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miniwfa.c
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miniwfa.c
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#include <string.h>
#include <assert.h>
#include <stdlib.h>
#include <stdio.h>
#include "miniwfa.h"
#include "kalloc.h"
/*
* Default setting
*/
void mwf_opt_init(mwf_opt_t *opt)
{
memset(opt, 0, sizeof(*opt));
opt->x = 4; // corresponding SW score: m=1, x=3, o1=4, e1=3/2, o2=15, e2=1/2
opt->o1 = 4, opt->e1 = 2;
opt->o2 = 15, opt->e2 = 1;
opt->kmer = 13, opt->max_occ = 2, opt->min_len = 30;
}
/*
* Structs and simple functions for traceback
*/
typedef struct {
int32_t lo, hi;
uint8_t *x;
} wf_tb1_t;
typedef struct {
int32_t m, n;
wf_tb1_t *a;
} wf_tb_t;
static wf_tb1_t *wf_tb_add(void *km, wf_tb_t *tb, int32_t lo, int32_t hi)
{
wf_tb1_t *p;
if (tb->n == tb->m) {
tb->m += (tb->m>>1) + 4;
tb->a = Krealloc(km, wf_tb1_t, tb->a, tb->m);
}
p = &tb->a[tb->n++];
p->lo = lo, p->hi = hi;
p->x = Kcalloc(km, uint8_t, hi - lo + 1);
return p;
}
typedef struct {
int32_t m, n;
uint32_t *cigar;
} wf_cigar_t;
static void wf_cigar_push1(void *km, wf_cigar_t *c, int32_t op, int32_t len)
{
if (c->n && op == (c->cigar[c->n-1]&0xf)) {
c->cigar[c->n-1] += len<<4;
} else {
if (c->n == c->m) {
c->m = c->m + (c->m>>1) + 4;
c->cigar = Krealloc(km, uint32_t, c->cigar, c->m);
}
c->cigar[c->n++] = len<<4 | op;
}
}
/*
* The stripe data structure
*/
#define WF_NEG_INF (-0x40000000)
typedef struct {
int32_t lo, hi;
int32_t *mem, *H, *E1, *E2, *F1, *F2;
} wf_slice_t;
typedef struct {
int32_t s, top, n, max_pen, lo, hi;
wf_slice_t *a;
} wf_stripe_t;
void wf_stripe_add(void *km, wf_stripe_t *wf, int32_t lo, int32_t hi)
{
int32_t i, n, m1 = wf->max_pen + 1, m2 = m1 * 2;
wf_slice_t *f;
++wf->s;
++wf->top;
if (wf->top == wf->n) wf->top = 0;
f = &wf->a[wf->top];
f->lo = lo, f->hi = hi;
n = hi - lo + 1;
kfree(km, f->mem);
f->mem = Kmalloc(km, int32_t, 5 * (n + m2));
f->H = f->mem + m1;
f->E1 = f->H + n + m2;
f->F1 = f->E1 + n + m2;
f->E2 = f->F1 + n + m2;
f->F2 = f->E2 + n + m2;
for (i = -m1; i < 0; ++i)
f->H[i] = f->E1[i] = f->E2[i] = f->F1[i] = f->F2[i] = WF_NEG_INF;
for (i = n; i < n + m1; ++i)
f->H[i] = f->E1[i] = f->E2[i] = f->F1[i] = f->F2[i] = WF_NEG_INF;
f->H -= lo, f->E1 -= lo, f->E2 -= lo, f->F1 -= lo, f->F2 -= lo; // such that f->H[lo] points to 0
}
static wf_stripe_t *wf_stripe_init(void *km, int32_t max_pen)
{
int32_t i;
wf_stripe_t *wf;
wf = Kcalloc(km, wf_stripe_t, 1);
wf->max_pen = max_pen;
wf->n = max_pen + 1;
wf->a = Kcalloc(km, wf_slice_t, wf->n);
wf->lo = wf->hi = 0;
for (i = 0; i < wf->n; ++i) {
wf_slice_t *f;
wf_stripe_add(km, wf, 0, 0);
f = &wf->a[wf->top];
f->H[0] = f->E1[0] = f->E2[0] = f->F1[0] = f->F2[0] = WF_NEG_INF;
}
wf->s = 0;
wf->a[wf->top].H[0] = -1;
return wf;
}
static void wf_stripe_destroy(void *km, wf_stripe_t *wf)
{
int32_t i;
for (i = 0; i < wf->n; ++i)
kfree(km, wf->a[i].mem);
kfree(km, wf->a);
kfree(km, wf);
}
static inline wf_slice_t *wf_stripe_get(const wf_stripe_t *wf, int32_t x)
{
int32_t y = wf->top - x;
if (y < 0) y += wf->n;
return &wf->a[y];
}
static inline int good_diag(int32_t d, int32_t k, int32_t tl, int32_t ql) // check if (d,k) falls within the DP matrix
{
return ((k >= -1 && k < tl) && (d + k >= -1 && d + k < ql));
}
static void wf_stripe_shrink(wf_stripe_t *wf, int32_t tl, int32_t ql)
{
int32_t j, d;
for (d = wf->lo; d <= wf->hi; ++d) {
for (j = 0; j < wf->n; ++j) {
wf_slice_t *p = &wf->a[(wf->top + 1 + j) % wf->n];
if (d < p->lo || d > p->hi) continue;
if (good_diag(d, p->H[d], tl, ql)) break;
if (good_diag(d, p->E1[d], tl, ql) || good_diag(d, p->F1[d], tl, ql)) break;
if (good_diag(d, p->E2[d], tl, ql) || good_diag(d, p->F2[d], tl, ql)) break;
}
if (j < wf->n) break; // stop when we see a "good diagonal" in the stripe
}
assert(d <= wf->hi); // should never happen
wf->lo = d;
for (d = wf->hi; d >= wf->lo; --d) {
for (j = 0; j < wf->n; ++j) {
wf_slice_t *p = &wf->a[(wf->top + 1 + j) % wf->n];
if (d < p->lo || d > p->hi) continue;
if (good_diag(d, p->H[d], tl, ql)) break;
if (good_diag(d, p->E1[d], tl, ql) || good_diag(d, p->F1[d], tl, ql)) break;
if (good_diag(d, p->E2[d], tl, ql) || good_diag(d, p->F2[d], tl, ql)) break;
}
if (j < wf->n) break;
}
assert(d >= wf->lo);
wf->hi = d;
}
typedef struct {
int32_t s, d;
} wf_chkpt_t;
/*
* Extend a diagonal along exact matches
*/
// pad strings with distinct characters
static void wf_pad_str(void *km, int32_t tl, const char *ts, int32_t ql, const char *qs, char **pts, char **pqs)
{
uint8_t t[256];
int32_t i, c1 = -1, c2 = -1;
char *s1, *s2;
*pts = *pqs = 0;
// collect all used characters
memset(t, 0, 256);
for (i = 0; i < tl; ++i)
if (t[(uint8_t)ts[i]] == 0)
t[(uint8_t)ts[i]] = 1;
for (i = 0; i < ql; ++i)
if (t[(uint8_t)qs[i]] == 0)
t[(uint8_t)qs[i]] = 1;
for (i = 0; i < 256; ++i)
if (t[i] == 0) {
if (c1 < 0) c1 = i;
else if (c2 < 0) c2 = i;
}
if (c1 < 0 || c2 < 0) return; // The two strings use >=255 characters. Unlikely for bio strings.
s1 = Kmalloc(km, char, tl + ql + 16); // the two strings are allocated together
s2 = s1 + tl + 8;
memcpy(s1, ts, tl);
for (i = tl; i < tl + 8; ++i) s1[i] = c1; // pad with c1
memcpy(s2, qs, ql);
for (i = ql; i < ql + 8; ++i) s2[i] = c2; // pad with c2
*pts = s1, *pqs = s2;
}
// Extend a diagonal along exact matches.
static inline int32_t wf_extend1_padded(const char *ts, const char *qs, int32_t k, int32_t d)
{
uint64_t cmp = 0;
const char *ts_ = ts + 1;
const char *qs_ = qs + d + 1;
while (1) {
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;
}
k += __builtin_ctzl(cmp) >> 3;
return k;
}
/*
* Core wf_next() routines
*/
// Force loop vectorization. Learned from WFA.
#if defined(__clang__)
#define PRAGMA_LOOP_VECTORIZE _Pragma("clang loop vectorize(enable)")
#elif defined(__GNUC__)
#define PRAGMA_LOOP_VECTORIZE _Pragma("GCC ivdep")
#else
#define PRAGMA_LOOP_VECTORIZE _Pragma("ivdep")
#endif
#define wf_max(a, b) ((a) >= (b)? (a) : (b))
static void wf_next_prep(void *km, const mwf_opt_t *opt, wf_stripe_t *wf, int32_t lo, int32_t hi,
int32_t **H, int32_t **E1, int32_t **F1, int32_t **E2, int32_t **F2,
const int32_t **pHx, const int32_t **pHo1, const int32_t **pHo2,
const int32_t **pE1, const int32_t **pF1, const int32_t **pE2, const int32_t **pF2)
{
const wf_slice_t *fx, *fo1, *fo2, *fe1, *fe2;
wf_slice_t *ft;
wf_stripe_add(km, wf, lo, hi);
ft = &wf->a[wf->top];
fx = wf_stripe_get(wf, opt->x);
fo1 = wf_stripe_get(wf, opt->o1 + opt->e1);
fo2 = wf_stripe_get(wf, opt->o2 + opt->e2);
fe1 = wf_stripe_get(wf, opt->e1);
fe2 = wf_stripe_get(wf, opt->e2);
*pHx = fx->H, *pHo1 = fo1->H, *pHo2 = fo2->H, *pE1 = fe1->E1, *pE2 = fe2->E2, *pF1 = fe1->F1, *pF2 = fe2->F2;
*H = ft->H, *E1 = ft->E1, *E2 = ft->E2, *F1 = ft->F1, *F2 = ft->F2;
}
static void wf_next_score(int32_t lo, int32_t hi, int32_t *H, int32_t *E1, int32_t *F1, int32_t *E2, int32_t *F2,
const int32_t *pHx, const int32_t *pHo1, const int32_t *pHo2,
const int32_t *pE1, const int32_t *pF1, const int32_t *pE2, const int32_t *pF2)
{
int32_t d;
PRAGMA_LOOP_VECTORIZE
for (d = lo; d <= hi; ++d) {
int32_t h, f, e;
E1[d] = wf_max(pHo1[d-1], pE1[d-1]);
E2[d] = wf_max(pHo2[d-1], pE2[d-1]);
e = wf_max(E1[d], E2[d]);
F1[d] = wf_max(pHo1[d+1], pF1[d+1]) + 1;
F2[d] = wf_max(pHo2[d+1], pF2[d+1]) + 1;
f = wf_max(F1[d], F2[d]);
h = wf_max(e, f);
H[d] = wf_max(pHx[d] + 1, h);
// if (H[d] >= -1) fprintf(stderr, "s=%d, d=%d, k=%d, (%d,%d)\n", wf->s, d, H[d], E1[d], F1[d]);
}
}
static void wf_next_tb(int32_t lo, int32_t hi, int32_t *H, int32_t *E1, int32_t *F1, int32_t *E2, int32_t *F2, uint8_t *ax,
const int32_t *pHx, const int32_t *pHo1, const int32_t *pHo2,
const int32_t *pE1, const int32_t *pF1, const int32_t *pE2, const int32_t *pF2)
{
int32_t d;
PRAGMA_LOOP_VECTORIZE
for (d = lo; d <= hi; ++d) {
int32_t h, f, e;
uint8_t x = 0, ze, zf, z;
x |= pHo1[d-1] >= pE1[d-1]? 0 : 0x08;
E1[d] = wf_max(pHo1[d-1], pE1[d-1]);
x |= pHo2[d-1] >= pE2[d-1]? 0 : 0x20;
E2[d] = wf_max(pHo2[d-1], pE2[d-1]);
ze = E1[d] >= E2[d]? 1 : 3;
e = wf_max(E1[d], E2[d]);
x |= pHo1[d+1] >= pF1[d+1]? 0 : 0x10;
F1[d] = wf_max(pHo1[d+1], pF1[d+1]) + 1;
x |= pHo2[d+1] >= pF2[d+1]? 0 : 0x40;
F2[d] = wf_max(pHo2[d+1], pF2[d+1]) + 1;
zf = F1[d] >= F2[d]? 2 : 4;
f = wf_max(F1[d], F2[d]);
z = e >= f? ze : zf;
h = wf_max(e, f);
z = pHx[d] + 1 >= h? 0 : z;
H[d] = wf_max(pHx[d] + 1, h);
ax[d] = x | z;
}
}
/*
* Core algorithm
*/
static void wf_next_basic(void *km, void *km_tb, const mwf_opt_t *opt, wf_stripe_t *wf, wf_tb_t *tb, int32_t lo, int32_t hi)
{
int32_t *H, *E1, *E2, *F1, *F2;
const int32_t *pHx, *pHo1, *pHo2, *pE1, *pE2, *pF1, *pF2;
wf_next_prep(km, opt, wf, lo, hi, &H, &E1, &F1, &E2, &F2, &pHx, &pHo1, &pHo2, &pE1, &pF1, &pE2, &pF2);
if (tb) {
uint8_t *ax;
ax = wf_tb_add(km_tb, tb, lo, hi)->x - lo;
wf_next_tb(lo, hi, H, E1, F1, E2, F2, ax, pHx, pHo1, pHo2, pE1, pF1, pE2, pF2);
} else {
wf_next_score(lo, hi, H, E1, F1, E2, F2, pHx, pHo1, pHo2, pE1, pF1, pE2, pF2);
}
if (H[lo] >= -1 || E1[lo] >= -1 || F1[lo] >= -1 || E2[lo] >= -1 || F2[lo] >= -1) wf->lo = lo;
if (H[hi] >= -1 || E1[hi] >= -1 || F1[hi] >= -1 || E2[hi] >= -1 || F2[hi] >= -1) wf->hi = hi;
}
static uint32_t *wf_traceback(void *km, const mwf_opt_t *opt, wf_tb_t *tb, int32_t t_end, const char *ts, int32_t q_end, const char *qs, int32_t last, int32_t *n_cigar)
{
wf_cigar_t cigar = {0,0,0};
int32_t i = q_end, k = t_end, s = tb->n - 1;
while (i >= 0 && k >= 0) {
int32_t k0 = k, j, x, state, ext;
if (last == 0) { // if the previous state is 0, check exact matches
while (i >= 0 && k >= 0 && qs[i] == ts[k])
--i, --k;
if (k0 - k > 0)
wf_cigar_push1(km, &cigar, 7, k0 - k);
if (i < 0 || k < 0) break;
}
assert(s >= 0);
j = i - k - tb->a[s].lo;
assert(j <= tb->a[s].hi - tb->a[s].lo);
x = tb->a[s].x[j];
state = last == 0? x&7 : last;
ext = state > 0? x>>(state+2)&1 : 0; // whether an extension
//fprintf(stderr, "s=%d, %d->%d, ext=%d%d%d%d, i=%d, k=%d\n", s, last, state, x>>3&1, x>>4&1, x>>5&1, x>>6&1, i, k);
if (state == 0) {
wf_cigar_push1(km, &cigar, 8, 1);
--i, --k, s -= opt->x;
} else if (state == 1) {
wf_cigar_push1(km, &cigar, 1, 1);
--i, s -= ext? opt->e1 : opt->o1 + opt->e1;
} else if (state == 3) {
wf_cigar_push1(km, &cigar, 1, 1);
--i, s -= ext? opt->e2 : opt->o2 + opt->e2;
} else if (state == 2) {
wf_cigar_push1(km, &cigar, 2, 1);
--k, s -= ext? opt->e1 : opt->o1 + opt->e1;
} else if (state == 4) {
wf_cigar_push1(km, &cigar, 2, 1);
--k, s -= ext? opt->e2 : opt->o2 + opt->e2;
} else abort();
last = state > 0 && ext? state : 0;
}
if (opt->flag&MWF_F_DEBUG) fprintf(stderr, "s0=%d, s=%d, i=%d, k=%d\n", tb->n-1, s, i, k);
if (i >= 0) wf_cigar_push1(km, &cigar, 1, i + 1);
else if (k >= 0) wf_cigar_push1(km, &cigar, 2, k + 1);
for (i = 0; i < cigar.n>>1; ++i) { // reverse to the input order
uint32_t t = cigar.cigar[i];
cigar.cigar[i] = cigar.cigar[cigar.n - i - 1];
cigar.cigar[cigar.n - i - 1] = t;
}
*n_cigar = cigar.n;
return cigar.cigar;
}
// pts and pqs MUST BE padded with wf_pad_str()
static void mwf_wfa_core(void *km, const mwf_opt_t *opt, int32_t tl, const char *pts, int32_t ql, const char *pqs, int32_t n_seg, wf_chkpt_t *seg, mwf_rst_t *r)
{
int32_t max_pen, sid, is_tb = !!(opt->flag&MWF_F_CIGAR), last_state = 0, stopped = 0;
wf_stripe_t *wf;
wf_tb_t tb = {0,0,0};
void *km_tb, *km_st;
memset(r, 0, sizeof(*r));
km_tb = is_tb && !(opt->flag&MWF_F_NO_KALLOC)? km_init2(km, 0) : 0;
km_st = !(opt->flag&MWF_F_NO_KALLOC)? km_init2(km, 0) : 0;
max_pen = opt->x;
max_pen = max_pen > opt->o1 + opt->e1? max_pen : opt->o1 + opt->e1;
max_pen = max_pen > opt->o2 + opt->e2? max_pen : opt->o2 + opt->e2;
wf = wf_stripe_init(km_st, max_pen);
assert(pts);
sid = 0;
while (1) {
wf_slice_t *p = &wf->a[wf->top];
int32_t d, lo, hi, *H = p->H;
for (d = p->lo; d <= p->hi; ++d) {
int32_t k = 0;
if (H[d] < -1 || d + H[d] < -1 || H[d] >= tl || d + H[d] >= ql) continue;
k = wf_extend1_padded(pts, pqs, H[d], d);
//fprintf(stderr, "[s=%d] [%d,%d]:%d %d->%d,%d,%d,%d,%d\n", wf->s, p->lo, p->hi, d, H[d], k, wf->a[wf->top].E1[d], wf->a[wf->top].F1[d], wf->a[wf->top].E2[d], wf->a[wf->top].F2[d]);
if (k == tl - 1 && d + k == ql - 1) {
if (k == H[d] && is_tb)
last_state = tb.a[tb.n-1].x[d - tb.a[tb.n-1].lo] & 7;
break;
}
H[d] = k;
}
if (d <= p->hi) break;
if (is_tb && seg && sid < n_seg && seg[sid].s == wf->s) {
assert(seg[sid].d >= wf->lo && seg[sid].d <= wf->hi);
wf->lo = wf->hi = seg[sid++].d;
}
lo = wf->lo > -tl? wf->lo - 1 : -tl;
hi = wf->hi < ql? wf->hi + 1 : ql;
wf_next_basic(km_st, km_tb, opt, wf, is_tb? &tb : 0, lo, hi);
if ((wf->s&0xff) == 0) wf_stripe_shrink(wf, tl, ql);
r->n_iter += hi - lo + 1;
if ((opt->max_iter > 0 && r->n_iter > opt->max_iter) || (opt->max_s > 0 && wf->s > opt->max_s)) {
stopped = 1;
break;
}
}
r->s = stopped? -1 : wf->s;
if (is_tb && !stopped)
r->cigar = wf_traceback(km, opt, &tb, tl-1, pts, ql-1, pqs, last_state, &r->n_cigar);
if (km_st == 0) wf_stripe_destroy(km_st, wf);
else km_destroy(km_st);
km_destroy(km_tb);
if (is_tb && !stopped)
r->cigar = (uint32_t*)krelocate(km, r->cigar, r->n_cigar * sizeof(*r->cigar));
}
/*
* Low-memory mode
*/
typedef struct {
int32_t n, n_intv, max_s;
int32_t *x;
uint64_t *intv;
} wf_ss_t; // snapshot
typedef struct {
int32_t n, m;
wf_ss_t *a;
} wf_sss_t;
static void wf_snapshot1(void *km, wf_stripe_t *sf, wf_ss_t *ss)
{
int32_t j, k, t;
ss->n = 0, ss->max_s = sf->s;
for (j = 0; j < sf->n; ++j)
ss->n += 5 * (sf->a[j].hi - sf->a[j].lo + 1);
ss->x = Kmalloc(km, int32_t, ss->n);
ss->n_intv = sf->n;
ss->intv = Kmalloc(km, uint64_t, ss->n_intv);
for (j = 0, t = 0; j < sf->n; ++j) {
wf_slice_t *p;
k = (sf->top + 1 + j) % sf->n;
p = &sf->a[k];
ss->intv[j] = (uint64_t)p->lo << 32 | (p->hi - p->lo + 1) * 5;
for (k = p->lo; k <= p->hi; ++k) {
ss->x[t] = p->H[k], p->H[k] = t++;
ss->x[t] = p->E1[k], p->E1[k] = t++;
ss->x[t] = p->F1[k], p->F1[k] = t++;
ss->x[t] = p->E2[k], p->E2[k] = t++;
ss->x[t] = p->F2[k], p->F2[k] = t++;
}
}
assert(t == ss->n);
}
static void wf_snapshot(void *km, wf_sss_t *sss, wf_stripe_t *sf)
{
if (sss->n == sss->m) {
sss->m += (sss->m>>1) + 8;
sss->a = Krealloc(km, wf_ss_t, sss->a, sss->m);
}
wf_snapshot1(km, sf, &sss->a[sss->n++]);
}
static void wf_snapshot_free(void *km, wf_sss_t *sss)
{
int32_t j;
for (j = 0; j < sss->n; ++j) {
kfree(km, sss->a[j].x);
kfree(km, sss->a[j].intv);
}
kfree(km, sss->a);
}
static void wf_next_seg(void *km, const mwf_opt_t *opt, uint8_t *xbuf, wf_stripe_t *wf, wf_stripe_t *sf, int32_t lo, int32_t hi)
{
int32_t d, *H, *E1, *E2, *F1, *F2;
const int32_t *pHx, *pHo1, *pHo2, *pE1, *pE2, *pF1, *pF2;
uint8_t *ax = xbuf - lo;
wf_next_prep(km, opt, wf, lo, hi, &H, &E1, &F1, &E2, &F2, &pHx, &pHo1, &pHo2, &pE1, &pF1, &pE2, &pF2);
wf_next_tb(lo, hi, H, E1, F1, E2, F2, ax, pHx, pHo1, pHo2, pE1, pF1, pE2, pF2);
wf_next_prep(km, opt, sf, lo, hi, &H, &E1, &F1, &E2, &F2, &pHx, &pHo1, &pHo2, &pE1, &pF1, &pE2, &pF2);
PRAGMA_LOOP_VECTORIZE
for (d = lo; d <= hi; ++d) { // FIXME: merge this loop into the loop in wf_next_tb(). I tried but couldn't make clang vectorize.
uint8_t x = ax[d];
int32_t a, b, e1, f1, e2, f2, h;
a = pHo1[d-1], b = pE1[d-1];
e1 = E1[d] = (x&0x08) == 0? a : b;
a = pHo1[d+1], b = pF1[d+1];
f1 = F1[d] = (x&0x10) == 0? a : b;
a = pHo2[d-1], b = pE2[d-1];
e2 = E2[d] = (x&0x20) == 0? a : b;
a = pHo2[d+1], b = pF2[d+1];
f2 = F2[d] = (x&0x40) == 0? a : b;
x &= 7;
h = pHx[d];
h = x == 1? e1 : h;
h = x == 2? f1 : h;
h = x == 3? e2 : h;
h = x == 4? f2 : h;
H[d] = h;
}
if (H[lo] >= -1 || E1[lo] >= -1 || F1[lo] >= -1 || E2[lo] >= -1 || F2[lo] >= -1) wf->lo = lo;
if (H[hi] >= -1 || E1[hi] >= -1 || F1[hi] >= -1 || E2[hi] >= -1 || F2[hi] >= -1) wf->hi = hi;
}
static wf_chkpt_t *wf_traceback_seg(void *km, wf_sss_t *sss, int32_t last, int32_t *n_seg)
{
int32_t j;
wf_chkpt_t *seg;
*n_seg = sss->n;
seg = Kmalloc(km, wf_chkpt_t, sss->n);
for (j = sss->n - 1; j >= 0; --j) {
int32_t k, m;
wf_ss_t *p = &sss->a[j];
for (k = 0, m = 0; k < p->n_intv; ++k) {
if (last >= m && last < m + (int32_t)p->intv[k])
break;
m += (int32_t)p->intv[k];
}
assert(k < p->n_intv);
seg[j].s = p->max_s - (p->n_intv - k - 1);
seg[j].d = (int32_t)(p->intv[k]>>32) + (last - m) / 5;
last = p->x[last];
}
assert(last == -1);
return seg;
}
wf_chkpt_t *mwf_wfa_seg(void *km, const mwf_opt_t *opt, int32_t tl, const char *pts, int32_t ql, const char *pqs, int32_t *n_seg_)
{
int32_t max_pen, last, n_seg;
wf_stripe_t *wf, *sf;
wf_sss_t sss = {0,0,0};
uint8_t *xbuf;
wf_chkpt_t *seg;
void *km_st;
km_st = !(opt->flag&MWF_F_NO_KALLOC)? km_init2(km, 0) : 0;
max_pen = opt->x;
max_pen = max_pen > opt->o1 + opt->e1? max_pen : opt->o1 + opt->e1;
max_pen = max_pen > opt->o2 + opt->e2? max_pen : opt->o2 + opt->e2;
xbuf = Kcalloc(km_st, uint8_t, tl + ql + 1);
wf = wf_stripe_init(km_st, max_pen);
sf = wf_stripe_init(km_st, max_pen);
assert(pts);
while (1) {
wf_slice_t *p = &wf->a[wf->top];
int32_t d, lo, hi, *H = p->H;
for (d = p->lo; d <= p->hi; ++d) {
int32_t k;
if (H[d] < -1 || d + H[d] < -1 || H[d] >= tl || d + H[d] >= ql) continue;
k = wf_extend1_padded(pts, pqs, H[d], d);
if (k == tl - 1 && d + k == ql - 1) {
last = sf->a[sf->top].H[d];
break;
}
H[d] = k;
}
if (d <= p->hi) break;
lo = wf->lo > -tl? wf->lo - 1 : -tl;
hi = wf->hi < ql? wf->hi + 1 : ql;
if ((wf->s + 1) % opt->step == 0)
wf_snapshot(km_st, &sss, sf);
wf_next_seg(km_st, opt, xbuf, wf, sf, lo, hi);
if ((wf->s&0xff) == 0) wf_stripe_shrink(wf, tl, ql);
}
seg = wf_traceback_seg(km, &sss, last, &n_seg);
if (km_st == 0) {
wf_snapshot_free(km_st, &sss);
wf_stripe_destroy(km_st, wf);
wf_stripe_destroy(km_st, sf);
kfree(km_st, xbuf);
} else km_destroy(km_st);
seg = (wf_chkpt_t*)krelocate(km, seg, n_seg * sizeof(*seg));
*n_seg_ = n_seg;
return seg;
}
void mwf_wfa_exact(void *km, const mwf_opt_t *opt, int32_t tl, const char *ts, int32_t ql, const char *qs, mwf_rst_t *r)
{
int32_t n_seg = 0;
wf_chkpt_t *seg = 0;
char *pts, *pqs;
wf_pad_str(km, tl, ts, ql, qs, &pts, &pqs);
if (opt->step > 0)
seg = mwf_wfa_seg(km, opt, tl, pts, ql, pqs, &n_seg);
mwf_wfa_core(km, opt, tl, pts, ql, pqs, n_seg, seg, r);
kfree(km, seg);
kfree(km, pts);
}
/*
* Heuristics
*/
static int32_t mg_lis_64(void *km, int32_t n, const uint64_t *a, int32_t *b)
{
int32_t i, k, L = 0, *M, *P = b;
KMALLOC(km, M, n+1);
for (i = 0; i < n; ++i) {
int32_t lo = 1, hi = L, newL;
while (lo <= hi) {
int32_t mid = (lo + hi + 1) >> 1;
if (a[M[mid]] < a[i]) lo = mid + 1;
else hi = mid - 1;
}
newL = lo, P[i] = M[newL - 1], M[newL] = i;
if (newL > L) L = newL;
}
k = M[L];
memcpy(M, P, n * sizeof(int32_t));
for (i = L - 1; i >= 0; --i) b[i] = k, k = M[k];
kfree(km, M);
return L;
}
extern void radix_sort_gfa64(uint64_t*, uint64_t*);
extern unsigned char seq_nt4_table[256];
static int32_t mg_fc_kmer(int32_t len, const char *seq, int32_t rid, int32_t k, uint64_t *a)
{
int32_t i, l, n;
uint64_t x, mask = (1ULL<<k*2) - 1;
for (i = l = 0, x = 0, n = 0; i < len; ++i) {
int32_t c = seq_nt4_table[(uint8_t)seq[i]];
if (c < 4) {
x = (x << 2 | c) & mask;
if (++l >= k) a[n++] = (x<<1|rid) << 32 | i;
} else l = 0, x = 0;
}
return n;
}
static uint64_t *mg_chain(void *km, int32_t l1, const char *s1, int32_t l2, const char *s2, int32_t k, int32_t max_occ, int32_t *n_lis_)
{
int32_t i, n_a, n_b, m_b, i0, n_lis, *lis;
uint64_t *a, *b;
*n_lis_ = 0;
if (l1 < k || l2 < k) return 0;
assert(k >= 2 && k <= 15);
// collect k-mers
KMALLOC(km, a, l1 + l2);
n_a = mg_fc_kmer(l1, s1, 0, k, a);
n_a += mg_fc_kmer(l2, s2, 1, k, &a[n_a]);
radix_sort_gfa64(a, a + n_a);
// collect k-mer matches
n_b = m_b = 0, b = 0;
for (i0 = 0, i = 1; i <= n_a; ++i) {
if (i == n_a || a[i0]>>33 != a[i]>>33) {
if (i - i0 >= 2) {
int32_t j, s, t;
for (j = i0; j < i && (a[j]>>32&1) == 0; ++j) {}
if (j > i0 && j < i && j - i0 <= max_occ && i - j <= max_occ) {
for (s = i0; s < j; ++s)
for (t = j; t < i; ++t) {
if (n_b == m_b) KEXPAND(km, b, m_b);
b[n_b++] = a[s]<<32 | (uint32_t)a[t];
}
}
}
i0 = i;
}
}
kfree(km, a);
// find co-linear chain with LIS
radix_sort_gfa64(b, b + n_b);
for (i = 0; i < n_b; ++i)
b[i] = b[i]>>32 | b[i]<<32;
KMALLOC(km, lis, n_b);
n_lis = mg_lis_64(km, n_b, b, lis);
a = Kmalloc(km, uint64_t, n_lis);
for (i = 0; i < n_lis; ++i) a[i] = b[lis[i]];
kfree(km, lis);
kfree(km, b);
b = Kmalloc(km, uint64_t, n_lis);
memcpy(b, a, sizeof(uint64_t) * n_lis);
kfree(km, a);
*n_lis_ = n_lis;
for (i = 0; i < n_lis; ++i) // switch back, such that seq1 on the high bits
b[i] = b[i]>>32 | b[i]<<32;
return b;
}
static double mwf_ksim(void *km, int32_t l1, const char *s1, int32_t l2, const char *s2, int32_t k)
{
int32_t i, i0, j, n_a, n1 = 0, n2 = 0, t1 = 0, t2 = 0;
double p1, p2;
uint64_t *a;
if (l1 < k || l2 < k) return 0;
assert(k >= 2 && k <= 15);
KMALLOC(km, a, l1 + l2);
n_a = mg_fc_kmer(l1, s1, 0, k, a);
n_a += mg_fc_kmer(l2, s2, 1, k, &a[n_a]);
radix_sort_gfa64(a, a + n_a);
for (i0 = 0, i = 1; i <= n_a; ++i) {
if (i == n_a || a[i0]>>33 != a[i]>>33) {
int32_t m1, m2, min;
for (j = i0; j < i && (a[j]>>32&1) == 0; ++j) {}
m1 = j - i0, m2 = i - j;
min = m1 < m2? m1 : m2;
n1 += m1, n2 += m2;
if (m1 > 0 && m2 > 0)
t1 += min, t2 += min;
i0 = i;
}
}
kfree(km, a);
p1 = (double)t1 / n1, p2 = (double)t2 / n2;
return p1 > p2? p1 : p2;
}
#define kroundup32(x) (--(x), (x)|=(x)>>1, (x)|=(x)>>2, (x)|=(x)>>4, (x)|=(x)>>8, (x)|=(x)>>16, ++(x))
static void wf_cigar_push(void *km, wf_cigar_t *c, int32_t n_cigar, const uint32_t *cigar)
{
if (n_cigar == 0) return;
wf_cigar_push1(km, c, cigar[0]&0xf, cigar[0]>>4);
if (c->n + n_cigar - 1 > c->m) {
c->m = c->n + n_cigar - 1;
kroundup32(c->m);
c->cigar = Krealloc(km, uint32_t, c->cigar, c->m);
}
memcpy(&c->cigar[c->n], &cigar[1], sizeof(*cigar) * (n_cigar - 1));
c->n += n_cigar - 1;
}
static int32_t wf_anchor_filter(int32_t n, uint64_t *a, int32_t tl, int32_t ql, int32_t k, int32_t min_l)
{
int32_t i, st, x0, y0, x1, y1, j, l, m;
for (i = 0, x0 = y0 = x1 = y1 = 0, st = -1, l = 0; i <= n; ++i) {
int32_t x, y;
if (i == n) x = tl, y = ql;
else x = (int32_t)(a[i]>>32) + 1, y = (int32_t)a[i] + 1;
if (x - x0 != y - y0) {
//fprintf(stderr, "X\t%d\t(%d,%d) -> (%d,%d)\n", l, x0, y0, x, y);
if (l < min_l)
for (j = st > 0? st : 0; j < i; ++j)
a[j] = 0;
x0 = x, y0 = y, st = i, l = k;
} else l += x - x1;
x1 = x, y1 = y;
}
for (i = 0, m = 0; i < n; ++i)
if (a[i] != 0) a[m++] = a[i];
return m;
}
void mwf_wfa_chain(void *km, const mwf_opt_t *opt, int32_t tl, const char *ts, int32_t ql, const char *qs, mwf_rst_t *r)
{
int32_t n_a, i, x0, y0;
uint64_t *a;
void *km_wfa;
wf_cigar_t c = {0,0,0};
km_wfa = !(opt->flag&MWF_F_NO_KALLOC)? km_init2(km, 0) : 0;
a = mg_chain(km_wfa, tl, ts, ql, qs, opt->kmer, opt->max_occ, &n_a);
n_a = wf_anchor_filter(n_a, a, tl, ql, opt->kmer, opt->min_len);
r->s = 0;
for (i = 0, x0 = y0 = 0; i <= n_a; ++i) {
int32_t x1, y1;
if (i == n_a) x1 = tl, y1 = ql;
else x1 = (int32_t)(a[i]>>32) + 1, y1 = (int32_t)a[i] + 1;
if (i < n_a && x1 - x0 == y1 - y0 && x1 - x0 <= opt->kmer) {
if (opt->flag&MWF_F_CIGAR)
wf_cigar_push1(km, &c, 7, x1 - x0);
} else if (x0 < x1 && y0 < y1) {
if (x1 - x0 >= 10000 && y1 - y0 >= 10000 && mwf_ksim(km, x1 - x0, &ts[x0], y1 - y0, &qs[y0], opt->kmer) < 0.02) {
if (opt->flag&MWF_F_CIGAR) {
wf_cigar_push1(km, &c, 2, x1 - x0);
wf_cigar_push1(km, &c, 1, y1 - y0);
}
r->s += opt->o2 * 2 + opt->e2 * ((x1 - x0) + (y1 - y0));
} else {
mwf_rst_t q;
mwf_wfa_exact(km_wfa, opt, x1 - x0, &ts[x0], y1 - y0, &qs[y0], &q);
if (opt->flag&MWF_F_CIGAR)
wf_cigar_push(km, &c, q.n_cigar, q.cigar);
r->s += q.s;
kfree(km_wfa, q.cigar);
}
} else if (x0 < x1) {
wf_cigar_push1(km, &c, 2, x1 - x0);
r->s += opt->o2 + (x1 - x0) * opt->e2 < opt->o1 + (x1 - x0) * opt->e1? opt->o2 + (x1 - x0) * opt->e2 : opt->o1 + (x1 - x0) * opt->e1;
} else if (y0 < y1) {
wf_cigar_push1(km, &c, 1, y1 - y0);
r->s += opt->o2 + (y1 - y0) * opt->e2 < opt->o1 + (y1 - y0) * opt->e1? opt->o2 + (y1 - y0) * opt->e2 : opt->o1 + (y1 - y0) * opt->e1;
}
x0 = x1, y0 = y1;
}
if (km_wfa == 0) kfree(km_wfa, a);
km_destroy(km_wfa);
r->n_cigar = c.n, r->cigar = c.cigar;
r->cigar = (uint32_t*)krelocate(km, r->cigar, r->n_cigar * sizeof(*r->cigar));
}
void mwf_wfa_auto(void *km, const mwf_opt_t *opt0, int32_t tl, const char *ts, int32_t ql, const char *qs, mwf_rst_t *r)
{
mwf_opt_t opt = *opt0;
opt.step = 0, opt.max_iter = 100000000;
mwf_wfa_exact(km, &opt, tl, ts, ql, qs, r);
if (r->s < 0) {
if (opt.flag & MWF_F_CIGAR) opt.step = 5000;
opt.max_iter = -1;
mwf_wfa_chain(km, &opt, tl, ts, ql, qs, r);
}
}