Submission #668098

#	Submission time	Handle	Problem	Language	Result	Execution time	Memory
668098	2022-12-02T18:23:08 Z	tibinyte	Lampice (COCI19_lampice)	C++17	42 / 110	5000 ms	10272 KB

lampice

#include <bits/stdc++.h>

using namespace std;

const int mod = 1e9 + 9;
const int base = 29;

int add(int x, int y)
{
    x += y;
    if (x >= mod)
    {
        return x - mod;
    }
    return x;
}

int mult(int x, int y)
{
    return (int64_t)x * y % mod;
}

mt19937_64 rng(chrono::steady_clock::now().time_since_epoch().count());
int random(int st, int dr)
{
    uniform_int_distribution<mt19937::result_type> gen(st, dr);
    return gen(rng);
}
struct lampice
{
    int n;
    vector<vector<int>> g;
    vector<char> colors;
    vector<bool> seen;
    vector<int> sz;
    vector<int> depth;
    vector<int> hashup;
    vector<int> hashdown;
    vector<int> par;
    vector<int> nodes;
    vector<int> neortodox;
    vector<int> dp;
    void init(int _n)
    {
        n = _n;
        g = vector<vector<int>>(n + 1);
        colors = vector<char>(n + 1);
        seen = vector<bool>(n + 1);
        dp = neortodox = nodes = sz = depth = hashup = hashdown = par = vector<int>(n + 1);
    }
    void set_color(int pos, char x)
    {
        colors[pos] = x;
    }
    void add_edge(int a, int b)
    {
        g[a].push_back(b);
        g[b].push_back(a);
    }
    void dfs_size(int node, int parent)
    {
        sz[node] = 1;
        for (auto i : g[node])
        {
            if (i != parent && !seen[i])
            {
                dfs_size(i, node);
                sz[node] += sz[i];
            }
        }
    }
    int find_centroid(int node, int parent, int size)
    {
        for (auto i : g[node])
        {
            if (i != parent && !seen[i] && sz[i] > size / 2)
            {
                return find_centroid(i, node, size);
            }
        }
        return node;
    }
    int solve(int node, int k)
    {
        int max_depth = 0;
        function<void(int, int, int)> dfs_init = [&](int node, int parent, int d)
        {
            par[node] = parent;
            depth[node] = d;
            dp[node] = 1;
            max_depth = max(max_depth, d);
            for (auto i : g[node])
            {

                if (i != parent && !seen[i])
                {
                    dfs_init(i, node, d + 1);
                    dp[node] = max(dp[node], dp[i] + 1);
                }
            }
            int mx1 = 0, mx2 = 0;
            for (auto i : g[node])
            {
                if (i != parent && !seen[i])
                {
                    if (dp[i] > mx1)
                    {
                        mx2 = mx1;
                        mx1 = dp[i];
                    }
                    else
                    {
                        if (dp[i] > mx2)
                        {
                            mx2 = dp[i];
                        }
                    }
                }
            }
            neortodox[node] = mx1 + mx2 + 1;
        };
        dfs_init(node, 0, 0);
        if (neortodox[node] < k)
        {
            return 0;
        }
        vector<int> power(max_depth + 1);
        power[0] = 1;
        for (int i = 1; i <= max_depth; ++i)
        {
            power[i] = mult(power[i - 1], base);
        }
        function<void(int, int)> compute_hash = [&](int node, int parent)
        {
            hashup[node] = add(mult(base, hashup[parent]), colors[node] - 'a' + 1);
            hashdown[node] = add(hashdown[parent], mult(power[depth[node]], (colors[node] - 'a' + 1)));
            for (auto i : g[node])
            {
                if (i != parent && !seen[i])
                {
                    compute_hash(i, node);
                }
            }
        };
        compute_hash(node, 0);
        function<int(int, int)> get_hashup = [&](int a, int b)
        {
            int c = par[b];
            return add(hashup[a], mod - mult(hashup[c], power[depth[a] - depth[c]]));
        };
        unordered_multiset<int> exista;
        function<void(int, int, int)> add_subtree = [&](int node, int parent, int root)
        {
            exista.insert(get_hashup(node, root));
            for (auto i : g[node])
            {
                if (i != parent && !seen[i])
                {
                    add_subtree(i, node, root);
                }
            }
        };
        function<void(int, int, int)> remove_subtree = [&](int node, int parent, int root)
        {
            exista.erase(exista.find(get_hashup(node, root)));
            for (auto i : g[node])
            {
                if (i != parent && !seen[i])
                {
                    remove_subtree(i, node, root);
                }
            }
        };
        bool este = false;
        int m = 1;
        nodes[1] = node;
        function<void(int, int, int)> dfs = [&](int node, int parent, int d)
        {
            if (este)
            {
                return;
            }
            nodes[++m] = node;
            int t = 2 * d - k;
            int l = k - d;
            if (l >= 0 && t >= 0)
            {
                if (l == 0)
                {
                    if (hashup[node] == hashdown[node])
                    {
                        este = true;
                    }
                }
                else
                {
                    int qui = nodes[m - l];
                    if (hashup[qui] == hashdown[qui] && exista.count(get_hashup(node, nodes[m - l + 1])))
                    {
                        este = true;
                    }
                }
            }
            for (auto i : g[node])
            {
                if (i != parent && !seen[i])
                {
                    dfs(i, node, d + 1);
                }
            }
            --m;
        };
        for (auto i : g[node])
        {
            if (!seen[i])
            {
                add_subtree(i, node, i);
            }
        }
        for (auto i : g[node])
        {
            if (!seen[i])
            {
                remove_subtree(i, node, i);
                dfs(i, node, 2);
                if (este)
                {
                    break;
                }
                add_subtree(i, node, i);
            }
        }
        return este;
    }
    int decomp(int node, int k)
    {
        dfs_size(node, 0);
        node = find_centroid(node, 0, sz[node]);
        int ans = solve(node, k);
        seen[node] = true;
        for (auto i : g[node])
        {
            if (!seen[i])
            {
                ans = max(ans, decomp(i, k));
            }
        }
        return ans;
    }
    void reinit()
    {
        seen = vector<bool>(n + 1);
    }
};
int32_t main()
{
    cin.tie(nullptr)->sync_with_stdio(false);
    int n;
    cin >> n;
    lampice g;
    g.init(n);
    for (int i = 1; i <= n; ++i)
    {
        char x;
        cin >> x;
        g.set_color(i, x);
    }
    for (int i = 1; i < n; ++i)
    {
        int u, v;
        cin >> u >> v;
        g.add_edge(u, v);
    }
    int ans = 1;
    int st = 1, dr = n / 2;
    while (st <= dr)
    {
        int mid = (st + dr) / 2;
        if (g.decomp(1, 2 * mid))
        {
            ans = max(ans, 2 * mid);
            st = mid + 1;
        }
        else
        {
            dr = mid - 1;
        }
        g.reinit();
    }
    st = max(1, ans / 2), dr = n / 2;
    while (st <= dr)
    {
        int mid = (st + dr) / 2;
        if (g.decomp(1, 2 * mid + 1))
        {
            ans = max(ans, 2 * mid + 1);
            st = mid + 1;
        }
        else
        {
            dr = mid - 1;
        }
        g.reinit();
    }
    cout << ans;
}

Subtask #1

17.0 / 17.0

#	Verdict	Execution time	Memory	Grader output
1	Correct	3 ms	340 KB	Output is correct
2	Correct	7 ms	416 KB	Output is correct
3	Correct	30 ms	552 KB	Output is correct
4	Correct	52 ms	596 KB	Output is correct
5	Correct	0 ms	212 KB	Output is correct
6	Correct	1 ms	212 KB	Output is correct
7	Correct	0 ms	212 KB	Output is correct

Subtask #2

25.0 / 25.0

#	Verdict	Execution time	Memory	Grader output
1	Correct	3656 ms	9348 KB	Output is correct
2	Correct	1538 ms	9428 KB	Output is correct
3	Correct	696 ms	9664 KB	Output is correct
4	Correct	761 ms	10040 KB	Output is correct
5	Correct	1324 ms	10272 KB	Output is correct
6	Correct	636 ms	10244 KB	Output is correct

Subtask #3

0 / 31.0

#	Verdict	Execution time	Memory	Grader output
1	Execution timed out	5019 ms	8368 KB	Time limit exceeded
2	Halted	0 ms	0 KB	-

Subtask #4

0 / 37.0

#	Verdict	Execution time	Memory	Grader output
1	Correct	3 ms	340 KB	Output is correct
2	Correct	7 ms	416 KB	Output is correct
3	Correct	30 ms	552 KB	Output is correct
4	Correct	52 ms	596 KB	Output is correct
5	Correct	0 ms	212 KB	Output is correct
6	Correct	1 ms	212 KB	Output is correct
7	Correct	0 ms	212 KB	Output is correct
8	Correct	3656 ms	9348 KB	Output is correct
9	Correct	1538 ms	9428 KB	Output is correct
10	Correct	696 ms	9664 KB	Output is correct
11	Correct	761 ms	10040 KB	Output is correct
12	Correct	1324 ms	10272 KB	Output is correct
13	Correct	636 ms	10244 KB	Output is correct
14	Execution timed out	5019 ms	8368 KB	Time limit exceeded
15	Halted	0 ms	0 KB	-