結果
問題 | No.778 クリスマスツリー |
ユーザー | shino16 |
提出日時 | 2021-01-31 19:33:25 |
言語 | Rust (1.77.0 + proconio) |
結果 |
WA
|
実行時間 | - |
コード長 | 13,506 bytes |
コンパイル時間 | 12,787 ms |
コンパイル使用メモリ | 402,936 KB |
実行使用メモリ | 21,920 KB |
最終ジャッジ日時 | 2024-06-29 04:00:08 |
合計ジャッジ時間 | 14,643 ms |
ジャッジサーバーID (参考情報) |
judge4 / judge1 |
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テストケース
テストケース表示入力 | 結果 | 実行時間 実行使用メモリ |
---|---|---|
testcase_00 | AC | 1 ms
5,248 KB |
testcase_01 | AC | 1 ms
5,376 KB |
testcase_02 | AC | 1 ms
5,376 KB |
testcase_03 | AC | 1 ms
5,376 KB |
testcase_04 | AC | 1 ms
5,376 KB |
testcase_05 | AC | 1 ms
5,376 KB |
testcase_06 | AC | 39 ms
21,232 KB |
testcase_07 | AC | 36 ms
21,920 KB |
testcase_08 | WA | - |
testcase_09 | AC | 112 ms
18,432 KB |
testcase_10 | AC | 112 ms
18,432 KB |
testcase_11 | AC | 104 ms
18,560 KB |
testcase_12 | AC | 97 ms
18,176 KB |
testcase_13 | AC | 37 ms
17,792 KB |
testcase_14 | WA | - |
ソースコード
use crate::lib::ds::fenwick::*; use crate::lib::graph::dfs_io::*; use crate::lib::io::*; fn main() { let mut io = IO::new(); let n = io.scan(); let mut graph = vec![Vec::new(); n]; for v in 1..n { let p: usize = io.scan(); graph[p].push(v); graph[v].push(p); } let mut fwk = FenwickTree::new(vec![0; n], Addition::new()); let mut ans = 0; dfs_io(&graph, 0, |v, _| match v { In(v) => { ans += fwk.ask_prefix(v); fwk.add(v, 1); }, Out(v) => fwk.sub(v, 1), }); io.println(ans); } pub mod lib { pub mod alg { pub trait Alg { type Item: Copy; } pub trait Monoid: Alg { fn unit(&self) -> Self::Item; fn op(&self, x: Self::Item, y: Self::Item) -> Self::Item; fn op_to(&self, y: Self::Item, x: &mut Self::Item) { *x = self.op(*x, y); } } pub trait Group: Monoid { fn inv(&self, x: Self::Item) -> Self::Item; fn op_inv_to(&self, y: Self::Item, x: &mut Self::Item) { *x = self.op(*x, self.inv(y)) } } macro_rules! impl_monoid { ($target:ty, $($params:tt : $bounds:tt),*) => { impl<$($params : $bounds),*> Alg for $target { type Item = T; } impl<$($params : $bounds),*> Monoid for $target { fn unit(&self) -> Self::Item { (self.0)() } fn op(&self, x: Self::Item, y: Self::Item) -> Self::Item { (self.1)(x, y) } } }; } macro_rules! impl_group { ($target:ty, $($params:tt : $bounds:tt),*) => { impl_monoid!($target, $($params : $bounds),*); impl<$($params : $bounds),*> Group for $target { fn inv(&self, x: Self::Item) -> Self::Item { (self.2)(x) } } }; } pub struct MonoidImpl<T: Copy, Unit: Fn() -> T, Op: Fn(T, T) -> T>(pub Unit, pub Op); pub struct GroupImpl<T, Unit, Op, Inv>(pub Unit, pub Op, pub Inv) where T: Copy, Unit: Fn() -> T, Op: Fn(T, T) -> T, Inv: Fn(T) -> T; // help! impl_monoid!(MonoidImpl<T, Unit, Op>, T: Copy, Unit: (Fn() -> T), Op: (Fn(T, T) -> T)); impl_group!(GroupImpl<T, Unit, Op, Inv>, T: Copy, Unit: (Fn() -> T), Op: (Fn(T, T) -> T), Inv: (Fn(T) -> T)); pub mod arith { pub use super::*; pub use crate::lib::num::*; use std::marker::PhantomData; #[derive(Default)] pub struct Addition<N>(PhantomData<N>); impl<N> Addition<N> { pub fn new() -> Self { Self(PhantomData) } } impl<N: Num> Alg for Addition<N> { type Item = N; } impl<N: Num> Monoid for Addition<N> { fn unit(&self) -> Self::Item { N::ZERO } fn op(&self, x: Self::Item, y: Self::Item) -> Self::Item { x.wrapping_add(y) } } impl<N: Num> Group for Addition<N> { fn inv(&self, x: Self::Item) -> Self::Item { x.wrapping_neg() } } } // mod arith } // mod alg pub mod bit { use std::ops::*; pub trait Bits: Sized + BitAnd<Output = Self> + BitAndAssign + BitOr<Output = Self> + BitOrAssign + BitXor<Output = Self> + BitXorAssign + Shl<u32, Output = Self> + ShlAssign<u32> + Shr<u32, Output = Self> + ShrAssign<u32> + Not<Output = Self> { fn trailing_zeros(self) -> u32; fn lsb(self) -> Self; fn ilog2(self) -> u32; fn msb(self) -> Self; } macro_rules! impl_bit { ($($t:ty), *) => { $( impl Bits for $t { fn trailing_zeros(self) -> u32 { <$t>::trailing_zeros(self) } fn lsb(self) -> Self { self & self.wrapping_neg() } fn ilog2(self) -> u32 { std::mem::size_of::<$t>() as u32 * 8 - self.leading_zeros() - 1 } fn msb(self) -> Self { (1 as $t) << self.ilog2() } } )* }; } impl_bit!(i32, i64, i128, isize, u32, u64, u128, usize); } // mod bit pub mod ds { pub mod bitset { pub trait BitSet { fn get_bit(&self, i: usize) -> bool; fn set_bit(&mut self, i: usize, b: bool); fn modify_bit(&mut self, i: usize, b: bool) -> bool { if self.get_bit(i) == b { false } else { self.set_bit(i, b); true } } fn negate(&mut self); fn reset(&mut self); } macro_rules! impl_bitset { ($($type:ty),*) => { $( impl BitSet for $type { fn get_bit(&self, i: usize) -> bool { ((*self >> i) & 1) != 0 } fn set_bit(&mut self, i: usize, b: bool) { *self |= (b as $type) << i; } fn negate(&mut self) { *self = !*self; } fn reset(&mut self) { *self = 0; } } )* }; } impl_bitset!(i32, i64, i128, isize, u32, u64, u128, usize); impl BitSet for [u32] { fn get_bit(&self, i: usize) -> bool { self[i / 32].get_bit(i % 32) } fn set_bit(&mut self, i: usize, b: bool) { self[i / 32].set_bit(i % 32, b); } fn negate(&mut self) { for x in self { x.negate() } } fn reset(&mut self) { for x in self { x.reset(); } } } pub fn new_bitset(n: usize) -> Vec<u32> { vec![0; (n + 31) / 32] } } // mod bitset pub mod fenwick { pub use crate::lib::alg::arith::*; use crate::lib::bit::*; #[derive(Clone)] pub struct FenwickTree<A: Alg> { data: Vec<A::Item>, alg: A, } /// A: Commutative impl<A: Monoid> FenwickTree<A> { pub fn new(mut data: Vec<A::Item>, alg: A) -> Self { let len = data.len(); data.insert(0, alg.unit()); for i in 1..=len { if i + i.lsb() <= len { data[i + i.lsb()] = alg.op(data[i + i.lsb()], data[i]); } } Self { data, alg } } pub fn len(&self) -> usize { self.data.len() - 1 } pub fn add(&mut self, pos: usize, v: A::Item) { let mut pos = pos + 1; while pos < self.data.len() { self.data[pos] = self.alg.op(self.data[pos], v); pos += pos.lsb(); } } pub fn push(&mut self, v: A::Item) { self.data.push(self.alg.unit()); self.add(self.data.len() - 1, v); } pub fn ask_prefix(&self, mut r: usize) -> A::Item { let mut res = self.alg.unit(); while r != 0 { res = self.alg.op(self.data[r], res); r -= r.lsb(); } res } pub fn partition_point<F: FnMut(A::Item) -> bool>(&self, mut pred: F) -> usize { let mut x = 0; // pred(&self.ask_prefix(x)) == true let mut w = (self.data.len() - 1).msb(); let mut l = self.alg.unit(); while w != 0 { if x + w < self.data.len() && pred(self.alg.op(l, self.data[x + w])) { x += w; l = self.alg.op(l, self.data[x + w]); } w >>= 1; } x + 1 } pub fn lower_bound(&self, v: A::Item) -> usize where A::Item: Ord, { self.partition_point(|x| x < v) } pub fn upper_bound(&self, v: A::Item) -> usize where A::Item: Ord, { self.partition_point(|x| x <= v) } } /// A: Commutative impl<A: Group> FenwickTree<A> { pub fn sub(&mut self, pos: usize, v: A::Item) { self.add(pos, self.alg.inv(v)); } pub fn ask(&self, l: usize, r: usize) -> A::Item { self.alg.op(self.alg.inv(self.ask_prefix(l)), self.ask_prefix(r)) } } } // mod fenwick } // mod ds pub mod graph { use crate::lib::zo::ZeroOne; pub trait Graph { fn len(&self) -> usize; fn adj<F: FnMut(usize)>(&self, v: usize, f: F); } pub trait WGraph<W>: Graph { fn adj_w<F: FnMut(usize, &W)>(&self, v: usize, f: F); } pub trait Tree: Graph {} pub trait WTree<W>: WGraph<W> {} impl Graph for Vec<Vec<usize>> { fn len(&self) -> usize { self.len() } fn adj<F: FnMut(usize)>(&self, v: usize, f: F) { self[v].iter().copied().for_each(f); } } impl<N: ZeroOne> WGraph<N> for Vec<Vec<usize>> { fn adj_w<F: FnMut(usize, &N)>(&self, v: usize, mut f: F) { self[v].iter().for_each(|&v| f(v, &N::ONE)) } } impl<W> Graph for Vec<Vec<(usize, W)>> { fn len(&self) -> usize { self.len() } fn adj<F: FnMut(usize)>(&self, v: usize, mut f: F) { self[v].iter().for_each(|&(v, _)| f(v)) } } impl<W> WGraph<W> for Vec<Vec<(usize, W)>> { fn adj_w<F: FnMut(usize, &W)>(&self, v: usize, mut f: F) { self[v].iter().for_each(|&(v, ref e)| f(v, e)); } } impl<G: Graph> Tree for G {} impl<W, G: WGraph<W>> WTree<W> for G {} pub mod dfs_io { pub use super::*; use crate::lib::ds::bitset::*; #[derive(Debug)] pub enum InOut { In(usize), Out(usize), } pub use InOut::*; pub fn dfs_io<G: Graph, F: FnMut(InOut, usize)>(g: &G, s: usize, mut f: F) { let mut visited = new_bitset(g.len()); visited.set_bit(s, true); let mut togo = vec![(s, !0)]; while let Some((v, par)) = togo.pop() { if v >> 31 != 0 { f(Out(!v), par); } else { f(In(v), par); togo.push((!v, par)); g.adj(v, |w| { if visited.modify_bit(w, true) { togo.push((w, v)); } }); } } } } // mod dfs_io } // mod graph pub mod io { use std::io::{stdout, BufWriter, Read, StdoutLock, Write}; use std::marker::PhantomData; pub struct IO { iter: std::str::SplitAsciiWhitespace<'static>, buf: BufWriter<StdoutLock<'static>>, } impl IO { pub fn new() -> Self { let mut input = String::new(); std::io::stdin().read_to_string(&mut input).unwrap(); let input = Box::leak(input.into_boxed_str()); let out = Box::leak(Box::new(stdout())); IO { iter: input.split_ascii_whitespace(), buf: BufWriter::new(out.lock()), } } fn scan_str(&mut self) -> &'static str { self.iter.next().unwrap() } fn scan_raw(&mut self) -> &'static [u8] { self.scan_str().as_bytes() } pub fn scan<T: Scan>(&mut self) -> T { T::scan(self) } pub fn scan_iter<T: Scan>(&mut self, n: usize) -> std::iter::Take<Iter<'_, T>> { Iter { io: self, _m: PhantomData }.take(n) } pub fn scan_vec<T: Scan>(&mut self, n: usize) -> Vec<T> { (0..n).map(|_| self.scan()).collect() } pub fn print<T: Print>(&mut self, x: T) { T::print(self, x); } pub fn println<T: Print>(&mut self, x: T) { self.print(x); self.print("\n"); } pub fn iterln<T: Print, I: IntoIterator<Item = T>>(&mut self, into_iter: I, delim: &str) { let mut iter = into_iter.into_iter(); if let Some(v) = iter.next() { self.print(v); for v in iter { self.print(delim); self.print(v); } } self.print("\n"); } pub fn flush(&mut self) { self.buf.flush().unwrap(); } } pub struct Iter<'a, T> { io: &'a mut IO, _m: PhantomData<T>, } impl<T: Scan> Iterator for Iter<'_, T> { type Item = T; fn next(&mut self) -> Option<Self::Item> { Some(self.io.scan()) } } pub trait Scan { fn scan(io: &mut IO) -> Self; } pub trait Print { fn print(w: &mut IO, x: Self); } macro_rules! impl_parse_iint { ($($t:ty),*) => { $( impl Scan for $t { fn scan(s: &mut IO) -> Self { let scan = |t: &[u8]| t.iter().fold(0, |s, &b| s * 10 + (b & 0x0F) as $t); let s = s.scan_raw(); if let Some((&b'-', t)) = s.split_first() { -scan(t) } else { scan(s) } } } )* }; } macro_rules! impl_parse_uint { ($($t:ty),*) => { $( impl Scan for $t { fn scan(s: &mut IO) -> Self { s.scan_raw().iter().fold(0, |s, &b| s * 10 + (b & 0x0F) as $t) } } )* }; } impl_parse_iint!(i32, i64, i128, isize); impl_parse_uint!(u32, u64, u128, usize); impl Scan for u8 { fn scan(s: &mut IO) -> Self { let bytes = s.scan_raw(); debug_assert_eq!(bytes.len(), 1); bytes[0] } } impl Scan for &[u8] { fn scan(s: &mut IO) -> Self { s.scan_raw() } } impl Scan for Vec<u8> { fn scan(s: &mut IO) -> Self { s.scan_raw().to_vec() } } macro_rules! impl_tuple { () => {}; ($t:ident $($ts:ident)*) => { impl<$t: Scan, $($ts: Scan),*> Scan for ($t, $($ts),*) { fn scan(s: &mut IO) -> Self { ($t::scan(s), $($ts::scan(s)),*) } } impl<$t: Print, $($ts: Print),*> Print for ($t, $($ts),*) { #[allow(non_snake_case)] fn print(w: &mut IO, ($t, $($ts),*): Self) { w.print($t); $( w.print(" "); w.print($ts); )* } } impl_tuple!($($ts)*); }; } impl_tuple!(A B C D E F G); macro_rules! impl_scan_array { () => {}; ($n:literal $($ns:literal)*) => { impl<T: Scan> Scan for [T; $n] { fn scan(s: &mut IO) -> Self { let mut scan = |_| T::scan(s); [scan($n), $(scan($ns)),*] } } impl_scan_array!($($ns)*); }; } impl_scan_array!(7 6 5 4 3 2 1); macro_rules! impl_print_prim { ($($t:ty),*) => { $( impl Print for $t { fn print(w: &mut IO, x: Self) { w.buf.write_all(format!("{:.10}", x).as_bytes()).unwrap(); } } impl Print for &$t { fn print(w: &mut IO, x: Self) { w.print(*x); } } )* }; } impl_print_prim!(i32, i64, i128, isize, u32, u64, u128, usize, f32, f64); impl Print for u8 { fn print(w: &mut IO, x: Self) { w.buf.write_all(&[x]).unwrap(); } } impl Print for &[u8] { fn print(w: &mut IO, x: Self) { w.buf.write_all(x).unwrap(); } } impl Print for Vec<u8> { fn print(w: &mut IO, x: Self) { w.buf.write_all(&x).unwrap(); } } impl Print for &str { fn print(w: &mut IO, x: Self) { w.print(x.as_bytes()); } } #[derive(Debug, Clone, Copy, Default)] pub struct Usize1(pub usize); impl Scan for Usize1 { fn scan(io: &mut IO) -> Self { let n: usize = io.scan(); Self(n - 1) } } impl Print for Usize1 { fn print(w: &mut IO, x: Self) { w.print(x.0 + 1) } } } // mod io pub mod num { pub use crate::lib::zo::ZeroOne; use std::fmt::*; use std::ops::*; pub trait Num: ZeroOne + Add<Output = Self> + AddAssign + Sub<Output = Self> + SubAssign + Mul<Output = Self> + MulAssign + Div<Output = Self> + DivAssign + Debug + Display { fn wrapping_add(self, rhs: Self) -> Self; fn wrapping_neg(self) -> Self; } pub trait INum: Num + Neg<Output = Self> {} macro_rules! impl_num { ($($t:ty),*) => { $( impl Num for $t { fn wrapping_add(self, rhs: Self) -> Self { self.wrapping_add(rhs) } fn wrapping_neg(self) -> Self { self.wrapping_neg() } } )* }; } impl_num!(i32, i64, i128, isize, u32, u64, u128, usize); impl<T: Num + Neg<Output = Self>> INum for T {} } // mod num pub mod zo { pub trait ZeroOne: Copy + Eq { const ZERO: Self; fn is_zero(self) -> bool { self == Self::ZERO } const ONE: Self; } macro_rules! impl_zo { ($($t:ty),*) => { $( impl ZeroOne for $t { const ZERO: Self = 0; const ONE: Self = 1; } )* }; } impl_zo!(i32, i64, i128, isize, u32, u64, u128, usize); } // mod zo } // mod lib