Solution -「NOI 2018」「洛谷 P4768」归程

$\mathcal{Description}$

  Link.

  给定一个 $n$ 个点 $m$ 条边的无向连通图，边形如 $(u,v,l,a)$。每次询问给出 $u,p$，回答所有从 $u$ 出发，只经过 $a$ 值 $>p$ 的边能够到达的点中，到 $1$ 号点的最小距离（以 $l$ 之和为路径距离）。强制在线，多测。

  $n\le2 \times 10^5$，$m,q\le4 \times 10^5$。

$\mathcal{Solution}$

  Kruskal 生成树的板子，还是当做算法总结写一下吧。（

  Kruskal 生成树就是在用 Kruskal 求最小（最大）生成树时，以加入边的边权作为虚点点权，并从虚点连向左右两个联通块的根，使虚点成为新连通块的根，最终构成的一棵大根（小根）树堆。

  对于本题，构最大生成树，答案即为子树内点到 $1$ 最短路的最小值。复杂度 $\mathcal O(T\left((n+q)\log n+m\log m\right))$。

$\mathcal{Code}$

/* Clearink */

#include <queue>
#include <cstdio>
#include <algorithm>

typedef std::pair<int, int> pii;
typedef std::pair<int, std::pair<int, int> > EdgeT;

inline int rint () {
	int x = 0; char s = getchar ();
	for ( ; s < '0' || '9' < s; s = getchar () );
	for ( ; '0' <= s && s <= '9'; s = getchar () ) x = x * 10 + ( s ^ '0' );
	return x;
}

inline void wint ( int x ) {
	if ( x < 0 ) putchar ( '-' ), x = -x;
	if ( 9 < x ) wint ( x / 10 );
	putchar ( x % 10 ^ '0' );
}

inline void chkmin ( int& a, const int b ) { a > b ? a = b : 0; }

const int MAXN = 4e5, MAXLG = 18;
int n, m, node, len[MAXN + 5], val[MAXN + 5], dist[MAXN + 5];
int fa[MAXN + 5][MAXLG + 5], mndist[MAXN + 5];
EdgeT edge[MAXN + 5];

struct Graph {
	int ecnt, head[MAXN + 5], to[MAXN * 2 + 5], nxt[MAXN * 2 + 5];
	Graph (): ecnt ( 1 ) {}
	inline void link ( const int s, const int t ) {
		to[++ ecnt] = t, nxt[ecnt] = head[s];
		head[s] = ecnt;
	}
} G, T;

struct DSU {
	int fa[MAXN + 5];
	inline int find ( const int x ) { return x ^ fa[x] ? fa[x] = find ( fa[x] ) : x; }
} dsu;

inline void buildKT () {
	node = n;
	std::sort ( edge + 1, edge + m + 1, []( const auto& a, const auto& b ) {
		return a.first > b.first;
	} );
	for ( int i = 1; i <= n; ++ i ) dsu.fa[i] = i;
	for ( int i = 1, u, v; i <= m; ++ i ) {
		if ( ( u = dsu.find ( edge[i].second.first ) )
		!= ( v = dsu.find ( edge[i].second.second ) ) ) {
			val[++ node] = edge[i].first;
			dsu.fa[u] = dsu.fa[v] = dsu.fa[node] = node;
			T.link ( node, u ), T.link ( node, v );
		}
	}
}

inline void Dijkstra () {
	static bool vis[MAXN + 5];
	static std::priority_queue<pii, std::vector<pii>, std::greater<pii> > heap;
	for ( int i = 1; i <= n; ++ i ) dist[i] = -1, vis[i] = false;
	heap.push ( { dist[1] = 0, 1 } );
	while ( !heap.empty () ) {
		pii p ( heap.top () ); heap.pop ();
		if ( vis[p.second] ) continue;
		vis[p.second] = true;
		for ( int i = G.head[p.second], v; i; i = G.nxt[i] ) {
			if ( int t = p.first + len[i >> 1]; !~dist[v = G.to[i]] || dist[v] > t ) {
				heap.push ( { dist[v] = t, v } );
			}
		}
	}
}

inline void prepKT ( const int u ) {
	for ( int i = 1; i <= 18; ++ i ) fa[u][i] = fa[fa[u][i - 1]][i - 1];
	mndist[u] = u <= n ? dist[u] : 0x7fffffff;
	for ( int i = T.head[u], v; i; i = T.nxt[i] ) {
		fa[v = T.to[i]][0] = u, prepKT ( v );
		chkmin ( mndist[u], mndist[v] );
	}
}

inline int climb ( int u, const int p ) {
	for ( int i = 18; ~i; -- i ) if ( fa[u][i] && val[fa[u][i]] > p ) u = fa[u][i];
	return u;
}

inline void clear () {
	G.ecnt = T.ecnt = 1;
	for ( int i = 1; i <= node; ++ i ) G.head[i] = T.head[i] = 0;
}

int main () {
	for ( int T = rint (); T --; ) {
		clear ();
		n = rint (), m = rint ();
		for ( int i = 1, u, v, a; i <= m; ++ i ) {
			u = rint (), v = rint (), len[i] = rint (), a = rint ();
			G.link ( u, v ), G.link ( v, u ), edge[i] = { a, { u, v } };
		}
		buildKT (), Dijkstra (), prepKT ( node );
		for ( int q = rint (), k = rint (), s = rint (), ans = 0, u, p; q --; ) {
			u = ( rint () + k * ans - 1 ) % n + 1;
			p = ( rint () + k * ans ) % ( s + 1 );
			wint ( ans = mndist[climb ( u, p )] ), putchar ( '\n' );
		}
	}
	return 0;
}

$\mathcal{Details}$

  多测不清空，爆零两行泪 qwq。