// This file is part of the thin-provisioning-tools source.
//
// thin-provisioning-tools is free software: you can redistribute it
// and/or modify it under the terms of the GNU General Public License
// as published by the Free Software Foundation, either version 3 of
// the License, or (at your option) any later version.
//
// thin-provisioning-tools is distributed in the hope that it will be
// useful, but WITHOUT ANY WARRANTY; without even the implied warranty
// of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License along
// with thin-provisioning-tools. If not, see
// .
namespace persistent_data {
template
btree_detail::shadow_child
btree::
create_shadow_child(internal_node &parent,
unsigned index)
{
block_address b = parent.value_at(index);
pair p = tm_.shadow(b, validator_);
write_ref &wr = p.first;
btree_detail::node_type type;
node_ref n = to_node(wr);
if (n.get_type() == btree_detail::INTERNAL) {
type = btree_detail::INTERNAL;
if (p.second)
n.inc_children(internal_rc_);
} else {
type = btree_detail::LEAF;
if (p.second) {
node_ref leaf = to_node(wr);
leaf.inc_children(rc_);
}
}
parent.set_value(index, wr.get_location());
return btree_detail::shadow_child(wr, type);
}
template
void
btree::
remove(key const &key)
{
using namespace btree_detail;
block_address block = root_;
unsigned index = 0;
shadow_spine spine(tm_, validator_);
bool need_remove = true;
for (unsigned level = 0; level < Levels - 1; ++level) {
need_remove = remove_location(spine, block,
key[level], &index,
internal_rc_);
if (!need_remove)
break;
internal_node n = spine.get_node();
block = n.value_at(index);
}
if (need_remove) {
need_remove = remove_location(spine, block,
key[Levels - 1], &index,
rc_);
if (need_remove) {
leaf_node leaf = spine.get_node();
leaf.delete_at(index);
}
}
root_ = spine.get_root();
}
template
template
bool
btree::
remove_location(btree_detail::shadow_spine &spine,
block_address block,
uint64_t key,
unsigned *index,
RC &leaf_rc)
{
using namespace btree_detail;
unsigned i = *index;
for (;;) {
bool inc = spine.step(block);
if (inc)
inc_children(spine, leaf_rc);
// patch up the parent to point to the new shadow
if (spine.has_parent()) {
internal_node p = spine.get_parent();
p.set_value(i, spine.get_block());
}
internal_node n = spine.get_node();
if (n.get_type() == btree_detail::LEAF) {
node_ref leaf = spine.get_node();
boost::optional idx = leaf.exact_search(key);
if (!idx)
return false;
*index = *idx;
return true;
}
bool r = rebalance_children(spine, key);
if (!r)
return false;
n = spine.get_node();
if (n.get_type() == btree_detail::LEAF) {
node_ref leaf = spine.get_node();
boost::optional idx = leaf.exact_search(key);
if (!idx)
return false;
*index = *idx;
return true;
}
i = n.lower_bound(key);
block = n.value_at(i);
}
return true;
}
template
template
bool
btree::
rebalance_children(btree_detail::shadow_spine &spine, uint64_t key)
{
internal_node n = spine.get_node();
if (n.get_nr_entries() == 1) {
block_address b = n.value_at(0);
read_ref child = tm_.read_lock(b, validator_);
// FIXME: is it safe?
::memcpy(n.raw(), child.data(), read_ref::BLOCK_SIZE);
tm_.get_sm()->dec(child.get_location());
return true;
}
int i = n.lower_bound(key);
if (i < 0)
return false;
bool has_left_sibling = i > 0;
bool has_right_sibling = static_cast(i) < (n.get_nr_entries() - 1);
if (!has_left_sibling)
rebalance2(spine, i);
else if (!has_right_sibling)
rebalance2(spine, i - 1);
else
rebalance3(spine, i - 1);
return true;
}
template
template
void
btree::
rebalance2(btree_detail::shadow_spine &spine, unsigned left_index)
{
internal_node parent = spine.get_node();
shadow_child left = create_shadow_child(parent, left_index);
shadow_child right = create_shadow_child(parent, left_index + 1);
// FIXME: ugly
if (left.get_type() == btree_detail::INTERNAL) {
internal_node l = left.get_node();
internal_node r = right.get_node();
__rebalance2(parent, l, r, left_index);
} else {
node_ref l = left.get_node();
node_ref r = right.get_node();
__rebalance2(parent, l, r, left_index);
}
}
template
template
void
btree::
__rebalance2(internal_node &parent,
node_ref &left,
node_ref &right,
unsigned left_index)
{
unsigned nr_left = left.get_nr_entries();
unsigned nr_right = right.get_nr_entries();
unsigned right_index = left_index + 1;
unsigned threshold = 2 * (left.merge_threshold() + 1);
if (nr_left + nr_right < threshold) {
// Merge the right child into the left
left.copy_entries_to_left(right, nr_right);
left.set_nr_entries(nr_left + nr_right);
parent.delete_at(right_index);
tm_.get_sm()->dec(right.get_location());
} else {
// Rebalance
unsigned target_left = (nr_left + nr_right) / 2;
left.move_entries(right, nr_left - target_left);
parent.set_key(right_index, right.key_at(0));
}
}
template
template
void
btree::
rebalance3(btree_detail::shadow_spine &spine, unsigned left_index)
{
internal_node parent = spine.get_node();
shadow_child left = create_shadow_child(parent, left_index);
shadow_child center = create_shadow_child(parent, left_index + 1);
shadow_child right = create_shadow_child(parent, left_index + 2);
// FIXME: ugly
if (left.get_type() == btree_detail::INTERNAL) {
internal_node l = left.get_node();
internal_node c = center.get_node();
internal_node r = right.get_node();
__rebalance3(parent, l, c, r, left_index);
} else {
node_ref l = left.get_node();
node_ref c = center.get_node();
node_ref r = right.get_node();
__rebalance3(parent, l, c, r, left_index);
}
}
template
template
void
btree::
__rebalance3(internal_node &parent,
node_ref &left,
node_ref ¢er,
node_ref &right,
unsigned left_index)
{
unsigned nr_left = left.get_nr_entries();
unsigned nr_center = center.get_nr_entries();
unsigned nr_right = right.get_nr_entries();
unsigned threshold = left.merge_threshold() * 4 + 1;
if ((nr_left + nr_center + nr_right) < threshold)
delete_center_node(parent, left, center, right, left_index);
else
redistribute3(parent, left, center, right, left_index);
}
template
template
void
btree::
delete_center_node(internal_node &parent,
node_ref &left,
node_ref ¢er,
node_ref &right,
unsigned left_index)
{
unsigned center_index = left_index + 1;
unsigned right_index = left_index + 2;
unsigned max_entries = left.get_max_entries();
unsigned nr_left = left.get_nr_entries();
unsigned nr_center = center.get_nr_entries();
unsigned nr_right = right.get_nr_entries();
unsigned shift = std::min(max_entries - nr_left, nr_center);
if (nr_left + shift > max_entries)
throw std::runtime_error("too many entries");
left.copy_entries_to_left(center, shift);
left.set_nr_entries(nr_left + shift);
if (shift != nr_center) {
shift = nr_center - shift;
if ((nr_right + shift) > max_entries)
throw std::runtime_error("too many entries");
right.shift_entries_right(shift);
center.copy_entries_to_right(right, shift);
right.set_nr_entries(nr_right + shift);
}
parent.set_key(right_index, right.key_at(0));
parent.delete_at(center_index);
--right_index;
tm_.get_sm()->dec(center.get_location());
__rebalance2(parent, left, right, left_index);
}
template
template
void
btree::
redistribute3(internal_node &parent,
node_ref &left,
node_ref ¢er,
node_ref &right,
unsigned left_index)
{
unsigned center_index = left_index + 1;
unsigned right_index = left_index + 2;
unsigned nr_left = left.get_nr_entries();
unsigned nr_center = center.get_nr_entries();
unsigned nr_right = right.get_nr_entries();
unsigned max_entries = left.get_max_entries();
unsigned total = nr_left + nr_center + nr_right;
unsigned target_right = total / 3;
unsigned remainder = (target_right * 3) != total;
unsigned target_left = target_right + remainder;
if (target_left > max_entries || target_right > max_entries)
throw std::runtime_error("too many entries");
if (nr_left < nr_right) {
int s = nr_left - target_left;
// FIXME: signed & unsigned comparison
if (s < 0 && nr_center < static_cast(-s)) {
// not enough in central node
left.move_entries(center, -nr_center);
s += nr_center;
left.move_entries(right, s);
nr_right += s;
} else
left.move_entries(center, s);
center.move_entries(right, target_right - nr_right);
} else {
int s = target_right - nr_right;
if (s > 0 && nr_center < static_cast(s)) {
// not enough in central node
center.move_entries(right, nr_center);
s -= nr_center;
left.move_entries(right, s);
nr_left -= s;
} else
center.move_entries(right, s);
left.move_entries(center, nr_left - target_left);
}
parent.set_key(center_index, center.key_at(0));
parent.set_key(right_index, right.key_at(0));
}
};