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shortk.c
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shortk.c
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#include "mgpriv.h"
#include "ksort.h"
#include "kavl.h"
#include "algo.h"
#include "khashl.h"
typedef struct sp_node_s {
uint64_t di; // dist<<32 | unique_id
uint32_t v;
int32_t pre;
uint32_t hash;
int32_t is_0;
KAVL_HEAD(struct sp_node_s) head;
} sp_node_t, *sp_node_p;
#define sp_node_cmp(a, b) (((a)->di > (b)->di) - ((a)->di < (b)->di))
KAVL_INIT(sp, sp_node_t, head, sp_node_cmp)
#define sp_node_lt(a, b) ((a)->di < (b)->di)
KSORT_INIT(sp, sp_node_p, sp_node_lt)
typedef struct {
int32_t k;
int32_t qs, qe;
sp_node_t *p[MG_MAX_SHORT_K]; // this forms a max-heap
} sp_topk_t;
KHASHL_MAP_INIT(KH_LOCAL, kh_sp_t, sp, uint32_t, sp_topk_t, kh_hash_uint32, kh_eq_generic)
KHASHL_MAP_INIT(KH_LOCAL, kh_sp2_t, sp2, uint32_t, uint64_t, kh_hash_uint32, kh_eq_generic)
#define MG_SHORT_K_EXT 1000
static inline sp_node_t *gen_sp_node(void *km, const gfa_t *g, uint32_t v, int32_t d, int32_t id)
{
sp_node_t *p;
KMALLOC(km, p, 1);
p->v = v, p->di = (uint64_t)d<<32 | id, p->pre = -1, p->is_0 = 1;
return p;
}
mg_pathv_t *mg_shortest_k(void *km0, const gfa_t *g, uint32_t src, int32_t n_dst, mg_path_dst_t *dst, int32_t max_dist, int32_t max_k, int32_t *n_pathv)
{
sp_node_t *p, *root = 0, **out;
sp_topk_t *q;
kh_sp_t *h;
kh_sp2_t *h2;
void *km;
khint_t k;
int absent;
int32_t i, j, n_done, n_found;
uint32_t id, n_out, m_out;
int8_t *dst_done;
mg_pathv_t *ret = 0;
uint64_t *dst_group, *seeds = 0;
void *h_seeds = 0;
mg128_v mini = {0,0,0};
if (n_pathv) *n_pathv = 0;
if (n_dst <= 0) return 0;
for (i = 0; i < n_dst; ++i) { // initialize
mg_path_dst_t *t = &dst[i];
if (t->inner)
t->dist = 0, t->n_path = 1, t->path_end = -1;
else
t->dist = -1, t->n_path = 0, t->path_end = -1;
}
if (max_k > MG_MAX_SHORT_K) max_k = MG_MAX_SHORT_K;
km = (mg_dbg_flag&MG_DBG_NO_KALLOC) && (mg_dbg_flag&MG_DBG_SHORTK)? 0 : km_init2(km0, 0x4000);
KCALLOC(km, dst_done, n_dst);
KMALLOC(km, dst_group, n_dst);
for (i = 0; i < n_dst; ++i) // multiple dst[] may have the same dst[].v. We need to group them first.
dst_group[i] = (uint64_t)dst[i].v<<32 | i;
radix_sort_gfa64(dst_group, dst_group + n_dst);
h2 = sp2_init2(km); // this hash table keeps all destinations
sp2_resize(h2, n_dst * 2);
for (i = 1, j = 0; i <= n_dst; ++i) {
if (i == n_dst || dst_group[i]>>32 != dst_group[j]>>32) {
k = sp2_put(h2, dst_group[j]>>32, &absent);
kh_val(h2, k) = (uint64_t)j << 32 | (i - j);
assert(absent);
j = i;
}
}
h = sp_init2(km); // this hash table keeps visited vertices
sp_resize(h, 16);
m_out = 16, n_out = 0;
KMALLOC(km, out, m_out);
id = 0;
p = gen_sp_node(km, g, src, 0, id++);
p->hash = kh_hash_uint32(src);
kavl_insert(sp, &root, p, 0);
k = sp_put(h, src, &absent);
q = &kh_val(h, k);
q->k = 1, q->p[0] = p, q->qs = q->qe = -1;
n_done = 0;
while (kavl_size(head, root) > 0) {
int32_t i, nv;
gfa_arc_t *av;
sp_node_t *r;
r = kavl_erase_first(sp, &root); // take out the closest vertex in the heap (as a binary tree)
//fprintf(stderr, "XX\t%d\t%d\t%d\t%c%s[%d]\t%d\n", n_out, kavl_size(head, root), n_finished, "><"[(r->v&1)^1], g->seg[r->v>>1].name, r->v, (int32_t)(r->di>>32));
if (n_out == m_out) KEXPAND(km, out, m_out);
r->di = r->di>>32<<32 | n_out; // lower 32 bits now for position in the out[] array
out[n_out++] = r;
k = sp2_get(h2, r->v);
if (k != kh_end(h2)) { // we have reached one dst vertex
int32_t j, dist = r->di>>32, off = kh_val(h2, k) >> 32, cnt = (int32_t)kh_val(h2, k);
for (j = 0; j < cnt; ++j) {
mg_path_dst_t *t = &dst[(int32_t)dst_group[off + j]];
int32_t done = 0;
if (t->inner) {
done = 1;
} else {
int32_t copy = 0;
//if (mg_dbg_flag & MG_DBG_GC1) fprintf(stderr, " src=%c%s[%d],qlen=%d\tdst=%c%s[%d]\ttarget_distx=%d,target_hash=%x\tdistx=%d,hash=%x\n", "><"[src&1], g->seg[src>>1].name, src, ql, "><"[t->v&1], g->seg[t->v>>1].name, t->v, t->target_dist - g->seg[src>>1].len, t->target_hash, dist - g->seg[src>>1].len, r->hash);
if (t->n_path == 0) { // keep the shortest path
copy = 1;
} else if (t->target_dist >= 0) { // we have a target distance; choose the closest
if (dist == t->target_dist && t->check_hash && r->hash == t->target_hash) { // we found the target path
copy = 1, done = 1;
} else {
int32_t d0 = t->dist, d1 = dist;
d0 = d0 > t->target_dist? d0 - t->target_dist : t->target_dist - d0;
d1 = d1 > t->target_dist? d1 - t->target_dist : t->target_dist - d1;
if (d1 < d0) copy = 1;
}
}
if (copy) {
t->path_end = n_out - 1, t->dist = dist, t->hash = r->hash, t->is_0 = r->is_0;
if (t->target_dist >= 0) {
if (dist == t->target_dist && t->check_hash && r->hash == t->target_hash) done = 1;
else if (dist > t->target_dist + MG_SHORT_K_EXT) done = 1;
}
}
++t->n_path;
if (t->n_path >= max_k) done = 1;
}
if (dst_done[off + j] == 0 && done)
dst_done[off + j] = 1, ++n_done;
}
if (n_done == n_dst) break;
}
nv = gfa_arc_n(g, r->v);
av = gfa_arc_a(g, r->v);
for (i = 0; i < nv; ++i) { // visit all neighbors
gfa_arc_t *ai = &av[i];
int32_t d = (r->di>>32) + (uint32_t)ai->v_lv;
if (d > max_dist) continue; // don't probe vertices too far away
k = sp_put(h, ai->w, &absent);
q = &kh_val(h, k);
if (absent) { // a new vertex visited
q->k = 0, q->qs = q->qe = -1;
//if (ql && qs) fprintf(stderr, "ql=%d,src=%d\tv=%c%s[%d]\n", ql, src, "><"[ai->w&1], g->seg[ai->w>>1].name, ai->w);
}
if (q->k < max_k) { // enough room: add to the heap
p = gen_sp_node(km, g, ai->w, d, id++);
p->pre = n_out - 1;
p->hash = r->hash + kh_hash_uint32(ai->w);
p->is_0 = r->is_0;
if (ai->rank > 0) p->is_0 = 0;
kavl_insert(sp, &root, p, 0);
q->p[q->k++] = p;
ks_heapup_sp(q->k, q->p);
} else if (q->p[0]->di>>32 > d) { // shorter than the longest path so far: replace the longest
p = kavl_erase(sp, &root, q->p[0], 0);
if (p) {
p->di = (uint64_t)d<<32 | (id++);
p->pre = n_out - 1;
p->hash = r->hash + kh_hash_uint32(ai->w);
p->is_0 = r->is_0;
if (ai->rank > 0) p->is_0 = 0;
kavl_insert(sp, &root, p, 0);
ks_heapdown_sp(0, q->k, q->p);
} else {
fprintf(stderr, "Warning: logical bug in gfa_shortest_k(): q->k=%d,q->p[0]->{d,i}={%d,%d},d=%d,src=%u,max_dist=%d,n_dst=%d\n", q->k, (int32_t)(q->p[0]->di>>32), (int32_t)q->p[0]->di, d, src, max_dist, n_dst);
km_destroy(km);
return 0;
}
} // else: the path is longer than all the existing paths ended at ai->w
}
}
kfree(km, dst_group);
kfree(km, dst_done);
sp_destroy(h);
mg_idx_hfree(h_seeds);
kfree(km, seeds);
kfree(km, mini.a);
// NB: AVL nodes are not deallocated. When km==0, they are memory leaks.
for (i = 0, n_found = 0; i < n_dst; ++i)
if (dst[i].n_path > 0) ++n_found;
if (n_found > 0 && n_pathv) { // then generate the backtrack array
int32_t n, *trans;
KCALLOC(km, trans, n_out); // used to squeeze unused elements in out[]
for (i = 0; i < n_dst; ++i) { // mark dst vertices with a target distance
mg_path_dst_t *t = &dst[i];
if (t->n_path > 0 && t->target_dist >= 0 && t->path_end >= 0)
trans[(int32_t)out[t->path_end]->di] = 1;
}
for (i = 0; i < n_out; ++i) { // mark dst vertices without a target distance
k = sp2_get(h2, out[i]->v);
if (k != kh_end(h2)) { // TODO: check if this is correct!
int32_t off = kh_val(h2, k)>>32, cnt = (int32_t)kh_val(h2, k);
for (j = off; j < off + cnt; ++j)
if (dst[j].target_dist < 0)
trans[i] = 1;
}
}
for (i = n_out - 1; i >= 0; --i) // mark all predecessors
if (trans[i] && out[i]->pre >= 0)
trans[out[i]->pre] = 1;
for (i = n = 0; i < n_out; ++i) // generate coordinate translations
if (trans[i]) trans[i] = n++;
else trans[i] = -1;
*n_pathv = n;
KMALLOC(km0, ret, n);
for (i = 0; i < n_out; ++i) { // generate the backtrack array
mg_pathv_t *p;
if (trans[i] < 0) continue;
p = &ret[trans[i]];
p->v = out[i]->v, p->d = out[i]->di >> 32;
p->pre = out[i]->pre < 0? out[i]->pre : trans[out[i]->pre];
}
for (i = 0; i < n_dst; ++i) // translate "path_end"
if (dst[i].path_end >= 0)
dst[i].path_end = trans[dst[i].path_end];
}
km_destroy(km);
return ret;
}
void mg_sub_print_path(FILE *fp, const gfa_t *g, int32_t n, mg_pathv_t *path)
{
int32_t i;
for (i = 0; i < n; ++i) {
mg_pathv_t *p = &path[i];
fprintf(fp, "[%d]\t%d\t%s\t%d\t%d\n", i, p->v, g->seg[p->v>>1].name, p->d, p->pre);
}
}