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cal_cov.c
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cal_cov.c
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#include <assert.h>
#include <string.h>
#include "mgpriv.h"
#include "gfa-priv.h"
#include "algo.h"
#include "kalloc.h"
void mg_cov_map(const gfa_t *g, const mg_gchains_t *gt, int32_t min_mapq, int32_t min_blen, double *c_seg, double *c_link, const char *qname)
{
int32_t i, j;
if (c_seg == 0 && c_link == 0) return;
if (gt == 0 || gt->n_gc == 0) return;
for (i = 0; i < gt->n_gc; ++i) {
const mg_gchain_t *gc = >->gc[i];
const mg128_t *last_an;
assert(gc->cnt > 0 && gc->n_anchor > 0);
if (gc->mapq < min_mapq || gc->blen < min_blen) continue;
// count segment coverage
for (j = 0; j < gc->cnt; ++j) {
const mg_llchain_t *lc = >->lc[gc->off + j];
int32_t s, e;
s = 0, e = g->seg[lc->v>>1].len;
if (j == 0) s = (int32_t)gt->a[lc->off].x + 1 - (int32_t)(gt->a[lc->off].y>>32&0xff);
if (j == gc->cnt - 1) e = (int32_t)gt->a[lc->off + lc->cnt - 1].x + 1;
if (c_seg) c_seg[lc->v>>1] += (double)(e - s) / g->seg[lc->v>>1].len;
}
// count link
assert(gt->lc[gc->off].cnt > 0);
last_an = >->a[gt->lc[gc->off].off + gt->lc[gc->off].cnt - 1];
for (j = 1; j < gc->cnt; ++j) {
const mg_llchain_t *lc0 = >->lc[gc->off + j - 1];
const mg_llchain_t *lc1 = >->lc[gc->off + j];
int64_t a01, a10;
if (lc1->cnt > 0) {
const mg128_t *curr_an = >->a[lc1->off];
int32_t is_skip = (mg_seg_id(*curr_an) != mg_seg_id(*last_an));
last_an = >->a[lc1->off + lc1->cnt - 1];
if (is_skip) continue;
}
a01 = gfa_find_arc(g, lc0->v, lc1->v);
a10 = gfa_find_arc(g, lc1->v^1, lc0->v^1);
if (a01 < 0 || a10 < 0) {
if (mg_verbose >= 2)
fprintf(stderr, "[W] Multi/disconnected link: %c%s[%d] -> %c%s[%d] (%s, %ld, %ld). Continue anyway!\n",
"><"[lc0->v&1], g->seg[lc0->v>>1].name, lc0->v,
"><"[lc1->v&1], g->seg[lc1->v>>1].name, lc1->v, qname, (long)a01, (long)a10);
continue;
}
assert((g->arc[a01].comp ^ g->arc[a10].comp) == 1);
if (c_link) c_link[a01] += 1.0, c_link[a10] += 1.0;
}
}
}
void mg_cov_asm(const gfa_t *g, int32_t n_seq, mg_gchains_t *const *gcs, int32_t min_mapq, int32_t min_blen, double *cov_seg, double *cov_link)
{
int32_t i, j, t, *soff, *scnt, *cnt_link;
int64_t k;
mg_intv_t *sintv = 0;
void *km = 0;
// precalculate the size of sintv[] for each segment
KCALLOC(km, scnt, g->n_seg);
for (t = 0; t < n_seq; ++t) {
const mg_gchains_t *gt = gcs[t];
if (gt == 0 || gt->n_gc == 0) continue;
for (i = 0; i < gt->n_gc; ++i) {
const mg_gchain_t *gc = >->gc[i];
assert(gc->cnt > 0 && gc->n_anchor > 0);
if (gc->mapq < min_mapq || gc->blen < min_blen) continue;
for (j = 0; j < gc->cnt; ++j) {
const mg_llchain_t *lc = >->lc[gc->off + j];
++scnt[lc->v>>1];
}
}
}
KMALLOC(km, soff, g->n_seg + 1);
for (soff[0] = 0, i = 1; i <= g->n_seg; ++i)
soff[i] = soff[i - 1] + scnt[i - 1];
memset(scnt, 0, 4 * g->n_seg);
KMALLOC(km, sintv, soff[g->n_seg]);
// fill sintv[]
KCALLOC(km, cnt_link, g->n_arc);
for (t = 0; t < n_seq; ++t) {
const mg_gchains_t *gt = gcs[t];
if (gt == 0 || gt->n_gc == 0) continue;
for (i = 0; i < gt->n_gc;) {
const mg_gchain_t *gc = >->gc[i];
if (gc->mapq < min_mapq || gc->blen < min_blen) continue;
// count segment coverage
for (j = 0; j < gc->cnt; ++j) {
const mg_llchain_t *lc = >->lc[gc->off + j];
int32_t s, e, tmp;
mg_intv_t *p;
s = 0, e = g->seg[lc->v>>1].len;
if (j == 0) s = (int32_t)gt->a[lc->off].x + 1 - (int32_t)(gt->a[lc->off].y>>32&0xff);
if (j == gc->cnt - 1) e = (int32_t)gt->a[lc->off + lc->cnt - 1].x + 1;
if (lc->v&1) // convert to the forward strand of segment lc->v>>1
tmp = g->seg[lc->v>>1].len - s, s = g->seg[lc->v>>1].len - e, e = tmp;
p = &sintv[soff[lc->v>>1] + scnt[lc->v>>1]];
++scnt[lc->v>>1];
p->st = s, p->en = e, p->rev = lc->v&1, p->far = -1, p->i = -1;
}
// count link
for (j = 1; j < gc->cnt; ++j) {
const mg_llchain_t *lc0 = >->lc[gc->off + j - 1];
const mg_llchain_t *lc1 = >->lc[gc->off + j];
int64_t a01, a10;
a01 = gfa_find_arc(g, lc0->v, lc1->v);
a10 = gfa_find_arc(g, lc1->v^1, lc0->v^1);
assert(a01 >= 0 && a10 >= 0);
assert((g->arc[a01].comp ^ g->arc[a10].comp) == 1);
++cnt_link[a01];
++cnt_link[a10];
}
}
}
// update cov_link[] and cov_seg[]
for (k = 0; k < g->n_arc; ++k)
if (cnt_link[k] > 0) cov_link[k] += 1.0;
for (i = 0; i < g->n_seg; ++i) {
int32_t st = 0, en = 0, cov = 0;
assert(scnt[i] == soff[i+1] - soff[i]);
radix_sort_mg_intv(&sintv[soff[i]], &sintv[soff[i+1]]);
for (j = soff[i]; j < soff[i+1]; ++j) {
if (sintv[j].st > en)
cov += en - st, st = sintv[j].st, en = sintv[j].en;
else en = sintv[j].en > en? sintv[j].en : en;
}
cov += en - st;
cov_seg[i] += (double)cov / g->seg[i].len;
}
// free
kfree(km, cnt_link);
kfree(km, sintv); kfree(km, soff); kfree(km, scnt);
}