Submission #1010322

#TimeUsernameProblemLanguageResultExecution timeMemory
1010322asdfgracePalembang Bridges (APIO15_bridge)C++17
63 / 100
2058 ms4444 KiB
#include <bits/stdc++.h> using namespace std; #define dbg(x) x #define prt(x) dbg(cerr << x) #define pv(x) dbg(cerr << #x << " = " << x << '\n') #define pv2(x) dbg(cerr << #x << " = " << x.first << ',' << x.second << '\n') #define parr(x) dbg(prt(#x << " = { "); for (auto y : x) prt(y << ' '); prt("}\n");) #define parr2(x) dbg(prt(#x << " = { "); for (auto [y, z] : x) prt(y << ',' << z << " "); prt("}\n");) #define parr2d(x) dbg(prt(#x << ":\n"); for (auto arr : x) {parr(arr);} prt('\n')); #define parr2d2(x) dbg(prt(#x << ":\n"); for (auto arr : x) {parr2(arr);} prt('\n')); /* build 1 or 2 bridges add to baseline of sum of all distances driven without crossing bridge + n then only consider people crossing k=1: minimize the sum of all abs(s[i] - x) + abs(t[i] - x) one of the given locs is optimal so here treat all s[i] and t[i] the same, sort, etc. k=2: if l <= x or y <= r, dist = r - l else, dist = r - l + 2 * (dist btwn either end & closest bridge) assume x < y 5 cases 1) left of x 2) contains x 3) btwn x, y 4) contains y 5) right of y best y for each x? everything to left/containing x is handled (i.e. everything with l <= x) n^2 sol: for each lb consider the rb and update as we go maybe with set or smth probably maintain 3 sets or smth? like 1 set of things ending on the left of x or containing x these don't change everything else ends after x as y moves to the right sets of things that start after x 1) starts on the right of y/containing y --> automatically use y 2) x on left and y on right --> use y if r is closer to y tha x is to l can maintain 2 sets when y moves to the right of a segment that used to contain it (sort other set by rb and pop elems) move it to the "y closer" set probs for each elem binary search where you would update that and don't even maintain a set for case 2 */ int main() { ios::sync_with_stdio(0); cin.tie(0); int k, n; cin >> k >> n; vector<array<int, 2>> a; long long bsl = 0; for (int i = 0; i < n; i++) { char c1, c2; int i1, i2; cin >> c1 >> i1 >> c2 >> i2; if (c1 == c2) { bsl += abs(i2 - i1); } else { if (i2 < i1) swap(i1, i2); a.push_back({i1, i2}); bsl++; } } n = (int) a.size(); if (n == 0) { cout << bsl << '\n'; return 0; } vector<int> b; for (int i = 0; i < n; i++) { b.push_back(a[i][0]); b.push_back(a[i][1]); } sort(b.begin(), b.end()); if (k == 1) { long long sum = 0; for (int i = 0; i < 2 * n; i++) { sum += b[i] - b[0]; } long long best = sum; for (int i = 1; i < 2 * n; i++) { sum += (long long) i * (b[i] - b[i - 1]); sum -= (long long) (2 * n - i) * (b[i] - b[i - 1]); best = min(best, sum); } cout << best + bsl << '\n'; } else { long long best = 1e18; for (int x = 0; x < 2 * n - 1; x++) { long long sum = 0; int c = 0; vector<long long> dif(2 * n, 0); vector<int> cd(2 * n, 0); for (int i = 0; i < n; i++) { if (a[i][0] <= b[x]) { sum += abs(a[i][0] - b[x]) + abs(a[i][1] - b[x]); } else { sum += abs(a[i][0] - b[x]) + abs(a[i][1] - b[x]); c--; int i1 = lower_bound(b.begin(), b.end(), a[i][0]) - b.begin(); dif[i1] += (a[i][1] - a[i][0]) - (a[i][1] + a[i][0] - 2 * b[i1]); cd[i1]++; int i2 = lower_bound(b.begin(), b.end(), a[i][1]) - b.begin(); dif[i2] += (2 * b[i2] - (a[i][0] + a[i][1])) - (a[i][1] - a[i][0]); cd[i2]++; if (b[2 * n - 1] >= a[i][1] + (a[i][0] - b[x])) { int i3 = lower_bound(b.begin(), b.end(), a[i][1] + (a[i][0] - b[x])) - b.begin(); dif[i3] += ((a[i][0] + a[i][1]) - 2 * b[x]) - (2 * b[i3] - (a[i][0] + a[i][1])); cd[i3]--; } } } for (int y = x + 1; y < 2 * n; y++) { sum += 2ll * c * (b[y] - b[y - 1]); c += cd[y]; sum += dif[y]; best = min(best, bsl + sum); } } cout << best << '\n'; } } /* any observations help check every line IF YOUR LINES AREN'T WRONG CHECK IF YOUR LINES ARE IN THE RIGHT ORDER NEVER GIVE UP */
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