### Clarification on your algorithm.

The `l(i,j)`

recursive function should compute the minimum distance of a bitonic tour `i -> 1 -> j`

visiting all nodes that are smaller than `i`

. So, the solution to the initial problem will be `l(n,n)`

!

Important notes:

we can assume that the nodes are ordered by their x coordinate and labeled accordingly (`p1.x < p2.x < p3.x ... < pn.x`

). It they weren't ordered, we could sort them in `O(nlogn)`

time.

`l(i,j) = l(j,i)`

. The reason is that in the lhs, we have a `i ->...-> 1 -> ... -> j`

tour which is optimal. However traversing this route backward will give us the same distance, and won't broke bitonic property.

Now the easy cases (note the changes!):

```
(a) When i = 1 and j = 2, l(i; j) = dist(pi; pj ) = dist(1,2)
```

Here we have the following tour : `1->1->...->2`

. Trivially this is equivalent to the length of the path `1->...->2`

. Since points are ordered by their `.x`

coordinate, there is no point between `1`

and `2`

, so the straight line connecting them will be the optimal one. ( Choosing any number of other points to visit before `2`

would result in a longer path! )

```
(b) When i < j - 1; l(i; j) = l(i; j - 1) + dist(pj-1; pj)
```

In this case, we must get to `j-1`

, since `argmin k (d(k,j) ) = j-1`

. (The node from which `j`

can be reached at the shortest path is `j-1`

). So, this is equivalent to the tour: `i -> ... -> 1 -> .... -> j-1 -> j`

, which is equivalent to `l(i,j-1) + dist(pj-1,pj)`

!

Anf finally the interesting part comes:

```
(c) When i = j - 1 or i = j, min 1<=k<i (l(k; i) + dist(pk; pj ))
```

Here we know that we have to get from `i`

to `1`

, but there is no clue on the bacward sweep! The key idea here is that we must think of the node just before `j`

on our backward route. It may be any of the nodes from `1`

to `j-1`

! Let us assume that this node is `k`

.
Now we have a tour: `i -> ... -> 1 -> .... -> k -> j`

, right? The cost of this tour is `l(i,k) + dist(pk,pj)`

.

Hope you got it.

### Implementation.

You will need a 2-dimensional array say `BT[1..n][1..n]`

. Let `i`

be the row index, `j`

be the column index. How should we fill in this table?

In the first row we know `BT[1][1] = 0`

, `BT[1][2] = d(1,2)`

, so we have only `i,j`

indexes left that fall into the `(b)`

category.

In the remainin rows, we fill the elements from the diagonal till the end.

Here is a sample C++ code (not tested):

```
void ComputeBitonicTSPCost( const std::vector< std::vector<int> >& dist, int* opt ) {
int n = dist.size();
std::vector< std::vector< int > > BT;
BT.resize(n);
for ( int i = 0; i < n; ++i )
BT.at(i).resize(n);
BT.at(0).at(0) = 0; // p1 to p1 bitonic distance is 0
BT.at(0).at(1) = dist.at(0).at(1); // p1 to p2 bitonic distance is d(2,1)
// fill the first row
for ( int j = 2; j < n; ++j )
BT.at(0).at(j) = BT.at(0).at(j-1) + dist.at(j-1).at(j);
// fill the remaining rows
int temp, min;
for ( int i = 1; i < n; ++i ) {
for ( int j = i; j < n; ++j ) {
BT.at(i).at(j) = -1;
min = std::numeric_limits<int>::max();
if ( i == j || i == j -1 ) {
for( int k = 0; k < i; ++k ) {
temp = BT.at(k).at(i) + dist.at(k).at(j);
min = ( temp < min ) ? temp : min;
}
BT.at(i).at(j) = min;
} else {
BT.at(i).at(j) = BT.at(i).at(j-1) + dist.at(j-1).at(j);
}
}
}
*opt = BT.at(n-1).at(n-1);
}
```