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gfa-aug.c
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gfa-aug.c
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#include <assert.h>
#include <ctype.h>
#include "gfa-priv.h"
#include "ksort.h"
typedef struct {
uint32_t side;
uint32_t ins:31, end:1;
} gfa_split_t;
#define split_key(p) ((p).side)
KRADIX_SORT_INIT(split, gfa_split_t, split_key, 4)
static inline void create_first_arc_semi(gfa_t *g, const gfa_seg_t *seg, uint32_t v, uint32_t w, int32_t rank, uint64_t link_id, int is_comp)
{
gfa_arc_t *a;
if (g->n_arc == g->m_arc) GFA_EXPAND(g->arc, g->m_arc);
a = &g->arc[g->n_arc++];
a->v_lv = (uint64_t)v<<32 | seg[v>>1].len;
a->w = w;
a->rank = rank;
a->ov = a->ow = 0;
a->link_id = link_id;
a->del = 0;
a->comp = !!is_comp;
}
static inline void create_first_arc(gfa_t *g, const gfa_seg_t *seg, uint32_t v, uint32_t w, int32_t rank)
{
uint64_t link_id = g->n_arc;
create_first_arc_semi(g, seg, v, w, rank, link_id, 0);
create_first_arc_semi(g, seg, w^1, v^1, rank, link_id, 1);
}
void gfa_augment(gfa_t *g, int32_t n_ins, const gfa_ins_t *ins, int32_t n_ctg, const char *const* name, const char *const* seq)
{
int32_t i, j, k, *scnt, *soff, n_ctg_seg, n_old_seg, n_seg;
gfa_split_t *sp;
gfa_seg_t *seg;
char buf[16];
uint64_t t, n_old_arc = g->n_arc, *ins_side, *oldcnt;
if (n_ins <= 0 || n_ctg <= 0) return;
// set soff[]
GFA_CALLOC(scnt, g->n_seg);
for (i = 0; i < n_ins; ++i)
++scnt[ins[i].v[0]>>1], ++scnt[ins[i].v[1]>>1];
GFA_MALLOC(soff, g->n_seg + 1);
for (j = 1, soff[0] = 0; j <= g->n_seg; ++j)
soff[j] = soff[j-1] + scnt[j-1];
// populate sp[]
GFA_MALLOC(sp, soff[g->n_seg]);
GFA_BZERO(scnt, g->n_seg);
for (i = 0, n_ctg_seg = 0; i < n_ins; ++i) {
const gfa_ins_t *p = &ins[i];
for (k = 0; k < 2; ++k) {
uint32_t vlen = g->seg[p->v[k]>>1].len;
gfa_split_t *q = &sp[soff[p->v[k]>>1] + scnt[p->v[k]>>1]];
q->ins = i, q->end = k;
q->side = (p->v[k]&1? vlen - p->voff[k] : p->voff[k]) << 1 | ((p->v[k]&1) ^ k);
assert(q->side != (0<<1|0) && q->side != (vlen<<1|1)); // not possible to link such sides
++scnt[p->v[k]>>1];
}
if (p->coff[1] > p->coff[0])
++n_ctg_seg;
}
free(scnt);
// sort sp[]
for (j = 0, n_old_seg = 0; j < g->n_seg; ++j)
if (soff[j+1] - soff[j] > 1)
radix_sort_split(&sp[soff[j]], &sp[soff[j+1]]);
// precompute the number of segments after split
for (j = 0, n_old_seg = 0; j < g->n_seg; ++j) {
int32_t i0;
for (i0 = soff[j], i = i0 + 1, k = 0; i <= soff[j+1]; ++i)
if (i == soff[j+1] || sp[i0].side>>1 != sp[i].side>>1) {
if (sp[i0].side>>1 != 0 && sp[i0].side>>1 != g->seg[j].len) // otherwise no new segment will be created
++k;
i0 = i;
}
n_old_seg += k + 1;
}
// compute ins_side[] and split old segments
n_seg = n_old_seg + n_ctg_seg;
GFA_CALLOC(seg, n_seg);
GFA_CALLOC(ins_side, n_ins);
GFA_MALLOC(oldcnt, g->n_seg);
for (j = 0, k = 0; j < g->n_seg; ++j) {
int32_t i0, l, off = 0, k0 = k;
gfa_seg_t *s = &g->seg[j];
gfa_seg_t *t = &seg[k]; // this is so far a placeholder
// create the first half of a new segment
snprintf(buf, 15, "s%d", k + 1);
t->name = gfa_strdup(buf);
t->snid = s->snid, t->soff = s->soff, t->rank = s->rank;
// iterate over splits
for (i0 = soff[j], i = i0 + 1; i <= soff[j+1]; ++i) {
if (i == soff[j+1] || sp[i].side>>1 != sp[i0].side>>1) {
gfa_split_t *q0 = &sp[i0];
for (l = i0; l < i; ++l) {
gfa_split_t *q = &sp[l];
int32_t shift = q->end == 0? 32 : 0; // first end on the higher 32 bits
int32_t side = q->side & 1;
int32_t which = q->side>>1 == 0? 0 : side; // special-casing when q->side==1, because no new segment created in this case
ins_side[q->ins] |= (uint64_t)((uint32_t)(k + which) << 1 | (side^q->end)) << shift;
}
if (q0->side>>1 != 0 && q0->side>>1 != g->seg[j].len) { // create a new segment
t->len = (q0->side>>1) - off;
GFA_MALLOC(t->seq, t->len + 1);
memcpy(t->seq, &s->seq[off], t->len);
t->seq[t->len] = 0;
off += t->len;
t = &seg[++k]; // create a new segment
snprintf(buf, 15, "s%d", k + 1);
t->name = gfa_strdup(buf);
t->snid = s->snid, t->soff = s->soff + off, t->rank = s->rank;
}
i0 = i;
}
}
// finish the last segment
t->len = s->len - off;
GFA_MALLOC(t->seq, t->len + 1);
memcpy(t->seq, &s->seq[off], t->len);
t->seq[t->len] = 0;
++k;
oldcnt[j] = (uint64_t)k0 << 32 | (k - k0);
// add new arcs between newly created segments
for (i = 0; i < k - k0 - 1; ++i)
create_first_arc(g, seg, (uint32_t)(k0+i)<<1, (uint32_t)(k0+i+1)<<1, s->rank);
}
assert(k == n_old_seg);
free(soff);
free(sp);
// update existing g->arc[]
for (t = 0; t < n_old_arc; ++t) {
gfa_arc_t *a = &g->arc[t];
uint32_t v = a->v_lv >> 32;
uint32_t off = oldcnt[v>>1]>>32, cnt = (uint32_t)oldcnt[v>>1];
v = (v&1) == 0? (off+cnt-1)<<1 : off<<1 | 1;
a->v_lv = (uint64_t)v << 32 | seg[v>>1].len;
off = oldcnt[a->w>>1]>>32, cnt = (uint32_t)oldcnt[a->w>>1];
a->w = (a->w&1) == 0? off<<1 : (off+cnt-1)<<1 | 1;
}
free(oldcnt);
// create newly inserted segments
for (i = 0, k = n_old_seg; i < n_ins; ++i) {
const gfa_ins_t *p = &ins[i];
if (p->coff[0] < p->coff[1]) { // not a pure deletion
gfa_seg_t *t = &seg[k];
snprintf(buf, 15, "s%d", k + 1);
t->name = gfa_strdup(buf);
GFA_MALLOC(t->seq, p->coff[1] - p->coff[0] + 1);
for (j = 0; j < p->coff[1] - p->coff[0]; ++j)
t->seq[j] = seq[p->ctg][p->coff[0] + j];
t->seq[j] = 0;
t->len = j;
t->snid = gfa_sseq_add(g, name[p->ctg]);
t->soff = p->coff[0];
t->rank = g->max_rank + 1; // TODO: to deal with SN/SO/SR tags somewhere
gfa_sseq_update(g, t);
create_first_arc(g, seg, ins_side[i]>>32, (uint32_t)k<<1, t->rank);
create_first_arc(g, seg, (uint32_t)k<<1, (uint32_t)ins_side[i], t->rank);
++k;
} else { // a pure deletion
create_first_arc(g, seg, ins_side[i]>>32, (uint32_t)ins_side[i], g->max_rank + 1);
}
}
free(ins_side);
// update *g
for (j = 0; j < g->n_seg; ++j) {
free(g->seg[j].name);
free(g->seg[j].seq);
free(g->seg[j].aux.aux);
}
free(g->seg);
g->seg = seg, g->n_seg = g->m_seg = n_seg;
++g->max_rank;
GFA_REALLOC(g->link_aux, g->m_arc);
GFA_BZERO(&g->link_aux[n_old_arc], g->m_arc - n_old_arc);
gfa_arc_sort(g);
gfa_arc_index(g);
gfa_fix_multi(g);
// k = gfa_fix_symm(g); assert(k == 0); // for debugging; the graph should be symmetric
}
static int32_t gfa_ins_shrink_semi(const gfa_t *g, int32_t pen, uint32_t v, int32_t voff, int32_t coff, uint32_t vv, int32_t vend, int32_t cend, const char *seq)
{
int32_t i, j, l, dir, score, max, max_l;
extern unsigned char gfa_comp_table[256];
if (cend == coff) return 0;
dir = cend > coff? +1 : -1;
for (i = coff, j = voff, l = max_l = 0, score = max = 0; i != cend; i += dir, j += dir) {
int32_t cg, vlen = g->seg[v>>1].len;
if (j == vlen || j == -1) break;
if (vv == v && j == vend) break;
++l;
cg = (v&1) == 0? g->seg[v>>1].seq[j] : gfa_comp_table[(uint8_t)g->seg[v>>1].seq[vlen - 1 - j]];
score += tolower(cg) == tolower(seq[i])? +1 : -pen;
if (score > max) max = score, max_l = l;
if (score < max - pen * pen) break; // X-drop
}
return max_l;
}
int gfa_ins_adj(const gfa_t *g, int pen, gfa_ins_t *ins, const char *seq) // min_len is NOT used for now
{
int32_t l, tot = 0;
l = gfa_ins_shrink_semi(g, pen, ins->v[0], ins->voff[0], ins->coff[0], ins->v[1], ins->voff[1], ins->coff[1], seq);
ins->voff[0] += l, ins->coff[0] += l, tot += l;
l = gfa_ins_shrink_semi(g, pen, ins->v[1], ins->voff[1] - 1, ins->coff[1] - 1, ins->v[0], ins->voff[0] - 1, ins->coff[0] - 1, seq);
ins->voff[1] -= l, ins->coff[1] -= l, tot += l;
return tot;
}
static inline int check_multi(const gfa_t *g, const gfa_ins_t *ins)
{
if (ins->v[0] != ins->v[1] && ins->coff[1] - ins->coff[0] == 0) {
const gfa_seg_t *s[2];
uint32_t v[2];
s[0] = &g->seg[ins->v[0]>>1];
s[1] = &g->seg[ins->v[1]>>1];
if (ins->voff[0] != 0 && ins->voff[0] != s[0]->len) return 0;
if (ins->voff[1] != 0 && ins->voff[1] != s[1]->len) return 0;
v[0] = ins->voff[0] == 0? ins->v[0]^1 : ins->v[0];
v[1] = ins->voff[1] == 0? ins->v[1] : ins->v[1]^1;
if (gfa_find_arc(g, v[0], v[1]) >= 0) return 1;
return 0;
} else return 0;
}
int32_t gfa_ins_filter(const gfa_t *g, int32_t n_ins, gfa_ins_t *ins) // filter out impossible inserts
{
int32_t i, k, n;
for (i = 0, n = 0; i < n_ins; ++i) {
gfa_ins_t *p = &ins[i];
for (k = 0; k < 2; ++k) {
uint32_t vlen = g->seg[p->v[k]>>1].len;
uint32_t side = (p->v[k]&1? vlen - p->voff[k] : p->voff[k]) << 1 | ((p->v[k]&1) ^ k);
if (side == (0<<1|0) || side == (vlen<<1|1))
break;
}
if (k != 2 || check_multi(g, p)) { // multi-link may happen due to inconsistency between graph chaining and WFA alignment
if (gfa_verbose >= 2)
fprintf(stderr, "[W::%s] %s between %c%s and %c%s derived from the %d-th query at %d-%d\n",
__func__, k != 2? "impossible insert" : "multi-link",
"><"[p->v[0]&1], g->seg[p->v[0]>>1].name, "><"[p->v[1]&1], g->seg[p->v[1]>>1].name, p->ctg, p->coff[0], p->coff[1]);
continue;
}
ins[n++] = ins[i];
}
return n;
}