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gfa-util.c
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#include <assert.h>
#include <stdlib.h>
#include <ctype.h>
#include "gfa-priv.h"
#include "kvec.h"
#include "ksort.h"
#include "kdq.h"
KDQ_INIT(uint64_t)
#include "khashl.h"
KHASHL_MAP_INIT(KH_LOCAL, gfa_map64_t, gfa_map64, uint64_t, int32_t, kh_hash_uint64, kh_eq_generic)
/*
* rGFA: get stable FASTA
*/
static uint64_t find_join(const gfa_t *g, uint32_t v)
{
gfa_seg_t *t, *s = &g->seg[v>>1];
int32_t i, nv, n_low, n_r;
uint32_t w;
gfa_arc_t *av;
if (s->rank == 0) return (uint64_t)-1;
nv = gfa_arc_n(g, v);
av = gfa_arc_a(g, v);
for (i = 0, n_low = n_r = 0, w = 0; i < nv; ++i) {
gfa_arc_t *q = &av[i];
if (q->rank >= 0 && q->rank == s->rank) {
++n_r, w = q->w;
} else {
t = &g->seg[q->w>>1];
if (t->rank >= 0 && t->rank < s->rank)
++n_low, w = q->w;
}
}
if (n_r != 1 && gfa_verbose >= 2)
fprintf(stderr, "[W] failed to find the associated arc for vertex %c%s[%d]: %d,%d\n", "><"[v&1], g->seg[v>>1].name, v, n_r, n_low);
if (n_r != 1 && n_low != 1) return (uint64_t)-1;
t = &g->seg[w>>1];
return (uint64_t)t->snid<<32 | (uint32_t)(w&1? t->soff + t->len : t->soff) << 1 | (w&1);
}
gfa_sfa_t *gfa_gfa2sfa(const gfa_t *g, int32_t *n_sfa_, int32_t write_seq)
{
int32_t i, j, k, *scnt, *soff, n_sfa;
gfa_sfa_t *sfa = 0;
uint64_t *a;
*n_sfa_ = 0;
if (g->n_sseq == 0) return 0;
// precount
GFA_CALLOC(scnt, g->n_sseq);
for (i = 0; i < g->n_seg; ++i)
if (g->seg[i].snid >= 0)
++scnt[g->seg[i].snid];
GFA_MALLOC(soff, g->n_sseq + 1);
for (soff[0] = 0, i = 1; i <= g->n_sseq; ++i)
soff[i] = soff[i - 1] + scnt[i - 1];
// fill a[]
GFA_BZERO(scnt, g->n_sseq);
GFA_MALLOC(a, g->n_seg);
for (i = 0; i < g->n_seg; ++i) {
const gfa_seg_t *s = &g->seg[i];
if (s->snid < 0) continue;
a[soff[s->snid] + scnt[s->snid]] = (uint64_t)s->soff<<32 | i;
++scnt[s->snid];
}
for (i = 0; i < g->n_sseq; ++i)
if (scnt[i] > 1)
radix_sort_gfa64(&a[soff[i]], &a[soff[i+1]]);
free(scnt);
// check
n_sfa = g->n_sseq;
for (i = 0; i < g->n_sseq; ++i) {
const gfa_seg_t *s;
if (soff[i] == soff[i+1]) --n_sfa;
if (soff[i] == soff[i+1]) continue;
s = &g->seg[(int32_t)a[soff[i]]];
if (s->rank == 0 && s->soff != 0) {
if (gfa_verbose >= 2)
fprintf(stderr, "[W] rank-0 stable sequence \"%s\" not started with 0\n", g->sseq[s->snid].name);
goto end_check;
}
for (j = soff[i] + 1; j < soff[i+1]; ++j) {
const gfa_seg_t *s = &g->seg[(int32_t)a[j-1]];
const gfa_seg_t *t = &g->seg[(int32_t)a[j]];
if (s->soff + s->len > t->soff) {
if (gfa_verbose >= 2)
fprintf(stderr, "[W] overlap on stable sequence \"%s\"\n", g->sseq[s->snid].name);
goto end_check;
}
if (s->rank == 0 && s->soff + s->len != t->soff) {
if (gfa_verbose >= 2)
fprintf(stderr, "[W] rank-0 stable sequence \"%s\" is not contiguous\n", g->sseq[s->snid].name);
goto end_check;
}
if (s->rank != t->rank) {
if (gfa_verbose >= 2)
fprintf(stderr, "[W] stable sequence \"%s\" associated with different ranks\n", g->sseq[s->snid].name);
goto end_check;
}
if (s->soff + s->len == t->soff) {
int32_t k, nv;
const gfa_arc_t *av;
nv = gfa_arc_n(g, (uint32_t)a[j-1]<<1);
av = gfa_arc_a(g, (uint32_t)a[j-1]<<1);
for (k = 0; k < nv; ++k)
if (av[k].w == (uint32_t)a[j]<<1)
break;
if (s->rank == 0 && k == nv) {
if (gfa_verbose >= 2)
fprintf(stderr, "[W] nearby segments on rank-0 stable sequence \"%s\" are not connected\n", g->sseq[s->snid].name);
goto end_check;
}
if (k == nv) ++n_sfa;
} else ++n_sfa;
}
}
// fill sfa[]
*n_sfa_ = n_sfa;
GFA_CALLOC(sfa, n_sfa);
for (i = 0, k = 0; i < g->n_sseq; ++i) {
int32_t jst;
if (soff[i] == soff[i+1]) continue;
for (j = soff[i] + 1, jst = j - 1; j <= soff[i+1]; ++j) {
int32_t is_cont = 0;
if (j < soff[i+1]) {
const gfa_seg_t *s = &g->seg[(int32_t)a[j-1]];
const gfa_seg_t *t = &g->seg[(int32_t)a[j]];
if (s->soff + s->len == t->soff) {
int32_t k, nv;
const gfa_arc_t *av;
nv = gfa_arc_n(g, (uint32_t)a[j-1]<<1);
av = gfa_arc_a(g, (uint32_t)a[j-1]<<1);
for (k = 0; k < nv; ++k)
if (av[k].w == (uint32_t)a[j]<<1)
break;
if (k < nv) is_cont = 1;
}
}
if (!is_cont) {
int32_t l;
const gfa_seg_t *s = &g->seg[(int32_t)a[jst]];
gfa_sfa_t *p = &sfa[k++];
assert(jst < j);
p->snid = s->snid, p->soff = s->soff, p->rank = s->rank;
p->end[0] = find_join(g, (uint32_t)a[jst]<<1|1);
if (p->end[0] != (uint64_t)-1) p->end[0] ^= 1;
p->end[1] = find_join(g, (uint32_t)a[j-1]<<1);
for (l = jst, p->len = 0; l < j; ++l)
p->len += g->seg[(int32_t)a[l]].len;
if (write_seq) {
GFA_MALLOC(p->seq, p->len + 1);
for (l = jst, p->len = 0; l < j; ++l) {
s = &g->seg[(int32_t)a[l]];
memcpy(&p->seq[p->len], s->seq, s->len);
p->len += s->len;
}
p->seq[p->len] = 0;
}
jst = j;
}
}
}
assert(k == n_sfa);
end_check:
free(soff);
free(a);
return sfa;
}
/*
* rGFA: extract overlapping segments given a reference coordinate
*/
const char *gfa_parse_reg(const char *s, int32_t *beg, int32_t *end)
{
int32_t i, k, l, name_end;
*beg = *end = -1;
name_end = l = strlen(s);
// determine the sequence name
for (i = l - 1; i >= 0; --i) if (s[i] == ':') break; // look for colon from the end
if (i >= 0) name_end = i;
if (name_end < l) { // check if this is really the end
int n_hyphen = 0;
for (i = name_end + 1; i < l; ++i) {
if (s[i] == '-') ++n_hyphen;
else if (!isdigit(s[i]) && s[i] != ',') break;
}
if (i < l || n_hyphen > 1) name_end = l; // malformated region string; then take str as the name
}
// parse the interval
if (name_end < l) {
char *tmp, *tmp0;
tmp0 = tmp = (char*)malloc(l - name_end + 1);
for (i = name_end + 1, k = 0; i < l; ++i)
if (s[i] != ',') tmp[k++] = s[i];
tmp[k] = 0;
if ((*beg = strtol(tmp, &tmp, 10) - 1) < 0) *beg = 0;
*end = *tmp? strtol(tmp + 1, &tmp, 10) : 1<<29;
if (*beg > *end) name_end = l;
free(tmp0);
}
if (name_end == l) *beg = 0, *end = 1<<29;
return s + name_end;
}
static int32_t *gfa_append_list(int32_t *a, uint32_t *n, uint32_t *m, int32_t seg)
{
if (*n == *m) GFA_EXPAND(a, *m);
a[(*n)++] = seg;
return a;
}
int32_t *gfa_query_by_id(const gfa_t *g, int32_t n_bb, const gfa_bubble_t *bb, int32_t snid, int32_t start, int32_t end, int *n_seg_)
{ // TODO: This is an inefficient implementationg. Faster query requires to index the bubble intervals first.
uint32_t n_seg = 0, m_seg = 0;
int32_t i, j, last = 0, bb_st = -1, bb_st_on = -1, bb_en = -1, bb_en_on = -1, bb_last = -1, *seg = 0;
assert(start <= end && start >= 0);
*n_seg_ = 0;
for (i = 0; i < n_bb; ++i) {
const gfa_bubble_t *b = &bb[i];
if (i == 0 || bb[i].snid != bb[i-1].snid) last = 0;
if (b->snid != snid) continue;
assert(b->n_seg > 0);
bb_last = i;
if (last <= start && start < b->ss) {
assert(bb_st < 0);
bb_st = i, bb_st_on = 1;
} else if (b->ss <= start && start < b->se) {
bb_st = i, bb_st_on = 0;
}
if (last < end && end <= b->ss) {
assert(bb_st >= 0);
bb_en = i, bb_en_on = 1;
} else if (b->ss < end && end <= b->se) {
bb_en = i, bb_en_on = 0;
}
last = b->se;
}
if (bb_last < 0) return 0; // snid not found
if (bb_st < 0) { // on the last stem
uint32_t v = bb[bb_last].v[bb[bb_last].n_seg - 1];
const gfa_seg_t *s = &g->seg[v>>1];
assert(s->snid == snid && start >= s->soff);
if (start < s->soff + s->len)
seg = gfa_append_list(seg, &n_seg, &m_seg, v>>1);
} else if (bb_st_on && bb_st == bb_en && bb_en_on) { // on one stem
seg = gfa_append_list(seg, &n_seg, &m_seg, bb[bb_st].v[0]>>1);
} else { // extract bubbles
if (bb_en < 0) bb_en = bb_last;
for (i = bb_st; i <= bb_en; ++i) {
int32_t s = i == bb_st? 0 : 1;
for (j = s; j < bb[i].n_seg; ++j)
seg = gfa_append_list(seg, &n_seg, &m_seg, bb[i].v[j]>>1);
}
}
*n_seg_ = n_seg;
return seg;
}
int32_t *gfa_query_by_reg(const gfa_t *g, int32_t n_bb, const gfa_bubble_t *bb, const char *reg, int *n_seg)
{
int32_t snid, start, end;
const char *p;
char *tmp;
*n_seg = 0;
p = gfa_parse_reg(reg, &start, &end);
if (p == 0) return 0;
tmp = gfa_strndup(reg, p - reg);
snid = gfa_sseq_get(g, tmp);
free(tmp);
if (snid < 0) return 0;
return gfa_query_by_id(g, n_bb, bb, snid, start, end, n_seg);
}
/*
* GFA: extract a subgraph
*/
gfa_t *gfa_subview2(gfa_t *g, int32_t n_seg, const int32_t *seg, int32_t sub_walk)
{
gfa_map64_t *h;
gfa_t *f;
int32_t i, j, absent;
uint32_t k, l;
h = gfa_map64_init();
for (i = j = 0; i < n_seg; ++i) {
if (seg[i] < g->n_seg) {
k = gfa_map64_put(h, seg[i], &absent);
if (absent) kh_val(h, k) = j++;
}
}
GFA_CALLOC(f, 1);
f->n_seg = kh_size(h);
GFA_CALLOC(f->seg, f->n_seg);
for (k = 0; k < kh_end(h); ++k) {
int32_t nv, s, i, j, t;
const gfa_arc_t *av;
if (!kh_exist(h, k)) continue;
s = kh_key(h, k), t = kh_val(h, k);
f->seg[t] = g->seg[s];
for (j = 0; j < 2; ++j) {
uint32_t v = (uint32_t)s<<1 | j;
nv = gfa_arc_n(g, v);
av = gfa_arc_a(g, v);
for (i = 0; i < nv; ++i) {
gfa_arc_t *a;
l = gfa_map64_get(h, av[i].w>>1);
if (l != kh_end(h)) {
if (f->n_arc == f->m_arc) {
f->m_arc += (f->m_arc>>1) + 16;
GFA_REALLOC(f->arc, f->m_arc);
}
a = &f->arc[f->n_arc++];
*a = av[i];
a->v_lv = (uint64_t)t<<33 | (uint64_t)j<<32 | a->v_lv<<32>>32;
a->w = (uint32_t)kh_val(h, l)<<1 | (a->w&1);
}
}
}
}
if (sub_walk) {
for (i = 0; i < g->n_walk; ++i) {
const gfa_walk_t *w = &g->walk[i];
gfa_walk_t *p;
int32_t n_v = 0;
for (j = 0; j < w->n_v; ++j) {
k = gfa_map64_get(h, w->v[j]>>1);
if (k != kh_end(h)) ++n_v;
}
if (n_v == 0) continue;
GFA_GROW0(gfa_walk_t, f->walk, f->n_walk, f->m_walk);
p = &f->walk[f->n_walk++];
p->st = p->en = -1;
p->sample = w->sample;
p->snid = w->snid;
p->hap = w->hap;
p->aux.l_aux = p->aux.m_aux = 0, p->aux.aux = 0;
GFA_MALLOC(p->v, n_v);
for (j = 0; j < w->n_v; ++j) {
k = gfa_map64_get(h, w->v[j]>>1);
if (k != kh_end(h))
p->v[p->n_v++] = (uint32_t)kh_val(h, k)<<1 | (w->v[j]&1);
}
if (w->aux.l_aux > 0) {
int32_t l_rest = w->aux.l_aux;
uint8_t *t, *rest = w->aux.aux;
while ((t = gfa_aux_next(&l_rest, &rest)) != 0) {
int32_t do_copy = 0;
if (t[2] == 'B') { // array type
int32_t ts, n;
uint8_t *q;
ts = gfa_aux_type2size(t[3]);
memcpy(&n, t + 4, 4);
if (n == w->n_v) { // same size as the number of vertices
GFA_GROW(uint8_t, p->aux.aux, p->aux.l_aux + 8 + p->n_v * ts, p->aux.m_aux);
q = p->aux.aux + p->aux.l_aux;
memcpy(q, t, 4); q += 4;
memcpy(q, &p->n_v, 4); q += 4;
for (j = 0; j < w->n_v; ++j) {
if (gfa_map64_get(h, w->v[j]>>1) != kh_end(h)) {
memcpy(q, t + 8 + j * ts, ts);
q += ts;
}
}
p->aux.l_aux += q - p->aux.aux;
} else do_copy = 1;
} else do_copy = 1;
if (do_copy) {
GFA_GROW(uint8_t, p->aux.aux, p->aux.l_aux + (rest - t), p->aux.m_aux);
memcpy(p->aux.aux + p->aux.l_aux, t, rest - t);
p->aux.l_aux += rest - t;
}
}
}
}
}
gfa_map64_destroy(h);
gfa_arc_sort(f);
gfa_arc_index(f);
f->sseq = g->sseq;
f->link_aux = g->link_aux;
return f;
}
gfa_t *gfa_subview(gfa_t *g, int32_t n_seg, const int32_t *seg)
{
return gfa_subview2(g, n_seg, seg, 0);
}
void gfa_subview_destroy(gfa_t *f)
{
int32_t i;
for (i = 0; i < f->n_walk; ++i) {
free(f->walk[i].v);
free(f->walk[i].aux.aux);
}
free(f->walk); free(f->idx); free(f->arc); free(f->seg); free(f);
}
int32_t *gfa_sub_extend(const gfa_t *g, int n_seg, const int32_t *seg, int step, int32_t *n_ret)
{
uint32_t v;
int32_t i, k, *ret;
int8_t *flag, *sflag;
kdq_t(uint64_t) *q;
if (n_seg == 0) return 0;
q = kdq_init(uint64_t, 0);
GFA_CALLOC(flag, g->n_seg * 2);
for (i = 0; i < n_seg; ++i) {
kdq_push(uint64_t, q, ((uint64_t)seg[i]<<1|0)<<32);
kdq_push(uint64_t, q, ((uint64_t)seg[i]<<1|1)<<32);
}
while (kdq_size(q) > 0) {
uint64_t x = *kdq_shift(uint64_t, q);
uint32_t v = x>>32;
int r = (int32_t)x;
if (flag[v]) continue; // already visited
flag[v] = 1;
if (r < step) {
uint32_t nv = gfa_arc_n(g, v);
gfa_arc_t *av = gfa_arc_a(g, v);
for (i = 0; i < nv; ++i) {
if (flag[av[i].w] == 0)
kdq_push(uint64_t, q, (uint64_t)av[i].w<<32 | (r + 1));
if (flag[av[i].w^1] == 0)
kdq_push(uint64_t, q, (uint64_t)(av[i].w^1)<<32 | (r + 1));
}
}
}
kdq_destroy(uint64_t, q);
GFA_CALLOC(sflag, g->n_seg);
for (v = 0; v < gfa_n_vtx(g); ++v)
if (flag[v]) sflag[v>>1] = 1;
free(flag);
for (i = 0, k = 0; i < g->n_seg; ++i)
if (sflag[i]) ++k;
GFA_CALLOC(ret, k);
for (i = 0, k = 0; i < g->n_seg; ++i)
if (sflag[i]) ret[k++] = i;
free(sflag);
*n_ret = k;
return ret;
}
int32_t *gfa_list2seg(const gfa_t *g, int32_t n_seg, char *const* seg, int32_t *n_ret)
{
int32_t i, k, *ret;
GFA_MALLOC(ret, n_seg);
for (i = k = 0; i < n_seg; ++i) {
int32_t s;
s = gfa_name2id(g, seg[i]);
if (s >= 0) ret[k++] = s;
}
*n_ret = k;
return ret;
}
void gfa_walk_flip(gfa_t *g, const char *flip_name)
{
int32_t i, j, flip_sid = -1;
int8_t *strand;
if (g->n_walk == 0) return;
if (flip_name) { // NB: g may be a view. In this case, we can't use gfa_name2id()
for (i = 0; i < g->n_seg; ++i)
if (strcmp(flip_name, g->seg[i].name) == 0)
flip_sid = i;
}
GFA_CALLOC(strand, g->n_seg);
for (i = 0; i < g->n_walk; ++i) { // prefer the strand on the first occurrence
gfa_walk_t *w = &g->walk[i];
for (j = 0; j < w->n_v; ++j)
if (strand[w->v[j]>>1] == 0)
strand[w->v[j]>>1] = w->v[j]&1? -1 : 1;
}
if (flip_sid >= 0 && flip_sid < g->n_seg && strand[flip_sid] < 0)
for (i = 0; i < g->n_seg; ++i)
strand[i] *= -1;
for (i = 0; i < g->n_walk; ++i) {
gfa_walk_t *w = &g->walk[i];
int32_t n[2], m[2], to_flip = -1;
n[0] = n[1] = m[0] = m[1] = 0;
for (j = 0; j < w->n_v; ++j) {
int8_t s;
assert(strand[w->v[j]>>1] != 0);
s = w->v[j]&1? -1 : 1;
if (s == strand[w->v[j]>>1]) ++n[0]; // count how many consistent/inconsistent with the preferred strand
else ++n[1];
if (flip_sid >= 0 && w->v[j]>>1 == flip_sid) { // count the strand of the target segment
if ((w->v[j]&1) == 0) ++m[0];
else ++m[1];
}
}
// determine the orientation (i.e. whether to flip)
if (flip_sid >= 0) {
if (m[0] > m[1]) to_flip = 0;
else if (m[0] < m[1]) to_flip = 1;
}
if (to_flip < 0)
to_flip = (n[0] < n[1]);
//if (m[0] + m[1] > 0) fprintf(stderr, "%d\t%d\t%d\t%d\t%d\n", m[0], m[1], n[0], n[1], to_flip);
if (to_flip == 0) continue;
// flip walks
for (j = 0; j < w->n_v>>1; ++j) {
uint32_t t = w->v[j]^1;
w->v[j] = w->v[w->n_v - 1 - j]^1;
w->v[w->n_v - 1 - j] = t;
}
if (w->n_v&1) w->v[w->n_v>>1] ^= 1;
if (w->aux.l_aux > 0) { // reverse array tags
int32_t l_rest = w->aux.l_aux;
uint8_t *t, *rest = w->aux.aux;
while ((t = gfa_aux_next(&l_rest, &rest)) != 0) {
if (t[2] == 'B') {
int32_t ts, n;
ts = gfa_aux_type2size(t[3]);
memcpy(&n, t + 4, 4);
if (n == w->n_v) { // same size as the number of vertices
uint8_t buf[8];
for (j = 0; j < w->n_v>>1; ++j) {
memcpy(buf, t + 8 + j * ts, ts);
memcpy(t + 8 + j * ts, t + 8 + (w->n_v - 1 - j) * ts, ts);
memcpy(t + 8 + (w->n_v - 1 - j) * ts, buf, ts);
}
}
}
}
}
}
free(strand);
}