#include #include #include #include #include #include "rle.h" #include "rope.h" /******************* *** Memory Pool *** *******************/ #define MP_CHUNK_SIZE 0x100000 // 1MB per chunk typedef struct { // memory pool for fast and compact memory allocation (no free) int size, i, n_elems; int64_t top, max; uint8_t **mem; } mempool_t; static mempool_t *mp_init(int size) { mempool_t *mp; mp = calloc(1, sizeof(mempool_t)); mp->size = size; mp->i = mp->n_elems = MP_CHUNK_SIZE / size; mp->top = -1; return mp; } static void mp_destroy(mempool_t *mp) { int64_t i; for (i = 0; i <= mp->top; ++i) free(mp->mem[i]); free(mp->mem); free(mp); } static inline void *mp_alloc(mempool_t *mp) { if (mp->i == mp->n_elems) { if (++mp->top == mp->max) { mp->max = mp->max? mp->max<<1 : 1; mp->mem = realloc(mp->mem, sizeof(void*) * mp->max); } mp->mem[mp->top] = calloc(mp->n_elems, mp->size); mp->i = 0; } return mp->mem[mp->top] + (mp->i++) * mp->size; } /*************** *** B+ rope *** ***************/ rope_t *rope_init(int max_nodes, int block_len) { rope_t *rope; rope = calloc(1, sizeof(rope_t)); if (block_len < 32) block_len = 32; rope->max_nodes = (max_nodes+ 1)>>1<<1; rope->block_len = (block_len + 7) >> 3 << 3; rope->node = mp_init(sizeof(rpnode_t) * rope->max_nodes); rope->leaf = mp_init(rope->block_len); rope->root = mp_alloc(rope->node); rope->root->n = 1; rope->root->is_bottom = 1; rope->root->p = mp_alloc(rope->leaf); return rope; } void rope_destroy(rope_t *rope) { mp_destroy(rope->node); mp_destroy(rope->leaf); free(rope); } static inline rpnode_t *split_node(rope_t *rope, rpnode_t *u, rpnode_t *v) { // split $v's child. $u is the first node in the bucket. $v and $u are in the same bucket. IMPORTANT: there is always enough room in $u int j, i = v - u; rpnode_t *w; // $w is the sibling of $v if (u == 0) { // only happens at the root; add a new root u = v = mp_alloc(rope->node); v->n = 1; v->p = rope->root; // the new root has the old root as the only child memcpy(v->c, rope->c, 48); for (j = 0; j < 6; ++j) v->l += v->c[j]; rope->root = v; } if (i != u->n - 1) // then make room for a new node memmove(v + 2, v + 1, sizeof(rpnode_t) * (u->n - i - 1)); ++u->n; w = v + 1; memset(w, 0, sizeof(rpnode_t)); w->p = mp_alloc(u->is_bottom? rope->leaf : rope->node); if (u->is_bottom) { // we are at the bottom level; $v->p is a string instead of a node uint8_t *p = (uint8_t*)v->p, *q = (uint8_t*)w->p; rle_split(p, q); rle_count(q, w->c); } else { // $v->p is a node, not a string rpnode_t *p = v->p, *q = w->p; // $v and $w are siblings and thus $p and $q are cousins p->n -= rope->max_nodes>>1; memcpy(q, p + p->n, sizeof(rpnode_t) * (rope->max_nodes>>1)); q->n = rope->max_nodes>>1; // NB: this line must below memcpy() as $q->n and $q->is_bottom are modified by memcpy() q->is_bottom = p->is_bottom; for (i = 0; i < q->n; ++i) for (j = 0; j < 6; ++j) w->c[j] += q[i].c[j]; } for (j = 0; j < 6; ++j) // compute $w->l and update $v->c w->l += w->c[j], v->c[j] -= w->c[j]; v->l -= w->l; // update $v->c return v; } int64_t rope_insert_run(rope_t *rope, int64_t x, int a, int64_t rl, rpcache_t *cache) { // insert $a after $x symbols in $rope and the returns rank(a, x) rpnode_t *u = 0, *v = 0, *p = rope->root; // $v is the parent of $p; $u and $v are at the same level and $u is the first node in the bucket int64_t y = 0, z = 0, cnt[6]; int n_runs; do { // top-down update. Searching and node splitting are done together in one pass. if (p->n == rope->max_nodes) { // node is full; split v = split_node(rope, u, v); // $v points to the parent of $p; when a new root is added, $v points to the root if (y + v->l < x) // if $v is not long enough after the split, we need to move both $p and its parent $v y += v->l, z += v->c[a], ++v, p = v->p; } u = p; if (v && x - y > v->l>>1) { // then search backwardly for the right node to descend p += p->n - 1; y += v->l; z += v->c[a]; for (; y >= x; --p) y -= p->l, z -= p->c[a]; ++p; } else for (; y + p->l < x; ++p) y += p->l, z += p->c[a]; // then search forwardly assert(p - u < u->n); if (v) v->c[a] += rl, v->l += rl; // we should not change p->c[a] because this may cause troubles when p's child is split v = p; p = p->p; // descend } while (!u->is_bottom); rope->c[a] += rl; // $rope->c should be updated after the loop as adding a new root needs the old $rope->c counts if (cache) { if (cache->p != (uint8_t*)p) memset(cache, 0, sizeof(rpcache_t)); n_runs = rle_insert_cached((uint8_t*)p, x - y, a, rl, cnt, v->c, &cache->beg, cache->bc); cache->p = (uint8_t*)p; } else n_runs = rle_insert((uint8_t*)p, x - y, a, rl, cnt, v->c); z += cnt[a]; v->c[a] += rl; v->l += rl; // this should be after rle_insert(); otherwise rle_insert() won't work if (n_runs + RLE_MIN_SPACE > rope->block_len) { split_node(rope, u, v); if (cache) memset(cache, 0, sizeof(rpcache_t)); } return z; } static rpnode_t *rope_count_to_leaf(const rope_t *rope, int64_t x, int64_t cx[6], int64_t *rest) { rpnode_t *u, *v = 0, *p = rope->root; int64_t y = 0; int a; memset(cx, 0, 48); do { u = p; if (v && x - y > v->l>>1) { p += p->n - 1; y += v->l; for (a = 0; a != 6; ++a) cx[a] += v->c[a]; for (; y >= x; --p) { y -= p->l; for (a = 0; a != 6; ++a) cx[a] -= p->c[a]; } ++p; } else { for (; y + p->l < x; ++p) { y += p->l; for (a = 0; a != 6; ++a) cx[a] += p->c[a]; } } v = p; p = p->p; } while (!u->is_bottom); *rest = x - y; return v; } void rope_rank2a(const rope_t *rope, int64_t x, int64_t y, int64_t *cx, int64_t *cy) { rpnode_t *v; int64_t rest; v = rope_count_to_leaf(rope, x, cx, &rest); if (y < x || cy == 0) { rle_rank1a((const uint8_t*)v->p, rest, cx, v->c); } else if (rest + (y - x) <= v->l) { memcpy(cy, cx, 48); rle_rank2a((const uint8_t*)v->p, rest, rest + (y - x), cx, cy, v->c); } else { rle_rank1a((const uint8_t*)v->p, rest, cx, v->c); v = rope_count_to_leaf(rope, y, cy, &rest); rle_rank1a((const uint8_t*)v->p, rest, cy, v->c); } } /********************* *** Rope iterator *** *********************/ void rope_itr_first(const rope_t *rope, rpitr_t *i) { memset(i, 0, sizeof(rpitr_t)); i->rope = rope; for (i->pa[i->d] = rope->root; !i->pa[i->d]->is_bottom;) // descend to the leftmost leaf ++i->d, i->pa[i->d] = i->pa[i->d - 1]->p; } const uint8_t *rope_itr_next_block(rpitr_t *i) { const uint8_t *ret; assert(i->d < ROPE_MAX_DEPTH); // a B+ tree should not be that tall if (i->d < 0) return 0; ret = (uint8_t*)i->pa[i->d][i->ia[i->d]].p; while (i->d >= 0 && ++i->ia[i->d] == i->pa[i->d]->n) i->ia[i->d--] = 0; // backtracking if (i->d >= 0) while (!i->pa[i->d]->is_bottom) // descend to the leftmost leaf ++i->d, i->pa[i->d] = i->pa[i->d - 1][i->ia[i->d - 1]].p; return ret; } /*********** *** I/O *** ***********/ void rope_print_node(const rpnode_t *p) { if (p->is_bottom) { int i; putchar('('); for (i = 0; i < p->n; ++i) { uint8_t *block = (uint8_t*)p[i].p; const uint8_t *q = block + 2, *end = block + 2 + *rle_nptr(block); if (i) putchar(','); while (q < end) { int c = 0; int64_t j, l; rle_dec1(q, c, l); for (j = 0; j < l; ++j) putchar("$ACGTN"[c]); } } putchar(')'); } else { int i; putchar('('); for (i = 0; i < p->n; ++i) { if (i) putchar(','); rope_print_node(p[i].p); } putchar(')'); } } void rope_dump_node(const rpnode_t *p, FILE *fp) { int16_t i, n = p->n; uint8_t is_bottom = p->is_bottom; fwrite(&is_bottom, 1, 1, fp); fwrite(&n, 2, 1, fp); if (is_bottom) { for (i = 0; i < n; ++i) { fwrite(p[i].c, 8, 6, fp); fwrite(p[i].p, 1, *rle_nptr(p[i].p) + 2, fp); } } else { for (i = 0; i < p->n; ++i) rope_dump_node(p[i].p, fp); } } void rope_dump(const rope_t *r, FILE *fp) { fwrite(&r->max_nodes, 4, 1, fp); fwrite(&r->block_len, 4, 1, fp); rope_dump_node(r->root, fp); } rpnode_t *rope_restore_node(const rope_t *r, FILE *fp, int64_t c[6]) { uint8_t is_bottom, a; int16_t i, n; rpnode_t *p; fread(&is_bottom, 1, 1, fp); fread(&n, 2, 1, fp); p = mp_alloc(r->node); p->is_bottom = is_bottom, p->n = n; if (is_bottom) { for (i = 0; i < n; ++i) { uint16_t *q; p[i].p = mp_alloc(r->leaf); q = rle_nptr(p[i].p); fread(p[i].c, 8, 6, fp); fread(q, 2, 1, fp); fread(q + 1, 1, *q, fp); } } else { for (i = 0; i < n; ++i) p[i].p = rope_restore_node(r, fp, p[i].c); } memset(c, 0, 48); for (i = 0; i < n; ++i) { p[i].l = 0; for (a = 0; a < 6; ++a) c[a] += p[i].c[a], p[i].l += p[i].c[a]; } return p; } rope_t *rope_restore(FILE *fp) { rope_t *r; r = calloc(1, sizeof(rope_t)); fread(&r->max_nodes, 4, 1, fp); fread(&r->block_len, 4, 1, fp); r->node = mp_init(sizeof(rpnode_t) * r->max_nodes); r->leaf = mp_init(r->block_len); r->root = rope_restore_node(r, fp, r->c); return r; }