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bwtsw2_pair.c
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bwtsw2_pair.c
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#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "utils.h"
#include "bwt.h"
#include "bntseq.h"
#include "bwtsw2.h"
#include "kstring.h"
#include "ksw.h"
#ifdef USE_MALLOC_WRAPPERS
# include "malloc_wrap.h"
#endif
#define MIN_RATIO 0.8
#define OUTLIER_BOUND 2.0
#define MAX_STDDEV 4.0
#define EXT_STDDEV 4.0
typedef struct {
int low, high, failed;
double avg, std;
} bsw2pestat_t;
bsw2pestat_t bsw2_stat(int n, bwtsw2_t **buf, kstring_t *msg, int max_ins)
{
int i, k, x, p25, p50, p75, tmp, max_len = 0;
uint64_t *isize;
bsw2pestat_t r;
memset(&r, 0, sizeof(bsw2pestat_t));
isize = calloc(n, 8);
for (i = k = 0; i < n; i += 2) {
bsw2hit_t *t[2];
int l;
if (buf[i] == 0 || buf[i]->n != 1 || buf[i+1]->n != 1) continue; // more than 1 hits
t[0] = &buf[i]->hits[0]; t[1] = &buf[i+1]->hits[0];
if (t[0]->G2 > 0.8 * t[0]->G) continue; // the best hit is not good enough
if (t[1]->G2 > 0.8 * t[1]->G) continue; // the best hit is not good enough
l = t[0]->k > t[1]->k? t[0]->k - t[1]->k + t[1]->len : t[1]->k - t[0]->k + t[0]->len;
if (l >= max_ins) continue; // skip pairs with excessively large insert
max_len = max_len > t[0]->end - t[0]->beg? max_len : t[0]->end - t[0]->beg;
max_len = max_len > t[1]->end - t[1]->beg? max_len : t[1]->end - t[1]->beg;
isize[k++] = l;
}
ks_introsort_64(k, isize);
p25 = isize[(int)(.25 * k + .499)];
p50 = isize[(int)(.50 * k + .499)];
p75 = isize[(int)(.75 * k + .499)];
ksprintf(msg, "[%s] infer the insert size distribution from %d high-quality pairs.\n", __func__, k);
if (k < 8) {
ksprintf(msg, "[%s] fail to infer the insert size distribution: too few good pairs.\n", __func__);
free(isize);
r.failed = 1;
return r;
}
tmp = (int)(p25 - OUTLIER_BOUND * (p75 - p25) + .499);
r.low = tmp > max_len? tmp : max_len;
if (r.low < 1) r.low = 1;
r.high = (int)(p75 + OUTLIER_BOUND * (p75 - p25) + .499);
if (r.low > r.high) {
ksprintf(msg, "[%s] fail to infer the insert size distribution: upper bound is smaller than max read length.\n", __func__);
free(isize);
r.failed = 1;
return r;
}
ksprintf(msg, "[%s] (25, 50, 75) percentile: (%d, %d, %d)\n", __func__, p25, p50, p75);
ksprintf(msg, "[%s] low and high boundaries for computing mean and std.dev: (%d, %d)\n", __func__, r.low, r.high);
for (i = x = 0, r.avg = 0; i < k; ++i)
if (isize[i] >= r.low && isize[i] <= r.high)
r.avg += isize[i], ++x;
if (x == 0) {
ksprintf(msg, "[%s] fail to infer the insert size distribution: no pairs within boundaries.\n", __func__);
free(isize);
r.failed = 1;
return r;
}
r.avg /= x;
for (i = 0, r.std = 0; i < k; ++i)
if (isize[i] >= r.low && isize[i] <= r.high)
r.std += (isize[i] - r.avg) * (isize[i] - r.avg);
r.std = sqrt(r.std / x);
ksprintf(msg, "[%s] mean and std.dev: (%.2f, %.2f)\n", __func__, r.avg, r.std);
tmp = (int)(p25 - 3. * (p75 - p25) + .499);
r.low = tmp > max_len? tmp : max_len;
if (r.low < 1) r.low = 1;
r.high = (int)(p75 + 3. * (p75 - p25) + .499);
if (r.low > r.avg - MAX_STDDEV * r.std) r.low = (int)(r.avg - MAX_STDDEV * r.std + .499);
r.low = tmp > max_len? tmp : max_len;
if (r.high < r.avg + MAX_STDDEV * r.std) r.high = (int)(r.avg + MAX_STDDEV * r.std + .499);
ksprintf(msg, "[%s] low and high boundaries for proper pairs: (%d, %d)\n", __func__, r.low, r.high);
free(isize);
return r;
}
typedef struct {
int n_cigar, beg, end, len;
int64_t pos;
uint32_t *cigar;
} pairaux_t;
extern unsigned char nst_nt4_table[256];
void bsw2_pair1(const bsw2opt_t *opt, int64_t l_pac, const uint8_t *pac, const bsw2pestat_t *st, const bsw2hit_t *h, int l_mseq, const char *mseq, bsw2hit_t *a, int8_t g_mat[25])
{
extern void seq_reverse(int len, ubyte_t *seq, int is_comp);
int64_t k, beg, end;
uint8_t *seq, *ref;
int i;
// compute the region start and end
a->n_seeds = 1; a->flag |= BSW2_FLAG_MATESW; // before calling this routine, *a has been cleared with memset(0); the flag is set with 1<<6/7
if (h->is_rev == 0) {
beg = (int64_t)(h->k + st->avg - EXT_STDDEV * st->std - l_mseq + .499);
if (beg < h->k) beg = h->k;
end = (int64_t)(h->k + st->avg + EXT_STDDEV * st->std + .499);
a->is_rev = 1; a->flag |= 16;
} else {
beg = (int64_t)(h->k + h->end - h->beg - st->avg - EXT_STDDEV * st->std + .499);
end = (int64_t)(h->k + h->end - h->beg - st->avg + EXT_STDDEV * st->std + l_mseq + .499);
if (end > h->k + (h->end - h->beg)) end = h->k + (h->end - h->beg);
a->is_rev = 0;
}
if (beg < 1) beg = 1;
if (end > l_pac) end = l_pac;
if (end - beg < l_mseq) return;
// generate the sequence
seq = malloc(l_mseq + (end - beg));
ref = seq + l_mseq;
for (k = beg; k < end; ++k)
ref[k - beg] = pac[k>>2] >> ((~k&3)<<1) & 0x3;
if (h->is_rev == 0) {
for (i = 0; i < l_mseq; ++i) { // on the reverse strand
int c = nst_nt4_table[(int)mseq[i]];
seq[l_mseq - 1 - i] = c > 3? 4 : 3 - c;
}
} else {
for (i = 0; i < l_mseq; ++i) // on the forward strand
seq[i] = nst_nt4_table[(int)mseq[i]];
}
{
int flag = KSW_XSUBO | KSW_XSTART | (l_mseq * g_mat[0] < 250? KSW_XBYTE : 0) | opt->t;
kswr_t aln;
aln = ksw_align(l_mseq, seq, end - beg, ref, 5, g_mat, opt->q, opt->r, flag, 0);
a->G = aln.score;
a->G2 = aln.score2;
if (a->G < opt->t) a->G = 0;
if (a->G2 < opt->t) a->G2 = 0;
if (a->G2) a->flag |= BSW2_FLAG_TANDEM;
a->k = beg + aln.tb;
a->len = aln.te - aln.tb + 1;
a->beg = aln.qb;
a->end = aln.qe + 1;
/*
printf("[Q] "); for (i = 0; i < l_mseq; ++i) putchar("ACGTN"[(int)seq[i]]); putchar('\n');
printf("[R] "); for (i = 0; i < end - beg; ++i) putchar("ACGTN"[(int)ref[i]]); putchar('\n');
printf("G=%d,G2=%d,beg=%d,end=%d,k=%lld,len=%d\n", a->G, a->G2, a->beg, a->end, a->k, a->len);
*/
}
if (a->is_rev) i = a->beg, a->beg = l_mseq - a->end, a->end = l_mseq - i;
free(seq);
}
void bsw2_pair(const bsw2opt_t *opt, int64_t l_pac, const uint8_t *pac, int n, bsw2seq1_t *seq, bwtsw2_t **hits)
{
extern int bsw2_resolve_duphits(const bntseq_t *bns, const bwt_t *bwt, bwtsw2_t *b, int IS);
bsw2pestat_t pes;
int i, j, k, n_rescued = 0, n_moved = 0, n_fixed = 0;
int8_t g_mat[25];
kstring_t msg;
memset(&msg, 0, sizeof(kstring_t));
pes = bsw2_stat(n, hits, &msg, opt->max_ins);
for (i = k = 0; i < 5; ++i) {
for (j = 0; j < 4; ++j)
g_mat[k++] = i == j? opt->a : -opt->b;
g_mat[k++] = 0;
}
for (i = 0; i < n; i += 2) {
bsw2hit_t a[2];
memset(&a, 0, sizeof(bsw2hit_t) * 2);
a[0].flag = 1<<6; a[1].flag = 1<<7;
for (j = 0; j < 2; ++j) { // set the read1/2 flag
if (hits[i+j] == 0) continue;
for (k = 0; k < hits[i+j]->n; ++k) {
bsw2hit_t *p = &hits[i+j]->hits[k];
p->flag |= 1<<(6+j);
}
}
if (pes.failed) continue;
if (hits[i] == 0 || hits[i+1] == 0) continue; // one end has excessive N
if (hits[i]->n != 1 && hits[i+1]->n != 1) continue; // no end has exactly one hit
if (hits[i]->n > 1 || hits[i+1]->n > 1) continue; // one read has more than one hit
if (!opt->skip_sw) {
if (hits[i+0]->n == 1) bsw2_pair1(opt, l_pac, pac, &pes, &hits[i+0]->hits[0], seq[i+1].l, seq[i+1].seq, &a[1], g_mat);
if (hits[i+1]->n == 1) bsw2_pair1(opt, l_pac, pac, &pes, &hits[i+1]->hits[0], seq[i+0].l, seq[i+0].seq, &a[0], g_mat);
} // else a[0].G == a[1].G == a[0].G2 == a[1].G2 == 0
// the following enumerate all possibilities. It is tedious but necessary...
if (hits[i]->n + hits[i+1]->n == 1) { // one end mapped; the other not;
bwtsw2_t *p[2];
int which;
if (hits[i]->n == 1) p[0] = hits[i], p[1] = hits[i+1], which = 1;
else p[0] = hits[i+1], p[1] = hits[i], which = 0;
if (a[which].G == 0) continue;
a[which].flag |= BSW2_FLAG_RESCUED;
if (p[1]->max == 0) {
p[1]->max = 1;
p[1]->hits = malloc(sizeof(bsw2hit_t));
}
p[1]->hits[0] = a[which];
p[1]->n = 1;
p[0]->hits[0].flag |= 2;
p[1]->hits[0].flag |= 2;
++n_rescued;
} else { // then both ends mapped
int is_fixed = 0;
//fprintf(stderr, "%d; %lld,%lld; %d,%d\n", a[0].is_rev, hits[i]->hits[0].k, a[0].k, hits[i]->hits[0].end, a[0].end);
for (j = 0; j < 2; ++j) { // fix wrong mappings and wrong suboptimal alignment score
bsw2hit_t *p = &hits[i+j]->hits[0];
if (p->G < a[j].G) { // the orginal mapping is suboptimal
a[j].G2 = a[j].G2 > p->G? a[j].G2 : p->G; // FIXME: reset BSW2_FLAG_TANDEM?
*p = a[j];
++n_fixed;
is_fixed = 1;
} else if (p->k != a[j].k && p->G2 < a[j].G) {
p->G2 = a[j].G;
} else if (p->k == a[j].k && p->G2 < a[j].G2) {
p->G2 = a[j].G2;
}
}
if (hits[i]->hits[0].k == a[0].k && hits[i+1]->hits[0].k == a[1].k) { // properly paired and no ends need to be moved
for (j = 0; j < 2; ++j)
hits[i+j]->hits[0].flag |= 2 | (a[j].flag & BSW2_FLAG_TANDEM);
} else if (hits[i]->hits[0].k == a[0].k || hits[i+1]->hits[0].k == a[1].k) { // a tandem match
for (j = 0; j < 2; ++j) {
hits[i+j]->hits[0].flag |= 2;
if (hits[i+j]->hits[0].k != a[j].k)
hits[i+j]->hits[0].flag |= BSW2_FLAG_TANDEM;
}
} else if (!is_fixed && (a[0].G || a[1].G)) { // it is possible to move one end
if (a[0].G && a[1].G) { // now we have two "proper pairs"
int G[2];
double diff;
G[0] = hits[i]->hits[0].G + a[1].G;
G[1] = hits[i+1]->hits[0].G + a[0].G;
diff = fabs((double)(G[0] - G[1])) / (opt->a + opt->b) / ((hits[i]->hits[0].len + a[1].len + hits[i+1]->hits[0].len + a[0].len) / 2.);
if (diff > 0.05) a[G[0] > G[1]? 0 : 1].G = 0;
}
if (a[0].G == 0 || a[1].G == 0) { // one proper pair only
bsw2hit_t *p[2]; // p[0] points the unchanged hit; p[1] to the hit to be moved
int which, isize;
double dev, diff;
if (a[0].G) p[0] = &hits[i+1]->hits[0], p[1] = &hits[i]->hits[0], which = 0;
else p[0] = &hits[i]->hits[0], p[1] = &hits[i+1]->hits[0], which = 1;
isize = p[0]->is_rev? p[0]->k + p[0]->len - a[which].k : a[which].k + a[which].len - p[0]->k;
dev = fabs(isize - pes.avg) / pes.std;
diff = (double)(p[1]->G - a[which].G) / (opt->a + opt->b) / (p[1]->end - p[1]->beg) * 100.0;
if (diff < dev * 2.) { // then move (heuristic)
a[which].G2 = a[which].G;
p[1][0] = a[which];
p[1]->flag |= BSW2_FLAG_MOVED | 2;
p[0]->flag |= 2;
++n_moved;
}
}
} else if (is_fixed) {
hits[i+0]->hits[0].flag |= 2;
hits[i+1]->hits[0].flag |= 2;
}
}
}
ksprintf(&msg, "[%s] #fixed=%d, #rescued=%d, #moved=%d\n", __func__, n_fixed, n_rescued, n_moved);
fputs(msg.s, stderr);
free(msg.s);
}