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bwamem.c
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bwamem.c
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#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include <assert.h>
#include <math.h>
#ifdef HAVE_PTHREAD
#include <pthread.h>
#endif
#include "kstring.h"
#include "bwamem.h"
#include "bntseq.h"
#include "ksw.h"
#include "kvec.h"
#include "ksort.h"
#include "utils.h"
#ifdef USE_MALLOC_WRAPPERS
# include "malloc_wrap.h"
#endif
/* Theory on probability and scoring *ungapped* alignment
*
* s'(a,b) = log[P(b|a)/P(b)] = log[4P(b|a)], assuming uniform base distribution
* s'(a,a) = log(4), s'(a,b) = log(4e/3), where e is the error rate
*
* Scale s'(a,b) to s(a,a) s.t. s(a,a)=x. Then s(a,b) = x*s'(a,b)/log(4), or conversely: s'(a,b)=s(a,b)*log(4)/x
*
* If the matching score is x and mismatch penalty is -y, we can compute error rate e:
* e = .75 * exp[-log(4) * y/x]
*
* log P(seq) = \sum_i log P(b_i|a_i) = \sum_i {s'(a,b) - log(4)}
* = \sum_i { s(a,b)*log(4)/x - log(4) } = log(4) * (S/x - l)
*
* where S=\sum_i s(a,b) is the alignment score. Converting to the phred scale:
* Q(seq) = -10/log(10) * log P(seq) = 10*log(4)/log(10) * (l - S/x) = 6.02 * (l - S/x)
*
*
* Gap open (zero gap): q' = log[P(gap-open)], r' = log[P(gap-ext)] (see Durbin et al. (1998) Section 4.1)
* Then q = x*log[P(gap-open)]/log(4), r = x*log[P(gap-ext)]/log(4)
*
* When there are gaps, l should be the length of alignment matches (i.e. the M operator in CIGAR)
*/
static const bntseq_t *global_bns = 0; // for debugging only
mem_opt_t *mem_opt_init()
{
mem_opt_t *o;
o = calloc(1, sizeof(mem_opt_t));
o->flag = 0;
o->a = 1; o->b = 4;
o->o_del = o->o_ins = 6;
o->e_del = o->e_ins = 1;
o->w = 100;
o->T = 30;
o->zdrop = 100;
o->pen_unpaired = 17;
o->pen_clip5 = o->pen_clip3 = 5;
o->min_seed_len = 19;
o->split_width = 10;
o->max_occ = 10000;
o->max_chain_gap = 10000;
o->max_ins = 10000;
o->mask_level = 0.50;
o->drop_ratio = 0.50;
o->split_factor = 1.5;
o->chunk_size = 10000000;
o->n_threads = 1;
o->max_matesw = 100;
o->mask_level_redun = 0.95;
o->min_chain_weight = 0;
o->max_chain_extend = 1<<30;
o->mapQ_coef_len = 50; o->mapQ_coef_fac = log(o->mapQ_coef_len);
bwa_fill_scmat(o->a, o->b, o->mat);
return o;
}
/***************************
* Collection SA invervals *
***************************/
#define intv_lt(a, b) ((a).info < (b).info)
KSORT_INIT(mem_intv, bwtintv_t, intv_lt)
typedef struct {
bwtintv_v mem, mem1, *tmpv[2];
} smem_aux_t;
static smem_aux_t *smem_aux_init()
{
smem_aux_t *a;
a = calloc(1, sizeof(smem_aux_t));
a->tmpv[0] = calloc(1, sizeof(bwtintv_v));
a->tmpv[1] = calloc(1, sizeof(bwtintv_v));
return a;
}
static void smem_aux_destroy(smem_aux_t *a)
{
free(a->tmpv[0]->a); free(a->tmpv[0]);
free(a->tmpv[1]->a); free(a->tmpv[1]);
free(a->mem.a); free(a->mem1.a);
free(a);
}
static void mem_collect_intv(const mem_opt_t *opt, const bwt_t *bwt, int len, const uint8_t *seq, smem_aux_t *a)
{
int i, k, x = 0, old_n;
int start_width = (opt->flag & MEM_F_SELF_OVLP)? 2 : 1;
int split_len = (int)(opt->min_seed_len * opt->split_factor + .499);
a->mem.n = 0;
// first pass: find all SMEMs
while (x < len) {
if (seq[x] < 4) {
x = bwt_smem1(bwt, len, seq, x, start_width, &a->mem1, a->tmpv);
for (i = 0; i < a->mem1.n; ++i) {
bwtintv_t *p = &a->mem1.a[i];
int slen = (uint32_t)p->info - (p->info>>32); // seed length
if (slen >= opt->min_seed_len && p->x[2] <= opt->max_occ)
kv_push(bwtintv_t, a->mem, *p);
}
} else ++x;
}
// second pass: find MEMs inside a long SMEM
old_n = a->mem.n;
for (k = 0; k < old_n; ++k) {
bwtintv_t *p = &a->mem.a[k];
int start = p->info>>32, end = (int32_t)p->info;
if (end - start < split_len || p->x[2] > opt->split_width) continue;
bwt_smem1(bwt, len, seq, (start + end)>>1, p->x[2]+1, &a->mem1, a->tmpv);
for (i = 0; i < a->mem1.n; ++i)
kv_push(bwtintv_t, a->mem, a->mem1.a[i]);
}
// sort
ks_introsort(mem_intv, a->mem.n, a->mem.a);
}
/************
* Chaining *
************/
typedef struct {
int64_t rbeg;
int32_t qbeg, len;
} mem_seed_t; // unaligned memory
typedef struct {
int n, m, first, rid;
int w, kept;
int64_t pos;
mem_seed_t *seeds;
} mem_chain_t;
typedef struct { size_t n, m; mem_chain_t *a; } mem_chain_v;
#include "kbtree.h"
#define chain_cmp(a, b) (((b).pos < (a).pos) - ((a).pos < (b).pos))
KBTREE_INIT(chn, mem_chain_t, chain_cmp)
// return 1 if the seed is merged into the chain
static int test_and_merge(const mem_opt_t *opt, int64_t l_pac, mem_chain_t *c, const mem_seed_t *p, int seed_rid)
{
int64_t qend, rend, x, y;
const mem_seed_t *last = &c->seeds[c->n-1];
qend = last->qbeg + last->len;
rend = last->rbeg + last->len;
if (seed_rid != c->rid) return 0; // different chr; request a new chain
if (p->qbeg >= c->seeds[0].qbeg && p->qbeg + p->len <= qend && p->rbeg >= c->seeds[0].rbeg && p->rbeg + p->len <= rend)
return 1; // contained seed; do nothing
if ((last->rbeg < l_pac || c->seeds[0].rbeg < l_pac) && p->rbeg >= l_pac) return 0; // don't chain if on different strand
x = p->qbeg - last->qbeg; // always non-negtive
y = p->rbeg - last->rbeg;
if (y >= 0 && x - y <= opt->w && y - x <= opt->w && x - last->len < opt->max_chain_gap && y - last->len < opt->max_chain_gap) { // grow the chain
if (c->n == c->m) {
c->m <<= 1;
c->seeds = realloc(c->seeds, c->m * sizeof(mem_seed_t));
}
c->seeds[c->n++] = *p;
return 1;
}
return 0; // request to add a new chain
}
int mem_chain_weight(const mem_chain_t *c)
{
int64_t end;
int j, w = 0, tmp;
for (j = 0, end = 0; j < c->n; ++j) {
const mem_seed_t *s = &c->seeds[j];
if (s->qbeg >= end) w += s->len;
else if (s->qbeg + s->len > end) w += s->qbeg + s->len - end;
end = end > s->qbeg + s->len? end : s->qbeg + s->len;
}
tmp = w;
for (j = 0, end = 0; j < c->n; ++j) {
const mem_seed_t *s = &c->seeds[j];
if (s->rbeg >= end) w += s->len;
else if (s->rbeg + s->len > end) w += s->rbeg + s->len - end;
end = end > s->qbeg + s->len? end : s->qbeg + s->len;
}
return w < tmp? w : tmp;
}
void mem_print_chain(const bntseq_t *bns, mem_chain_v *chn)
{
int i, j;
for (i = 0; i < chn->n; ++i) {
mem_chain_t *p = &chn->a[i];
err_printf("* Found CHAIN(%d): n=%d; weight=%d", i, p->n, mem_chain_weight(p));
for (j = 0; j < p->n; ++j) {
bwtint_t pos;
int is_rev, ref_id;
pos = bns_depos(bns, p->seeds[j].rbeg, &is_rev);
if (is_rev) pos -= p->seeds[j].len - 1;
bns_cnt_ambi(bns, pos, p->seeds[j].len, &ref_id);
err_printf("\t%d;%d,%ld(%s:%c%ld)", p->seeds[j].len, p->seeds[j].qbeg, (long)p->seeds[j].rbeg, bns->anns[ref_id].name, "+-"[is_rev], (long)(pos - bns->anns[ref_id].offset) + 1);
}
err_putchar('\n');
}
}
mem_chain_v mem_chain(const mem_opt_t *opt, const bwt_t *bwt, const bntseq_t *bns, int len, const uint8_t *seq)
{
int i;
int64_t l_pac = bns->l_pac;
mem_chain_v chain;
kbtree_t(chn) *tree;
smem_aux_t *aux;
kv_init(chain);
if (len < opt->min_seed_len) return chain; // if the query is shorter than the seed length, no match
tree = kb_init(chn, KB_DEFAULT_SIZE);
aux = smem_aux_init();
mem_collect_intv(opt, bwt, len, seq, aux);
for (i = 0; i < aux->mem.n; ++i) {
bwtintv_t *p = &aux->mem.a[i];
int slen = (uint32_t)p->info - (p->info>>32); // seed length
int64_t k;
if (slen < opt->min_seed_len || p->x[2] > opt->max_occ) continue; // ignore if too short or too repetitive
for (k = 0; k < p->x[2]; ++k) {
mem_chain_t tmp, *lower, *upper;
mem_seed_t s;
int rid, to_add = 0;
s.rbeg = tmp.pos = bwt_sa(bwt, p->x[0] + k); // this is the base coordinate in the forward-reverse reference
s.qbeg = p->info>>32;
s.len = slen;
rid = bns_intv2rid(bns, s.rbeg, s.rbeg + s.len);
if (rid < 0) continue; // bridging multiple reference sequences or the forward-reverse boundary
if (kb_size(tree)) {
kb_intervalp(chn, tree, &tmp, &lower, &upper); // find the closest chain
if (!lower || !test_and_merge(opt, l_pac, lower, &s, rid)) to_add = 1;
} else to_add = 1;
if (to_add) { // add the seed as a new chain
tmp.n = 1; tmp.m = 4;
tmp.seeds = calloc(tmp.m, sizeof(mem_seed_t));
tmp.seeds[0] = s;
tmp.rid = rid;
kb_putp(chn, tree, &tmp);
}
}
}
smem_aux_destroy(aux);
kv_resize(mem_chain_t, chain, kb_size(tree));
#define traverse_func(p_) (chain.a[chain.n++] = *(p_))
__kb_traverse(mem_chain_t, tree, traverse_func);
#undef traverse_func
kb_destroy(chn, tree);
return chain;
}
/********************
* Filtering chains *
********************/
#define chn_beg(ch) ((ch).seeds->qbeg)
#define chn_end(ch) ((ch).seeds[(ch).n-1].qbeg + (ch).seeds[(ch).n-1].len)
#define flt_lt(a, b) ((a).w > (b).w)
KSORT_INIT(mem_flt, mem_chain_t, flt_lt)
int mem_chain_flt(const mem_opt_t *opt, int n_chn, mem_chain_t *a)
{
int i, k;
kvec_t(int) chains = {0,0,0}; // this keeps int indices of the non-overlapping chains
if (n_chn == 0) return 0; // no need to filter
// compute the weight of each chain and drop chains with small weight
for (i = k = 0; i < n_chn; ++i) {
mem_chain_t *c = &a[i];
c->first = -1; c->kept = 0;
c->w = mem_chain_weight(c);
if (c->w < opt->min_chain_weight) free(c->seeds);
else a[k++] = *c;
}
n_chn = k;
ks_introsort(mem_flt, n_chn, a);
// pairwise chain comparisons
a[0].kept = 3;
kv_push(int, chains, 0);
for (i = 1; i < n_chn; ++i) {
int large_ovlp = 0;
for (k = 0; k < chains.n; ++k) {
int j = chains.a[k];
int b_max = chn_beg(a[j]) > chn_beg(a[i])? chn_beg(a[j]) : chn_beg(a[i]);
int e_min = chn_end(a[j]) < chn_end(a[i])? chn_end(a[j]) : chn_end(a[i]);
if (e_min > b_max) { // have overlap
int li = chn_end(a[i]) - chn_beg(a[i]);
int lj = chn_end(a[j]) - chn_beg(a[j]);
int min_l = li < lj? li : lj;
if (e_min - b_max >= min_l * opt->mask_level && min_l < opt->max_chain_gap) { // significant overlap
large_ovlp = 1;
if (a[j].first < 0) a[j].first = i; // keep the first shadowed hit s.t. mapq can be more accurate
if (a[i].w < a[j].w * opt->drop_ratio && a[j].w - a[i].w >= opt->min_seed_len<<1)
break;
}
}
}
if (k == chains.n) {
kv_push(int, chains, i);
a[i].kept = large_ovlp? 2 : 3;
}
}
for (i = 0; i < chains.n; ++i) {
mem_chain_t *c = &a[chains.a[i]];
if (c->first >= 0) a[c->first].kept = 1;
}
free(chains.a);
for (i = k = 0; i < n_chn; ++i) { // don't extend more than opt->max_chain_extend .kept=1/2 chains
if (a[i].kept == 0 || a[i].kept == 3) continue;
if (++k >= opt->max_chain_extend) break;
}
for (; i < n_chn; ++i)
if (a[i].kept < 3) a[i].kept = 0;
for (i = k = 0; i < n_chn; ++i) { // free discarded chains
mem_chain_t *c = &a[i];
if (c->kept == 0) free(c->seeds);
else a[k++] = a[i];
}
n_chn = k;
return k;
}
/******************************
* De-overlap single-end hits *
******************************/
#define alnreg_slt2(a, b) ((a).re < (b).re)
KSORT_INIT(mem_ars2, mem_alnreg_t, alnreg_slt2)
#define alnreg_slt(a, b) ((a).score > (b).score || ((a).score == (b).score && ((a).rb < (b).rb || ((a).rb == (b).rb && (a).qb < (b).qb))))
KSORT_INIT(mem_ars, mem_alnreg_t, alnreg_slt)
#define alnreg_hlt(a, b) ((a).score > (b).score || ((a).score == (b).score && (a).hash < (b).hash))
KSORT_INIT(mem_ars_hash, mem_alnreg_t, alnreg_hlt)
int mem_sort_and_dedup(int n, mem_alnreg_t *a, float mask_level_redun)
{
int m, i, j;
if (n <= 1) return n;
ks_introsort(mem_ars2, n, a);
for (i = 1; i < n; ++i) {
mem_alnreg_t *p = &a[i];
if (p->rb >= a[i-1].re) continue;
for (j = i - 1; j >= 0 && p->rb < a[j].re; --j) {
mem_alnreg_t *q = &a[j];
int64_t or, oq, mr, mq;
if (q->qe == q->qb) continue; // a[j] has been excluded
or = q->re - p->rb; // overlap length on the reference
oq = q->qb < p->qb? q->qe - p->qb : p->qe - q->qb; // overlap length on the query
mr = q->re - q->rb < p->re - p->rb? q->re - q->rb : p->re - p->rb; // min ref len in alignment
mq = q->qe - q->qb < p->qe - p->qb? q->qe - q->qb : p->qe - p->qb; // min qry len in alignment
if (or > mask_level_redun * mr && oq > mask_level_redun * mq) { // one of the hits is redundant
if (p->score < q->score) {
p->qe = p->qb;
break;
} else q->qe = q->qb;
}
}
}
for (i = 0, m = 0; i < n; ++i) // exclude identical hits
if (a[i].qe > a[i].qb) {
if (m != i) a[m++] = a[i];
else ++m;
}
n = m;
ks_introsort(mem_ars, n, a);
for (i = 1; i < n; ++i) { // mark identical hits
if (a[i].score == a[i-1].score && a[i].rb == a[i-1].rb && a[i].qb == a[i-1].qb)
a[i].qe = a[i].qb;
}
for (i = 1, m = 1; i < n; ++i) // exclude identical hits
if (a[i].qe > a[i].qb) {
if (m != i) a[m++] = a[i];
else ++m;
}
return m;
}
int mem_test_and_remove_exact(const mem_opt_t *opt, int n, mem_alnreg_t *a, int qlen)
{
if (!(opt->flag & MEM_F_SELF_OVLP) || n == 0 || a->truesc != qlen * opt->a) return n;
memmove(a, a + 1, (n - 1) * sizeof(mem_alnreg_t));
return n - 1;
}
void mem_mark_primary_se(const mem_opt_t *opt, int n, mem_alnreg_t *a, int64_t id) // IMPORTANT: must run mem_sort_and_dedup() before calling this function
{ // similar to the loop in mem_chain_flt()
int i, k, tmp;
kvec_t(int) z;
if (n == 0) return;
kv_init(z);
for (i = 0; i < n; ++i) a[i].sub = 0, a[i].secondary = -1, a[i].hash = hash_64(id+i);
ks_introsort(mem_ars_hash, n, a);
tmp = opt->a + opt->b;
tmp = opt->o_del + opt->e_del > tmp? opt->o_del + opt->e_del : tmp;
tmp = opt->o_ins + opt->e_ins > tmp? opt->o_ins + opt->e_ins : tmp;
kv_push(int, z, 0);
for (i = 1; i < n; ++i) {
for (k = 0; k < z.n; ++k) {
int j = z.a[k];
int b_max = a[j].qb > a[i].qb? a[j].qb : a[i].qb;
int e_min = a[j].qe < a[i].qe? a[j].qe : a[i].qe;
if (e_min > b_max) { // have overlap
int min_l = a[i].qe - a[i].qb < a[j].qe - a[j].qb? a[i].qe - a[i].qb : a[j].qe - a[j].qb;
if (e_min - b_max >= min_l * opt->mask_level) { // significant overlap
if (a[j].sub == 0) a[j].sub = a[i].score;
if (a[j].score - a[i].score <= tmp) ++a[j].sub_n;
break;
}
}
}
if (k == z.n) kv_push(int, z, i);
else a[i].secondary = z.a[k];
}
free(z.a);
}
/****************************************
* Construct the alignment from a chain *
****************************************/
/* mem_chain2aln() vs mem_chain2aln_short()
*
* mem_chain2aln() covers all the functionality of mem_chain2aln_short().
* However, it may waste time on extracting the reference sequences given a
* very long query. mem_chain2aln_short() is faster for very short chains in a
* long query. It may fail when the matches are long or reach the end of the
* query. In this case, mem_chain2aln() will be called again.
* mem_chain2aln_short() is almost never used for short-read alignment.
*/
#define MEM_SHORT_EXT 50
#define MEM_SHORT_LEN 200
#define MEM_HSP_COEF 1.5
#define MAX_BAND_TRY 2
/* mem_test_chain_sw() uses SSE2-SW to align a short chain with 50bp added to
* each end of the chain. If the SW score is below min_HSP_score, it will
* return 0, informing the caller to discard the chain. This heuristic is
* somewhat similar to BLAST which drops a seed hit if ungapped extension is
* below a certain score (true for old BLAST; don't know how BLAST+ works).
*
* For PacBio data, we need to set high matching score and low gap penalties;
* otherwise we are likely to get fragmented alignments. However, with such
* settings, we can often extend most random seed hits to the end. These
* extensions are wasteful and time consuming. By testing the chain with SW,
* we can discard bad chains before performing the expensive extension.
*
* Although probably it is not a bad idea to use this function for
* low-divergence sequences, more testing is needed. For now, I only recommend
* to use mem_test_chain_sw() for PacBio data. It is disabled by default.
*/
int mem_test_chain_sw(const mem_opt_t *opt, const bntseq_t *bns, const uint8_t *pac, int l_query, const uint8_t *query, const mem_chain_t *c)
{
int i, qb, qe, rid;
int min_HSP_score = (int)(opt->min_chain_weight * opt->a * MEM_HSP_COEF + .499);
int64_t rb, re, l_pac = bns->l_pac;
uint8_t *rseq = 0;
kswr_t x;
if (c->n == 0) return -1;
qb = l_query; qe = 0;
rb = l_pac<<1; re = 0;
for (i = 0; i < c->n; ++i) {
const mem_seed_t *s = &c->seeds[i];
qb = qb < s->qbeg? qb : s->qbeg;
qe = qe > s->qbeg + s->len? qe : s->qbeg + s->len;
rb = rb < s->rbeg? rb : s->rbeg;
re = re > s->rbeg + s->len? re : s->rbeg + s->len;
}
qb -= MEM_SHORT_EXT; qe += MEM_SHORT_EXT;
qb = qb > 0? qb : 0;
qe = qe < l_query? qe : l_query;
rb -= MEM_SHORT_EXT; re += MEM_SHORT_EXT;
rb = rb > 0? rb : 0;
re = re < l_pac<<1? re : l_pac<<1;
if (rb < l_pac && l_pac < re) {
if (c->seeds[0].rbeg < l_pac) re = l_pac;
else rb = l_pac;
}
if ((re - rb) - (qe - qb) > MEM_SHORT_EXT || (qe - qb) - (re - rb) > MEM_SHORT_EXT) return 1;
if (qe - qb >= opt->w * 4 || re - rb >= opt->w * 4) return 1;
if (qe - qb >= MEM_SHORT_LEN || re - rb >= MEM_SHORT_LEN) return 1;
rseq = bns_fetch_seq(bns, pac, &rb, c->seeds[0].rbeg, &re, &rid);
assert(c->rid == rid);
x = ksw_align2(qe - qb, (uint8_t*)query + qb, re - rb, rseq, 5, opt->mat, opt->o_del, opt->e_del, opt->o_ins, opt->e_ins, KSW_XSTART, 0);
free(rseq);
if (x.score >= min_HSP_score) return 1;
if (bwa_verbose >= 4) printf("** give up the chain due to small HSP score %d.\n", x.score);
return 0;
}
int mem_chain2aln_short(const mem_opt_t *opt, const bntseq_t *bns, const uint8_t *pac, int l_query, const uint8_t *query, const mem_chain_t *c, mem_alnreg_v *av)
{
int i, qb, qe, xtra, rid;
int64_t rb, re, l_pac = bns->l_pac;
uint8_t *rseq = 0;
mem_alnreg_t a;
kswr_t x;
if (c->n == 0) return -1;
qb = l_query; qe = 0;
rb = l_pac<<1; re = 0;
memset(&a, 0, sizeof(mem_alnreg_t));
for (i = 0; i < c->n; ++i) {
const mem_seed_t *s = &c->seeds[i];
qb = qb < s->qbeg? qb : s->qbeg;
qe = qe > s->qbeg + s->len? qe : s->qbeg + s->len;
rb = rb < s->rbeg? rb : s->rbeg;
re = re > s->rbeg + s->len? re : s->rbeg + s->len;
a.seedcov += s->len;
}
qb -= MEM_SHORT_EXT; qe += MEM_SHORT_EXT;
if (qb <= 10 || qe >= l_query - 10) return 1; // because ksw_align() does not support end-to-end alignment
rb -= MEM_SHORT_EXT; re += MEM_SHORT_EXT;
rb = rb > 0? rb : 0;
re = re < l_pac<<1? re : l_pac<<1;
if (rb < l_pac && l_pac < re) {
if (c->seeds[0].rbeg < l_pac) re = l_pac;
else rb = l_pac;
}
if ((re - rb) - (qe - qb) > MEM_SHORT_EXT || (qe - qb) - (re - rb) > MEM_SHORT_EXT) return 1;
if (qe - qb >= opt->w * 4 || re - rb >= opt->w * 4) return 1;
if (qe - qb >= MEM_SHORT_LEN || re - rb >= MEM_SHORT_LEN) return 1;
rseq = bns_fetch_seq(bns, pac, &rb, c->seeds[0].rbeg, &re, &rid);
assert(c->rid == rid);
xtra = KSW_XSUBO | KSW_XSTART | ((qe - qb) * opt->a < 250? KSW_XBYTE : 0) | (opt->min_seed_len * opt->a);
x = ksw_align2(qe - qb, (uint8_t*)query + qb, re - rb, rseq, 5, opt->mat, opt->o_del, opt->e_del, opt->o_ins, opt->e_ins, xtra, 0);
free(rseq);
a.rb = rb + x.tb; a.re = rb + x.te + 1;
a.qb = qb + x.qb; a.qe = qb + x.qe + 1;
a.score = x.score;
a.csub = x.score2;
a.rid = c->rid;
if (bwa_verbose >= 4) printf("** Attempted alignment via mem_chain2aln_short(): [%d,%d) <=> [%ld,%ld); score=%d; %d/%d\n", a.qb, a.qe, (long)a.rb, (long)a.re, x.score, a.qe-a.qb, qe-qb);
if (x.tb < MEM_SHORT_EXT>>1 || x.te > re - rb - (MEM_SHORT_EXT>>1)) return 1;
kv_push(mem_alnreg_t, *av, a);
return 0;
}
static inline int cal_max_gap(const mem_opt_t *opt, int qlen)
{
int l_del = (int)((double)(qlen * opt->a - opt->o_del) / opt->e_del + 1.);
int l_ins = (int)((double)(qlen * opt->a - opt->o_ins) / opt->e_ins + 1.);
int l = l_del > l_ins? l_del : l_ins;
l = l > 1? l : 1;
return l < opt->w<<1? l : opt->w<<1;
}
void mem_chain2aln(const mem_opt_t *opt, const bntseq_t *bns, const uint8_t *pac, int l_query, const uint8_t *query, const mem_chain_t *c, mem_alnreg_v *av)
{
int i, k, rid, max_off[2], aw[2]; // aw: actual bandwidth used in extension
int64_t l_pac = bns->l_pac, rmax[2], tmp, max = 0;
const mem_seed_t *s;
uint8_t *rseq = 0;
uint64_t *srt;
if (c->n == 0) return;
// get the max possible span
rmax[0] = l_pac<<1; rmax[1] = 0;
for (i = 0; i < c->n; ++i) {
int64_t b, e;
const mem_seed_t *t = &c->seeds[i];
b = t->rbeg - (t->qbeg + cal_max_gap(opt, t->qbeg));
e = t->rbeg + t->len + ((l_query - t->qbeg - t->len) + cal_max_gap(opt, l_query - t->qbeg - t->len));
rmax[0] = rmax[0] < b? rmax[0] : b;
rmax[1] = rmax[1] > e? rmax[1] : e;
if (t->len > max) max = t->len;
}
rmax[0] = rmax[0] > 0? rmax[0] : 0;
rmax[1] = rmax[1] < l_pac<<1? rmax[1] : l_pac<<1;
if (rmax[0] < l_pac && l_pac < rmax[1]) { // crossing the forward-reverse boundary; then choose one side
if (c->seeds[0].rbeg < l_pac) rmax[1] = l_pac; // this works because all seeds are guaranteed to be on the same strand
else rmax[0] = l_pac;
}
// retrieve the reference sequence
rseq = bns_fetch_seq(bns, pac, &rmax[0], c->seeds[0].rbeg, &rmax[1], &rid);
assert(c->rid == rid);
srt = malloc(c->n * 8);
for (i = 0; i < c->n; ++i)
srt[i] = (uint64_t)c->seeds[i].len<<32 | i;
ks_introsort_64(c->n, srt);
for (k = c->n - 1; k >= 0; --k) {
mem_alnreg_t *a;
s = &c->seeds[(uint32_t)srt[k]];
for (i = 0; i < av->n; ++i) { // test whether extension has been made before
mem_alnreg_t *p = &av->a[i];
int64_t rd;
int qd, w, max_gap;
if (s->rbeg < p->rb || s->rbeg + s->len > p->re || s->qbeg < p->qb || s->qbeg + s->len > p->qe) continue; // not fully contained
// qd: distance ahead of the seed on query; rd: on reference
qd = s->qbeg - p->qb; rd = s->rbeg - p->rb;
max_gap = cal_max_gap(opt, qd < rd? qd : rd); // the maximal gap allowed in regions ahead of the seed
w = max_gap < opt->w? max_gap : opt->w; // bounded by the band width
if (qd - rd < w && rd - qd < w) break; // the seed is "around" a previous hit
// similar to the previous four lines, but this time we look at the region behind
qd = p->qe - (s->qbeg + s->len); rd = p->re - (s->rbeg + s->len);
max_gap = cal_max_gap(opt, qd < rd? qd : rd);
w = max_gap < opt->w? max_gap : opt->w;
if (qd - rd < w && rd - qd < w) break;
}
if (i < av->n) { // the seed is (almost) contained in an existing alignment; further testing is needed to confirm it is not leading to a different aln
if (bwa_verbose >= 4)
printf("** Seed(%d) [%ld;%ld,%ld] is almost contained in an existing alignment. Confirming whether extension is needed...\n", k, (long)s->len, (long)s->qbeg, (long)s->rbeg);
for (i = k + 1; i < c->n; ++i) { // check overlapping seeds in the same chain
const mem_seed_t *t;
if (srt[i] == 0) continue;
t = &c->seeds[(uint32_t)srt[i]];
if (t->len < s->len * .95) continue; // only check overlapping if t is long enough; TODO: more efficient by early stopping
if (s->qbeg <= t->qbeg && s->qbeg + s->len - t->qbeg >= s->len>>2 && t->qbeg - s->qbeg != t->rbeg - s->rbeg) break;
if (t->qbeg <= s->qbeg && t->qbeg + t->len - s->qbeg >= s->len>>2 && s->qbeg - t->qbeg != s->rbeg - t->rbeg) break;
}
if (i == c->n) { // no overlapping seeds; then skip extension
srt[k] = 0; // mark that seed extension has not been performed
continue;
}
if (bwa_verbose >= 4)
printf("** Seed(%d) might lead to a different alignment even though it is contained. Extension will be performed.\n", k);
}
a = kv_pushp(mem_alnreg_t, *av);
memset(a, 0, sizeof(mem_alnreg_t));
a->w = aw[0] = aw[1] = opt->w;
a->score = a->truesc = -1;
a->rid = c->rid;
if (bwa_verbose >= 4) err_printf("** ---> Extending from seed(%d) [%ld;%ld,%ld] <---\n", k, (long)s->len, (long)s->qbeg, (long)s->rbeg);
if (s->qbeg) { // left extension
uint8_t *rs, *qs;
int qle, tle, gtle, gscore;
qs = malloc(s->qbeg);
for (i = 0; i < s->qbeg; ++i) qs[i] = query[s->qbeg - 1 - i];
tmp = s->rbeg - rmax[0];
rs = malloc(tmp);
for (i = 0; i < tmp; ++i) rs[i] = rseq[tmp - 1 - i];
for (i = 0; i < MAX_BAND_TRY; ++i) {
int prev = a->score;
aw[0] = opt->w << i;
if (bwa_verbose >= 4) {
int j;
printf("*** Left ref: "); for (j = 0; j < tmp; ++j) putchar("ACGTN"[(int)rs[j]]); putchar('\n');
printf("*** Left query: "); for (j = 0; j < s->qbeg; ++j) putchar("ACGTN"[(int)qs[j]]); putchar('\n');
}
a->score = ksw_extend2(s->qbeg, qs, tmp, rs, 5, opt->mat, opt->o_del, opt->e_del, opt->o_ins, opt->e_ins, aw[0], opt->pen_clip5, opt->zdrop, s->len * opt->a, &qle, &tle, >le, &gscore, &max_off[0]);
if (bwa_verbose >= 4) { printf("*** Left extension: prev_score=%d; score=%d; bandwidth=%d; max_off_diagonal_dist=%d\n", prev, a->score, aw[0], max_off[0]); fflush(stdout); }
if (a->score == prev || max_off[0] < (aw[0]>>1) + (aw[0]>>2)) break;
}
// check whether we prefer to reach the end of the query
if (gscore <= 0 || gscore <= a->score - opt->pen_clip5) { // local extension
a->qb = s->qbeg - qle, a->rb = s->rbeg - tle;
a->truesc = a->score;
} else { // to-end extension
a->qb = 0, a->rb = s->rbeg - gtle;
a->truesc = gscore;
}
free(qs); free(rs);
} else a->score = a->truesc = s->len * opt->a, a->qb = 0, a->rb = s->rbeg;
if (s->qbeg + s->len != l_query) { // right extension
int qle, tle, qe, re, gtle, gscore, sc0 = a->score;
qe = s->qbeg + s->len;
re = s->rbeg + s->len - rmax[0];
assert(re >= 0);
for (i = 0; i < MAX_BAND_TRY; ++i) {
int prev = a->score;
aw[1] = opt->w << i;
if (bwa_verbose >= 4) {
int j;
printf("*** Right ref: "); for (j = 0; j < rmax[1] - rmax[0] - re; ++j) putchar("ACGTN"[(int)rseq[re+j]]); putchar('\n');
printf("*** Right query: "); for (j = 0; j < l_query - qe; ++j) putchar("ACGTN"[(int)query[qe+j]]); putchar('\n');
}
a->score = ksw_extend2(l_query - qe, query + qe, rmax[1] - rmax[0] - re, rseq + re, 5, opt->mat, opt->o_del, opt->e_del, opt->o_ins, opt->e_ins, aw[1], opt->pen_clip3, opt->zdrop, sc0, &qle, &tle, >le, &gscore, &max_off[1]);
if (bwa_verbose >= 4) { printf("*** Right extension: prev_score=%d; score=%d; bandwidth=%d; max_off_diagonal_dist=%d\n", prev, a->score, aw[1], max_off[1]); fflush(stdout); }
if (a->score == prev || max_off[1] < (aw[1]>>1) + (aw[1]>>2)) break;
}
// similar to the above
if (gscore <= 0 || gscore <= a->score - opt->pen_clip3) { // local extension
a->qe = qe + qle, a->re = rmax[0] + re + tle;
a->truesc += a->score - sc0;
} else { // to-end extension
a->qe = l_query, a->re = rmax[0] + re + gtle;
a->truesc += gscore - sc0;
}
} else a->qe = l_query, a->re = s->rbeg + s->len;
if (bwa_verbose >= 4) printf("*** Added alignment region: [%d,%d) <=> [%ld,%ld); score=%d; {left,right}_bandwidth={%d,%d}\n", a->qb, a->qe, (long)a->rb, (long)a->re, a->score, aw[0], aw[1]);
// compute seedcov
for (i = 0, a->seedcov = 0; i < c->n; ++i) {
const mem_seed_t *t = &c->seeds[i];
if (t->qbeg >= a->qb && t->qbeg + t->len <= a->qe && t->rbeg >= a->rb && t->rbeg + t->len <= a->re) // seed fully contained
a->seedcov += t->len; // this is not very accurate, but for approx. mapQ, this is good enough
}
a->w = aw[0] > aw[1]? aw[0] : aw[1];
}
free(srt); free(rseq);
}
/*****************************
* Basic hit->SAM conversion *
*****************************/
static inline int infer_bw(int l1, int l2, int score, int a, int q, int r)
{
int w;
if (l1 == l2 && l1 * a - score < (q + r - a)<<1) return 0; // to get equal alignment length, we need at least two gaps
w = ((double)((l1 < l2? l1 : l2) * a - score - q) / r + 2.);
if (w < abs(l1 - l2)) w = abs(l1 - l2);
return w;
}
static inline int get_rlen(int n_cigar, const uint32_t *cigar)
{
int k, l;
for (k = l = 0; k < n_cigar; ++k) {
int op = cigar[k]&0xf;
if (op == 0 || op == 2)
l += cigar[k]>>4;
}
return l;
}
void mem_aln2sam(const bntseq_t *bns, kstring_t *str, bseq1_t *s, int n, const mem_aln_t *list, int which, const mem_aln_t *m_)
{
int i;
mem_aln_t ptmp = list[which], *p = &ptmp, mtmp, *m = 0; // make a copy of the alignment to convert
if (m_) mtmp = *m_, m = &mtmp;
// set flag
p->flag |= m? 0x1 : 0; // is paired in sequencing
p->flag |= p->rid < 0? 0x4 : 0; // is mapped
p->flag |= m && m->rid < 0? 0x8 : 0; // is mate mapped
if (p->rid < 0 && m && m->rid >= 0) // copy mate to alignment
p->rid = m->rid, p->pos = m->pos, p->is_rev = m->is_rev, p->n_cigar = 0;
if (m && m->rid < 0 && p->rid >= 0) // copy alignment to mate
m->rid = p->rid, m->pos = p->pos, m->is_rev = p->is_rev, m->n_cigar = 0;
p->flag |= p->is_rev? 0x10 : 0; // is on the reverse strand
p->flag |= m && m->is_rev? 0x20 : 0; // is mate on the reverse strand
// print up to CIGAR
kputs(s->name, str); kputc('\t', str); // QNAME
kputw((p->flag&0xffff) | (p->flag&0x10000? 0x100 : 0), str); kputc('\t', str); // FLAG
if (p->rid >= 0) { // with coordinate
kputs(bns->anns[p->rid].name, str); kputc('\t', str); // RNAME
kputl(p->pos + 1, str); kputc('\t', str); // POS
kputw(p->mapq, str); kputc('\t', str); // MAPQ
if (p->n_cigar) { // aligned
for (i = 0; i < p->n_cigar; ++i) {
int c = p->cigar[i]&0xf;
if (c == 3 || c == 4) c = which? 4 : 3; // use hard clipping for supplementary alignments
kputw(p->cigar[i]>>4, str); kputc("MIDSH"[c], str);
}
} else kputc('*', str); // having a coordinate but unaligned (e.g. when copy_mate is true)
} else kputsn("*\t0\t0\t*", 7, str); // without coordinte
kputc('\t', str);
// print the mate position if applicable
if (m && m->rid >= 0) {
if (p->rid == m->rid) kputc('=', str);
else kputs(bns->anns[m->rid].name, str);
kputc('\t', str);
kputl(m->pos + 1, str); kputc('\t', str);
if (p->rid == m->rid) {
int64_t p0 = p->pos + (p->is_rev? get_rlen(p->n_cigar, p->cigar) - 1 : 0);
int64_t p1 = m->pos + (m->is_rev? get_rlen(m->n_cigar, m->cigar) - 1 : 0);
if (m->n_cigar == 0 || p->n_cigar == 0) kputc('0', str);
else kputl(-(p0 - p1 + (p0 > p1? 1 : p0 < p1? -1 : 0)), str);
} else kputc('0', str);
} else kputsn("*\t0\t0", 5, str);
kputc('\t', str);
// print SEQ and QUAL
if (p->flag & 0x100) { // for secondary alignments, don't write SEQ and QUAL
kputsn("*\t*", 3, str);
} else if (!p->is_rev) { // the forward strand
int i, qb = 0, qe = s->l_seq;
if (p->n_cigar) {
if (which && ((p->cigar[0]&0xf) == 4 || (p->cigar[0]&0xf) == 3)) qb += p->cigar[0]>>4;
if (which && ((p->cigar[p->n_cigar-1]&0xf) == 4 || (p->cigar[p->n_cigar-1]&0xf) == 3)) qe -= p->cigar[p->n_cigar-1]>>4;
}
ks_resize(str, str->l + (qe - qb) + 1);
for (i = qb; i < qe; ++i) str->s[str->l++] = "ACGTN"[(int)s->seq[i]];
kputc('\t', str);
if (s->qual) { // printf qual
ks_resize(str, str->l + (qe - qb) + 1);
for (i = qb; i < qe; ++i) str->s[str->l++] = s->qual[i];
str->s[str->l] = 0;
} else kputc('*', str);
} else { // the reverse strand
int i, qb = 0, qe = s->l_seq;
if (p->n_cigar) {
if (which && ((p->cigar[0]&0xf) == 4 || (p->cigar[0]&0xf) == 3)) qe -= p->cigar[0]>>4;
if (which && ((p->cigar[p->n_cigar-1]&0xf) == 4 || (p->cigar[p->n_cigar-1]&0xf) == 3)) qb += p->cigar[p->n_cigar-1]>>4;
}
ks_resize(str, str->l + (qe - qb) + 1);
for (i = qe-1; i >= qb; --i) str->s[str->l++] = "TGCAN"[(int)s->seq[i]];
kputc('\t', str);
if (s->qual) { // printf qual
ks_resize(str, str->l + (qe - qb) + 1);
for (i = qe-1; i >= qb; --i) str->s[str->l++] = s->qual[i];
str->s[str->l] = 0;
} else kputc('*', str);
}
// print optional tags
if (p->n_cigar) {
kputsn("\tNM:i:", 6, str); kputw(p->NM, str);
kputsn("\tMD:Z:", 6, str); kputs((char*)(p->cigar + p->n_cigar), str);
}
if (p->score >= 0) { kputsn("\tAS:i:", 6, str); kputw(p->score, str); }
if (p->sub >= 0) { kputsn("\tXS:i:", 6, str); kputw(p->sub, str); }
if (bwa_rg_id[0]) { kputsn("\tRG:Z:", 6, str); kputs(bwa_rg_id, str); }
if (!(p->flag & 0x100)) { // not multi-hit
for (i = 0; i < n; ++i)
if (i != which && !(list[i].flag&0x100)) break;
if (i < n) { // there are other primary hits; output them
kputsn("\tSA:Z:", 6, str);
for (i = 0; i < n; ++i) {
const mem_aln_t *r = &list[i];
int k;
if (i == which || (list[i].flag&0x100)) continue; // proceed if: 1) different from the current; 2) not shadowed multi hit
kputs(bns->anns[r->rid].name, str); kputc(',', str);
kputl(r->pos+1, str); kputc(',', str);
kputc("+-"[r->is_rev], str); kputc(',', str);
for (k = 0; k < r->n_cigar; ++k) {
kputw(r->cigar[k]>>4, str); kputc("MIDSH"[r->cigar[k]&0xf], str);
}
kputc(',', str); kputw(r->mapq, str);
kputc(',', str); kputw(r->NM, str);
kputc(';', str);
}
}
}
if (s->comment) { kputc('\t', str); kputs(s->comment, str); }
kputc('\n', str);
}
/************************
* Integrated interface *
************************/
int mem_approx_mapq_se(const mem_opt_t *opt, const mem_alnreg_t *a)
{
int mapq, l, sub = a->sub? a->sub : opt->min_seed_len * opt->a;
double identity;
sub = a->csub > sub? a->csub : sub;
if (sub >= a->score) return 0;
l = a->qe - a->qb > a->re - a->rb? a->qe - a->qb : a->re - a->rb;
identity = 1. - (double)(l * opt->a - a->score) / (opt->a + opt->b) / l;
if (a->score == 0) {
mapq = 0;
} else if (opt->mapQ_coef_len > 0) {
double tmp;
tmp = l < opt->mapQ_coef_len? 1. : opt->mapQ_coef_fac / log(l);
tmp *= identity * identity;
mapq = (int)(6.02 * (a->score - sub) / opt->a * tmp * tmp + .499);
} else {
mapq = (int)(MEM_MAPQ_COEF * (1. - (double)sub / a->score) * log(a->seedcov) + .499);
mapq = identity < 0.95? (int)(mapq * identity * identity + .499) : mapq;
}
if (a->sub_n > 0) mapq -= (int)(4.343 * log(a->sub_n+1) + .499);
if (mapq > 60) mapq = 60;
if (mapq < 0) mapq = 0;
return mapq;
}
// TODO (future plan): group hits into a uint64_t[] array. This will be cleaner and more flexible
void mem_reg2sam_se(const mem_opt_t *opt, const bntseq_t *bns, const uint8_t *pac, bseq1_t *s, mem_alnreg_v *a, int extra_flag, const mem_aln_t *m)
{
kstring_t str;
kvec_t(mem_aln_t) aa;
int k;
kv_init(aa);
str.l = str.m = 0; str.s = 0;
for (k = 0; k < a->n; ++k) {
mem_alnreg_t *p = &a->a[k];
mem_aln_t *q;
if (p->score < opt->T) continue;
if (p->secondary >= 0 && !(opt->flag&MEM_F_ALL)) continue;
if (p->secondary >= 0 && p->score < a->a[p->secondary].score * opt->drop_ratio) continue;
q = kv_pushp(mem_aln_t, aa);
*q = mem_reg2aln2(opt, bns, pac, s->l_seq, s->seq, p, s->name);
if (q->rid < 0) {
--aa.n;
continue;
}
q->flag |= extra_flag; // flag secondary
if (p->secondary >= 0) q->sub = -1; // don't output sub-optimal score
if (k && p->secondary < 0) // if supplementary
q->flag |= (opt->flag&MEM_F_NO_MULTI)? 0x10000 : 0x800;
if (k && q->mapq > aa.a[0].mapq) q->mapq = aa.a[0].mapq;
}
if (aa.n == 0) { // no alignments good enough; then write an unaligned record
mem_aln_t t;
t = mem_reg2aln(opt, bns, pac, s->l_seq, s->seq, 0);
t.flag |= extra_flag;
mem_aln2sam(bns, &str, s, 1, &t, 0, m);
} else {
for (k = 0; k < aa.n; ++k)
mem_aln2sam(bns, &str, s, aa.n, aa.a, k, m);
for (k = 0; k < aa.n; ++k) free(aa.a[k].cigar);
free(aa.a);
}
s->sam = str.s;
}
mem_alnreg_v mem_align1_core(const mem_opt_t *opt, const bwt_t *bwt, const bntseq_t *bns, const uint8_t *pac, int l_seq, char *seq)
{
int i;
mem_chain_v chn;
mem_alnreg_v regs;
for (i = 0; i < l_seq; ++i) // convert to 2-bit encoding if we have not done so
seq[i] = seq[i] < 4? seq[i] : nst_nt4_table[(int)seq[i]];
chn = mem_chain(opt, bwt, bns, l_seq, (uint8_t*)seq);
chn.n = mem_chain_flt(opt, chn.n, chn.a);
if (bwa_verbose >= 4) mem_print_chain(bns, &chn);
kv_init(regs);
for (i = 0; i < chn.n; ++i) {
mem_chain_t *p = &chn.a[i];
int ret;
if (bwa_verbose >= 4) err_printf("* ---> Processing chain(%d) <---\n", i);
if (opt->min_chain_weight > 0) ret = mem_test_chain_sw(opt, bns, pac, l_seq, (uint8_t*)seq, p);
else ret = mem_chain2aln_short(opt, bns, pac, l_seq, (uint8_t*)seq, p, ®s);
if (ret > 0) mem_chain2aln(opt, bns, pac, l_seq, (uint8_t*)seq, p, ®s);
free(chn.a[i].seeds);
}
free(chn.a);
regs.n = mem_sort_and_dedup(regs.n, regs.a, opt->mask_level_redun);
if (opt->flag & MEM_F_SELF_OVLP)
regs.n = mem_test_and_remove_exact(opt, regs.n, regs.a, l_seq);
if (bwa_verbose >= 4) {
err_printf("* %ld chains remain after removing duplicated chains\n", regs.n);
for (i = 0; i < regs.n; ++i) {
mem_alnreg_t *p = ®s.a[i];
printf("** %d, [%d,%d) <=> [%ld,%ld)\n", p->score, p->qb, p->qe, (long)p->rb, (long)p->re);
}
}
return regs;
}
mem_aln_t mem_reg2aln2(const mem_opt_t *opt, const bntseq_t *bns, const uint8_t *pac, int l_query, const char *query_, const mem_alnreg_t *ar, const char *name)
{
mem_aln_t a;
int i, w2, tmp, qb, qe, NM, score, is_rev, last_sc = -(1<<30), l_MD;
int64_t pos, rb, re;
uint8_t *query;
memset(&a, 0, sizeof(mem_aln_t));
if (ar == 0 || ar->rb < 0 || ar->re < 0) { // generate an unmapped record
a.rid = -1; a.pos = -1; a.flag |= 0x4;
return a;
}
qb = ar->qb, qe = ar->qe;
rb = ar->rb, re = ar->re;
query = malloc(l_query);
for (i = 0; i < l_query; ++i) // convert to the nt4 encoding
query[i] = query_[i] < 5? query_[i] : nst_nt4_table[(int)query_[i]];
a.mapq = ar->secondary < 0? mem_approx_mapq_se(opt, ar) : 0;
if (ar->secondary >= 0) a.flag |= 0x100; // secondary alignment
tmp = infer_bw(qe - qb, re - rb, ar->truesc, opt->a, opt->o_del, opt->e_del);
w2 = infer_bw(qe - qb, re - rb, ar->truesc, opt->a, opt->o_ins, opt->e_ins);
w2 = w2 > tmp? w2 : tmp;
if (bwa_verbose >= 4) printf("* Band width: inferred=%d, cmd_opt=%d, alnreg=%d\n", w2, opt->w, ar->w);
if (w2 > opt->w) w2 = w2 < ar->w? w2 : ar->w;
i = 0; a.cigar = 0;