Datasets:

hackercupai
/

hackercup

	// Evening of the Living Dead
	// Solution by Jacob Plachta

	#define DEBUG 0

	#include <algorithm>
	#include <functional>
	#include <numeric>
	#include <iostream>
	#include <iomanip>
	#include <cstdio>
	#include <cmath>
	#include <complex>
	#include <cstdlib>
	#include <ctime>
	#include <cstring>
	#include <cassert>
	#include <string>
	#include <vector>
	#include <list>
	#include <map>
	#include <set>
	#include <deque>
	#include <queue>
	#include <stack>
	#include <bitset>
	#include <sstream>
	using namespace std;

	#define LL long long
	#define LD long double
	#define PR pair<int,int>

	#define Fox(i,n) for (i=0; i<n; i++)
	#define Fox1(i,n) for (i=1; i<=n; i++)
	#define FoxI(i,a,b) for (i=a; i<=b; i++)
	#define FoxR(i,n) for (i=(n)-1; i>=0; i--)
	#define FoxR1(i,n) for (i=n; i>0; i--)
	#define FoxRI(i,a,b) for (i=b; i>=a; i--)
	#define Foxen(i,s) for (i=s.begin(); i!=s.end(); i++)
	#define Min(a,b) a=min(a,b)
	#define Max(a,b) a=max(a,b)
	#define Sz(s) int((s).size())
	#define All(s) (s).begin(),(s).end()
	#define Fill(s,v) memset(s,v,sizeof(s))
	#define pb push_back
	#define mp make_pair
	#define x first
	#define y second

	template<typename T> T Abs(T x) { return(x<0 ? -x : x); }
	template<typename T> T Sqr(T x) { return(x*x); }
	string plural(string s) { return(Sz(s) && s[Sz(s)-1]=='x' ? s+"en" : s+"s"); }

	const int INF = (int)1e9;
	const LD EPS = 1e-12;
	const LD PI = acos(-1.0);

	#if DEBUG
	#define GETCHAR getchar
	#else
	#define GETCHAR getchar_unlocked
	#endif

	bool Read(int &x)
	{
	char c,r=0,n=0;
	x=0;
	for(;;)
	{
	c=GETCHAR();
	if ((c<0) && (!r))
	return(0);
	if ((c=='-') && (!r))
	n=1;
	else
	if ((c>='0') && (c<='9'))
	x=x*10+c-'0',r=1;
	else
	if (r)
	break;
	}
	if (n)
	x=-x;
	return(1);
	}

	#define LIM 3003
	#define MOD 1000000007

	int A[LIM],B[LIM];

	PR GCD(int a,int b)
	{
	if (!b)
	return(mp(1,0));
	PR p=GCD(b,a%b);
	return(mp(p.y,p.x-p.y*(a/b)));
	}

	int Add(int a,int b)
	{
	return((a+b)%MOD);
	}

	int Sub(int a,int b)
	{
	return((a-b+MOD)%MOD);
	}

	int Mult(int a,int b)
	{
	return((LL)a*b%MOD);
	}

	int Div(int a,int b)
	{
	int inv=GCD(b,MOD).x;
	if (inv<0)
	inv+=MOD;
	return(Mult(a,inv));
	}

	int Prob(int i,int a,int b)
	{
	Max(a,A[i]);
	Min(b,B[i]);
	if (a>b)
	return(0);
	return(Div(b-a+1,B[i]-A[i]+1));
	}

	int main()
	{
	if (DEBUG)
	freopen("in.txt","r",stdin);
	// vars
	int T,t;
	int N,M;
	int i,j,h,z,d,p,ans;
	int mH[LIM];
	int nh,H[LIM];
	static int dynSafe[LIM][LIM]; // [yard][max fence height protecting safe yard]
	static int dynZomb[LIM][LIM]; // [yard][max active zombie height]
	int aggr[LIM];
	// testcase loop
	Read(T);
	Fox1(t,T)
	{
	// input
	Read(N),Read(M);
	Fox(i,N-1)
	Read(A[i]),Read(B[i]);
	Fill(mH,0);
	Fox(i,M)
	{
	Read(j),Read(h);
	Max(mH[j-1],h);
	}
	// coordinate compress zombie heights
	nh=0;
	H[nh++]=0;
	H[nh++]=INF;
	Fox(i,N)
	if (mH[i])
	H[nh++]=mH[i];
	sort(H,H+nh);
	nh=unique(H,H+nh)-H;
	Fox(i,N)
	mH[i]=lower_bound(H,H+nh,mH[i])-H;
	// DP
	Fill(dynSafe,0);
	Fill(dynZomb,0);
	if (mH[0])
	dynZomb[1][mH[0]]=1;
	else
	dynSafe[1][0]=1;
	Fox1(i,N-1)
	{
	Fill(aggr,0);
	Fox(h,nh)
	{
	z=mH[i];
	if (d=dynSafe[i][h])
	{
	// new zombie's lower anyway?
	if ((!z) \|\| (z<h))
	{
	// new fence is no taller?
	p=Prob(i-1,0,H[h]);
	dynSafe[i+1][h]=Add(dynSafe[i+1][h],Mult(d,p));
	// new fence is taller?
	aggr[h+1]=Add(aggr[h+1],d); // aggregate
	}
	else
	{
	// new fence is no taller than the zombie?
	p=Prob(i-1,0,H[z]);
	dynZomb[i+1][z]=Add(dynZomb[i+1][z],Mult(d,p));
	// new fence is taller?
	aggr[z+1]=Add(aggr[z+1],d); // aggregate
	}
	}
	if (d=dynZomb[i][h])
	{
	// new zombie's at least as tall?
	if (z>=h)
	dynZomb[i+1][z]=Add(dynZomb[i+1][z],d);
	else
	{
	// prev zombie carrying over?
	p=Prob(i-1,0,H[h]);
	dynZomb[i+1][h]=Add(dynZomb[i+1][h],Mult(d,p));
	// not carrying over?
	p=Sub(1,p);
	if (z) // new zombie
	dynZomb[i+1][z]=Add(dynZomb[i+1][z],Mult(d,p));
	else // now safe
	dynSafe[i+1][0]=Add(dynSafe[i+1][0],Mult(d,p));
	}
	}
	}
	// handle aggregated transitions
	d=0;
	Fox1(j,nh-1)
	{
	d=Add(d,aggr[j]);
	if (d)
	{
	p=Prob(i-1,H[j-1]+1,H[j]);
	dynSafe[i+1][j]=Add(dynSafe[i+1][j],Mult(d,p));
	}
	}
	}
	// compute answer
	ans=0;
	Fox(h,nh)
	ans=Add(ans,dynSafe[N][h]);
	// output
	printf("Case #%d: %d\n",t,ans);
	}
	return(0);
	}