Details will be updated next week. I am a little busy now, so please do not downvote me. If you are interested or confused, you can comment or chat with me.
The idea is from official. This blog is about the implementation.
My submission: submission.
My code here:
#include<bits/stdc++.h>
using namespace std;
#define BIT(x, i) (((x) & (1 << (i))) >> (i))
#define DEBUG 0
#define DEBUG_INTERACTIVE 0
constexpr int C = 11, MAXN=2005; //Since N <= 2000, nim number <= 2000, so we only need to scan 1<<0 to 1<<11.
int n, l, r;
int sg[MAXN]; //sg number for 1-n
int f[MAXN][MAXN];
//f[i][j] If we want to get sg number j from [1, i], where should I cut?
//For example, if sg(i) = 4 and get sg number 3 after cutting [j, k], then f[i][3] = j;
int nim(const vector<int>& v, int* index, int* value_after_change){
//input:
//v: A vector of stones.
//index and value_after_change: If the XOR sum of v is 0, then index remains unchanged. we modify v[*index]
//to *value_after_change to guarantee that the XOR sum of v after modification is 0.
//Output:
//The XOR sum of v (current v)
//Example1:
//vector<int> v = {1, 4, 3};
//int index, value_after_change;
//int value = nim(v, &index, &value_after_change);
//cout << value << " " << index << " " << value_after_change << "\n"; //6 1 2
//value = 1^4^3 = 6;
//change 4->2, 1^2^3=0
//Example2:
//vector<int> v = {1, 2, 3};
//int index, value_after_change;
//int value = nim(v, &index, &value_after_change);
//cout << value << " " << index << " " << value_after_change << "\n"; //0 32763 -1204770170
//1^2^3 = 0. You cannot modify any number, then index and value_after_change are uninitialized random numbers (may not be 32763 -1204770170)
int sz = (int)v.size();
vector<int> ones[C+1];
int res = 0;
for(int b = 0; b <= C; ++b){
for(int i = 0; i < sz; ++i){
if(BIT(v[i], b)){
ones[b].push_back(i);
}
if(!b) res ^= v[i]; //Calculate the XOR sum, also known as the Nim sum. Remember only xor once.
}
}
if(res == 0) return res;
bool flipped = false;
*value_after_change = 0;
int choosed = -1; //FIX
for(int b = C; b >= 0; --b){
if(BIT(res, b)){
if(!flipped){
choosed = b;//FIX
flipped = true;
*index = ones[b][0]; //Never overflows, think out why?
}else{
*value_after_change += ((!BIT(v[*index], b)) << b);
}
}else if(flipped){
(*value_after_change) += (v[*index] & (1 << b));
}
}
for(int i = choosed+1; i <= C; ++i){ //FIX
*value_after_change += (v[*index] & (1<<i)); //FIX
} //FIX
return res;
}
void sgdp(bool debug){ //dynamic programming to calculate sprague-grundy numbers
//The following code is unnecessary because sg is global variable.
//for(int i = 0; i <= l-1; ++i){
// sg[i] = 0; //Nowhere to fetch, have to lose, sg number is 0.
//}
for(int len = l; len <= n; ++len){
set<int> mex;
for(int i = 1; i <= len-l+1; ++i){
//We fetch [i, i+l-1]
int sgleft = sg[i-1]; //sg[0] is defined
int sgright = sg[len-i-l+1];
int sgall = sgleft ^ sgright; //Grundy theorem!!!
f[len][sgall] = i;
mex.insert(sgall);
}
int t = 0;
while(mex.count(t)) ++t;
sg[len] = t;
}
//DEBUG
if(!debug) return;
for(int len = l; len <= n; ++len){
printf("sg[%d]==%d\n", len, sg[len]);
for(int k = 0; k < sg[len]; ++k){
printf("f[%d][%d]==%d\n", len, k, f[len][k]);
}
printf("\n");
}
}
int main(int argc, char** argv){
if(DEBUG){
//freopen(argc == 1?"test1.txt":argv[1], "r", stdin);
}else if(DEBUG_INTERACTIVE){
; //DO NOTHING
}else{
cin.tie(0) -> sync_with_stdio(0);
}
cin >> n >> l >> r;
//The first case: r is large enough:
//Prefix (length <= l-1), Middle (length==r), Appendix (length <= l-1)
int a = 1, b = 1; //Ready to receive moves from the AI.
if(r + 2 * l - 2 >= n && l + r - 1 <= n){
//Killer move
cout << "First" << endl;
cout << l << " " << r << endl;
cin >> a >> b;
//AI fails.
return 0;
}
//The second case: Mimicking
if(l != r || n % 2 == l % 2){
//According to the tutorial, we can use the first move to separate [1-n] into two symmetric parts.
int tmp = r;
while((n - tmp) % 2) --tmp; //Don't be scary, it is O(1).
//Such tmp is always valid. If l != r, one of {r-1, r} is ok. Otherwise if l==r, r is eligible for tmp.
int interval = (n - tmp)/2;
cout << "First" << endl;
cout << interval+1 << " " << tmp << endl;
//Here we cut the interval [1, n] into two parts: [1, interval], [interval+tmp+1, n]
//interval == n-interval-tmp.
while(a || b){
cin >> a >> b;
if(a == 0 && b == 0){
return 0;
}
if(a <= interval){
//cout << a+interval+tmp << " " << b+interval+tmp << endl; //BUG. The second parameter is the LENGTH, not the ENDING POINT.
cout << a+interval+tmp << " " << b << endl;
}else{
//cout << a-interval-tmp << " " << b-interval-tmp << endl; //BUG. The second parameter is the LENGTH, not the ENDING POINT.
cout << a-interval-tmp << " " << b << endl;
}
}
return 0;
}
//The third case: l == r && n % 2 != l % 2. We cannot mimick. No matter where we choose [x, x+y-1], We cannot separate [1, n]
sgdp(DEBUG || DEBUG_INTERACTIVE);
set<pair<int, int>> intervals = {{1, n}};
bool turn = true, initial = true;
if(sg[n] == 0) {
cout << "Second" << endl;
turn = false;
}else{
cout << "First" << endl;
}
while(a || b){
if(turn){
if(!initial){
//Use {a, a+b-1} to separate intervals
pair<int, int> ab = {a, a+b-1};
auto it = intervals.upper_bound(ab);
if(it==intervals.end() || it->first > ab.first) it = prev(it);//Always valid
int fi = it->first, se = it->second;
if(DEBUG || DEBUG_INTERACTIVE) {
for(auto pa: intervals){
cout << "[Intervals1]" << pa.first << " " << pa.second << "\n";
}
printf("DEBUG1: it=={%d, %d}, ab=={%d, %d}\n", fi, se, ab.first, ab.second);
}
if(ab.first-1 >= it->first){
intervals.insert({it->first, ab.first-1});
}
if(ab.second+1 <= it->second){
intervals.insert({ab.second+1, it->second});
}
intervals.erase({fi, se});
}
int isz = (int)intervals.size();
vector<int> v(isz);
vector<pair<int, int>> vp(intervals.begin(), intervals.end()); //This is bad, but convenient...
if(DEBUG || DEBUG_INTERACTIVE) {
for(int i = 0; i < isz; ++i) {
printf("DEBUG_PLACE1 <SG should NOT be 0>: vp[%d]=={%d, %d}, gr==%d\n", i, vp[i].first, vp[i].second, sg[vp[i].second - vp[i].first + 1]);
}
}
for(int i = 0; i < isz; ++i){
v[i] = sg[vp[i].second - vp[i].first + 1];
}
int index = -1, value_after_change = -1;
nim(v, &index, &value_after_change); //I will never make nim(v, &index, &value_after_change)==0 here!
int cutplace = f[vp[index].second - vp[index].first + 1][value_after_change];
if(DEBUG || DEBUG_INTERACTIVE) {
for(int i = 0; i < isz; ++i) printf("v[%d]==%d, index==%d, value_after_change==%d\n", i, v[i], index, value_after_change);
cout << vp[index].first + cutplace - 1 << " " << l << " AI" << endl;
}
else cout << vp[index].first + cutplace - 1 << " " << l << endl;
//Also remember to separate intervals!
pair<int, int> ab = {vp[index].first + cutplace - 1, vp[index].first + cutplace + l - 2};
auto it = intervals.upper_bound(ab); //Always valid
if(it==intervals.end() || it->first > ab.first) it = prev(it);
int fi = it->first, se = it->second;
if(DEBUG || DEBUG_INTERACTIVE) {
for(auto pa: intervals){
cout << "[Intervals2]" << pa.first << " " << pa.second << "\n";
}
printf("DEBUG2: it=={%d, %d}, ab=={%d, %d}\n", fi, se, ab.first, ab.second);
}
if(ab.first-1 >= it->first){
intervals.insert({it->first, ab.first-1});
}
if(ab.second+1 <= it->second){
intervals.insert({ab.second+1, it->second});
}
intervals.erase({fi, se});
if(DEBUG || DEBUG_INTERACTIVE) {
int i = 0;
for(pair<int, int> pa: intervals) {
printf("DEBUG_PLACE2 <SG should be 0>: i==%d, {%d, %d}, sg==%d\n", i, pa.first, pa.second, sg[pa.second-pa.first+1]);
++i;
}
}
}else{
cin >> a >> b;
}
turn = !turn;
initial = false;
}
if(a == -1 && b == -1) return 0;
}
Acknowledgment: ABalobanov, Nyaan.
