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#define PROBLEM "https://atcoder.jp/contests/abc253/tasks/abc253_f" #include <iostream> #include "library/datastructure/segment_tree/persistent_lazy_segment_tree.hpp" long long op(long long x, long long) { return x; } long long e() { return 0; } long long mapping(long long f, long long x) { return f + x; } long long composition(long long f, long long g) { return f + g; } long long id() { return 0; } using Tree = suisen::PersistentLazySegmentTree<long long, op, e, long long, mapping, composition, id>; int main() { std::ios::sync_with_stdio(false); std::cin.tie(nullptr); int n, m, q; std::cin >> n >> m >> q; std::vector<std::pair<int, int>> last(n); Tree::init_pool(15000000); std::vector<Tree> segs(q + 1); segs[0] = Tree(m + 1); for (int t = 1; t <= q; ++t) { int query_type; std::cin >> query_type; segs[t] = segs[t - 1]; if (query_type == 1) { int l, r, x; std::cin >> l >> r >> x; --l; segs[t] = segs[t].apply(l, r, x); } else if (query_type == 2) { int i, x; std::cin >> i >> x; --i; last[i] = { t - 1, x }; } else { int i, j; std::cin >> i >> j; --i, --j; auto [tl, x] = last[i]; std::cout << x + segs[t - 1].get(j) - segs[tl].get(j) << '\n'; } } return 0; }
#line 1 "test/src/datastructure/segment_tree/persistent_lazy_segment_tree/abc253.test.cpp" #define PROBLEM "https://atcoder.jp/contests/abc253/tasks/abc253_f" #include <iostream> #line 1 "library/datastructure/segment_tree/persistent_lazy_segment_tree.hpp" #include <cassert> #line 1 "library/util/object_pool.hpp" #include <deque> #include <vector> namespace suisen { template <typename T, bool auto_extend = false> struct ObjectPool { using value_type = T; using value_pointer_type = T*; template <typename U> using container_type = std::conditional_t<auto_extend, std::deque<U>, std::vector<U>>; container_type<value_type> pool; container_type<value_pointer_type> stock; decltype(stock.begin()) it; ObjectPool() : ObjectPool(0) {} ObjectPool(int siz) : pool(siz), stock(siz) { clear(); } int capacity() const { return pool.size(); } int size() const { return it - stock.begin(); } value_pointer_type alloc() { if constexpr (auto_extend) ensure(); return *it++; } void free(value_pointer_type t) { *--it = t; } void clear() { int siz = pool.size(); it = stock.begin(); for (int i = 0; i < siz; i++) stock[i] = &pool[i]; } void ensure() { if (it != stock.end()) return; int siz = stock.size(); for (int i = siz; i <= siz * 2; ++i) { stock.push_back(&pool.emplace_back()); } it = stock.begin() + siz; } }; } // namespace suisen #line 7 "library/datastructure/segment_tree/persistent_lazy_segment_tree.hpp" namespace suisen { template <typename T, T(*op)(T, T), T(*e)(), typename F, T(*mapping)(F, T), F(*composition)(F, F), F(*id)()> struct PersistentLazySegmentTree { struct Node; using value_type = T; using operator_type = F; using node_type = Node; using node_pointer_type = node_type*; struct Node { static inline ObjectPool<node_type> _pool; node_pointer_type _ch[2]{ nullptr, nullptr }; value_type _dat; operator_type _laz; Node() : _dat(e()), _laz(id()) {} static node_pointer_type clone(node_pointer_type node) { return &(*_pool.alloc() = *node); } static void update(node_pointer_type node) { node->_dat = op(node->_ch[0]->_dat, node->_ch[1]->_dat); } template <bool do_clone = true> static auto push(node_pointer_type node) { node_pointer_type res = node; if constexpr (do_clone) res = clone(res); res->_ch[0] = apply_all(res->_ch[0], res->_laz); res->_ch[1] = apply_all(res->_ch[1], res->_laz); res->_laz = id(); if constexpr (do_clone) { return res; } else { return; } } static bool is_leaf(node_pointer_type node) { return not node->_ch[0]; } static node_pointer_type build(const std::vector<value_type>& dat) { auto rec = [&](auto rec, int l, int r) -> node_pointer_type { node_pointer_type res = _pool.alloc(); if (r - l == 1) { res->_dat = dat[l]; res->_laz = id(); } else { int m = (l + r) >> 1; res->_ch[0] = rec(rec, l, m), res->_ch[1] = rec(rec, m, r); update(res); res->_laz = id(); } return res; }; return rec(rec, 0, dat.size()); } static value_type prod_all(node_pointer_type node) { return node ? node->_dat : e(); } static value_type prod(node_pointer_type node, int tl, int tr, int ql, int qr, const operator_type &f = id()) { if (tr <= ql or qr <= tl) return e(); if (ql <= tl and tr <= qr) return mapping(f, node->_dat); int tm = (tl + tr) >> 1; operator_type g = composition(f, node->_laz); return op(prod(node->_ch[0], tl, tm, ql, qr, g), prod(node->_ch[1], tm, tr, ql, qr, g)); } static node_pointer_type apply_all(node_pointer_type node, const operator_type &f) { if (not node) return nullptr; node_pointer_type res = clone(node); res->_dat = mapping(f, res->_dat); res->_laz = composition(f, res->_laz); return res; } static node_pointer_type apply(node_pointer_type node, int tl, int tr, int ql, int qr, const operator_type &f) { if (tr <= ql or qr <= tl) return node; if (ql <= tl and tr <= qr) return apply_all(node, f); node_pointer_type res = push(node); int tm = (tl + tr) >> 1; res->_ch[0] = apply(res->_ch[0], tl, tm, ql, qr, f); res->_ch[1] = apply(res->_ch[1], tm, tr, ql, qr, f); update(res); return res; } template <typename Func> static auto update_leaf(node_pointer_type node, int siz, int i, Func &&f) { static std::vector<node_pointer_type> path; node_pointer_type res = clone(node); node_pointer_type cur = res; for (int l = 0, r = siz; r - l > 1;) { path.push_back(cur); push</*do_clone = */false>(cur); int m = (l + r) >> 1; if (i < m) { cur = cur->_ch[0]; r = m; } else { cur = cur->_ch[1]; l = m; } } cur->_dat = f(cur->_dat); while (path.size()) update(path.back()), path.pop_back(); return res; } static value_type get(node_pointer_type node, int siz, int i) { operator_type f = id(); node_pointer_type cur = node; for (int l = 0, r = siz; r - l > 1;) { f = composition(f, cur->_laz); int m = (l + r) >> 1; if (i < m) { cur = cur->_ch[0]; r = m; } else { cur = cur->_ch[1]; l = m; } } return mapping(f, cur->_dat); } template <typename Func> static node_pointer_type apply(node_pointer_type node, int siz, int i, Func&& f) { return update_leaf(node, siz, i, [&](const value_type &v) { return f(v); }); } static node_pointer_type set(node_pointer_type node, int siz, int i, const value_type& dat) { return apply(node, siz, i, [&](const value_type&) { return dat; }); } template <typename Pred> static int max_right(node_pointer_type node, int siz, int l, Pred&& pred) { assert(pred(e())); auto rec = [&](auto rec, node_pointer_type cur, int tl, int tr, value_type& sum, const operator_type &f) -> int { if (tr <= l) return tr; if (l <= tl) { value_type nxt_sum = op(sum, mapping(f, cur->_dat)); if (pred(nxt_sum)) { sum = std::move(nxt_sum); return tr; } if (tr - tl == 1) return tl; } int tm = (tl + tr) >> 1; operator_type g = composition(f, cur->_laz); int res_l = rec(rec, cur->_ch[0], tl, tm, sum, g); return res_l != tm ? res_l : rec(rec, cur->_ch[1], tm, tr, sum, g); }; value_type sum = e(); return rec(rec, node, 0, siz, sum, id()); } template <typename Pred> static int min_left(node_pointer_type node, int siz, int r, Pred&& pred) { assert(pred(e())); auto rec = [&](auto rec, node_pointer_type cur, int tl, int tr, value_type& sum, const operator_type &f) -> int { if (r <= tl) return tl; if (tr <= r) { value_type nxt_sum = op(mapping(f, cur->_dat), sum); if (pred(nxt_sum)) { sum = std::move(nxt_sum); return tl; } if (tr - tl == 1) return tr; } int tm = (tl + tr) >> 1; operator_type g = composition(f, cur->_laz); int res_r = rec(rec, cur->_ch[1], tm, tr, sum, g); return res_r != tm ? res_r : rec(rec, cur->_ch[0], tl, tm, sum, g); }; value_type sum = e(); return rec(rec, node, 0, siz, sum, id()); } template <typename OutputIterator> static void dump(node_pointer_type node, OutputIterator it) { if (not node) return; auto rec = [&](auto rec, node_pointer_type cur, const operator_type &f) -> void { if (is_leaf(cur)) { *it++ = mapping(f, cur->_dat); } else { *it++ = mapping(f, cur->_dat); rec(rec, cur->_ch[0], composition(cur->_laz, f)), rec(rec, cur->_ch[1], composition(cur->_laz, f)); } }; rec(rec, node, id()); } static std::vector<value_type> dump(node_pointer_type node) { std::vector<value_type> res; dump(node, std::back_inserter(res)); return res; } }; PersistentLazySegmentTree() : _n(0), _root(nullptr) {} explicit PersistentLazySegmentTree(int n) : PersistentLazySegmentTree(std::vector<value_type>(n, e())) {} PersistentLazySegmentTree(const std::vector<value_type>& dat) : _n(dat.size()), _root(node_type::build(dat)) {} static void init_pool(int siz) { node_type::_pool = ObjectPool<node_type>(siz); } static void clear_pool() { node_type::_pool.clear(); } value_type prod_all() { return node_type::prod_all(_root); } value_type prod(int l, int r) { assert(0 <= l and l <= r and r <= _n); return node_type::prod(_root, 0, _n, l, r); } value_type operator()(int l, int r) { return prod(l, r); } PersistentLazySegmentTree apply_all(const operator_type &f) { return PersistentLazySegmentTree(_n, node_type::apply_all(_root, f)); } PersistentLazySegmentTree apply(int l, int r, const operator_type &f) { return PersistentLazySegmentTree(_n, node_type::apply(_root, 0, _n, l, r, f)); } value_type get(int i) { assert(0 <= i and i < _n); return node_type::get(_root, _n, i); } value_type operator[](int i) { return get(i); } template <typename Func> PersistentLazySegmentTree apply(int i, Func&& f) { assert(0 <= i and i < _n); return PersistentLazySegmentTree(_n, node_type::apply(_root, _n, i, std::forward<F>(f))); } PersistentLazySegmentTree set(int i, const value_type& v) { assert(0 <= i and i < _n); return PersistentLazySegmentTree(_n, node_type::set(_root, _n, i, v)); } template <typename Pred> int max_right(int l, Pred&& pred) { assert(0 <= l and l <= _n); return node_type::max_right(_root, _n, l, std::forward<Pred>(pred)); } template <bool(*pred)(value_type)> static int max_right(int l) { return max_right(l, pred); } template <typename Pred> int min_left(int r, Pred&& pred) { assert(0 <= r and r <= _n); return node_type::min_left(_root, _n, r, std::forward<Pred>(pred)); } template <bool(*pred)(value_type)> static int min_left(int r) { return min_left(r, pred); } template <typename OutputIterator> void dump(OutputIterator it) { node_type::dump(_root, it); } std::vector<value_type> dump() { return node_type::dump(_root); } private: int _n; node_pointer_type _root; PersistentLazySegmentTree(int n, node_pointer_type root) : _n(n), _root(root) {} }; } #line 6 "test/src/datastructure/segment_tree/persistent_lazy_segment_tree/abc253.test.cpp" long long op(long long x, long long) { return x; } long long e() { return 0; } long long mapping(long long f, long long x) { return f + x; } long long composition(long long f, long long g) { return f + g; } long long id() { return 0; } using Tree = suisen::PersistentLazySegmentTree<long long, op, e, long long, mapping, composition, id>; int main() { std::ios::sync_with_stdio(false); std::cin.tie(nullptr); int n, m, q; std::cin >> n >> m >> q; std::vector<std::pair<int, int>> last(n); Tree::init_pool(15000000); std::vector<Tree> segs(q + 1); segs[0] = Tree(m + 1); for (int t = 1; t <= q; ++t) { int query_type; std::cin >> query_type; segs[t] = segs[t - 1]; if (query_type == 1) { int l, r, x; std::cin >> l >> r >> x; --l; segs[t] = segs[t].apply(l, r, x); } else if (query_type == 2) { int i, x; std::cin >> i >> x; --i; last[i] = { t - 1, x }; } else { int i, j; std::cin >> i >> j; --i, --j; auto [tl, x] = last[i]; std::cout << x + segs[t - 1].get(j) - segs[tl].get(j) << '\n'; } } return 0; }