# Tiling algorithm for recalculation position of vertexes

I'm searching for an algorithm for recalculation position of vectors which defines polygon which represents one tile.

I have pattern of tile — a polygon defined by 16 vertices which are in field of vertices. For example, I have a square (or rhombus or any other polynom which can fit together with the same polygon).

``````x - x - x - x - x
|               |
x               x
|               |
x               x
|               |
x               x
|               |
x - x - x - x - x
``````

This pattern represents one tile. If I move with one vertex (change its position), I have to recalculate position of other vertex in order to have tile which fit together with other tiles.
1)Does any algorithm exist which already solves that?
2)What is a good basic pattern? Square is too simple.
I heard that is good to have symmetric shapes for patterns, cause it's easier to recalculate it.

Edit: Motivation is to draw tiles on some bitmap. It's like tiles in your bathroom, they must also fit together.

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Sorry, what? Why can't you just move every vertex in the same direction by the same amount? –  BlueRaja - Danny Pflughoeft Mar 23 '12 at 20:32
Cause reason for moving one vertex is to change the shape ;) –  user1097772 Mar 23 '12 at 20:37
So, you're asking if there's an algorithm to determine if a particular set of tiles can tile the plane? I think you're going to be sorely disappointed... –  BlueRaja - Danny Pflughoeft Mar 23 '12 at 20:45
Or, every tile has the same shape, and you alter one edge, and you want to know how to alter the other edges to keep it tiled? –  BlueRaja - Danny Pflughoeft Mar 23 '12 at 20:48

If I understand your question: You start out with a square that passes through some vertices (horizontally- and vertically-symmetric) that you use for tiling. You move some of those vertices around, and want to know how to keep the resulting-shape tiled?

In that case, every time you move a vertex, move the vertically-and-horizontally-mirrored vertex in the same direction by the same amount.

For example, if you move the lower-right vertex down 2 and right 1, you should also move the upper-left vertex down 2 and right 1. This will create a "hole" in the upper-left that snugly fits the new pointy edge in the lower-right.

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On basic tile-able shapes:

Square and rectangle, hexagon are good basic tile-able shapes.

Equilateral triangles are tile-able, but need to be flipped.

There are also more complicated patterns where tiles are not identical. I.e. octagon + square.

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