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#include "aligns/KmerAlignCore.h"
#include "analysis/DNAVector.h"
#include "analysis/KmerTable.h"
#include "util/mutil.h"
#include "analysis/NonRedKmerTable.h"
int K = 12;
const vecDNAVector * pAll = NULL;
DNAVector dummy;
KmerSequence::KmerSequence(int k, const vecDNAVector * p)
{
m_count = 0;
K = k;
pAll = p;
}
int KmerSequence::GetK() const
{
return K;
}
long long KmerSequence::BasesToNumber(const DNAVector & d, int off) {
long long i;
dummy = d;
KmerEntry dummyKmer;
dummyKmer.SetIndex(-1, off);
//cout << "Searching " << tmp << endl;
long long ret = BinSearch(m_kmers, dummyKmer);
return ret;
}
long long KmerSequence::BasesToNumberCount(int & count, const DNAVector & d, int off) {
long long i;
dummy = d;
KmerEntry dummyKmer;
dummyKmer.SetIndex(-1, off);
//cout << "Searching " << tmp << endl;
long long ret = BinSearch(m_kmers, dummyKmer);
//cout << "ret=" << ret << endl;
count = 0;
if (ret < 0)
return -1;
for (i=ret; i<m_kmers.lsize(); i++) {
//cout << "ret=" << ret << " i=" << i << endl;
if (m_kmers[i] < m_kmers[ret])
break;
if (m_kmers[ret] < m_kmers[i])
break;
count++;
}
return ret;
}
long long KmerSequence::BasesToNumberCountPlus(svec<IDS> & ids, long long & count, const DNAVector & d, int edge) {
long long i;
dummy = d;
KmerEntry dummyKmer;
dummyKmer.SetIndex(-1, 0);
//cout << "Searching " << tmp << endl;
//FIXME
//------------------------------------------------------------
// note, this is very confusing as written. global 'dummy', as assigned to parameter kmer 'd' is actually being searched.
//------------------------------------------------------------
long long ret = BinSearch(m_kmers, dummyKmer);
//cerr << "ret=" << ret << endl;
count = 0;
if (ret < 0) {
//cerr << "Searched: " << d.AsString() << "\tMISSING" << endl;
return -1;
}
for (i=ret; i<m_kmers.lsize(); i++) {
//cerr << "ret=" << ret << " i=" << i << endl;
if (m_kmers[i] < m_kmers[ret])
break;
if (m_kmers[ret] < m_kmers[i])
break;
ids.push_back(IDS(m_kmers[i].Index(), m_kmers[i].Pos(), edge));
count++;
}
// cerr << "Searched: " << d.AsString() << "\tcount: " << count << endl;
return ret;
}
void KmerSequence::Add(const vecDNAVector & all)
{
pAll = &all;
//long long est = (long long)(all[0].isize()-K+1)*(long long)all.isize();
size_t est = 0;
for (size_t i=0; i<all.size(); i++) {
est += (all[i].size()-K+1);
}
// cout << "Estimate space: " << est << endl;
m_kmers.resize(est);
m_count = 0;
for (size_t j=0; j<all.size(); j++) {
const DNAVector & d = all[j];
for (int i=0; i<=d.isize()-K; i++) {
if (m_kmers.lsize() <= m_count)
m_kmers.resize(m_count + 1000000);
m_kmers[m_count].SetIndex(j, i);
m_count++;
}
}
// cout << "Effective space: " << m_count << endl;
m_kmers.resize(m_count);
// cout << "Sorting..." << endl;
Sort(m_kmers);
// cout << "done!" << endl;
}
void KmerSequence::AddRestrict(const vecDNAVector & all, const vecDNAVector & restrict)
{
pAll = &all;
cout << "Restriction table..." << endl;
NonRedKmerTable nr(K);
nr.SetUp(restrict);
long long est = (long long)(all[0].isize()-K+1)*all.size() / 4;
cout << "Estimate space: " << est << " (" << est * 4 << ")" << endl;
m_kmers.resize(est);
m_count = 0;
int kk = 0;
for (size_t j=0; j<all.size(); j++) {
const DNAVector & d = all[j];
for (int i=0; i<=d.isize()-K; i++) {
if (m_kmers.lsize() <= m_count)
m_kmers.resize(m_count + 1000000);
kk++;
if (kk % 1000000 == 0) {
cout << kk << " (" << m_count << ")" << endl;
}
if (!nr.IsPresent(d, i))
continue;
m_kmers[m_count].SetIndex(j, i);
m_count++;
}
}
cout << "Effective space: " << m_count << endl;
m_kmers.resize(m_count);
cout << "Sorting..." << endl;
Sort(m_kmers);
cout << "done!" << endl;
}
bool KmerEntry::operator < (const KmerEntry & k) const {
int i;
//const DNAVector & me = (*pAll)[m_index];
const DNAVector * me = NULL;
if (m_index < 0) {
//cout << "Using dummy." << endl;
me = &dummy;
} else {
me = &((*pAll)[m_index]);
}
const DNAVector * you = NULL;
if (k.Index() < 0) {
//cout << "Using dummy." << endl;
you = &dummy;
} else {
you = &((*pAll)[k.Index()]);
}
//ML: perform the actual comparison on the raw char array
const char* me_str = ( &((*me)[0]) ) + m_pos;
const char* you_str = ( &((*you)[0]) ) + k.Pos();
for (i=0; i<K; i++) {
if (me_str[i] > you_str[i])
return false;
if (me_str[i] < you_str[i])
return true;
}
return false;
}
void KmerSequence::Read(const string & fileName)
{
int ver;
CMReadFileStream f;
f.Open(fileName.c_str());
long long s;
f.Read(ver);
f.Read(s);
f.Read(K);
m_kmers.resize(s);
for (int i=0; i<s; i++) {
int index, pos;
f.Read(index);
f.Read(pos);
m_kmers[i].SetIndex(index, pos);
}
}
void KmerSequence::Write(const string & fileName)
{
int ver = 1;
CMWriteFileStream f;
f.Open(fileName.c_str());
f.Write(ver);
f.Write(m_count);
f.Write(m_kmers.isize());
f.Write(K);
for (int i=0; i<m_kmers.isize(); i++) {
f.Write(m_kmers[i].Index());
f.Write(m_kmers[i].Pos());
}
}
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