# Minimum steps to win Snake Ladder

Given a snake and ladder game, write a function that returns the minimum number of jumps to take top or destination position. You can assume the die you throws results in always favor of you

**

Here is my solution, but not sure it's correct or not.

This problem is similar to frog jump in an array.But before that we will have to model the problem in that format.

Create an array of size 100 and for each position store 6 if there is no snake or ladder. store jump count . if ladder is present at that point . If snake is present then store -ve jump at that location.

Now we have to solve in how many minimum steps we can reach till end. Main problem can be solved using dynamic programing in O(n^2) time complexity and O(n ) space.

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Try BFS(Breadth First Search). Runtime will be O(N*6)=O(N) as from a certain point you'll move at most 6 cells forward. –  Fallen Aug 19 '13 at 16:39
@Fallen, Yes, but out of those six steps, I have to choose the one with maximum ladder jump and avoid the one with snake position. Right? –  AKS Aug 19 '13 at 16:43
I used simulation to solve this problem at my blog. My solution is in Scheme; there are also solutions in Haskell and Python. In addition to simulation, commenters used transition matrices and Dijkstra's shortest-path algorithm to find solutions. –  user448810 Aug 19 '13 at 18:23
Please put comments and reason if you are down voting this. There is no point in down voting without any comment. –  AKS Aug 19 '13 at 21:58
For a scaleable approach I would definately think Dijkstra shortest path, however given the size of the problem it can easily be brute forced. (6^7 isn't a lot). –  Dennis Jaheruddin Aug 21 '13 at 8:33

Have a look at this blog post, it does a full mathematical analysis of Chutes and Ladders, using both Monte-Carlo simulations and Markov chains. He does show a way of calculating the minimum number of steps to win (basically construct a transition matrix and see how many times you have to multiply the starting vector to get to a solution that has a non-zero final position). This is probably not the most efficient way of doing it, but the post is well worth the read.

Here is a quick solution in python, using sets. I got the numbers in the jump-table from the blog post. At every step, it simply calculates all the positions reachable from the previous step, and continues to do so until the final position is among the reachable positions:

``````jumps = {1: 38, 4: 14, 9: 31, 21: 42, 28: 84, 36: 44, 51: 67, 71: 91, 80: 100,
98: 78, 95: 75, 93: 73, 87: 24, 64: 60, 62: 19, 56: 53, 49: 11, 48: 26, 16: 6}
final_pos = 100
positions = {0} #initial position off the board
nsteps = 0

while final_pos not in positions:
nsteps += 1
old_positions = positions
positions = set()
for pos in old_positions:
for dice in range(1, 7):
new_pos = pos + dice

print 'Reached finish in %i steps' % nsteps
``````

Execution time is negligible and it spits out the correct answer (see blog) of 7.

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Breadth First Search (BFS) Or Dynamic Programming solution will work in O(N) time using O(N) space.

Initialization: Keep an auxiliary array to keep the ladders and snakes. Suppose there's a ladder from xth to yth cell. So auxi[x] = y. If there's snake from cell x to y, `x>y` then keep `auxi[x]=-1`. If there's no ladder or snake from the current cell, keep auxi[x] = x;

A dynamic programming solution:

``````res[top]=0;
for(int i  = top-1; i>=0; i--) {

res[i] = INF;
for(int j=1; j<=6; j++){

if(i-j<0)break;

if(auxi[i+j]>-1)     // if i+jth cell is start of a snake, we'll always skip it
res[i]=min( res[i] , res[auxi[i+j]]+1 );
}

}
``````

We'll always skip a cell where a snake starts because let's assume, on the x the cell a snake starts and it ends on the yth cell where, y

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I think there must be something wrong with your code; it's accessing elements of `res` before they're initialized. –  Ilmari Karonen Aug 19 '13 at 19:31
@IlmariKaronen: Where? Please note that, I'm initializing `res[i] = INF;` before the inner loop. –  Fallen Aug 19 '13 at 19:55
Yes, but `auxi[i-j]` may be (and typically is) less than `i`. (I think that's probably a bug, and it should be `auxi[i+j]` since you're looping backwards from `top` to `0`, but even if you fix that, you'll still be referencing uninitialized elements whenever there's a snake.) –  Ilmari Karonen Aug 19 '13 at 19:58
What is `res`, number of turns to reach the top from a certain position? And does your algorithm take into account that a solution potentially goes both up ladders and down snakes? Not sure if the `min()` takes that correctly into account, since you seem to look up board positions that might change value later ... –  Bas Swinckels Aug 19 '13 at 21:36
I did not study CS, but I do know what DP is. You get the downvotes because either your algo is very cryptic, or it is simply buggy. As both me and @IlmariKaronen noted, you are probably accessing uninitialized parts of `res` in case of a snake, you do not reply to that criticism in the comments. Your solution might work if there are only ladders. But would it find a solution with a ladder from 1 to 80, another from 50 to 100 and a snake from 81 to 49? Probably not, when `i=80`, it does not yet know that 49 is 1 step away from the finish. Did you test your own code? –  Bas Swinckels Aug 20 '13 at 7:21

Solution in C# in o(n).

Build an help matrix to go over each step and see what is the minimum way to get there and add one to it.

``````const int BoardSize = 100;
const int MaxStep = 6;
static void Main()
{

// - means a ledder ending at the pos
// + means a snake (taking you back n steps)
int[] arr = new int[] {
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,      8,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,     -1,
-1,     -1,     -1,     -1,     -1,     -1,     -1,     -71,    -1,     -1      };

Console.WriteLine("Steps needed: " + solve(arr));
}

public static int solve(int[] inArr)
{
int[] arr = new int[BoardSize];

arr[0] = 1;

for (int i = 0; i < BoardSize; ++i)
{
// steps here is the minimum of all the positions in all the previos 6 cells +1
if (i < MaxStep)
arr[i] = 1;
else
{
int extraOption = int.MaxValue;
if (inArr[i] < -1 || inArr[i] > 0)
extraOption = arr[i + inArr[i]];
else if (inArr[i] > 0)
extraOption = arr[i + inArr[i]];
arr[i] = min(arr[i - 1], arr[i - 2], arr[i - 3], arr[i - 4], arr[i - 5], arr[i - 6], extraOption) + 1;
}
}

for (int i = 0; i < BoardSize; ++i)
{
Console.Write(arr[i] + "\t");
if ((i + 1) % 10 == 0)
Console.WriteLine("");
}

return arr[arr.Length-1];
}

public static int min(int a, int b, int c, int d, int e, int f, int g)
{
int ab = Math.Min(a,b);
int cd = Math.Min(c,d);
int ef = Math.Min(e,f);
return Math.Min(Math.Min(ab, cd), Math.Min(ef,g));
}
``````
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Here's a simple breadth-first search solution in Python:

``````# the target square and the positions of the snakes and ladders:
top = 100
jump = { 1: 38,  4: 14,  9: 31, 16:  6, 21: 42, 28: 84, 36: 44,
48: 26, 49: 11, 51: 67, 56: 53, 62: 19, 64: 60, 71: 91,
80:100, 87: 24, 93: 73, 95: 75, 98: 78}

# start from square 0 (= outside the board) after 0 rolls
open = {0}
path = {0: ()}

while len(open) > 0:
i = open.pop()
p = path[i] + (i,)
for j in xrange(i+1, i+7):
if j > top: break
if j in jump: j = jump[j]
if j not in path or len(path[j]) > len(p):
path[j] = p

for i in path:
print "Square", i, "can be reached in", len(path[i]), "rolls via", path[i]
``````

The board layout (i.e. the `jump` dictionary) is taken from the blog post linked to by Bas Swinckels in his answer. This code will print (one of the) shortest path(s) to each reachable square on the board, ending with:

``````Square 100 can be reached in 7 rolls via (0, 38, 41, 45, 67, 68, 74)
``````

If you want the full output, see this demo on ideone.com.

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This program simulate actual scenario..kindly let me know if it meet the expectation or not..

``````import java.util.HashMap;
import java.util.Map;

private int winPosition=100;
private int currentPosition=1;

}

public int startGame(){
int count=0;
while(currentPosition!=winPosition){
count++;
getNextPosition(rollDice());
}
System.out.println("Game Won!!!!!!");
return count;
}

public int rollDice(){
return 1+ (int)(Math.random()*5);
}

public void getNextPosition(int diceValue){
int temp=currentPosition+diceValue;
}else{
if(temp<=winPosition){
currentPosition=temp;
}
}
}
/**
* @param args
*/
public static void main(String[] args) {