#include "plants.h"
#include <bits/stdc++.h>
#include <type_traits>
using namespace std;
/*
* Si h[i] < h[i+1], alors r[i+1] <= r[i]
* Si h[i] > h[i+1] alors r[i+1] >= r[i]
* Donc si on a r[i] != r[i+1] on peut comparer r[i] et r[i+1] !
* r[i+1] > r[i] => h[i+1] < h[i]
* r[i+1] < r[i] => h[i+1] > h[i]
* 1 : AC
* 2 : AC
* 3 : AC
* 4 : AC
* 5 : AC
* 6 : NA
* 7 : NA
*
* If can build graph efficiently then ez !
*/
const int MAXN = 2e5;
int k;
int nbPlusGrands[MAXN], cntEq[MAXN][2];
vector<int> adj[MAXN];
int ordre[MAXN];
int nbDevant[MAXN];
bool reach[301][301];
set<int> alwaysSmaller, alwaysBigger;
int nbPlantes;
struct Seg {
int nbValeurs;
vector<int> order;
vector<int> valeurs;
vector<int> iDeb, iFin, lazy, minVal;
const int INF = 1e9;
Seg(vector<int> _v) : nbValeurs(_v.size()), valeurs(_v) {
int p = 0;
while ((1 << p) < nbValeurs)
++p;
int x = 2 * (1 << p) + 1;
iDeb.resize(x), iFin.resize(x), lazy.resize(x), minVal.resize(x);
buildTree(1, 0, nbValeurs - 1);
}
void pull(int iNoeud) {
minVal[iNoeud] = min(minVal[2 * iNoeud], minVal[2 * iNoeud + 1]);
}
void push(int iNoeud) {
if (!lazy[iNoeud])
return;
minVal[iNoeud] += lazy[iNoeud];
if (iDeb[iNoeud] < iFin[iNoeud]) {
lazy[2 * iNoeud] += lazy[iNoeud];
lazy[2 * iNoeud + 1] += lazy[iNoeud];
}
lazy[iNoeud] = 0;
}
void buildTree(int iNoeud, int deb, int fin) {
iDeb[iNoeud] = deb, iFin[iNoeud] = fin;
if (deb == fin) {
minVal[iNoeud] = valeurs[deb];
return;
}
buildTree(2 * iNoeud, deb, (deb + fin) / 2);
buildTree(2 * iNoeud + 1, (deb + fin) / 2 + 1, fin);
pull(iNoeud);
}
int queryMin(int iNoeud, int deb, int fin) {
push(iNoeud);
if (deb > iFin[iNoeud] or fin < iDeb[iNoeud])
return 2 * INF;
if (iDeb[iNoeud] >= deb and iFin[iNoeud] <= fin)
return minVal[iNoeud];
return min(queryMin(2 * iNoeud, deb, fin),
queryMin(2 * iNoeud + 1, deb, fin));
}
void decrement(int iNoeud, int deb, int fin) {
push(iNoeud);
if (deb > iFin[iNoeud] or fin < iDeb[iNoeud])
return;
if (deb <= iDeb[iNoeud] and iFin[iNoeud] <= fin) {
lazy[iNoeud]--;
push(iNoeud);
return;
}
decrement(2 * iNoeud, deb, fin);
decrement(1 + 2 * iNoeud, deb, fin);
pull(iNoeud);
}
int findFirstZero(int iNoeud, int deb, int fin) {
push(iNoeud);
if (minVal[iNoeud] or iDeb[iNoeud] > fin or iFin[iNoeud] < deb)
return -1;
if (iDeb[iNoeud] == iFin[iNoeud])
return iDeb[iNoeud];
int retLft = findFirstZero(2 * iNoeud, deb, fin);
if (retLft != -1)
return retLft;
return findFirstZero(2 * iNoeud + 1, deb, fin);
}
void delVal(int iNoeud, int pos) {
push(iNoeud);
if (iDeb[iNoeud] > pos or iFin[iNoeud] < pos)
return;
if (iDeb[iNoeud] == iFin[iNoeud]) {
minVal[iNoeud] = INF;
return;
}
delVal(2 * iNoeud, pos);
delVal(2 * iNoeud + 1, pos);
pull(iNoeud);
}
int findZeroBefore(int pos) {
int posAvant = pos - k + 1;
if (posAvant >= 0)
return findFirstZero(1, posAvant, pos - 1);
else {
posAvant += nbValeurs;
int ret = findFirstZero(1, posAvant, nbValeurs - 1);
if (ret == -1 and pos)
ret = findFirstZero(1, 0, pos - 1);
return ret;
}
}
void get(int pos) {
// cout << "EXTRACTING " << pos << endl;
while (true) {
int x = findZeroBefore(pos);
if (x == -1)
break;
get(x);
}
order.push_back(pos);
int posAvant = pos - k + 1;
delVal(1, pos);
if (pos)
decrement(1, max(0, posAvant), pos - 1);
if (posAvant < 0)
decrement(1, posAvant + nbValeurs, nbValeurs - 1);
// cout << "EXTRACTED " << pos << endl;
}
void getNxt() {
/*cout << "FINDING NEXT : " << endl;
for (int i = 0; i < nbValeurs; ++i)
cout << queryMin(1, i, i) << ' ';
cout << endl;*/
int posZero = findFirstZero(1, 0, nbValeurs - 1);
assert(posZero != -1);
get(posZero);
}
};
int disCircle(int x, int y) {
if (x < y)
return y - x;
return nbPlantes - x + y;
}
void init(int _k, vector<int> r) {
k = _k;
nbPlantes = r.size();
for (int iPlante = 0; iPlante < nbPlantes; ++iPlante) {
nbPlusGrands[iPlante] = r[iPlante];
}
Seg segMax(r);
while ((int)segMax.order.size() < nbPlantes)
segMax.getNxt();
for (int i = 0; i < nbPlantes; ++i)
r[i] = k - 1 - r[i];
Seg segMin(r);
while ((int)segMin.order.size() < nbPlantes)
segMin.getNxt();
for (int i = 0; i < nbPlantes and segMax.order[i]; ++i)
alwaysBigger.insert(segMax.order[i]);
for (int i = 0; i < nbPlantes and segMin.order[i]; ++i)
alwaysSmaller.insert(segMin.order[i]);
/*if (k == 2) {
for (int i = nbPlantes - 1; i >= 0; --i) {
if (i == nbPlantes - 1) {
int x = 1;
while (x < nbPlantes and nbPlusGrands[x - 1] == nbPlusGrands[i])
x++;
cntEq[i][nbPlusGrands[i]] = x;
} else {
cntEq[i][nbPlusGrands[i]] = 1 + cntEq[i + 1][nbPlusGrands[i]];
}
}
} else {
Seg seg(r);
while ((int)seg.order.size() < nbPlantes)
seg.getNxt();
for (int i = 0; i < nbPlantes; ++i)
ordre[seg.order[i]] = nbPlantes - 1 - i;
}*/
}
int compare_plants(int x, int y) {
if (alwaysBigger.count(y))
return -1;
if (alwaysSmaller.count(y))
return 1;
return 0;
if (k == 2) {
bool allSame1[2] = {true, true};
bool allSame2[2] = {true, true};
int dis1 = disCircle(x, y);
int dis2 = disCircle(y, x);
for (int b = 0; b < 2; ++b) {
allSame1[b] = cntEq[x][b] >= dis1;
allSame2[b] = cntEq[y][b] >= dis2;
}
if (allSame1[0] or allSame2[1])
return 1;
else if (allSame1[1] or allSame2[0])
return -1;
return 0;
} else
return (ordre[x] < ordre[y] ? -1 : 1);
}
| # |
Verdict |
Execution time |
Memory |
Grader output |
| 1 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 2 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 3 |
Incorrect |
3 ms |
4940 KB |
Output isn't correct |
| 4 |
Halted |
0 ms |
0 KB |
- |
| # |
Verdict |
Execution time |
Memory |
Grader output |
| 1 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 2 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 3 |
Incorrect |
3 ms |
4940 KB |
Output isn't correct |
| 4 |
Halted |
0 ms |
0 KB |
- |
| # |
Verdict |
Execution time |
Memory |
Grader output |
| 1 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 2 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 3 |
Incorrect |
3 ms |
4940 KB |
Output isn't correct |
| 4 |
Halted |
0 ms |
0 KB |
- |
| # |
Verdict |
Execution time |
Memory |
Grader output |
| 1 |
Incorrect |
3 ms |
4940 KB |
Output isn't correct |
| 2 |
Halted |
0 ms |
0 KB |
- |
| # |
Verdict |
Execution time |
Memory |
Grader output |
| 1 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 2 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 3 |
Incorrect |
3 ms |
4940 KB |
Output isn't correct |
| 4 |
Halted |
0 ms |
0 KB |
- |
| # |
Verdict |
Execution time |
Memory |
Grader output |
| 1 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 2 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 3 |
Correct |
3 ms |
4968 KB |
Output is correct |
| 4 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 5 |
Correct |
5 ms |
5068 KB |
Output is correct |
| 6 |
Correct |
598 ms |
32728 KB |
Output is correct |
| 7 |
Correct |
980 ms |
39348 KB |
Output is correct |
| 8 |
Correct |
1136 ms |
41308 KB |
Output is correct |
| 9 |
Correct |
1262 ms |
41400 KB |
Output is correct |
| 10 |
Correct |
520 ms |
32832 KB |
Output is correct |
| 11 |
Correct |
892 ms |
41072 KB |
Output is correct |
| 12 |
Correct |
619 ms |
39472 KB |
Output is correct |
| 13 |
Correct |
623 ms |
33460 KB |
Output is correct |
| 14 |
Correct |
977 ms |
40208 KB |
Output is correct |
| 15 |
Correct |
1113 ms |
41268 KB |
Output is correct |
| 16 |
Correct |
597 ms |
39188 KB |
Output is correct |
| 17 |
Correct |
590 ms |
34176 KB |
Output is correct |
| # |
Verdict |
Execution time |
Memory |
Grader output |
| 1 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 2 |
Correct |
3 ms |
4940 KB |
Output is correct |
| 3 |
Incorrect |
3 ms |
4940 KB |
Output isn't correct |
| 4 |
Halted |
0 ms |
0 KB |
- |
