```
rank[0...7]: 4 6 8 1 2 3 5 7
string: a a b a a a a b
-------------------------------------------
sa[1] = 3 : a a a a b height[1] = 0
sa[2] = 4 : a a a b height[2] = 3
sa[3] = 5 : a a b height[3] = 2
sa[4] = 0 : a a b a a a a b height[4] = 3
sa[5] = 6 : a b height[5] = 1
sa[6] = 1 : a b a a a a b height[6] = 2
sa[7] = 7 : b height[7] = 0
sa[8] = 2 : b a a a a b height[8] = 1
```

Here array **height** is equal to array **L**

using array **sa** , we can easily calculate array **rank**

Then using **Sparse Table (ST) algorithm** to calculate **rmq question**.
http://community.topcoder.com/tc?module=Static&d1=tutorials&d2=lowestCommonAncestor#Range_Minimum_Query_%28RMQ%29

```
int *RMQ = height;
//int RMQ[N];
int mm[N];
int best[20][N]; //best[i][j] means the minimal value in the range [j, j + 2^i)
void initRMQ(int n){
int i,j,a,b;
for(mm[0]=-1,i=1;i<=n;i++)
mm[i]=((i&(i-1))==0)?mm[i-1]+1:mm[i-1];
for(i=1;i<=n;i++) best[0][i]=i;
for(i=1;i<=mm[n];i++)
for(j=1;j<=n+1-(1<<i);j++){
a=best[i-1][j];
b=best[i-1][j+(1<<(i-1))];
if(RMQ[a]<RMQ[b]) best[i][j]=a;
else best[i][j]=b;
}
}
int askRMQ(int a,int b){
int t;
t=mm[b-a+1];b-=(1<<t)-1;
a=best[t][a];b=best[t][b];
return RMQ[a]<RMQ[b]?a:b;
}
int lcp(int a,int b){ //this is your answer
int t;
a=rank[a];b=rank[b];
if(a>b) {t=a;a=b;b=t;}
return(height[askRMQ(a+1,b)]);
}
```

Then just call the function lcp(). Time and space is O(nlogn)

anyx,y (notonly the subset relevant for the Manber/Myers suffix array search algorithm), then the answer is quite complicated. The basic idea is that you use the standard LCP that you have already, and then for given x,y you look at all values LCP[x+1],...,LCP[y] and find the minimum. The minimum is the LCP of x and y that you want. In other words, you need to compute an RMQ (range minimum query) on your existing LCP array. The naive method takes O(n). But there are O(1)-time, O(n)-space methods. E.g. described by Sadakane, DOI: 10.1007/s00224-006-1198-x. – jogojapan Jun 19 '12 at 14:17