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#pragma once
#include <cassert>
#include <algorithm>
#include <array>
#include <memory>
#include <type_traits>
#include <vector>
#include "Box.h"
namespace quadtree
{
template<typename T, typename GetBox, typename Equal = std::equal_to<T>, typename Float = float>
class Quadtree
{
static_assert(std::is_convertible_v<std::invoke_result_t<GetBox, const T&>, Box<Float>>,
"GetBox must be a callable of signature Box<Float>(const T&)");
static_assert(std::is_convertible_v<std::invoke_result_t<Equal, const T&, const T&>, bool>,
"Equal must be a callable of signature bool(const T&, const T&)");
static_assert(std::is_arithmetic_v<Float>);
public:
Quadtree(const Box<Float>& box, const GetBox& getBox = GetBox(),
const Equal& equal = Equal()) :
mBox(box), mRoot(std::make_unique<Node>()), mGetBox(getBox), mEqual(equal)
{
}
void add(const T& value)
{
add(mRoot.get(), 0, mBox, value);
}
void remove(const T& value)
{
remove(mRoot.get(), mBox, value);
}
std::vector<T> query(const Box<Float>& box) const
{
auto values = std::vector<T>();
query(mRoot.get(), mBox, box, values);
return values;
}
std::vector<std::pair<T, T>> findAllIntersections() const
{
auto intersections = std::vector<std::pair<T, T>>();
findAllIntersections(mRoot.get(), intersections);
return intersections;
}
Box<Float> getBox() const
{
return mBox;
}
private:
static constexpr auto Threshold = std::size_t(16);
static constexpr auto MaxDepth = std::size_t(8);
struct Node
{
std::array<std::unique_ptr<Node>, 4> children;
std::vector<T> values;
};
Box<Float> mBox;
std::unique_ptr<Node> mRoot;
GetBox mGetBox;
Equal mEqual;
bool isLeaf(const Node* node) const
{
return !static_cast<bool>(node->children[0]);
}
Box<Float> computeBox(const Box<Float>& box, int i) const
{
auto origin = box.getTopLeft();
auto childSize = box.getSize() / static_cast<Float>(2);
switch (i)
{
// North West
case 0:
return Box<Float>(origin, childSize);
// Norst East
case 1:
return Box<Float>(Vector2<Float>(origin.x + childSize.x, origin.y), childSize);
// South West
case 2:
return Box<Float>(Vector2<Float>(origin.x, origin.y + childSize.y), childSize);
// South East
case 3:
return Box<Float>(origin + childSize, childSize);
default:
assert(false && "Invalid child index");
return Box<Float>();
}
}
int getQuadrant(const Box<Float>& nodeBox, const Box<Float>& valueBox) const
{
auto center = nodeBox.getCenter();
// West
if (valueBox.getRight() < center.x)
{
// North West
if (valueBox.getBottom() < center.y)
return 0;
// South West
else if (valueBox.top >= center.y)
return 2;
// Not contained in any quadrant
else
return -1;
}
// East
else if (valueBox.left >= center.x)
{
// North East
if (valueBox.getBottom() < center.y)
return 1;
// South East
else if (valueBox.top >= center.y)
return 3;
// Not contained in any quadrant
else
return -1;
}
// Not contained in any quadrant
else
return -1;
}
void add(Node* node, std::size_t depth, const Box<Float>& box, const T& value)
{
assert(node != nullptr);
assert(box.contains(mGetBox(value)));
if (isLeaf(node))
{
// Insert the value in this node if possible
if (depth >= MaxDepth || node->values.size() < Threshold)
node->values.push_back(value);
// Otherwise, we split and we try again
else
{
split(node, box);
add(node, depth, box, value);
}
}
else
{
auto i = getQuadrant(box, mGetBox(value));
// Add the value in a child if the value is entirely contained in it
if (i != -1)
add(node->children[static_cast<std::size_t>(i)].get(), depth + 1, computeBox(box, i), value);
// Otherwise, we add the value in the current node
else
node->values.push_back(value);
}
}
void split(Node* node, const Box<Float>& box)
{
assert(node != nullptr);
assert(isLeaf(node) && "Only leaves can be split");
// Create children
for (auto& child : node->children)
child = std::make_unique<Node>();
// Assign values to children
auto newValues = std::vector<T>(); // New values for this node
for (const auto& value : node->values)
{
auto i = getQuadrant(box, mGetBox(value));
if (i != -1)
node->children[static_cast<std::size_t>(i)]->values.push_back(value);
else
newValues.push_back(value);
}
node->values = std::move(newValues);
}
bool remove(Node* node, const Box<Float>& box, const T& value)
{
assert(node != nullptr);
assert(box.contains(mGetBox(value)));
if (isLeaf(node))
{
// Remove the value from node
removeValue(node, value);
return true;
}
else
{
// Remove the value in a child if the value is entirely contained in it
auto i = getQuadrant(box, mGetBox(value));
if (i != -1)
{
if (remove(node->children[static_cast<std::size_t>(i)].get(), computeBox(box, i), value))
return tryMerge(node);
}
// Otherwise, we remove the value from the current node
else
removeValue(node, value);
return false;
}
}
void removeValue(Node* node, const T& value)
{
// Find the value in node->values
auto it = std::find_if(std::begin(node->values), std::end(node->values),
[this, &value](const auto& rhs){ return mEqual(value, rhs); });
assert(it != std::end(node->values) && "Trying to remove a value that is not present in the node");
// Swap with the last element and pop back
*it = std::move(node->values.back());
node->values.pop_back();
}
bool tryMerge(Node* node)
{
assert(node != nullptr);
assert(!isLeaf(node) && "Only interior nodes can be merged");
auto nbValues = node->values.size();
for (const auto& child : node->children)
{
if (!isLeaf(child.get()))
return false;
nbValues += child->values.size();
}
if (nbValues <= Threshold)
{
node->values.reserve(nbValues);
// Merge the values of all the children
for (const auto& child : node->children)
{
for (const auto& value : child->values)
node->values.push_back(value);
}
// Remove the children
for (auto& child : node->children)
child.reset();
return true;
}
else
return false;
}
void query(Node* node, const Box<Float>& box, const Box<Float>& queryBox, std::vector<T>& values) const
{
assert(node != nullptr);
assert(queryBox.intersects(box));
for (const auto& value : node->values)
{
if (queryBox.intersects(mGetBox(value)))
values.push_back(value);
}
if (!isLeaf(node))
{
for (auto i = std::size_t(0); i < node->children.size(); ++i)
{
auto childBox = computeBox(box, static_cast<int>(i));
if (queryBox.intersects(childBox))
query(node->children[i].get(), childBox, queryBox, values);
}
}
}
void findAllIntersections(Node* node, std::vector<std::pair<T, T>>& intersections) const
{
// Find intersections between values stored in this node
// Make sure to not report the same intersection twice
for (auto i = std::size_t(0); i < node->values.size(); ++i)
{
for (auto j = std::size_t(0); j < i; ++j)
{
if (mGetBox(node->values[i]).intersects(mGetBox(node->values[j])))
intersections.emplace_back(node->values[i], node->values[j]);
}
}
if (!isLeaf(node))
{
// Values in this node can intersect values in descendants
for (const auto& child : node->children)
{
for (const auto& value : node->values)
findIntersectionsInDescendants(child.get(), value, intersections);
}
// Find intersections in children
for (const auto& child : node->children)
findAllIntersections(child.get(), intersections);
}
}
void findIntersectionsInDescendants(Node* node, const T& value, std::vector<std::pair<T, T>>& intersections) const
{
// Test against the values stored in this node
for (const auto& other : node->values)
{
if (mGetBox(value).intersects(mGetBox(other)))
intersections.emplace_back(value, other);
}
// Test against values stored into descendants of this node
if (!isLeaf(node))
{
for (const auto& child : node->children)
findIntersectionsInDescendants(child.get(), value, intersections);
}
}
};
}
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