///////////////////////////////////////////////////////////////// // Main.cc // // Main routines for PROBCONS program. ///////////////////////////////////////////////////////////////// #include "SafeVector.h" #include "MultiSequence.h" #include "Defaults.h" #include "ScoreType.h" #include "ProbabilisticModel.h" #include "EvolutionaryTree.h" #include "SparseMatrix.h" #include #include #include #include #include #include #include #include #include #include #include #include string parametersInputFilename = ""; string parametersOutputFilename = "no training"; string annotationFilename = ""; bool enableTraining = false; bool enableVerbose = false; bool enableAllPairs = false; bool enableAnnotation = false; bool enableViterbi = false; bool enableClustalWOutput = false; bool enableTrainEmissions = false; bool enableAlignOrder = false; int numConsistencyReps = 2; int numPreTrainingReps = 0; int numIterativeRefinementReps = 100; float cutoff = 0; float gapOpenPenalty = 0; float gapContinuePenalty = 0; VF initDistrib (NumMatrixTypes); VF gapOpen (2*NumInsertStates); VF gapExtend (2*NumInsertStates); VVF emitPairs (256, VF (256, 1e-10)); VF emitSingle (256, 1e-5); string alphabet = alphabetDefault; const int MIN_PRETRAINING_REPS = 0; const int MAX_PRETRAINING_REPS = 20; const int MIN_CONSISTENCY_REPS = 0; const int MAX_CONSISTENCY_REPS = 5; const int MIN_ITERATIVE_REFINEMENT_REPS = 0; const int MAX_ITERATIVE_REFINEMENT_REPS = 1000; ///////////////////////////////////////////////////////////////// // Function prototypes ///////////////////////////////////////////////////////////////// void PrintHeading(); void PrintParameters (const char *message, const VF &initDistrib, const VF &gapOpen, const VF &gapExtend, const VVF &emitPairs, const VF &emitSingle, const char *filename); MultiSequence *DoAlign (MultiSequence *sequence, const ProbabilisticModel &model, VF &initDistrib, VF &gapOpen, VF &gapExtend, VVF &emitPairs, VF &emitSingle); SafeVector ParseParams (int argc, char **argv); void ReadParameters (); MultiSequence *ComputeFinalAlignment (const TreeNode *tree, MultiSequence *sequences, const SafeVector > &sparseMatrices, const ProbabilisticModel &model); MultiSequence *AlignAlignments (MultiSequence *align1, MultiSequence *align2, const SafeVector > &sparseMatrices, const ProbabilisticModel &model); SafeVector > DoRelaxation (MultiSequence *sequences, SafeVector > &sparseMatrices); void Relax (SparseMatrix *matXZ, SparseMatrix *matZY, VF &posterior); void Relax1 (SparseMatrix *matXZ, SparseMatrix *matZY, VF &posterior); set GetSubtree (const TreeNode *tree); void TreeBasedBiPartitioning (const SafeVector > &sparseMatrices, const ProbabilisticModel &model, MultiSequence* &alignment, const TreeNode *tree); void DoIterativeRefinement (const SafeVector > &sparseMatrices, const ProbabilisticModel &model, MultiSequence* &alignment); void WriteAnnotation (MultiSequence *alignment, const SafeVector > &sparseMatrices); int ComputeScore (const SafeVector > &active, const SafeVector > &sparseMatrices); ///////////////////////////////////////////////////////////////// // main() // // Calls all initialization routines and runs the PROBCONS // aligner. ///////////////////////////////////////////////////////////////// int main (int argc, char **argv){ // print PROBCONS heading PrintHeading(); // parse program parameters SafeVector sequenceNames = ParseParams (argc, argv); ReadParameters(); PrintParameters ("Using parameter set:", initDistrib, gapOpen, gapExtend, emitPairs, emitSingle, NULL); // now, we'll process all the files given as input. If we are given // several filenames as input, then we'll load all of those sequences // simultaneously, as long as we're not training. On the other hand, // if we are training, then we'll treat each file as a separate // training instance // if we are training if (enableTraining){ // build new model for aligning ProbabilisticModel model (initDistrib, gapOpen, gapExtend, emitPairs, emitSingle); // prepare to average parameters for (int i = 0; i < (int) initDistrib.size(); i++) initDistrib[i] = 0; for (int i = 0; i < (int) gapOpen.size(); i++) gapOpen[i] = 0; for (int i = 0; i < (int) gapExtend.size(); i++) gapExtend[i] = 0; if (enableTrainEmissions){ for (int i = 0; i < (int) emitPairs.size(); i++) for (int j = 0; j < (int) emitPairs[i].size(); j++) emitPairs[i][j] = 0; for (int i = 0; i < (int) emitSingle.size(); i++) emitSingle[i] = 0; } // align each file individually for (int i = 0; i < (int) sequenceNames.size(); i++){ VF thisInitDistrib (NumMatrixTypes); VF thisGapOpen (2*NumInsertStates); VF thisGapExtend (2*NumInsertStates); VVF thisEmitPairs (256, VF (256, 1e-10)); VF thisEmitSingle (256, 1e-5); // load sequence file MultiSequence *sequences = new MultiSequence(); assert (sequences); cerr << "Loading sequence file: " << sequenceNames[i] << endl; sequences->LoadMFA (sequenceNames[i], true); // align sequences DoAlign (sequences, model, thisInitDistrib, thisGapOpen, thisGapExtend, thisEmitPairs, thisEmitSingle); // add in contribution of the derived parameters for (int i = 0; i < (int) initDistrib.size(); i++) initDistrib[i] += thisInitDistrib[i]; for (int i = 0; i < (int) gapOpen.size(); i++) gapOpen[i] += thisGapOpen[i]; for (int i = 0; i < (int) gapExtend.size(); i++) gapExtend[i] += thisGapExtend[i]; if (enableTrainEmissions){ for (int i = 0; i < (int) emitPairs.size(); i++) for (int j = 0; j < (int) emitPairs[i].size(); j++) emitPairs[i][j] += thisEmitPairs[i][j]; for (int i = 0; i < (int) emitSingle.size(); i++) emitSingle[i] += thisEmitSingle[i]; } delete sequences; } // compute new parameters and print them out for (int i = 0; i < (int) initDistrib.size(); i++) initDistrib[i] /= (int) sequenceNames.size(); for (int i = 0; i < (int) gapOpen.size(); i++) gapOpen[i] /= (int) sequenceNames.size(); for (int i = 0; i < (int) gapExtend.size(); i++) gapExtend[i] /= (int) sequenceNames.size(); if (enableTrainEmissions){ for (int i = 0; i < (int) emitPairs.size(); i++) for (int j = 0; j < (int) emitPairs[i].size(); j++) emitPairs[i][j] /= (int) sequenceNames.size(); for (int i = 0; i < (int) emitSingle.size(); i++) emitSingle[i] /= sequenceNames.size(); } PrintParameters ("Trained parameter set:", initDistrib, gapOpen, gapExtend, emitPairs, emitSingle, parametersOutputFilename.c_str()); } // if we are not training, we must simply want to align some sequences else { // load all files together MultiSequence *sequences = new MultiSequence(); assert (sequences); for (int i = 0; i < (int) sequenceNames.size(); i++){ cerr << "Loading sequence file: " << sequenceNames[i] << endl; sequences->LoadMFA (sequenceNames[i], true); } // do all "pre-training" repetitions first for (int ct = 0; ct < numPreTrainingReps; ct++){ enableTraining = true; // build new model for aligning ProbabilisticModel model (initDistrib, gapOpen, gapExtend, emitPairs, emitSingle); // do initial alignments DoAlign (sequences, model, initDistrib, gapOpen, gapExtend, emitPairs, emitSingle); // print new parameters PrintParameters ("Recomputed parameter set:", initDistrib, gapOpen, gapExtend, emitPairs, emitSingle, NULL); enableTraining = false; } // now, we can perform the alignments and write them out MultiSequence *alignment = DoAlign (sequences, ProbabilisticModel (initDistrib, gapOpen, gapExtend, emitPairs, emitSingle), initDistrib, gapOpen, gapExtend, emitPairs, emitSingle); if (!enableAllPairs){ if (enableClustalWOutput) alignment->WriteALN (cout); else alignment->WriteMFA (cout); } delete alignment; delete sequences; } } ///////////////////////////////////////////////////////////////// // PrintHeading() // // Prints heading for PROBCONS program. ///////////////////////////////////////////////////////////////// void PrintHeading (){ cerr << endl << "PROBCONS version " << VERSION << " - align multiple protein sequences and print to standard output" << endl << "Written by Chuong Do" << endl << endl; } ///////////////////////////////////////////////////////////////// // PrintParameters() // // Prints PROBCONS parameters to STDERR. If a filename is // specified, then the parameters are also written to the file. ///////////////////////////////////////////////////////////////// void PrintParameters (const char *message, const VF &initDistrib, const VF &gapOpen, const VF &gapExtend, const VVF &emitPairs, const VF &emitSingle, const char *filename){ // print parameters to the screen cerr << message << endl << " initDistrib[] = { "; for (int i = 0; i < NumMatrixTypes; i++) cerr << setprecision (10) << initDistrib[i] << " "; cerr << "}" << endl << " gapOpen[] = { "; for (int i = 0; i < NumInsertStates*2; i++) cerr << setprecision (10) << gapOpen[i] << " "; cerr << "}" << endl << " gapExtend[] = { "; for (int i = 0; i < NumInsertStates*2; i++) cerr << setprecision (10) << gapExtend[i] << " "; cerr << "}" << endl << endl; /* for (int i = 0; i < 5; i++){ for (int j = 0; j <= i; j++){ cerr << emitPairs[(unsigned char) alphabet[i]][(unsigned char) alphabet[j]] << " "; } cerr << endl; }*/ // if a file name is specified if (filename){ // attempt to open the file for writing FILE *file = fopen (filename, "w"); if (!file){ cerr << "ERROR: Unable to write parameter file: " << filename << endl; exit (1); } // if successful, then write the parameters to the file for (int i = 0; i < NumMatrixTypes; i++) fprintf (file, "%.10f ", initDistrib[i]); fprintf (file, "\n"); for (int i = 0; i < 2*NumInsertStates; i++) fprintf (file, "%.10f ", gapOpen[i]); fprintf (file, "\n"); for (int i = 0; i < 2*NumInsertStates; i++) fprintf (file, "%.10f ", gapExtend[i]); fprintf (file, "\n"); fprintf (file, "%s\n", alphabet.c_str()); for (int i = 0; i < (int) alphabet.size(); i++){ for (int j = 0; j <= i; j++) fprintf (file, "%.10f ", emitPairs[(unsigned char) alphabet[i]][(unsigned char) alphabet[j]]); fprintf (file, "\n"); } for (int i = 0; i < (int) alphabet.size(); i++) fprintf (file, "%.10f ", emitSingle[(unsigned char) alphabet[i]]); fprintf (file, "\n"); fclose (file); } } ///////////////////////////////////////////////////////////////// // DoAlign() // // First computes all pairwise posterior probability matrices. // Then, computes new parameters if training, or a final // alignment, otherwise. ///////////////////////////////////////////////////////////////// MultiSequence *DoAlign (MultiSequence *sequences, const ProbabilisticModel &model, VF &initDistrib, VF &gapOpen, VF &gapExtend, VVF &emitPairs, VF &emitSingle){ assert (sequences); const int numSeqs = sequences->GetNumSequences(); VVF distances (numSeqs, VF (numSeqs, 0)); SafeVector > sparseMatrices (numSeqs, SafeVector(numSeqs, NULL)); if (enableTraining){ // prepare to average parameters for (int i = 0; i < (int) initDistrib.size(); i++) initDistrib[i] = 0; for (int i = 0; i < (int) gapOpen.size(); i++) gapOpen[i] = 0; for (int i = 0; i < (int) gapExtend.size(); i++) gapExtend[i] = 0; if (enableTrainEmissions){ for (int i = 0; i < (int) emitPairs.size(); i++) for (int j = 0; j < (int) emitPairs[i].size(); j++) emitPairs[i][j] = 0; for (int i = 0; i < (int) emitSingle.size(); i++) emitSingle[i] = 0; } } // skip posterior calculations if we just want to do Viterbi alignments if (!enableViterbi){ // do all pairwise alignments for posterior probability matrices for (int a = 0; a < numSeqs-1; a++){ for (int b = a+1; b < numSeqs; b++){ Sequence *seq1 = sequences->GetSequence (a); Sequence *seq2 = sequences->GetSequence (b); // verbose output if (enableVerbose) cerr << "Computing posterior matrix: (" << a+1 << ") " << seq1->GetHeader() << " vs. " << "(" << b+1 << ") " << seq2->GetHeader() << " -- "; // compute forward and backward probabilities VF *forward = model.ComputeForwardMatrix (seq1, seq2); assert (forward); VF *backward = model.ComputeBackwardMatrix (seq1, seq2); assert (backward); // if we are training, then we'll simply want to compute the // expected counts for each region within the matrix separately; // otherwise, we'll need to put all of the regions together and // assemble a posterior probability match matrix // so, if we're training if (enableTraining){ // compute new parameters VF thisInitDistrib (NumMatrixTypes); VF thisGapOpen (2*NumInsertStates); VF thisGapExtend (2*NumInsertStates); VVF thisEmitPairs (256, VF (256, 1e-10)); VF thisEmitSingle (256, 1e-5); model.ComputeNewParameters (seq1, seq2, *forward, *backward, thisInitDistrib, thisGapOpen, thisGapExtend, thisEmitPairs, thisEmitSingle, enableTrainEmissions); // add in contribution of the derived parameters for (int i = 0; i < (int) initDistrib.size(); i++) initDistrib[i] += thisInitDistrib[i]; for (int i = 0; i < (int) gapOpen.size(); i++) gapOpen[i] += thisGapOpen[i]; for (int i = 0; i < (int) gapExtend.size(); i++) gapExtend[i] += thisGapExtend[i]; if (enableTrainEmissions){ for (int i = 0; i < (int) emitPairs.size(); i++) for (int j = 0; j < (int) emitPairs[i].size(); j++) emitPairs[i][j] += thisEmitPairs[i][j]; for (int i = 0; i < (int) emitSingle.size(); i++) emitSingle[i] += thisEmitSingle[i]; } // let us know that we're done. if (enableVerbose) cerr << "done." << endl; } else { // compute posterior probability matrix VF *posterior = model.ComputePosteriorMatrix (seq1, seq2, *forward, *backward); assert (posterior); // compute sparse representations sparseMatrices[a][b] = new SparseMatrix (seq1->GetLength(), seq2->GetLength(), *posterior); sparseMatrices[b][a] = NULL; if (!enableAllPairs){ // perform the pairwise sequence alignment pair *, float> alignment = model.ComputeAlignment (seq1->GetLength(), seq2->GetLength(), *posterior); // compute "expected accuracy" distance for evolutionary tree computation float distance = alignment.second / min (seq1->GetLength(), seq2->GetLength()); distances[a][b] = distances[b][a] = distance; if (enableVerbose) cerr << setprecision (10) << distance << endl; delete alignment.first; } else { // let us know that we're done. if (enableVerbose) cerr << "done." << endl; } delete posterior; } delete forward; delete backward; } } } // now average out parameters derived if (enableTraining){ // compute new parameters for (int i = 0; i < (int) initDistrib.size(); i++) initDistrib[i] /= numSeqs * (numSeqs - 1) / 2; for (int i = 0; i < (int) gapOpen.size(); i++) gapOpen[i] /= numSeqs * (numSeqs - 1) / 2; for (int i = 0; i < (int) gapExtend.size(); i++) gapExtend[i] /= numSeqs * (numSeqs - 1) / 2; if (enableTrainEmissions){ for (int i = 0; i < (int) emitPairs.size(); i++) for (int j = 0; j < (int) emitPairs[i].size(); j++) emitPairs[i][j] /= numSeqs * (numSeqs - 1) / 2; for (int i = 0; i < (int) emitSingle.size(); i++) emitSingle[i] /= numSeqs * (numSeqs - 1) / 2; } } // see if we still want to do some alignments else { if (!enableViterbi){ // perform the consistency transformation the desired number of times for (int r = 0; r < numConsistencyReps; r++){ SafeVector > newSparseMatrices = DoRelaxation (sequences, sparseMatrices); // now replace the old posterior matrices for (int i = 0; i < numSeqs; i++){ for (int j = 0; j < numSeqs; j++){ delete sparseMatrices[i][j]; sparseMatrices[i][j] = newSparseMatrices[i][j]; } } } } MultiSequence *finalAlignment = NULL; if (enableAllPairs){ for (int a = 0; a < numSeqs-1; a++){ for (int b = a+1; b < numSeqs; b++){ Sequence *seq1 = sequences->GetSequence (a); Sequence *seq2 = sequences->GetSequence (b); if (enableVerbose) cerr << "Performing pairwise alignment: (" << a+1 << ") " << seq1->GetHeader() << " vs. " << "(" << b+1 << ") " << seq2->GetHeader() << " -- "; // perform the pairwise sequence alignment pair *, float> alignment; if (enableViterbi) alignment = model.ComputeViterbiAlignment (seq1, seq2); else { // build posterior matrix VF *posterior = sparseMatrices[a][b]->GetPosterior(); assert (posterior); int length = (seq1->GetLength() + 1) * (seq2->GetLength() + 1); for (int i = 0; i < length; i++) (*posterior)[i] -= cutoff; alignment = model.ComputeAlignment (seq1->GetLength(), seq2->GetLength(), *posterior); delete posterior; } // write pairwise alignments string name = seq1->GetHeader() + "-" + seq2->GetHeader() + (enableClustalWOutput ? ".aln" : ".fasta"); ofstream outfile (name.c_str()); MultiSequence *result = new MultiSequence(); result->AddSequence (seq1->AddGaps(alignment.first, 'X')); result->AddSequence (seq2->AddGaps(alignment.first, 'Y')); if (enableClustalWOutput) result->WriteALN (outfile); else result->WriteMFA (outfile); outfile.close(); delete alignment.first; } } } // now if we still need to do a final multiple alignment else { if (enableVerbose) cerr << endl; // compute the evolutionary tree TreeNode *tree = TreeNode::ComputeTree (distances); tree->Print (cerr, sequences); cerr << endl; // make the final alignment finalAlignment = ComputeFinalAlignment (tree, sequences, sparseMatrices, model); // build annotation if (enableAnnotation){ WriteAnnotation (finalAlignment, sparseMatrices); } delete tree; } if (!enableViterbi){ // delete sparse matrices for (int a = 0; a < numSeqs-1; a++){ for (int b = a+1; b < numSeqs; b++){ delete sparseMatrices[a][b]; delete sparseMatrices[b][a]; } } } return finalAlignment; } return NULL; } ///////////////////////////////////////////////////////////////// // GetInteger() // // Attempts to parse an integer from the character string given. // Returns true only if no parsing error occurs. ///////////////////////////////////////////////////////////////// bool GetInteger (char *data, int *val){ char *endPtr; long int retVal; assert (val); errno = 0; retVal = strtol (data, &endPtr, 0); if (retVal == 0 && (errno != 0 || data == endPtr)) return false; if (errno != 0 && (retVal == LONG_MAX || retVal == LONG_MIN)) return false; if (retVal < (long) INT_MIN || retVal > (long) INT_MAX) return false; *val = (int) retVal; return true; } ///////////////////////////////////////////////////////////////// // GetFloat() // // Attempts to parse a float from the character string given. // Returns true only if no parsing error occurs. ///////////////////////////////////////////////////////////////// bool GetFloat (char *data, float *val){ char *endPtr; double retVal; assert (val); errno = 0; retVal = strtod (data, &endPtr); if (retVal == 0 && (errno != 0 || data == endPtr)) return false; if (errno != 0 && (retVal >= 1000000.0 || retVal <= -1000000.0)) return false; *val = (float) retVal; return true; } ///////////////////////////////////////////////////////////////// // ParseParams() // // Parse all command-line options. ///////////////////////////////////////////////////////////////// SafeVector ParseParams (int argc, char **argv){ if (argc < 2){ cerr << "PROBCONS comes with ABSOLUTELY NO WARRANTY. This is free software, and" << endl << "you are welcome to redistribute it under certain conditions. See the" << endl << "file COPYING.txt for details." << endl << endl << "Usage:" << endl << " probcons [OPTION]... [MFAFILE]..." << endl << endl << "Description:" << endl << " Align sequences in MFAFILE(s) and print result to standard output" << endl << endl << " -clustalw" << endl << " use CLUSTALW output format instead of MFA" << endl << endl << " -c, --consistency REPS" << endl << " use " << MIN_CONSISTENCY_REPS << " <= REPS <= " << MAX_CONSISTENCY_REPS << " (default: " << numConsistencyReps << ") passes of consistency transformation" << endl << endl << " -ir, --iterative-refinement REPS" << endl << " use " << MIN_ITERATIVE_REFINEMENT_REPS << " <= REPS <= " << MAX_ITERATIVE_REFINEMENT_REPS << " (default: " << numIterativeRefinementReps << ") passes of iterative-refinement" << endl << endl << " -pre, --pre-training REPS" << endl << " use " << MIN_PRETRAINING_REPS << " <= REPS <= " << MAX_PRETRAINING_REPS << " (default: " << numPreTrainingReps << ") rounds of pretraining" << endl << endl << " -pairs" << endl << " generate all-pairs pairwise alignments" << endl << endl << " -viterbi" << endl << " use Viterbi algorithm to generate all pairs (automatically enables -pairs)" << endl << endl << " -v, --verbose" << endl << " report progress while aligning (default: " << (enableVerbose ? "on" : "off") << ")" << endl << endl << " -annot FILENAME" << endl << " write annotation for multiple alignment to FILENAME" << endl << endl << " -t, --train FILENAME" << endl << " compute EM transition probabilities, store in FILENAME (default: " << parametersOutputFilename << ")" << endl << endl << " -e, --emissions" << endl << " also reestimate emission probabilities (default: " << (enableTrainEmissions ? "on" : "off") << ")" << endl << endl << " -p, --paramfile FILENAME" << endl << " read parameters from FILENAME (default: " << parametersInputFilename << ")" << endl << endl << " -a, --alignment-order" << endl << " print sequences in alignment order rather than input order (default: " << (enableAlignOrder ? "on" : "off") << ")" << endl << endl; // << " -go, --gap-open VALUE" << endl // << " gap opening penalty of VALUE <= 0 (default: " << gapOpenPenalty << ")" << endl // << endl // << " -ge, --gap-extension VALUE" << endl // << " gap extension penalty of VALUE <= 0 (default: " << gapContinuePenalty << ")" << endl // << endl // << " -co, --cutoff CUTOFF" << endl // << " subtract 0 <= CUTOFF <= 1 (default: " << cutoff << ") from all posterior values before final alignment" << endl // << endl exit (1); } SafeVector sequenceNames; int tempInt; float tempFloat; for (int i = 1; i < argc; i++){ if (argv[i][0] == '-'){ // training if (!strcmp (argv[i], "-t") || !strcmp (argv[i], "--train")){ enableTraining = true; if (i < argc - 1) parametersOutputFilename = string (argv[++i]); else { cerr << "ERROR: Filename expected for option " << argv[i] << endl; exit (1); } } // emission training else if (!strcmp (argv[i], "-e") || !strcmp (argv[i], "--emissions")){ enableTrainEmissions = true; } // parameter file else if (!strcmp (argv[i], "-p") || !strcmp (argv[i], "--paramfile")){ if (i < argc - 1) parametersInputFilename = string (argv[++i]); else { cerr << "ERROR: Filename expected for option " << argv[i] << endl; exit (1); } } // number of consistency transformations else if (!strcmp (argv[i], "-c") || !strcmp (argv[i], "--consistency")){ if (i < argc - 1){ if (!GetInteger (argv[++i], &tempInt)){ cerr << "ERROR: Invalid integer following option " << argv[i-1] << ": " << argv[i] << endl; exit (1); } else { if (tempInt < MIN_CONSISTENCY_REPS || tempInt > MAX_CONSISTENCY_REPS){ cerr << "ERROR: For option " << argv[i-1] << ", integer must be between " << MIN_CONSISTENCY_REPS << " and " << MAX_CONSISTENCY_REPS << "." << endl; exit (1); } else numConsistencyReps = tempInt; } } else { cerr << "ERROR: Integer expected for option " << argv[i] << endl; exit (1); } } // number of randomized partitioning iterative refinement passes else if (!strcmp (argv[i], "-ir") || !strcmp (argv[i], "--iterative-refinement")){ if (i < argc - 1){ if (!GetInteger (argv[++i], &tempInt)){ cerr << "ERROR: Invalid integer following option " << argv[i-1] << ": " << argv[i] << endl; exit (1); } else { if (tempInt < MIN_ITERATIVE_REFINEMENT_REPS || tempInt > MAX_ITERATIVE_REFINEMENT_REPS){ cerr << "ERROR: For option " << argv[i-1] << ", integer must be between " << MIN_ITERATIVE_REFINEMENT_REPS << " and " << MAX_ITERATIVE_REFINEMENT_REPS << "." << endl; exit (1); } else numIterativeRefinementReps = tempInt; } } else { cerr << "ERROR: Integer expected for option " << argv[i] << endl; exit (1); } } // number of EM pre-training rounds else if (!strcmp (argv[i], "-pre") || !strcmp (argv[i], "--pre-training")){ if (i < argc - 1){ if (!GetInteger (argv[++i], &tempInt)){ cerr << "ERROR: Invalid integer following option " << argv[i-1] << ": " << argv[i] << endl; exit (1); } else { if (tempInt < MIN_PRETRAINING_REPS || tempInt > MAX_PRETRAINING_REPS){ cerr << "ERROR: For option " << argv[i-1] << ", integer must be between " << MIN_PRETRAINING_REPS << " and " << MAX_PRETRAINING_REPS << "." << endl; exit (1); } else numPreTrainingReps = tempInt; } } else { cerr << "ERROR: Integer expected for option " << argv[i] << endl; exit (1); } } // gap open penalty else if (!strcmp (argv[i], "-go") || !strcmp (argv[i], "--gap-open")){ if (i < argc - 1){ if (!GetFloat (argv[++i], &tempFloat)){ cerr << "ERROR: Invalid floating-point value following option " << argv[i-1] << ": " << argv[i] << endl; exit (1); } else { if (tempFloat > 0){ cerr << "ERROR: For option " << argv[i-1] << ", floating-point value must not be positive." << endl; exit (1); } else gapOpenPenalty = tempFloat; } } else { cerr << "ERROR: Floating-point value expected for option " << argv[i] << endl; exit (1); } } // gap extension penalty else if (!strcmp (argv[i], "-ge") || !strcmp (argv[i], "--gap-extension")){ if (i < argc - 1){ if (!GetFloat (argv[++i], &tempFloat)){ cerr << "ERROR: Invalid floating-point value following option " << argv[i-1] << ": " << argv[i] << endl; exit (1); } else { if (tempFloat > 0){ cerr << "ERROR: For option " << argv[i-1] << ", floating-point value must not be positive." << endl; exit (1); } else gapContinuePenalty = tempFloat; } } else { cerr << "ERROR: Floating-point value expected for option " << argv[i] << endl; exit (1); } } // all-pairs pairwise alignments else if (!strcmp (argv[i], "-pairs")){ enableAllPairs = true; } // all-pairs pairwise Viterbi alignments else if (!strcmp (argv[i], "-viterbi")){ enableAllPairs = true; enableViterbi = true; } // annotation files else if (!strcmp (argv[i], "-annot")){ enableAnnotation = true; if (i < argc - 1) annotationFilename = argv[++i]; else { cerr << "ERROR: FILENAME expected for option " << argv[i] << endl; exit (1); } } // clustalw output format else if (!strcmp (argv[i], "-clustalw")){ enableClustalWOutput = true; } // cutoff else if (!strcmp (argv[i], "-co") || !strcmp (argv[i], "--cutoff")){ if (i < argc - 1){ if (!GetFloat (argv[++i], &tempFloat)){ cerr << "ERROR: Invalid floating-point value following option " << argv[i-1] << ": " << argv[i] << endl; exit (1); } else { if (tempFloat < 0 || tempFloat > 1){ cerr << "ERROR: For option " << argv[i-1] << ", floating-point value must be between 0 and 1." << endl; exit (1); } else cutoff = tempFloat; } } else { cerr << "ERROR: Floating-point value expected for option " << argv[i] << endl; exit (1); } } // verbose reporting else if (!strcmp (argv[i], "-v") || !strcmp (argv[i], "--verbose")){ enableVerbose = true; } // alignment order else if (!strcmp (argv[i], "-a") || !strcmp (argv[i], "--alignment-order")){ enableAlignOrder = true; } // bad arguments else { cerr << "ERROR: Unrecognized option: " << argv[i] << endl; exit (1); } } else { sequenceNames.push_back (string (argv[i])); } } if (enableTrainEmissions && !enableTraining){ cerr << "ERROR: Training emissions (-e) requires training (-t)" << endl; exit (1); } return sequenceNames; } ///////////////////////////////////////////////////////////////// // ReadParameters() // // Read initial distribution, transition, and emission // parameters from a file. ///////////////////////////////////////////////////////////////// void ReadParameters (){ ifstream data; emitPairs = VVF (256, VF (256, 1e-10)); emitSingle = VF (256, 1e-5); // read initial state distribution and transition parameters if (parametersInputFilename == string ("")){ if (NumInsertStates == 1){ for (int i = 0; i < NumMatrixTypes; i++) initDistrib[i] = initDistrib1Default[i]; for (int i = 0; i < 2*NumInsertStates; i++) gapOpen[i] = gapOpen1Default[i]; for (int i = 0; i < 2*NumInsertStates; i++) gapExtend[i] = gapExtend1Default[i]; } else if (NumInsertStates == 2){ for (int i = 0; i < NumMatrixTypes; i++) initDistrib[i] = initDistrib2Default[i]; for (int i = 0; i < 2*NumInsertStates; i++) gapOpen[i] = gapOpen2Default[i]; for (int i = 0; i < 2*NumInsertStates; i++) gapExtend[i] = gapExtend2Default[i]; } else { cerr << "ERROR: No default initial distribution/parameter settings exist" << endl << " for " << NumInsertStates << " pairs of insert states. Use --paramfile." << endl; exit (1); } alphabet = alphabetDefault; for (int i = 0; i < (int) alphabet.length(); i++){ emitSingle[(unsigned char) tolower(alphabet[i])] = emitSingleDefault[i]; emitSingle[(unsigned char) toupper(alphabet[i])] = emitSingleDefault[i]; for (int j = 0; j <= i; j++){ emitPairs[(unsigned char) tolower(alphabet[i])][(unsigned char) tolower(alphabet[j])] = emitPairsDefault[i][j]; emitPairs[(unsigned char) tolower(alphabet[i])][(unsigned char) toupper(alphabet[j])] = emitPairsDefault[i][j]; emitPairs[(unsigned char) toupper(alphabet[i])][(unsigned char) tolower(alphabet[j])] = emitPairsDefault[i][j]; emitPairs[(unsigned char) toupper(alphabet[i])][(unsigned char) toupper(alphabet[j])] = emitPairsDefault[i][j]; emitPairs[(unsigned char) tolower(alphabet[j])][(unsigned char) tolower(alphabet[i])] = emitPairsDefault[i][j]; emitPairs[(unsigned char) tolower(alphabet[j])][(unsigned char) toupper(alphabet[i])] = emitPairsDefault[i][j]; emitPairs[(unsigned char) toupper(alphabet[j])][(unsigned char) tolower(alphabet[i])] = emitPairsDefault[i][j]; emitPairs[(unsigned char) toupper(alphabet[j])][(unsigned char) toupper(alphabet[i])] = emitPairsDefault[i][j]; } } } else { data.open (parametersInputFilename.c_str()); if (data.fail()){ cerr << "ERROR: Unable to read parameter file: " << parametersInputFilename << endl; exit (1); } string line[3]; for (int i = 0; i < 3; i++){ if (!getline (data, line[i])){ cerr << "ERROR: Unable to read transition parameters from parameter file: " << parametersInputFilename << endl; exit (1); } } istringstream data2; data2.clear(); data2.str (line[0]); for (int i = 0; i < NumMatrixTypes; i++) data2 >> initDistrib[i]; data2.clear(); data2.str (line[1]); for (int i = 0; i < 2*NumInsertStates; i++) data2 >> gapOpen[i]; data2.clear(); data2.str (line[2]); for (int i = 0; i < 2*NumInsertStates; i++) data2 >> gapExtend[i]; if (!getline (data, line[0])){ cerr << "ERROR: Unable to read alphabet from scoring matrix file: " << parametersInputFilename << endl; exit (1); } // read alphabet as concatenation of all characters on alphabet line alphabet = ""; string token; data2.clear(); data2.str (line[0]); while (data2 >> token) alphabet += token; for (int i = 0; i < (int) alphabet.size(); i++){ for (int j = 0; j <= i; j++){ float val; data >> val; emitPairs[(unsigned char) tolower(alphabet[i])][(unsigned char) tolower(alphabet[j])] = val; emitPairs[(unsigned char) tolower(alphabet[i])][(unsigned char) toupper(alphabet[j])] = val; emitPairs[(unsigned char) toupper(alphabet[i])][(unsigned char) tolower(alphabet[j])] = val; emitPairs[(unsigned char) toupper(alphabet[i])][(unsigned char) toupper(alphabet[j])] = val; emitPairs[(unsigned char) tolower(alphabet[j])][(unsigned char) tolower(alphabet[i])] = val; emitPairs[(unsigned char) tolower(alphabet[j])][(unsigned char) toupper(alphabet[i])] = val; emitPairs[(unsigned char) toupper(alphabet[j])][(unsigned char) tolower(alphabet[i])] = val; emitPairs[(unsigned char) toupper(alphabet[j])][(unsigned char) toupper(alphabet[i])] = val; } } for (int i = 0; i < (int) alphabet.size(); i++){ float val; data >> val; emitSingle[(unsigned char) tolower(alphabet[i])] = val; emitSingle[(unsigned char) toupper(alphabet[i])] = val; } data.close(); } } ///////////////////////////////////////////////////////////////// // ProcessTree() // // Process the tree recursively. Returns the aligned sequences // corresponding to a node or leaf of the tree. ///////////////////////////////////////////////////////////////// MultiSequence *ProcessTree (const TreeNode *tree, MultiSequence *sequences, const SafeVector > &sparseMatrices, const ProbabilisticModel &model){ MultiSequence *result; // check if this is a node of the alignment tree if (tree->GetSequenceLabel() == -1){ MultiSequence *alignLeft = ProcessTree (tree->GetLeftChild(), sequences, sparseMatrices, model); MultiSequence *alignRight = ProcessTree (tree->GetRightChild(), sequences, sparseMatrices, model); assert (alignLeft); assert (alignRight); result = AlignAlignments (alignLeft, alignRight, sparseMatrices, model); assert (result); delete alignLeft; delete alignRight; } // otherwise, this is a leaf of the alignment tree else { result = new MultiSequence(); assert (result); result->AddSequence (sequences->GetSequence(tree->GetSequenceLabel())->Clone()); } return result; } ///////////////////////////////////////////////////////////////// // ComputeFinalAlignment() // // Compute the final alignment by calling ProcessTree(), then // performing iterative refinement as needed. ///////////////////////////////////////////////////////////////// MultiSequence *ComputeFinalAlignment (const TreeNode *tree, MultiSequence *sequences, const SafeVector > &sparseMatrices, const ProbabilisticModel &model){ MultiSequence *alignment = ProcessTree (tree, sequences, sparseMatrices, model); SafeVector oldOrdering; if (enableAlignOrder){ for (int i = 0; i < alignment->GetNumSequences(); i++) oldOrdering.push_back (alignment->GetSequence(i)->GetSortLabel()); alignment->SaveOrdering(); enableAlignOrder = false; } // tree-based refinement // TreeBasedBiPartitioning (sparseMatrices, model, alignment, tree); // iterative refinement for (int i = 0; i < numIterativeRefinementReps; i++) DoIterativeRefinement (sparseMatrices, model, alignment); cerr << endl; if (oldOrdering.size() > 0){ for (int i = 0; i < (int) oldOrdering.size(); i++){ alignment->GetSequence(i)->SetSortLabel(oldOrdering[i]); } } // return final alignment return alignment; } ///////////////////////////////////////////////////////////////// // AlignAlignments() // // Returns the alignment of two MultiSequence objects. ///////////////////////////////////////////////////////////////// MultiSequence *AlignAlignments (MultiSequence *align1, MultiSequence *align2, const SafeVector > &sparseMatrices, const ProbabilisticModel &model){ // print some info about the alignment if (enableVerbose){ for (int i = 0; i < align1->GetNumSequences(); i++) cerr << ((i==0) ? "[" : ",") << align1->GetSequence(i)->GetLabel(); cerr << "] vs. "; for (int i = 0; i < align2->GetNumSequences(); i++) cerr << ((i==0) ? "[" : ",") << align2->GetSequence(i)->GetLabel(); cerr << "]: "; } VF *posterior = model.BuildPosterior (align1, align2, sparseMatrices, cutoff); pair *, float> alignment; // choose the alignment routine depending on the "cosmetic" gap penalties used if (gapOpenPenalty == 0 && gapContinuePenalty == 0) alignment = model.ComputeAlignment (align1->GetSequence(0)->GetLength(), align2->GetSequence(0)->GetLength(), *posterior); else alignment = model.ComputeAlignmentWithGapPenalties (align1, align2, *posterior, align1->GetNumSequences(), align2->GetNumSequences(), gapOpenPenalty, gapContinuePenalty); delete posterior; if (enableVerbose){ // compute total length of sequences int totLength = 0; for (int i = 0; i < align1->GetNumSequences(); i++) for (int j = 0; j < align2->GetNumSequences(); j++) totLength += min (align1->GetSequence(i)->GetLength(), align2->GetSequence(j)->GetLength()); // give an "accuracy" measure for the alignment cerr << alignment.second / totLength << endl; } // now build final alignment MultiSequence *result = new MultiSequence(); for (int i = 0; i < align1->GetNumSequences(); i++) result->AddSequence (align1->GetSequence(i)->AddGaps(alignment.first, 'X')); for (int i = 0; i < align2->GetNumSequences(); i++) result->AddSequence (align2->GetSequence(i)->AddGaps(alignment.first, 'Y')); if (!enableAlignOrder) result->SortByLabel(); // free temporary alignment delete alignment.first; return result; } ///////////////////////////////////////////////////////////////// // DoRelaxation() // // Performs one round of the consistency transformation. The // formula used is: // 1 // P'(x[i]-y[j]) = --- sum sum P(x[i]-z[k]) P(z[k]-y[j]) // |S| z in S k // // where S = {x, y, all other sequences...} // ///////////////////////////////////////////////////////////////// SafeVector > DoRelaxation (MultiSequence *sequences, SafeVector > &sparseMatrices){ const int numSeqs = sequences->GetNumSequences(); SafeVector > newSparseMatrices (numSeqs, SafeVector(numSeqs, NULL)); // for every pair of sequences for (int i = 0; i < numSeqs; i++){ for (int j = i+1; j < numSeqs; j++){ Sequence *seq1 = sequences->GetSequence (i); Sequence *seq2 = sequences->GetSequence (j); if (enableVerbose) cerr << "Relaxing (" << i+1 << ") " << seq1->GetHeader() << " vs. " << "(" << j+1 << ") " << seq2->GetHeader() << ": "; // get the original posterior matrix VF *posteriorPtr = sparseMatrices[i][j]->GetPosterior(); assert (posteriorPtr); VF &posterior = *posteriorPtr; const int seq1Length = seq1->GetLength(); const int seq2Length = seq2->GetLength(); // contribution from the summation where z = x and z = y for (int k = 0; k < (seq1Length+1) * (seq2Length+1); k++) posterior[k] += posterior[k]; if (enableVerbose) cerr << sparseMatrices[i][j]->GetNumCells() << " --> "; // contribution from all other sequences for (int k = 0; k < numSeqs; k++) if (k != i && k != j){ if (k < i) Relax1 (sparseMatrices[k][i], sparseMatrices[k][j], posterior); else if (k > i && k < j) Relax (sparseMatrices[i][k], sparseMatrices[k][j], posterior); else { SparseMatrix *temp = sparseMatrices[j][k]->ComputeTranspose(); Relax (sparseMatrices[i][k], temp, posterior); delete temp; } } // now renormalization for (int k = 0; k < (seq1Length+1) * (seq2Length+1); k++) posterior[k] /= numSeqs; // mask out positions not originally in the posterior matrix SparseMatrix *matXY = sparseMatrices[i][j]; for (int y = 0; y <= seq2Length; y++) posterior[y] = 0; for (int x = 1; x <= seq1Length; x++){ SafeVector::iterator XYptr = matXY->GetRowPtr(x); SafeVector::iterator XYend = XYptr + matXY->GetRowSize(x); VF::iterator base = posterior.begin() + x * (seq2Length + 1); int curr = 0; while (XYptr != XYend){ // zero out all cells until the first filled column while (curr < XYptr->first){ base[curr] = 0; curr++; } // now, skip over this column curr++; ++XYptr; } // zero out cells after last column while (curr <= seq2Length){ base[curr] = 0; curr++; } } // save the new posterior matrix newSparseMatrices[i][j] = new SparseMatrix (seq1->GetLength(), seq2->GetLength(), posterior); newSparseMatrices[j][i] = NULL; if (enableVerbose) cerr << newSparseMatrices[i][j]->GetNumCells() << " -- "; delete posteriorPtr; if (enableVerbose) cerr << "done." << endl; } } return newSparseMatrices; } ///////////////////////////////////////////////////////////////// // Relax() // // Computes the consistency transformation for a single sequence // z, and adds the transformed matrix to "posterior". ///////////////////////////////////////////////////////////////// void Relax (SparseMatrix *matXZ, SparseMatrix *matZY, VF &posterior){ assert (matXZ); assert (matZY); int lengthX = matXZ->GetSeq1Length(); int lengthY = matZY->GetSeq2Length(); assert (matXZ->GetSeq2Length() == matZY->GetSeq1Length()); // for every x[i] for (int i = 1; i <= lengthX; i++){ SafeVector::iterator XZptr = matXZ->GetRowPtr(i); SafeVector::iterator XZend = XZptr + matXZ->GetRowSize(i); VF::iterator base = posterior.begin() + i * (lengthY + 1); // iterate through all x[i]-z[k] while (XZptr != XZend){ SafeVector::iterator ZYptr = matZY->GetRowPtr(XZptr->first); SafeVector::iterator ZYend = ZYptr + matZY->GetRowSize(XZptr->first); const float XZval = XZptr->second; // iterate through all z[k]-y[j] while (ZYptr != ZYend){ base[ZYptr->first] += XZval * ZYptr->second; ZYptr++; } XZptr++; } } } ///////////////////////////////////////////////////////////////// // Relax1() // // Computes the consistency transformation for a single sequence // z, and adds the transformed matrix to "posterior". ///////////////////////////////////////////////////////////////// void Relax1 (SparseMatrix *matZX, SparseMatrix *matZY, VF &posterior){ assert (matZX); assert (matZY); int lengthZ = matZX->GetSeq1Length(); int lengthY = matZY->GetSeq2Length(); // for every z[k] for (int k = 1; k <= lengthZ; k++){ SafeVector::iterator ZXptr = matZX->GetRowPtr(k); SafeVector::iterator ZXend = ZXptr + matZX->GetRowSize(k); // iterate through all z[k]-x[i] while (ZXptr != ZXend){ SafeVector::iterator ZYptr = matZY->GetRowPtr(k); SafeVector::iterator ZYend = ZYptr + matZY->GetRowSize(k); const float ZXval = ZXptr->second; VF::iterator base = posterior.begin() + ZXptr->first * (lengthY + 1); // iterate through all z[k]-y[j] while (ZYptr != ZYend){ base[ZYptr->first] += ZXval * ZYptr->second; ZYptr++; } ZXptr++; } } } ///////////////////////////////////////////////////////////////// // GetSubtree // // Returns set containing all leaf labels of the current subtree. ///////////////////////////////////////////////////////////////// set GetSubtree (const TreeNode *tree){ set s; if (tree->GetSequenceLabel() == -1){ s = GetSubtree (tree->GetLeftChild()); set t = GetSubtree (tree->GetRightChild()); for (set::iterator iter = t.begin(); iter != t.end(); ++iter) s.insert (*iter); } else { s.insert (tree->GetSequenceLabel()); } return s; } ///////////////////////////////////////////////////////////////// // TreeBasedBiPartitioning // // Uses the iterative refinement scheme from MUSCLE. ///////////////////////////////////////////////////////////////// void TreeBasedBiPartitioning (const SafeVector > &sparseMatrices, const ProbabilisticModel &model, MultiSequence* &alignment, const TreeNode *tree){ // check if this is a node of the alignment tree if (tree->GetSequenceLabel() == -1){ TreeBasedBiPartitioning (sparseMatrices, model, alignment, tree->GetLeftChild()); TreeBasedBiPartitioning (sparseMatrices, model, alignment, tree->GetRightChild()); set leftSubtree = GetSubtree (tree->GetLeftChild()); set rightSubtree = GetSubtree (tree->GetRightChild()); set leftSubtreeComplement, rightSubtreeComplement; // calculate complement of each subtree for (int i = 0; i < alignment->GetNumSequences(); i++){ if (leftSubtree.find(i) == leftSubtree.end()) leftSubtreeComplement.insert (i); if (rightSubtree.find(i) == rightSubtree.end()) rightSubtreeComplement.insert (i); } // perform realignments for edge to left child if (!leftSubtree.empty() && !leftSubtreeComplement.empty()){ MultiSequence *groupOneSeqs = alignment->Project (leftSubtree); assert (groupOneSeqs); MultiSequence *groupTwoSeqs = alignment->Project (leftSubtreeComplement); assert (groupTwoSeqs); delete alignment; alignment = AlignAlignments (groupOneSeqs, groupTwoSeqs, sparseMatrices, model); } // perform realignments for edge to right child if (!rightSubtree.empty() && !rightSubtreeComplement.empty()){ MultiSequence *groupOneSeqs = alignment->Project (rightSubtree); assert (groupOneSeqs); MultiSequence *groupTwoSeqs = alignment->Project (rightSubtreeComplement); assert (groupTwoSeqs); delete alignment; alignment = AlignAlignments (groupOneSeqs, groupTwoSeqs, sparseMatrices, model); } } } ///////////////////////////////////////////////////////////////// // DoIterativeRefinement() // // Performs a single round of randomized partionining iterative // refinement. ///////////////////////////////////////////////////////////////// void DoIterativeRefinement (const SafeVector > &sparseMatrices, const ProbabilisticModel &model, MultiSequence* &alignment){ set groupOne, groupTwo; // create two separate groups for (int i = 0; i < alignment->GetNumSequences(); i++){ if (rand() % 2) groupOne.insert (i); else groupTwo.insert (i); } if (groupOne.empty() || groupTwo.empty()) return; // project into the two groups MultiSequence *groupOneSeqs = alignment->Project (groupOne); assert (groupOneSeqs); MultiSequence *groupTwoSeqs = alignment->Project (groupTwo); assert (groupTwoSeqs); delete alignment; // realign alignment = AlignAlignments (groupOneSeqs, groupTwoSeqs, sparseMatrices, model); delete groupOneSeqs; delete groupTwoSeqs; } ///////////////////////////////////////////////////////////////// // WriteAnnotation() // // Computes annotation for multiple alignment and write values // to a file. ///////////////////////////////////////////////////////////////// void WriteAnnotation (MultiSequence *alignment, const SafeVector > &sparseMatrices){ ofstream outfile (annotationFilename.c_str()); if (outfile.fail()){ cerr << "ERROR: Unable to write annotation file." << endl; exit (1); } const int alignLength = alignment->GetSequence(0)->GetLength(); const int numSeqs = alignment->GetNumSequences(); SafeVector position (numSeqs, 0); SafeVector::iterator> seqs (numSeqs); for (int i = 0; i < numSeqs; i++) seqs[i] = alignment->GetSequence(i)->GetDataPtr(); SafeVector > active; active.reserve (numSeqs); SafeVector lab; for (int i = 0; i < numSeqs; i++) lab.push_back(alignment->GetSequence(i)->GetSortLabel()); // for every column for (int i = 1; i <= alignLength; i++){ // find all aligned residues in this particular column active.clear(); for (int j = 0; j < numSeqs; j++){ if (seqs[j][i] != '-'){ active.push_back (make_pair(lab[j], ++position[j])); } } sort (active.begin(), active.end()); outfile << setw(4) << ComputeScore (active, sparseMatrices) << endl; } outfile.close(); } ///////////////////////////////////////////////////////////////// // ComputeScore() // // Computes the annotation score for a particular column. ///////////////////////////////////////////////////////////////// int ComputeScore (const SafeVector > &active, const SafeVector > &sparseMatrices){ if (active.size() <= 1) return 0; // ALTERNATIVE #1: Compute the average alignment score. float val = 0; for (int i = 0; i < (int) active.size(); i++){ for (int j = i+1; j < (int) active.size(); j++){ val += sparseMatrices[active[i].first][active[j].first]->GetValue(active[i].second, active[j].second); } } return (int) (200 * val / ((int) active.size() * ((int) active.size() - 1))); }