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ClusterUpdate.cpp
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ClusterUpdate.cpp
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#include <iostream>
#include <string>
#include <sstream>
#include <fstream>
#include <vector>
#include <set>
#include <cstdlib>
#include <algorithm>
#include <boost/algorithm/string/split.hpp>
#include <boost/algorithm/string.hpp>
#include <boost/lexical_cast.hpp>
#define THRESHOLD 10
using namespace std;
using namespace boost;
struct GPD {
string gname;
string tname;
string chro;
string strand;
int start;
int end;
int cstart;
int cend;
int nblock;
vector<int> vec_exon_start;
vector<int> vec_exon_end;
};
void BuildGPDFromString (string &str, GPD &gpd) {
vector<string> vec_temp;
boost::split(vec_temp, str, boost::is_any_of("\t"));
gpd.gname = vec_temp[0];
gpd.tname = vec_temp[1];
int L = vec_temp[2].length();
gpd.chro = vec_temp[2];
gpd.strand = vec_temp[3];
gpd.start = lexical_cast<int>(vec_temp[4]);
gpd.end = lexical_cast<int>(vec_temp[5]);
gpd.cstart = lexical_cast<int>(vec_temp[6]);
gpd.cend = lexical_cast<int>(vec_temp[7]);
gpd.nblock = lexical_cast<int>(vec_temp[8]);
vector<string> vec1;
boost::split(vec1, vec_temp[9], boost::is_any_of(","));
for(int i = 0; i < vec1.size() - 1; ++i) (gpd.vec_exon_start).push_back(lexical_cast<int>(vec1[i]));
vector<string> vec2;
boost::split(vec2, vec_temp[10], boost::is_any_of(","));
for(int i = 0; i < vec2.size() - 1; ++i) (gpd.vec_exon_end).push_back(lexical_cast<int>(vec2[i]));
}
void DisplayGPD (GPD gpd) {
cout << gpd.gname << endl;
cout << gpd.tname << endl;
cout << gpd.chro << endl;
cout << gpd.strand << endl;
cout << gpd.start << endl;
cout << gpd.end << endl;
cout << gpd.cstart << endl;
cout << gpd.cend << endl;
cout << gpd.nblock << endl;
for(int i = 0; i < gpd.vec_exon_start.size(); ++i) cout << gpd.vec_exon_start[i] << '\t';
cout << endl;
for(int i = 0; i < gpd.vec_exon_end.size(); ++i) cout << gpd.vec_exon_end[i] << '\t';
cout << endl;
}
void DisplayGPDinLine (GPD gpd) {
cout << gpd.gname << '\t' << gpd.tname << '\t' << gpd.chro << '\t' << gpd.strand << '\t' << gpd.start << '\t' << gpd.end << '\t' << gpd.cstart << '\t';
cout << gpd.cend << '\t' << gpd.nblock << '\t';
for(int i = 0; i < gpd.vec_exon_start.size(); ++i) cout << gpd.vec_exon_start[i] << ',';
cout << '\t';
for(int i = 0; i < gpd.vec_exon_end.size(); ++i) cout << gpd.vec_exon_end[i] << ',';
//cout << endl;
}
void DisplayGPDtoFile (GPD gpd, ofstream &ouf) {
ouf << gpd.gname << '\t' << gpd.tname << '\t' << gpd.chro << '\t' << gpd.strand << '\t' << gpd.start << '\t' << gpd.end << '\t' << gpd.cstart << '\t';
ouf << gpd.cend << '\t' << gpd.nblock << '\t';
for(int i = 0; i < gpd.vec_exon_start.size(); ++i) ouf << gpd.vec_exon_start[i] << ',';
ouf << '\t';
for(int i = 0; i < gpd.vec_exon_end.size(); ++i) ouf << gpd.vec_exon_end[i] << ',';
ouf << endl;
}
/*int compare_gpd_sort (const void *a, const void *b) {
if( (*(GPD*) a).chro > (*(GPD*) b).chro ) return 1;
else if ( (*(GPD*) a).chro == (*(GPD*) b).chro ){
if( (*(GPD*) a).start > (*(GPD*) b).start ) return 1;
else return -1;
}
else return -1;
}*/
int compare_two_gpd (GPD a, GPD b) {
if(a.chro > b.chro) return 1;
else if (a.chro == b.chro){
if(a.start > b.start ) return 1;
else return -1;
}
else return -1;
}
int BinarySearch (GPD gpd_query, GPD *gpd_array, int total) {
int up = 0;
int down = total - 1;
while(down - up > 1){
int middle = (up + down) / 2;
if(compare_two_gpd(gpd_array[middle],gpd_query) == 1) down = middle;
else up = middle;
}
return up;
}
pair<int,int> AlignGPD (GPD gpd_query, GPD gpd_base) {
int score = 0;
int divergence = 0;
if(gpd_query.chro != gpd_base.chro || gpd_query.nblock != gpd_base.nblock || gpd_query.strand != gpd_base.strand) score = 0; // Add the third condition on 2017-10-09.
else{
if(gpd_query.nblock == 1){
bool left_aligned = false;
bool right_aligned = false;
if(abs(gpd_query.start - gpd_base.start) < 100 || abs(gpd_query.start - gpd_base.cstart) < 100) left_aligned = true;
if(abs(gpd_query.end - gpd_base.end) < 100 || abs(gpd_query.end - gpd_base.cend) < 100) right_aligned = true;
divergence = abs(gpd_query.start - gpd_base.start) + abs(gpd_query.start - gpd_base.cstart);
if(left_aligned && right_aligned) score = 1;
else score = 0;
}
else{
bool aligned = true;
if(abs(gpd_query.vec_exon_end[0] - gpd_base.vec_exon_end[0]) > THRESHOLD) aligned = false;
divergence += abs(gpd_query.vec_exon_end[0] - gpd_base.vec_exon_end[0]);
for(int i = 1; i <= gpd_query.nblock - 2; ++i){
if(abs(gpd_query.vec_exon_start[i] - gpd_base.vec_exon_start[i]) > THRESHOLD) aligned = false;
if(abs(gpd_query.vec_exon_end[i] - gpd_base.vec_exon_end[i]) > THRESHOLD) aligned = false;
divergence = divergence + abs(gpd_query.vec_exon_start[i] - gpd_base.vec_exon_start[i]) + abs(gpd_query.vec_exon_end[i] - gpd_base.vec_exon_end[i]);
}
int last = gpd_query.nblock - 1;
if(abs(gpd_query.vec_exon_start[last] - gpd_base.vec_exon_start[last]) > THRESHOLD) aligned = false;
divergence += abs(gpd_query.vec_exon_start[last] - gpd_base.vec_exon_start[last]);
if(aligned) score = 2;
else score = 0;
}
}
return pair<int,int>(score,divergence);
}
int main (int argc, char **argv) {
ifstream inf(argv[1]);
ofstream ouf1(argv[2]);
ofstream ouf2(argv[3]);
vector<GPD> gpd_vec;
while(inf){
string strInput;
getline(inf, strInput);
if(strInput.length() > 0){
GPD gpd;
BuildGPDFromString(strInput, gpd);
gpd_vec.push_back(gpd);
}
}
inf.close();
//qsort(&gpd_vec[0],gpd_vec.size(),sizeof(GPD),compare_gpd_sort);
vector<GPD> cluster;
vector<int> indicator;
vector<int> abundance;
cluster.push_back(gpd_vec[0]);
indicator.push_back(0);
abundance.push_back(1);
int index;
for(int i = 1; i < gpd_vec.size(); ++i){
index = cluster.size() - 1;
bool Success = false;
int match_pos = -1;
while(index >= 0){
if(cluster[index].chro != gpd_vec[i].chro || gpd_vec[i].start - cluster[index].end > 1000000) break;
else{
pair<int,int> result = AlignGPD(gpd_vec[i], cluster[index]);
if(result.first > 0){
Success = true;
match_pos = index;
break;
}
}
--index;
}
if(Success){
indicator.push_back(index);
++abundance[index];
}
else{
cluster.push_back(gpd_vec[i]);
indicator.push_back(cluster.size() - 1);
abundance.push_back(1);
}
}
int acculmulate = 0;
for(int i = 0; i < cluster.size(); ++i){
if(abundance[i] >= 2){
++acculmulate;
cluster[i].tname = "CAGE_novel_" + lexical_cast<string>(acculmulate);
DisplayGPDtoFile(cluster[i], ouf1);
}
}
for(int i = 0; i < gpd_vec.size(); ++i){
int n = indicator[i];
if(abundance[n] >= 2){
ouf2 << gpd_vec[i].tname << '\t' << cluster[n].gname << '\t' << cluster[n].tname << '\t' << cluster[n].strand << '\t';
ouf2 << gpd_vec[i].chro << ':' << gpd_vec[i].start << '-' << gpd_vec[i].end << '\t';
ouf2 << cluster[n].chro << ':' << cluster[n].start << '-' << cluster[n].end << '\t' << cluster[n].nblock << endl;
}
}
inf.close();
return 0;
}