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gfa-ed.c
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gfa-ed.c
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#include <assert.h>
#include <string.h>
#include <stdio.h>
#include "gfa-priv.h"
#include "kalloc.h"
#include "ksort.h"
#include "khashl.h" // make it compatible with kalloc
#include "kdq.h"
#include "kvec-km.h"
int gfa_ed_dbg = 0;
/***************
* Preparation *
***************/
void gfa_edopt_init(gfa_edopt_t *opt)
{
memset(opt, 0, sizeof(gfa_edopt_t));
opt->bw_dyn = opt->max_lag = opt->s_term = -1;
opt->max_chk = 1000;
}
gfa_edseq_t *gfa_edseq_init(const gfa_t *g)
{
uint32_t i, n_vtx = gfa_n_vtx(g);
gfa_edseq_t *es;
GFA_MALLOC(es, n_vtx);
for (i = 0; i < g->n_seg; ++i) {
const gfa_seg_t *s = &g->seg[i];
char *t;
int32_t j;
GFA_MALLOC(t, s->len + 1);
for (j = 0; j < s->len; ++j)
t[s->len - j - 1] = gfa_comp_table[(uint8_t)s->seq[j]];
t[s->len] = 0;
es[i<<1].seq = (char*)s->seq;
es[i<<1|1].seq = t;
es[i<<1].len = es[i<<1|1].len = s->len;
}
return es;
}
void gfa_edseq_destroy(int32_t n_seg, gfa_edseq_t *es)
{
int32_t i;
for (i = 0; i < n_seg; ++i)
free((char*)es[i<<1|1].seq);
free(es);
}
/*****************
* Edit distance *
*****************/
#define GWF_DIAG_SHIFT 0x40000000
static inline uint64_t gwf_gen_vd(uint32_t v, int32_t d)
{
return (uint64_t)v<<32 | (GWF_DIAG_SHIFT + d);
}
/*
* Diagonal interval
*/
typedef struct {
uint64_t vd0, vd1;
} gwf_intv_t;
typedef kvec_t(gwf_intv_t) gwf_intv_v;
#define intvd_key(x) ((x).vd0)
KRADIX_SORT_INIT(gwf_intv, gwf_intv_t, intvd_key, 8)
static int gwf_intv_is_sorted(int32_t n_a, const gwf_intv_t *a)
{
int32_t i;
for (i = 1; i < n_a; ++i)
if (a[i-1].vd0 > a[i].vd0) break;
return (i == n_a);
}
// merge overlapping intervals; input must be sorted
static size_t gwf_intv_merge_adj(size_t n, gwf_intv_t *a)
{
size_t i, k;
uint64_t st, en;
if (n == 0) return 0;
st = a[0].vd0, en = a[0].vd1;
for (i = 1, k = 0; i < n; ++i) {
if (a[i].vd0 > en) {
a[k].vd0 = st, a[k++].vd1 = en;
st = a[i].vd0, en = a[i].vd1;
} else en = en > a[i].vd1? en : a[i].vd1;
}
a[k].vd0 = st, a[k++].vd1 = en;
return k;
}
// merge two sorted interval lists
static size_t gwf_intv_merge2(gwf_intv_t *a, size_t n_b, const gwf_intv_t *b, size_t n_c, const gwf_intv_t *c)
{
size_t i = 0, j = 0, k = 0;
while (i < n_b && j < n_c) {
if (b[i].vd0 <= c[j].vd0)
a[k++] = b[i++];
else a[k++] = c[j++];
}
while (i < n_b) a[k++] = b[i++];
while (j < n_c) a[k++] = c[j++];
return gwf_intv_merge_adj(k, a);
}
/*
* Diagonal
*/
typedef struct { // a diagonal
uint64_t vd; // higher 32 bits: vertex ID; lower 32 bits: diagonal+0x4000000
int32_t k;
int32_t len;
uint32_t xo; // higher 31 bits: anti diagonal; lower 1 bit: out-of-order or not
int32_t t;
} gwf_diag_t;
typedef kvec_t(gwf_diag_t) gwf_diag_v;
#define ed_key(x) ((x).vd)
KRADIX_SORT_INIT(gwf_ed, gwf_diag_t, ed_key, 8)
KDQ_INIT(gwf_diag_t)
// push (v,d,k) to the end of the queue
static inline void gwf_diag_push(void *km, gwf_diag_v *a, uint32_t v, int32_t d, int32_t k, uint32_t x, uint32_t ooo, int32_t t)
{
gwf_diag_t *p;
kv_pushp(gwf_diag_t, km, *a, &p);
p->vd = gwf_gen_vd(v, d), p->k = k, p->xo = x<<1|ooo, p->t = t;
}
// determine the wavefront on diagonal (v,d)
static inline int32_t gwf_diag_update(gwf_diag_t *p, uint32_t v, int32_t d, int32_t k, uint32_t x, uint32_t ooo, int32_t t)
{
uint64_t vd = gwf_gen_vd(v, d);
if (p->vd == vd) {
p->xo = p->k > k? p->xo : x<<1|ooo;
p->t = p->k > k? p->t : t;
p->k = p->k > k? p->k : k;
return 0;
}
return 1;
}
static int gwf_diag_is_sorted(int32_t n_a, const gwf_diag_t *a)
{
int32_t i;
for (i = 1; i < n_a; ++i)
if (a[i-1].vd > a[i].vd) break;
return (i == n_a);
}
// sort a[]. This uses the gwf_diag_t::ooo field to speed up sorting.
static void gwf_diag_sort(int32_t n_a, gwf_diag_t *a, void *km, gwf_diag_v *ooo)
{
int32_t i, j, k, n_b, n_c;
gwf_diag_t *b, *c;
kv_resize(gwf_diag_t, km, *ooo, n_a);
for (i = 0, n_c = 0; i < n_a; ++i)
if (a[i].xo&1) ++n_c;
n_b = n_a - n_c;
b = ooo->a, c = b + n_b;
for (i = j = k = 0; i < n_a; ++i) {
if (a[i].xo&1) c[k++] = a[i];
else b[j++] = a[i];
}
radix_sort_gwf_ed(c, c + n_c);
for (k = 0; k < n_c; ++k) c[k].xo &= 0xfffffffeU;
i = j = k = 0;
while (i < n_b && j < n_c) {
if (b[i].vd <= c[j].vd)
a[k++] = b[i++];
else a[k++] = c[j++];
}
while (i < n_b) a[k++] = b[i++];
while (j < n_c) a[k++] = c[j++];
}
// remove diagonals not on the wavefront
static int32_t gwf_diag_dedup(int32_t n_a, gwf_diag_t *a, void *km, gwf_diag_v *ooo)
{
int32_t i, n, st;
if (!gwf_diag_is_sorted(n_a, a))
gwf_diag_sort(n_a, a, km, ooo);
for (i = 1, st = 0, n = 0; i <= n_a; ++i) {
if (i == n_a || a[i].vd != a[st].vd) {
int32_t j, max_j = st;
if (st + 1 < i)
for (j = st + 1; j < i; ++j) // choose the far end (i.e. the wavefront)
if (a[max_j].k < a[j].k) max_j = j;
a[n++] = a[max_j];
st = i;
}
}
return n;
}
// use forbidden bands to remove diagonals not on the wavefront
static int32_t gwf_mixed_dedup(int32_t n_a, gwf_diag_t *a, int32_t n_b, gwf_intv_t *b)
{
int32_t i = 0, j = 0, k = 0;
while (i < n_a && j < n_b) {
if (a[i].vd >= b[j].vd0 && a[i].vd < b[j].vd1) ++i;
else if (a[i].vd >= b[j].vd1) ++j;
else a[k++] = a[i++];
}
while (i < n_a) a[k++] = a[i++];
return k;
}
/*
* Traceback stack
*/
KHASHL_MAP_INIT(KH_LOCAL, gwf_map64_t, gwf_map64, uint64_t, int32_t, kh_hash_uint64, kh_eq_generic)
typedef struct {
int32_t v;
int32_t pre;
} gwf_trace_t;
typedef kvec_t(gwf_trace_t) gwf_trace_v;
static int32_t gwf_trace_push(void *km, gwf_trace_v *a, int32_t v, int32_t pre, gwf_map64_t *h)
{
uint64_t key = (uint64_t)v << 32 | (uint32_t)pre;
khint_t k;
int absent;
k = gwf_map64_put(h, key, &absent);
if (absent) {
gwf_trace_t *p;
kv_pushp(gwf_trace_t, km, *a, &p);
p->v = v, p->pre = pre;
kh_val(h, k) = a->n - 1;
return a->n - 1;
}
return kh_val(h, k);
}
/*
* Core GWFA routine
*/
KHASHL_INIT(KH_LOCAL, gwf_set64_t, gwf_set64, uint64_t, kh_hash_dummy, kh_eq_generic)
typedef struct {
void *km;
gwf_set64_t *ha; // hash table for adjacency
gwf_map64_t *ht; // hash table for traceback
gwf_intv_v intv;
gwf_intv_v tmp, swap;
gwf_diag_v ooo;
gwf_trace_v t;
} gwf_edbuf_t;
// remove diagonals not on the wavefront
static int32_t gwf_dedup(gwf_edbuf_t *buf, int32_t n_a, gwf_diag_t *a)
{
if (buf->intv.n + buf->tmp.n > 0) {
if (!gwf_intv_is_sorted(buf->tmp.n, buf->tmp.a))
radix_sort_gwf_intv(buf->tmp.a, buf->tmp.a + buf->tmp.n);
kv_copy(gwf_intv_t, buf->km, buf->swap, buf->intv);
kv_resize(gwf_intv_t, buf->km, buf->intv, buf->intv.n + buf->tmp.n);
buf->intv.n = gwf_intv_merge2(buf->intv.a, buf->swap.n, buf->swap.a, buf->tmp.n, buf->tmp.a);
}
n_a = gwf_diag_dedup(n_a, a, buf->km, &buf->ooo);
if (buf->intv.n > 0)
n_a = gwf_mixed_dedup(n_a, a, buf->intv.n, buf->intv.a);
return n_a;
}
// remove diagonals that lag far behind the furthest wavefront
static int32_t gwf_prune(int32_t n_a, gwf_diag_t *a, uint32_t max_lag, int32_t bw_dyn)
{
int32_t i, j, iq, dq, max_i = -1;
uint32_t max_x = 0;
gwf_diag_t *q;
for (i = 0; i < n_a; ++i)
if (a[i].xo>>1 > max_x)
max_x = a[i].xo>>1, max_i = i;
q = &a[max_i];
iq = (int32_t)q->vd - GWF_DIAG_SHIFT + q->k;
dq = (int32_t)(q->xo>>1) - iq - iq;
for (i = j = 0; i < n_a; ++i) {
gwf_diag_t *p = &a[i];
int32_t ip = (int32_t)p->vd - GWF_DIAG_SHIFT + p->k;
int32_t dp = (int32_t)(p->xo>>1) - ip - ip;
int32_t w = dp > dq? dp - dq : dq - dp;
if (bw_dyn >= 0 && w > bw_dyn) continue;
if ((p->xo>>1) + max_lag < max_x) continue;
a[j++] = *p;
}
return j;
}
// reach the wavefront
static inline int32_t gwf_extend1(int32_t d, int32_t k, int32_t vl, const char *ts, int32_t ql, const char *qs)
{
int32_t max_k = (ql - d < vl? ql - d : vl) - 1;
const char *ts_ = ts + 1, *qs_ = qs + d + 1;
#if 0
// int32_t i = k + d; while (k + 1 < vl && i + 1 < ql && ts[k+1] == q[i+1]) ++k, ++i;
while (k < max_k && *(ts_ + k) == *(qs_ + k))
++k;
#else
uint64_t cmp = 0;
while (k + 7 < max_k) {
uint64_t x = *(uint64_t*)(ts_ + k); // warning: unaligned memory access
uint64_t y = *(uint64_t*)(qs_ + k);
cmp = x ^ y;
if (cmp == 0) k += 8;
else break;
}
if (cmp)
k += __builtin_ctzl(cmp) >> 3; // on x86, this is done via the BSR instruction: https://www.felixcloutier.com/x86/bsr
else if (k + 7 >= max_k)
while (k < max_k && *(ts_ + k) == *(qs_ + k)) // use this for generic CPUs. It is slightly faster than the unoptimized version
++k;
#endif
return k;
}
// This is essentially Landau-Vishkin for linear sequences. The function speeds up alignment to long vertices. Not really necessary.
static void gwf_ed_extend_batch(void *km, const gfa_t *g, const gfa_edseq_t *es, int32_t ql, const char *q, int32_t n, gwf_diag_t *a, gwf_diag_v *B,
kdq_t(gwf_diag_t) *A, gwf_intv_v *tmp_intv, gfa_edrst_t *r)
{
int32_t j, m;
int32_t v = a->vd>>32;
int32_t vl = es[v].len;
const char *ts = es[v].seq;
gwf_diag_t *b;
// wfa_extend
for (j = 0; j < n; ++j) {
int32_t k;
k = gwf_extend1((int32_t)a[j].vd - GWF_DIAG_SHIFT, a[j].k, vl, ts, ql, q);
a[j].len = k - a[j].k;
a[j].xo += a[j].len << 2;
a[j].k = k;
}
// wfa_next
kv_resize(gwf_diag_t, km, *B, B->n + n + 2);
b = &B->a[B->n];
b[0].vd = a[0].vd - 1;
b[0].xo = a[0].xo + 2; // 2 == 1<<1
b[0].k = a[0].k + 1;
b[0].t = a[0].t;
b[1].vd = a[0].vd;
b[1].xo = n == 1 || a[0].k > a[1].k? a[0].xo + 4 : a[1].xo + 2;
b[1].t = n == 1 || a[0].k > a[1].k? a[0].t : a[1].t;
b[1].k = (n == 1 || a[0].k > a[1].k? a[0].k : a[1].k) + 1;
for (j = 1; j < n - 1; ++j) {
uint32_t x = a[j-1].xo + 2;
int32_t k = a[j-1].k, t = a[j-1].t;
x = k > a[j].k + 1? x : a[j].xo + 4;
t = k > a[j].k + 1? t : a[j].t;
k = k > a[j].k + 1? k : a[j].k + 1;
x = k > a[j+1].k + 1? x : a[j+1].xo + 2;
t = k > a[j+1].k + 1? t : a[j+1].t;
k = k > a[j+1].k + 1? k : a[j+1].k + 1;
b[j+1].vd = a[j].vd, b[j+1].k = k, b[j+1].xo = x, b[j+1].t = t;
}
if (n >= 2) {
b[n].vd = a[n-1].vd;
b[n].xo = a[n-2].k > a[n-1].k + 1? a[n-2].xo + 2 : a[n-1].xo + 4;
b[n].t = a[n-2].k > a[n-1].k + 1? a[n-2].t : a[n-1].t;
b[n].k = a[n-2].k > a[n-1].k + 1? a[n-2].k : a[n-1].k + 1;
}
b[n+1].vd = a[n-1].vd + 1;
b[n+1].xo = a[n-1].xo + 2;
b[n+1].t = a[n-1].t;
b[n+1].k = a[n-1].k;
// drop out-of-bound cells
//if (a[n-1].k == vl - 1) b[n+1].k = vl; // insertion to the end of a vertex is handled elsewhere. FIXME: this line leads to wrong result for MHC-57 and MHC-HG002.2
for (j = 0; j < n; ++j) {
gwf_diag_t *p = &a[j];
if (p->k == vl - 1 || (int32_t)p->vd - GWF_DIAG_SHIFT + p->k == ql - 1)
p->xo |= 1, *kdq_pushp(gwf_diag_t, A) = *p;
}
for (j = 0, m = 0; j < n + 2; ++j) {
gwf_diag_t *p = &b[j];
int32_t d = (int32_t)p->vd - GWF_DIAG_SHIFT;
if (d + p->k < ql && p->k < vl) {
b[m++] = *p;
} else if (p->k == vl) {
gwf_intv_t *q;
kv_pushp(gwf_intv_t, km, *tmp_intv, &q);
q->vd0 = gwf_gen_vd(v, d), q->vd1 = q->vd0 + 1;
}
}
B->n += m;
}
// wfa_extend and wfa_next combined
static gwf_diag_t *gwf_ed_extend(gwf_edbuf_t *buf, const gfa_edopt_t *opt, const gfa_t *g, const gfa_edseq_t *es, int32_t s, int32_t ql, const char *q,
uint32_t v1, int32_t off1, int32_t *end_tb, int32_t *n_a_, gwf_diag_t *a, gfa_edrst_t *r)
{
int32_t i, x, n = *n_a_, do_dedup = 1;
kdq_t(gwf_diag_t) *A;
gwf_diag_v B = {0,0,0};
gwf_diag_t *b;
r->end_v = (uint32_t)-1;
r->end_off = *end_tb = -1;
buf->tmp.n = 0;
gwf_set64_clear(buf->ha); // hash table $h to avoid visiting a vertex twice
for (i = 0, x = 1; i < 32; ++i, x <<= 1)
if (x >= n) break;
if (i < 4) i = 4;
A = kdq_init2(gwf_diag_t, buf->km, i); // $A is a queue
kv_resize(gwf_diag_t, buf->km, B, n * 2);
#if 0 // unoptimized version without calling gwf_ed_extend_batch() at all. The final result will be the same.
A->count = n;
memcpy(A->a, a, n * sizeof(*a));
#else // optimized for long vertices.
for (x = 0, i = 1; i <= n; ++i) {
if (i == n || a[i].vd != a[i-1].vd + 1) {
gwf_ed_extend_batch(buf->km, g, es, ql, q, i - x, &a[x], &B, A, &buf->tmp, r);
x = i;
}
}
if (kdq_size(A) == 0) do_dedup = 0;
#endif
kfree(buf->km, a); // $a is not used as it has been copied to $A
while (kdq_size(A)) {
gwf_diag_t t;
uint32_t v, x0;
int32_t ooo, d, k, i, vl;
t = *kdq_shift(gwf_diag_t, A);
ooo = t.xo&1, v = t.vd >> 32; // vertex
d = (int32_t)t.vd - GWF_DIAG_SHIFT; // diagonal
k = t.k; // wavefront position on the vertex
vl = es[v].len; // $vl is the vertex length
k = gwf_extend1(d, k, vl, es[v].seq, ql, q);
i = k + d; // query position
x0 = (t.xo >> 1) + ((k - t.k) << 1); // current anti diagonal
if (k + 1 < vl && i + 1 < ql) { // the most common case: the wavefront is in the middle
int32_t push1 = 1, push2 = 1;
if (B.n >= 2) push1 = gwf_diag_update(&B.a[B.n - 2], v, d-1, k+1, x0 + 1, ooo, t.t);
if (B.n >= 1) push2 = gwf_diag_update(&B.a[B.n - 1], v, d, k+1, x0 + 2, ooo, t.t);
if (push1) gwf_diag_push(buf->km, &B, v, d-1, k+1, x0 + 1, 1, t.t);
if (push2 || push1) gwf_diag_push(buf->km, &B, v, d, k+1, x0 + 2, 1, t.t);
gwf_diag_push(buf->km, &B, v, d+1, k, x0 + 1, ooo, t.t);
} else if (i + 1 < ql) { // k + 1 == g->len[v]; reaching the end of the vertex but not the end of query
int32_t nv = gfa_arc_n(g, v), j, n_ext = 0, tw = -1;
gfa_arc_t *av = gfa_arc_a(g, v);
gwf_intv_t *p;
kv_pushp(gwf_intv_t, buf->km, buf->tmp, &p);
p->vd0 = gwf_gen_vd(v, d), p->vd1 = p->vd0 + 1;
if (opt->traceback) tw = gwf_trace_push(buf->km, &buf->t, v, t.t, buf->ht);
for (j = 0; j < nv; ++j) { // traverse $v's neighbors
uint32_t w = av[j].w; // $w is next to $v
int32_t ol = av[j].ow;
int absent;
gwf_set64_put(buf->ha, (uint64_t)w<<32 | (i + 1), &absent); // test if ($w,$i) has been visited
if (q[i + 1] == es[w].seq[ol]) { // can be extended to the next vertex without a mismatch
++n_ext;
if (absent) {
gwf_diag_t *p;
p = kdq_pushp(gwf_diag_t, A);
p->vd = gwf_gen_vd(w, i + 1 - ol), p->k = ol, p->xo = (x0+2)<<1 | 1, p->t = tw;
}
} else if (absent) {
gwf_diag_push(buf->km, &B, w, i - ol, ol, x0 + 1, 1, tw);
gwf_diag_push(buf->km, &B, w, i + 1 - ol, ol, x0 + 2, 1, tw);
}
}
if (nv == 0 || n_ext != nv) // add an insertion to the target; this *might* cause a duplicate in corner cases
gwf_diag_push(buf->km, &B, v, d+1, k, x0 + 1, 1, t.t);
} else if (v1 == (uint32_t)-1 || (v == v1 && k == off1)) { // i + 1 == ql
r->end_v = v, r->end_off = k, r->wlen = x0 - i - 1, *end_tb = t.t, *n_a_ = 0;
kdq_destroy(gwf_diag_t, A);
kfree(buf->km, B.a);
return 0;
} else if (k + 1 < vl) { // i + 1 == ql; reaching the end of the query but not the end of the vertex
gwf_diag_push(buf->km, &B, v, d-1, k+1, x0 + 1, ooo, t.t); // add an deletion; this *might* case a duplicate in corner cases
} else if (v != v1) { // i + 1 == ql && k + 1 == g->len[v]; not reaching the last vertex $v1
int32_t nv = gfa_arc_n(g, v), j, tw = -1;
const gfa_arc_t *av = gfa_arc_a(g, v);
if (opt->traceback) tw = gwf_trace_push(buf->km, &buf->t, v, t.t, buf->ht);
for (j = 0; j < nv; ++j)
gwf_diag_push(buf->km, &B, av[j].w, i - av[j].ow, av[j].ow, x0 + 1, 1, tw); // deleting the first base on the next vertex
} else { // may come here when k>off1 (due to banding); do nothing in this case
}
}
kdq_destroy(gwf_diag_t, A);
*n_a_ = n = B.n, b = B.a;
if (do_dedup) *n_a_ = n = gwf_dedup(buf, n, b);
if (opt->max_lag > 0 && n > opt->max_chk && ((s+1)&0xf) == 0)
*n_a_ = n = gwf_prune(n, b, opt->max_lag, opt->bw_dyn);
return b;
}
static void gwf_traceback(gwf_edbuf_t *buf, int32_t end_v, int32_t end_tb, gfa_edrst_t *path)
{
int32_t i = end_tb, n = 1;
while (i >= 0 && buf->t.a[i].v >= 0)
++n, i = buf->t.a[i].pre;
KMALLOC(buf->km, path->v, n);
i = end_tb, n = 0;
path->v[n++] = end_v;
while (i >= 0 && buf->t.a[i].v >= 0)
path->v[n++] = buf->t.a[i].v, i = buf->t.a[i].pre;
path->nv = n;
for (i = 0; i < path->nv>>1; ++i)
n = path->v[i], path->v[i] = path->v[path->nv - 1 - i], path->v[path->nv - 1 - i] = n;
}
static void gwf_ed_print_diag(const gfa_t *g, size_t n, gwf_diag_t *a) // for debugging only
{
size_t i;
for (i = 0; i < n; ++i) {
int32_t d = (int32_t)a[i].vd - GWF_DIAG_SHIFT;
printf("Z\t%d\t%s\t%d\t%d\t%d\n", d + a[i].k, g->seg[(a[i].vd>>32)>>1].name, d, a[i].k, a[i].xo>>1);
}
}
static void gwf_ed_print_intv(size_t n, gwf_intv_t *a) // for debugging only
{
size_t i;
for (i = 0; i < n; ++i)
printf("Z\t%d\t%d\t%d\n", (int32_t)(a[i].vd0>>32), (int32_t)a[i].vd0 - GWF_DIAG_SHIFT, (int32_t)a[i].vd1 - GWF_DIAG_SHIFT);
}
typedef struct {
const gfa_t *g;
const gfa_edseq_t *es;
const gfa_edopt_t *opt;
int32_t ql;
const char *q;
gwf_edbuf_t buf;
int32_t s, n_a;
gwf_diag_t *a;
int32_t end_tb;
} gfa_edbuf_t;
void *gfa_ed_init(void *km, const gfa_edopt_t *opt, const gfa_t *g, const gfa_edseq_t *es, int32_t ql, const char *q, uint32_t v0, int32_t off0)
{
gfa_edbuf_t *z;
KCALLOC(km, z, 1);
z->buf.km = km;
z->opt = opt;
z->g = g, z->es = es;
z->ql = ql, z->q = q;
z->buf.ha = gwf_set64_init2(km);
z->buf.ht = gwf_map64_init2(km);
kv_resize(gwf_trace_t, km, z->buf.t, 16);
KCALLOC(km, z->a, 1);
z->a[0].vd = gwf_gen_vd(v0, -off0), z->a[0].k = off0 - 1, z->a[0].xo = 0;
if (z->opt->traceback) z->a[0].t = gwf_trace_push(km, &z->buf.t, -1, -1, z->buf.ht);
z->n_a = 1;
return z;
}
void gfa_ed_step(void *z_, uint32_t v1, int32_t off1, int32_t s_term, gfa_edrst_t *r)
{
gfa_edbuf_t *z = (gfa_edbuf_t*)z_;
const gfa_edopt_t *opt = z->opt;
if (s_term < 0 && z->opt->s_term >= 0) s_term = z->opt->s_term;
r->n_end = 0, r->n_iter = 0;
while (z->n_a > 0) {
z->a = gwf_ed_extend(&z->buf, opt, z->g, z->es, z->s, z->ql, z->q, v1, off1, &z->end_tb, &z->n_a, z->a, r);
r->n_iter += z->n_a + z->buf.intv.n;
if (r->end_off >= 0 || z->n_a == 0) break;
if (r->n_end > 0) break;
if (s_term >= 0 && z->s >= s_term) break;
++z->s;
if (gfa_ed_dbg >= 1) {
printf("[%s] dist=%d, n=%d, n_intv=%ld, n_tb=%ld\n", __func__, z->s, z->n_a, z->buf.intv.n, z->buf.t.n);
if (gfa_ed_dbg == 2) gwf_ed_print_diag(z->g, z->n_a, z->a);
if (gfa_ed_dbg == 3) gwf_ed_print_intv(z->buf.intv.n, z->buf.intv.a);
}
}
if (opt->traceback && r->end_off >= 0)
gwf_traceback(&z->buf, r->end_v, z->end_tb, r);
r->s = r->end_v != (uint32_t)-1? z->s : -1;
}
void gfa_ed_destroy(void *z_)
{
gfa_edbuf_t *z = (gfa_edbuf_t*)z_;
void *km = z->buf.km;
kfree(km, z->a);
gwf_set64_destroy(z->buf.ha);
gwf_map64_destroy(z->buf.ht);
kfree(km, z->buf.ooo.a);
kfree(km, z->buf.intv.a);
kfree(km, z->buf.tmp.a);
kfree(km, z->buf.swap.a);
kfree(km, z->buf.t.a);
kfree(km, z);
}
int32_t gfa_edit_dist(void *km, const gfa_edopt_t *opt, const gfa_t *g, const gfa_edseq_t *es, int32_t ql, const char *q, uint32_t v0, int32_t off0, gfa_edrst_t *rst)
{
void *z;
z = gfa_ed_init(km, opt, g, es, ql, q, v0, off0);
gfa_ed_step(z, (uint32_t)-1, -1, -1, rst);
gfa_ed_destroy(z);
return rst->s;
}