matsutaku-library
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test/aoj/aoj-do_use_segment_tree-binary_tree.test.cpp
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- Last update: 2024-07-22 18:41:16+09:00
- Problem: https://onlinejudge.u-aizu.ac.jp/problems/2450
Code
#define PROBLEM "https://onlinejudge.u-aizu.ac.jp/problems/2450"
#include "include/mtl/lazy_segment_tree.hpp"
#include "include/mtl/hld.hpp"
#include <bits/stdc++.h>
using namespace std;
constexpr int MINF = -1e9;
struct M {
int l,r,sum,v,sz;
M() : v(MINF), sz(0) {}
M(int w) : l(w),r(w),sum(w),v(w), sz(1) {}
friend M operator*(const M& lhs, const M& rhs) {
if (lhs.v == MINF) return rhs;
if (rhs.v == MINF) return lhs;
M ret;
ret.l = max(lhs.l, lhs.sum + rhs.l);
ret.r = max(rhs.r, lhs.r + rhs.sum);
ret.v = max({lhs.v, rhs.v, lhs.r + rhs.l});
ret.sum = lhs.sum + rhs.sum;
ret.sz = lhs.sz + rhs.sz;
return ret;
}
};
struct A {
int v;
bool f;
A() : f(false) {}
A(int v) : v(v), f(true) {}
bool operator()() const { return f; }
A& operator*=(const A& r) {
if (r.f) *this = r;
return *this;
}
M act(const M& m) const {
if (!f) return m;
M ret = m;
ret.sum = v*m.sz;
ret.l = ret.r = ret.v = (v >= 0 ? ret.sum : v);
return ret;
}
};
int main() {
int n,q; cin>>n>>q;
vector<int> W(n);
for (auto& w:W) cin>>w;
Hld T(n);
for (int i = 0; i < n-1; i++) {
int s,e; cin>>s>>e; s--; e--;
T.add_edge(s,e);
}
T.build();
vector<int> X(n*2);
for (int i = 0; i < n; i++)
X[T.in[i]] = X[n+n-1-T.in[i]] = W[i];
SegmentTreebase<M,A> RQ(X.begin(), X.end());
auto range_update = [&](int l, int r, int v) {
RQ.update(l,r,v);
RQ.update(n+n-r, n+n-l, v);
};
auto query = [&](int l, int r) {
return RQ.query(l,r);
};
auto reverse_query = [&](int l, int r) {
return RQ.query(n+n-r, n+n-l);
};
for (int i = 0; i < q; i++) {
int t; cin>>t;
if (t == 1) {
int a,b,c; cin>>a>>b>>c; a--; b--;
T.update(a,b,range_update,c);
} else if (t == 2) {
int a,b,c; cin>>a>>b>>c; a--; b--;
cout << T.query(a,b,query,reverse_query).v << endl;
}
}
}#line 1 "test/aoj/aoj-do_use_segment_tree-binary_tree.test.cpp"
#define PROBLEM "https://onlinejudge.u-aizu.ac.jp/problems/2450"
#line 2 "include/mtl/bit_manip.hpp"
#include <cstdint>
#include <cassert>
#if __cplusplus >= 202002L
#ifndef MTL_CPP20
#define MTL_CPP20
#endif
#include <bit>
#endif
namespace bm {
/// Count 1s for each 8 bits
inline constexpr uint64_t popcnt_e8(uint64_t x) {
x = (x & 0x5555555555555555) + ((x>>1) & 0x5555555555555555);
x = (x & 0x3333333333333333) + ((x>>2) & 0x3333333333333333);
x = (x & 0x0F0F0F0F0F0F0F0F) + ((x>>4) & 0x0F0F0F0F0F0F0F0F);
return x;
}
/// Count 1s
inline constexpr unsigned popcnt(uint64_t x) {
#ifdef MTL_CPP20
return std::popcount(x);
#else
return (popcnt_e8(x) * 0x0101010101010101) >> 56;
#endif
}
/// Alias to mtl::popcnt(x)
constexpr unsigned popcount(uint64_t x) {
return popcnt(x);
}
/// Count trailing 0s. s.t. *11011000 -> 3
inline constexpr unsigned ctz(uint64_t x) {
#ifdef MTL_CPP20
return std::countr_zero(x);
#else
return popcnt((x & (-x)) - 1);
#endif
}
/// Alias to mtl::ctz(x)
constexpr unsigned countr_zero(uint64_t x) {
return ctz(x);
}
/// Count trailing 1s. s.t. *11011011 -> 2
inline constexpr unsigned cto(uint64_t x) {
#ifdef MTL_CPP20
return std::countr_one(x);
#else
return ctz(~x);
#endif
}
/// Alias to mtl::cto(x)
constexpr unsigned countr_one(uint64_t x) {
return cto(x);
}
inline constexpr unsigned ctz8(uint8_t x) {
return x == 0 ? 8 : popcnt_e8((x & (-x)) - 1);
}
/// [00..0](8bit) -> 0, [**..*](not only 0) -> 1
inline constexpr uint8_t summary(uint64_t x) {
constexpr uint64_t hmask = 0x8080808080808080ull;
constexpr uint64_t lmask = 0x7F7F7F7F7F7F7F7Full;
auto a = x & hmask;
auto b = x & lmask;
b = hmask - b;
b = ~b;
auto c = (a | b) & hmask;
c *= 0x0002040810204081ull;
return uint8_t(c >> 56);
}
/// Extract target area of bits
inline constexpr uint64_t bextr(uint64_t x, unsigned start, unsigned len) {
uint64_t mask = len < 64 ? (1ull<<len)-1 : 0xFFFFFFFFFFFFFFFFull;
return (x >> start) & mask;
}
/// 00101101 -> 00111111 -count_1s-> 6
inline constexpr unsigned log2p1(uint8_t x) {
if (x & 0x80)
return 8;
uint64_t p = uint64_t(x) * 0x0101010101010101ull;
p -= 0x8040201008040201ull;
p = ~p & 0x8080808080808080ull;
p = (p >> 7) * 0x0101010101010101ull;
p >>= 56;
return p;
}
/// 00101100 -mask_mssb-> 00100000 -to_index-> 5
inline constexpr unsigned mssb8(uint8_t x) {
assert(x != 0);
return log2p1(x) - 1;
}
/// 00101100 -mask_lssb-> 00000100 -to_index-> 2
inline constexpr unsigned lssb8(uint8_t x) {
assert(x != 0);
return popcnt_e8((x & -x) - 1);
}
/// Count leading 0s. 00001011... -> 4
inline constexpr unsigned clz(uint64_t x) {
#ifdef MTL_CPP20
return std::countl_zero(x);
#else
if (x == 0)
return 64;
auto i = mssb8(summary(x));
auto j = mssb8(bextr(x, 8 * i, 8));
return 63 - (8 * i + j);
#endif
}
/// Alias to mtl::clz(x)
constexpr unsigned countl_zero(uint64_t x) {
return clz(x);
}
/// Count leading 1s. 11110100... -> 4
inline constexpr unsigned clo(uint64_t x) {
#ifdef MTL_CPP20
return std::countl_one(x);
#else
return clz(~x);
#endif
}
/// Alias to mtl::clo(x)
constexpr unsigned countl_one(uint64_t x) {
return clo(x);
}
inline constexpr unsigned clz8(uint8_t x) {
return x == 0 ? 8 : 7 - mssb8(x);
}
inline constexpr uint64_t bit_reverse(uint64_t x) {
x = ((x & 0x00000000FFFFFFFF) << 32) | ((x & 0xFFFFFFFF00000000) >> 32);
x = ((x & 0x0000FFFF0000FFFF) << 16) | ((x & 0xFFFF0000FFFF0000) >> 16);
x = ((x & 0x00FF00FF00FF00FF) << 8) | ((x & 0xFF00FF00FF00FF00) >> 8);
x = ((x & 0x0F0F0F0F0F0F0F0F) << 4) | ((x & 0xF0F0F0F0F0F0F0F0) >> 4);
x = ((x & 0x3333333333333333) << 2) | ((x & 0xCCCCCCCCCCCCCCCC) >> 2);
x = ((x & 0x5555555555555555) << 1) | ((x & 0xAAAAAAAAAAAAAAAA) >> 1);
return x;
}
/// Check if x is power of 2. 00100000 -> true, 00100001 -> false
constexpr bool has_single_bit(uint64_t x) noexcept {
#ifdef MTL_CPP20
return std::has_single_bit(x);
#else
return x != 0 && (x & (x - 1)) == 0;
#endif
}
/// Bit width needs to represent x. 00110110 -> 6
constexpr int bit_width(uint64_t x) noexcept {
#ifdef MTL_CPP20
return std::bit_width(x);
#else
return 64 - clz(x);
#endif
}
/// Ceil power of 2. 00110110 -> 01000000
constexpr uint64_t bit_ceil(uint64_t x) {
#ifdef MTL_CPP20
return std::bit_ceil(x);
#else
if (x == 0) return 1;
return 1ull << bit_width(x - 1);
#endif
}
/// Floor power of 2. 00110110 -> 00100000
constexpr uint64_t bit_floor(uint64_t x) {
#ifdef MTL_CPP20
return std::bit_floor(x);
#else
if (x == 0) return 0;
return 1ull << (bit_width(x) - 1);
#endif
}
} // namespace bm
#line 3 "include/mtl/lazy_segment_tree.hpp"
// #include "monoid.hpp"
#include <cstddef>
#include <utility>
#include <vector>
#include <stack>
#line 9 "include/mtl/lazy_segment_tree.hpp"
#if __cpp_concepts >= 202002L
#include <concepts>
template<typename M>
concept LazySegmentTreeMonoid = requires (M m) {
{m * m} -> std::same_as<M>;
};
template<typename A, typename M>
concept LazySegmentTreeOperatorMonoid = requires(A a, M m) {
{a *= a} -> std::same_as<A&>;
{a.act(m)} -> std::same_as<M>;
};
#endif
template <typename M, typename A>
#if __cpp_concepts >= 202002L
requires LazySegmentTreeMonoid<M> &&
LazySegmentTreeOperatorMonoid<A,M>
#endif
class SegmentTreebase {
private:
size_t size_;
std::vector<std::pair<M, A>> tree_;
std::vector<size_t> ids_;
public:
explicit SegmentTreebase(size_t size) :
size_(1ull<<(64-bm::clz(size-1))),
tree_(size_*2) {
ids_.reserve((64-bm::clz(size-1))*2);
}
template <typename Iter>
explicit SegmentTreebase(Iter begin, Iter end)
: SegmentTreebase(std::distance(begin, end)) {
static_assert(std::is_convertible<typename std::iterator_traits<Iter>::value_type, M>::value, "");
for (auto it = begin; it != end; ++it) {
tree_[size_ + it - begin].first = *it;
}
for (size_t i = size_-1; i > 0; i--) {
tree_[i].first = tree_[i*2].first * tree_[i*2+1].first;
}
}
inline void range_update(size_t l, size_t r, const A& e) {
assert(l <= r);
assert(r <= size_);
if (l == r) return;
_lazy_propagation(l, r);
for (size_t _l=l+size_, _r=r+size_; _l<_r; _l>>=1, _r>>=1) {
if (_l&1)
tree_[_l++].second *= e;
if (_r&1)
tree_[--_r].second *= e;
}
for (auto id : ids_) {
_propagate(id*2);
_propagate(id*2+1);
tree_[id].first = tree_[id*2].first * tree_[id*2+1].first;
}
}
inline void update(size_t l, size_t r, const A& e) {
range_update(l, r, e);
}
inline void update(size_t i, const A& e) {
range_update(i, i+1, e);
}
template<typename T>
inline void set(size_t i, T&& e) {
_lazy_propagation(i, i+1);
int u = i+size_;
tree_[u].first = M(std::forward<T>(e));
u >>= 1;
while (u > 0) {
tree_[u].first = tree_[u*2].first * tree_[u*2+1].first;
u >>= 1;
}
}
inline M query(size_t l, size_t r) {
_lazy_propagation(l, r);
M lhs,rhs;
for (size_t _l=l+size_, _r=r+size_; _l<_r; _l>>=1, _r>>=1) {
if (_l&1) {
_propagate(_l);
lhs = lhs * tree_[_l].first;
++_l;
}
if (_r&1) {
--_r;
_propagate(_r);
rhs = tree_[_r].first * rhs;
}
}
return lhs * rhs;
}
/// Alias for query(l, r)
M prod(size_t l, size_t r) {
return query(l, r);
}
inline const M& get(size_t index) {
_lazy_propagation(index, index+1);
auto l = index+size_;
_propagate(l);
return tree_[l].first;
}
private:
void _set_ids(size_t l, size_t r) {
ids_.clear();
auto _l=l+size_, _r=r+size_;
auto lth = _l/(_l&(-_l))/2;
auto rth = _r/(_r&(-_r))/2;
for (; _l<_r; _l>>=1, _r>>=1) {
if (_r <= rth) ids_.push_back(_r);
if (_l <= lth) ids_.push_back(_l);
}
for (; _l>0; _l>>=1)
ids_.push_back(_l);
}
inline void _propagate(size_t id) {
A& e = tree_[id].second;
tree_[id].first = e.act(tree_[id].first);
if (id < size_) {
tree_[id*2].second *= e;
tree_[id*2+1].second *= e;
}
tree_[id].second = A();
}
void _lazy_propagation(size_t l, size_t r) {
if (l == r) return;
_set_ids(l, r);
for (auto it = ids_.rbegin(); it != ids_.rend(); ++it)
_propagate(*it);
}
public:
template<class F>
size_t max_right(size_t begin, size_t end, F f) {
if (begin == end) return end;
M p;
std::stack<std::pair<size_t, M>> rps;
auto l = size_ + begin;
auto r = size_ + end;
_lazy_propagation(begin, end);
auto access = [&](size_t i) {
_propagate(i);
return tree_[i].first;
};
while (l < r and f(p * access(l))) {
if (l&1) p = p * tree_[l++].first;
if (r&1) {
rps.emplace(r, access(r-1));
r--;
}
l>>=1; r>>=1;
}
if (l >= r) {
while (rps.size()) {
auto& [r, rp] = rps.top();
if (!f(p * rp)) {
l = r-1;
break;
}
p = p * rp;
rps.pop();
}
if (rps.empty()) return end;
}
while (l < size_) {
assert(!f(p * access(l)));
l <<= 1;
auto pl = access(l);
if (f(p * pl)) {
p = p * pl;
l++;
}
}
return l - size_;
}
template<bool (*F)(M)>
size_t max_right(size_t begin, size_t end) {
return max_right(begin, end, [](M x) { return F(x); });
}
template<class F>
size_t min_left(size_t begin, size_t end, F f) {
if (end == begin) return begin;
M p;
std::stack<std::pair<size_t, M>> lps;
auto l = size_ + begin;
auto r = size_ + end;
_lazy_propagation(begin, end);
auto access = [&](size_t i) {
_propagate(i);
return tree_[i].first;
};
while (l < r and f(access(r-1) * p)) {
if (l&1) {
lps.emplace(l, access(l));
l++;
}
if (r&1) p = tree_[r-1].first * p;
l>>=1; r>>=1;
}
if (l >= r) {
while (lps.size()) {
auto& [l, lp] = lps.top();
if (!f(lp * p)) {
r = l+1;
break;
}
p = lp * p;
lps.pop();
}
if (lps.empty()) return begin;
}
while (r <= size_) {
assert(!f(access(r-1) * p));
r <<= 1;
auto pr = access(r-1);
if (f(pr * p)) {
p = pr * p;
--r;
}
}
return r - size_;
}
template<bool (*F)(M)>
size_t min_left(size_t begin, size_t end) {
return min_left(begin, [](M x) { return F(x); });
}
};
#line 4 "include/mtl/hld.hpp"
struct Hld {
int r,n;
std::vector<std::vector<int>> edge;
std::vector<int> size, in, out, head, rev, par, depth, clen;
private:
void dfs_sz(int v, int p, int d) {
par[v] = p;
size[v] = 1;
if (!edge[v].empty() and edge[v][0] == p)
std::swap(edge[v][0], edge[v].back());
for (auto& t:edge[v]) {
if (t == p) continue;
dfs_sz(t, v, d+1);
size[v] += size[t];
if (size[edge[v][0]] < size[t])
std::swap(edge[v][0], t);
}
}
void dfs_hld(int v, int p, int& times) {
in[v] = times++;
rev[in[v]] = v;
clen[v] = 1;
if (!edge[v].empty() and edge[v][0] != p) {
int t = edge[v][0];
head[t] = head[v];
depth[t] = depth[v];
dfs_hld(t, v, times);
clen[v] += clen[t];
}
for (size_t i = 1; i < edge[v].size(); i++) {
int t = edge[v][i];
if (t == p) continue;
head[t] = t;
depth[t] = depth[v] + 1;
dfs_hld(t, v, times);
}
out[v] = times;
}
public:
Hld(int n) : r(0), n(n), edge(n), size(n), in(n, -1), out(n, -1), head(n, -1), rev(n, -1), par(n, -1), depth(n, -1), clen(n) {}
inline void add_edge(int a, int b) {
edge[a].push_back(b);
edge[b].push_back(a);
}
void build(int root = 0) {
r = root;
dfs_sz(root, -1, 0);
int t = 0;
head[root] = root;
depth[root] = 0;
dfs_hld(root, -1, t);
}
inline int lca(int a, int b) const {
if (depth[a] > depth[b]) std::swap(a, b);
while (depth[a] < depth[b]) {
b = par[head[b]];
}
while (head[a] != head[b]) {
a = par[head[a]];
b = par[head[b]];
}
return in[a] < in[b] ? a : b;
}
private:
template<class Query, class ReverseQuery>
auto _query(int u, int v, Query Q, ReverseQuery RQ, bool include_lca) const -> decltype(Q(0,0)) {
using T = decltype(Q(0,0));
T um, vm;
auto u_up = [&]() {
um = um * (T)RQ(in[head[u]], in[u]+1);
u = par[head[u]];
};
auto v_up = [&]() {
vm = (T)Q(in[head[v]], in[v]+1) * vm;
v = par[head[v]];
};
while (depth[u] > depth[v])
u_up();
while (depth[u] < depth[v])
v_up();
while (head[u] != head[v]) {
u_up();
v_up();
}
if (in[u] < in[v]) {
int l = include_lca ? in[u] : in[u]+1;
return um * (T)Q(l, in[v]+1) * vm;
} else {
int l = include_lca ? in[v] : in[v]+1;
return um * (T)RQ(l, in[u]+1) * vm;
}
}
public:
template<class Query, class ReverseQuery>
auto query(int u, int v, Query Q, ReverseQuery RQ, bool include_lca = true) const -> decltype(Q(0,0)) {
return _query(u, v, Q, RQ, include_lca);
}
/// Query for commutative monoid
template<class Query>
auto query(int u, int v, Query Q, bool include_lca = true) const -> decltype(Q(0,0)) {
return _query(u, v, Q, Q, include_lca);
}
template<class Set, class T>
void set(int i, Set S, T&& val) const {
S(in[i], std::forward<T>(val));
}
template<typename Upd, typename T>
void update(int u, int v, Upd U, const T& val, bool include_lca = true) const {
if (depth[u] > depth[v]) std::swap(u,v);
auto up = [&](int& v) {
U(in[head[v]], in[v]+1, val);
v = par[head[v]];
};
while (depth[u] < depth[v]) {
up(v);
}
while (head[u] != head[v]) {
up(u);
up(v);
}
if (in[u] > in[v]) std::swap(u,v);
int l = include_lca ? in[u] : in[u]+1;
U(l, in[v]+1, val);
}
public:
template<class Add, class Sum>
void subtree_build(Add A, Sum S) const {
dfs_subtree_build(A, S, r);
}
private:
template<class Add, class Sum>
void dfs_subtree_build(Add A, Sum S, int u) const {
for (size_t i = 0; i < edge[u].size(); i++) {
auto v = edge[u][i];
if (v == par[u]) continue;
dfs_subtree_build(A, S, v);
if (i > 0)
A(in[u], S(in[v], in[v]+clen[v]));
}
}
public:
template<class T, class Sum>
T subtree_sum(int r, Sum S) const {
return (T)S(in[r], in[r]+clen[r]);
}
template<class T, class Add>
void subtree_point_add(int u, Add A, const T& val) const {
while (u != -1) {
A(in[u], val);
u = par[head[u]];
}
}
};
#line 4 "test/aoj/aoj-do_use_segment_tree-binary_tree.test.cpp"
#include <bits/stdc++.h>
using namespace std;
constexpr int MINF = -1e9;
struct M {
int l,r,sum,v,sz;
M() : v(MINF), sz(0) {}
M(int w) : l(w),r(w),sum(w),v(w), sz(1) {}
friend M operator*(const M& lhs, const M& rhs) {
if (lhs.v == MINF) return rhs;
if (rhs.v == MINF) return lhs;
M ret;
ret.l = max(lhs.l, lhs.sum + rhs.l);
ret.r = max(rhs.r, lhs.r + rhs.sum);
ret.v = max({lhs.v, rhs.v, lhs.r + rhs.l});
ret.sum = lhs.sum + rhs.sum;
ret.sz = lhs.sz + rhs.sz;
return ret;
}
};
struct A {
int v;
bool f;
A() : f(false) {}
A(int v) : v(v), f(true) {}
bool operator()() const { return f; }
A& operator*=(const A& r) {
if (r.f) *this = r;
return *this;
}
M act(const M& m) const {
if (!f) return m;
M ret = m;
ret.sum = v*m.sz;
ret.l = ret.r = ret.v = (v >= 0 ? ret.sum : v);
return ret;
}
};
int main() {
int n,q; cin>>n>>q;
vector<int> W(n);
for (auto& w:W) cin>>w;
Hld T(n);
for (int i = 0; i < n-1; i++) {
int s,e; cin>>s>>e; s--; e--;
T.add_edge(s,e);
}
T.build();
vector<int> X(n*2);
for (int i = 0; i < n; i++)
X[T.in[i]] = X[n+n-1-T.in[i]] = W[i];
SegmentTreebase<M,A> RQ(X.begin(), X.end());
auto range_update = [&](int l, int r, int v) {
RQ.update(l,r,v);
RQ.update(n+n-r, n+n-l, v);
};
auto query = [&](int l, int r) {
return RQ.query(l,r);
};
auto reverse_query = [&](int l, int r) {
return RQ.query(n+n-r, n+n-l);
};
for (int i = 0; i < q; i++) {
int t; cin>>t;
if (t == 1) {
int a,b,c; cin>>a>>b>>c; a--; b--;
T.update(a,b,range_update,c);
} else if (t == 2) {
int a,b,c; cin>>a>>b>>c; a--; b--;
cout << T.query(a,b,query,reverse_query).v << endl;
}
}
}
Test cases
| Env | Name | Status | Elapsed | Memory |
|---|---|---|---|---|
| g++ | testcase_00 |
AC |
6 ms | 3 MB |
| g++ | testcase_01 |
AC |
5 ms | 3 MB |
| g++ | testcase_02 |
AC |
5 ms | 3 MB |
| g++ | testcase_03 |
AC |
5 ms | 3 MB |
| g++ | testcase_04 |
AC |
6 ms | 4 MB |
| g++ | testcase_05 |
AC |
237 ms | 14 MB |
| g++ | testcase_06 |
AC |
380 ms | 47 MB |
| g++ | testcase_07 |
AC |
464 ms | 123 MB |
| g++ | testcase_08 |
AC |
6 ms | 3 MB |
| g++ | testcase_09 |
AC |
79 ms | 4 MB |
| g++ | testcase_10 |
AC |
351 ms | 52 MB |
| g++ | testcase_11 |
AC |
6 ms | 3 MB |
| g++ | testcase_12 |
AC |
6 ms | 3 MB |
| g++ | testcase_13 |
AC |
7 ms | 3 MB |
| g++ | testcase_14 |
AC |
10 ms | 4 MB |
| g++ | testcase_15 |
AC |
43 ms | 4 MB |
| g++ | testcase_16 |
AC |
230 ms | 6 MB |
| g++ | testcase_17 |
AC |
387 ms | 15 MB |
| g++ | testcase_18 |
AC |
445 ms | 28 MB |
| g++ | testcase_19 |
AC |
703 ms | 52 MB |
| g++ | testcase_20 |
AC |
6 ms | 3 MB |
| g++ | testcase_21 |
AC |
6 ms | 4 MB |
| g++ | testcase_22 |
AC |
18 ms | 4 MB |
| g++ | testcase_23 |
AC |
165 ms | 5 MB |
| g++ | testcase_24 |
AC |
505 ms | 26 MB |
| g++ | testcase_25 |
AC |
529 ms | 52 MB |
| g++ | testcase_26 |
AC |
7 ms | 3 MB |
| g++ | testcase_27 |
AC |
366 ms | 9 MB |
| g++ | testcase_28 |
AC |
466 ms | 28 MB |
| g++ | testcase_29 |
AC |
564 ms | 52 MB |
| g++ | testcase_30 |
AC |
6 ms | 3 MB |
| g++ | testcase_31 |
AC |
10 ms | 3 MB |
| g++ | testcase_32 |
AC |
59 ms | 4 MB |
| g++ | testcase_33 |
AC |
270 ms | 14 MB |
| g++ | testcase_34 |
AC |
364 ms | 28 MB |
| g++ | testcase_35 |
AC |
451 ms | 51 MB |
| g++ | testcase_36 |
AC |
530 ms | 51 MB |
| g++ | testcase_37 |
AC |
452 ms | 52 MB |
| g++ | testcase_38 |
AC |
444 ms | 52 MB |
| clang++ | testcase_00 |
AC |
6 ms | 3 MB |
| clang++ | testcase_01 |
AC |
5 ms | 3 MB |
| clang++ | testcase_02 |
AC |
5 ms | 3 MB |
| clang++ | testcase_03 |
AC |
5 ms | 3 MB |
| clang++ | testcase_04 |
AC |
7 ms | 3 MB |
| clang++ | testcase_05 |
AC |
248 ms | 10 MB |
| clang++ | testcase_06 |
AC |
411 ms | 31 MB |
| clang++ | testcase_07 |
AC |
481 ms | 64 MB |
| clang++ | testcase_08 |
AC |
6 ms | 3 MB |
| clang++ | testcase_09 |
AC |
86 ms | 4 MB |
| clang++ | testcase_10 |
AC |
416 ms | 52 MB |
| clang++ | testcase_11 |
AC |
6 ms | 3 MB |
| clang++ | testcase_12 |
AC |
6 ms | 3 MB |
| clang++ | testcase_13 |
AC |
8 ms | 3 MB |
| clang++ | testcase_14 |
AC |
14 ms | 3 MB |
| clang++ | testcase_15 |
AC |
72 ms | 4 MB |
| clang++ | testcase_16 |
AC |
279 ms | 6 MB |
| clang++ | testcase_17 |
AC |
514 ms | 15 MB |
| clang++ | testcase_18 |
AC |
563 ms | 27 MB |
| clang++ | testcase_19 |
AC |
796 ms | 52 MB |
| clang++ | testcase_20 |
AC |
6 ms | 3 MB |
| clang++ | testcase_21 |
AC |
6 ms | 3 MB |
| clang++ | testcase_22 |
AC |
20 ms | 4 MB |
| clang++ | testcase_23 |
AC |
293 ms | 5 MB |
| clang++ | testcase_24 |
AC |
570 ms | 25 MB |
| clang++ | testcase_25 |
AC |
743 ms | 52 MB |
| clang++ | testcase_26 |
AC |
6 ms | 3 MB |
| clang++ | testcase_27 |
AC |
428 ms | 9 MB |
| clang++ | testcase_28 |
AC |
534 ms | 27 MB |
| clang++ | testcase_29 |
AC |
709 ms | 52 MB |
| clang++ | testcase_30 |
AC |
6 ms | 3 MB |
| clang++ | testcase_31 |
AC |
11 ms | 4 MB |
| clang++ | testcase_32 |
AC |
85 ms | 4 MB |
| clang++ | testcase_33 |
AC |
348 ms | 14 MB |
| clang++ | testcase_34 |
AC |
400 ms | 27 MB |
| clang++ | testcase_35 |
AC |
495 ms | 50 MB |
| clang++ | testcase_36 |
AC |
548 ms | 51 MB |
| clang++ | testcase_37 |
AC |
588 ms | 52 MB |
| clang++ | testcase_38 |
AC |
491 ms | 52 MB |