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|
// This is an open source non-commercial project. Dear PVS-Studio, please check
// it. PVS-Studio Static Code Analyzer for C, C++ and C#: http://www.viva64.com
// Tree data structure for storing marks at (row, col) positions and updating
// them to arbitrary text changes. Derivative work of kbtree in klib, whose
// copyright notice is reproduced below. Also inspired by the design of the
// marker tree data structure of the Atom editor, regarding efficient updates
// to text changes.
//
// Marks are inserted using marktree_put. Text changes are processed using
// marktree_splice. All read and delete operations use the iterator.
// use marktree_itr_get to put an iterator at a given position or
// marktree_lookup to lookup a mark by its id (iterator optional in this case).
// Use marktree_itr_current and marktree_itr_next/prev to read marks in a loop.
// marktree_del_itr deletes the current mark of the iterator and implicitly
// moves the iterator to the next mark.
//
// Work is ongoing to fully support ranges (mark pairs).
// Copyright notice for kbtree (included in heavily modified form):
//
// Copyright 1997-1999, 2001, John-Mark Gurney.
// 2008-2009, Attractive Chaos <attractor@live.co.uk>
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
//
// 1. Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// 2. Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimer in the
// documentation and/or other materials provided with the distribution.
//
// THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
// ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
// FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
// DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
// OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
// HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
// LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
// OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
// SUCH DAMAGE.
//
// Changes done by by the neovim project follow the Apache v2 license available
// at the repo root.
#include <assert.h>
#include "klib/kvec.h"
#include "nvim/garray.h"
#include "nvim/marktree.h"
#define T MT_BRANCH_FACTOR
#define ILEN (sizeof(mtnode_t) + (2 * T) * sizeof(void *))
#define ID_INCR (((uint64_t)1) << 2)
#define rawkey(itr) ((itr)->node->key[(itr)->i])
static bool pos_leq(mtpos_t a, mtpos_t b)
{
return a.row < b.row || (a.row == b.row && a.col <= b.col);
}
static void relative(mtpos_t base, mtpos_t *val)
{
assert(pos_leq(base, *val));
if (val->row == base.row) {
val->row = 0;
val->col -= base.col;
} else {
val->row -= base.row;
}
}
static void unrelative(mtpos_t base, mtpos_t *val)
{
if (val->row == 0) {
val->row = base.row;
val->col += base.col;
} else {
val->row += base.row;
}
}
static void compose(mtpos_t *base, mtpos_t val)
{
if (val.row == 0) {
base->col += val.col;
} else {
base->row += val.row;
base->col = val.col;
}
}
#ifdef INCLUDE_GENERATED_DECLARATIONS
# include "marktree.c.generated.h"
#endif
#define mt_generic_cmp(a, b) (((b) < (a)) - ((a) < (b)))
static int key_cmp(mtkey_t a, mtkey_t b)
{
int cmp = mt_generic_cmp(a.pos.row, b.pos.row);
if (cmp != 0) {
return cmp;
}
cmp = mt_generic_cmp(a.pos.col, b.pos.col);
if (cmp != 0) {
return cmp;
}
// NB: keeping the events at the same pos sorted by id is actually not
// necessary only make sure that START is before END etc.
return mt_generic_cmp(a.flags, b.flags);
}
static inline int marktree_getp_aux(const mtnode_t *x, mtkey_t k, int *r)
{
int tr, *rr, begin = 0, end = x->n;
if (x->n == 0) {
return -1;
}
rr = r? r : &tr;
while (begin < end) {
int mid = (begin + end) >> 1;
if (key_cmp(x->key[mid], k) < 0) {
begin = mid + 1;
} else {
end = mid;
}
}
if (begin == x->n) {
*rr = 1; return x->n - 1;
}
if ((*rr = key_cmp(k, x->key[begin])) < 0) {
begin--;
}
return begin;
}
static inline void refkey(MarkTree *b, mtnode_t *x, int i)
{
pmap_put(uint64_t)(b->id2node, mt_lookup_key(x->key[i]), x);
}
// put functions
// x must be an internal node, which is not full
// x->ptr[i] should be a full node, i e x->ptr[i]->n == 2*T-1
static inline void split_node(MarkTree *b, mtnode_t *x, const int i)
{
mtnode_t *y = x->ptr[i];
mtnode_t *z;
z = (mtnode_t *)xcalloc(1, y->level ? ILEN : sizeof(mtnode_t));
b->n_nodes++;
z->level = y->level;
z->n = T - 1;
memcpy(z->key, &y->key[T], sizeof(mtkey_t) * (T - 1));
for (int j = 0; j < T - 1; j++) {
refkey(b, z, j);
}
if (y->level) {
memcpy(z->ptr, &y->ptr[T], sizeof(mtnode_t *) * T);
for (int j = 0; j < T; j++) {
z->ptr[j]->parent = z;
}
}
y->n = T - 1;
memmove(&x->ptr[i + 2], &x->ptr[i + 1],
sizeof(mtnode_t *) * (size_t)(x->n - i));
x->ptr[i + 1] = z;
z->parent = x; // == y->parent
memmove(&x->key[i + 1], &x->key[i], sizeof(mtkey_t) * (size_t)(x->n - i));
// move key to internal layer:
x->key[i] = y->key[T - 1];
refkey(b, x, i);
x->n++;
for (int j = 0; j < T - 1; j++) {
relative(x->key[i].pos, &z->key[j].pos);
}
if (i > 0) {
unrelative(x->key[i - 1].pos, &x->key[i].pos);
}
}
// x must not be a full node (even if there might be internal space)
static inline void marktree_putp_aux(MarkTree *b, mtnode_t *x, mtkey_t k)
{
int i;
if (x->level == 0) {
i = marktree_getp_aux(x, k, 0);
if (i != x->n - 1) {
memmove(&x->key[i + 2], &x->key[i + 1],
(size_t)(x->n - i - 1) * sizeof(mtkey_t));
}
x->key[i + 1] = k;
refkey(b, x, i + 1);
x->n++;
} else {
i = marktree_getp_aux(x, k, 0) + 1;
if (x->ptr[i]->n == 2 * T - 1) {
split_node(b, x, i);
if (key_cmp(k, x->key[i]) > 0) {
i++;
}
}
if (i > 0) {
relative(x->key[i - 1].pos, &k.pos);
}
marktree_putp_aux(b, x->ptr[i], k);
}
}
void marktree_put(MarkTree *b, mtkey_t key, int end_row, int end_col, bool end_right)
{
assert(!(key.flags & ~MT_FLAG_EXTERNAL_MASK));
if (end_row >= 0) {
key.flags |= MT_FLAG_PAIRED;
}
marktree_put_key(b, key);
if (end_row >= 0) {
mtkey_t end_key = key;
end_key.flags = (uint16_t)((uint16_t)(key.flags & ~MT_FLAG_RIGHT_GRAVITY)
|(uint16_t)MT_FLAG_END
|(uint16_t)(end_right ? MT_FLAG_RIGHT_GRAVITY : 0));
end_key.pos = (mtpos_t){ end_row, end_col };
marktree_put_key(b, end_key);
}
}
void marktree_put_key(MarkTree *b, mtkey_t k)
{
k.flags |= MT_FLAG_REAL; // let's be real.
if (!b->root) {
b->root = (mtnode_t *)xcalloc(1, ILEN);
b->n_nodes++;
}
mtnode_t *r, *s;
b->n_keys++;
r = b->root;
if (r->n == 2 * T - 1) {
b->n_nodes++;
s = (mtnode_t *)xcalloc(1, ILEN);
b->root = s; s->level = r->level + 1; s->n = 0;
s->ptr[0] = r;
r->parent = s;
split_node(b, s, 0);
r = s;
}
marktree_putp_aux(b, r, k);
}
/// INITIATING DELETION PROTOCOL:
///
/// 1. Construct a valid iterator to the node to delete (argument)
/// 2. If an "internal" key. Iterate one step to the left or right,
/// which gives an internal key "auxiliary key".
/// 3. Now delete this internal key (intended or auxiliary).
/// The leaf node X might become undersized.
/// 4. If step two was done: now replace the key that _should_ be
/// deleted with the auxiliary key. Adjust relative
/// 5. Now "repair" the tree as needed. We always start at a leaf node X.
/// - if the node is big enough, terminate
/// - if we can steal from the left, steal
/// - if we can steal from the right, steal
/// - otherwise merge this node with a neighbour. This might make our
/// parent undersized. So repeat 5 for the parent.
/// 6. If 4 went all the way to the root node. The root node
/// might have ended up with size 0. Delete it then.
///
/// NB: ideally keeps the iterator valid. Like point to the key after this
/// if present.
///
/// @param rev should be true if we plan to iterate _backwards_ and delete
/// stuff before this key. Most of the time this is false (the
/// recommended strategy is to always iterate forward)
void marktree_del_itr(MarkTree *b, MarkTreeIter *itr, bool rev)
{
int adjustment = 0;
mtnode_t *cur = itr->node;
int curi = itr->i;
uint64_t id = mt_lookup_key(cur->key[curi]);
// fprintf(stderr, "\nDELET %lu\n", id);
if (itr->node->level) {
if (rev) {
abort();
} else {
// fprintf(stderr, "INTERNAL %d\n", cur->level);
// steal previous node
marktree_itr_prev(b, itr);
adjustment = -1;
}
}
// 3.
mtnode_t *x = itr->node;
assert(x->level == 0);
mtkey_t intkey = x->key[itr->i];
if (x->n > itr->i + 1) {
memmove(&x->key[itr->i], &x->key[itr->i + 1],
sizeof(mtkey_t) * (size_t)(x->n - itr->i - 1));
}
x->n--;
// 4.
// if (adjustment == 1) {
// abort();
// }
if (adjustment == -1) {
int ilvl = itr->lvl - 1;
const mtnode_t *lnode = x;
do {
const mtnode_t *const p = lnode->parent;
if (ilvl < 0) {
abort();
}
const int i = itr->s[ilvl].i;
assert(p->ptr[i] == lnode);
if (i > 0) {
unrelative(p->key[i - 1].pos, &intkey.pos);
}
lnode = p;
ilvl--;
} while (lnode != cur);
mtkey_t deleted = cur->key[curi];
cur->key[curi] = intkey;
refkey(b, cur, curi);
relative(intkey.pos, &deleted.pos);
mtnode_t *y = cur->ptr[curi + 1];
if (deleted.pos.row || deleted.pos.col) {
while (y) {
for (int k = 0; k < y->n; k++) {
unrelative(deleted.pos, &y->key[k].pos);
}
y = y->level ? y->ptr[0] : NULL;
}
}
itr->i--;
}
b->n_keys--;
pmap_del(uint64_t)(b->id2node, id);
// 5.
bool itr_dirty = false;
int rlvl = itr->lvl - 1;
int *lasti = &itr->i;
while (x != b->root) {
assert(rlvl >= 0);
mtnode_t *p = x->parent;
if (x->n >= T - 1) {
// we are done, if this node is fine the rest of the tree will be
break;
}
int pi = itr->s[rlvl].i;
assert(p->ptr[pi] == x);
if (pi > 0 && p->ptr[pi - 1]->n > T - 1) {
*lasti += 1;
itr_dirty = true;
// steal one key from the left neighbour
pivot_right(b, p, pi - 1);
break;
} else if (pi < p->n && p->ptr[pi + 1]->n > T - 1) {
// steal one key from right neighbour
pivot_left(b, p, pi);
break;
} else if (pi > 0) {
// fprintf(stderr, "LEFT ");
assert(p->ptr[pi - 1]->n == T - 1);
// merge with left neighbour
*lasti += T;
x = merge_node(b, p, pi - 1);
if (lasti == &itr->i) {
// TRICKY: we merged the node the iterator was on
itr->node = x;
}
itr->s[rlvl].i--;
itr_dirty = true;
} else {
// fprintf(stderr, "RIGHT ");
assert(pi < p->n && p->ptr[pi + 1]->n == T - 1);
merge_node(b, p, pi);
// no iter adjustment needed
}
lasti = &itr->s[rlvl].i;
rlvl--;
x = p;
}
// 6.
if (b->root->n == 0) {
if (itr->lvl > 0) {
memmove(itr->s, itr->s + 1, (size_t)(itr->lvl - 1) * sizeof(*itr->s));
itr->lvl--;
}
if (b->root->level) {
mtnode_t *oldroot = b->root;
b->root = b->root->ptr[0];
b->root->parent = NULL;
xfree(oldroot);
} else {
// no items, nothing for iterator to point to
// not strictly needed, should handle delete right-most mark anyway
itr->node = NULL;
}
}
if (itr->node && itr_dirty) {
marktree_itr_fix_pos(b, itr);
}
// BONUS STEP: fix the iterator, so that it points to the key afterwards
// TODO(bfredl): with "rev" should point before
// if (adjustment == 1) {
// abort();
// }
if (adjustment == -1) {
// tricky: we stand at the deleted space in the previous leaf node.
// But the inner key is now the previous key we stole, so we need
// to skip that one as well.
marktree_itr_next(b, itr);
marktree_itr_next(b, itr);
} else {
if (itr->node && itr->i >= itr->node->n) {
// we deleted the last key of a leaf node
// go to the inner key after that.
assert(itr->node->level == 0);
marktree_itr_next(b, itr);
}
}
}
static mtnode_t *merge_node(MarkTree *b, mtnode_t *p, int i)
{
mtnode_t *x = p->ptr[i], *y = p->ptr[i + 1];
x->key[x->n] = p->key[i];
refkey(b, x, x->n);
if (i > 0) {
relative(p->key[i - 1].pos, &x->key[x->n].pos);
}
memmove(&x->key[x->n + 1], y->key, (size_t)y->n * sizeof(mtkey_t));
for (int k = 0; k < y->n; k++) {
refkey(b, x, x->n + 1 + k);
unrelative(x->key[x->n].pos, &x->key[x->n + 1 + k].pos);
}
if (x->level) {
memmove(&x->ptr[x->n + 1], y->ptr, ((size_t)y->n + 1) * sizeof(mtnode_t *));
for (int k = 0; k < y->n + 1; k++) {
x->ptr[x->n + k + 1]->parent = x;
}
}
x->n += y->n + 1;
memmove(&p->key[i], &p->key[i + 1], (size_t)(p->n - i - 1) * sizeof(mtkey_t));
memmove(&p->ptr[i + 1], &p->ptr[i + 2],
(size_t)(p->n - i - 1) * sizeof(mtkey_t *));
p->n--;
xfree(y);
b->n_nodes--;
return x;
}
// TODO(bfredl): as a potential "micro" optimization, pivoting should balance
// the two nodes instead of stealing just one key
static void pivot_right(MarkTree *b, mtnode_t *p, int i)
{
mtnode_t *x = p->ptr[i], *y = p->ptr[i + 1];
memmove(&y->key[1], y->key, (size_t)y->n * sizeof(mtkey_t));
if (y->level) {
memmove(&y->ptr[1], y->ptr, ((size_t)y->n + 1) * sizeof(mtnode_t *));
}
y->key[0] = p->key[i];
refkey(b, y, 0);
p->key[i] = x->key[x->n - 1];
refkey(b, p, i);
if (x->level) {
y->ptr[0] = x->ptr[x->n];
y->ptr[0]->parent = y;
}
x->n--;
y->n++;
if (i > 0) {
unrelative(p->key[i - 1].pos, &p->key[i].pos);
}
relative(p->key[i].pos, &y->key[0].pos);
for (int k = 1; k < y->n; k++) {
unrelative(y->key[0].pos, &y->key[k].pos);
}
}
static void pivot_left(MarkTree *b, mtnode_t *p, int i)
{
mtnode_t *x = p->ptr[i], *y = p->ptr[i + 1];
// reverse from how we "always" do it. but pivot_left
// is just the inverse of pivot_right, so reverse it literally.
for (int k = 1; k < y->n; k++) {
relative(y->key[0].pos, &y->key[k].pos);
}
unrelative(p->key[i].pos, &y->key[0].pos);
if (i > 0) {
relative(p->key[i - 1].pos, &p->key[i].pos);
}
x->key[x->n] = p->key[i];
refkey(b, x, x->n);
p->key[i] = y->key[0];
refkey(b, p, i);
if (x->level) {
x->ptr[x->n + 1] = y->ptr[0];
x->ptr[x->n + 1]->parent = x;
}
memmove(y->key, &y->key[1], (size_t)(y->n - 1) * sizeof(mtkey_t));
if (y->level) {
memmove(y->ptr, &y->ptr[1], (size_t)y->n * sizeof(mtnode_t *));
}
x->n++;
y->n--;
}
/// frees all mem, resets tree to valid empty state
void marktree_clear(MarkTree *b)
{
if (b->root) {
marktree_free_node(b->root);
b->root = NULL;
}
if (b->id2node->table.keys) {
pmap_destroy(uint64_t)(b->id2node);
pmap_init(uint64_t, b->id2node);
}
b->n_keys = 0;
b->n_nodes = 0;
}
void marktree_free_node(mtnode_t *x)
{
if (x->level) {
for (int i = 0; i < x->n + 1; i++) {
marktree_free_node(x->ptr[i]);
}
}
xfree(x);
}
/// NB: caller must check not pair!
void marktree_revise(MarkTree *b, MarkTreeIter *itr, uint8_t decor_level, mtkey_t key)
{
// TODO(bfredl): clean up this mess and re-instantiate &= and |= forms
// once we upgrade to a non-broken version of gcc in functionaltest-lua CI
rawkey(itr).flags = (uint16_t)(rawkey(itr).flags & (uint16_t) ~MT_FLAG_DECOR_MASK);
rawkey(itr).flags = (uint16_t)(rawkey(itr).flags
| (uint16_t)(decor_level << MT_FLAG_DECOR_OFFSET)
| (uint16_t)(key.flags & MT_FLAG_DECOR_MASK));
rawkey(itr).decor_full = key.decor_full;
rawkey(itr).hl_id = key.hl_id;
rawkey(itr).priority = key.priority;
}
void marktree_move(MarkTree *b, MarkTreeIter *itr, int row, int col)
{
mtkey_t key = rawkey(itr);
// TODO(bfredl): optimize when moving a mark within a leaf without moving it
// across neighbours!
marktree_del_itr(b, itr, false);
key.pos = (mtpos_t){ row, col };
marktree_put_key(b, key);
itr->node = NULL; // itr might become invalid by put
}
// itr functions
// TODO(bfredl): static inline?
bool marktree_itr_get(MarkTree *b, int32_t row, int col, MarkTreeIter *itr)
{
return marktree_itr_get_ext(b, (mtpos_t){ row, col },
itr, false, false, NULL);
}
bool marktree_itr_get_ext(MarkTree *b, mtpos_t p, MarkTreeIter *itr, bool last, bool gravity,
mtpos_t *oldbase)
{
if (b->n_keys == 0) {
itr->node = NULL;
return false;
}
mtkey_t k = { .pos = p, .flags = gravity ? MT_FLAG_RIGHT_GRAVITY : 0 };
if (last && !gravity) {
k.flags = MT_FLAG_LAST;
}
itr->pos = (mtpos_t){ 0, 0 };
itr->node = b->root;
itr->lvl = 0;
if (oldbase) {
oldbase[itr->lvl] = itr->pos;
}
while (true) {
itr->i = marktree_getp_aux(itr->node, k, 0) + 1;
if (itr->node->level == 0) {
break;
}
itr->s[itr->lvl].i = itr->i;
itr->s[itr->lvl].oldcol = itr->pos.col;
if (itr->i > 0) {
compose(&itr->pos, itr->node->key[itr->i - 1].pos);
relative(itr->node->key[itr->i - 1].pos, &k.pos);
}
itr->node = itr->node->ptr[itr->i];
itr->lvl++;
if (oldbase) {
oldbase[itr->lvl] = itr->pos;
}
}
if (last) {
return marktree_itr_prev(b, itr);
} else if (itr->i >= itr->node->n) {
return marktree_itr_next(b, itr);
}
return true;
}
bool marktree_itr_first(MarkTree *b, MarkTreeIter *itr)
{
itr->node = b->root;
if (b->n_keys == 0) {
return false;
}
itr->i = 0;
itr->lvl = 0;
itr->pos = (mtpos_t){ 0, 0 };
while (itr->node->level > 0) {
itr->s[itr->lvl].i = 0;
itr->s[itr->lvl].oldcol = 0;
itr->lvl++;
itr->node = itr->node->ptr[0];
}
return true;
}
// gives the first key that is greater or equal to p
int marktree_itr_last(MarkTree *b, MarkTreeIter *itr)
{
if (b->n_keys == 0) {
itr->node = NULL;
return false;
}
itr->pos = (mtpos_t){ 0, 0 };
itr->node = b->root;
itr->lvl = 0;
while (true) {
itr->i = itr->node->n;
if (itr->node->level == 0) {
break;
}
itr->s[itr->lvl].i = itr->i;
itr->s[itr->lvl].oldcol = itr->pos.col;
assert(itr->i > 0);
compose(&itr->pos, itr->node->key[itr->i - 1].pos);
itr->node = itr->node->ptr[itr->i];
itr->lvl++;
}
itr->i--;
return true;
}
// TODO(bfredl): static inline
bool marktree_itr_next(MarkTree *b, MarkTreeIter *itr)
{
return marktree_itr_next_skip(b, itr, false, NULL);
}
static bool marktree_itr_next_skip(MarkTree *b, MarkTreeIter *itr, bool skip, mtpos_t oldbase[])
{
if (!itr->node) {
return false;
}
itr->i++;
if (itr->node->level == 0 || skip) {
if (itr->i < itr->node->n) {
// TODO(bfredl): this is the common case,
// and could be handled by inline wrapper
return true;
}
// we ran out of non-internal keys. Go up until we find an internal key
while (itr->i >= itr->node->n) {
itr->node = itr->node->parent;
if (itr->node == NULL) {
return false;
}
itr->lvl--;
itr->i = itr->s[itr->lvl].i;
if (itr->i > 0) {
itr->pos.row -= itr->node->key[itr->i - 1].pos.row;
itr->pos.col = itr->s[itr->lvl].oldcol;
}
}
} else {
// we stood at an "internal" key. Go down to the first non-internal
// key after it.
while (itr->node->level > 0) {
// internal key, there is always a child after
if (itr->i > 0) {
itr->s[itr->lvl].oldcol = itr->pos.col;
compose(&itr->pos, itr->node->key[itr->i - 1].pos);
}
if (oldbase && itr->i == 0) {
oldbase[itr->lvl + 1] = oldbase[itr->lvl];
}
itr->s[itr->lvl].i = itr->i;
assert(itr->node->ptr[itr->i]->parent == itr->node);
itr->node = itr->node->ptr[itr->i];
itr->i = 0;
itr->lvl++;
}
}
return true;
}
bool marktree_itr_prev(MarkTree *b, MarkTreeIter *itr)
{
if (!itr->node) {
return false;
}
if (itr->node->level == 0) {
itr->i--;
if (itr->i >= 0) {
// TODO(bfredl): this is the common case,
// and could be handled by inline wrapper
return true;
}
// we ran out of non-internal keys. Go up until we find a non-internal key
while (itr->i < 0) {
itr->node = itr->node->parent;
if (itr->node == NULL) {
return false;
}
itr->lvl--;
itr->i = itr->s[itr->lvl].i - 1;
if (itr->i >= 0) {
itr->pos.row -= itr->node->key[itr->i].pos.row;
itr->pos.col = itr->s[itr->lvl].oldcol;
}
}
} else {
// we stood at an "internal" key. Go down to the last non-internal
// key before it.
while (itr->node->level > 0) {
// internal key, there is always a child before
if (itr->i > 0) {
itr->s[itr->lvl].oldcol = itr->pos.col;
compose(&itr->pos, itr->node->key[itr->i - 1].pos);
}
itr->s[itr->lvl].i = itr->i;
assert(itr->node->ptr[itr->i]->parent == itr->node);
itr->node = itr->node->ptr[itr->i];
itr->i = itr->node->n;
itr->lvl++;
}
itr->i--;
}
return true;
}
void marktree_itr_rewind(MarkTree *b, MarkTreeIter *itr)
{
if (!itr->node) {
return;
}
if (itr->node->level) {
marktree_itr_prev(b, itr);
}
itr->i = 0;
}
bool marktree_itr_node_done(MarkTreeIter *itr)
{
return !itr->node || itr->i == itr->node->n - 1;
}
mtpos_t marktree_itr_pos(MarkTreeIter *itr)
{
mtpos_t pos = rawkey(itr).pos;
unrelative(itr->pos, &pos);
return pos;
}
mtkey_t marktree_itr_current(MarkTreeIter *itr)
{
if (itr->node) {
mtkey_t key = rawkey(itr);
key.pos = marktree_itr_pos(itr);
return key;
}
return MT_INVALID_KEY;
}
static bool itr_eq(MarkTreeIter *itr1, MarkTreeIter *itr2)
{
return (&rawkey(itr1) == &rawkey(itr2));
}
static void itr_swap(MarkTreeIter *itr1, MarkTreeIter *itr2)
{
mtkey_t key1 = rawkey(itr1);
mtkey_t key2 = rawkey(itr2);
rawkey(itr1) = key2;
rawkey(itr1).pos = key1.pos;
rawkey(itr2) = key1;
rawkey(itr2).pos = key2.pos;
}
bool marktree_splice(MarkTree *b, int32_t start_line, int start_col, int old_extent_line,
int old_extent_col, int new_extent_line, int new_extent_col)
{
mtpos_t start = { start_line, start_col };
mtpos_t old_extent = { old_extent_line, old_extent_col };
mtpos_t new_extent = { new_extent_line, new_extent_col };
bool may_delete = (old_extent.row != 0 || old_extent.col != 0);
bool same_line = old_extent.row == 0 && new_extent.row == 0;
unrelative(start, &old_extent);
unrelative(start, &new_extent);
MarkTreeIter itr[1] = { 0 };
MarkTreeIter enditr[1] = { 0 };
mtpos_t oldbase[MT_MAX_DEPTH] = { 0 };
marktree_itr_get_ext(b, start, itr, false, true, oldbase);
if (!itr->node) {
// den e FÄRDIG
return false;
}
mtpos_t delta = { new_extent.row - old_extent.row,
new_extent.col - old_extent.col };
if (may_delete) {
mtpos_t ipos = marktree_itr_pos(itr);
if (!pos_leq(old_extent, ipos)
|| (old_extent.row == ipos.row && old_extent.col == ipos.col
&& !mt_right(rawkey(itr)))) {
marktree_itr_get_ext(b, old_extent, enditr, true, true, NULL);
assert(enditr->node);
// "assert" (itr <= enditr)
} else {
may_delete = false;
}
}
bool past_right = false;
bool moved = false;
// Follow the general strategy of messing things up and fix them later
// "oldbase" carries the information needed to calculate old position of
// children.
if (may_delete) {
while (itr->node && !past_right) {
mtpos_t loc_start = start;
mtpos_t loc_old = old_extent;
relative(itr->pos, &loc_start);
relative(oldbase[itr->lvl], &loc_old);
continue_same_node:
// NB: strictly should be less than the right gravity of loc_old, but
// the iter comparison below will already break on that.
if (!pos_leq(rawkey(itr).pos, loc_old)) {
break;
}
if (mt_right(rawkey(itr))) {
while (!itr_eq(itr, enditr)
&& mt_right(rawkey(enditr))) {
marktree_itr_prev(b, enditr);
}
if (!mt_right(rawkey(enditr))) {
itr_swap(itr, enditr);
refkey(b, itr->node, itr->i);
refkey(b, enditr->node, enditr->i);
} else {
past_right = true; // NOLINT
(void)past_right;
break;
}
}
if (itr_eq(itr, enditr)) {
// actually, will be past_right after this key
past_right = true;
}
moved = true;
if (itr->node->level) {
oldbase[itr->lvl + 1] = rawkey(itr).pos;
unrelative(oldbase[itr->lvl], &oldbase[itr->lvl + 1]);
rawkey(itr).pos = loc_start;
marktree_itr_next_skip(b, itr, false, oldbase);
} else {
rawkey(itr).pos = loc_start;
if (itr->i < itr->node->n - 1) {
itr->i++;
if (!past_right) {
goto continue_same_node;
}
} else {
marktree_itr_next(b, itr);
}
}
}
while (itr->node) {
mtpos_t loc_new = new_extent;
relative(itr->pos, &loc_new);
mtpos_t limit = old_extent;
relative(oldbase[itr->lvl], &limit);
past_continue_same_node:
if (pos_leq(limit, rawkey(itr).pos)) {
break;
}
mtpos_t oldpos = rawkey(itr).pos;
rawkey(itr).pos = loc_new;
moved = true;
if (itr->node->level) {
oldbase[itr->lvl + 1] = oldpos;
unrelative(oldbase[itr->lvl], &oldbase[itr->lvl + 1]);
marktree_itr_next_skip(b, itr, false, oldbase);
} else {
if (itr->i < itr->node->n - 1) {
itr->i++;
goto past_continue_same_node;
} else {
marktree_itr_next(b, itr);
}
}
}
}
while (itr->node) {
unrelative(oldbase[itr->lvl], &rawkey(itr).pos);
int realrow = rawkey(itr).pos.row;
assert(realrow >= old_extent.row);
bool done = false;
if (realrow == old_extent.row) {
if (delta.col) {
rawkey(itr).pos.col += delta.col;
moved = true;
}
} else {
if (same_line) {
// optimization: column only adjustment can skip remaining rows
done = true;
}
}
if (delta.row) {
rawkey(itr).pos.row += delta.row;
moved = true;
}
relative(itr->pos, &rawkey(itr).pos);
if (done) {
break;
}
marktree_itr_next_skip(b, itr, true, NULL);
}
return moved;
}
void marktree_move_region(MarkTree *b, int start_row, colnr_T start_col, int extent_row,
colnr_T extent_col, int new_row, colnr_T new_col)
{
mtpos_t start = { start_row, start_col }, size = { extent_row, extent_col };
mtpos_t end = size;
unrelative(start, &end);
MarkTreeIter itr[1] = { 0 };
marktree_itr_get_ext(b, start, itr, false, true, NULL);
kvec_t(mtkey_t) saved = KV_INITIAL_VALUE;
while (itr->node) {
mtkey_t k = marktree_itr_current(itr);
if (!pos_leq(k.pos, end) || (k.pos.row == end.row && k.pos.col == end.col
&& mt_right(k))) {
break;
}
relative(start, &k.pos);
kv_push(saved, k);
marktree_del_itr(b, itr, false);
}
marktree_splice(b, start.row, start.col, size.row, size.col, 0, 0);
mtpos_t new = { new_row, new_col };
marktree_splice(b, new.row, new.col,
0, 0, size.row, size.col);
for (size_t i = 0; i < kv_size(saved); i++) {
mtkey_t item = kv_A(saved, i);
unrelative(new, &item.pos);
marktree_put_key(b, item);
}
kv_destroy(saved);
}
/// @param itr OPTIONAL. set itr to pos.
mtkey_t marktree_lookup_ns(MarkTree *b, uint32_t ns, uint32_t id, bool end, MarkTreeIter *itr)
{
return marktree_lookup(b, mt_lookup_id(ns, id, end), itr);
}
/// @param itr OPTIONAL. set itr to pos.
mtkey_t marktree_lookup(MarkTree *b, uint64_t id, MarkTreeIter *itr)
{
mtnode_t *n = pmap_get(uint64_t)(b->id2node, id);
if (n == NULL) {
if (itr) {
itr->node = NULL;
}
return MT_INVALID_KEY;
}
int i = 0;
for (i = 0; i < n->n; i++) {
if (mt_lookup_key(n->key[i]) == id) {
goto found;
}
}
abort();
found: {}
mtkey_t key = n->key[i];
if (itr) {
itr->i = i;
itr->node = n;
itr->lvl = b->root->level - n->level;
}
while (n->parent != NULL) {
mtnode_t *p = n->parent;
for (i = 0; i < p->n + 1; i++) {
if (p->ptr[i] == n) {
goto found_node;
}
}
abort();
found_node:
if (itr) {
itr->s[b->root->level - p->level].i = i;
}
if (i > 0) {
unrelative(p->key[i - 1].pos, &key.pos);
}
n = p;
}
if (itr) {
marktree_itr_fix_pos(b, itr);
}
return key;
}
mtpos_t marktree_get_altpos(MarkTree *b, mtkey_t mark, MarkTreeIter *itr)
{
return marktree_get_alt(b, mark, itr).pos;
}
mtkey_t marktree_get_alt(MarkTree *b, mtkey_t mark, MarkTreeIter *itr)
{
mtkey_t end = MT_INVALID_KEY;
if (mt_paired(mark)) {
end = marktree_lookup_ns(b, mark.ns, mark.id, !mt_end(mark), itr);
}
return end;
}
static void marktree_itr_fix_pos(MarkTree *b, MarkTreeIter *itr)
{
itr->pos = (mtpos_t){ 0, 0 };
mtnode_t *x = b->root;
for (int lvl = 0; lvl < itr->lvl; lvl++) {
itr->s[lvl].oldcol = itr->pos.col;
int i = itr->s[lvl].i;
if (i > 0) {
compose(&itr->pos, x->key[i - 1].pos);
}
assert(x->level);
x = x->ptr[i];
}
assert(x == itr->node);
}
// for unit test
void marktree_put_test(MarkTree *b, uint32_t id, int row, int col, bool right_gravity)
{
mtkey_t key = { { row, col }, UINT32_MAX, id, 0,
mt_flags(right_gravity, 0), 0, NULL };
marktree_put(b, key, -1, -1, false);
}
// for unit test
bool mt_right_test(mtkey_t key)
{
return mt_right(key);
}
void marktree_check(MarkTree *b)
{
#ifndef NDEBUG
if (b->root == NULL) {
assert(b->n_keys == 0);
assert(b->n_nodes == 0);
assert(b->id2node == NULL || map_size(b->id2node) == 0);
return;
}
mtpos_t dummy;
bool last_right = false;
size_t nkeys = check_node(b, b->root, &dummy, &last_right);
assert(b->n_keys == nkeys);
assert(b->n_keys == map_size(b->id2node));
#else
// Do nothing, as assertions are required
(void)b;
#endif
}
#ifndef NDEBUG
static size_t check_node(MarkTree *b, mtnode_t *x, mtpos_t *last, bool *last_right)
{
assert(x->n <= 2 * T - 1);
// TODO(bfredl): too strict if checking "in repair" post-delete tree.
assert(x->n >= (x != b->root ? T - 1 : 0));
size_t n_keys = (size_t)x->n;
for (int i = 0; i < x->n; i++) {
if (x->level) {
n_keys += check_node(b, x->ptr[i], last, last_right);
} else {
*last = (mtpos_t) { 0, 0 };
}
if (i > 0) {
unrelative(x->key[i - 1].pos, last);
}
assert(pos_leq(*last, x->key[i].pos));
if (last->row == x->key[i].pos.row && last->col == x->key[i].pos.col) {
assert(!*last_right || mt_right(x->key[i]));
}
*last_right = mt_right(x->key[i]);
assert(x->key[i].pos.col >= 0);
assert(pmap_get(uint64_t)(b->id2node, mt_lookup_key(x->key[i])) == x);
}
if (x->level) {
n_keys += check_node(b, x->ptr[x->n], last, last_right);
unrelative(x->key[x->n - 1].pos, last);
for (int i = 0; i < x->n + 1; i++) {
assert(x->ptr[i]->parent == x);
assert(x->ptr[i]->level == x->level - 1);
// PARANOIA: check no double node ref
for (int j = 0; j < i; j++) {
assert(x->ptr[i] != x->ptr[j]);
}
}
} else {
*last = x->key[x->n - 1].pos;
}
return n_keys;
}
#endif
char *mt_inspect_rec(MarkTree *b)
{
garray_T ga;
ga_init(&ga, (int)sizeof(char), 80);
mtpos_t p = { 0, 0 };
mt_inspect_node(b, &ga, b->root, p);
return ga.ga_data;
}
void mt_inspect_node(MarkTree *b, garray_T *ga, mtnode_t *n, mtpos_t off)
{
static char buf[1024];
ga_concat(ga, "[");
if (n->level) {
mt_inspect_node(b, ga, n->ptr[0], off);
}
for (int i = 0; i < n->n; i++) {
mtpos_t p = n->key[i].pos;
unrelative(off, &p);
snprintf((char *)buf, sizeof(buf), "%d/%d", p.row, p.col);
ga_concat(ga, buf);
if (n->level) {
mt_inspect_node(b, ga, n->ptr[i + 1], p);
} else {
ga_concat(ga, ",");
}
}
ga_concat(ga, "]");
}
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