# Minimum Knight moves to go from one square to another [duplicate]

Is there a mathematical formula one can use to compute the minimum number of knight moves to get between two points in a infinite 2D grid? I can figure it out using a breadth-first search, but is there a closed-form expression we can use instead?

Thanks!

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## marked as duplicate by templatetypedef, Greg, andrewsi, Rakib, Ryan HainingMay 28 at 3:24

Is the grid finite or infinite? I guess for infinite grids, one can visualize the BFS tree starting at the origin, and try to come up with a formula describing that. But for a finite grid, the boundaries will probably cause lots of special cases. –  MvG Oct 21 '13 at 10:04
we can assume the gird is infinite –  Ahmed Ameen Oct 22 '13 at 22:00
I believe this is the answer you're looking for: stackoverflow.com/a/8778592/1729005 –  axblount Oct 22 '13 at 22:05

I dont think there is one formula that generates the minimum distands for all pairs of points.

But for some special points there are. Let A,B be points on a 2D - Grid with `A = (0,0)` and `B = (x,y)` and `dist(x,y)` the minimum number of knight moves.

First of all, the distance is symmetric:

`dist(x,y) = dist(-x,y) = dist(x,-y) = dist(-x,-y) = dist(y,x)`

1. Case: `2x=y` -> `dist(x,2x) = x`
2. Case: `x = 0`
• Subcase 1: `y = 4k` (k is a natural number)
-> `dist(x,y) = 2k`
• Subcase 2: `y = 4k+1` or `y = 4k+3`
-> `dist(x,y) = 2k + 3`
• Subcase 3: `y = 4k+2`
-> `dist(x,y) = 2k + 2`
3. Case: `x = y`
• Subcase 1: `x = 3k` (k is a natural number)
-> `dist(x,y) = 2k`
• Subcase 2: `x = 3k+1`
-> `dist(x,y) = 2k + 2`
• Subcase 3: `y = 3k+2`
-> `dist(x,y) = 2k + 4`

If B (with `0 <= x <= y`) fits in no case, you know at least
`dist(x,y) <= dist(x-k,y-2k) + dist(k,2k) = dist(0,y-2k) + k`
and
`dist(x,y) <= dist(x-z,y-z) + dist(z,z) = dist(0,y-z) + dist(z,z)`

EDIT: I have thought about it a little more. I think the following algorithm computs the minimum moves (Maple Code):

``````dist := proc(x,y)
global d;
local temp;

if x < 0 then x:= -x; fi;
if y < 0 then y:= -y; fi;
if x > y then temp := x; x:= y; y:= temp; fi;

if y = 2*x then return x; fi;
if x = y then
if x mod 3 = 0 then return 2*(x/3); fi;
if x mod 3 = 1 then return 2+2*(x-1)/3 fi;
if x mod 3 = 1 then return 4+2*(x-2)/3 fi;
fi;
if x = 0 then
if y mod 4 = 0 then return y/2; fi;
if y mod 4 = 1 or y mod 4 = 3 then return 3+(y - (y mod 4))/2; fi;
if y mod 4 = 2 then return 2+(y-2)/2; fi;
fi;
if y > 2*x then
return dist(2*x-y,2*x-y) + dist(y-x,2*(y-x));
else
return dist(0,y-2*x) + dist(x,2*x);
fi;
end proc:
``````

NOTE: this is only correct on a infinite 2D grid.

EDIT2: This (recursive) algorithm runs in `O(1)` (time and space) cause it has a constant number of `O(1)` operations and calls it self at most one more time.

EDIT3: I thought a littel further and I think this is also correkt on a finite 2D grid, if `A` or `B` are at least 1 row/column away from at least one border.

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