import * as fs from 'fs' import { resolve } from 'path' /** * 单点更新,区间查询的线段树. */ class SegmentTreePointUpdateRangeQuery { private readonly _n: number private readonly _size: number private readonly _seg: E[] private readonly _e: () => E private readonly _op: (a: E, b: E) => E /** * @param nOrLeaves 大小或叶子节点的值. * @param e 幺元. * @param op 结合律. */ constructor(nOrLeaves: number | ArrayLike, e: () => E, op: (a: E, b: E) => E) { const n = typeof nOrLeaves === 'number' ? nOrLeaves : nOrLeaves.length let size = 1 while (size < n) size <<= 1 const seg = Array(size << 1) for (let i = 0; i < seg.length; i++) seg[i] = e() this._n = n this._size = size this._seg = seg this._e = e this._op = op if (typeof nOrLeaves !== 'number') this.build(nOrLeaves) } set(index: number, value: E): void { if (index < 0 || index >= this._n) return index += this._size this._seg[index] = value while ((index >>= 1)) { this._seg[index] = this._op(this._seg[index << 1], this._seg[(index << 1) | 1]) } } get(index: number): E { if (index < 0 || index >= this._n) return this._e() return this._seg[index + this._size] } /** * 将`index`处的值与作用素`value`结合. */ update(index: number, value: E): void { if (index < 0 || index >= this._n) return index += this._size this._seg[index] = this._op(this._seg[index], value) while ((index >>= 1)) { this._seg[index] = this._op(this._seg[index << 1], this._seg[(index << 1) | 1]) } } /** * 查询区间`[start,end)`的聚合值. * 0 <= start <= end <= n. */ query(start: number, end: number): E { if (start < 0) start = 0 if (end > this._n) end = this._n if (start >= end) return this._e() let leftRes = this._e() let rightRes = this._e() for (start += this._size, end += this._size; start < end; start >>= 1, end >>= 1) { if (start & 1) leftRes = this._op(leftRes, this._seg[start++]) if (end & 1) rightRes = this._op(this._seg[--end], rightRes) } return this._op(leftRes, rightRes) } queryAll(): E { return this._seg[1] } /** * 树上二分查询最大的`end`使得`[start,end)`内的值满足`predicate`. */ maxRight(start: number, predicate: (value: E) => boolean): number { if (start === this._n) return this._n start += this._size let res = this._e() while (true) { while (!(start & 1)) start >>= 1 if (!predicate(this._op(res, this._seg[start]))) { while (start < this._size) { start <<= 1 if (predicate(this._op(res, this._seg[start]))) { res = this._op(res, this._seg[start]) start++ } } return start - this._size } res = this._op(res, this._seg[start]) start++ if ((start & -start) === start) break } return this._n } /** * 树上二分查询最小的`start`使得`[start,end)`内的值满足`predicate` */ minLeft(end: number, predicate: (value: E) => boolean): number { if (end === 0) return 0 end += this._size let res = this._e() while (true) { end-- while (end > 1 && end & 1) end >>= 1 if (!predicate(this._op(this._seg[end], res))) { while (end < this._size) { end = (end << 1) | 1 if (predicate(this._op(this._seg[end], res))) { res = this._op(this._seg[end], res) end-- } } return end + 1 - this._size } res = this._op(this._seg[end], res) if ((end & -end) === end) break } return 0 } build(arr: ArrayLike): void { for (let i = 0; i < arr.length; i++) { this._seg[i + this._size] = arr[i] // 叶子结点 } for (let i = this._size - 1; ~i; i--) { this._seg[i] = this._op(this._seg[i << 1], this._seg[(i << 1) | 1]) } } } function useInput(path?: string) { let data: string if (path) { data = fs.readFileSync(resolve(__dirname, path), 'utf8') } else { data = fs.readFileSync(process.stdin.fd, 'utf8') } const lines = data.split(/\r\n|\r|\n/) let lineId = 0 const input = (): string => lines[lineId++] return { input } } const { input } = useInput() const [N, Q] = input().split(' ').map(Number) const a = input().split(' ').map(Number) const INF = 2e15 const seg = new SegmentTreePointUpdateRangeQuery(a, () => INF, Math.min) for (let i = 0; i < Q; i++) { let [c, l, r] = input().split(' ').map(Number) if (c === 1) { l-- r-- const vl = seg.get(l) seg.update(l, seg.get(r)) seg.update(r, vl) } else { l-- const mn = seg.query(l, r) const a1 = seg.maxRight(l, n => n > mn) let a2 = seg.minLeft(r, n => n > mn) a2-- console.log(a1 + 1) } }