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pe.c
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pe.c
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#include <stdlib.h>
#include <math.h>
#include "mmpriv.h"
#include "kvec.h"
void mm_select_sub_multi(void *km, float pri_ratio, float pri1, float pri2, int max_gap_ref, int min_diff, int best_n, int n_segs, const int *qlens, int *n_, mm_reg1_t *r)
{
if (pri_ratio > 0.0f && *n_ > 0) {
int i, k, n = *n_, n_2nd = 0;
int max_dist = n_segs == 2? qlens[0] + qlens[1] + max_gap_ref : 0;
for (i = k = 0; i < n; ++i) {
int to_keep = 0;
if (r[i].parent == i) { // primary
to_keep = 1;
} else if (r[i].score + min_diff >= r[r[i].parent].score) {
to_keep = 1;
} else {
mm_reg1_t *p = &r[r[i].parent], *q = &r[i];
if (p->rev == q->rev && p->rid == q->rid && q->re - p->rs < max_dist && p->re - q->rs < max_dist) { // child and parent are close on the ref
if (q->score >= p->score * pri1)
to_keep = 1;
} else {
int is_par_both = (n_segs == 2 && p->qs < qlens[0] && p->qe > qlens[0]);
int is_chi_both = (n_segs == 2 && q->qs < qlens[0] && q->qe > qlens[0]);
if (is_chi_both || is_chi_both == is_par_both) {
if (q->score >= p->score * pri_ratio)
to_keep = 1;
} else { // the remaining case: is_chi_both == 0 && is_par_both == 1
if (q->score >= p->score * pri2)
to_keep = 1;
}
}
}
if (to_keep && r[i].parent != i) {
if (n_2nd++ >= best_n) to_keep = 0; // don't keep if there are too many secondary hits
}
if (to_keep) r[k++] = r[i];
else if (r[i].p) free(r[i].p);
}
if (k != n) mm_sync_regs(km, k, r); // removing hits requires sync()
*n_ = k;
}
}
void mm_set_pe_thru(const int *qlens, int *n_regs, mm_reg1_t **regs)
{
int s, i, n_pri[2], pri[2];
n_pri[0] = n_pri[1] = 0;
pri[0] = pri[1] = -1;
for (s = 0; s < 2; ++s)
for (i = 0; i < n_regs[s]; ++i)
if (regs[s][i].id == regs[s][i].parent)
++n_pri[s], pri[s] = i;
if (n_pri[0] == 1 && n_pri[1] == 1) {
mm_reg1_t *p = ®s[0][pri[0]];
mm_reg1_t *q = ®s[1][pri[1]];
if (p->rid == q->rid && p->rev == q->rev && abs(p->rs - q->rs) < 3 && abs(p->re - q->re) < 3
&& ((p->qs == 0 && qlens[1] - q->qe == 0) || (q->qs == 0 && qlens[0] - p->qe == 0)))
{
p->pe_thru = q->pe_thru = 1;
}
}
}
#include "ksort.h"
typedef struct {
int s, rev;
uint64_t key;
mm_reg1_t *r;
} pair_arr_t;
#define sort_key_pair(a) ((a).key)
KRADIX_SORT_INIT(pair, pair_arr_t, sort_key_pair, 8)
void mm_pair(void *km, int max_gap_ref, int pe_bonus, int sub_diff, int match_sc, const int *qlens, int *n_regs, mm_reg1_t **regs)
{
int i, j, s, n, last[2], dp_thres, segs = 0, max_idx[2];
int64_t max;
pair_arr_t *a;
kvec_t(uint64_t) sc = {0,0,0};
a = (pair_arr_t*)kmalloc(km, (n_regs[0] + n_regs[1]) * sizeof(pair_arr_t));
for (s = n = 0, dp_thres = 0; s < 2; ++s) {
int max = 0;
for (i = 0; i < n_regs[s]; ++i) {
a[n].s = s;
a[n].r = ®s[s][i];
a[n].rev = a[n].r->rev;
a[n].key = (uint64_t)a[n].r->rid << 32 | a[n].r->rs<<1 | (s^a[n].rev);
max = max > a[n].r->p->dp_max? max : a[n].r->p->dp_max;
++n;
segs |= 1<<s;
}
dp_thres += max;
}
if (segs != 3) {
kfree(km, a); // only one end is mapped
return;
}
dp_thres -= pe_bonus;
if (dp_thres < 0) dp_thres = 0;
radix_sort_pair(a, a + n);
max = -1;
max_idx[0] = max_idx[1] = -1;
last[0] = last[1] = -1;
kv_resize(uint64_t, km, sc, (size_t)n);
for (i = 0; i < n; ++i) {
if (a[i].key & 1) { // reverse first read or forward second read
mm_reg1_t *q, *r;
if (last[a[i].rev] < 0) continue;
r = a[i].r;
q = a[last[a[i].rev]].r;
if (r->rid != q->rid || r->rs - q->re > max_gap_ref) continue;
for (j = last[a[i].rev]; j >= 0; --j) {
int64_t score;
if (a[j].rev != a[i].rev || a[j].s == a[i].s) continue;
q = a[j].r;
if (r->rid != q->rid || r->rs - q->re > max_gap_ref) break;
if (r->p->dp_max + q->p->dp_max < dp_thres) continue;
//klocwork fix
//score = (int64_t)(()r->p->dp_max + q->p->dp_max) << 32 | (r->hash + q->hash);
score = (int64_t)((int64_t)r->p->dp_max + q->p->dp_max) << 32 | (r->hash + q->hash);
if (score > max)
max = score, max_idx[a[j].s] = j, max_idx[a[i].s] = i;
kv_push(uint64_t, km, sc, score);
}
} else { // forward first read or reverse second read
last[a[i].rev] = i;
}
}
if (sc.n > 1)
radix_sort_64(sc.a, sc.a + sc.n);
if (sc.n > 0 && max > 0) { // found at least one pair
int n_sub = 0, mapq_pe;
mm_reg1_t *r[2];
r[0] = a[max_idx[0]].r, r[1] = a[max_idx[1]].r;
r[0]->proper_frag = r[1]->proper_frag = 1;
for (s = 0; s < 2; ++s) {
if (r[s]->id != r[s]->parent) { // then lift to primary and update parent
mm_reg1_t *p = ®s[s][r[s]->parent];
for (i = 0; i < n_regs[s]; ++i)
if (regs[s][i].parent == p->id)
regs[s][i].parent = r[s]->id;
p->mapq = 0;
}
if (!r[s]->sam_pri) { // then sync sam_pri
for (i = 0; i < n_regs[s]; ++i)
regs[s][i].sam_pri = 0;
r[s]->sam_pri = 1;
}
}
mapq_pe = r[0]->mapq > r[1]->mapq? r[0]->mapq : r[1]->mapq;
for (i = 0; i < (int)sc.n; ++i)
if ((sc.a[i]>>32) + sub_diff >= (uint64_t)max>>32)
++n_sub;
if (sc.n > 1) {
int mapq_pe_alt;
mapq_pe_alt = (int)(6.02f * ((max>>32) - (sc.a[sc.n - 2]>>32)) / match_sc - 4.343f * logf(n_sub)); // n_sub > 0 because it counts the optimal, too
mapq_pe = mapq_pe < mapq_pe_alt? mapq_pe : mapq_pe_alt;
}
if (r[0]->mapq < mapq_pe) r[0]->mapq = (int)(.2f * r[0]->mapq + .8f * mapq_pe + .499f);
if (r[1]->mapq < mapq_pe) r[1]->mapq = (int)(.2f * r[1]->mapq + .8f * mapq_pe + .499f);
if (sc.n == 1) {
if (r[0]->mapq < 2) r[0]->mapq = 2;
if (r[1]->mapq < 2) r[1]->mapq = 2;
} else if ((uint64_t)max>>32 > sc.a[sc.n - 2]>>32) {
if (r[0]->mapq < 1) r[0]->mapq = 1;
if (r[1]->mapq < 1) r[1]->mapq = 1;
}
}
kfree(km, a);
kfree(km, sc.a);
mm_set_pe_thru(qlens, n_regs, regs);
}