# Knight's Shortest Path Chess Question

I've been practicing for an upcoming programming competition and I have stumbled across a question that I am just completely bewildered at. However, I feel as though it's a concept I should learn now rather than cross my fingers that it never comes up.

Basically, it deals with a knight piece on a chess board. You are given two inputs: starting location and ending location. The goal is to then calculate and print the shortest path that the knight can take to get to the target location.

I've never dealt with shortest-path-esque things, and I don't even know where to start. What logic do I employ to go about tackling this?

P.S. If it's of any relevance, they want you to supplement the Knight's normal move ability by also allowing it to move to the four corners of the square a Knight's move paths create if in the center of the board.

-
Could you clarify the P.S.? You mean, if a knight is on E4, it can move to C2, C6, G2, and G6? –  Steve Tjoa Feb 26 '10 at 2:45
Yes, in addition to it's normal moves. –  Kyle Hughes Feb 26 '10 at 3:40

You have a graph here, where all available moves are connected (value=1), and unavailable moves are disconnected (value=0), the sparse matrix would be like:

``````(a1,b3)=1,
(a1,c2)=1,
.....
``````

And the shortest path of two points in a graph can be found using http://en.wikipedia.org/wiki/Dijkstra's_algorithm

Pseudo-code from wikipedia-page:

``````   function Dijkstra(Graph, source):
for each vertex v in Graph:           // Initializations
dist[v] := infinity               // Unknown distance function from source to v
previous[v] := undefined          // Previous node in optimal path from source
dist[source] := 0                     // Distance from source to source
Q := the set of all nodes in Graph
// All nodes in the graph are unoptimized - thus are in Q
while Q is not empty:                 // The main loop
u := vertex in Q with smallest dist[]
if dist[u] = infinity:
break                         // all remaining vertices are inaccessible from source
remove u from Q
for each neighbor v of u:         // where v has not yet been removed from Q.
alt := dist[u] + dist_between(u, v)
if alt < dist[v]:             // Relax (u,v,a)
dist[v] := alt
previous[v] := u
return dist[]
``````

EDIT:

1. as moron, said using the http://en.wikipedia.org/wiki/A*_algorithm can be faster.
2. the fastest way, is to pre-calculate all the distances and save it to a 8x8 full matrix. well, I would call that cheating, and works only because the problem is small. But sometimes competitions will check how fast your program runs.
3. The main point is that if you are preparing for a programming competition, you must know common algorithms including Dijkstra's. A good starting point is reading `Introduction to Algorithms` ISBN 0-262-03384-4. Or you could try wikipedia, http://en.wikipedia.org/wiki/List_of_algorithms
-
This seems to be complex compared to Mustafa's solution below. –  lpapp Apr 27 at 8:08

Actually there is an O(1) formula

This is an image that I've made to visualize it ( Squares a knight can reach on Nth move are painted with same color ).

Can you notice the pattern here?

Although we can see the pattern, it is really hard to find the function `f( x , y )` that returns the number of moves required to go from square `( 0 , 0 )` to square `( x , y )`

But here is the formula that works when `0 <= y <= x`

``````int f( int x , int y )
{
int delta = x - y;

if( y > delta )
return 2 * ( ( y - delta ) / 3 ) + delta;
else
return delta - 2 * ( ( delta - y ) / 4 );
}
``````

Note: This question was asked on SACO 2007 Day 1
And solutions are here

-
Any chance you could describe how you worked out that formula? –  kybernetikos Aug 11 '13 at 20:27
I didn't derive the formula myself. I found it on the solutions link that I provided on my answer. –  Mustafa Serdar Şanlı Aug 14 '13 at 11:10
+1 for the image, -1 for the solution not really working. :( –  Arielr Nov 12 at 14:21

Yes, Dijkstra and BFS will get you the answer, but I think the chess context of this problem provides knowledge that can yield a solution that is much faster than a generic shortest-path algorithm, especially on an infinite chess board.

For simplicity, let's describe the chess board as the (x,y) plane. The goal is to find the shortest path from (x0,y0) to (x1,y1) using only the candidate steps (+-1, +-2) and (+-2, +-1), as described in the question's P.S.

Here is the new observation: draw a square with corners (x-4,y-4), (x-4,y+4), (x+4,y-4), (x+4,y+4). This set (call it S4) contains 32 points. The shortest path from any of these 32 points to (x,y) requires exactly two moves.

The shortest path from any of the 24 points in the set S3 (defined similarly) to (x,y) requires at least two moves.

Therefore, if |x1-x0|>4 or |y1-y0|>4, the shortest path from (x0,y0) to (x1,y1) is exactly two moves greater than the shortest path from (x0,y0) to S4. And the latter problem can be solved quickly with straightforward iteration.

Let N = max(|x1-x0|,|y1-y0|). If N>=4, then the shortest path from (x0,y0) to (x1,y1) has ceil(N/2) steps.

-

What you need to do is think of the possible moves of the knight as a graph, where every position on the board is a node and the possible moves to other position as an edge. There is no need for dijkstra's algorithm, because every edge has the same weight or distance (they are all just as easy or short to do). You can just do a BFS search from your starting point until you reach the end position.

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+!, for this specific problem BFS is enough. –  TiansHUo Feb 26 '10 at 3:33
BFS could be enough, but a plain BST will blow up for many queries - you will need to cache which squares you have visited. And then BFS starts looking a bit like Dijkstra's algorithm... –  Charles Stewart Mar 1 '10 at 9:53
What would be the best way to track all the position we have already travelled so that the BFS tree only grows forward and when we discover nodes availaible from the a new point, we dont end up adding the older node again..and getting stuck in an infinite loop! –  Myth17 Feb 13 '11 at 10:27
I here suppose that we can just do by storing our last knight position? –  Myth17 Feb 13 '11 at 10:43
``````/*
This program takes two sets of cordinates on a 8*8 chessboard, representing the
starting and ending points of a knight's path.
The problem is to print the cordinates that the knight traverses in between, following
the shortest path it can take.
Normally this program is to be implemented using the Djikstra's algorithm(using graphs)
but can also be implemented using the array method.
NOTE:Between 2 points there may be more than one shortest path. This program prints
only one of them.
*/

#include<stdio.h>

#include<stdlib.h>

#include<conio.h>

int m1=0,m2=0;

/*
This array contains three columns and 37 rows:
The rows signify the possible coordinate differences.
The columns 1 and 2 contains the possible permutations of the row and column difference
between two positions on a chess board;
The column 3 contains the minimum number of steps involved in traversing the knight's
path with the given permutation*/

int arr[37][3]={{0,0,0},{0,1,3},{0,2,2},{0,3,3},{0,4,2},{0,5,3},{0,6,4},{0,7,5},    {1,1,2},{1,2,1},{1,3,2},{1,4,3},{1,5,4},{1,6,3},{1,7,4},{2,2,4},{2,3,3},{2,4,2},
{2,5,3},{2,6,3},{2,7,5},{3,3,2},{3,4,3},{3,5,4},{3,6,3},{3,7,4},{4,4,4},{4,5,3},{4,6,4},{4,7,5},{5,5,4},{5,6,5},{5,7,4},{6,6,5},{6,7,5},{7,7,6}};

void printMoves(int,int,int,int,int,int);
void futrLegalMove(int,int,int,int);
main()
{
printf("KNIGHT'S SHORTEST PATH ON A 8*8 CHESSBOARD :\n");
printf("------------------------------------------");
printf("\nThe chessboard may be treated as a 8*8 array here i.e. the (1,1) ");
printf("\non chessboard is to be referred as (0,0) here and same for (8,8) ");
printf("\nwhich is to be referred as (7,7) and likewise.\n");
int ix,iy,fx,fy;
printf("\nEnter the initial position of the knight :\n");
scanf("%d%d",&ix,&iy);
printf("\nEnter the final position to be reached :\n");
scanf("%d%d",&fx,&fy);
int px=ix,py=iy;
int temp;
int tx,ty;
printf("\nThe Knight's shortest path is given by :\n\n");
printf("(%d, %d)",ix,iy);
futrLegalMove(px,py,m1,m2);
printMoves(px,py,fx,fy,m1,m2);
getch();
}

/*
This method checkSteps() checks the minimum number of steps involved from current
position(a & b) to final position(c & d) by looking up in the array arr[][].
*/

int checkSteps(int a,int b,int c,int d)
{
int xdiff, ydiff;
int i, j;
if(c>a)
xdiff=c-a;
else
xdiff=a-c;
if(d>b)
ydiff=d-b;
else
ydiff=b-d;
for(i=0;i<37;i++)
{
if(((xdiff==arr[i][0])&&(ydiff==arr[i][1])) || ((xdiff==arr[i][1])&& (ydiff==arr[i] [0])))
{
j=arr[i][2];break;
}
}

return j;
}

/*
This method printMoves() prints all the moves involved.
*/

void printMoves(int px,int py, int fx, int fy,int a,int b)
{
int temp;
int tx,ty;
int t1,t2;
while(!((px==fx) && (py==fy)))
{
printf(" --> ");
temp=checkSteps(px+a,py+b,fx,fy);
tx=px+a;
ty=py+b;
if(!(a==2 && b==1))
{if((checkSteps(px+2,py+1,fx,fy)<temp) && checkMove(px+2,py+1))
{temp=checkSteps(px+2,py+1,fx,fy);
tx=px+2;ty=py+1;}}
if(!(a==2 && b==-1))
{if((checkSteps(px+2,py-1,fx,fy)<temp) && checkMove(px+2,py-1))
{temp=checkSteps(px+2,py-1,fx,fy);
tx=px+2;ty=py-1;}}
if(!(a==-2 && b==1))
{if((checkSteps(px-2,py+1,fx,fy)<temp) && checkMove(px-2,py+1))
{temp=checkSteps(px-2,py+1,fx,fy);
tx=px-2;ty=py+1;}}
if(!(a==-2 && b==-1))
{if((checkSteps(px-2,py-1,fx,fy)<temp) && checkMove(px-2,py-1))
{temp=checkSteps(px-2,py-1,fx,fy);
tx=px-2;ty=py-1;}}
if(!(a==1 && b==2))
{if((checkSteps(px+1,py+2,fx,fy)<temp) && checkMove(px+1,py+2))
{temp=checkSteps(px+1,py+2,fx,fy);
tx=px+1;ty=py+2;}}
if(!(a==1 && b==-2))
{if((checkSteps(px+1,py-2,fx,fy)<temp) && checkMove(px+1,py-2))
{temp=checkSteps(px+1,py-2,fx,fy);
tx=px+1;ty=py-2;}}
if(!(a==-1 && b==2))
{if((checkSteps(px-1,py+2,fx,fy)<temp) && checkMove(px-1,py+2))
{temp=checkSteps(px-1,py+2,fx,fy);
tx=px-1;ty=py+2;}}
if(!(a==-1 && b==-2))
{if((checkSteps(px-1,py-2,fx,fy)<temp) && checkMove(px-1,py-2))
{temp=checkSteps(px-1,py-2,fx,fy);
tx=px-1;ty=py-2;}}
t1=tx-px;//the step taken in the current move in the x direction.
t2=ty-py;//" " " " " " " " " " " " " " " " " " " " " y " " " " ".
px=tx;
py=ty;
printf("(%d, %d)",px,py);
futrLegalMove(px,py,t1,t2);
a=m1;
b=m2;
}

}

/*
The method checkMove() checks whether the move in consideration is beyond the scope of
board or not.
*/

int checkMove(int a, int b)
{
if(a>7 || b>7 || a<0 || b<0)
return 0;
else
return 1;
}

/*Out of the 8 possible moves, this function futrLegalMove() sets the valid move by
applying the following constraints
1. The next move should not be beyond the scope of the board.
2. The next move should not be the exact opposite of the previous move.
The 1st constraint is checked by sending all possible moves to the checkMove()
method;
The 2nd constraint is checked by passing as parameters(i.e. a and b) the steps of the
previous move and checking whether or not it is the exact opposite of the current move.
*/

void futrLegalMove(int px,int py,int a,int b)
{
if(checkMove(px+2,py+1) && (a!=-2 && b!=-1))
m1=2,m2=1;
else
{
if(checkMove(px+2,py-1)&& (a!=-2 && b!=1))
m1=2,m2=-1;
else
{
if(checkMove(px-2,py+1)&& (a!=2 && b!=-1))
m1=-2,m2=1;
else
{
if(checkMove(px-2,py-1)&& (a!=2 && b!=1))
m1=-2,m2=-1;
else
{
if(checkMove(px+1,py+2)&& (b!=-2 && a!=-1))
m2=2,m1=1;
else
{
if(checkMove(px+1,py-2)&& (a!=-1 && b!=2))
m2=-2,m1=1;
else
{
if(checkMove(px-1,py+2)&& (a!=1 && b!=-2))
m2=2,m1=-1;
else
{
if(checkMove(px-1,py-2)&& (a!=1 && b!=2))
m2=-2,m1=-1;
}}}}}}}
}

//End of Program.
``````

I haven't studied graphs yet..as per the problem of implementing it through simply arrays, I could not derive any solution other than this. I treated the positions not as ranks and files(The usual chess notation), but as array indices. FYI, this is for a 8*8 chessboard only. Any improvement advice is always welcomed.

*Checked on DEV-C++ 4.9.9.2 compiler(Bloodshed Software).

-

``````NumWays(x,y)=1+min(NumWays(x+-2,y-+1),NumWays(x+-1,y+-2));
``````

and using Dynamic Programming to get the solution.

P.S: It kinda uses the BFS without having to take the trouble of declaring the nodes and edges of the graph.

-

Here is a solution for this particular problem implemented in Perl. It will show one of the shortest paths - there might be more than one in some cases.

I didn't use any of the algorithms described above - but it would be nice to compare it to other solutions.

``````#!/usr/local/bin/perl -w

use strict;

my \$from = [0,0];
my \$to   = [7,7];

my \$f_from = flat(\$from);
my \$f_to   = flat(\$to);

my \$max_x = 7;
my \$max_y = 7;
my @moves = ([-1,2],[1,2],[2,1],[2,-1],[1,-2],[-1,-2],[-2,-1],[-2,1]);
my %squares = ();
my \$i = 0;
my \$min = -1;

my @s = ( \$from );

while ( @s ) {

my @n = ();
\$i++;

foreach my \$s ( @s ) {
unless ( \$squares{ flat(\$s) } ) {
my @m = moves( \$s );
push @n, @m;
\$squares{ flat(\$s) } = { i=>\$i, n=>{ map {flat(\$_)=>1} @m }, };

\$min = \$i if \$squares{ flat(\$s) }->{n}->{\$f_to};
}
}

last if \$min > -1;
@s = @n;
}

show_path( \$f_to, \$min );

sub show_path {
my (\$s,\$i) = @_;

return if \$s eq \$f_from;

print "\$i => \$f_to\n" if \$i == \$min;

foreach my \$k ( keys %squares ) {
if ( \$squares{\$k}->{i} == \$i && \$squares{\$k}->{n}->{\$s} ) {
\$i--;
print "\$i => \$k\n";
show_path( \$k, \$i );
last;
}
}
}

sub flat { "\$_[0]->[0],\$_[0]->[1]" }

sub moves {
my \$c = shift;
my @s = ();

foreach my \$m ( @moves ) {
my \$x = \$c->[0] + \$m->[0];
my \$y = \$c->[1] + \$m->[1];

if ( \$x >= 0 && \$x <=\$max_x && \$y >=0 && \$y <=\$max_y) {
push @s, [\$x, \$y];
}
}
return @s;
}

__END__
``````
-

The O(1) answer above isn't really working. (Check (1,1) or (3,2) or (4,4), aside for the obvious edge cases of (1,0) or (2,2)).

Below is a much uglier solution (python), which does work (with added "tests"):

``````def solve(x,y):
x = abs(x)
y = abs(y)
if y > x:
temp=y
y=x
x=temp
if (x==2 and y==2):
return 4
if (x==1 and y==0):
return 3

if(y == 0 or float(y) / float(x) <= 0.5):
xClass = x % 4
if (xClass == 0):
initX = x/2
elif(xClass == 1):
initX = 1 + (x/2)
elif(xClass == 2):
initX = 1 + (x/2)
else:
initX = 1 + ((x+1)/2)

if (xClass > 1):
return initX - (y%2)
else:
return initX + (y%2)
else:
diagonal = x - ((x-y)/2)
if((x-y)%2 == 0):
if (diagonal % 3 == 0):
return (diagonal/3)*2
if (diagonal % 3 == 1):
return ((diagonal/3)*2)+2
else:
return ((diagonal/3)*2)+2
else:
return ((diagonal/3)*2)+1

def test():
real=[
[0,3,2,3,2,3,4,5,4,5,6,7,6,7],
[3,2,1,2,3,4,3,4,5,6,5,6,7,8],
[2,1,4,3,2,3,4,5,4,5,6,7,6,7],
[3,2,3,2,3,4,3,4,5,6,5,6,7,8],
[2,3,2,3,4,3,4,5,4,5,6,7,6,7],
[3,4,3,4,3,4,5,4,5,6,5,6,7,8],
[4,3,4,3,4,5,4,5,6,5,6,7,6,7],
[5,4,5,4,5,4,5,6,5,6,7,6,7,8],
[4,5,4,5,4,5,6,5,6,7,6,7,8,7],
[5,6,5,6,5,6,5,6,7,6,7,8,7,8],
[6,5,6,5,6,5,6,7,6,7,8,7,8,9],
[7,6,7,6,7,6,7,6,7,8,7,8,9,8]]

for x in range(12):
for y in range(12):
res = solve(x,y)
if res!= real[x][y]:
print (x, y), "failed, and returned", res, "rather than", real[x][y]
else:
print (x, y), "worked. Cool!"

test()
``````
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## protected by lpappApr 27 at 8:07

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