// ---------- begin Lazy Segment Tree ---------- pub trait TE { type T: Clone; type E: Clone; fn fold(l: &Self::T, r: &Self::T) -> Self::T; fn eval(x: &Self::T, f: &Self::E) -> Self::T; fn merge(g: &Self::E, h: &Self::E) -> Self::E; fn e() -> Self::T; fn id() -> Self::E; } pub struct LazySegmentTree { size: usize, bit: usize, a: Vec<(R::T, R::E)>, } impl LazySegmentTree { pub fn new(n: usize) -> LazySegmentTree { let size = n.next_power_of_two(); let bit = size.trailing_zeros() as usize; LazySegmentTree { size: size, bit: bit, a: vec![(R::e(), R::id()); 2 * size], } } pub fn build_by(z: &[R::T]) -> LazySegmentTree { let mut seg = LazySegmentTree::::new(z.len()); for (a, z) in seg.a[seg.size..].iter_mut().zip(z.iter()) { a.0 = z.clone(); } let a = &mut seg.a; for i in (1..seg.size).rev() { a[i].0 = R::fold(&a[2 * i].0, &a[2 * i + 1].0); } seg } fn apply(&mut self, x: usize, op: &R::E) { let node = &mut self.a[x]; node.0 = R::eval(&node.0, op); node.1 = R::merge(&node.1, op); } fn propagate(&mut self, x: usize) { let mut op = R::id(); std::mem::swap(&mut op, &mut self.a[x].1); self.apply(2 * x, &op); self.apply(2 * x + 1, &op); } fn propagate_range(&mut self, l: usize, r: usize) { let x = l + self.size; let y = r + self.size; let mut k = self.bit; while (x >> k) == (y >> k) { self.propagate(x >> k); k -= 1; } for i in ((x.trailing_zeros() as usize + 1)..=k).rev() { self.propagate(x >> i); } for i in ((y.trailing_zeros() as usize + 1)..=k).rev() { self.propagate(y >> i); } } fn save_range(&mut self, l: usize, r: usize) { let mut x = l + self.size; let mut y = r + self.size; let mut p = (x & 1) == 1; let mut q = (y & 1) == 1; x >>= 1; y >>= 1; while 0 < x && x < y { if p { self.a[x].0 = R::fold(&self.a[2 * x].0, &self.a[2 * x + 1].0); } if q { self.a[y].0 = R::fold(&self.a[2 * y].0, &self.a[2 * y + 1].0); } p |= (x & 1) == 1; q |= (y & 1) == 1; x >>= 1; y >>= 1; } while 0 < x { self.a[x].0 = R::fold(&self.a[2 * x].0, &self.a[2 * x + 1].0); x >>= 1; } } pub fn update(&mut self, l: usize, r: usize, op: R::E) { if l == r { return; } self.propagate_range(l, r); let mut x = l + self.size; let mut y = r + self.size; while x < y { if x & 1 == 1 { self.apply(x, &op); x += 1; } if y & 1 == 1 { y -= 1; self.apply(y, &op); } x >>= 1; y >>= 1; } self.save_range(l, r); } pub fn find(&mut self, l: usize, r: usize) -> R::T { if l == r { return R::e(); } self.propagate_range(l, r); let mut x = l + self.size; let mut y = r + self.size; let mut p = R::e(); let mut q = R::e(); while x < y { if x & 1 == 1 { p = R::fold(&p, &self.a[x].0); x += 1; } if y & 1 == 1 { y -= 1; q = R::fold(&self.a[y].0, &q); } x >>= 1; y >>= 1; } R::fold(&p, &q) } } // ---------- end Lazy Segment Tree ---------- // ---------- begin input macro ---------- // reference: https://qiita.com/tanakh/items/0ba42c7ca36cd29d0ac8 macro_rules! input { (source = $s:expr, $($r:tt)*) => { let mut iter = $s.split_whitespace(); input_inner!{iter, $($r)*} }; ($($r:tt)*) => { let s = { use std::io::Read; let mut s = String::new(); std::io::stdin().read_to_string(&mut s).unwrap(); s }; let mut iter = s.split_whitespace(); input_inner!{iter, $($r)*} }; } macro_rules! input_inner { ($iter:expr) => {}; ($iter:expr, ) => {}; ($iter:expr, $var:ident : $t:tt $($r:tt)*) => { let $var = read_value!($iter, $t); input_inner!{$iter $($r)*} }; } macro_rules! read_value { ($iter:expr, ( $($t:tt),* )) => { ( $(read_value!($iter, $t)),* ) }; ($iter:expr, [ $t:tt ; $len:expr ]) => { (0..$len).map(|_| read_value!($iter, $t)).collect::>() }; ($iter:expr, chars) => { read_value!($iter, String).chars().collect::>() }; ($iter:expr, bytes) => { read_value!($iter, String).bytes().collect::>() }; ($iter:expr, usize1) => { read_value!($iter, usize) - 1 }; ($iter:expr, $t:ty) => { $iter.next().unwrap().parse::<$t>().expect("Parse error") }; } // ---------- end input macro ---------- use std::io::Write; // 集合が等しい // 左端を固定した時最左の要素にのみ注目 // 区間0の個数とか捌けたらいいができるわけねえ // ある要素について考えると // 右端が s未満or以上 // みたいな条件になる // 区間0の個数クエリになる struct R; impl TE for R { type T = (i32, i64); type E = i32; fn fold(l: &Self::T, r: &Self::T) -> Self::T { if l.0 == r.0 { (l.0, l.1 + r.1) } else { std::cmp::min(*l, *r) } } fn eval(x: &Self::T, f: &Self::E) -> Self::T { (x.0 + *f, x.1) } fn merge(g: &Self::E, h: &Self::E) -> Self::E { *g + *h } fn e() -> Self::T { (0, 0) } fn id() -> Self::E { 0 } } fn run() { input! { n: usize, a: [usize; n], b: [usize; n], } let m = *a.iter().chain(&b).max().unwrap(); let mut range = vec![(n + 1, n + 1); m + 1]; let mut seg = LazySegmentTree::::build_by(&vec![(0, 1); n + 1]); let mut ans = 0; for l in (0..n).rev() { if a[l] == b[l] { let (s, t) = range[a[l]]; seg.update(s.min(t), s.max(t), -1); range[a[l]] = (l, l); } else { let (s, t) = range[a[l]]; seg.update(s.min(t), s.max(t), -1); range[a[l]].0 = l; let (s, t) = range[a[l]]; seg.update(s.min(t), s.max(t), 1); let (s, t) = range[b[l]]; seg.update(s.min(t), s.max(t), -1); range[b[l]].1 = l; let (s, t) = range[b[l]]; seg.update(s.min(t), s.max(t), 1); } let p = seg.find(l, n); if p.0 == 0 { ans += p.1; } } println!("{}", ans); } fn main() { run(); }