Zkw线段树 High Quality May 2026

int lower_bound(int k) int pos = 1; while (pos < N) if (tree[pos<<1] < k) k -= tree[pos<<1]; pos = pos<<1 else pos = pos<<1; return pos - N;

Abstract The segment tree is a fundamental data structure for range queries and point updates. While recursive implementations are intuitive, they suffer from high constant factors due to function call overhead and conditional branching. This paper describes the zkw segment tree , a non‑recursive alternative introduced by Zhang Kunwei (zkw). By storing data in a perfect binary tree indexed from the bottom layer, it eliminates recursion entirely. The resulting implementation is shorter, faster, and particularly well‑suited for competitive programming and low‑latency systems. 1. Introduction A standard segment tree is usually built as an array tree[] of size about 4*N . Recursive functions traverse the tree to answer range sum/min/max queries or apply point updates. Despite its asymptotic $O(\log N)$ performance, recursion overhead and repeated bounds checking slow down execution. zkw线段树

template<typename T> class ZkwSegTree int N; vector<T> tree; public: ZkwSegTree(int n, const vector<T>& init) N = 1; while (N < n) N <<= 1; tree.assign(2*N, 0); for (int i = 0; i < n; i++) tree[N+i] = init[i]; for (int i = N-1; i; i--) tree[i] = tree[2*i] + tree[2*i+1]; void update(int p, T val) p += N; tree[p] = val; while (p >>= 1) tree[p] = tree[2*p] + tree[2*p+1]; T query(int l, int r) // inclusive l += N, r += N; T res = 0; while (l <= r) if (l & 1) res += tree[l++]; if (!(r & 1)) res += tree[r--]; l >>= 1; r >>= 1; return res; ; int lower_bound(int k) int pos = 1; while

On a sum tree, find smallest p such that sum[0..p] >= k . By storing data in a perfect binary tree

l and r climb up. When l is a right child, its parent covers an interval that starts before l , so we take tree[l] and move l right. Symmetrically for r . 5. Comparison with Recursive Segment Tree | Aspect | Recursive Segment Tree | zkw Segment Tree | |----------------------|---------------------------------|----------------------------------| | Code length | ~40 lines (build, update, query)| ~15 lines total | | Memory | usually 4*N | exactly 2*N | | Recursion | yes (overhead + risk of stack) | none (loops only) | | Speed (log N range) | baseline (1×) | ~2–3× faster | | Lazy propagation | straightforward | more complex (but possible) | | Ease of debugging | moderate | easy (no recursion stack) | 6. Advanced Operations 6.1 Prefix / Suffix Queries For [0, r] or [l, N-1] , the code simplifies.

Prefix sum [0, r] :