#include <bits/stdc++.h>
#include<unordered_map>
#include<unordered_set>
#include<algorithm>
using namespace std;
template <typename T>
T inverse(T a, T m) {
T u = 0, v = 1;
while (a != 0) {
T t = m / a;
m -= t * a; swap(a, m);
u -= t * v; swap(u, v);
}
assert(m == 1);
return u;
}
template <typename T>
class Modular {
public:
using Type = typename decay<decltype(T::value)>::type;
constexpr Modular() : value() {}
template <typename U>
Modular(const U& x) {
value = normalize(x);
}
template <typename U>
static Type normalize(const U& x) {
Type v;
if (-mod() <= x && x < mod()) v = static_cast<Type>(x);
else v = static_cast<Type>(x % mod());
if (v < 0) v += mod();
return v;
}
const Type& operator()() const { return value; }
template <typename U>
explicit operator U() const { return static_cast<U>(value); }
constexpr static Type mod() { return T::value; }
Modular& operator+=(const Modular& other) { if ((value += other.value) >= mod()) value -= mod(); return *this; }
Modular& operator-=(const Modular& other) { if ((value -= other.value) < 0) value += mod(); return *this; }
template <typename U> Modular& operator+=(const U& other) { return *this += Modular(other); }
template <typename U> Modular& operator-=(const U& other) { return *this -= Modular(other); }
Modular& operator++() { return *this += 1; }
Modular& operator--() { return *this -= 1; }
Modular operator++(int) { Modular result(*this); *this += 1; return result; }
Modular operator--(int) { Modular result(*this); *this -= 1; return result; }
Modular operator-() const { return Modular(-value); }
template <typename U = T>
typename enable_if<is_same<typename Modular<U>::Type, int>::value, Modular>::type& operator*=(const Modular& rhs) {
value = normalize(static_cast<int64_t>(value) * static_cast<int64_t>(rhs.value));
return *this;
}
template <typename U = T>
typename enable_if<is_same<typename Modular<U>::Type, int64_t>::value, Modular>::type& operator*=(const Modular& rhs) {
int64_t q = static_cast<int64_t>(static_cast<long ld>(value) * rhs.value / mod());
value = normalize(value * rhs.value - q * mod());
return *this;
}
template <typename U = T>
typename enable_if<!is_integral<typename Modular<U>::Type>::value, Modular>::type& operator*=(const Modular& rhs) {
value = normalize(value * rhs.value);
return *this;
}
Modular& operator/=(const Modular& other) { return *this *= Modular(inverse(other.value, mod())); }
template <typename U>
friend const Modular<U>& abs(const Modular<U>& v) { return v; }
template <typename U>
friend bool operator==(const Modular<U>& lhs, const Modular<U>& rhs);
template <typename U>
friend bool operator<(const Modular<U>& lhs, const Modular<U>& rhs);
template <typename U>
friend std::istream& operator>>(std::istream& stream, Modular<U>& number);
private:
Type value;
};
template <typename T> bool operator==(const Modular<T>& lhs, const Modular<T>& rhs) { return lhs.value == rhs.value; }
template <typename T, typename U> bool operator==(const Modular<T>& lhs, U rhs) { return lhs == Modular<T>(rhs); }
template <typename T, typename U> bool operator==(U lhs, const Modular<T>& rhs) { return Modular<T>(lhs) == rhs; }
template <typename T> bool operator!=(const Modular<T>& lhs, const Modular<T>& rhs) { return !(lhs == rhs); }
template <typename T, typename U> bool operator!=(const Modular<T>& lhs, U rhs) { return !(lhs == rhs); }
template <typename T, typename U> bool operator!=(U lhs, const Modular<T>& rhs) { return !(lhs == rhs); }
template <typename T> bool operator<(const Modular<T>& lhs, const Modular<T>& rhs) { return lhs.value < rhs.value; }
template <typename T> Modular<T> operator+(const Modular<T>& lhs, const Modular<T>& rhs) { return Modular<T>(lhs) += rhs; }
template <typename T, typename U> Modular<T> operator+(const Modular<T>& lhs, U rhs) { return Modular<T>(lhs) += rhs; }
template <typename T, typename U> Modular<T> operator+(U lhs, const Modular<T>& rhs) { return Modular<T>(lhs) += rhs; }
template <typename T> Modular<T> operator-(const Modular<T>& lhs, const Modular<T>& rhs) { return Modular<T>(lhs) -= rhs; }
template <typename T, typename U> Modular<T> operator-(const Modular<T>& lhs, U rhs) { return Modular<T>(lhs) -= rhs; }
template <typename T, typename U> Modular<T> operator-(U lhs, const Modular<T>& rhs) { return Modular<T>(lhs) -= rhs; }
template <typename T> Modular<T> operator*(const Modular<T>& lhs, const Modular<T>& rhs) { return Modular<T>(lhs) *= rhs; }
template <typename T, typename U> Modular<T> operator*(const Modular<T>& lhs, U rhs) { return Modular<T>(lhs) *= rhs; }
template <typename T, typename U> Modular<T> operator*(U lhs, const Modular<T>& rhs) { return Modular<T>(lhs) *= rhs; }
template <typename T> Modular<T> operator/(const Modular<T>& lhs, const Modular<T>& rhs) { return Modular<T>(lhs) /= rhs; }
template <typename T, typename U> Modular<T> operator/(const Modular<T>& lhs, U rhs) { return Modular<T>(lhs) /= rhs; }
template <typename T, typename U> Modular<T> operator/(U lhs, const Modular<T>& rhs) { return Modular<T>(lhs) /= rhs; }
template<typename T, typename U>
Modular<T> power(const Modular<T>& a, const U& b) {
assert(b >= 0);
Modular<T> x = a, res = 1;
U p = b;
while (p > 0) {
if (p & 1) res *= x;
x *= x;
p >>= 1;
}
return res;
}
template <typename T>
bool IsZero(const Modular<T>& number) {
return number() == 0;
}
template <typename T>
string to_string(const Modular<T>& number) {
return to_string(number());
}
template <typename T>
std::ostream& operator<<(std::ostream& stream, const Modular<T>& number) {
return stream << number();
}
template <typename T>
std::istream& operator>>(std::istream& stream, Modular<T>& number) {
typename common_type<typename Modular<T>::Type, int64_t>::type x;
stream >> x;
number.value = Modular<T>::normalize(x);
return stream;
}
/*
using ModType = int;
struct VarMod { static ModType value; };
ModType VarMod::value;
ModType& md = VarMod::value;
using Mint = Modular<VarMod>;
*/
constexpr int md = 998244353;
using Mint = Modular<std::integral_constant<decay<decltype(md)>::type, md>>;
vector<Mint> fact(1, 1);
vector<Mint> inv_fact(1, 1);
Mint C(int n, int k) {
if (k < 0 || k > n) {
return 0;
}
while ((int)fact.size() < n + 1) {
fact.push_back(fact.back() * (int)fact.size());
inv_fact.push_back(1 / fact.back());
}
return fact[n] * inv_fact[k] * inv_fact[n - k];
}
#define mp make_pair
#define pb push_back
#define fi first
#define se second
#define all(x) begin(x), end(x)
#define rall(x) rbegin(x), rend(x)
#define yes cout<<"YES\n"
#define no cout<<"NO\n"
#define out(x) cout<<x<<'\n'
typedef long long ll;
typedef vector<int> vi;
typedef vector<vi> vvi;
typedef vector<pair<int, int> > vpii;
typedef pair<ll, ll> pll;
typedef vector<pll> vpll;
typedef vector<ll> vll;
#define pii pair<int,int>
int dx[4] = { -1, 0, 1, 0 };
int dy[4] = { 0, 1, 0, -1 };
int dx8[8] = { 0,0,-1,1,-1,1,-1,1 };
int dy8[8] = { -1,1,0,0,-1,1,1,-1 };
#include "cyberland.h"
struct dsu{
vector<int> par,sz;
int total_groups;
void init(int n){
par.resize(n); sz.resize(n);
for(int i=0;i<n;i++){
par[i]=i;
sz[i]=1;
}
}
int find(int x){
if(par[x]==x) return x;
else return par[x]=find(par[x]);
}
void unite(int x, int y) {
x = find(x);
y = find(y);
if (x == y) return;
if (sz[x] < sz[y]) swap(x, y);
par[y] = x;
sz[x] += sz[y];
total_groups--;
}
bool same(int x,int y){
x = find(x);
y = find(y);
if(x==y) return true;
else return false;
}
};
#defeint ld long double
double solve(int N, int M, int K, int H, vi fir, vi sec, vi co, vi arr) {
vector<vpii> g(N);
dsu ds; ds.init(N);
for(int i=0;i<M;i++){
if(fir[i]!=H && sec[i]!=H) ds.unite(fir[i],sec[i]);
g[fir[i]].pb(mp(co[i],sec[i]));
g[sec[i]].pb(mp(co[i],fir[i]));
}
vector<ld> pwr(K+1,1);
for(int i=1;i<=K;i++){
pwr[i]=pwr[i-1]/2;
}
arr[0]=0;
vector<vector<ld>> dist(K+1,vector<ld>(N,1e18));
using node=tuple<ld,int,int>;
priority_queue<node,vector<node>,greater<node>> pq;
auto enq=[&](int k,int x,ld d){
if(dist[k][x]>d){
dist[k][x]=d;
pq.push({d,k,x});
}
};
enq(K,H,0);
while(pq.size()){
auto [d,k,x]=pq.top(); pq.pop();
if (dist[k][x] < d) continue;
if (arr[x] == 0) return (double)d;
for(auto&[c,v]:g[x]){
if(ds.find(v)!=ds.find(0)) continue;
enq(k,v,d+c*pwr[K-k]);
if(arr[x]==2 && k>0) enq(k-1,v,d+c*pwr[K-k+1]);
}
}
return (double)-1;
}
Compilation message
cyberland.cpp:231:2: error: invalid preprocessing directive #defeint; did you mean #define?
231 | #defeint ld long double
| ^~~~~~~
| define
cyberland.cpp: In member function 'typename std::enable_if<std::is_same<typename Modular<U>::Type, long int>::value, Modular<T> >::type& Modular<T>::operator*=(const Modular<T>&)':
cyberland.cpp:60:53: error: expected '>' before 'ld'
60 | int64_t q = static_cast<int64_t>(static_cast<long ld>(value) * rhs.value / mod());
| ^~
cyberland.cpp:60:53: error: expected '(' before 'ld'
60 | int64_t q = static_cast<int64_t>(static_cast<long ld>(value) * rhs.value / mod());
| ^~
| (
cyberland.cpp:60:53: error: 'ld' was not declared in this scope
60 | int64_t q = static_cast<int64_t>(static_cast<long ld>(value) * rhs.value / mod());
| ^~
cyberland.cpp:60:84: error: expected ')' before ';' token
60 | int64_t q = static_cast<int64_t>(static_cast<long ld>(value) * rhs.value / mod());
| ^
| )
cyberland.cpp: In function 'double solve(int, int, int, int, vi, vi, vi, vi)':
cyberland.cpp:240:9: error: 'ld' was not declared in this scope; did you mean 'll'?
240 | vector<ld> pwr(K+1,1);
| ^~
| ll
cyberland.cpp:240:11: error: template argument 1 is invalid
240 | vector<ld> pwr(K+1,1);
| ^
cyberland.cpp:240:11: error: template argument 2 is invalid
cyberland.cpp:240:22: error: expression list treated as compound expression in initializer [-fpermissive]
240 | vector<ld> pwr(K+1,1);
| ^
cyberland.cpp:240:18: warning: left operand of comma operator has no effect [-Wunused-value]
240 | vector<ld> pwr(K+1,1);
| ~^~
cyberland.cpp:242:6: error: invalid types 'int[int]' for array subscript
242 | pwr[i]=pwr[i-1]/2;
| ^
cyberland.cpp:242:13: error: invalid types 'int[int]' for array subscript
242 | pwr[i]=pwr[i-1]/2;
| ^
cyberland.cpp:245:16: error: template argument 2 is invalid
245 | vector<vector<ld>> dist(K+1,vector<ld>(N,1e18));
| ^~
cyberland.cpp:245:18: error: template argument 1 is invalid
245 | vector<vector<ld>> dist(K+1,vector<ld>(N,1e18));
| ^~
cyberland.cpp:245:18: error: template argument 2 is invalid
cyberland.cpp:245:39: error: template argument 2 is invalid
245 | vector<vector<ld>> dist(K+1,vector<ld>(N,1e18));
| ^
cyberland.cpp:245:48: error: expression list treated as compound expression in initializer [-fpermissive]
245 | vector<vector<ld>> dist(K+1,vector<ld>(N,1e18));
| ^
cyberland.cpp:247:17: error: 'node' was not declared in this scope
247 | priority_queue<node,vector<node>,greater<node>> pq;
| ^~~~
cyberland.cpp:247:33: error: template argument 2 is invalid
247 | priority_queue<node,vector<node>,greater<node>> pq;
| ^
cyberland.cpp:247:47: error: template argument 1 is invalid
247 | priority_queue<node,vector<node>,greater<node>> pq;
| ^~
cyberland.cpp:247:47: error: template argument 2 is invalid
cyberland.cpp:247:47: error: template argument 3 is invalid
cyberland.cpp:248:27: error: 'ld' is not a type
248 | auto enq=[&](int k,int x,ld d){
| ^~
cyberland.cpp: In lambda function:
cyberland.cpp:249:10: error: invalid types 'int[int]' for array subscript
249 | if(dist[k][x]>d){
| ^
cyberland.cpp:250:8: error: invalid types 'int[int]' for array subscript
250 | dist[k][x]=d;
| ^
cyberland.cpp:251:7: error: request for member 'push' in 'pq', which is of non-class type 'int'
251 | pq.push({d,k,x});
| ^~~~
cyberland.cpp: In function 'double solve(int, int, int, int, vi, vi, vi, vi)':
cyberland.cpp:255:11: error: request for member 'size' in 'pq', which is of non-class type 'int'
255 | while(pq.size()){
| ^~~~
cyberland.cpp:256:19: error: request for member 'top' in 'pq', which is of non-class type 'int'
256 | auto [d,k,x]=pq.top(); pq.pop();
| ^~~
cyberland.cpp:256:29: error: request for member 'pop' in 'pq', which is of non-class type 'int'
256 | auto [d,k,x]=pq.top(); pq.pop();
| ^~~