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treap_indexed.cpp
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treap_indexed.cpp
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#include <bits/stdc++.h>
using namespace std;
// https://cp-algorithms.com/data_structures/treap.html
mt19937_64 rng(chrono::steady_clock::now().time_since_epoch().count());
struct Treap {
long long node_value;
long long mx;
long long sum;
long long add;
int size;
long long prio;
Treap *l, *r;
Treap(long long value)
: node_value(value), mx(value), sum(value), add(0), size(1), prio(rng()), l(nullptr), r(nullptr) {}
void apply(long long v) {
node_value += v;
mx += v;
sum += v * size;
add += v;
}
void push() {
if (add != 0) {
if (l != nullptr)
l->apply(add);
if (r != nullptr)
r->apply(add);
add = 0;
}
}
void pull() {
mx = max(node_value, max(get_mx(l), get_mx(r)));
sum = node_value + get_sum(l) + get_sum(r);
size = 1 + get_size(l) + get_size(r);
}
static long long get_mx(Treap *root) { return root == nullptr ? numeric_limits<long long>::min() : root->mx; }
static long long get_sum(Treap *root) { return root == nullptr ? 0 : root->sum; }
static int get_size(Treap *root) { return root == nullptr ? 0 : root->size; }
};
using pTreap = Treap *;
void split(pTreap t, int min_right, pTreap &l, pTreap &r) {
if (!t) {
l = r = nullptr;
} else {
t->push();
if (Treap::get_size(t->l) >= min_right) {
split(t->l, min_right, l, t->l);
r = t;
} else {
split(t->r, min_right - Treap::get_size(t->l) - 1, t->r, r);
l = t;
}
t->pull();
}
}
void merge(pTreap &t, pTreap &l, pTreap &r) {
if (!l || !r) {
t = l ? l : r;
} else {
l->push();
r->push();
if (l->prio > r->prio) {
merge(l->r, l->r, r);
t = l;
} else {
merge(r->l, l, r->l);
t = r;
}
t->pull();
}
}
void insert(pTreap &t, int index, long long value) {
pTreap l, r;
split(t, index, l, r);
auto node = new Treap(value);
merge(t, l, node);
merge(t, t, r);
}
void remove(pTreap &t, int index) {
pTreap left1, right1, left2, right2;
split(t, index, left1, right1);
split(right1, 1, left2, right2);
delete left2;
merge(t, left1, right2);
}
void modify(pTreap &t, int ll, int rr, long long delta) {
pTreap left1, right1, left2, right2;
split(t, rr + 1, left1, right1);
split(left1, ll, left2, right2);
if (right2 != nullptr)
right2->apply(delta);
merge(t, left2, right2);
merge(t, t, right1);
}
Treap query(pTreap &t, int ll, int rr) {
pTreap left1, right1, left2, right2;
split(t, rr + 1, left1, right1);
split(left1, ll, left2, right2);
Treap res = *right2;
merge(t, left2, right2);
merge(t, t, right1);
return res;
}
int find_first(pTreap t, int ll, int rr, const function<bool(const Treap &)> &f, int l, int r) {
if (ll <= l && r <= rr && !f(*t)) {
return -1;
}
if (l == r) {
return l;
}
t->push();
int m = Treap::get_size(t->l);
int res = -1;
if (ll < m) {
res = find_first(t->l, ll, rr, f, l, l + m - 1);
}
if (res == -1) {
auto single = new Treap(0);
single->size = 1;
single->apply(t->node_value);
res = find_first(single, ll, rr, f, l + m, l + m);
}
if (rr > m && res == -1) {
res = find_first(t->r, ll, rr, f, l + m + 1, r);
}
t->pull();
return res;
}
// calls all FALSE elements to the left of the sought position exactly once
int find_first(pTreap t, int ll, int rr, const function<bool(const Treap &)> &f) {
assert(0 <= ll && ll <= rr && rr <= Treap::get_size(t) - 1);
return find_first(t, ll, rr, f, 0, Treap::get_size(t) - 1);
}
// Returns min(p | p<=rr && sum[ll..p]>=sum). If no such p exists, returns -1
int sum_lower_bound(pTreap t, int ll, int rr, long long sum) {
long long sumSoFar = 0;
return find_first(t, ll, rr, [&](const Treap &node) {
if (sumSoFar + node.sum >= sum)
return true;
sumSoFar += node.sum;
return false;
});
}
void clear(pTreap &t) {
if (!t)
return;
clear(t->l);
clear(t->r);
delete t;
t = nullptr;
}
void print(pTreap t) {
if (!t)
return;
print(t->l);
cout << t->node_value << endl;
print(t->r);
}
// usage example
int main() {
pTreap t = nullptr;
int pos = 0;
for (int a : {1, 2, 7, 4, 5})
insert(t, pos++, a);
int n = t->size;
for (int i = 0; i < n; ++i)
cout << query(t, i, i).node_value << endl;
modify(t, 1, 3, 10);
for (int i = 0; i < n; ++i)
cout << query(t, i, i).node_value << endl;
for (int i = 0; i < n; ++i)
remove(t, 0);
cout << Treap::get_size(t) << endl;
for (int v : {2, 1, 10, 20}) {
insert(t, Treap::get_size(t), v);
}
cout << (2 == sum_lower_bound(t, 0, Treap::get_size(t) - 1, 12));
clear(t);
}