Submission #166756

#	Submission time	Handle	Problem	Language	Result	Execution time	Memory
166756	2019-12-03T16:57:12 Z	wleung_bvg	Street Lamps (APIO19_street_lamps)	C++14	100 / 100	2476 ms	226032 KB

street_lamps

#include <bits/stdc++.h>
#include <ext/pb_ds/assoc_container.hpp>
#include <ext/pb_ds/tree_policy.hpp>
#include <ext/pb_ds/priority_queue.hpp>
using namespace std;using namespace __gnu_pbds;
template<class C>constexpr int sz(const C&c){return int(c.size());}
using ll=long long;using ld=long double;using uint=unsigned int;using ull=unsigned long long;
using pii=std::pair<int,int>;using pll=std::pair<ll,ll>;using pill=std::pair<int,ll>;using plli=std::pair<ll,int>;using pdd=std::pair<double,double>;using pld=std::pair<ld,ld>;
#if __SIZEOF_INT128__
    using i128=__int128_t;using ui128=__uint128_t;using pi128=std::pair<i128,i128>;
#endif
constexpr const char nl='\n',sp=' ';constexpr const int INT_INF=0x3f3f3f3f;constexpr const ll LL_INF=0x3f3f3f3f3f3f3f3f;
constexpr const double D_INF=std::numeric_limits<double>::infinity();constexpr const ld LD_INF=std::numeric_limits<ld>::infinity();
template<class T>constexpr const T&_min(const T&x,const T&y){return x<y?x:y;}template<class T>constexpr const T&_max(const T&x,const T&y){return x<y?y:x;}
template<class T,class...Ts>constexpr const T&_min(const T&x,const Ts&...xs){return _min(x,_min(xs...));}
template<class T,class...Ts>constexpr const T&_max(const T&x,const Ts&...xs){return _max(x,_max(xs...));}
template<class T,class...Ts>void MIN(T&x,const Ts&...xs){x=_min(x,xs...);}template<class T,class...Ts>void MAX(T&x,const Ts&...xs){x=_max(x,xs...);}
template<class T,class...Args>std::unique_ptr<T>_make_unique(Args&&...args){return std::unique_ptr<T>(new T(std::forward<Args>(args)...));}
template<class T,class...Args>std::shared_ptr<T>_make_shared(Args&&...args){return std::shared_ptr<T>(new T(std::forward<Args>(args)...));}
#define min(...) _min(__VA_ARGS__)
#define max(...) _max(__VA_ARGS__)
#define make_unique _make_unique
#define make_shared _make_shared
std::seed_seq seq{
    (uint64_t)std::chrono::duration_cast<std::chrono::nanoseconds>(std::chrono::high_resolution_clock::now().time_since_epoch()).count(),
    (uint64_t)__builtin_ia32_rdtsc(),(uint64_t)(uintptr_t)make_unique<char>().get()
};
std::mt19937 rng(seq);std::mt19937_64 rng64(seq);const std::size_t RANDOM=std::uniform_int_distribution<std::size_t>(0,(std::numeric_limits<std::size_t>::max)())(rng64);
template<class T,class H=std::hash<T>>struct rand_hash{
    static uint64_t splitmix64(uint64_t x){x+=0x9e3779b97f4a7c15;x=(x^(x>>30))*0xbf58476d1ce4e5b9;x=(x^(x>>27))*0x94d049bb133111eb;return x^(x>>31);}
    std::size_t operator()(const T&x)const{return splitmix64(H{}(x)+RANDOM);}
};
template<class K,class H=rand_hash<K>,class...Ts>using hashset=__gnu_pbds::gp_hash_table<K,__gnu_pbds::null_type,H,Ts...>;
template<class K,class V,class H=rand_hash<K>,class...Ts>using hashmap=__gnu_pbds::gp_hash_table<K,V,H,Ts...>;
template<class K,class C=std::less<K>,class...Ts>using treeset=__gnu_pbds::tree<K,__gnu_pbds::null_type,C,__gnu_pbds::rb_tree_tag,__gnu_pbds::tree_order_statistics_node_update,Ts...>;
template<class K,class V,class C=std::less<K>,class...Ts>using treemap=__gnu_pbds::tree<K,V,C,__gnu_pbds::rb_tree_tag,__gnu_pbds::tree_order_statistics_node_update,Ts...>;
template<class K,class H=rand_hash<K>,class...Ts>using uset=std::unordered_set<K,H,Ts...>;
template<class K,class V,class H=rand_hash<K>,class...Ts>using umap=std::unordered_map<K,V,H,Ts...>;
template<class T>using minpq=std::priority_queue<T,std::vector<T>,std::greater<T>>;template<class T>using maxpq=std::priority_queue<T,std::vector<T>,std::less<T>>;
template<class T>using minpairingheap=__gnu_pbds::priority_queue<T,std::greater<T>,__gnu_pbds::pairing_heap_tag>;
template<class T>using maxpairingheap=__gnu_pbds::priority_queue<T,std::less<T>,__gnu_pbds::pairing_heap_tag>;
template<class T1,class T2,class H1=rand_hash<T1>,class H2=rand_hash<T2>>struct pair_hash{
    std::size_t operator()(const std::pair<T1,T2>&p)const{return 31*H1{}(p.first)+H2{}(p.second);}
};
template<class T>struct is_iterator{
    template<class U,typename std::enable_if<!std::is_convertible<U,const char*>::value,int>::type=0>constexpr static auto has_indirection(int)->decltype(*std::declval<U>(),bool()){return true;}
    template<class>constexpr static bool has_indirection(long){return false;}constexpr static bool value=has_indirection<T>(0);
};

#define INTERACTIVE_INPUT 0
constexpr const int _bufferSize=1<<16,_maxNumLength=128;
char _inputBuffer[_bufferSize+1],*_inputPtr=_inputBuffer,_outputBuffer[_bufferSize],_c,_last,_sign,*_tempInputBuf=nullptr,_numBuf[_maxNumLength],_tempOutputBuf[_maxNumLength],_fill=' ';
FILE*_input=stdin,*_output=stdout,*_error=stderr;const char*_delimiter=" ";int _cur,_outputPtr=0,_numPtr=0,_precision=9,_width=0,_tempOutputPtr=0,_cnt;ull _precisionBase=1000000000;
#ifdef _WIN32
    #define getchar_unlocked getchar
    #define fread_unlocked fread
    #define fwrite_unlocked fwrite
#endif
#if INTERACTIVE_INPUT
    char _getchar(){return _last=getchar_unlocked();}
    char _getcharskipr(){while(_getchar()=='\r');return _last;}
#else
    char _peekchar(){return*_inputPtr?*_inputPtr:(_inputBuffer[fread_unlocked(_inputPtr=_inputBuffer,1,_bufferSize,_input)]='\0',*_inputPtr);}
    char _peekcharskipr(){while(_peekchar()=='\r')_last=*_inputPtr++;return _peekchar();}
    char _getchar(){return _last=*_inputPtr?*_inputPtr++:(_inputBuffer[fread_unlocked(_inputPtr=_inputBuffer,1,_bufferSize,_input)]='\0',*_inputPtr++);}
    char _getcharskipr(){while(_getchar()=='\r');return _last;}
    bool hasNext(){return (_last&&_peekcharskipr())||!feof(_input);}bool hasNextToken(){while(hasNext()&&_peekchar()<=' ')_getchar();return hasNext();}
#endif
template<class I>void _readSigned(I&x){while((_c=_getchar())<=' ');_sign=_c=='-';if(_sign)_c=_getchar();if(_c>='0')for(x=_c-'0';(_c=_getchar())>='0';x=x*10+_c-'0');}
template<class UI>void _readUnsigned(UI&x){while((_c=_getchar())<=' ');for(x=_c-'0';(_c=_getchar())>='0';x=x*10+_c-'0');}
template<class F>void _readFloatingPoint(F&x){for(F _div=1.0;(_c=_getchar())>='0';x+=(_c-'0')/(_div*=10));}
void setLength(int x){if(_tempInputBuf)delete[](_tempInputBuf);_tempInputBuf=new char[x+1];}
template<class I>typename std::enable_if<std::is_integral<I>::value&&std::is_signed<I>::value>::type read(I&x){_readSigned(x);if(_sign)x=-x;}
template<class UI>typename std::enable_if<std::is_integral<UI>::value&&std::is_unsigned<UI>::value>::type read(UI&x){_readUnsignedSigned(x);}
#if __SIZEOF_INT128__
    void read(i128&x){_readSigned(x);if(_sign)x=-x;}void read(ui128&x){_readUnsigned(x);}
#endif
template<class F>typename std::enable_if<std::is_floating_point<F>::value>::type read(F&x){_readSigned(x);if(_c=='.')_readFloatingPoint(x);if(_sign)x=-x;}
void read(char&x){while((x=_getchar())<=' ');}void read(char*x){_cur=0;do{_c=_getchar();}while(_c<=' ');do{x[_cur++]=_c;}while((_c=_getchar())>' ');x[_cur]='\0';}
void readln(char*x){if(_last=='\r')_getcharskipr();for(_cur=0;(_c=_getcharskipr())!='\n'&&_c;x[_cur++]=_c);x[_cur]='\0';}
void read(std::string&x){if(!_tempInputBuf)assert(0);read(_tempInputBuf);x=std::string(_tempInputBuf,_cur);}
void readln(std::string &x){if(!_tempInputBuf)assert(0);readln(_tempInputBuf);x=std::string(_tempInputBuf,_cur);}
template<class T1,class T2>void read(std::pair<T1,T2>&x){read(x.first);read(x.second);}template<class T>void read(std::complex<T>&x){T _re,_im;read(_re);read(_im);x.real(_re);x.imag(_im);}
template<class T>typename std::enable_if<is_iterator<typename T::iterator>::value>::type read(T&x);template<class T,class...Ts>void read(T&x,Ts&&...xs);
template<class It>typename std::enable_if<is_iterator<It>::value>::type read(It st,It en){for(It _i=st;_i!=en;_i++)read(*_i);}
template<class It,class...Ts>typename std::enable_if<is_iterator<It>::value>::type read(It st,It en,Ts&&...xs){read(st,en);read(std::forward<Ts>(xs)...);}
template<class T>typename std::enable_if<is_iterator<typename T::iterator>::value>::type read(T&x){for(auto&&_i:x)read(_i);}
template<class T,class...Ts>void read(T&x,Ts&&...xs){read(x);read(std::forward<Ts>(xs)...);}
void setInput(FILE*file){*_inputPtr='\0';_input=file;}void setInput(const char*s){*_inputPtr='\0';_input=fopen(s,"r");}void setInput(const std::string&s){*_inputPtr='\0';_input=fopen(s.c_str(),"r");}
int _flushBuf(){fwrite_unlocked(_outputBuffer,1,_outputPtr,_output);return _outputPtr=0;}void flush(){_flushBuf();fflush(_output);}
int _putchar(char x){return _outputBuffer[_outputPtr==_bufferSize?_flushBuf():_outputPtr]=x,_outputPtr++;}
void _writeTempBuf(char x){_tempOutputBuf[_tempOutputPtr++]=x;}void _writeOutput(){for(int _i=0;_i<_tempOutputPtr;_putchar(_tempOutputBuf[_i++]));_tempOutputPtr=0;}
void _fillBuf(int x){for(int _i=0;_i<x;_i++)_putchar(_fill);}void _flushNumBuf(){for(;_numPtr;_writeTempBuf(_numBuf[--_numPtr]));}
void _flushTempBuf(){int _tempLen=_tempOutputPtr;_fillBuf(_width-_tempLen);_writeOutput();_fillBuf(-_width-_tempLen);}
void setPrecision(int x){_precision=x;_precisionBase=1;for(int _i=0;_i<x;_i++,_precisionBase*=10);}void setWidth(int x){_width=x;}void setFill(char x){_fill=x;}
void setDelimiter(const char*x){_delimiter=x;}void setDelimiter(const std::string&x){_delimiter=x.c_str();}
void writeDelimiter(){for(const char*_p=_delimiter;*_p;_putchar(*_p++));}
template<class T>void _writeNum(const T&x,int digits){_cnt=0;for(T _y=x;_y;_y/=10,_cnt++)_numBuf[_numPtr++]='0'+_y%10;for(;_cnt<digits;_cnt++)_numBuf[_numPtr++]='0';_flushNumBuf();}
template<class F>void _writeFloatingPoint(const F&x){ull _I=ull(x);ull _F=(x-_I)*_precisionBase+F(0.5);if(_F>=_precisionBase){_I++;_F=0;}_writeNum(_I,1);_writeTempBuf('.');_writeNum(_F,_precision);}
void write(const bool&x){if(x)_writeTempBuf('1');else _writeTempBuf('0');_flushTempBuf();}void write(const char&x){_writeTempBuf(x);_flushTempBuf();}
void write(const char*x){int _slen=strlen(x);_fillBuf(_width-_slen);for(const char*_p=x;*_p;_putchar(*_p++));_fillBuf(-_width-_slen);}
void write(const std::string&x){_fillBuf(_width-int(x.length()));for(int _i=0;_i<int(x.length());_putchar(x[_i++]));_fillBuf(-_width-int(x.length()));}
template<class I>typename std::enable_if<std::is_integral<I>::value&&std::is_signed<I>::value>::type write(const I&x){
    using UI=typename std::make_unsigned<I>::type;if(x<0){_writeTempBuf('-');_writeNum(UI(-x),1);}else{_writeNum(UI(x),1);}_flushTempBuf();
}
template<class UI>typename std::enable_if<std::is_integral<UI>::value&&std::is_unsigned<UI>::value>::type write(const UI&x){_writeNum(x,1);_flushTempBuf();}
template<class F>typename std::enable_if<std::is_floating_point<F>::value>::type write(const F&x){
    if(std::isnan(x)){write("NaN");}else if(std::isinf(x)){write("Inf");}else if(x<0){_writeTempBuf('-');_writeFloatingPoint(-x);}else{_writeFloatingPoint(x);}_flushTempBuf();
}
#if __SIZEOF_INT128__
    void write(const i128&x){if(x<0){_writeTempBuf('-');_writeNum(ui128(-x),1);}else{_writeNum(ui128(x),1);}_flushTempBuf();}void write(const ui128&x){_writeNum(x,1);_flushTempBuf();}
#endif
template<class T1,class T2>void write(const std::pair<T1,T2>&x){write(x.first);writeDelimiter();write(x.second);}
template<class T>void write(const std::complex<T>&x){write(x.real());writeDelimiter();write(x.imag());}
template<class T>typename std::enable_if<is_iterator<typename T::iterator>::value>::type write(const T&x);template<class T,class...Ts>void write(const T&x,Ts&&...xs);
template<class It>typename std::enable_if<is_iterator<It>::value>::type write(It st,It en){bool _first=1;for(It _i=st;_i!=en;_i++){if(_first)_first=0;else writeDelimiter();write(*_i);}}
template<class It,class...Ts>typename std::enable_if<is_iterator<It>::value>::type write(It st,It en,Ts&&...xs){write(st,en);writeDelimiter();write(std::forward<Ts>(xs)...);}
template<class T>typename std::enable_if<is_iterator<typename T::iterator>::value>::type write(const T&x){bool _first=1;for(auto&&_i:x){if(_first)_first=0;else writeDelimiter();write(_i);}}
template<class T,class...Ts>void write(const T&x,Ts&&...xs){write(x);writeDelimiter();write(std::forward<Ts>(xs)...);}
void writeln(){_putchar('\n');}template<class...Ts>void writeln(Ts&&...xs){write(std::forward<Ts>(xs)...);_putchar('\n');}
class IOManager{public:~IOManager(){flush();if(_tempInputBuf)delete[](_tempInputBuf);}};std::unique_ptr<IOManager>iomanager=make_unique<IOManager>();
void setOutput(FILE*file){flush();_output=file;}void setOutput(const char*s){flush();_output=fopen(s,"w");}void setOutput(const std::string&s){flush();_output=fopen(s.c_str(),"w");}
template<class...Ts>void debug(const Ts&...xs){FILE*_temp=_output;setOutput(_error);write(xs...);setOutput(_temp);}
template<class...Ts>void debugln(const Ts&...xs){FILE*_temp=_output;setOutput(_error);writeln(xs...);setOutput(_temp);}
void setError(FILE*file){flush();_error=file;}void setError(const char*s){flush();_error=fopen(s,"w");}void setError(const std::string&s){flush();_error=fopen(s.c_str(),"w");}

template <class T, const bool ONE_INDEXED, const int ...Args> struct FenwickTree {
    T val;
    void init() { val = 0; }
    void update(T v) { val += v; }
    T rsq() { return val; }
};

template <class T, const bool ONE_INDEXED, const int MAXN, const int ...Ns> struct FenwickTree <T, ONE_INDEXED, MAXN, Ns...> {
    FenwickTree<T, ONE_INDEXED, Ns...> BIT[MAXN];
    void init() { for (int i = 0; i < MAXN; i++) BIT[i].init(); }
    template <class ...Args> void update(int i, Args ...args) { for (i += !ONE_INDEXED; i < MAXN; i += i & -i) BIT[i].update(args...); }
    template <class ...Args> T rsq(int l, int r, Args ...args) {
        T ret = 0;
        for (r += !ONE_INDEXED; r > 0; r -= r & -r) ret += BIT[r].rsq(args...);
        for (l -= ONE_INDEXED; l > 0; l -= l & -l) ret -= BIT[l].rsq(args...);
        return ret;
    }
};

template <class Value, class CountType, class Comparator = less<Value>> struct SqrtBuffer {
    Comparator cmp; CountType tot; double SCALE_FACTOR; vector<pair<Value, CountType>> small, large;
    function<bool(const pair<Value, CountType>&, const pair<Value, CountType>&)> pairCmp =
        [&] (const pair<Value, CountType> &a, const pair<Value, CountType> &b) { return cmp(a.first, b.first); };
    SqrtBuffer(const double SCALE_FACTOR = 1) : tot(0), SCALE_FACTOR(SCALE_FACTOR) {}
    template <class PairIt> SqrtBuffer(const PairIt st, const PairIt en, const double SCALE_FACTOR = 1) :
            SCALE_FACTOR(SCALE_FACTOR), large(st, en) {
        assert(is_sorted(st, en, pairCmp)); resizeUnique(large); tot = 0; for (auto &&p : large) tot += p.second;
    }
    void resizeUnique(vector<pair<Value, CountType>> &v) {
        if (!v.empty()) {
            int j = 0;
            for (int i = 1; i < int(v.size()); i++) {
                if (cmp(v[i].first, v[j].first) || cmp(v[j].first, v[i].first)) {
                    v[++j] = v[i]; v[j].second += v[j - 1].second;
                } else v[j].second += v[i].second;
            }
            v.resize(j + 1);
        }
    }
    void rebuild() {
        if (int(small.size()) > SCALE_FACTOR * sqrt(small.size() + large.size())) {
            int largeSz = int(large.size()); sort(small.begin(), small.end(), pairCmp);
            for (int i = largeSz - 1; i >= 1; i--) large[i].second -= large[i - 1].second;
            for (auto &&p : small) large.push_back(p);
            small.clear(); inplace_merge(large.begin(), large.begin() + largeSz, large.end(), pairCmp); resizeUnique(large);
        }
    }
    void insert(const pair<Value, CountType> &p) { small.push_back(p); tot += p.second; }
    void emplace(const Value &v, const CountType &c) { small.emplace_back(v, c); tot += c; }
    CountType aboveInd(const Value &val) {
        rebuild(); int ind = upper_bound(large.begin(), large.end(), make_pair(val, CountType(0)), pairCmp) - large.begin();
        CountType ret = ind == 0 ? 0 : large[ind - 1].second;
        for (auto &&p : small) if (!cmp(val, p.first)) ret += p.second;
        return ret;
    }
    CountType ceilingInd(const Value &val) {
        rebuild(); int ind = lower_bound(large.begin(), large.end(), make_pair(val, CountType(0)), pairCmp) - large.begin();
        CountType ret = ind == 0 ? 0 : large[ind - 1].second;
        for (auto &&p : small) if (cmp(p.first, val)) ret += p.second;
        return ret;
    }
    CountType floorInd(const Value &val) { return aboveInd(val) - 1; }
    CountType belowInd(const Value &val) { return ceilingInd(val) - 1; }
    bool contains(const Value &val) {
        if (binary_search(large.begin(), large.end(), make_pair(val, CountType(0)), pairCmp)) return true;
        rebuild();
        if (binary_search(large.begin(), large.end(), make_pair(val, CountType(0)), pairCmp)) return true;
        for (auto &&p : small) if (!cmp(val, p.first) && !cmp(p.first, val)) return true;
        return false;
    }
    CountType count(const Value &val) { return aboveInd(val) - ceilingInd(val); }
    // number of values in the range [lo, hi]
    CountType count(const Value &lo, const Value &hi) { return aboveInd(hi) - ceilingInd(lo); }
    CountType count() const { return tot; } 
    void clear() { tot = 0; small.clear(); large.clear(); }
    vector<pair<Value, CountType>> valuesAndCount() const { // sorted
        vector<pair<Value, CountType>> ret;
        for (auto &&p : small) ret.push_back(p);
        int mid = int(ret.size());
        for (auto &&p : large) ret.push_back(p);
        inplace_merge(ret.begin(), ret.begin() + mid, ret.end(), pairCmp); resizeUnique(ret); return ret;
    }
};

template <class T, class IndexType, const int MAXN, const bool ONE_INDEXED, class Tree = SqrtBuffer<IndexType, T>> struct SemiSparseFenwickTree2DSqrt {
    Tree BIT[MAXN];
    void init(const double SCALE_FACTOR = 1) { for (int i = 0; i < MAXN; i++) BIT[i] = Tree(SCALE_FACTOR); }
    void clear() { for (int i = 0; i < MAXN; i++) BIT[i].clear(); }
    void update(int x, IndexType y, T v) { for (x += !ONE_INDEXED; x < MAXN; x += x & -x) BIT[x].emplace(y, v); }
    T rsq(int x, IndexType y) { T ret = 0; for (x += !ONE_INDEXED; x > 0; x -= x & -x) ret += BIT[x].aboveInd(y); return ret; }
    T rsq(int x, IndexType y1, IndexType y2) { T ret = 0; for (x += !ONE_INDEXED; x > 0; x -= x & -x) ret += BIT[x].count(y1, y2); return ret; }
    T rsq(int x1, IndexType y1, int x2, IndexType y2) { return rsq(x2, y1, y2) - rsq(x1 - 1, y1, y2); }
};

template <class T, class F> T getFirst(T lo, T hi, F f) {
    while (lo < hi) {
        T mid = lo + (hi - lo) / 2;
        if (f(mid)) hi = mid;
        else lo = mid + 1;
    }
    return lo;
}

template <class T, class F> T getLast(T lo, T hi, F f) {
    hi--;
    while (lo <= hi) {
        T mid = lo + (hi - lo) / 2;
        if (f(mid)) lo = mid + 1;
        else hi = mid - 1;
    }
    return hi;
}

const int MAXN = 3e5 + 5;

int N, Q;
bool cur[MAXN];
FenwickTree<int, 1, MAXN> ft1;
SemiSparseFenwickTree2DSqrt<int, int, MAXN, 1> ft2;

void update(int l1, int l2, int r1, int r2, int v) {
    ft2.update(l1, r1, v);
    ft2.update(l1, r2 + 1, -v);
    ft2.update(l2 + 1, r1, -v);
    ft2.update(l2 + 1, r2 + 1, v);
}

int main() {
    // setInput("in.txt");
    // setOutput("out.txt");
    // setError("err.txt");
    setLength(MAXN);
    ft1.init();
    ft2.init(8);
    string S;
    read(N, Q, S);
    for (int i = 1; i <= N; i++) {
        cur[i] = S[i - 1] == '1';
        if (cur[i]) ft1.update(i, 1);
    }
    for (int qi = 1; qi <= Q; qi++) {
        read(S);
        if (S == "toggle") {
            int i;
            read(i);
            int mul = cur[i] ? 1 : -1;
            if (!cur[i]) ft1.update(i, 1);
            int l1 = getFirst(1, i, [&] (int x) {
                return ft1.rsq(x, i) == i - x + 1;
            });
            int r2 = getLast(i, N + 1, [&] (int x) {
                return ft1.rsq(i, x) == x - i + 1;
            });
            if (cur[i]) ft1.update(i, -1);
            cur[i] = !cur[i];
            update(l1, i, i, r2, mul * qi);
        } else {
            int l, r;
            read(l, r);
            --r;
            int ans = ft2.rsq(l, r);
            if (ft1.rsq(l, r) == r - l + 1) ans += qi;
            writeln(ans);
        }
    }
    return 0;
}

Subtask #1

20.0 / 20.0

#	Verdict	Execution time	Memory	Grader output
1	Correct	34 ms	29688 KB	Output is correct
2	Correct	42 ms	29688 KB	Output is correct
3	Correct	36 ms	29816 KB	Output is correct
4	Correct	35 ms	29688 KB	Output is correct
5	Correct	35 ms	29688 KB	Output is correct
6	Correct	35 ms	29688 KB	Output is correct
7	Correct	35 ms	29688 KB	Output is correct

Subtask #2

20.0 / 20.0

#	Verdict	Execution time	Memory	Grader output
1	Correct	629 ms	89952 KB	Output is correct
2	Correct	707 ms	82928 KB	Output is correct
3	Correct	986 ms	74104 KB	Output is correct
4	Correct	2137 ms	80984 KB	Output is correct
5	Correct	1805 ms	70680 KB	Output is correct
6	Correct	1611 ms	163656 KB	Output is correct
7	Correct	286 ms	32564 KB	Output is correct
8	Correct	300 ms	33912 KB	Output is correct

Subtask #3

20.0 / 20.0

#	Verdict	Execution time	Memory	Grader output
1	Correct	39 ms	30200 KB	Output is correct
2	Correct	38 ms	30200 KB	Output is correct
3	Correct	38 ms	30072 KB	Output is correct
4	Correct	36 ms	29816 KB	Output is correct
5	Correct	2428 ms	132968 KB	Output is correct
6	Correct	2476 ms	96576 KB	Output is correct
7	Correct	1600 ms	70680 KB	Output is correct
8	Correct	287 ms	33904 KB	Output is correct
9	Correct	100 ms	31800 KB	Output is correct
10	Correct	106 ms	31608 KB	Output is correct
11	Correct	173 ms	31992 KB	Output is correct
12	Correct	285 ms	32632 KB	Output is correct
13	Correct	301 ms	33912 KB	Output is correct

Subtask #4

20.0 / 20.0

#	Verdict	Execution time	Memory	Grader output
1	Correct	36 ms	29688 KB	Output is correct
2	Correct	36 ms	29944 KB	Output is correct
3	Correct	38 ms	30220 KB	Output is correct
4	Correct	38 ms	30328 KB	Output is correct
5	Correct	405 ms	34372 KB	Output is correct
6	Correct	1144 ms	97328 KB	Output is correct
7	Correct	1605 ms	162132 KB	Output is correct
8	Correct	2208 ms	214996 KB	Output is correct
9	Correct	953 ms	193480 KB	Output is correct
10	Correct	1136 ms	225876 KB	Output is correct
11	Correct	967 ms	193112 KB	Output is correct
12	Correct	1236 ms	225684 KB	Output is correct
13	Correct	955 ms	191344 KB	Output is correct
14	Correct	1155 ms	226032 KB	Output is correct
15	Correct	301 ms	31496 KB	Output is correct
16	Correct	317 ms	33016 KB	Output is correct

Subtask #5

20.0 / 20.0

#	Verdict	Execution time	Memory	Grader output
1	Correct	34 ms	29688 KB	Output is correct
2	Correct	42 ms	29688 KB	Output is correct
3	Correct	36 ms	29816 KB	Output is correct
4	Correct	35 ms	29688 KB	Output is correct
5	Correct	35 ms	29688 KB	Output is correct
6	Correct	35 ms	29688 KB	Output is correct
7	Correct	35 ms	29688 KB	Output is correct
8	Correct	629 ms	89952 KB	Output is correct
9	Correct	707 ms	82928 KB	Output is correct
10	Correct	986 ms	74104 KB	Output is correct
11	Correct	2137 ms	80984 KB	Output is correct
12	Correct	1805 ms	70680 KB	Output is correct
13	Correct	1611 ms	163656 KB	Output is correct
14	Correct	286 ms	32564 KB	Output is correct
15	Correct	300 ms	33912 KB	Output is correct
16	Correct	39 ms	30200 KB	Output is correct
17	Correct	38 ms	30200 KB	Output is correct
18	Correct	38 ms	30072 KB	Output is correct
19	Correct	36 ms	29816 KB	Output is correct
20	Correct	2428 ms	132968 KB	Output is correct
21	Correct	2476 ms	96576 KB	Output is correct
22	Correct	1600 ms	70680 KB	Output is correct
23	Correct	287 ms	33904 KB	Output is correct
24	Correct	100 ms	31800 KB	Output is correct
25	Correct	106 ms	31608 KB	Output is correct
26	Correct	173 ms	31992 KB	Output is correct
27	Correct	285 ms	32632 KB	Output is correct
28	Correct	301 ms	33912 KB	Output is correct
29	Correct	36 ms	29688 KB	Output is correct
30	Correct	36 ms	29944 KB	Output is correct
31	Correct	38 ms	30220 KB	Output is correct
32	Correct	38 ms	30328 KB	Output is correct
33	Correct	405 ms	34372 KB	Output is correct
34	Correct	1144 ms	97328 KB	Output is correct
35	Correct	1605 ms	162132 KB	Output is correct
36	Correct	2208 ms	214996 KB	Output is correct
37	Correct	953 ms	193480 KB	Output is correct
38	Correct	1136 ms	225876 KB	Output is correct
39	Correct	967 ms	193112 KB	Output is correct
40	Correct	1236 ms	225684 KB	Output is correct
41	Correct	955 ms	191344 KB	Output is correct
42	Correct	1155 ms	226032 KB	Output is correct
43	Correct	301 ms	31496 KB	Output is correct
44	Correct	317 ms	33016 KB	Output is correct
45	Correct	401 ms	79516 KB	Output is correct
46	Correct	402 ms	68976 KB	Output is correct
47	Correct	965 ms	63304 KB	Output is correct
48	Correct	2138 ms	79260 KB	Output is correct
49	Correct	241 ms	30712 KB	Output is correct
50	Correct	106 ms	30712 KB	Output is correct
51	Correct	192 ms	30860 KB	Output is correct
52	Correct	106 ms	30712 KB	Output is correct
53	Correct	106 ms	30712 KB	Output is correct
54	Correct	107 ms	30768 KB	Output is correct