates, (mStatisticsCounters.NonUniqueMates / (double)totalMates) * 100.0); printf("-----------------------------------\n"); printf("total: %9llu\n", (unsigned long long)totalMates); printf("total aligned: "); CConsole::Bold(); printf("%9llu", (unsigned long long)totalAlignedMates); CConsole::Reset(); printf(" ("); CConsole::Bold(); printf("%5.1f %%", (totalAlignedMates / (double)totalMates) * 100.0); CConsole::Reset(); printf(")\n"); // print our local alignment search statistics // we don't print out local alignment information when the low-memory approach is enabled. if( !mFlags.UseLowMemory && mFlags.UseLocalAlignmentSearch ) { printf("\n"); CConsole::Heading(); printf("Local alignment search statistics:\n"); CConsole::Reset(); printf("===================================\n"); double rescuedAlignmentsPercent = mStatisticsCounters.AdditionalLocalMates / (double)totalMates * 100.0; printf("rescued mates: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.AdditionalLocalMates, rescuedAlignmentsPercent); } // print our alignment statistics (reads) if(isPairedEnd) { printf("\n"); CConsole::Heading(); printf("Alignment statistics (reads):\n"); CConsole::Reset(); printf("============================================\n"); printf("# unaligned: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.UnalignedReads, (mStatisticsCounters.UnalignedReads / (double)numReadArchiveReads) * 100.0); printf("# orphaned: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.OrphanedReads, (mStatisticsCounters.OrphanedReads / (double)numReadArchiveReads) * 100.0); printf("# both mates unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.BothUniqueReads, (mStatisticsCounters.BothUniqueReads / (double)numReadArchiveReads) * 100.0); printf("# one mate non-unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.OneNonUniqueReads, (mStatisticsCounters.OneNonUniqueReads / (double)numReadArchiveReads) * 100.0); printf("# both mates non-unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.BothNonUniqueReads, (mStatisticsCounters.BothNonUniqueReads / (double)numReadArchiveReads) * 100.0); printf("--------------------------------------------\n"); printf("total reads: "); CConsole::Bold(); printf("%9llu", (unsigned long long)numReadArchiveReads); CConsole::Reset(); printf("\n"); printf("total reads aligned: "); CConsole::Bold(); printf("%9llu", (unsigned long long)totalAlignedReads); CConsole::Reset(); printf(" ("); CConsole::Bold(); printf("%5.1f %%", (totalAlignedReads / (double)numReadArchiveReads) * 100.0); CConsole::Reset(); printf(")\n"); } // print our jump cache statistics if( !mFlags.UseLowMemory && mFlags.IsUsingJumpDB && (mSettings.NumCachedHashes > 0)) { printf("\n"); CConsole::Heading(); printf("Jump database cache statistics:\n"); CConsole::Reset(); printf("====================================\n"); uint64_t cacheHits = 0, cacheMisses = 0, cacheTotal = 0; CJumpDnaHash* pJump = (CJumpDnaHash*)mpDNAHash; pJump->GetCacheStatistics(cacheHits, cacheMisses); cacheTotal = cacheHits + cacheMisses; double cacheHitsPercent = cacheHits / (double)cacheTotal * 100.0; printf("cache hits: %10llu (%5.1f %%)\n", (unsigned long long)cacheHits, cacheHitsPercent); printf("cache misses: %10llu\n", (unsigned long long)cacheMisses); } //if ( !mFlags.UseLowMemory ) { // printf("\n"); // CConsole::Heading(); printf("Miscellaneous statistics:\n"); CConsole::Reset(); // printf("==================================\n"); // printf("aligned mate bp: %10llu\n", (unsigned long long)mStatisticsCounters.MateBasesAligned); // printf("alignment candidates/s: %10.1f\n", mStatisticsCounters.AlignmentCandidates / alignmentBench.GetElapsedWallTime()); //} }
int main(int argc, char* argv[]) { // set srand srand(1); CConsole::Initialize(); ConfigurationSettings settings; string commandLine; for ( int i = 0; i < argc; ++i ) commandLine = commandLine + argv[i] + " "; printf("------------------------------------------------------------------------------\n"); printf("Mosaik"); CConsole::Red(); printf("Aligner"); CConsole::Reset(); printf(" %u.%u.%u %s\n", MOSAIK_MAJOR_VERSION, MOSAIK_MINOR_VERSION, MOSAIK_BUILD_VERSION, MOSAIK_VERSION_DATE); printf("Michael Stromberg & Wan-Ping Lee Marth Lab, Boston College Biology Department\n"); printf("------------------------------------------------------------------------------\n\n"); // ================================= // configure the command line parser // ================================= // set general info about the program COptions::SetProgramInfo("MosaikAligner", "pairwise aligns a MOSAIK read file", "-in <filename> -out <filename> -ia <filename>"); // add the input/output options OptionGroup* pIoOpts = COptions::CreateOptionGroup("Input/output: (required)"); COptions::AddValueOption("-ia", "MOSAIK reference filename", "the input reference file", "An input MOSAIK reference file", settings.HasReferencesFilename, settings.ReferencesFilename, pIoOpts); COptions::AddValueOption("-in", "MOSAIK read filename", "the input read file", "An input MOSAIK read file", settings.HasReadsFilename, settings.ReadsFilename, pIoOpts); COptions::AddValueOption("-out", "MOSAIK alignment filename", "the output alignment file", "An output MOSAIK alignment file", settings.HasAlignmentsFilename, settings.AlignmentsFilename, pIoOpts); COptions::AddValueOption("-ibs", "MOSAIK reference filename", "enables colorspace to basespace conversion using the supplied BASESPACE reference archive", "", settings.HasBasespaceReferencesFilename, settings.BasespaceReferencesFilename, pIoOpts); COptions::AddValueOption("-annpe", "Neural network filename", "", "", settings.HasPeNeuralNetworkFilename, settings.PeNeuralNetworkFilename, pIoOpts); COptions::AddValueOption("-annse", "Neural network filename", "", "", settings.HasSeNeuralNetworkFilename, settings.SeNeuralNetworkFilename, pIoOpts); // add the essential options OptionGroup* pEssentialOpts = COptions::CreateOptionGroup("Essential parameters"); COptions::AddValueOption("-a", "algorithm", "alignment algorithm: [fast, single, multi, all]", "", settings.HasAlgorithm, settings.Algorithm, pEssentialOpts, DEFAULT_ALGORITHM); COptions::AddValueOption("-m", "mode", "alignment mode: [unique, all]", "", settings.HasMode, settings.Mode, pEssentialOpts, DEFAULT_MODE); COptions::AddValueOption("-hs", "hash size", "hash size [4 - 32]", "", settings.HasHashSize, settings.HashSize, pEssentialOpts, DEFAULT_HASH_SIZE); // add the filtering options OptionGroup* pFilterOpts = COptions::CreateOptionGroup("Filtering"); COptions::AddValueOption("-act", "threshold", "the alignment candidate threshold (length)", "", settings.EnableAlignmentCandidateThreshold, settings.AlignmentCandidateThreshold, pFilterOpts); //COptions::AddOption("-dh", "require at least two hash hits", settings.EnableDoubleHashHits, pFilterOpts); COptions::AddValueOption("-ls", "radius", "enable local alignment search for PE reads", "", settings.HasLocalAlignmentSearchRadius, settings.LocalAlignmentSearchRadius, pFilterOpts); //COptions::AddValueOption("-lsh", "mapping quality", "MQ threshold", "", settings.HasLocalAlignmentSearchHighMqThreshold, settings.LocalAlignmentSearchHighMqThreshold, pFilterOpts ); //COptions::AddValueOption("-lsl", "mapping quality", "MQ threshold; when the best MQ is higher than -lsh and the second best is lower than -lsl, local alignment search is enabled.", "", settings.HasLocalAlignmentSearchLowMqThreshold, settings.LocalAlignmentSearchLowMqThreshold, pFilterOpts ); COptions::AddValueOption("-mhp", "hash positions", "the maximum # of positions stored per seed", "", settings.LimitHashPositions, settings.HashPositionThreshold, pFilterOpts); COptions::AddValueOption("-mhr", "hash regionss", "the maximum # of regions for aligning", "", settings.LimitHashRegions, settings.HashRegionThreshold, pFilterOpts); COptions::AddValueOption("-min", "nucleotides", "the minimum # of aligned nucleotides", "", settings.CheckMinAlignment, settings.MinimumAlignment, pFilterOpts); COptions::AddValueOption("-minp", "percent", "the minimum alignment percentage [0.0 - 1.0]", "", settings.CheckMinAlignmentPercent, settings.MinimumAlignmentPercentage, pFilterOpts); COptions::AddValueOption("-mm", "mismatches", "the # of mismatches allowed", "", settings.CheckNumMismatches, settings.NumMismatches, pFilterOpts); COptions::AddValueOption("-mmp", "threshold", "the percentage of mismatches allowed [0.0 - 1.0]", "", settings.CheckMismatchPercent, settings.MismatchPercent, pFilterOpts); COptions::AddOption( "-ncg", "not count gaps as mismatches", settings.NotCountGapAsMismatch, pFilterOpts); //COptions::AddOption("-mmal", "when enabled, unaligned portions of the read will not count as a mismatch", settings.UseAlignedLengthForMismatches, pFilterOpts); // TODO: we need to move the alignment quality calculation up to ApplyReadFilters in order to make this option useable //COptions::AddValueOption("-aq", "threshold", "enable an alignment quality threshold", "", settings.CheckAlignmentQuality, settings.AlignmentQualityThreshold, pFilterOpts); // add the performance options OptionGroup* pPerformanceOpts = COptions::CreateOptionGroup("Performance"); COptions::AddValueOption("-p", "processors", "uses the specified number of processors", "", settings.HasNumThreads, settings.NumThreads, pPerformanceOpts); COptions::AddValueOption("-bw", "bandwidth", "specifies the Smith-Waterman bandwidth", "", settings.HasBandwidth, settings.Bandwidth, pPerformanceOpts, DEFAULT_BANDWIDTH); COptions::AddOption("-lm", "enable low-memory functions", settings.UseLowMemory, pPerformanceOpts); // add the jump database options OptionGroup* pJumpOpts = COptions::CreateOptionGroup("Jump database"); COptions::AddValueOption("-j", "filename stub", "uses the specified jump database", "", settings.UseJumpDB, settings.JumpFilenameStub, pJumpOpts); //COptions::AddValueOption("-jc", "# of hashes", "caches the most recently used hashes", "", settings.HasJumpCacheMemory, settings.JumpCacheMemory, pJumpOpts); COptions::AddOption("-kd", "keeps the keys file on disk", settings.KeepJumpKeysOnDisk, pJumpOpts); COptions::AddOption("-pd", "keeps the positions file on disk", settings.KeepJumpPositionsOnDisk, pJumpOpts); COptions::AddValueOption("-sref", "reference prefixes", "specifies the prefixes of special references", "", settings.HasSpecialReferencePrefix, settings.SpecialReferencePrefix, pJumpOpts); COptions::AddValueOption("-srefn", "hashes", "the maximum special hashes", "", settings.HasSpecialHashCount, settings.SpecialHashCount, pJumpOpts); // add the reporting options OptionGroup* pReportingOpts = COptions::CreateOptionGroup("Reporting"); COptions::AddValueOption("-statmq", "threshold", "enable mapping quality threshold for statistical map [0 - 255]", "", settings.HasStatMappingQuality, settings.StatMappingQuality, pReportingOpts); COptions::AddOption("-omi", "output chrmosome ids and positions of multiply mapped alignments in the multiple.bam", settings.OutputMultiplyIncomplete, pReportingOpts); COptions::AddOption("-om", "output complete multiply mapped alignments in the multiple.bam", settings.OutputMultiplyComplete, pReportingOpts); COptions::AddOption("-zn", "output zn tags",settings.EnableZnTag, pReportingOpts); //COptions::AddValueOption("-rur", "FASTQ filename", "stores unaligned reads in a FASTQ file", "", settings.RecordUnalignedReads, settings.UnalignedReadsFilename, pReportingOpts); // add the pairwise alignment scoring options OptionGroup* pPairwiseOpts = COptions::CreateOptionGroup("Pairwise Alignment Scores"); COptions::AddValueOption("-ms", "match score", "the match score", "", settings.HasMatchScore, settings.MatchScore, pPairwiseOpts, CPairwiseUtilities::MatchScore); COptions::AddValueOption("-mms", "mismatch score", "the mismatch score", "", settings.HasMismatchScore, settings.MismatchScore, pPairwiseOpts, CPairwiseUtilities::MismatchScore); COptions::AddValueOption("-gop", "gap open penalty", "the gap open penalty", "", settings.HasGapOpenPenalty, settings.GapOpenPenalty, pPairwiseOpts, CPairwiseUtilities::GapOpenPenalty); COptions::AddValueOption("-gep", "gap extend penalty", "the gap extend penalty", "", settings.HasGapExtendPenalty, settings.GapExtendPenalty, pPairwiseOpts, CPairwiseUtilities::GapExtendPenalty); COptions::AddValueOption("-hgop", "gap open penalty", "enables the homopolymer gop", "", settings.HasHomoPolymerGapOpenPenalty, settings.HomoPolymerGapOpenPenalty, pPairwiseOpts, CPairwiseUtilities::HomoPolymerGapOpenPenalty); // add interface options OptionGroup* pInterface = COptions::CreateOptionGroup("Interface Options"); COptions::AddOption("-quiet", "disable progress bars and counters", settings.IsQuietMode, pInterface); // parse the current command line COptions::Parse(argc, argv); // ============================= // check for missing information // ============================= bool foundError = false; ostringstream errorBuilder; const string ERROR_SPACER(7, ' '); //if(settings.EnableAlignmentCandidateThreshold && settings.EnableDoubleHashHits) { // errorBuilder << ERROR_SPACER << "Please specify either an alignment candidate threshold (-act) or double-hash hits (-dh). Double-hash hits are equivalent to '-act <hash size + 1>." << endl; // foundError = true; //} if((settings.HasJumpCacheMemory || settings.KeepJumpKeysOnDisk || settings.KeepJumpPositionsOnDisk) && !settings.UseJumpDB) { errorBuilder << ERROR_SPACER << "Jump database settings were specified, but the jump database was not explicitly chosen. Please use the -j parameter." << endl; foundError = true; } if(settings.UseJumpDB) { string keysFilename = settings.JumpFilenameStub + "_keys.jmp"; string metaFilename = settings.JumpFilenameStub + "_meta.jmp"; string positionsFilename = settings.JumpFilenameStub + "_positions.jmp"; CFileUtilities::CheckFile(keysFilename.c_str(), true); CFileUtilities::CheckFile(metaFilename.c_str(), true); CFileUtilities::CheckFile(positionsFilename.c_str(), true); if(!settings.KeepJumpKeysOnDisk && !settings.KeepJumpPositionsOnDisk && settings.HasJumpCacheMemory) settings.HasJumpCacheMemory = false; } if(!settings.CheckNumMismatches && !settings.CheckMismatchPercent ) { //settings.CheckNumMismatches = true; settings.CheckMismatchPercent = true; } // figure out which algorithm to use CSequenceUtilities::LowercaseSequence(settings.Algorithm); CAlignmentThread::AlignerAlgorithmType algorithmType = CAlignmentThread::AlignerAlgorithm_ALL; if(settings.Algorithm == "fast") algorithmType = CAlignmentThread::AlignerAlgorithm_FAST; else if(settings.Algorithm == "single") algorithmType = CAlignmentThread::AlignerAlgorithm_SINGLE; else if(settings.Algorithm == "multi") algorithmType = CAlignmentThread::AlignerAlgorithm_MULTI; else if(settings.Algorithm == "all") algorithmType = CAlignmentThread::AlignerAlgorithm_ALL; else { errorBuilder << ERROR_SPACER << "Unknown algorithm type. Please choose between 'fast', 'single', 'multi', or 'all'. The default value is '" << DEFAULT_ALGORITHM << "'." << endl; foundError = true; } // set the hash positions threshold if ( ( settings.LimitHashPositions ) && ( settings.HashPositionThreshold == 0 ) ) settings.LimitHashPositions = false; if ( settings.LimitHashPositions ) { // make sure we're using the all algorithm if ( algorithmType != CAlignmentThread::AlignerAlgorithm_ALL ) { errorBuilder << ERROR_SPACER << "Setting the hash positions threshold is only applicable when using the 'all' algorithm. This can be set by using the '-a all' parameter. Or turn off the hash positions threshold by using '-mhp 0'" << endl; foundError = true; } // won't be the case //if ( settings.HashPositionThreshold == 0 ) { // errorBuilder << ERROR_SPACER << "The hash position threshold should be larger than 0. Use the -mhp parameter to change the hash position threshold." << endl; // foundError = true; //} } if ( settings.LimitHashRegions ) { if ( settings.HashRegionThreshold == 0 ) { errorBuilder << ERROR_SPACER << "The hash region threshold should be larger than 0. Use the -mhr parameter to change the hash position threshold." << endl; foundError = true; } } // figure out which alignment mode to use CSequenceUtilities::LowercaseSequence(settings.Algorithm); CAlignmentThread::AlignerModeType modeType = CAlignmentThread::AlignerMode_ALL; if(settings.Mode == "unique") modeType = CAlignmentThread::AlignerMode_UNIQUE; else if(settings.Mode == "all") modeType = CAlignmentThread::AlignerMode_ALL; else { errorBuilder << ERROR_SPACER << "Unknown mode type. Please choose between 'unique' or 'all'. The default value is '" << DEFAULT_MODE << "'." << endl; foundError = true; } // set the maximum mismatch percentage if(settings.CheckMismatchPercent) { // make sure our value is within bounds if((settings.MismatchPercent < 0.0) || (settings.MismatchPercent > 1.0)) { errorBuilder << ERROR_SPACER << "The maximum mismatch percentage should be between 0.0 and 1.0." << endl; foundError = true; } CPairwiseUtilities::MaxMismatchPercent = settings.MismatchPercent; CPairwiseUtilities::UseMismatchPercentFilter = true; } // set the minimum aligned percentage if(settings.CheckMinAlignmentPercent) { // make sure our value is within bounds if((settings.MinimumAlignmentPercentage < 0.0) || (settings.MinimumAlignmentPercentage > 1.0)) { errorBuilder << ERROR_SPACER << "The minimum alignment percentage should be between 0.0 and 1.0." << endl; foundError = true; } // assign the minimum percentage alignment CPairwiseUtilities::MinPercentAlignment = settings.MinimumAlignmentPercentage; CPairwiseUtilities::UseMinAlignmentPercentFilter = true; } // check the minimum alignment quality //if(settings.CheckAlignmentQuality && (settings.AlignmentQualityThreshold > 99)) { // errorBuilder << ERROR_SPACER << "The alignment quality threshold should be between 0 and 99." << endl; // foundError = true; //} // set the hash size if(settings.HasHashSize && ((settings.HashSize < MIN_HASH_SIZE) || (settings.HashSize > MAX_HASH_SIZE))) { errorBuilder << ERROR_SPACER << "The hash size should be between " << MIN_HASH_SIZE << " and " << MAX_HASH_SIZE << ". The default value is " << DEFAULT_HASH_SIZE << "." << endl; foundError = true; } // set the number of threads if(settings.HasNumThreads && (settings.NumThreads < 1)) { errorBuilder << ERROR_SPACER << "At least one processor should be specified. Use the -p parameter to change the number of desired processors." << endl; foundError = true; } // test if the specified input files exist and are in the right format SequencingTechnologies seqTech; ReadStatus readStatus; MosaikReadFormat::CReadReader::CheckFile(settings.ReadsFilename, seqTech, readStatus, true); MosaikReadFormat::CReferenceSequenceReader::CheckFile(settings.ReferencesFilename, true); // set defaults of act, ls and bw { MosaikReadFormat::CReadReader reader; reader.Open( settings.ReadsFilename ); uint64_t nReads, nBases; nReads = reader.GetNumReads(); nBases = reader.GetNumBases(); // sanity checker if ( nBases < nReads ) errorBuilder << ERROR_SPACER << "The number of reads is smaller than the number of total bases in " << settings.ReadsFilename; double readLength = nBases/nReads; if ( ( readStatus & RS_PAIRED_END_READ ) != 0 ) readLength /= 2; // act if ( settings.EnableAlignmentCandidateThreshold ) { if ( settings.AlignmentCandidateThreshold == 0 ) { settings.EnableAlignmentCandidateThreshold = false; settings.AlignmentCandidateThreshold = 0; } } else { if ( seqTech == ST_454 ) { settings.EnableAlignmentCandidateThreshold = true; settings.AlignmentCandidateThreshold = ( readLength > 350.0 ) ? 55 : 26; } else { settings.EnableAlignmentCandidateThreshold = true; settings.AlignmentCandidateThreshold = (unsigned char)floor( 13 + ( readLength / 5 ) ); } } // bw if ( settings.HasBandwidth ) { if ( settings.Bandwidth == 0 ) { settings.HasBandwidth = false; settings.Bandwidth = 0; } } else { if ( settings.CheckNumMismatches ) { settings.HasBandwidth = true; settings.Bandwidth = static_cast<unsigned int>(ceil( 2.5 * settings.NumMismatches )); if ( ( settings.Bandwidth % 2 ) != 1 ) ++settings.Bandwidth; } else if ( settings.CheckMismatchPercent ) { settings.HasBandwidth = true; settings.Bandwidth = static_cast<unsigned int>(ceil( 2.5 * settings.MismatchPercent * ceil(readLength) )); if ( ( settings.Bandwidth % 2 ) != 1 ) ++settings.Bandwidth; } else { settings.HasBandwidth = false; settings.Bandwidth = 0; } } // ls // only for paired-end data and the -mfl setting in the given archive != 0 MosaikReadFormat::ReadGroup readGroup = reader.GetReadGroup(); if ( settings.HasLocalAlignmentSearchRadius ) { if ( settings.LocalAlignmentSearchRadius == 0 ) { settings.HasLocalAlignmentSearchRadius = false; settings.LocalAlignmentSearchRadius = 0; } else { if ( ( readStatus & RS_PAIRED_END_READ ) == 0 ) { cout << "WARNING: Local alignment search only works for paired-end data." << endl; settings.HasLocalAlignmentSearchRadius = false; settings.LocalAlignmentSearchRadius = 0; } } } else { if ( ( readStatus & RS_PAIRED_END_READ ) != 0 ) { if ( readGroup.MedianFragmentLength == 0 ) { cout << "WARNING: Paired-end data is detected, but the median fragment length is not specified." << endl; cout << " Accordingly, local alignment search is not enabled." << endl; cout << " The median fragment length (-mfl parameter) can be specified in MosaikBuild.\n" << endl; } else { settings.HasLocalAlignmentSearchRadius = true; settings.LocalAlignmentSearchRadius = readGroup.MedianFragmentLength; } } } if ( !settings.HasLocalAlignmentSearchRadius && settings.HasLocalAlignmentSearchHighMqThreshold ) cout << "WARNING: -lsh is enabled but -ls is not." << endl; if ( !settings.HasLocalAlignmentSearchRadius && settings.HasLocalAlignmentSearchLowMqThreshold ) cout << "WARNING: -lsl is enabled but -ls is not." << endl; if ( settings.HasLocalAlignmentSearchHighMqThreshold || settings.HasLocalAlignmentSearchLowMqThreshold ) { if ( settings.LocalAlignmentSearchLowMqThreshold > settings.LocalAlignmentSearchHighMqThreshold ) { errorBuilder << ERROR_SPACER << "The high MQ threshold (-lsh) must be larger than low MQ threshold (-lsl)." << endl; foundError = true; } } // Note: These two statements are always tru //if (settings.LocalAlignmentSearchHighMqThreshold > 255) { // errorBuilder << ERROR_SPACER << "The range of high MQ threshold (-lsh) is 0-255." << endl; // foundError = true; //} //if ( settings.LocalAlignmentSearchLowMqThreshold > 255 ) { // errorBuilder << ERROR_SPACER << "The range of low MQ threshold (-lsl) is 0-255." << endl; // foundError = true; //} reader.Close(); } // set the Smith-Waterman bandwidth if ( settings.HasBandwidth && ( ( settings.Bandwidth % 2 ) != 1 ) ) { errorBuilder << ERROR_SPACER << "The bandwidth must be an odd number. Use the -bw parameter to change the bandwidth." << endl; foundError = true; } switch(seqTech) { case ST_454: if(!settings.HasHomoPolymerGapOpenPenalty) { CPairwiseUtilities::UseHomoPolymerGapOpenPenalty = true; settings.HasHomoPolymerGapOpenPenalty = true; settings.HomoPolymerGapOpenPenalty = CPairwiseUtilities::HomoPolymerGapOpenPenalty; } break; case ST_SOLID: settings.EnableColorspace = true; break; } // check if we have a supplied basespace reference archive when aligning a SOLiD read archive if(seqTech == ST_SOLID) { // force -ibs to be basespace and -ia to be colorspace if aligning SOLiD reads if(settings.HasBasespaceReferencesFilename && settings.HasReferencesFilename) { MosaikReadFormat::CReferenceSequenceReader csRef, bsRef; // retrieve the colorspace status csRef.Open(settings.ReferencesFilename); ReferenceSequenceStatus csStatus = csRef.GetStatus(); csRef.Close(); // retrieve the basespace status bsRef.Open(settings.BasespaceReferencesFilename); ReferenceSequenceStatus bsStatus = bsRef.GetStatus(); bsRef.Close(); if(csStatus != REF_COLORSPACE) { errorBuilder << ERROR_SPACER << "Expected to find a colorspace reference sequence archive (" << settings.ReferencesFilename << ") with the -ia parameter, but found a basespace reference sequence archive." << endl; foundError = true; } if(bsStatus != REF_UNKNOWN) { errorBuilder << ERROR_SPACER << "Expected to find a basespace reference sequence archive (" << settings.BasespaceReferencesFilename << ") with the -ibs parameter, but found a colorspace reference sequence archive." << endl; foundError = true; } } if(!settings.HasBasespaceReferencesFilename) { errorBuilder << ERROR_SPACER << "When aligning SOLiD read archives, both a colorspace reference archive AND a basespace reference archive are required. Use the -ibs parameter to supply the basespace reference archive filename." << endl; foundError = true; } //if( settings.UseLowMemory ) { // errorBuilder << ERROR_SPACER << "The low-memory algorithm does not support for SOLiD reads yet." << endl; // foundError = true; //} } // files for neural network for mapping quality calculation if (!settings.HasPeNeuralNetworkFilename) { errorBuilder << ERROR_SPACER << "An input paired-end neural-network file was not specified. Please use the -annpe parameter." << endl << ERROR_SPACER << " The file is on src/networkFile/2.1.26.pe.100.0065.ann." << endl; foundError = true; } else { // test the exietence of the file // doesn't show error message CFileUtilities::CheckFile(settings.PeNeuralNetworkFilename.c_str(), true); } if (!settings.HasSeNeuralNetworkFilename) { errorBuilder << ERROR_SPACER << "An input single-end neural-network file was not specified. Please use the -annse parameter." << endl << ERROR_SPACER << " The file is on src/networkFile/2.1.26.se.100.005.ann." << endl; foundError = true; } else { // test the exietence of the file CFileUtilities::CheckFile(settings.SeNeuralNetworkFilename.c_str(), true); } if (settings.OutputMultiplyIncomplete && settings.OutputMultiplyComplete) { foundError = true; errorBuilder << ERROR_SPACER << "-omi and -om are incompatible." << endl; } // print the errors if any were found if(foundError) { CConsole::Red(); printf("ERROR: Some problems were encountered when parsing the command line options:\n"); CConsole::Reset(); printf("%s\n", errorBuilder.str().c_str()); printf("For a complete list of command line options, type \"%s -h\"\n", argv[0]); exit(1); } // =================================================== // Parse configuration strings and set class variables // =================================================== // set the minimum alignment quality //if(settings.CheckAlignmentQuality) { // CPairwiseUtilities::MinAlignmentQuality = settings.AlignmentQualityThreshold; // CPairwiseUtilities::UseMinAlignmentQualityFilter = true; //} // set the maximum number of mismatches if(settings.CheckNumMismatches) { CPairwiseUtilities::MaxNumMismatches = settings.NumMismatches; CPairwiseUtilities::UseMismatchFilter = true; } // set the minimum number of aligned nucleotides if(settings.CheckMinAlignment) { CPairwiseUtilities::MinAlignment = settings.MinimumAlignment; CPairwiseUtilities::UseMinAlignmentFilter = true; } // set the Smith-Waterman scores if(settings.HasMatchScore || settings.HasMismatchScore || settings.HasGapOpenPenalty || settings.HasGapExtendPenalty) { if(settings.HasMatchScore) CPairwiseUtilities::MatchScore = settings.MatchScore; if(settings.HasMismatchScore) CPairwiseUtilities::MismatchScore = settings.MismatchScore; if(settings.HasGapOpenPenalty) CPairwiseUtilities::GapOpenPenalty = settings.GapOpenPenalty; if(settings.HasGapExtendPenalty) CPairwiseUtilities::GapExtendPenalty = settings.GapExtendPenalty; } // set the Smith-Waterman h**o-polymer gap open penalty if(settings.HasHomoPolymerGapOpenPenalty) { CPairwiseUtilities::HomoPolymerGapOpenPenalty = settings.HomoPolymerGapOpenPenalty; CPairwiseUtilities::UseHomoPolymerGapOpenPenalty = true; } // show warning message about unique alignments if(((readStatus & RS_PAIRED_END_READ) != 0) && (modeType != CAlignmentThread::AlignerMode_ALL)) { cout << "WARNING: A paired-end read archive was detected and the aligner mode (-m parameter) was not set to 'all'. Paired-end resolution in MosaikSort will be limited to unique vs unique reads.\n" << endl << endl; } // show warning messages dealing with the local alignment search radius if(settings.HasLocalAlignmentSearchRadius) { // show the warning message if we have a SE read archive if( ( readStatus & RS_SINGLE_END_READ ) != 0 ) { cout << "WARNING: A single-end read archive was detected and the local alignment search was enabled. Local alignment search only works with paired-end reads.\n" << endl << endl; settings.HasLocalAlignmentSearchRadius = false; } else { // show the warning message if we have a PE read archive with no mean fragment length MosaikReadFormat::CReadReader in; in.Open(settings.ReadsFilename); MosaikReadFormat::ReadGroup readGroup = in.GetReadGroup(); in.Close(); if( readGroup.MedianFragmentLength == 0 ) { cout << "WARNING: Local alignment search only works when the median fragment length (-mfl parameter) has been specified in MosaikBuild.\n" << endl << endl; settings.HasLocalAlignmentSearchRadius = false; } } } // show warning message about using the local alignment search with SE read archives if(((readStatus & RS_SINGLE_END_READ) != 0) && settings.HasLocalAlignmentSearchRadius) { cout << "WARNING: A single-end read archive was detected and the local alignment search was enabled. Local alignment search only works with paired-end reads.\n" << endl << endl; settings.HasLocalAlignmentSearchRadius = false; } // start benchmarking CBenchmark bench; bench.Start(); // create our aligner CMosaikAligner ma(settings.HashSize, algorithmType, modeType, settings.NumThreads, commandLine ); // =============== // enable features // =============== // set zn tag reporting if (settings.EnableZnTag) ma.EnableZnTag(); // set neural network filename if (settings.HasPeNeuralNetworkFilename) ma.SetPeNeuralNetworkFilename(settings.PeNeuralNetworkFilename); if (settings.HasSeNeuralNetworkFilename) ma.SetSeNeuralNetworkFilename(settings.SeNeuralNetworkFilename); // output multiply mapped alignments ma.OutputMultiply(settings.OutputMultiplyIncomplete, settings.OutputMultiplyComplete); // enable quiet mode if (settings.IsQuietMode) ma.SetQuietMode(); // enable the hash positions threshold if(settings.LimitHashPositions) ma.EnableHashPositionThreshold(settings.HashPositionThreshold); // enable the hash region threshold if(settings.LimitHashRegions) ma.EnableHashRegionThreshold(settings.HashRegionThreshold); // enable the alignment candidate threshold if(settings.EnableAlignmentCandidateThreshold) ma.EnableAlignmentCandidateThreshold(settings.AlignmentCandidateThreshold); // enable unaligned read reporting if specified //if(settings.RecordUnalignedReads) ma.EnableUnalignedReadReporting(settings.UnalignedReadsFilename); // enable colorspace (SOLiD) if(settings.EnableColorspace) ma.EnableColorspace(settings.BasespaceReferencesFilename); // enable double-hash hits //if(settings.EnableDoubleHashHits) ma.EnableAlignmentCandidateThreshold(settings.HashSize + 1); // enable entire read length mismatch checking if(settings.UseAlignedLengthForMismatches) ma.UseAlignedReadLengthForMismatchCalculation(); // enable the jump database if(settings.UseJumpDB) ma.EnableJumpDB(settings.JumpFilenameStub, settings.JumpCacheMemory, !settings.KeepJumpKeysOnDisk, !settings.KeepJumpPositionsOnDisk); // enable the local alignment search if(settings.HasLocalAlignmentSearchRadius) ma.EnableLocalAlignmentSearch(settings.LocalAlignmentSearchRadius); // set the Smith-Waterman bandwidth if(settings.HasBandwidth) ma.EnableBandedSmithWaterman(settings.Bandwidth); // enable low-memory algorithm if(settings.UseLowMemory) ma.EnableLowMemory(); // not count gasp as mismatches if(settings.NotCountGapAsMismatch) ma.NotCountGapAsMismatch(); // enables special references checker if(settings.HasSpecialReferencePrefix) { ma.EnableSpecialReference(settings.SpecialReferencePrefix); if ( settings.HasSpecialHashCount ) ma.SetSpecialHashCount(settings.SpecialHashCount); else ma.SetSpecialHashCount(DEFAULT_SPECIAL_HASHES); } // set the trigger condition of local search if ( settings.HasLocalAlignmentSearchHighMqThreshold || settings.HasLocalAlignmentSearchLowMqThreshold ) ma.SetLocalAlignmentSearchMqThreshold ( settings.LocalAlignmentSearchHighMqThreshold, settings.LocalAlignmentSearchLowMqThreshold ); // set the mapping quality threshold for stat map if ( settings.HasStatMappingQuality ) ma.SetStatMappingQuality( settings.StatMappingQuality ); // ============= // set filenames // ============= ma.SetFilenames(settings.ReadsFilename, settings.AlignmentsFilename, settings.ReferencesFilename); // ==================== // echo enabled options // ==================== cout << "- Using the following alignment algorithm: "; switch(algorithmType) { case CAlignmentThread::AlignerAlgorithm_FAST: cout << "single position (fast)" << endl; break; case CAlignmentThread::AlignerAlgorithm_SINGLE: cout << "single position" << endl; break; case CAlignmentThread::AlignerAlgorithm_MULTI: cout << "multiple position" << endl; break; case CAlignmentThread::AlignerAlgorithm_ALL: cout << "all positions" << endl; break; default: cout << "ERROR: Unknown alignment algorithm specified." << endl; exit(1); break; } cout << "- Using the following alignment mode: "; switch(modeType) { case CAlignmentThread::AlignerMode_ALL: cout << "aligning reads to all possible locations" << endl; break; case CAlignmentThread::AlignerMode_UNIQUE: cout << "only aligning unique reads" << endl; break; default: cout << "ERROR: Unknown alignment mode specified." << endl; exit(1); break; } //if(settings.CheckAlignmentQuality) cout << "- Using an alignment quality threshold of " << CPairwiseUtilities::MinAlignmentQuality << endl; if(settings.CheckNumMismatches) cout << "- Using a maximum mismatch threshold of " << CPairwiseUtilities::MaxNumMismatches << endl; if(settings.CheckMismatchPercent) cout << "- Using a maximum mismatch percent threshold of " << CPairwiseUtilities::MaxMismatchPercent << endl; if(settings.CheckMinAlignment) cout << "- Using a minimum alignment threshold of " << CPairwiseUtilities::MinAlignment << endl; if(settings.CheckMinAlignmentPercent) cout << "- Using a minimum percent alignment threshold of " << CPairwiseUtilities::MinPercentAlignment << endl; if(settings.HasHashSize) cout << "- Using a hash size of " << (unsigned int)settings.HashSize << endl; //if(settings.EnableDoubleHashHits) cout << "- Using double-hash hits" << endl; if(settings.EnableColorspace) cout << "- Aligning in colorspace (SOLiD)" << endl; if(settings.HasNumThreads) cout << "- Using " << (short)settings.NumThreads << (settings.NumThreads > 1 ? " processors" : " processor") << endl; if(settings.HasBandwidth) cout << "- Using a Smith-Waterman bandwidth of " << settings.Bandwidth << endl; if(settings.EnableAlignmentCandidateThreshold) cout << "- Using an alignment candidate threshold of " << (unsigned short)settings.AlignmentCandidateThreshold << "bp." << endl; if(settings.HasLocalAlignmentSearchRadius) cout << "- Using a local alignment search radius of " << settings.LocalAlignmentSearchRadius << "bp." << endl; if(settings.LimitHashPositions) cout << "- Setting hash position threshold to " << settings.HashPositionThreshold << endl; if(settings.UseJumpDB) { cout << "- Using a jump database for hashing"; if(settings.HasJumpCacheMemory) cout << " with a " << settings.JumpCacheMemory << " element cache"; cout << "."; if(!settings.KeepJumpKeysOnDisk && !settings.KeepJumpPositionsOnDisk) cout << " Storing keys & positions in memory."; else if(!settings.KeepJumpKeysOnDisk && settings.KeepJumpPositionsOnDisk) cout << " Storing keys in memory."; else if(settings.KeepJumpKeysOnDisk && !settings.KeepJumpPositionsOnDisk) cout << " Storing positions in memory."; cout << endl; } //if(settings.RecordUnalignedReads) // cout << "- Reporting all unaligned reads to " << settings.UnalignedReadsFilename << "." << endl; if(settings.HasHomoPolymerGapOpenPenalty) cout << "- Using a h**o-polymer gap open penalty of " << CPairwiseUtilities::HomoPolymerGapOpenPenalty << endl; if(settings.HasMatchScore || settings.HasMismatchScore || settings.HasGapOpenPenalty || settings.HasGapExtendPenalty) cout << "- Updating Smith-Waterman scoring scheme (match, mismatch, gap open, gap extend): (" << CPairwiseUtilities::MatchScore << ", " << CPairwiseUtilities::MismatchScore << ", " << CPairwiseUtilities::GapOpenPenalty << ", " << CPairwiseUtilities::GapExtendPenalty << ")" << endl; // ============== // Start aligning // ============== ma.AlignReadArchiveLowMemory(); //ma.AlignReadArchive(); // ================== // Show total runtime // ================== // stop benchmarking bench.Stop(); // show the benchmarking results cout << endl; bench.DisplayTime("MosaikAligner"); return 0; }
// aligns the read archive void CMosaikAligner::AlignReadArchive(MosaikReadFormat::CReadReader& in, MosaikReadFormat::CAlignmentWriter& out, unsigned int* pRefBegin, unsigned int* pRefEnd, char** pBsRefSeqs) { // ============== // initialization // ============== // retrieve the concatenated reference sequence length /* vector<ReferenceSequence> referenceSequences; MosaikReadFormat::CReferenceSequenceReader refseq; refseq.Open(mSettings.ReferenceFilename); refseq.GetReferenceSequences(referenceSequences); mReferenceLength = refseq.GetReferenceSequenceLength(); const unsigned int numRefSeqs = refseq.GetNumReferenceSequences(); // retrieve the basespace reference filenames char** pBsRefSeqs = NULL; if(mFlags.EnableColorspace) { cout << "- loading basespace reference sequences... "; cout.flush(); MosaikReadFormat::CReferenceSequenceReader bsRefSeq; bsRefSeq.Open(mSettings.BasespaceReferenceFilename); if(!bsRefSeq.HasSameReferenceSequences(referenceSequences)) { printf("ERROR: The basespace and colorspace reference sequence archives do not seem to represent the same FASTA file.\n"); exit(1); } bsRefSeq.CopyReferenceSequences(pBsRefSeqs); bsRefSeq.Close(); cout << "finished." << endl; } // initialize our hash tables InitializeHashTables(CalculateHashTableSize(mReferenceLength, mSettings.HashSize)); // hash the concatenated reference sequence if(!mFlags.IsUsingJumpDB) HashReferenceSequence(refseq); cout << "- loading reference sequence... "; cout.flush(); refseq.LoadConcatenatedSequence(mReference); cout << "finished." << endl; refseq.Close(); // create our reference sequence LUTs unsigned int* pRefBegin = new unsigned int[numRefSeqs]; unsigned int* pRefEnd = new unsigned int[numRefSeqs]; for(unsigned int j = 0; j < numRefSeqs; j++) { pRefBegin[j] = referenceSequences[j].Begin; pRefEnd[j] = referenceSequences[j].End; } // set the hash positions threshold if(mFlags.IsUsingHashPositionThreshold && (mAlgorithm == CAlignmentThread::AlignerAlgorithm_ALL)) mpDNAHash->RandomizeAndTrimHashPositions(mSettings.HashPositionThreshold); // localize the read archive filenames string inputReadArchiveFilename = mSettings.InputReadArchiveFilename; string outputReadArchiveFilename = mSettings.OutputReadArchiveFilename; // define our read format reader and writer MosaikReadFormat::CReadReader in; in.Open(inputReadArchiveFilename); MosaikReadFormat::ReadGroup readGroup = in.GetReadGroup(); */ ReadStatus readStatus = in.GetStatus(); /* mSettings.SequencingTechnology = readGroup.SequencingTechnology; mSettings.MedianFragmentLength = readGroup.MedianFragmentLength; */ const bool isPairedEnd = (readStatus == RS_PAIRED_END_READ ? true : false); /* vector<MosaikReadFormat::ReadGroup> readGroups; readGroups.push_back(readGroup); // set the alignment status flags AlignmentStatus alignmentStatus = AS_UNSORTED_READ | readStatus; if(mMode == CAlignmentThread::AlignerMode_ALL) alignmentStatus |= AS_ALL_MODE; else alignmentStatus |= AS_UNIQUE_MODE; MosaikReadFormat::CAlignmentWriter out; out.Open(mSettings.OutputReadArchiveFilename.c_str(), referenceSequences, readGroups, alignmentStatus); */ // open the unaligned read report file FILE* unalignedStream = NULL; if(mFlags.IsReportingUnalignedReads) { if(fopen_s(&unalignedStream, mSettings.UnalignedReadReportFilename.c_str(), "wb") != 0) { cout << "ERROR: Unable to open the unaligned read FASTQ file for output." << endl; exit(1); } } // localize our read and reference counts. Initialize our statistical counters uint64_t numReadArchiveReads = in.GetNumReads(); uint64_t readCounter = 0; // initialize our threads pthread_t* activeThreads = new pthread_t[mSettings.NumThreads]; CAlignmentThread::ThreadData td; td.Algorithm = mAlgorithm; td.ReferenceLen = mReferenceLength; td.Filters = mFilters; td.SplitFilters = mSplitFilters; td.Flags = mFlags; td.Mode = mMode; td.pReference = mReference; td.pCounters = &mStatisticsCounters; td.pDnaHash = mpDNAHash; td.pIn = ∈ td.pOut = &out; td.pUnalignedStream = unalignedStream; td.pRefBegin = pRefBegin; td.pRefEnd = pRefEnd; td.Settings = mSettings; td.pReadCounter = &readCounter; td.IsPairedEnd = isPairedEnd; td.pBsRefSeqs = pBsRefSeqs; // unenable EnableColorspace flag for low-memory algorithm, deal with the SOLiD convertion when sorting the aligned archives //if ( mFlags.UseLowMemory ) // td.Flags.EnableColorspace = false; pthread_attr_t attr; pthread_attr_init(&attr); pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE); pthread_mutex_init(&CAlignmentThread::mGetReadMutex, NULL); pthread_mutex_init(&CAlignmentThread::mReportUnalignedMate1Mutex, NULL); pthread_mutex_init(&CAlignmentThread::mReportUnalignedMate2Mutex, NULL); pthread_mutex_init(&CAlignmentThread::mSaveReadMutex, NULL); pthread_mutex_init(&CAlignmentThread::mStatisticsMutex, NULL); pthread_mutex_init(&CAbstractDnaHash::mJumpCacheMutex, NULL); pthread_mutex_init(&CAbstractDnaHash::mJumpKeyMutex, NULL); pthread_mutex_init(&CAbstractDnaHash::mJumpPositionMutex, NULL); // =========================== // start our alignment threads // =========================== // initialize our progress bar if ( !mFlags.UseLowMemory ) { CConsole::Heading(); cout << endl; } cout << "Aligning read library (" << numReadArchiveReads << "):" << endl; if ( !mFlags.UseLowMemory ) CConsole::Reset(); CProgressBar<uint64_t>::StartThread(&readCounter, 0, numReadArchiveReads, "reads"); // create our threads for(unsigned int i = 0; i < mSettings.NumThreads; i++) pthread_create(&activeThreads[i], &attr, CAlignmentThread::StartThread, (void*)&td); pthread_attr_destroy(&attr); CBenchmark alignmentBench; alignmentBench.Start(); // wait for the threads to complete void* status = NULL; for(unsigned int i = 0; i < mSettings.NumThreads; i++) pthread_join(activeThreads[i], &status); // wait for the progress bar to finish CProgressBar<uint64_t>::WaitThread(); alignmentBench.Stop(); // free up some memory //delete [] mReference; delete [] activeThreads; activeThreads = NULL; //if(pRefBegin) delete [] pRefBegin; //if(pRefEnd) delete [] pRefEnd; //if(pBsRefSeqs) { // for(unsigned int i = 0; i < numRefSeqs; ++i) delete [] pBsRefSeqs[i]; // delete [] pBsRefSeqs; //} // close open file streams //in.Close(); // solid references should be one-base longer after converting back to basespace //if(mFlags.EnableColorspace) out.AdjustSolidReferenceBases(); //out.Close(); if(mFlags.IsReportingUnalignedReads) fclose(unalignedStream); //if(mFlags.IsUsingJumpDB) mpDNAHash->FreeMemory(); // ==================== // print our statistics // ==================== /* const uint64_t totalMates = mStatisticsCounters.ShortMates + mStatisticsCounters.FailedHashMates + mStatisticsCounters.UniqueMates + mStatisticsCounters.NonUniqueMates + mStatisticsCounters.FilteredOutMates; const uint64_t totalAlignedMates = mStatisticsCounters.UniqueMates + mStatisticsCounters.NonUniqueMates; const uint64_t totalAlignedReads = mStatisticsCounters.AlignedReads; // print our alignment statistics (mates) if don't enable low-memory algorithm if ( !mFlags.UseLowMemory ) { printf("\n"); CConsole::Heading(); printf("Alignment statistics (mates):\n"); CConsole::Reset(); printf("===================================\n"); if(mStatisticsCounters.ShortMates > 0) printf("# too short: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.ShortMates, (mStatisticsCounters.ShortMates / (double)totalMates) * 100.0); if(mStatisticsCounters.FailedHashMates > 0) printf("# failed hash: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.FailedHashMates, (mStatisticsCounters.FailedHashMates / (double)totalMates) * 100.0); if(mStatisticsCounters.FilteredOutMates > 0) printf("# filtered out: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.FilteredOutMates, (mStatisticsCounters.FilteredOutMates / (double)totalMates) * 100.0); if(mStatisticsCounters.UniqueMates > 0) printf("# unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.UniqueMates, (mStatisticsCounters.UniqueMates / (double)totalMates) * 100.0); if(mStatisticsCounters.NonUniqueMates > 0) printf("# non-unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.NonUniqueMates, (mStatisticsCounters.NonUniqueMates / (double)totalMates) * 100.0); printf("-----------------------------------\n"); printf("total: %9llu\n", (unsigned long long)totalMates); printf("total aligned: "); CConsole::Bold(); printf("%9llu", (unsigned long long)totalAlignedMates); CConsole::Reset(); printf(" ("); CConsole::Bold(); printf("%5.1f %%", (totalAlignedMates / (double)totalMates) * 100.0); CConsole::Reset(); printf(")\n"); // print our local alignment search statistics if(mFlags.UseLocalAlignmentSearch) { printf("\n"); CConsole::Heading(); printf("Local alignment search statistics:\n"); CConsole::Reset(); printf("===================================\n"); double rescuedAlignmentsPercent = mStatisticsCounters.AdditionalLocalMates / (double)totalMates * 100.0; printf("rescued mates: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.AdditionalLocalMates, rescuedAlignmentsPercent); } // print our alignment statistics (reads) if(isPairedEnd) { printf("\n"); CConsole::Heading(); printf("Alignment statistics (reads):\n"); CConsole::Reset(); printf("============================================\n"); printf("# unaligned: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.UnalignedReads, (mStatisticsCounters.UnalignedReads / (double)numReadArchiveReads) * 100.0); printf("# orphaned: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.OrphanedReads, (mStatisticsCounters.OrphanedReads / (double)numReadArchiveReads) * 100.0); printf("# both mates unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.BothUniqueReads, (mStatisticsCounters.BothUniqueReads / (double)numReadArchiveReads) * 100.0); printf("# one mate non-unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.OneNonUniqueReads, (mStatisticsCounters.OneNonUniqueReads / (double)numReadArchiveReads) * 100.0); printf("# both mates non-unique: %9llu (%5.1f %%)\n", (unsigned long long)mStatisticsCounters.BothNonUniqueReads, (mStatisticsCounters.BothNonUniqueReads / (double)numReadArchiveReads) * 100.0); printf("--------------------------------------------\n"); printf("total reads: "); CConsole::Bold(); printf("%9llu", (unsigned long long)numReadArchiveReads); CConsole::Reset(); printf("\n"); printf("total reads aligned: "); CConsole::Bold(); printf("%9llu", (unsigned long long)totalAlignedReads); CConsole::Reset(); printf(" ("); CConsole::Bold(); printf("%5.1f %%", (totalAlignedReads / (double)numReadArchiveReads) * 100.0); CConsole::Reset(); printf(")\n"); } // print our jump cache statistics if(mFlags.IsUsingJumpDB && (mSettings.NumCachedHashes > 0)) { printf("\n"); CConsole::Heading(); printf("Jump database cache statistics:\n"); CConsole::Reset(); printf("====================================\n"); uint64_t cacheHits = 0, cacheMisses = 0, cacheTotal = 0; CJumpDnaHash* pJump = (CJumpDnaHash*)mpDNAHash; pJump->GetCacheStatistics(cacheHits, cacheMisses); cacheTotal = cacheHits + cacheMisses; double cacheHitsPercent = cacheHits / (double)cacheTotal * 100.0; printf("cache hits: %10llu (%5.1f %%)\n", (unsigned long long)cacheHits, cacheHitsPercent); printf("cache misses: %10llu\n", (unsigned long long)cacheMisses); } printf("\n"); CConsole::Heading(); printf("Miscellaneous statistics:\n"); CConsole::Reset(); printf("==================================\n"); printf("aligned mate bp: %10llu\n", (unsigned long long)mStatisticsCounters.MateBasesAligned); printf("alignment candidates/s: %10.1f\n", mStatisticsCounters.AlignmentCandidates / alignmentBench.GetElapsedWallTime()); } */ }