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2分トライ木 (lib/binary_tree/binary_trie.hpp)
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#include "lib/binary_tree/binary_trie.hpp" - Link: https://kazuma8128.hatenablog.com/entry/2018/05/06/022654
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#pragma once
#include <array>
#include <cassert>
#include <concepts>
#include <optional>
#include <vector>
/// @brief 2分トライ木
/// @see https://kazuma8128.hatenablog.com/entry/2018/05/06/022654
template <std::integral T, int B = 31, bool Multi = false>
struct binary_trie {
private:
struct node_t {
int count;
std::array<int, 2> ch;
node_t() : count(), ch{-1, -1} {}
};
public:
constexpr binary_trie() : nodes(1) {}
constexpr T operator[](int k) const {
assert(0 <= k && k < size());
T res{};
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
int m = nodes[idx].ch[0] != -1 ? nodes[nodes[idx].ch[0]].count : 0;
if (k < m) {
idx = nodes[idx].ch[0];
} else {
k -= m;
res += T(1) << b;
idx = nodes[idx].ch[1];
}
}
return res;
}
constexpr T at(int k) const { return operator[](k); }
constexpr T get(int k) const { return operator[](k); }
constexpr T kth_element(int k) const { return operator[](k); }
constexpr bool empty() const { return nodes.front().count == 0; }
constexpr int size() const { return nodes.front().count; }
constexpr void insert(T val) {
if constexpr (!Multi) {
if (count(val)) return;
}
++nodes[0].count;
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (nodes[idx].ch[f] == -1) {
nodes[idx].ch[f] = nodes.size();
nodes.emplace_back();
}
idx = nodes[idx].ch[f];
++nodes[idx].count;
}
}
constexpr void erase(T val) {
if (!count(val)) return;
--nodes[0].count;
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
idx = nodes[idx].ch[val >> b & 1];
--nodes[idx].count;
}
}
constexpr T min_element(T bias = 0) const {
assert(!empty());
T res{};
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
bool f = bias >> b & 1;
f ^= !get_count(nodes[idx].ch[f]);
res += T(f) << b;
idx = nodes[idx].ch[f];
}
return res;
}
constexpr T max_element(T bias = 0) const { return min_element(~bias); }
constexpr bool contains(T val) const { return count(val); }
constexpr int count_less(T val) const { return lower_bound(val); }
constexpr int count(T val) const {
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
idx = nodes[idx].ch[val >> b & 1];
if (idx == -1) return 0;
}
return nodes[idx].count;
}
constexpr int count(T l, T r) const { return count_less(r) - count_less(l); }
constexpr int lower_bound(T val) const {
int res = 0, idx = 0;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (f) res += get_count(nodes[idx].ch[0]);
idx = nodes[idx].ch[f];
if (idx == -1) break;
}
return res;
}
constexpr int upper_bound(T val) const {
int res = 0, idx = 0;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (f) res += get_count(nodes[idx].ch[0]);
idx = nodes[idx].ch[f];
if (idx == -1) break;
}
return res + get_count(idx);
}
constexpr std::optional<T> floor(T val) const {
T res{}, last_res{};
int idx = 0, last_idx = -1, last_b = -1;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (f && get_count(nodes[idx].ch[0])) last_res = res, last_idx = nodes[idx].ch[0], last_b = b;
res += T(f) << b, idx = nodes[idx].ch[f];
if (!get_count(idx)) break;
}
if (get_count(idx)) return res;
if (last_idx == -1) return std::nullopt;
res = last_res, idx = last_idx;
for (int b = last_b - 1; b >= 0; --b) {
if (nodes[idx].ch[1] != -1 && nodes[nodes[idx].ch[1]].count) res += T(1) << b, idx = nodes[idx].ch[1];
else idx = nodes[idx].ch[0];
}
return res;
}
constexpr std::optional<T> ceil(T val) const {
T res{}, last_res{};
int idx = 0, last_idx = -1, last_b = -1;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (!f && get_count(nodes[idx].ch[1]))
last_res = res + (T(1) << b), last_idx = nodes[idx].ch[1], last_b = b;
res += T(f) << b, idx = nodes[idx].ch[f];
if (!get_count(idx)) break;
}
if (get_count(idx)) return res;
if (last_idx == -1) return std::nullopt;
res = last_res, idx = last_idx;
for (int b = last_b - 1; b >= 0; --b) {
if (get_count(nodes[idx].ch[0])) idx = nodes[idx].ch[0];
else res += T(1) << b, idx = nodes[idx].ch[1];
}
return res;
}
private:
std::vector<node_t> nodes;
constexpr int get_count(int idx) const { return idx == -1 ? 0 : nodes[idx].count; }
};
#line 2 "lib/binary_tree/binary_trie.hpp"
#include <array>
#include <cassert>
#include <concepts>
#include <optional>
#include <vector>
/// @brief 2分トライ木
/// @see https://kazuma8128.hatenablog.com/entry/2018/05/06/022654
template <std::integral T, int B = 31, bool Multi = false>
struct binary_trie {
private:
struct node_t {
int count;
std::array<int, 2> ch;
node_t() : count(), ch{-1, -1} {}
};
public:
constexpr binary_trie() : nodes(1) {}
constexpr T operator[](int k) const {
assert(0 <= k && k < size());
T res{};
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
int m = nodes[idx].ch[0] != -1 ? nodes[nodes[idx].ch[0]].count : 0;
if (k < m) {
idx = nodes[idx].ch[0];
} else {
k -= m;
res += T(1) << b;
idx = nodes[idx].ch[1];
}
}
return res;
}
constexpr T at(int k) const { return operator[](k); }
constexpr T get(int k) const { return operator[](k); }
constexpr T kth_element(int k) const { return operator[](k); }
constexpr bool empty() const { return nodes.front().count == 0; }
constexpr int size() const { return nodes.front().count; }
constexpr void insert(T val) {
if constexpr (!Multi) {
if (count(val)) return;
}
++nodes[0].count;
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (nodes[idx].ch[f] == -1) {
nodes[idx].ch[f] = nodes.size();
nodes.emplace_back();
}
idx = nodes[idx].ch[f];
++nodes[idx].count;
}
}
constexpr void erase(T val) {
if (!count(val)) return;
--nodes[0].count;
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
idx = nodes[idx].ch[val >> b & 1];
--nodes[idx].count;
}
}
constexpr T min_element(T bias = 0) const {
assert(!empty());
T res{};
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
bool f = bias >> b & 1;
f ^= !get_count(nodes[idx].ch[f]);
res += T(f) << b;
idx = nodes[idx].ch[f];
}
return res;
}
constexpr T max_element(T bias = 0) const { return min_element(~bias); }
constexpr bool contains(T val) const { return count(val); }
constexpr int count_less(T val) const { return lower_bound(val); }
constexpr int count(T val) const {
int idx = 0;
for (int b = B - 1; b >= 0; --b) {
idx = nodes[idx].ch[val >> b & 1];
if (idx == -1) return 0;
}
return nodes[idx].count;
}
constexpr int count(T l, T r) const { return count_less(r) - count_less(l); }
constexpr int lower_bound(T val) const {
int res = 0, idx = 0;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (f) res += get_count(nodes[idx].ch[0]);
idx = nodes[idx].ch[f];
if (idx == -1) break;
}
return res;
}
constexpr int upper_bound(T val) const {
int res = 0, idx = 0;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (f) res += get_count(nodes[idx].ch[0]);
idx = nodes[idx].ch[f];
if (idx == -1) break;
}
return res + get_count(idx);
}
constexpr std::optional<T> floor(T val) const {
T res{}, last_res{};
int idx = 0, last_idx = -1, last_b = -1;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (f && get_count(nodes[idx].ch[0])) last_res = res, last_idx = nodes[idx].ch[0], last_b = b;
res += T(f) << b, idx = nodes[idx].ch[f];
if (!get_count(idx)) break;
}
if (get_count(idx)) return res;
if (last_idx == -1) return std::nullopt;
res = last_res, idx = last_idx;
for (int b = last_b - 1; b >= 0; --b) {
if (nodes[idx].ch[1] != -1 && nodes[nodes[idx].ch[1]].count) res += T(1) << b, idx = nodes[idx].ch[1];
else idx = nodes[idx].ch[0];
}
return res;
}
constexpr std::optional<T> ceil(T val) const {
T res{}, last_res{};
int idx = 0, last_idx = -1, last_b = -1;
for (int b = B - 1; b >= 0; --b) {
bool f = val >> b & 1;
if (!f && get_count(nodes[idx].ch[1]))
last_res = res + (T(1) << b), last_idx = nodes[idx].ch[1], last_b = b;
res += T(f) << b, idx = nodes[idx].ch[f];
if (!get_count(idx)) break;
}
if (get_count(idx)) return res;
if (last_idx == -1) return std::nullopt;
res = last_res, idx = last_idx;
for (int b = last_b - 1; b >= 0; --b) {
if (get_count(nodes[idx].ch[0])) idx = nodes[idx].ch[0];
else res += T(1) << b, idx = nodes[idx].ch[1];
}
return res;
}
private:
std::vector<node_t> nodes;
constexpr int get_count(int idx) const { return idx == -1 ? 0 : nodes[idx].count; }
};