# How many moves to reach a destination? Efficient flood filling

I want to compute the distance of cells from a destination cell, using number of four-way movements to reach something. So the the four cells immediately adjacent to the destination have a distance of 1, and those on the four cardinal directions of each of them have a distance of 2 and so on. There is a maximum distance that might be around 16 or 20, and there are cells that are occupied by barriers; the distance can flow around them but not through them.

I want to store the output into a 2D array, and I want to be able to compute this 'distance map' for any destination on a bigger maze map very quickly.

I am successfully doing it with a variation on a flood fill where the I place incremental distance of the adjacent unfilled cells in a priority queue (using C++ STL).

I am happy with the functionality and now want to focus on optimizing the code, as it is very performance sensitive.

What cunning and fast approaches might there be?

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Without code its hard to know what can be optimised... –  Chris Nov 14 '11 at 10:51
You can use simple `queue` instead of `priority queue` because you iterate over cells in increasing order of distance from the start cell. –  Ivan Benko Nov 14 '11 at 11:02

I think you have done everything right. If you coded it correct it takes O(n) time and O(n) memory to compute flood fill, where n is the number of cells, and it can be proven that it's impossible to do better (in general case). And after fill is complete you just return distance for any destination with O(1), it easy to see that it also can be done better.

So if you want to optimize performance, you can only focused on CODE LOCAL OPTIMIZATION. Which will not affect asymptotic but can significantly improve your real execution time. But it's hard to give you any advice for code optimization without actually seeing source.

So if you really want to see optimized code see the following (Pure C):

# include

``````int* BFS()
{
int N, M; // Assume we have NxM grid.
int X, Y; // Start position. X, Y are unit based.
int i, j;
int movex[4] = {0, 0, 1, -1}; // Move on x dimension.
int movey[4] = {1, -1, 0, 0}; // Move on y dimension.

// TO DO: Read N, M, X, Y

// To reduce redundant functions calls and memory reallocation
// allocate all needed memory once and use a simple arrays.
int* map = (int*)malloc((N + 2) * (M + 2));
int leadDim = M + 2;
// Our map. We use one dimension array. map[x][y] = map[leadDim * x + y];
// If (x,y) is occupied then map[leadDim*x + y] = -1;
// If (x,y) is not visited map[leadDim*x + y] = -2;

int* queue = (int*)malloc(N*M);
int first = 0, last =1;

// Fill the boarders to simplify the code and reduce conditions
for (i = 0; i < N+2; ++i)
{
map[i * leadDim + 0] = -1;
map[i * leadDim + M + 1] = -1;
}

for (j = 0; j < M+2; ++j)
{
map[j] = -1;
map[(N + 1) * leadDim + j] = -1;
}

// TO DO: Read the map.

queue[first] = X * leadDim + Y;
map[X * leadDim + Y] = 0;

// Very simple optimized process loop.
while (first < last)
{
int current = queue[first];
int step = map[current];

for (i = 0; i < 4; ++i)
{
int temp = current + movex[i] * leadDim + movey[i];
if (map[temp] == -2) // only one condition in internal loop.
{
map[temp] = step + 1;
queue[last++] = temp;
}
}

++first;
}

free(queue);

return map;
}
``````

Code may seems tricky. And of course, it doesn't look like OOP (I actually think that OOP fans will hate it) but if you want something really fast that's what you need.

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priority queue isn't O(1)? I was hoping for descriptions of marching or sweeping algorithms –  Will Nov 14 '11 at 10:52
There are many priority queues data structures, designed for different needs. The easiest one called Binary Heap, has O(log n) asymptotic for add, delete, priority increase, priority decrease operations. Some new approaches (such as Fibonacci and Relaxed Heap) decrease asymptotic of some of operations (under certain conditions) to O(1) but they are pretty complex and has significant constant. Simple FIFO queue you need there already do push/pop in O(1). And nature of this task guarantees the validity of solution based on FIFO. Still nothing to optimize using algorithm theory. –  Wisdom's Wind Nov 14 '11 at 11:07
a friend pointed me at stackoverflow.com/questions/7426136/… –  Will Nov 14 '11 at 11:20
Interesting topic, but tasks they investigating is more complex than your. For your simple case you can use more simple (and effective) solution. –  Wisdom's Wind Nov 14 '11 at 12:33

`````` int visit( int xy, int dist) {
int ret =1;
if (array[xy] <= dist) return 0;
array[xy] = dist;
if (dist == maxdist) return ret;
ret += visit ( RIGHT(xy) , dist+1);
...
same for left, up, down
...
return ret;
}
``````

You'l need to handle the initalisation and the edge-cases. And you have to decide if you want a two dimentional array or a one dimensonal array.

A next step could be to use a todo list and remove the recursion, and a third step could be to add some bitmasking.

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BFS is better than DFS to that task –  Ivan Benko Nov 14 '11 at 11:09
This is a good example of bad solution. At first it recursive, while there is a clear and fast solution without recursion. Excessive recursive calls will slow down performance. Second, it suffer from stack overflow for big matrices. –  Wisdom's Wind Nov 14 '11 at 11:11
Recursion isn't always slow. In addition, it is often much easier to prove properties about a program when it utilizes recursion. –  I GIVE CRAP ANSWERS Nov 14 '11 at 11:16
IMHO the first step should always be simple. As I said: next step should be to use a todo list / queue / heap / whatever. –  wildplasser Nov 14 '11 at 11:25
"Recursion isn't always slow." Depends what you will use to compare. Good straight implementation of the same thing always better than recursion. But of course not always easier to understand and faster to code. And actually this code is not clear enough. If you really meant DFS, it's completely useless for this task. In fact it will take exponential time. –  Wisdom's Wind Nov 14 '11 at 12:39

It's common task for BFS. Complexity is O(cellsCount)

My c++ implementation:

``````vector<vector<int> > GetDistance(int x, int y, vector<vector<int> > cells)
{
const int INF = 0x7FFFFF;
vector<vector<int> > distance(cells.size());
for(int i = 0; i < distance.size(); i++)
distance[i].assign(cells[i].size(), INF);
queue<pair<int, int> > q;

q.push(make_pair(x, y));
distance[x][y] = 0;

while(!q.empty())
{
pair<int, int> curPoint = q.front();
q.pop();
int curDistance = distance[curPoint.first][curPoint.second];
for(int i = -1; i <= 1; i++)
for(int j = -1; j <= 1; j++)
{
if( (i + j) % 2 == 0 ) continue;
pair<int, int> nextPoint(curPoint.first + i, curPoint.second + j);
if(nextPoint.first >= 0 && nextPoint.first < cells.size()
&& nextPoint.second >= 0 && nextPoint.second < cells[nextPoint.first].size()
&& cells[nextPoint.first][nextPoint.second] != BARRIER
&& distance[nextPoint.first][nextPoint.second] > curDistance + 1)
{
distance[nextPoint.first][nextPoint.second] = curDistance + 1;
q.push(nextPoint);
}
}
}
return distance;
}
``````
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