#include <bits/stdc++.h>
using namespace std;

#define INF_LL (int64)1e18
#define INF (int32)1e9
#define REP(i, n) for(int64 i = 0;i < (n);i++)
#define FOR(i, a, b) for(int64 i = (a);i < (b);i++)
#define all(x) x.begin(),x.end()
#define fs first
#define sc second

using int32 = int_fast32_t;
using uint32 = uint_fast32_t;
using int64 = int_fast64_t;
using uint64 = uint_fast64_t;
using PII = pair<int32, int32>;
using PLL = pair<int64, int64>;

const double eps = 1e-10;

template<typename A, typename B>inline void chmin(A &a, B b){if(a > b) a = b;}
template<typename A, typename B>inline void chmax(A &a, B b){if(a < b) a = b;}

template<typename T>
vector<T> make_v(size_t a){return vector<T>(a);}

template<typename T,typename... Ts>
auto make_v(size_t a,Ts... ts){
  return vector<decltype(make_v<T>(ts...))>(a,make_v<T>(ts...));
}

template<typename T,typename U,typename... V>
typename enable_if<is_same<T, U>::value!=0>::type
fill_v(U &u,const V... v){u=U(v...);}

template<typename T,typename U,typename... V>
typename enable_if<is_same<T, U>::value==0>::type
fill_v(U &u,const V... v){
  for(auto &e:u) fill_v<T>(e,v...);
}

template <typename F>
class
#if defined(__has_cpp_attribute) && __has_cpp_attribute(nodiscard)
  [[nodiscard]]
#endif  // defined(__has_cpp_attribute) && __has_cpp_attribute(nodiscard)
FixPoint final : private F
{
public:
  template <typename G>
  explicit constexpr FixPoint(G&& g) noexcept
    : F{std::forward<G>(g)}
  {}

  template <typename... Args>
  constexpr decltype(auto)
  operator()(Args&&... args) const
#if !defined(__GNUC__) || defined(__clang__) || __GNUC__ >= 9
  noexcept(noexcept(F::operator()(std::declval<FixPoint>(), std::declval<Args>()...)))
#endif  // !defined(__GNUC__) || defined(__clang__) || __GNUC__ >= 9
  {
    return F::operator()(*this, std::forward<Args>(args)...);
  }
};  // class FixPoint


#if defined(__cpp_deduction_guides)
template <typename F>
FixPoint(F&&)
  -> FixPoint<std::decay_t<F>>;
#endif  // defined(__cpp_deduction_guides)


namespace
{
  template <typename F>
#if !defined(__has_cpp_attribute) || !__has_cpp_attribute(nodiscard)
  #  if defined(__GNUC__) && (__GNUC__ > 3 || __GNUC__ == 3 && __GNUC_MINOR__ >= 4)
__attribute__((warn_unused_result))
#  elif defined(_MSC_VER) && _MSC_VER >= 1700 && defined(_Check_return_)
_Check_return_
#  endif  // defined(__GNUC__) && (__GNUC__ > 3 || __GNUC__ == 3 && __GNUC_MINOR__ >= 4)
#endif  // !defined(__has_cpp_attribute) || !__has_cpp_attribute(nodiscard)
  inline constexpr decltype(auto)
  makeFixPoint(F&& f) noexcept
  {
    return FixPoint<std::decay_t<F>>{std::forward<std::decay_t<F>>(f)};
  }
}  // namespace

template<class ValueMonoid, class OperatorMonoid, class Modifier,
  template<class...> class Container=::std::vector>
class LazySegTree{
public:
  using value_structure = ValueMonoid;
  using value_type = typename value_structure::value_type;
  using operator_structure = OperatorMonoid;
  using operator_type = typename operator_structure::value_type;
  using modifier = Modifier;
  using const_reference = const value_type &;
  using container_value_type = Container<value_type>;
  using container_operator_type = Container<operator_type>;
  using size_type = typename container_value_type::size_type;

private:
  container_value_type tree;
  container_operator_type lazy;
  size_type size_, height;

  static size_type getsize(const size_type x){
    size_type ret = 1;
    while(ret < x)
      ret <<= 1;
    return ret;
  }

  static size_type getheight(const size_type x){
    size_type ret = 0;
    while((static_cast<size_type>(1) << ret) < x){
      ret++;
    }
    return ret;
  }

  inline static value_type calc(const value_type a, const value_type b){
    return value_structure::operation(a, b);
  }

  inline static void apply(operator_type &data, const operator_type a){
    data = operator_structure::operation(data, a);
  }

  inline static value_type reflect(const value_type v, const operator_type o){
    return modifier::operation(v, o);
  }

  void push(const size_type index){
    tree[index] = reflect(tree[index], lazy[index]);
    apply(lazy[index << 1], lazy[index]);
    apply(lazy[index << 1 | 1], lazy[index]);
    lazy[index] = operator_structure::identity();
  }

  void calc_node(const size_type index){
    if(tree.size() <= (index << 1 | 1)) return;
    assert(0 < index);
    tree[index] = calc(reflect(tree[index << 1],  lazy[index << 1]),
                       reflect(tree[index << 1 | 1], lazy[index << 1 | 1]));
  }

  void build(size_type index){
    while(index >>= 1){
      calc_node(index);
    }
  }

  void propagate(const size_type index){
    for(size_type shift = height; shift ; --shift){
      push(index >> shift);
    }
  }

  void rebuild(){
    for(size_type i = size_-1;i > 0;--i){
      calc_node(i);
    }
  }
public:
  LazySegTree() : size_(0), height(0), tree(), lazy(){}
  LazySegTree(const size_type size)
    : size_(size), height(getheight(size)),
      tree(size << 1, value_structure::initializer()),
      lazy(size << 1, operator_structure::identity()){
    rebuild();
  }
  template<class InputIterator>
  LazySegTree(InputIterator first, InputIterator last)
    : size_(::std::distance(first, last)){
    height = getheight(size_);
    tree = container_value_type(size_, value_structure::identity());
    lazy = container_operator_type(size_ << 1, operator_structure::identity());
    tree.insert(tree.end(), first, last);
    rebuild();
  }

  size_type size() const { return size_; }
  const_reference operator[](const size_type k){
    assert(k < size_);
    propagate(k+size_);
    tree[k+size_] = reflect(tree[k+size_], lazy[k+size_]);
    lazy[k+size_] = operator_structure::identity();
    return tree[k+size_];
  }

  value_type query(size_type l, size_type r){
    assert(l <= r);
    assert(0 <= l && l < size_);
    assert(0 <= r && r <= size_);
    value_type retl = value_structure::identity(),
      retr = value_structure::identity();
    l += size_;
    r += size_;
    propagate(l);
    propagate(r-1);
    build(l);
    build(r-1);
    for(; l < r ; l >>= 1, r >>= 1){
      if(l&1){
        retl = calc(retl, reflect(tree[l], lazy[l]));
        l++;
      }
      if(r&1){
        r--;
        retr = calc(reflect(tree[r], lazy[r]), retr);
      }
    }
    return calc(retl, retr);
  }

  void update(size_type l, size_type r, const operator_type& data){
    assert(l <= r);
    assert(0 <= l && l < size_);
    assert(0 <= r && r <= size_);
    l += size_;
    r += size_;
    propagate(l);
    propagate(r - 1);
    for(size_type l_ = l, r_ = r; l_ < r_ ; l_ >>= 1, r_ >>= 1){
      if(l_ & 1) apply(lazy[l_++], data);
      if(r_ & 1) apply(lazy[--r_], data);
    }
    build(l);
    build(r - 1);
  }

  template<class F>
  void update(size_type index, const F& f){
    assert(0 <= index && index < size());
    index += size_;
    propagate(index);
    tree[index] = f(::std::move(tree[index]));
    lazy[index] = operator_structure::identity();
    build(index);
  }

  /*
  template<class F>
  size_type search(const F& f) const { // [0, result) is True and [0, result-1) is not.
    if(f(value_structure::identity()))
      return 0;
    if(!f(tree[1]))
      return size_+1;
    value_type acc = value_structure::identity();
    size_type i = 1;
    while(i <
  }
  */
};

class v_monoid {
public:
  using value_type = PII;
  static const value_type identity() { return PII(INF, 0); }
  static const value_type initializer() { return identity(); }

  static const value_type operation(const value_type& a, const value_type& b) {
    if (a.fs < b.fs) return a;
    if (a.fs > b.fs) return b;
    return PLL(a.fs, a.sc + b.sc);
  }
};

class o_monoid {
public:
  using value_type = int;
  static const value_type identity() { return 0; }
  static const value_type operation(const value_type& a, const value_type& b) {
    return a + b;
  }
};

class modifier {
public:
  static const PII operation(const PII& a, const int& b) {
    return PII(a.fs + b, a.sc);
  }
};

int main(void){
  cin.tie(0);
  ios::sync_with_stdio(false);

  int N;
  cin >> N;
  assert(1 <= N && N <= 200000);
  vector<int> A(N), B(N);
  REP(i, N) {
    cin >> A[i];
    assert(1 <= A[i] && A[i] <= 400000);
  }
  REP(i, N) {
    cin >> B[i];
    assert(1 <= B[i] && B[i] <= 400000);
  }

  vector<vector<int>> Al(412345), Bl(412345);
  vector<PII> seg(412345, PII(N, N));

  vector<PII> v(N + 1, PII(0, 1));
  LazySegTree<v_monoid, o_monoid, modifier> lsg(all(v));

  REP(i, N) {
    Al[A[i]].push_back(i);
    Bl[B[i]].push_back(i);
  }

  auto add = [&](int64 i, int64 x) {
    auto [l, r] = minmax(seg[i].fs, seg[i].sc);
    lsg.update(l, r, x);
  };

  REP(i, 412345) {
    reverse(all(Al[i]));
    reverse(all(Bl[i]));
    if (Al[i].size()) seg[i].fs = Al[i].back();
    if (Bl[i].size()) seg[i].sc = Bl[i].back();
    add(i, 1);
  }
  int64 res = 0;

  REP(l, N) {
    auto ret = lsg.query(l, N);
    if (ret.fs == 0) res += ret.sc;

    add(A[l], -1);
    if (A[l] != B[l]) add(B[l], -1);
    seg[A[l]].fs = N; Al[A[l]].pop_back();
    seg[B[l]].sc = N; Bl[B[l]].pop_back();

    if (Al[A[l]].size()) seg[A[l]].fs = Al[A[l]].back();
    if (Bl[B[l]].size()) seg[B[l]].sc = Bl[B[l]].back();

    add(A[l], 1);
    if (A[l] != B[l]) add(B[l], 1);
  }
  cout << res << endl;
}