changed output format to contain FPKM etc. ; fixed a bug for paired-end reads

[rsem.git] / EM.cpp

#include<ctime>
#include<cmath>
#include<cstdio>
#include<cstdlib>
#include<cstring>
#include<cassert>
#include<string>
#include<vector>
#include<algorithm>
#include<fstream>
#include<iostream>
#include<pthread.h>

#include "utils.h"
#include "my_assert.h"
#include "sampling.h"

#include "Read.h"
#include "SingleRead.h"
#include "SingleReadQ.h"
#include "PairedEndRead.h"
#include "PairedEndReadQ.h"

#include "SingleHit.h"
#include "PairedEndHit.h"

#include "Model.h"
#include "SingleModel.h"
#include "SingleQModel.h"
#include "PairedEndModel.h"
#include "PairedEndQModel.h"

#include "Transcript.h"
#include "Transcripts.h"

#include "Refs.h"
#include "GroupInfo.h"
#include "HitContainer.h"
#include "ReadIndex.h"
#include "ReadReader.h"

#include "ModelParams.h"

#include "HitWrapper.h"
#include "BamWriter.h"

using namespace std;

const double STOP_CRITERIA = 0.001;
const int MAX_ROUND = 10000;
const int MIN_ROUND = 20;

struct Params {
        void *model;
        void *reader, *hitv, *ncpv, *mhp, *countv;
};

int read_type;
int m, M; // m genes, M isoforms
READ_INT_TYPE N0, N1, N2, N_tot;
int nThreads;


bool genBamF; // If user wants to generate bam file, true; otherwise, false.
bool bamSampling; // true if sampling from read posterior distribution when bam file is generated
bool updateModel, calcExpectedWeights;
bool genGibbsOut; // generate file for Gibbs sampler

char refName[STRLEN], outName[STRLEN];
char imdName[STRLEN], statName[STRLEN];
char refF[STRLEN], groupF[STRLEN], cntF[STRLEN], tiF[STRLEN];
char mparamsF[STRLEN];
char modelF[STRLEN], thetaF[STRLEN];

char inpSamType;
char *pt_fn_list, *pt_chr_list;
char inpSamF[STRLEN], outBamF[STRLEN], fn_list[STRLEN], chr_list[STRLEN];

char out_for_gibbs_F[STRLEN];

vector<double> theta, eel; // eel : expected effective length

double *probv, **countvs;

Refs refs;
GroupInfo gi;
Transcripts transcripts;

ModelParams mparams;

template<class ReadType, class HitType, class ModelType>
void init(ReadReader<ReadType> **&readers, HitContainer<HitType> **&hitvs, double **&ncpvs, ModelType **&mhps) {
        READ_INT_TYPE nReads;
        HIT_INT_TYPE nHits;
        int rt; // read type

        READ_INT_TYPE nrLeft, curnr; // nrLeft : number of reads left, curnr: current number of reads
        HIT_INT_TYPE nhT; // nhT : hit threshold per thread
        char datF[STRLEN];

        int s;
        char readFs[2][STRLEN];
        ReadIndex *indices[2];
        ifstream fin;

        readers = new ReadReader<ReadType>*[nThreads];
        genReadFileNames(imdName, 1, read_type, s, readFs);
        for (int i = 0; i < s; i++) {
                indices[i] = new ReadIndex(readFs[i]);
        }
        for (int i = 0; i < nThreads; i++) {
                readers[i] = new ReadReader<ReadType>(s, readFs, refs.hasPolyA(), mparams.seedLen); // allow calculation of calc_lq() function
                readers[i]->setIndices(indices);
        }

        hitvs = new HitContainer<HitType>*[nThreads];
        for (int i = 0; i < nThreads; i++) {
                hitvs[i] = new HitContainer<HitType>();
        }

        sprintf(datF, "%s.dat", imdName);
        fin.open(datF);
        general_assert(fin.is_open(), "Cannot open " + cstrtos(datF) + "! It may not exist.");
        fin>>nReads>>nHits>>rt;
        general_assert(nReads == N1, "Number of alignable reads does not match!");
        general_assert(rt == read_type, "Data file (.dat) does not have the right read type!");


        //A just so so strategy for paralleling
        nhT = nHits / nThreads;
        nrLeft = N1;
        curnr = 0;

        ncpvs = new double*[nThreads];
        for (int i = 0; i < nThreads; i++) {
                HIT_INT_TYPE ntLeft = nThreads - i - 1; // # of threads left

                general_assert(readers[i]->locate(curnr), "Read indices files do not match!");

                while (nrLeft > ntLeft && (i == nThreads - 1 || hitvs[i]->getNHits() < nhT)) {
                        general_assert(hitvs[i]->read(fin), "Cannot read alignments from .dat file!");

                        --nrLeft;
                        if (verbose && nrLeft % 1000000 == 0) { cout<< "DAT "<< nrLeft << " reads left"<< endl; }
                }
                ncpvs[i] = new double[hitvs[i]->getN()];
                memset(ncpvs[i], 0, sizeof(double) * hitvs[i]->getN());
                curnr += hitvs[i]->getN();

                if (verbose) { cout<<"Thread "<< i<< " : N = "<< hitvs[i]->getN()<< ", NHit = "<< hitvs[i]->getNHits()<< endl; }
        }

        fin.close();

        mhps = new ModelType*[nThreads];
        for (int i = 0; i < nThreads; i++) {
                mhps[i] = new ModelType(mparams, false); // just model helper
        }

        probv = new double[M + 1];
        countvs = new double*[nThreads];
        for (int i = 0; i < nThreads; i++) {
                countvs[i] = new double[M + 1];
        }


        if (verbose) { printf("EM_init finished!\n"); }
}

template<class ReadType, class HitType, class ModelType>
void* E_STEP(void* arg) {
        Params *params = (Params*)arg;
        ModelType *model = (ModelType*)(params->model);
        ReadReader<ReadType> *reader = (ReadReader<ReadType>*)(params->reader);
        HitContainer<HitType> *hitv = (HitContainer<HitType>*)(params->hitv);
        double *ncpv = (double*)(params->ncpv);
        ModelType *mhp = (ModelType*)(params->mhp);
        double *countv = (double*)(params->countv);

        bool needCalcConPrb = model->getNeedCalcConPrb();

        ReadType read;

        READ_INT_TYPE N = hitv->getN();
        double sum;
        vector<double> fracs; //to remove this, do calculation twice
        HIT_INT_TYPE fr, to, id;

        if (needCalcConPrb || updateModel) { reader->reset(); }
        if (updateModel) { mhp->init(); }

        memset(countv, 0, sizeof(double) * (M + 1));
        for (READ_INT_TYPE i = 0; i < N; i++) {
                if (needCalcConPrb || updateModel) {
                        general_assert(reader->next(read), "Can not load a read!");
                }

                fr = hitv->getSAt(i);
                to = hitv->getSAt(i + 1);
                fracs.resize(to - fr + 1);

                sum = 0.0;

                if (needCalcConPrb) { ncpv[i] = model->getNoiseConPrb(read); }
                fracs[0] = probv[0] * ncpv[i];
                if (fracs[0] < EPSILON) fracs[0] = 0.0;
                sum += fracs[0];
                for (HIT_INT_TYPE j = fr; j < to; j++) {
                        HitType &hit = hitv->getHitAt(j);
                        if (needCalcConPrb) { hit.setConPrb(model->getConPrb(read, hit)); }
                        id = j - fr + 1;
                        fracs[id] = probv[hit.getSid()] * hit.getConPrb();
                        if (fracs[id] < EPSILON) fracs[id] = 0.0;
                        sum += fracs[id];
                }

                if (sum >= EPSILON) {
                        fracs[0] /= sum;
                        countv[0] += fracs[0];
                        if (updateModel) { mhp->updateNoise(read, fracs[0]); }
                        if (calcExpectedWeights) { ncpv[i] = fracs[0]; }
                        for (HIT_INT_TYPE j = fr; j < to; j++) {
                                HitType &hit = hitv->getHitAt(j);
                                id = j - fr + 1;
                                fracs[id] /= sum;
                                countv[hit.getSid()] += fracs[id];
                                if (updateModel) { mhp->update(read, hit, fracs[id]); }
                                if (calcExpectedWeights) { hit.setConPrb(fracs[id]); }
                        }                       
                }
                else if (calcExpectedWeights) {
                        ncpv[i] = 0.0;
                        for (HIT_INT_TYPE j = fr; j < to; j++) {
                                HitType &hit = hitv->getHitAt(j);
                                hit.setConPrb(0.0);
                        }
                }
        }

        return NULL;
}

template<class ReadType, class HitType, class ModelType>
void* calcConProbs(void* arg) {
        Params *params = (Params*)arg;
        ModelType *model = (ModelType*)(params->model);
        ReadReader<ReadType> *reader = (ReadReader<ReadType>*)(params->reader);
        HitContainer<HitType> *hitv = (HitContainer<HitType>*)(params->hitv);
        double *ncpv = (double*)(params->ncpv);

        ReadType read;
        READ_INT_TYPE N = hitv->getN();
        HIT_INT_TYPE fr, to;

        assert(model->getNeedCalcConPrb());
        reader->reset();

        for (READ_INT_TYPE i = 0; i < N; i++) {
                general_assert(reader->next(read), "Can not load a read!");

                fr = hitv->getSAt(i);
                to = hitv->getSAt(i + 1);

                ncpv[i] = model->getNoiseConPrb(read);
                for (HIT_INT_TYPE j = fr; j < to; j++) {
                        HitType &hit = hitv->getHitAt(j);
                        hit.setConPrb(model->getConPrb(read, hit));
                }
        }

        return NULL;
}

template<class ModelType>
void calcExpectedEffectiveLengths(ModelType& model) {
        int lb, ub, span;
        double *pdf = NULL, *cdf = NULL, *clen = NULL; // clen[i] = sigma_{j=1}^{i}pdf[i]*(lb+i)
  
        model.getGLD().copyTo(pdf, cdf, lb, ub, span);
        clen = new double[span + 1];
        clen[0] = 0.0;
        for (int i = 1; i <= span; i++) {
                clen[i] = clen[i - 1] + pdf[i] * (lb + i);
        }

        eel.assign(M + 1, 0.0);
        for (int i = 1; i <= M; i++) {
                int totLen = refs.getRef(i).getTotLen();
                int fullLen = refs.getRef(i).getFullLen();
                int pos1 = max(min(totLen - fullLen + 1, ub) - lb, 0);
                int pos2 = max(min(totLen, ub) - lb, 0);

                if (pos2 == 0) { eel[i] = 0.0; continue; }
    
                eel[i] = fullLen * cdf[pos1] + ((cdf[pos2] - cdf[pos1]) * (totLen + 1) - (clen[pos2] - clen[pos1]));
                assert(eel[i] >= 0);
                if (eel[i] < MINEEL) { eel[i] = 0.0; }
        }
  
        delete[] pdf;
        delete[] cdf;
        delete[] clen;
}

void polishTheta(vector<double>& theta, const vector<double>& eel, const double* mw) {
        double sum = 0.0;

        /* The reason that for noise gene, mw value is 1 is :
         * currently, all masked positions are for poly(A) sites, which in theory should be filtered out.
         * So the theta0 does not containing reads from any masked position
         */

        for (int i = 0; i <= M; i++) {
                // i == 0, mw[i] == 1
                if (i > 0 && (mw[i] < EPSILON || eel[i] < EPSILON)) {
                        theta[i] = 0.0;
                        continue;
                }
                theta[i] = theta[i] / mw[i];
                sum += theta[i];
        }
        // currently is OK, since no transcript should be masked totally, only the poly(A) tail related part will be masked
        general_assert(sum >= EPSILON, "No effective length is no less than" + ftos(MINEEL, 6) + " !");
        for (int i = 0; i <= M; i++) theta[i] /= sum;
}

void calcExpressionValues(const vector<double>& theta, const vector<double>& eel, vector<double>& tpm, vector<double>& fpkm) {
        double denom;
        vector<double> frac;

        //calculate fraction of count over all mappabile reads
        denom = 0.0;
        frac.assign(M + 1, 0.0);
        for (int i = 1; i <= M; i++) 
          if (eel[i] >= EPSILON) {
            frac[i] = theta[i];
            denom += frac[i];
          }
        general_assert(denom > 0, "No alignable reads?!");
        for (int i = 1; i <= M; i++) frac[i] /= denom;
  
        //calculate FPKM
        fpkm.assign(M + 1, 0.0);
        for (int i = 1; i <= M; i++)
                if (eel[i] >= EPSILON) fpkm[i] = frac[i] * 1e9 / eel[i];

        //calculate TPM
        tpm.assign(M + 1, 0.0);
        denom = 0.0;
        for (int i = 1; i <= M; i++) denom += fpkm[i];
        for (int i = 1; i <= M; i++) tpm[i] = fpkm[i] / denom * 1e6;  
}

template<class ModelType>
void writeResults(ModelType& model, double* counts) {
        char outF[STRLEN];
        FILE *fo;

        sprintf(modelF, "%s.model", statName);
        model.write(modelF);

        vector<int> tlens;
        vector<double> fpkm, tpm, isopct;
        vector<double> glens, gene_eels, gene_counts, gene_tpm, gene_fpkm;

        calcExpressionValues(theta, eel, tpm, fpkm);

        //calculate IsoPct, etc.
        isopct.assign(M + 1, 0.0);
        tlens.assign(M + 1, 0);

        glens.assign(m, 0.0); gene_eels.assign(m, 0.0);
        gene_counts.assign(m, 0.0); gene_tpm.assign(m, 0.0); gene_fpkm.assign(m, 0.0);

        for (int i = 0; i < m; i++) {
                int b = gi.spAt(i), e = gi.spAt(i + 1);
                for (int j = b; j < e; j++) {
                        const Transcript& transcript = transcripts.getTranscriptAt(j);
                        tlens[j] = transcript.getLength();

                        glens[i] += tlens[j] * tpm[j];
                        gene_eels[i] += eel[j] * tpm[j];
                        gene_counts[i] += counts[j];
                        gene_tpm[i] += tpm[j];
                        gene_fpkm[i] += fpkm[j];
                }

                if (gene_tpm[i] < EPSILON) continue;

                for (int j = b; j < e; j++)
                        isopct[j] = tpm[j] / gene_tpm[i];
                glens[i] /= gene_tpm[i];
                gene_eels[i] /= gene_tpm[i];
        }

        //isoform level results
        sprintf(outF, "%s.iso_res", imdName);
        fo = fopen(outF, "w");
        for (int i = 1; i <= M; i++) {
                const Transcript& transcript = transcripts.getTranscriptAt(i);
                fprintf(fo, "%s%c", transcript.getTranscriptID().c_str(), (i < M ? '\t' : '\n'));
        }
        for (int i = 1; i <= M; i++) {
                const Transcript& transcript = transcripts.getTranscriptAt(i);
                fprintf(fo, "%s%c", transcript.getGeneID().c_str(), (i < M ? '\t' : '\n'));
        }
        for (int i = 1; i <= M; i++)
                fprintf(fo, "%d%c", tlens[i], (i < M ? '\t' : '\n'));
        for (int i = 1; i <= M; i++)
                fprintf(fo, "%.2f%c", eel[i], (i < M ? '\t' : '\n'));
        for (int i = 1; i <= M; i++)
                fprintf(fo, "%.2f%c", counts[i], (i < M ? '\t' : '\n'));
        for (int i = 1; i <= M; i++)
                fprintf(fo, "%.2f%c", tpm[i], (i < M ? '\t' : '\n'));
        for (int i = 1; i <= M; i++)
                fprintf(fo, "%.2f%c", fpkm[i], (i < M ? '\t' : '\n'));
        for (int i = 1; i <= M; i++)
                fprintf(fo, "%.2f%c", isopct[i] * 1e2, (i < M ? '\t' : '\n'));
        fclose(fo);

        //gene level results
        sprintf(outF, "%s.gene_res", imdName);
        fo = fopen(outF, "w");
        for (int i = 0; i < m; i++) {
                const Transcript& transcript = transcripts.getTranscriptAt(gi.spAt(i));
                fprintf(fo, "%s%c", transcript.getGeneID().c_str(), (i < m - 1 ? '\t' : '\n'));
        }
        for (int i = 0; i < m; i++) {
                int b = gi.spAt(i), e = gi.spAt(i + 1);
                for (int j = b; j < e; j++) {
                        fprintf(fo, "%s%c", transcripts.getTranscriptAt(j).getTranscriptID().c_str(), (j < e - 1 ? ',' : (i < m - 1 ? '\t' :'\n')));
                }
        }
        for (int i = 0; i < m; i++)
                fprintf(fo, "%.2f%c", glens[i], (i < m - 1 ? '\t' : '\n'));
        for (int i = 0; i < m; i++)
                fprintf(fo, "%.2f%c", gene_eels[i], (i < m - 1 ? '\t' : '\n'));
        for (int i = 0; i < m; i++)
                fprintf(fo, "%.2f%c", gene_counts[i], (i < m - 1 ? '\t' : '\n'));
        for (int i = 0; i < m; i++)
                fprintf(fo, "%.2f%c", gene_tpm[i], (i < m - 1 ? '\t' : '\n'));
        for (int i = 0; i < m; i++)
                fprintf(fo, "%.2f%c", gene_fpkm[i], (i < m - 1 ? '\t' : '\n'));
        fclose(fo);

        if (verbose) { printf("Expression Results are written!\n"); }
}

template<class ReadType, class HitType, class ModelType>
void release(ReadReader<ReadType> **readers, HitContainer<HitType> **hitvs, double **ncpvs, ModelType **mhps) {
        delete[] probv;
        for (int i = 0; i < nThreads; i++) {
                delete[] countvs[i];
        }
        delete[] countvs;

        for (int i = 0; i < nThreads; i++) {
                delete readers[i];
                delete hitvs[i];
                delete[] ncpvs[i];
                delete mhps[i];
        }
        delete[] readers;
        delete[] hitvs;
        delete[] ncpvs;
        delete[] mhps;
}

inline bool doesUpdateModel(int ROUND) {
  //  return ROUND <= 20 || ROUND % 100 == 0;
  return ROUND <= 10;
}

//Including initialize, algorithm and results saving
template<class ReadType, class HitType, class ModelType>
void EM() {
        FILE *fo;

        int ROUND;
        double sum;

        double bChange = 0.0, change = 0.0; // bChange : biggest change
        int totNum = 0;

        ModelType model(mparams); //master model
        ReadReader<ReadType> **readers;
        HitContainer<HitType> **hitvs;
        double **ncpvs;
        ModelType **mhps; //model helpers

        Params fparams[nThreads];
        pthread_t threads[nThreads];
        pthread_attr_t attr;
        int rc;


        //initialize boolean variables
        updateModel = calcExpectedWeights = false;

        theta.clear();
        theta.resize(M + 1, 0.0);
        init<ReadType, HitType, ModelType>(readers, hitvs, ncpvs, mhps);

        //set initial parameters
        assert(N_tot > N2);
        theta[0] = max(N0 * 1.0 / (N_tot - N2), 1e-8);
        double val = (1.0 - theta[0]) / M;
        for (int i = 1; i <= M; i++) theta[i] = val;

        model.estimateFromReads(imdName);

        for (int i = 0; i < nThreads; i++) {
                fparams[i].model = (void*)(&model);

                fparams[i].reader = (void*)readers[i];
                fparams[i].hitv = (void*)hitvs[i];
                fparams[i].ncpv = (void*)ncpvs[i];
                fparams[i].mhp = (void*)mhps[i];
                fparams[i].countv = (void*)countvs[i];
        }

        /* set thread attribute to be joinable */
        pthread_attr_init(&attr);
        pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE);

        ROUND = 0;
        do {
                ++ROUND;

                updateModel = doesUpdateModel(ROUND);

                for (int i = 0; i <= M; i++) probv[i] = theta[i];

                //E step
                for (int i = 0; i < nThreads; i++) {
                        rc = pthread_create(&threads[i], &attr, E_STEP<ReadType, HitType, ModelType>, (void*)(&fparams[i]));
                        pthread_assert(rc, "pthread_create", "Cannot create thread " + itos(i) + " (numbered from 0) at ROUND " + itos(ROUND) + "!");
                }

                for (int i = 0; i < nThreads; i++) {
                        rc = pthread_join(threads[i], NULL);
                        pthread_assert(rc, "pthread_join", "Cannot join thread " + itos(i) + " (numbered from 0) at ROUND " + itos(ROUND) + "!");
                }

                model.setNeedCalcConPrb(false);

                for (int i = 1; i < nThreads; i++) {
                        for (int j = 0; j <= M; j++) {
                                countvs[0][j] += countvs[i][j];
                        }
                }

                //add N0 noise reads
                countvs[0][0] += N0;

                //M step;
                sum = 0.0;
                for (int i = 0; i <= M; i++) sum += countvs[0][i];
                assert(sum >= EPSILON);
                for (int i = 0; i <= M; i++) theta[i] = countvs[0][i] / sum;

                if (updateModel) {
                        model.init();
                        for (int i = 0; i < nThreads; i++) { model.collect(*mhps[i]); }
                        model.finish();
                }

                // Relative error
                bChange = 0.0; totNum = 0;
                for (int i = 0; i <= M; i++)
                        if (probv[i] >= 1e-7) {
                                change = fabs(theta[i] - probv[i]) / probv[i];
                                if (change >= STOP_CRITERIA) ++totNum;
                                if (bChange < change) bChange = change;
                        }

                if (verbose) { cout<< "ROUND = "<< ROUND<< ", SUM = "<< setprecision(15)<< sum<< ", bChange = " << setprecision(6)<< bChange<< ", totNum = " << totNum<< endl; }
        } while (ROUND < MIN_ROUND || (totNum > 0 && ROUND < MAX_ROUND));
//      } while (ROUND < 1);

        if (totNum > 0) { cout<< "Warning: RSEM reaches "<< MAX_ROUND<< " iterations before meeting the convergence criteria."<< endl; }

        //generate output file used by Gibbs sampler
        if (genGibbsOut) {
                if (model.getNeedCalcConPrb()) {
                        for (int i = 0; i < nThreads; i++) {
                                rc = pthread_create(&threads[i], &attr, calcConProbs<ReadType, HitType, ModelType>, (void*)(&fparams[i]));
                                pthread_assert(rc, "pthread_create", "Cannot create thread " + itos(i) + " (numbered from 0) when generating files for Gibbs sampler!");
                        }
                        for (int i = 0; i < nThreads; i++) {
                                rc = pthread_join(threads[i], NULL);
                                pthread_assert(rc, "pthread_join", "Cannot join thread " + itos(i) + " (numbered from 0) when generating files for Gibbs sampler!");
                        }
                }
                model.setNeedCalcConPrb(false);

                sprintf(out_for_gibbs_F, "%s.ofg", imdName);
                ofstream fout(out_for_gibbs_F);
                fout<< M<< " "<< N0<< endl;
                for (int i = 0; i < nThreads; i++) {
                        READ_INT_TYPE numN = hitvs[i]->getN();
                        for (READ_INT_TYPE j = 0; j < numN; j++) {
                                HIT_INT_TYPE fr = hitvs[i]->getSAt(j);
                                HIT_INT_TYPE to = hitvs[i]->getSAt(j + 1);
                                HIT_INT_TYPE totNum = 0;

                                if (ncpvs[i][j] >= EPSILON) { ++totNum; fout<< "0 "<< setprecision(15)<< ncpvs[i][j]<< " "; }
                                for (HIT_INT_TYPE k = fr; k < to; k++) {
                                        HitType &hit = hitvs[i]->getHitAt(k);
                                        if (hit.getConPrb() >= EPSILON) {
                                                ++totNum;
                                                fout<< hit.getSid()<< " "<< setprecision(15)<< hit.getConPrb()<< " ";
                                        }
                                }

                                if (totNum > 0) { fout<< endl; }
                        }
                }
                fout.close();
        }

        //calculate expected weights and counts using learned parameters
        //just use the raw theta learned from the data, do not correct for eel or mw
        updateModel = false; calcExpectedWeights = true;
        for (int i = 0; i <= M; i++) probv[i] = theta[i];
        for (int i = 0; i < nThreads; i++) {
                rc = pthread_create(&threads[i], &attr, E_STEP<ReadType, HitType, ModelType>, (void*)(&fparams[i]));
                pthread_assert(rc, "pthread_create", "Cannot create thread " + itos(i) + " (numbered from 0) when calculating expected weights!");
        }
        for (int i = 0; i < nThreads; i++) {
                rc = pthread_join(threads[i], NULL);
                pthread_assert(rc, "pthread_join", "Cannot join thread " + itos(i) + " (numbered from 0) when calculating expected weights!");
        }
        model.setNeedCalcConPrb(false);
        for (int i = 1; i < nThreads; i++) {
                for (int j = 0; j <= M; j++) {
                        countvs[0][j] += countvs[i][j];
                }
        }
        countvs[0][0] += N0;

        /* destroy attribute */
        pthread_attr_destroy(&attr);


        sprintf(thetaF, "%s.theta", statName);
        fo = fopen(thetaF, "w");
        fprintf(fo, "%d\n", M + 1);

        // output theta'
        for (int i = 0; i < M; i++) fprintf(fo, "%.15g ", theta[i]);
        fprintf(fo, "%.15g\n", theta[M]);
        
        //calculate expected effective lengths for each isoform
        calcExpectedEffectiveLengths<ModelType>(model);
        polishTheta(theta, eel, model.getMW());

        // output theta
        for (int i = 0; i < M; i++) fprintf(fo, "%.15g ", theta[i]);
        fprintf(fo, "%.15g\n", theta[M]);

        fclose(fo);

        writeResults<ModelType>(model, countvs[0]);

        if (genBamF) {
                sprintf(outBamF, "%s.transcript.bam", outName);
                
                if (bamSampling) {
                        READ_INT_TYPE local_N;
                        HIT_INT_TYPE fr, to, len, id;
                        vector<double> arr;
                        uniform01 rg(engine_type(time(NULL)));

                        if (verbose) cout<< "Begin to sample reads from their posteriors."<< endl;
                        for (int i = 0; i < nThreads; i++) {
                                local_N = hitvs[i]->getN();
                                for (READ_INT_TYPE j = 0; j < local_N; j++) {
                                        fr = hitvs[i]->getSAt(j);
                                        to = hitvs[i]->getSAt(j + 1);
                                        len = to - fr + 1;
                                        arr.assign(len, 0);
                                        arr[0] = ncpvs[i][j];
                                        for (HIT_INT_TYPE k = fr; k < to; k++) arr[k - fr + 1] = arr[k - fr] + hitvs[i]->getHitAt(k).getConPrb();
                                        id = (arr[len - 1] < EPSILON ? -1 : sample(rg, arr, len)); // if all entries in arr are 0, let id be -1
                                        for (HIT_INT_TYPE k = fr; k < to; k++) hitvs[i]->getHitAt(k).setConPrb(k - fr + 1 == id ? 1.0 : 0.0);
                                }
                        }

                        if (verbose) cout<< "Sampling is finished."<< endl;
                }

                BamWriter writer(inpSamType, inpSamF, pt_fn_list, outBamF, transcripts);
                HitWrapper<HitType> wrapper(nThreads, hitvs);
                writer.work(wrapper);
        }

        release<ReadType, HitType, ModelType>(readers, hitvs, ncpvs, mhps);
}

int main(int argc, char* argv[]) {
        ifstream fin;
        bool quiet = false;

        if (argc < 6) {
                printf("Usage : rsem-run-em refName read_type sampleName imdName statName [-p #Threads] [-b samInpType samInpF has_fn_list_? [fn_list]] [-q] [--gibbs-out] [--sampling]\n\n");
                printf("  refName: reference name\n");
                printf("  read_type: 0 single read without quality score; 1 single read with quality score; 2 paired-end read without quality score; 3 paired-end read with quality score.\n");
                printf("  sampleName: sample's name, including the path\n");
                printf("  sampleToken: sampleName excludes the path\n");
                printf("  -p: number of threads which user wants to use. (default: 1)\n");
                printf("  -b: produce bam format output file. (default: off)\n");
                printf("  -q: set it quiet\n");
                printf("  --gibbs-out: generate output file used by Gibbs sampler. (default: off)\n");
                printf("  --sampling: sample each read from its posterior distribution when bam file is generated. (default: off)\n");
                printf("// model parameters should be in imdName.mparams.\n");
                exit(-1);
        }

        time_t a = time(NULL);

        strcpy(refName, argv[1]);
        read_type = atoi(argv[2]);
        strcpy(outName, argv[3]);
        strcpy(imdName, argv[4]);
        strcpy(statName, argv[5]);

        nThreads = 1;

        genBamF = false;
        bamSampling = false;
        genGibbsOut = false;
        pt_fn_list = pt_chr_list = NULL;

        for (int i = 6; i < argc; i++) {
                if (!strcmp(argv[i], "-p")) { nThreads = atoi(argv[i + 1]); }
                if (!strcmp(argv[i], "-b")) {
                        genBamF = true;
                        inpSamType = argv[i + 1][0];
                        strcpy(inpSamF, argv[i + 2]);
                        if (atoi(argv[i + 3]) == 1) {
                                strcpy(fn_list, argv[i + 4]);
                                pt_fn_list = (char*)(&fn_list);
                        }
                }
                if (!strcmp(argv[i], "-q")) { quiet = true; }
                if (!strcmp(argv[i], "--gibbs-out")) { genGibbsOut = true; }
                if (!strcmp(argv[i], "--sampling")) { bamSampling = true; }
        }

        general_assert(nThreads > 0, "Number of threads should be bigger than 0!");

        verbose = !quiet;

        //basic info loading
        sprintf(refF, "%s.seq", refName);
        refs.loadRefs(refF);
        M = refs.getM();
        sprintf(groupF, "%s.grp", refName);
        gi.load(groupF);
        m = gi.getm();

        sprintf(tiF, "%s.ti", refName);
        transcripts.readFrom(tiF);

        sprintf(cntF, "%s.cnt", statName);
        fin.open(cntF);

        general_assert(fin.is_open(), "Cannot open " + cstrtos(cntF) + "! It may not exist.");

        fin>>N0>>N1>>N2>>N_tot;
        fin.close();

        general_assert(N1 > 0, "There are no alignable reads!");

        if ((READ_INT_TYPE)nThreads > N1) nThreads = N1;

        //set model parameters
        mparams.M = M;
        mparams.N[0] = N0; mparams.N[1] = N1; mparams.N[2] = N2;
        mparams.refs = &refs;

        sprintf(mparamsF, "%s.mparams", imdName);
        fin.open(mparamsF);

        general_assert(fin.is_open(), "Cannot open " + cstrtos(mparamsF) + "It may not exist.");

        fin>> mparams.minL>> mparams.maxL>> mparams.probF;
        int val; // 0 or 1 , for estRSPD
        fin>>val;
        mparams.estRSPD = (val != 0);
        fin>> mparams.B>> mparams.mate_minL>> mparams.mate_maxL>> mparams.mean>> mparams.sd;
        fin>> mparams.seedLen;
        fin.close();

        //run EM
        switch(read_type) {
        case 0 : EM<SingleRead, SingleHit, SingleModel>(); break;
        case 1 : EM<SingleReadQ, SingleHit, SingleQModel>(); break;
        case 2 : EM<PairedEndRead, PairedEndHit, PairedEndModel>(); break;
        case 3 : EM<PairedEndReadQ, PairedEndHit, PairedEndQModel>(); break;
        default : fprintf(stderr, "Unknown Read Type!\n"); exit(-1);
        }

        time_t b = time(NULL);

        printTimeUsed(a, b, "EM.cpp");

        return 0;
}