#include using namespace std; using int64 = long long; const int mod = 1e9 + 7; // const int mod = 998244353; const int64 infll = (1LL << 62) - 1; const int inf = (1 << 30) - 1; struct IoSetup { IoSetup() { cin.tie(nullptr); ios::sync_with_stdio(false); cout << fixed << setprecision(10); cerr << fixed << setprecision(10); } } iosetup; template< typename T1, typename T2 > ostream &operator<<(ostream &os, const pair< T1, T2 > &p) { os << p.first << " " << p.second; return os; } template< typename T1, typename T2 > istream &operator>>(istream &is, pair< T1, T2 > &p) { is >> p.first >> p.second; return is; } template< typename T > ostream &operator<<(ostream &os, const vector< T > &v) { for(int i = 0; i < (int) v.size(); i++) { os << v[i] << (i + 1 != v.size() ? " " : ""); } return os; } template< typename T > istream &operator>>(istream &is, vector< T > &v) { for(T &in : v) is >> in; return is; } template< typename T1, typename T2 > inline bool chmax(T1 &a, T2 b) { return a < b && (a = b, true); } template< typename T1, typename T2 > inline bool chmin(T1 &a, T2 b) { return a > b && (a = b, true); } template< typename T = int64 > 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 V > typename enable_if< is_class< T >::value == 0 >::type fill_v(T &t, const V &v) { t = v; } template< typename T, typename V > typename enable_if< is_class< T >::value != 0 >::type fill_v(T &t, const V &v) { for(auto &e : t) fill_v(e, v); } template< typename F > struct FixPoint : F { FixPoint(F &&f) : F(forward< F >(f)) {} template< typename... Args > decltype(auto) operator()(Args &&... args) const { return F::operator()(*this, forward< Args >(args)...); } }; template< typename F > inline decltype(auto) MFP(F &&f) { return FixPoint< F >{forward< F >(f)}; } template< class Monoid, class OperatorMonoid = Monoid > struct RandomizedBinarySearchTree { using F = function< Monoid(Monoid, Monoid) >; using G = function< Monoid(Monoid, OperatorMonoid) >; using H = function< OperatorMonoid(OperatorMonoid, OperatorMonoid) >; using P = function< OperatorMonoid(OperatorMonoid, int) >; inline int xor128() { static int x = 123456789; static int y = 362436069; static int z = 521288629; static int w = 88675123; int t; t = x ^ (x << 11); x = y; y = z; z = w; return w = (w ^ (w >> 19)) ^ (t ^ (t >> 8)); } struct Node { Node *l, *r; int cnt; Monoid key, sum; OperatorMonoid lazy; Node() = default; Node(const Monoid &k, const OperatorMonoid &p) : cnt(1), key(k), sum(k), lazy(p), l(nullptr), r(nullptr) {} }; vector< Node > pool; int ptr; const Monoid M1; const OperatorMonoid OM0; const F f; const G g; const H h; const P p; RandomizedBinarySearchTree(int sz, const F &f, const Monoid &M1) : pool(sz), ptr(0), f(f), g(G()), h(H()), p(P()), M1(M1), OM0(OperatorMonoid()) {} RandomizedBinarySearchTree(int sz, const F &f, const G &g, const H &h, const P &p, const Monoid &M1, const OperatorMonoid &OM0) : pool(sz), ptr(0), f(f), g(g), h(h), p(p), M1(M1), OM0(OM0) {} inline Node *alloc(const Monoid &key) { return &(pool[ptr++] = Node(key, OM0)); } virtual Node *clone(Node *t) { return t; } inline int count(const Node *t) { return t ? t->cnt : 0; } inline Monoid sum(const Node *t) { return t ? t->sum : M1; } inline Node *update(Node *t) { t->cnt = count(t->l) + count(t->r) + 1; t->sum = f(f(sum(t->l), t->key), sum(t->r)); return t; } Node *propagate(Node *t) { t = clone(t); if(t->lazy != OM0) { t->key = g(t->key, p(t->lazy, 1)); if(t->l) { t->l = clone(t->l); t->l->lazy = h(t->l->lazy, t->lazy); t->l->sum = g(t->l->sum, p(t->lazy, count(t->l))); } if(t->r) { t->r = clone(t->r); t->r->lazy = h(t->r->lazy, t->lazy); t->r->sum = g(t->r->sum, p(t->lazy, count(t->r))); } t->lazy = OM0; } return update(t); } Node *merge(Node *l, Node *r) { if(!l || !r) return l ? l : r; if(xor128() % (l->cnt + r->cnt) < l->cnt) { l = propagate(l); l->r = merge(l->r, r); return update(l); } else { r = propagate(r); r->l = merge(l, r->l); return update(r); } } pair< Node *, Node * > split(Node *t, int k) { if(!t) return {t, t}; t = propagate(t); if(k <= count(t->l)) { auto s = split(t->l, k); t->l = s.second; return {s.first, update(t)}; } else { auto s = split(t->r, k - count(t->l) - 1); t->r = s.first; return {update(t), s.second}; } } Node *build(int l, int r, const vector< Monoid > &v) { if(l + 1 >= r) return alloc(v[l]); return merge(build(l, (l + r) >> 1, v), build((l + r) >> 1, r, v)); } Node *build(const vector< Monoid > &v) { ptr = 0; return build(0, (int) v.size(), v); } void dump(Node *r, typename vector< Monoid >::iterator &it) { if(!r) return; r = propagate(r); dump(r->l, it); *it = r->key; dump(r->r, ++it); } vector< Monoid > dump(Node *r) { vector< Monoid > v((size_t) count(r)); auto it = begin(v); dump(r, it); return v; } string to_string(Node *r) { auto s = dump(r); string ret; for(int i = 0; i < s.size(); i++) ret += ", "; return (ret); } void insert(Node *&t, int k, const Monoid &v) { auto x = split(t, k); t = merge(merge(x.first, alloc(v)), x.second); } void erase(Node *&t, int k) { auto x = split(t, k); t = merge(x.first, split(x.second, 1).second); } Monoid query(Node *&t, int a, int b) { auto x = split(t, a); auto y = split(x.second, b - a); auto ret = sum(y.first); t = merge(x.first, merge(y.first, y.second)); return ret; } void set_propagate(Node *&t, int a, int b, const OperatorMonoid &p) { auto x = split(t, a); auto y = split(x.second, b - a); y.first->lazy = h(y.first->lazy, p); t = merge(x.first, merge(propagate(y.first), y.second)); } void set_element(Node *&t, int k, const Monoid &x) { t = propagate(t); if(k < count(t->l)) set_element(t->l, k, x); else if(k == count(t->l)) t->key = t->sum = x; else set_element(t->r, k - count(t->l) - 1, x); t = update(t); } int size(Node *t) { return count(t); } bool empty(Node *t) { return !t; } Node *makeset() { return nullptr; } int lower_bound(Node *t, const Monoid &x) { if(!t) return 0; t = propagate(t); if(x <= t->key) return lower_bound(t->l, x); return lower_bound(t->r, x) + count(t->l) + 1; } }; int main() { int N; cin >> N; auto f = [](int a, int b) { return max(a, b); }; auto g = [](int a, int b) { return a + b; }; auto p = [](int a, int b) { return a; }; RandomizedBinarySearchTree< int, int > rbst(N, f, g, g, p, 0, 0); RandomizedBinarySearchTree< int, int >::Node *root = nullptr; for(int i = 0; i < N; i++) { int L, R; cin >> L >> R; auto latte = rbst.split(root, rbst.lower_bound(root, L)); auto malta = rbst.split(latte.second, rbst.lower_bound(latte.second, R)); if(malta.first) malta.first->lazy++; auto beet = rbst.split(malta.second, 1); root = rbst.merge(rbst.merge(rbst.merge(latte.first, rbst.alloc(L)), malta.first), beet.second); } cout << rbst.count(root) << "\n"; }