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using namespace std;
static const long long M_CAP = 20000000LL; // mg
static const long long L_CAP = 25000000LL; // uL
struct Item {
string name;
long long q, v, m, l;
int idx;
};
struct Parser {
string s;
size_t i=0;
Parser(const string& str): s(str), i(0) {}
void skip() {
while (i < s.size() && (s[i]==' ' || s[i]=='\n' || s[i]=='\r' || s[i]=='\t')) i++;
}
bool peek(char c) {
skip();
return i < s.size() && s[i]==c;
}
void expect(char c) {
skip();
if (i>=s.size() || s[i]!=c) {
// try to recover
} else {
i++;
}
}
string parseString() {
skip();
string out;
if (i < s.size() && s[i]=='"') {
i++;
while (i < s.size()) {
char c = s[i++];
if (c=='\\') {
if (i < s.size()) {
char nxt = s[i++];
// For simplicity, just append the escaped char
out.push_back(nxt);
}
} else if (c=='"') {
break;
} else {
out.push_back(c);
}
}
}
return out;
}
long long parseNumber() {
skip();
bool neg=false;
if (i<s.size() && s[i]=='-') { neg=true; i++; }
long long x=0;
while (i < s.size() && s[i]>='0' && s[i]<='9') {
x = x*10 + (s[i]-'0');
i++;
}
return neg? -x : x;
}
};
struct Solution {
vector<long long> cnt;
long long val=0;
long long m_used=0;
long long l_used=0;
};
int main() {
ios::sync_with_stdio(false);
cin.tie(nullptr);
// Read entire input
std::string input, line;
{
std::ostringstream oss;
oss << cin.rdbuf();
input = oss.str();
}
// Parse JSON
Parser p(input);
vector<Item> items;
p.expect('{');
int idx = 0;
while (true) {
p.skip();
if (p.peek('}')) { p.expect('}'); break; }
string key = p.parseString();
p.expect(':');
p.expect('[');
vector<long long> arr;
while (true) {
long long num = p.parseNumber();
arr.push_back(num);
p.skip();
if (p.peek(',')) { p.expect(','); p.skip(); if (p.peek(']')) { p.expect(']'); break; } }
else if (p.peek(']')) { p.expect(']'); break; }
else {
// keep parsing
}
}
Item it;
it.name = key;
if (arr.size() >= 4) {
it.q = arr[0];
it.v = arr[1];
it.m = arr[2];
it.l = arr[3];
} else {
it.q = 0; it.v=0; it.m=1; it.l=1;
}
it.idx = idx++;
items.push_back(it);
p.skip();
if (p.peek(',')) { p.expect(','); continue; }
else if (p.peek('}')) { p.expect('}'); break; }
else {
// continue
}
}
int n = (int)items.size();
if (n == 0) {
cout << "{}\n";
return 0;
}
// Precompute upper bound per item (can't exceed q, M/m, L/l)
vector<long long> r(n, 0);
for (int i=0;i<n;i++) {
if (items[i].m > 0 && items[i].l > 0 && items[i].v > 0) {
long long byM = items[i].m > 0 ? (M_CAP / items[i].m) : (long long)1e18;
long long byL = items[i].l > 0 ? (L_CAP / items[i].l) : (long long)1e18;
long long rr = min(items[i].q, min(byM, byL));
r[i] = max(0LL, rr);
} else {
r[i] = 0;
}
}
// Precompute normalized mass and volume
vector<double> nm(n), nl(n);
for (int i=0;i<n;i++) {
nm[i] = (double)items[i].m / (double)M_CAP;
nl[i] = (double)items[i].l / (double)L_CAP;
}
auto now = [](){ return chrono::high_resolution_clock::now(); };
auto start = now();
auto elapsed_ms = [&](double limit_ms){
auto t = now();
double ms = chrono::duration<double, std::milli>(t - start).count();
return ms;
};
// Greedy build function
struct WeightSpec { int type; double a,b; };
auto greedy_build = [&](const WeightSpec& ws)->Solution {
vector<int> order(n);
iota(order.begin(), order.end(), 0);
vector<double> dens(n, 0.0);
for (int i=0;i<n;i++) {
if (r[i] <= 0) { dens[i] = -1e300; continue; }
if (ws.type == 0) {
double denom = ws.a * (double)items[i].m + ws.b * (double)items[i].l;
if (denom <= 0) denom = 1e-18;
dens[i] = (double)items[i].v / denom;
} else if (ws.type == 1) {
double denom = max(nm[i], nl[i]);
if (denom <= 0) denom = 1e-18;
dens[i] = (double)items[i].v / denom;
} else if (ws.type == 2) {
double denom = hypot(nm[i], nl[i]);
if (denom <= 0) denom = 1e-18;
dens[i] = (double)items[i].v / denom;
} else if (ws.type == 3) {
dens[i] = (double)items[i].v;
} else {
double denom = ws.a * (double)items[i].m + ws.b * (double)items[i].l;
if (denom <= 0) denom = 1e-18;
dens[i] = (double)items[i].v / denom;
}
}
stable_sort(order.begin(), order.end(), [&](int i, int j){
if (dens[i] != dens[j]) return dens[i] > dens[j];
if (items[i].v != items[j].v) return items[i].v > items[j].v;
double wi = (ws.a * (double)items[i].m + ws.b * (double)items[i].l);
double wj = (ws.a * (double)items[j].m + ws.b * (double)items[j].l);
return wi < wj;
});
Solution sol;
sol.cnt.assign(n, 0);
long long Mm = M_CAP, Ll = L_CAP;
long long val = 0;
for (int idxi : order) {
if (r[idxi] <= 0) continue;
long long can_by_M = items[idxi].m > 0 ? (Mm / items[idxi].m) : 0;
long long can_by_L = items[idxi].l > 0 ? (Ll / items[idxi].l) : 0;
long long can = min(r[idxi], min(can_by_M, can_by_L));
if (can <= 0) continue;
sol.cnt[idxi] += can;
val += can * items[idxi].v;
Mm -= can * items[idxi].m;
Ll -= can * items[idxi].l;
if (Mm <= 0 || Ll <= 0) break;
}
sol.val = val;
sol.m_used = M_CAP - Mm;
sol.l_used = L_CAP - Ll;
return sol;
};
// Improvement heuristic
auto improve = [&](Solution& sol, const WeightSpec& ws, double time_ms_budget){
// Precompute removal order by lowest density under ws
vector<double> remDensity(n, 0.0);
for (int i=0;i<n;i++) {
if (ws.type == 0) {
double denom = ws.a * (double)items[i].m + ws.b * (double)items[i].l;
if (denom <= 0) denom = 1e-18;
remDensity[i] = (double)items[i].v / denom;
} else if (ws.type == 1) {
double denom = max(nm[i], nl[i]);
if (denom <= 0) denom = 1e-18;
remDensity[i] = (double)items[i].v / denom;
} else if (ws.type == 2) {
double denom = hypot(nm[i], nl[i]);
if (denom <= 0) denom = 1e-18;
remDensity[i] = (double)items[i].v / denom;
} else if (ws.type == 3) {
// For removals under type 3 (value only), define density as value per normalized combined weight
double denom = (double)items[i].m / (double)M_CAP + (double)items[i].l / (double)L_CAP;
if (denom <= 0) denom = 1e-18;
remDensity[i] = (double)items[i].v / denom;
} else {
double denom = ws.a * (double)items[i].m + ws.b * (double)items[i].l;
if (denom <= 0) denom = 1e-18;
remDensity[i] = (double)items[i].v / denom;
}
}
vector<int> remOrder(n);
iota(remOrder.begin(), remOrder.end(), 0);
stable_sort(remOrder.begin(), remOrder.end(), [&](int i, int j){
if (remDensity[i] != remDensity[j]) return remDensity[i] < remDensity[j];
return items[i].v < items[j].v;
});
vector<int> addOrder(n);
iota(addOrder.begin(), addOrder.end(), 0);
stable_sort(addOrder.begin(), addOrder.end(), [&](int i, int j){
if (items[i].v != items[j].v) return items[i].v > items[j].v;
double di = nm[i] + nl[i];
double dj = nm[j] + nl[j];
return di < dj;
});
long long Mm = M_CAP - sol.m_used;
long long Ll = L_CAP - sol.l_used;
long long curVal = sol.val;
auto time_ok = [&](){
return elapsed_ms(0) < time_ms_budget;
};
bool improved_any = true;
int outer_iters = 0;
while (improved_any && time_ok()) {
improved_any = false;
outer_iters++;
if (outer_iters > 100) break;
for (int j_idx = 0; j_idx < n && time_ok(); j_idx++) {
int j = addOrder[j_idx];
if (r[j] <= 0) continue;
if (sol.cnt[j] >= r[j]) continue;
// Try to add as many as fits directly
if (Mm >= items[j].m && Ll >= items[j].l) {
long long can_by_M = items[j].m > 0 ? (Mm / items[j].m) : 0;
long long can_by_L = items[j].l > 0 ? (Ll / items[j].l) : 0;
long long quota = r[j] - sol.cnt[j];
long long take = min(quota, min(can_by_M, can_by_L));
if (take > 0) {
sol.cnt[j] += take;
Mm -= take * items[j].m;
Ll -= take * items[j].l;
curVal += take * items[j].v;
improved_any = true;
}
}
// Attempt single-item addition by removing low-density items
bool changed = true;
int inner_added = 0;
while (changed && time_ok()) {
changed = false;
if (sol.cnt[j] >= r[j]) break;
if (Mm >= items[j].m && Ll >= items[j].l) {
sol.cnt[j] += 1;
Mm -= items[j].m;
Ll -= items[j].l;
curVal += items[j].v;
improved_any = true;
changed = true;
inner_added++;
if (inner_added > 64) break; // prevent long loops on single item
continue;
}
long long needM = (items[j].m > Mm) ? (items[j].m - Mm) : 0LL;
long long needL = (items[j].l > Ll) ? (items[j].l - Ll) : 0LL;
if (needM == 0 && needL == 0) continue;
long long freedM = 0, freedL = 0;
long long removedVal = 0;
vector<long long> removedCnt(n, 0);
for (int i_idx = 0; i_idx < n; i_idx++) {
int i2 = remOrder[i_idx];
if (i2 == j) continue;
long long have = sol.cnt[i2];
if (have <= 0) continue;
long long reqM = 0, reqL = 0;
if (needM > freedM) reqM = (needM - freedM + items[i2].m - 1) / items[i2].m;
if (needL > freedL) reqL = (needL - freedL + items[i2].l - 1) / items[i2].l;
long long need = max(reqM, reqL);
if (need <= 0) continue;
long long maxByValue = LLONG_MAX;
if (items[i2].v > 0) {
if (removedVal < items[j].v) {
long long cap = (items[j].v - 1 - removedVal) / items[i2].v;
if (cap < 0) cap = 0;
maxByValue = cap;
} else {
maxByValue = 0;
}
}
long long take = min(have, need);
take = min(take, maxByValue);
if (take <= 0) continue;
removedCnt[i2] += take;
freedM += take * items[i2].m;
freedL += take * items[i2].l;
removedVal += take * items[i2].v;
if ((Mm + freedM) >= items[j].m && (Ll + freedL) >= items[j].l) break;
}
if ((Mm + freedM) >= items[j].m && (Ll + freedL) >= items[j].l && removedVal < items[j].v) {
// Commit removals
for (int k=0;k<n;k++) {
if (removedCnt[k] > 0) {
sol.cnt[k] -= removedCnt[k];
}
}
Mm += freedM;
Ll += freedL;
curVal -= removedVal;
// Add one j
sol.cnt[j] += 1;
Mm -= items[j].m;
Ll -= items[j].l;
curVal += items[j].v;
improved_any = true;
changed = true;
inner_added++;
if (inner_added > 64) break;
} else {
// Can't improve by adding j via removal
break;
}
}
}
}
sol.val = curVal;
sol.m_used = M_CAP - Mm;
sol.l_used = L_CAP - Ll;
// Final greedy fill of any leftover capacity with low-value items just to fill
// Try to add anything that fits by density (high to low)
vector<int> fillOrder(n);
iota(fillOrder.begin(), fillOrder.end(), 0);
vector<double> densFill(n, 0.0);
for (int i=0;i<n;i++) {
double denom = (double)items[i].m / (double)M_CAP + (double)items[i].l / (double)L_CAP;
if (denom <= 0) denom = 1e-18;
densFill[i] = (double)items[i].v / denom;
}
stable_sort(fillOrder.begin(), fillOrder.end(), [&](int a, int b){
if (densFill[a] != densFill[b]) return densFill[a] > densFill[b];
return items[a].v > items[b].v;
});
long long Mm2 = M_CAP - sol.m_used;
long long Ll2 = L_CAP - sol.l_used;
for (int iidx : fillOrder) {
if (!time_ok()) break;
long long quota = r[iidx] - sol.cnt[iidx];
if (quota <= 0) continue;
long long can_by_M = items[iidx].m > 0 ? (Mm2 / items[iidx].m) : 0;
long long can_by_L = items[iidx].l > 0 ? (Ll2 / items[iidx].l) : 0;
long long take = min(quota, min(can_by_M, can_by_L));
if (take > 0) {
sol.cnt[iidx] += take;
sol.val += take * items[iidx].v;
Mm2 -= take * items[iidx].m;
Ll2 -= take * items[iidx].l;
}
}
sol.m_used = M_CAP - Mm2;
sol.l_used = L_CAP - Ll2;
};
// Prepare weight specs
vector<WeightSpec> weights;
// Linear combinations over t in [0,1]
const int T1 = 10;
for (int k=0;k<=T1;k++) {
double t = (double)k / (double)T1;
WeightSpec ws{0, t / (double)M_CAP, (1.0 - t) / (double)L_CAP};
weights.push_back(ws);
}
for (int k=0;k<=9;k++) {
double t = 0.05 + 0.1 * k;
WeightSpec ws{0, t / (double)M_CAP, (1.0 - t) / (double)L_CAP};
weights.push_back(ws);
}
// Some biased weights
vector<double> gammas = {0.25, 0.5, 1.0, 2.0, 4.0};
for (double g : gammas) {
WeightSpec ws{0, 1.0/(double)M_CAP, g/(double)L_CAP};
weights.push_back(ws);
}
// Special measures
weights.push_back(WeightSpec{1, 0.0, 0.0}); // max(nm, nl)
weights.push_back(WeightSpec{2, 0.0, 0.0}); // L2 norm
weights.push_back(WeightSpec{3, 0.0, 0.0}); // pure value
// Initialize best solution as empty
Solution best;
best.cnt.assign(n, 0);
best.val = 0;
best.m_used = 0;
best.l_used = 0;
double time_budget_ms = 950.0; // Slightly less than 1s
// Try all weight specs with improvements within time budget
for (size_t wi = 0; wi < weights.size(); wi++) {
if (elapsed_ms(0) > time_budget_ms) break;
Solution sol = greedy_build(weights[wi]);
if (elapsed_ms(0) > time_budget_ms) {
if (sol.val > best.val) best = sol;
break;
}
// Improvement with limited time slice
double remaining = time_budget_ms - elapsed_ms(0);
double alloc = max(10.0, remaining / (double)(weights.size() - wi + 1));
improve(sol, weights[wi], elapsed_ms(0) + alloc);
if (sol.val > best.val) best = sol;
}
// Safety: ensure feasibility
long long total_m = 0, total_l = 0;
for (int i=0;i<n;i++) {
best.cnt[i] = min(best.cnt[i], r[i]);
if (best.cnt[i] < 0) best.cnt[i] = 0;
total_m += best.cnt[i] * items[i].m;
total_l += best.cnt[i] * items[i].l;
}
if (total_m > M_CAP || total_l > L_CAP) {
// Trim greedily lowest density until feasible
vector<int> order(n);
iota(order.begin(), order.end(), 0);
vector<double> dens(n);
for (int i=0;i<n;i++) {
double denom = (double)items[i].m / (double)M_CAP + (double)items[i].l / (double)L_CAP;
if (denom <= 0) denom = 1e-18;
dens[i] = (double)items[i].v / denom;
}
stable_sort(order.begin(), order.end(), [&](int a, int b){
if (dens[a] != dens[b]) return dens[a] < dens[b];
return items[a].v < items[b].v;
});
for (int idxi : order) {
while ((total_m > M_CAP || total_l > L_CAP) && best.cnt[idxi] > 0) {
best.cnt[idxi]--;
total_m -= items[idxi].m;
total_l -= items[idxi].l;
}
if (total_m <= M_CAP && total_l <= L_CAP) break;
}
}
// Output JSON with same keys/order as input
cout << "{\n";
for (int i=0;i<n;i++) {
cout << " \"" << items[i].name << "\": " << best.cnt[i];
if (i+1<n) cout << ",\n";
else cout << "\n";
}
cout << "}\n";
return 0;
} |