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IDProblemSubmitterResultTimeMemoryLanguageFile sizeSubmit timeJudge time
#230970#7640. Colorful Cyclesucup-team296#WA 152ms2096kbRust45.0kb2023-10-28 22:39:132023-10-28 22:39:13

Judging History

你现在查看的是最新测评结果

  • [2024-07-04 22:58:32]
  • hack成功,自动添加数据
  • (/hack/728)
  • [2023-10-28 22:39:13]
  • 评测
  • 测评结果:WA
  • 用时:152ms
  • 内存:2096kb
  • [2023-10-28 22:39:13]
  • 提交

answer

// 
pub mod solution {

use crate::collections::bit_set::BitSet;
use crate::collections::default_map::default_hash_map::DefaultHashMap;
use crate::graph::cut_points::CutPointSearch;
use crate::graph::edges::bi_weighted_edge::BiWeightedEdge;
use crate::graph::edges::edge_trait::EdgeTrait;
use crate::graph::edges::weighted_edge_trait::WeightedEdgeTrait;
use crate::graph::graph::Graph;
use crate::io::input::Input;
use crate::io::output::{BoolOutput, Output};
use crate::misc::recursive_function::{Callable2, RecursiveFunction2};
use crate::numbers::num_traits::bit_ops::BitOps;

type PreCalc = ();

fn solve(input: &mut Input, out: &mut Output, _test_case: usize, _data: &PreCalc) {
    let n = input.read_size();
    let m = input.read_size();
    let edges = input.read_vec::<(usize, usize, usize)>(m);

    let mut graph = Graph::new(n);
    for (u, v, c) in edges {
        graph.add_edge(u - 1, BiWeightedEdge::new(v - 1, c));
    }
    let cut_points = graph.cut_points();
    let is_cut = BitSet::from_slice(n, &cut_points);
    let mut done = BitSet::new(n);
    for i in 0..n {
        if done[i] || is_cut[i] {
            continue;
        }
        let mut seen_colors = DefaultHashMap::<_, u8>::new();
        let mut dfs = RecursiveFunction2::new(|f, vert: usize, prev: usize| {
            done.set(vert);
            for e in &graph[vert] {
                if e.to() == prev {
                    continue;
                }
                seen_colors[e.to()].set_bit(e.weight());
                seen_colors[vert].set_bit(e.weight());
                if !done[e.to()] && !is_cut[e.to()] {
                    f.call(e.to(), vert);
                }
            }
        });
        dfs.call(i, i);
        let mut qty = 0;
        for &m in seen_colors.values() {
            if m.count_ones() > 1 {
                qty += 1;
            }
        }
        if qty > 2 {
            out.print_line(true);
            return;
        }
    }

    out.print_line(false);
}

pub(crate) fn run(mut input: Input, mut output: Output) -> bool {
    let pre_calc = ();

    #[allow(dead_code)]
    enum TestType {
        Single,
        MultiNumber,
        MultiEof,
    }
    let test_type = TestType::MultiNumber;
    output.set_bool_output(BoolOutput::YesNo);
    match test_type {
        TestType::Single => solve(&mut input, &mut output, 1, &pre_calc),
        TestType::MultiNumber => {
            let t = input.read();
            for i in 1..=t {
                solve(&mut input, &mut output, i, &pre_calc);
            }
        }
        TestType::MultiEof => {
            let mut i = 1;
            while input.peek().is_some() {
                solve(&mut input, &mut output, i, &pre_calc);
                i += 1;
            }
        }
    }
    output.flush();
    input.skip_whitespace();
    input.peek().is_none()
}

}
pub mod collections {
pub mod bit_set {
use crate::collections::slice_ext::legacy_fill::LegacyFill;
use crate::numbers::num_traits::bit_ops::BitOps;
use std::ops::{BitAndAssign, BitOrAssign, Index};

const TRUE: bool = true;
const FALSE: bool = false;

#[derive(Clone, Eq, PartialEq)]
pub struct BitSet {
    data: Vec<u64>,
    len: usize,
}

impl BitSet {
    pub fn new(len: usize) -> Self {
        let data_len = if len == 0 {
            0
        } else {
            Self::index(len - 1) + 1
        };
        Self {
            data: vec![0; data_len],
            len,
        }
    }
    
    pub fn from_slice(len: usize, set: &[usize]) -> Self {
        let mut res = Self::new(len);
        for &i in set {
            res.set(i);
        }
        res
    }

    pub fn set(&mut self, at: usize) {
        assert!(at < self.len);
        self.data[Self::index(at)].set_bit(at & 63);
    }

    pub fn unset(&mut self, at: usize) {
        assert!(at < self.len);
        self.data[Self::index(at)].unset_bit(at & 63);
    }

    pub fn change(&mut self, at: usize, value: bool) {
        if value {
            self.set(at);
        } else {
            self.unset(at);
        }
    }

    pub fn flip(&mut self, at: usize) {
        self.change(at, !self[at]);
    }

    #[allow(clippy::len_without_is_empty)]
    pub fn len(&self) -> usize {
        self.len
    }

    pub fn fill(&mut self, value: bool) {
        // 1.43
        self.data.legacy_fill(if value { std::u64::MAX } else { 0 })
    }

    pub fn is_superset(&self, other: &Self) -> bool {
        assert_eq!(self.len, other.len);
        for i in 0..self.data.len() {
            if self.data[i] & other.data[i] != other.data[i] {
                return false;
            }
        }
        true
    }

    pub fn is_subset(&self, other: &Self) -> bool {
        other.is_superset(self)
    }

    pub fn iter(&self) -> impl Iterator<Item = usize> + '_ {
        self.into_iter()
    }

    fn index(at: usize) -> usize {
        at >> 6
    }

    pub fn count_ones(&self) -> usize {
        self.data.iter().map(|x| x.count_ones() as usize).sum()
    }
}

pub struct BitSetIter<'s> {
    at: usize,
    inside: usize,
    set: &'s BitSet,
}

impl<'s> Iterator for BitSetIter<'s> {
    type Item = usize;

    fn next(&mut self) -> Option<Self::Item> {
        while self.at < self.set.data.len()
            && (self.inside == 64 || (self.set.data[self.at] >> self.inside) == 0)
        {
            self.at += 1;
            self.inside = 0;
        }
        if self.at == self.set.data.len() {
            None
        } else {
            while !self.set.data[self.at].is_set(self.inside) {
                self.inside += 1;
            }
            let res = self.at * 64 + self.inside;
            if res < self.set.len {
                self.inside += 1;
                Some(res)
            } else {
                None
            }
        }
    }
}

impl<'a> IntoIterator for &'a BitSet {
    type Item = usize;
    type IntoIter = BitSetIter<'a>;

    fn into_iter(self) -> Self::IntoIter {
        BitSetIter {
            at: 0,
            inside: 0,
            set: self,
        }
    }
}

impl BitOrAssign<&BitSet> for BitSet {
    fn bitor_assign(&mut self, rhs: &BitSet) {
        assert_eq!(self.len, rhs.len);
        for (i, &j) in self.data.iter_mut().zip(rhs.data.iter()) {
            *i |= j;
        }
    }
}

impl BitAndAssign<&BitSet> for BitSet {
    fn bitand_assign(&mut self, rhs: &BitSet) {
        assert_eq!(self.len, rhs.len);
        for (i, &j) in self.data.iter_mut().zip(rhs.data.iter()) {
            *i &= j;
        }
    }
}

impl Index<usize> for BitSet {
    type Output = bool;

    fn index(&self, at: usize) -> &Self::Output {
        assert!(at < self.len);
        if self.data[Self::index(at)].is_set(at & 63) {
            &TRUE
        } else {
            &FALSE
        }
    }
}

impl From<Vec<bool>> for BitSet {
    fn from(data: Vec<bool>) -> Self {
        let mut res = Self::new(data.len());
        for (i, &value) in data.iter().enumerate() {
            res.change(i, value);
        }
        res
    }
}
}
pub mod default_map {
pub mod default_hash_map {
use std::collections::HashMap;
use std::hash::Hash;
use std::iter::FromIterator;
use std::ops::{Deref, DerefMut, Index, IndexMut};

#[derive(Default, Clone, Eq, PartialEq)]
pub struct DefaultHashMap<K: Hash + Eq, V>(HashMap<K, V>, V);

impl<K: Hash + Eq, V> Deref for DefaultHashMap<K, V> {
    type Target = HashMap<K, V>;

    fn deref(&self) -> &Self::Target {
        &self.0
    }
}

impl<K: Hash + Eq, V> DerefMut for DefaultHashMap<K, V> {
    fn deref_mut(&mut self) -> &mut Self::Target {
        &mut self.0
    }
}

impl<K: Hash + Eq, V: Default> DefaultHashMap<K, V> {
    pub fn new() -> Self {
        Self(HashMap::new(), V::default())
    }

    pub fn with_capacity(cap: usize) -> Self {
        Self(HashMap::with_capacity(cap), V::default())
    }

    pub fn get(&self, key: &K) -> &V {
        self.0.get(key).unwrap_or(&self.1)
    }

    pub fn get_mut(&mut self, key: K) -> &mut V {
        self.0.entry(key).or_insert_with(|| V::default())
    }

    pub fn into_values(self) -> std::collections::hash_map::IntoValues<K, V> {
        self.0.into_values()
    }
}

impl<K: Hash + Eq, V: Default> Index<K> for DefaultHashMap<K, V> {
    type Output = V;

    fn index(&self, index: K) -> &Self::Output {
        self.get(&index)
    }
}

impl<K: Hash + Eq, V: Default> IndexMut<K> for DefaultHashMap<K, V> {
    fn index_mut(&mut self, index: K) -> &mut Self::Output {
        self.get_mut(index)
    }
}

impl<K: Hash + Eq, V> IntoIterator for DefaultHashMap<K, V> {
    type Item = (K, V);
    type IntoIter = std::collections::hash_map::IntoIter<K, V>;

    fn into_iter(self) -> Self::IntoIter {
        self.0.into_iter()
    }
}

impl<K: Hash + Eq, V: Default> FromIterator<(K, V)> for DefaultHashMap<K, V> {
    fn from_iter<T: IntoIterator<Item = (K, V)>>(iter: T) -> Self {
        Self(iter.into_iter().collect(), V::default())
    }
}
}
}
pub mod dsu {
use crate::collections::iter_ext::collect::IterCollect;
use crate::collections::slice_ext::bounds::Bounds;
use crate::collections::slice_ext::legacy_fill::LegacyFill;
use std::cell::Cell;

#[derive(Clone)]
pub struct DSU {
    id: Vec<Cell<u32>>,
    size: Vec<u32>,
    count: usize,
}

impl DSU {
    pub fn new(n: usize) -> Self {
        Self {
            id: (0..n).map(|i| Cell::new(i as u32)).collect_vec(),
            size: vec![1; n],
            count: n,
        }
    }

    pub fn size(&self, i: usize) -> usize {
        self.size[self.get(i)] as usize
    }

    #[allow(clippy::len_without_is_empty)]
    pub fn len(&self) -> usize {
        self.id.len()
    }

    pub fn iter(&self) -> impl Iterator<Item = usize> + '_ {
        self.id.iter().enumerate().filter_map(|(i, id)| {
            if (i as u32) == id.get() {
                Some(i)
            } else {
                None
            }
        })
    }

    pub fn set_count(&self) -> usize {
        self.count
    }

    pub fn join(&mut self, mut a: usize, mut b: usize) -> bool {
        a = self.get(a);
        b = self.get(b);
        if a == b {
            false
        } else {
            self.size[a] += self.size[b];
            self.id[b].replace(a as u32);
            self.count -= 1;
            true
        }
    }

    pub fn get(&self, i: usize) -> usize {
        if self.id[i].get() != i as u32 {
            let res = self.get(self.id[i].get() as usize);
            self.id[i].replace(res as u32);
        }
        self.id[i].get() as usize
    }

    pub fn clear(&mut self) {
        self.count = self.id.len();
        self.size.legacy_fill(1);
        self.id.iter().enumerate().for_each(|(i, id)| {
            id.replace(i as u32);
        });
    }

    pub fn parts(&self) -> Vec<Vec<usize>> {
        let roots = self.iter().collect_vec();
        let mut res = vec![Vec::new(); roots.len()];
        for i in 0..self.id.len() {
            res[roots.as_slice().bin_search(&self.get(i)).unwrap()].push(i);
        }
        res
    }
}
}
pub mod iter_ext {
pub mod collect {
pub trait IterCollect<T>: Iterator<Item = T> + Sized {
    fn collect_vec(self) -> Vec<T> {
        self.collect()
    }
}

impl<T, I: Iterator<Item = T> + Sized> IterCollect<T> for I {}
}
}
pub mod min_max {
pub trait MinimMaxim<Rhs = Self>: PartialOrd + Sized {
    fn minim(&mut self, other: Rhs) -> bool;

    fn maxim(&mut self, other: Rhs) -> bool;
}

impl<T: PartialOrd> MinimMaxim for T {
    fn minim(&mut self, other: Self) -> bool {
        if other < *self {
            *self = other;
            true
        } else {
            false
        }
    }

    fn maxim(&mut self, other: Self) -> bool {
        if other > *self {
            *self = other;
            true
        } else {
            false
        }
    }
}

impl<T: PartialOrd> MinimMaxim<T> for Option<T> {
    fn minim(&mut self, other: T) -> bool {
        match self {
            None => {
                *self = Some(other);
                true
            }
            Some(v) => v.minim(other),
        }
    }

    fn maxim(&mut self, other: T) -> bool {
        match self {
            None => {
                *self = Some(other);
                true
            }
            Some(v) => v.maxim(other),
        }
    }
}
}
pub mod slice_ext {
pub mod bounds {
pub trait Bounds<T: PartialOrd> {
    fn lower_bound(&self, el: &T) -> usize;
    fn upper_bound(&self, el: &T) -> usize;
    fn bin_search(&self, el: &T) -> Option<usize>;
    fn more(&self, el: &T) -> usize;
    fn more_or_eq(&self, el: &T) -> usize;
    fn less(&self, el: &T) -> usize;
    fn less_or_eq(&self, el: &T) -> usize;
}

impl<T: PartialOrd> Bounds<T> for [T] {
    fn lower_bound(&self, el: &T) -> usize {
        let mut left = 0;
        let mut right = self.len();
        while left < right {
            let mid = left + ((right - left) >> 1);
            if &self[mid] < el {
                left = mid + 1;
            } else {
                right = mid;
            }
        }
        left
    }

    fn upper_bound(&self, el: &T) -> usize {
        let mut left = 0;
        let mut right = self.len();
        while left < right {
            let mid = left + ((right - left) >> 1);
            if &self[mid] <= el {
                left = mid + 1;
            } else {
                right = mid;
            }
        }
        left
    }

    fn bin_search(&self, el: &T) -> Option<usize> {
        let at = self.lower_bound(el);
        if at == self.len() || &self[at] != el {
            None
        } else {
            Some(at)
        }
    }

    fn more(&self, el: &T) -> usize {
        self.len() - self.upper_bound(el)
    }

    fn more_or_eq(&self, el: &T) -> usize {
        self.len() - self.lower_bound(el)
    }

    fn less(&self, el: &T) -> usize {
        self.lower_bound(el)
    }

    fn less_or_eq(&self, el: &T) -> usize {
        self.upper_bound(el)
    }
}
}
pub mod legacy_fill {
// 1.50
pub trait LegacyFill<T> {
    fn legacy_fill(&mut self, val: T);
}

impl<T: Clone> LegacyFill<T> for [T] {
    fn legacy_fill(&mut self, val: T) {
        for el in self.iter_mut() {
            *el = val.clone();
        }
    }
}
}
}
pub mod vec_ext {
pub mod default {
pub fn default_vec<T: Default>(len: usize) -> Vec<T> {
    let mut v = Vec::with_capacity(len);
    for _ in 0..len {
        v.push(T::default());
    }
    v
}
}
}
}
pub mod graph {
pub mod cut_points {
use crate::collections::bit_set::BitSet;
use crate::collections::min_max::MinimMaxim;
use crate::graph::edges::edge_trait::EdgeTrait;
use crate::graph::graph::Graph;
use crate::misc::recursive_function::{Callable2, RecursiveFunction2};

pub trait CutPointSearch {
    fn cut_points(&self) -> Vec<usize>;
}

impl<E: EdgeTrait> CutPointSearch for Graph<E> {
    fn cut_points(&self) -> Vec<usize> {
        assert!(E::REVERSABLE);
        let n = self.vertex_count();
        let mut timer = 0;
        let mut tin = vec![0; n];
        let mut fup = vec![0; n];
        let mut used = BitSet::new(n);
        let mut ans = Vec::new();
        for i in 0..n {
            if !used[i] {
                let mut dfs = RecursiveFunction2::new(|f, vert: usize, prev: usize| {
                    let mut children = 0;
                    used.set(vert);
                    tin[vert] = timer;
                    fup[vert] = timer;
                    timer += 1;
                    for e in &self[vert] {
                        if e.to() == prev {
                            continue;
                        }
                        let to = e.to();
                        if used[to] {
                            fup[vert].minim(tin[to]);
                        } else {
                            f.call(to, vert);
                            let cand = fup[to];
                            fup[vert].minim(cand);
                            if fup[to] >= tin[vert] && prev != n {
                                ans.push(vert);
                            }
                            children += 1;
                        }
                    }
                    if prev == n && children > 1 {
                        ans.push(vert);
                    }
                });
                dfs.call(i, n);
            }
        }
        ans
    }
}
}
pub mod edges {
pub mod bi_edge {
use crate::graph::edges::bi_edge_trait::BiEdgeTrait;
use crate::graph::edges::edge_id::{EdgeId, NoId, WithId};
use crate::graph::edges::edge_trait::{BidirectionalEdgeTrait, EdgeTrait};
use crate::graph::graph::Graph;
use crate::io::input::{Input, Readable};

#[derive(Clone)]
pub struct BiEdgeRaw<Id: EdgeId> {
    to: u32,
    id: Id,
}

impl<Id: EdgeId> BiEdgeRaw<Id> {
    pub fn new(to: usize) -> Self {
        Self {
            to: to as u32,
            id: Id::new(),
        }
    }
}

impl<Id: EdgeId> BidirectionalEdgeTrait for BiEdgeRaw<Id> {}

impl<Id: EdgeId> EdgeTrait for BiEdgeRaw<Id> {
    const REVERSABLE: bool = true;

    fn to(&self) -> usize {
        self.to as usize
    }

    fn id(&self) -> usize {
        self.id.id()
    }

    fn set_id(&mut self, id: usize) {
        self.id.set_id(id);
    }

    fn reverse_id(&self) -> usize {
        panic!("no reverse id")
    }

    fn set_reverse_id(&mut self, _: usize) {}

    fn reverse_edge(&self, from: usize) -> Self {
        Self::new(from)
    }
}

impl<Id: EdgeId> BiEdgeTrait for BiEdgeRaw<Id> {}

pub type BiEdge = BiEdgeRaw<NoId>;
pub type BiEdgeWithId = BiEdgeRaw<WithId>;

pub trait ReadBiEdgeGraph {
    fn read_graph<Id: EdgeId>(&mut self, n: usize, m: usize) -> Graph<BiEdgeRaw<Id>>;

    fn read_tree<Id: EdgeId>(&mut self, n: usize) -> Graph<BiEdgeRaw<Id>> {
        self.read_graph(n, n - 1)
    }
}

impl ReadBiEdgeGraph for Input<'_> {
    fn read_graph<Id: EdgeId>(&mut self, n: usize, m: usize) -> Graph<BiEdgeRaw<Id>> {
        let mut graph = Graph::new(n);
        for _ in 0..m {
            graph.add_edge(self.read(), BiEdgeRaw::new(self.read()));
        }
        graph
    }
}

impl<Id: EdgeId> Readable for Graph<BiEdgeRaw<Id>> {
    fn read(input: &mut Input) -> Self {
        let n = input.read();
        let m = input.read();
        <Input as ReadBiEdgeGraph>::read_graph(input, n, m)
    }
}
}
pub mod bi_edge_trait {
use crate::graph::edges::edge_trait::EdgeTrait;

pub trait BiEdgeTrait: EdgeTrait {}
}
pub mod bi_weighted_edge {
use crate::graph::edges::bi_edge_trait::BiEdgeTrait;
use crate::graph::edges::edge_id::{EdgeId, NoId, WithId};
use crate::graph::edges::edge_trait::{BidirectionalEdgeTrait, EdgeTrait};
use crate::graph::edges::weighted_edge_trait::WeightedEdgeTrait;
use crate::graph::graph::Graph;
use crate::io::input::{Input, Readable};
use crate::numbers::num_traits::add_sub::Addable;
use crate::numbers::num_traits::zero_one::ZeroOne;

#[derive(Clone)]
pub struct BiWeightedEdgeRaw<W: Copy, Id: EdgeId> {
    to: u32,
    weight: W,
    id: Id,
}

impl<W: Copy, Id: EdgeId> BiWeightedEdgeRaw<W, Id> {
    pub fn new(to: usize, w: W) -> Self {
        Self {
            to: to as u32,
            weight: w,
            id: Id::new(),
        }
    }
}

impl<W: Copy, Id: EdgeId> BidirectionalEdgeTrait for BiWeightedEdgeRaw<W, Id> {}

impl<W: Copy, Id: EdgeId> EdgeTrait for BiWeightedEdgeRaw<W, Id> {
    const REVERSABLE: bool = true;

    fn to(&self) -> usize {
        self.to as usize
    }

    fn id(&self) -> usize {
        self.id.id()
    }

    fn set_id(&mut self, id: usize) {
        self.id.set_id(id);
    }

    fn reverse_id(&self) -> usize {
        panic!("no reverse")
    }

    fn set_reverse_id(&mut self, _: usize) {}

    fn reverse_edge(&self, from: usize) -> Self {
        Self::new(from, self.weight)
    }
}

impl<W: Copy, Id: EdgeId> BiEdgeTrait for BiWeightedEdgeRaw<W, Id> {}

impl<W: Copy, Id: EdgeId> WeightedEdgeTrait<W> for BiWeightedEdgeRaw<W, Id> {
    fn weight(&self) -> W {
        self.weight
    }

    fn weight_mut(&mut self) -> &mut W {
        &mut self.weight
    }
}

pub type BiWeightedEdge<W> = BiWeightedEdgeRaw<W, NoId>;
pub type BiWeightedEdgeWithId<W> = BiWeightedEdgeRaw<W, WithId>;

pub trait ReadBiWeightedEdgeGraph {
    fn read_graph<W: Addable + Copy + ZeroOne + Readable, Id: EdgeId>(
        &mut self,
        n: usize,
        m: usize,
    ) -> Graph<BiWeightedEdgeRaw<W, Id>>;

    fn read_tree<W: Addable + Copy + ZeroOne + Readable, Id: EdgeId>(
        &mut self,
        n: usize,
    ) -> Graph<BiWeightedEdgeRaw<W, Id>> {
        self.read_graph(n, n - 1)
    }
}

impl ReadBiWeightedEdgeGraph for Input<'_> {
    fn read_graph<W: Addable + Copy + ZeroOne + Readable, Id: EdgeId>(
        &mut self,
        n: usize,
        m: usize,
    ) -> Graph<BiWeightedEdgeRaw<W, Id>> {
        let mut graph = Graph::new(n);
        for _ in 0..m {
            graph.add_edge(
                self.read(),
                BiWeightedEdgeRaw::new(self.read(), self.read()),
            );
        }
        graph
    }
}

impl<W: Addable + Copy + ZeroOne + Readable, Id: EdgeId> Readable
    for Graph<BiWeightedEdgeRaw<W, Id>>
{
    fn read(input: &mut Input) -> Self {
        let n = input.read();
        let m = input.read();
        <Input as ReadBiWeightedEdgeGraph>::read_graph(input, n, m)
    }
}
}
pub mod edge {
use crate::graph::edges::edge_id::{EdgeId, NoId, WithId};
use crate::graph::edges::edge_trait::EdgeTrait;
use crate::graph::graph::Graph;
use crate::io::input::{Input, Readable};

#[derive(Clone)]
pub struct EdgeRaw<Id: EdgeId> {
    to: u32,
    id: Id,
}

impl<Id: EdgeId> EdgeRaw<Id> {
    pub fn new(to: usize) -> Self {
        Self {
            to: to as u32,
            id: Id::new(),
        }
    }
}

impl<Id: EdgeId> EdgeTrait for EdgeRaw<Id> {
    const REVERSABLE: bool = false;

    fn to(&self) -> usize {
        self.to as usize
    }

    fn id(&self) -> usize {
        self.id.id()
    }

    fn set_id(&mut self, id: usize) {
        self.id.set_id(id);
    }

    fn reverse_id(&self) -> usize {
        panic!("no reverse")
    }

    fn set_reverse_id(&mut self, _: usize) {
        panic!("no reverse")
    }

    fn reverse_edge(&self, _: usize) -> Self {
        panic!("no reverse")
    }
}

pub type Edge = EdgeRaw<NoId>;
pub type EdgeWithId = EdgeRaw<WithId>;

pub trait ReadEdgeGraph {
    fn read_graph<Id: EdgeId>(&mut self, n: usize, m: usize) -> Graph<EdgeRaw<Id>>;
}

impl ReadEdgeGraph for Input<'_> {
    fn read_graph<Id: EdgeId>(&mut self, n: usize, m: usize) -> Graph<EdgeRaw<Id>> {
        let mut graph = Graph::new(n);
        for _ in 0..m {
            graph.add_edge(self.read(), EdgeRaw::new(self.read()));
        }
        graph
    }
}

impl<Id: EdgeId> Readable for Graph<EdgeRaw<Id>> {
    fn read(input: &mut Input) -> Self {
        let n = input.read();
        let m = input.read();
        <Input as ReadEdgeGraph>::read_graph(input, n, m)
    }
}
}
pub mod edge_id {
pub trait EdgeId: Clone {
    fn new() -> Self;
    fn id(&self) -> usize;
    fn set_id(&mut self, id: usize);
}

#[derive(Clone)]
pub struct WithId {
    id: u32,
}

impl EdgeId for WithId {
    fn new() -> Self {
        Self { id: 0 }
    }

    fn id(&self) -> usize {
        self.id as usize
    }

    fn set_id(&mut self, id: usize) {
        self.id = id as u32;
    }
}

#[derive(Clone)]
pub struct NoId {}

impl EdgeId for NoId {
    fn new() -> Self {
        Self {}
    }

    fn id(&self) -> usize {
        panic!("Id called on no id")
    }

    fn set_id(&mut self, _: usize) {}
}
}
pub mod edge_trait {
pub trait EdgeTrait: Clone {
    const REVERSABLE: bool;

    fn to(&self) -> usize;
    fn id(&self) -> usize;
    fn set_id(&mut self, id: usize);
    fn reverse_id(&self) -> usize;
    fn set_reverse_id(&mut self, reverse_id: usize);
    #[must_use]
    fn reverse_edge(&self, from: usize) -> Self;
}

pub trait BidirectionalEdgeTrait: EdgeTrait {}
}
pub mod weighted_edge_trait {
use crate::graph::edges::edge_trait::EdgeTrait;

pub trait WeightedEdgeTrait<W: Copy>: EdgeTrait {
    fn weight(&self) -> W;
    fn weight_mut(&mut self) -> &mut W;
}
}
}
pub mod graph {
use crate::collections::dsu::DSU;
use crate::graph::edges::bi_edge::BiEdge;
use crate::graph::edges::edge::Edge;
use crate::graph::edges::edge_trait::{BidirectionalEdgeTrait, EdgeTrait};
use std::ops::{Index, IndexMut};

pub struct Graph<E: EdgeTrait> {
    pub(super) edges: Vec<Vec<E>>,
    edge_count: usize,
}

impl<E: EdgeTrait> Graph<E> {
    pub fn new(vertex_count: usize) -> Self {
        Self {
            edges: vec![Vec::new(); vertex_count],
            edge_count: 0,
        }
    }

    pub fn add_edge(&mut self, from: usize, mut edge: E) -> usize {
        let to = edge.to();
        assert!(to < self.edges.len());
        let direct_id = self.edges[from].len();
        edge.set_id(self.edge_count);
        self.edges[from].push(edge);
        if E::REVERSABLE {
            let rev_id = self.edges[to].len();
            self.edges[from][direct_id].set_reverse_id(rev_id);
            let mut rev_edge = self.edges[from][direct_id].reverse_edge(from);
            rev_edge.set_id(self.edge_count);
            rev_edge.set_reverse_id(direct_id);
            self.edges[to].push(rev_edge);
        }
        self.edge_count += 1;
        direct_id
    }

    pub fn add_vertices(&mut self, cnt: usize) {
        self.edges.resize(self.edges.len() + cnt, Vec::new());
    }

    pub fn clear(&mut self) {
        self.edge_count = 0;
        for ve in self.edges.iter_mut() {
            ve.clear();
        }
    }

    pub fn vertex_count(&self) -> usize {
        self.edges.len()
    }

    pub fn edge_count(&self) -> usize {
        self.edge_count
    }
}

impl<E: BidirectionalEdgeTrait> Graph<E> {
    pub fn is_tree(&self) -> bool {
        if self.edge_count + 1 != self.vertex_count() {
            false
        } else {
            self.is_connected()
        }
    }

    pub fn is_forest(&self) -> bool {
        let mut dsu = DSU::new(self.vertex_count());
        for i in 0..self.vertex_count() {
            for e in self[i].iter() {
                if i <= e.to() && !dsu.join(i, e.to()) {
                    return false;
                }
            }
        }
        true
    }

    pub fn is_connected(&self) -> bool {
        let mut dsu = DSU::new(self.vertex_count());
        for i in 0..self.vertex_count() {
            for e in self[i].iter() {
                dsu.join(i, e.to());
            }
        }
        dsu.set_count() == 1
    }
}

impl<E: EdgeTrait> Index<usize> for Graph<E> {
    type Output = [E];

    fn index(&self, index: usize) -> &Self::Output {
        &self.edges[index]
    }
}

impl<E: EdgeTrait> IndexMut<usize> for Graph<E> {
    fn index_mut(&mut self, index: usize) -> &mut Self::Output {
        &mut self.edges[index]
    }
}

impl Graph<Edge> {
    pub fn from_edges(n: usize, edges: &[(usize, usize)]) -> Self {
        let mut graph = Self::new(n);
        for &(from, to) in edges {
            graph.add_edge(from, Edge::new(to));
        }
        graph
    }
}

impl Graph<BiEdge> {
    pub fn from_biedges(n: usize, edges: &[(usize, usize)]) -> Self {
        let mut graph = Self::new(n);
        for &(from, to) in edges {
            graph.add_edge(from, BiEdge::new(to));
        }
        graph
    }
}
}
}
pub mod io {
pub mod input {
use crate::collections::vec_ext::default::default_vec;
use std::io::Read;

pub struct Input<'s> {
    input: &'s mut dyn Read,
    buf: Vec<u8>,
    at: usize,
    buf_read: usize,
}

macro_rules! read_impl {
    ($t: ty, $read_name: ident, $read_vec_name: ident) => {
        pub fn $read_name(&mut self) -> $t {
            self.read()
        }

        pub fn $read_vec_name(&mut self, len: usize) -> Vec<$t> {
            self.read_vec(len)
        }
    };

    ($t: ty, $read_name: ident, $read_vec_name: ident, $read_pair_vec_name: ident) => {
        read_impl!($t, $read_name, $read_vec_name);

        pub fn $read_pair_vec_name(&mut self, len: usize) -> Vec<($t, $t)> {
            self.read_vec(len)
        }
    };
}

impl<'s> Input<'s> {
    const DEFAULT_BUF_SIZE: usize = 4096;

    pub fn new(input: &'s mut dyn Read) -> Self {
        Self {
            input,
            buf: default_vec(Self::DEFAULT_BUF_SIZE),
            at: 0,
            buf_read: 0,
        }
    }

    pub fn new_with_size(input: &'s mut dyn Read, buf_size: usize) -> Self {
        Self {
            input,
            buf: default_vec(buf_size),
            at: 0,
            buf_read: 0,
        }
    }

    pub fn get(&mut self) -> Option<u8> {
        if self.refill_buffer() {
            let res = self.buf[self.at];
            self.at += 1;
            if res == b'\r' {
                if self.refill_buffer() && self.buf[self.at] == b'\n' {
                    self.at += 1;
                }
                return Some(b'\n');
            }
            Some(res)
        } else {
            None
        }
    }

    pub fn peek(&mut self) -> Option<u8> {
        if self.refill_buffer() {
            let res = self.buf[self.at];
            Some(if res == b'\r' { b'\n' } else { res })
        } else {
            None
        }
    }

    pub fn skip_whitespace(&mut self) {
        while let Some(b) = self.peek() {
            if !char::from(b).is_whitespace() {
                return;
            }
            self.get();
        }
    }

    pub fn next_token(&mut self) -> Option<Vec<u8>> {
        self.skip_whitespace();
        let mut res = Vec::new();
        while let Some(c) = self.get() {
            if char::from(c).is_whitespace() {
                break;
            }
            res.push(c);
        }
        if res.is_empty() {
            None
        } else {
            Some(res)
        }
    }

    //noinspection RsSelfConvention
    pub fn is_exhausted(&mut self) -> bool {
        self.peek().is_none()
    }

    pub fn read<T: Readable>(&mut self) -> T {
        T::read(self)
    }

    pub fn read_vec<T: Readable>(&mut self, size: usize) -> Vec<T> {
        let mut res = Vec::with_capacity(size);
        for _ in 0..size {
            res.push(self.read());
        }
        res
    }

    pub fn read_char(&mut self) -> char {
        self.skip_whitespace();
        self.get().unwrap().into()
    }

    read_impl!(u32, read_unsigned, read_unsigned_vec);
    read_impl!(u64, read_u64, read_u64_vec);
    read_impl!(usize, read_size, read_size_vec, read_size_pair_vec);
    read_impl!(i32, read_int, read_int_vec, read_int_pair_vec);
    read_impl!(i64, read_long, read_long_vec, read_long_pair_vec);
    read_impl!(i128, read_i128, read_i128_vec);

    fn refill_buffer(&mut self) -> bool {
        if self.at == self.buf_read {
            self.at = 0;
            self.buf_read = self.input.read(&mut self.buf).unwrap();
            self.buf_read != 0
        } else {
            true
        }
    }
}

pub trait Readable {
    fn read(input: &mut Input) -> Self;
}

impl Readable for char {
    fn read(input: &mut Input) -> Self {
        input.read_char()
    }
}

impl<T: Readable> Readable for Vec<T> {
    fn read(input: &mut Input) -> Self {
        let size = input.read();
        input.read_vec(size)
    }
}

macro_rules! read_integer {
    ($($t:ident)+) => {$(
        impl Readable for $t {
            fn read(input: &mut Input) -> Self {
                input.skip_whitespace();
                let mut c = input.get().unwrap();
                let sgn = match c {
                    b'-' => {
                        c = input.get().unwrap();
                        true
                    }
                    b'+' => {
                        c = input.get().unwrap();
                        false
                    }
                    _ => false,
                };
                let mut res = 0;
                loop {
                    assert!(c.is_ascii_digit());
                    res *= 10;
                    let d = (c - b'0') as $t;
                    if sgn {
                        res -= d;
                    } else {
                        res += d;
                    }
                    match input.get() {
                        None => break,
                        Some(ch) => {
                            if ch.is_ascii_whitespace() {
                                break;
                            } else {
                                c = ch;
                            }
                        }
                    }
                }
                res
            }
        }
    )+};
}

read_integer!(i8 i16 i32 i64 i128 isize u8 u16 u32 u64 u128 usize);

macro_rules! tuple_readable {
    ($($name:ident)+) => {
        impl<$($name: Readable), +> Readable for ($($name,)+) {
            fn read(input: &mut Input) -> Self {
                ($($name::read(input),)+)
            }
        }
    }
}

tuple_readable! {T}
tuple_readable! {T U}
tuple_readable! {T U V}
tuple_readable! {T U V X}
tuple_readable! {T U V X Y}
tuple_readable! {T U V X Y Z}
tuple_readable! {T U V X Y Z A}
tuple_readable! {T U V X Y Z A B}
tuple_readable! {T U V X Y Z A B C}
tuple_readable! {T U V X Y Z A B C D}
tuple_readable! {T U V X Y Z A B C D E}
tuple_readable! {T U V X Y Z A B C D E F}

impl Read for Input<'_> {
    fn read(&mut self, buf: &mut [u8]) -> std::io::Result<usize> {
        if self.at == self.buf_read {
            self.input.read(buf)
        } else {
            let mut i = 0;
            while i < buf.len() && self.at < self.buf_read {
                buf[i] = self.buf[self.at];
                i += 1;
                self.at += 1;
            }
            Ok(i)
        }
    }
}
}
pub mod output {
use crate::collections::vec_ext::default::default_vec;
use std::io::{stderr, Stderr, Write};

#[derive(Copy, Clone)]
pub enum BoolOutput {
    YesNo,
    YesNoCaps,
    PossibleImpossible,
    Custom(&'static str, &'static str),
}

impl BoolOutput {
    pub fn output(&self, output: &mut Output, val: bool) {
        (if val { self.yes() } else { self.no() }).write(output);
    }

    fn yes(&self) -> &str {
        match self {
            BoolOutput::YesNo => "Yes",
            BoolOutput::YesNoCaps => "YES",
            BoolOutput::PossibleImpossible => "Possible",
            BoolOutput::Custom(yes, _) => yes,
        }
    }

    fn no(&self) -> &str {
        match self {
            BoolOutput::YesNo => "No",
            BoolOutput::YesNoCaps => "NO",
            BoolOutput::PossibleImpossible => "Impossible",
            BoolOutput::Custom(_, no) => no,
        }
    }
}

pub struct Output<'s> {
    output: &'s mut dyn Write,
    buf: Vec<u8>,
    at: usize,
    auto_flush: bool,
    bool_output: BoolOutput,
}

impl<'s> Output<'s> {
    const DEFAULT_BUF_SIZE: usize = 4096;

    pub fn new(output: &'s mut dyn Write) -> Self {
        Self {
            output,
            buf: default_vec(Self::DEFAULT_BUF_SIZE),
            at: 0,
            auto_flush: false,
            bool_output: BoolOutput::YesNoCaps,
        }
    }

    pub fn new_with_auto_flush(output: &'s mut dyn Write) -> Self {
        Self {
            output,
            buf: default_vec(Self::DEFAULT_BUF_SIZE),
            at: 0,
            auto_flush: true,
            bool_output: BoolOutput::YesNoCaps,
        }
    }

    pub fn flush(&mut self) {
        if self.at != 0 {
            self.output.write_all(&self.buf[..self.at]).unwrap();
            self.output.flush().unwrap();
            self.at = 0;
        }
    }

    pub fn print<T: Writable>(&mut self, s: T) {
        s.write(self);
        self.maybe_flush();
    }

    pub fn print_line<T: Writable>(&mut self, s: T) {
        self.print(s);
        self.put(b'\n');
        self.maybe_flush();
    }

    pub fn put(&mut self, b: u8) {
        self.buf[self.at] = b;
        self.at += 1;
        if self.at == self.buf.len() {
            self.flush();
        }
    }

    pub fn maybe_flush(&mut self) {
        if self.auto_flush {
            self.flush();
        }
    }

    pub fn print_per_line<T: Writable>(&mut self, arg: &[T]) {
        for i in arg {
            i.write(self);
            self.put(b'\n');
        }
    }

    pub fn print_iter<T: Writable, I: Iterator<Item = T>>(&mut self, iter: I) {
        let mut first = true;
        for e in iter {
            if first {
                first = false;
            } else {
                self.put(b' ');
            }
            e.write(self);
        }
    }

    pub fn print_iter_ref<'a, T: 'a + Writable, I: Iterator<Item = &'a T>>(&mut self, iter: I) {
        let mut first = true;
        for e in iter {
            if first {
                first = false;
            } else {
                self.put(b' ');
            }
            e.write(self);
        }
    }

    pub fn set_bool_output(&mut self, bool_output: BoolOutput) {
        self.bool_output = bool_output;
    }
}

impl Write for Output<'_> {
    fn write(&mut self, buf: &[u8]) -> std::io::Result<usize> {
        let mut start = 0usize;
        let mut rem = buf.len();
        while rem > 0 {
            let len = (self.buf.len() - self.at).min(rem);
            self.buf[self.at..self.at + len].copy_from_slice(&buf[start..start + len]);
            self.at += len;
            if self.at == self.buf.len() {
                self.flush();
            }
            start += len;
            rem -= len;
        }
        self.maybe_flush();
        Ok(buf.len())
    }

    fn flush(&mut self) -> std::io::Result<()> {
        self.flush();
        Ok(())
    }
}

pub trait Writable {
    fn write(&self, output: &mut Output);
}

impl Writable for &str {
    fn write(&self, output: &mut Output) {
        output.write_all(self.as_bytes()).unwrap();
    }
}

impl Writable for String {
    fn write(&self, output: &mut Output) {
        output.write_all(self.as_bytes()).unwrap();
    }
}

impl Writable for char {
    fn write(&self, output: &mut Output) {
        output.put(*self as u8);
    }
}

impl<T: Writable> Writable for [T] {
    fn write(&self, output: &mut Output) {
        output.print_iter_ref(self.iter());
    }
}

impl<T: Writable, const N: usize> Writable for [T; N] {
    fn write(&self, output: &mut Output) {
        output.print_iter_ref(self.iter());
    }
}

impl<T: Writable> Writable for &T {
    fn write(&self, output: &mut Output) {
        T::write(self, output)
    }
}

impl<T: Writable> Writable for Vec<T> {
    fn write(&self, output: &mut Output) {
        self.as_slice().write(output);
    }
}

impl Writable for () {
    fn write(&self, _output: &mut Output) {}
}

macro_rules! write_to_string {
    ($($t:ident)+) => {$(
        impl Writable for $t {
            fn write(&self, output: &mut Output) {
                self.to_string().write(output);
            }
        }
    )+};
}

write_to_string!(u8 u16 u32 u64 u128 usize i8 i16 i32 i64 i128 isize);

macro_rules! tuple_writable {
    ($name0:ident $($name:ident: $id:tt )*) => {
        impl<$name0: Writable, $($name: Writable,)*> Writable for ($name0, $($name,)*) {
            fn write(&self, out: &mut Output) {
                self.0.write(out);
                $(
                out.put(b' ');
                self.$id.write(out);
                )*
            }
        }
    }
}

tuple_writable! {T}
tuple_writable! {T U:1}
tuple_writable! {T U:1 V:2}
tuple_writable! {T U:1 V:2 X:3}
tuple_writable! {T U:1 V:2 X:3 Y:4}
tuple_writable! {T U:1 V:2 X:3 Y:4 Z:5}
tuple_writable! {T U:1 V:2 X:3 Y:4 Z:5 A:6}
tuple_writable! {T U:1 V:2 X:3 Y:4 Z:5 A:6 B:7}

impl<T: Writable> Writable for Option<T> {
    fn write(&self, output: &mut Output) {
        match self {
            None => (-1).write(output),
            Some(t) => t.write(output),
        }
    }
}

impl Writable for bool {
    fn write(&self, output: &mut Output) {
        let bool_output = output.bool_output;
        bool_output.output(output, *self)
    }
}

static mut ERR: Option<Stderr> = None;
pub fn err() -> Output<'static> {
    unsafe {
        if ERR.is_none() {
            ERR = Some(stderr());
        }
        Output::new_with_auto_flush(ERR.as_mut().unwrap())
    }
}
}
}
pub mod misc {
pub mod recursive_function {
use std::marker::PhantomData;

macro_rules! recursive_function {
    ($name: ident, $trait: ident, ($($type: ident $arg: ident,)*)) => {
        pub trait $trait<$($type, )*Output> {
            fn call(&mut self, $($arg: $type,)*) -> Output;
        }

        pub struct $name<F, $($type, )*Output>
        where
            F: FnMut(&mut dyn $trait<$($type, )*Output>, $($type, )*) -> Output,
        {
            f: std::cell::UnsafeCell<F>,
            $($arg: PhantomData<$type>,
            )*
            phantom_output: PhantomData<Output>,
        }

        impl<F, $($type, )*Output> $name<F, $($type, )*Output>
        where
            F: FnMut(&mut dyn $trait<$($type, )*Output>, $($type, )*) -> Output,
        {
            pub fn new(f: F) -> Self {
                Self {
                    f: std::cell::UnsafeCell::new(f),
                    $($arg: Default::default(),
                    )*
                    phantom_output: Default::default(),
                }
            }
        }

        impl<F, $($type, )*Output> $trait<$($type, )*Output> for $name<F, $($type, )*Output>
        where
            F: FnMut(&mut dyn $trait<$($type, )*Output>, $($type, )*) -> Output,
        {
            fn call(&mut self, $($arg: $type,)*) -> Output {
                unsafe { (*self.f.get())(self, $($arg, )*) }
            }
        }
    }
}

recursive_function!(RecursiveFunction0, Callable0, ());
recursive_function!(RecursiveFunction, Callable, (Arg arg,));
recursive_function!(RecursiveFunction2, Callable2, (Arg1 arg1, Arg2 arg2,));
recursive_function!(RecursiveFunction3, Callable3, (Arg1 arg1, Arg2 arg2, Arg3 arg3,));
recursive_function!(RecursiveFunction4, Callable4, (Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4,));
recursive_function!(RecursiveFunction5, Callable5, (Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4, Arg5 arg5,));
recursive_function!(RecursiveFunction6, Callable6, (Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4, Arg5 arg5, Arg6 arg6,));
recursive_function!(RecursiveFunction7, Callable7, (Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4, Arg5 arg5, Arg6 arg6, Arg7 arg7,));
recursive_function!(RecursiveFunction8, Callable8, (Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4, Arg5 arg5, Arg6 arg6, Arg7 arg7, Arg8 arg8,));
recursive_function!(RecursiveFunction9, Callable9, (Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4, Arg5 arg5, Arg6 arg6, Arg7 arg7, Arg8 arg8, Arg9 arg9,));
}
}
pub mod numbers {
pub mod num_traits {
pub mod add_sub {
use std::ops::{Add, AddAssign, Sub, SubAssign};

pub trait Addable: Add<Output = Self> + AddAssign + Copy {}
impl<T: Add<Output = Self> + AddAssign + Copy> Addable for T {}

pub trait AddSub: Addable + Sub<Output = Self> + SubAssign {}
impl<T: Addable + Sub<Output = Self> + SubAssign> AddSub for T {}
}
pub mod bit_ops {
use crate::numbers::num_traits::zero_one::ZeroOne;
use std::ops::{BitAnd, BitAndAssign, BitOr, BitOrAssign, BitXor, BitXorAssign, Not, RangeInclusive, Shl,};
use std::ops::{ShlAssign, Shr, ShrAssign};

pub trait BitOps:
    Copy
    + BitAnd<Output = Self>
    + BitAndAssign
    + BitOr<Output = Self>
    + BitOrAssign
    + BitXor<Output = Self>
    + BitXorAssign
    + Not<Output = Self>
    + Shl<usize, Output = Self>
    + ShlAssign<usize>
    + Shr<usize, Output = Self>
    + ShrAssign<usize>
    + ZeroOne
    + PartialEq
{
    fn bit(at: usize) -> Self {
        Self::one() << at
    }

    fn is_set(&self, at: usize) -> bool {
        (*self >> at & Self::one()) == Self::one()
    }

    fn set_bit(&mut self, at: usize) {
        *self |= Self::bit(at)
    }

    fn unset_bit(&mut self, at: usize) {
        *self &= !Self::bit(at)
    }

    #[must_use]
    fn with_bit(mut self, at: usize) -> Self {
        self.set_bit(at);
        self
    }

    #[must_use]
    fn without_bit(mut self, at: usize) -> Self {
        self.unset_bit(at);
        self
    }

    fn flip_bit(&mut self, at: usize) {
        *self ^= Self::bit(at)
    }

    fn all_bits(n: usize) -> Self {
        let mut res = Self::zero();
        for i in 0..n {
            res.set_bit(i);
        }
        res
    }

    fn iter_all(n: usize) -> RangeInclusive<Self> {
        Self::zero()..=Self::all_bits(n)
    }
}

impl<
        T: Copy
            + BitAnd<Output = Self>
            + BitAndAssign
            + BitOr<Output = Self>
            + BitOrAssign
            + BitXor<Output = Self>
            + BitXorAssign
            + Not<Output = Self>
            + Shl<usize, Output = Self>
            + ShlAssign<usize>
            + Shr<usize, Output = Self>
            + ShrAssign<usize>
            + ZeroOne
            + PartialEq,
    > BitOps for T
{
}

pub trait Bits: BitOps {
    fn bits() -> u32;
}

macro_rules! bits_integer_impl {
    ($($t: ident $bits: expr),+) => {$(
        impl Bits for $t {
            fn bits() -> u32 {
                $bits
            }
        }
    )+};
}

bits_integer_impl!(i128 128, i64 64, i32 32, i16 16, i8 8, isize 64, u128 128, u64 64, u32 32, u16 16, u8 8, usize 64);
}
pub mod zero_one {
pub trait ZeroOne {
    fn zero() -> Self;
    fn one() -> Self;
}

macro_rules! zero_one_integer_impl {
    ($($t: ident)+) => {$(
        impl ZeroOne for $t {
            fn zero() -> Self {
                0
            }

            fn one() -> Self {
                1
            }
        }
    )+};
}

zero_one_integer_impl!(i128 i64 i32 i16 i8 isize u128 u64 u32 u16 u8 usize);
}
}
}
fn main() {
    let mut sin = std::io::stdin();
    let input = if false {
        io::input::Input::new_with_size(&mut sin, 1)
    } else {
        io::input::Input::new(&mut sin)
    };

    let mut stdout = std::io::stdout();
    let output = if false {
        io::output::Output::new_with_auto_flush(&mut stdout)
    } else {
        io::output::Output::new(&mut stdout)
    };

    solution::run(input, output);
}


Details

Tip: Click on the bar to expand more detailed information

Test #1:

score: 100
Accepted
time: 0ms
memory: 2096kb

input:

2
3 3
1 2 3
2 3 1
1 3 2
5 6
1 2 1
2 3 1
1 3 2
3 4 3
3 5 3
4 5 3

output:

Yes
No

result:

ok 2 token(s): yes count is 1, no count is 1

Test #2:

score: -100
Wrong Answer
time: 152ms
memory: 2080kb

input:

100000
7 10
7 2 2
6 4 2
6 1 2
7 1 3
3 4 1
6 7 1
2 6 3
3 1 2
5 3 1
2 1 1
7 10
5 7 3
7 1 1
4 6 3
6 3 1
3 4 3
4 2 2
3 2 3
1 3 3
3 7 1
1 4 2
7 10
5 6 3
3 5 2
7 2 3
7 3 3
1 2 2
4 3 2
7 4 2
6 1 2
2 6 1
7 5 2
7 10
7 1 3
7 5 3
6 4 1
7 6 1
1 4 1
3 4 2
2 7 2
1 3 1
3 5 3
5 1 3
7 10
6 7 2
3 4 3
1 4 2
5 3 2
7 4 ...

output:

Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
...

result:

wrong answer expected NO, found YES [13th token]