Submission #1117439

#TimeUsernameProblemLanguageResultExecution timeMemory
1117439KK_1729Hedgehog Daniyar and Algorithms (IZhO19_sortbooks)C++17
100 / 100
2168 ms113288 KiB
#include <bits/stdc++.h> using namespace std; // BeginCodeSnip{Lazy Segment Tree (from the module)} template <class Info, class Tag> class LazySegtree { private: const int n; vector<Info> tree; vector<Tag> lazy; void build(int v, int l, int r, const vector<Info> &a) { if (l == r) { tree[v] = a[l]; } else { int m = (l + r) >> 1; build(2 * v, l, m, a); build(2 * v + 1, m + 1, r, a); tree[v] = tree[2 * v] + tree[2 * v + 1]; } } void apply(int v, int l, int r, const Tag &x) { tree[v].apply(x, l, r); lazy[v].apply(x); } void push_down(int v, int l, int r) { int m = (l + r) >> 1; apply(2 * v, l, m, lazy[v]); apply(2 * v + 1, m + 1, r, lazy[v]); lazy[v] = Tag(); } void upd(int v, int l, int r, int ql, int qr, const Tag &x) { if (qr < l || ql > r) { return; } if (ql <= l && r <= qr) { apply(v, l, r, x); } else { push_down(v, l, r); int m = (l + r) >> 1; upd(2 * v, l, m, ql, qr, x); upd(2 * v + 1, m + 1, r, ql, qr, x); tree[v] = tree[2 * v] + tree[2 * v + 1]; } } Info qry(int v, int l, int r, int ql, int qr) { if (qr < l || ql > r) { return Info(); } if (l >= ql && r <= qr) { return tree[v]; } push_down(v, l, r); int m = (l + r) >> 1; return qry(2 * v, l, m, ql, qr) + qry(2 * v + 1, m + 1, r, ql, qr); } public: LazySegtree(const vector<Info> &a) : n(a.size()) { tree.assign(4 << __lg(n), Info()); lazy.assign(4 << __lg(n), Tag()); build(1, 0, n - 1, a); } /** updates [ql, qr] with the arbitrary update chosen */ void upd(int ql, int qr, const Tag &x) { upd(1, 0, n - 1, ql, qr, x); } /** @return result of range query on [ql, qr] */ Info qry(int ql, int qr) { return qry(1, 0, n - 1, ql, qr); } }; // EndCodeSnip struct Tag { int added_val = -1; /** applies another lazy update to this update */ void apply(const Tag &t) { if (t.added_val != -1) { added_val = t.added_val; } } }; struct Info { int mx = -1; int applied = -1; /** applies an update to this tree node */ void apply(const Tag &t, int l, int r) { if (t.added_val != -1) { applied = mx + t.added_val; } } }; /** @return result of joining nodes a and b together */ Info operator+(const Info &a, const Info &b) { return {max(a.mx, b.mx), max(a.applied, b.applied)}; } int main() { int n, q; cin >> n >> q; vector<int> w(n); for (int &i : w) { cin >> i; } vector<Info> arr(n); for (int i = 0; i < n; i++) { /* * The default applied value (a.k.a. inversion pair value) must be * initially set to 0, so that indices that aren't in an inversion pair * will be effectively ignored by the segment tree. */ arr[i] = {w[i], 0}; } LazySegtree<Info, Tag> st(arr); vector<vector<array<int, 3>>> tests(n); for (int i = 0; i < q; i++) { int l, r, k; cin >> l >> r >> k; l--, r--; tests[l].push_back({r, k, i}); } vector<bool> res(q); stack<int> indices; for (int i = n - 1; i >= 0; i--) { // maintain a monotonic stack to find the first index j where w[i] >= w[j] while (!indices.empty() && w[indices.top()] < w[i]) { indices.pop(); } int b = indices.empty() ? n : indices.top(); indices.push(i); st.upd(i + 1, b - 1, {w[i]}); for (auto [r, k, idx] : tests[i]) { res[idx] = st.qry(i, r).applied <= k; } } for (int i = 0; i < q; i++) { cout << res[i] << '\n'; } }
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...