# How do I represent a hextile/hex grid in memory?

Say I'm building a board game with a hextile grid, like Settlers of Catan:

Note that each vertex and edge may have an attribute (a road and settlement above).

How would I make a data structure which represents this board? What are the patterns for accessing each tile's neighbors, edges and vertices?

• you can also use a hilbert curve, they are spacing filing curves such that adjacency in the plane is preserved in a linear encoding. check out spatial indexing and how these are used! v interesting – pbordeaux Sep 20 '18 at 1:13

Amit Patel has posted an amazing page on this topic. It's so comprehensive and wonderful that it needs to be the definitive answer to this question: Hexagonal Grids

• Thanks :) That page doesn't cover edges and vertices, but I cover them in the Relationships Between Parts section of my grids article at www-cs-students.stanford.edu/~amitp/game-programming/grids (the diagrams are for square grids but the table includes the formulas for axial hex grids also) – amitp Jun 7 '13 at 0:58

Such a grid can be represented in a two-dimensional array:

If

``````   2
7     3
1
6     4
5
``````

is the number one with its neighbors in the hex grid, then you can put this into a 2D array like so:

``````2 3
7 1 4
6 5
``````

Obviously neighbor-ness is determined in this grid not only by being horizontally or vertically adjacent but also using one diagonal.

You can use a graph too, if you like to, though.

• Cool. What about data for edges and vertices? – a paid nerd Dec 3 '09 at 17:26
• I'd probably store them separately. Regardless of whether you primarily look at the tiles or the edges/vertices the other half of the data is either painful or redundant to store. – Joey Dec 3 '09 at 19:10
• See Amit Patel's article in "a paid nerd" answer. – aredridel Jun 3 '13 at 14:03

This article goes through how to set up a Isomeric/Hexagonal grid game. I recommend you have a look at the `Forcing Isometric and Hexagonal Maps onto a Rectangular Grid` section and the the movement section. Although it is different from what you are looking for it may help you formulate how to do what you want.

I've dealt a lot with hexes. In cases like this, you track each of the 6 points for the borders of the hex. This lets you draw it quite easily.

You would have a single array of objects that represent hexes. Each of these hex objects also has 6 "pointers" (or an index to another array) pointing to another array of "sides". Same thing for "vertices". Of course the vertices would have 3 pointers to the adjoining hexes, and the sides would have 2.

So, a hex may be something like: X, Y, Point(6), Vertices(6), Sides(6)

Then you have a Hex array, vertice array, and side array.

Then it is pretty simple to find the vertices/sides for a hex, or whatever.

When I say pointer it could just as easily be an integer pointing to the element in the vertice or side array or whatever. And of course arrays could be lists or whatever.

``````   2
7     3
1
6     4
5
``````

You can also try to 'flat' rows of your map. For this example it would be:

``````  2
7 1 3
6 5 4
``````

Its sometimes more useful to have rows in one row:P

• This might have some messy neighbour-checking code, because, for example, 1 and 6 are neighbours, but 3 and 5 are not, yet they have the same relative positions. – Dukeling Jul 27 '17 at 16:12

I would suggest something like the following (I'll use Delphi-style declarations):

``````type
THexEdge = record
Hexes: array[1..2] of Integer; // Index of adjoining hexes.
// Other edge stuff goes here.
end;

THexVertex = record
Hexes: array[1..3] of Integer; // Index of adjoining hexes.
// Other vertex stuff goes here.
end;

THex = record
Edges: array[1..6] of Integer; // Index of edge.
Vertices: array[1..6] of Integer; // Index of vertex.
// Other hex stuff goes here.
end;

var
Edges: array of THexEdge;
Vertices: array of THexVertex;
HexMap: array of THex;
``````

Each hex has six edges and six vertices. Each edge keeps track of its two adjoining hexes, and each vertex keeps track of its three adjoining hexes (hexes on the edges of the map will be a special case).

There are many things that you could do a different way of course. You could use pointers rather than arrays, you could use objects rather than records, and you could store your hexes in a two-dimensional array as other answerers have suggested.

Hopefully, that might give you some ideas about one way to approach it though.

We implemented a Settlers of Catan AI for a class project, and modified code from this answer (which was buggy) to create a Board with constant time random access to vertices and edges. It was a fun problem, but the board took a lot of time, so in case anyone is still looking for a simple implementation here is our Python code:

``````class Board:
# Layout is just a double list of Tiles, some will be None
def __init__(self, layout=None):
self.numRows = len(layout)
self.numCols = len(layout[0])
self.hexagons = [[None for x in xrange(self.numCols)] for x in xrange(self.numRows)]
self.edges = [[None for x in xrange(self.numCols*2+2)] for x in xrange(self.numRows*2+2)]
self.vertices = [[None for x in xrange(self.numCols*2+2)] for x in xrange(self.numRows*2+2)]
for row in self.hexagons:
for hexagon in row:
if hexagon == None: continue
edgeLocations = self.getEdgeLocations(hexagon)
vertexLocations = self.getVertexLocations(hexagon)
for xLoc,yLoc in edgeLocations:
if self.edges[xLoc][yLoc] == None:
self.edges[xLoc][yLoc] = Edge(xLoc,yLoc)
for xLoc,yLoc in vertexLocations:
if self.vertices[xLoc][yLoc] == None:
self.vertices[xLoc][yLoc] = Vertex(xLoc,yLoc)

def getNeighborHexes(self, hex):
neighbors = []
x = hex.X
y = hex.Y
offset = 1
if x % 2 != 0:
offset = -1

if (y+1) < len(self.hexagons[x]):
hexOne = self.hexagons[x][y+1]
if hexOne != None: neighbors.append(hexOne)
if y > 0:
hexTwo = self.hexagons[x][y-1]
if hexTwo != None: neighbors.append(hexTwo)
if (x+1) < len(self.hexagons):
hexThree = self.hexagons[x+1][y]
if hexThree != None: neighbors.append(hexThree)
if x > 0:
hexFour = self.hexagons[x-1][y]
if hexFour != None: neighbors.append(hexFour)
if (y+offset) >= 0 and (y+offset) < len(self.hexagons[x]):
if (x+1) < len(self.hexagons):
hexFive = self.hexagons[x+1][y+offset]
if hexFive != None: neighbors.append(hexFive)
if x > 0:
hexSix = self.hexagons[x-1][y+offset]
if hexSix != None: neighbors.append(hexSix)
return neighbors

def getNeighborVertices(self, vertex):
neighbors = []
x = vertex.X
y = vertex.Y
offset = -1
if x % 2 == y % 2: offset = 1
# Logic from thinking that this is saying getEdgesOfVertex
# and then for each edge getVertexEnds, taking out the three that are ==vertex
if (y+1) < len(self.vertices[0]):
vertexOne = self.vertices[x][y+1]
if vertexOne != None: neighbors.append(vertexOne)
if y > 0:
vertexTwo = self.vertices[x][y-1]
if vertexTwo != None: neighbors.append(vertexTwo)
if (x+offset) >= 0 and (x+offset) < len(self.vertices):
vertexThree = self.vertices[x+offset][y]
if vertexThree != None: neighbors.append(vertexThree)
return neighbors

# used to initially create vertices
def getVertexLocations(self, hex):
vertexLocations = []
x = hex.X
y = hex.Y
offset = x % 2
offset = 0-offset
vertexLocations.append((x, 2*y+offset))
vertexLocations.append((x, 2*y+1+offset))
vertexLocations.append((x, 2*y+2+offset))
vertexLocations.append((x+1, 2*y+offset))
vertexLocations.append((x+1, 2*y+1+offset))
vertexLocations.append((x+1, 2*y+2+offset))
return vertexLocations

# used to initially create edges
def getEdgeLocations(self, hex):
edgeLocations = []
x = hex.X
y = hex.Y
offset = x % 2
offset = 0-offset
edgeLocations.append((2*x,2*y+offset))
edgeLocations.append((2*x,2*y+1+offset))
edgeLocations.append((2*x+1,2*y+offset))
edgeLocations.append((2*x+1,2*y+2+offset))
edgeLocations.append((2*x+2,2*y+offset))
edgeLocations.append((2*x+2,2*y+1+offset))
return edgeLocations

def getVertices(self, hex):
hexVertices = []
x = hex.X
y = hex.Y
offset = x % 2
offset = 0-offset
hexVertices.append(self.vertices[x][2*y+offset]) # top vertex
hexVertices.append(self.vertices[x][2*y+1+offset]) # left top vertex
hexVertices.append(self.vertices[x][2*y+2+offset]) # left bottom vertex
hexVertices.append(self.vertices[x+1][2*y+offset]) # right top vertex
hexVertices.append(self.vertices[x+1][2*y+1+offset]) # right bottom vertex
hexVertices.append(self.vertices[x+1][2*y+2+offset]) # bottom vertex
return hexVertices

def getEdges(self, hex):
hexEdges = []
x = hex.X
y = hex.Y
offset = x % 2
offset = 0-offset
hexEdges.append(self.edges[2*x][2*y+offset])
hexEdges.append(self.edges[2*x][2*y+1+offset])
hexEdges.append(self.edges[2*x+1][2*y+offset])
hexEdges.append(self.edges[2*x+1][2*y+2+offset])
hexEdges.append(self.edges[2*x+2][2*y+offset])
hexEdges.append(self.edges[2*x+2][2*y+1+offset])
return hexEdges

# returns (start, end) tuple
def getVertexEnds(self, edge):
x = edge.X
y = edge.Y
vertexOne = self.vertices[(x-1)/2][y]
vertexTwo = self.vertices[(x+1)/2][y]
if x%2 == 0:
vertexOne = self.vertices[x/2][y]
vertexTwo = self.vertices[x/2][y+1]
return (vertexOne, vertexTwo)

def getEdgesOfVertex(self, vertex):
vertexEdges = []
x = vertex.X
y = vertex.Y
offset = -1
if x % 2 == y % 2: offset = 1
edgeOne = self.edges[x*2][y-1]
edgeTwo = self.edges[x*2][y]
edgeThree = self.edges[x*2+offset][y]
if edgeOne != None: vertexEdges.append(edgeOne)
if edgeTwo != None: vertexEdges.append(edgeTwo)
if edgeThree != None: vertexEdges.append(edgeThree)
return vertexEdges

def getHexes(self, vertex):
vertexHexes = []
x = vertex.X
y = vertex.Y
xOffset = x % 2
yOffset = y % 2

if x < len(self.hexagons) and y/2 < len(self.hexagons[x]):
hexOne = self.hexagons[x][y/2]
if hexOne != None: vertexHexes.append(hexOne)

weirdX = x
if (xOffset+yOffset) == 1: weirdX = x-1
weirdY = y/2
if yOffset == 1: weirdY += 1
else: weirdY -= 1
if weirdX >= 0 and weirdX < len(self.hexagons) and weirdY >= 0 and weirdY < len(self.hexagons):
hexTwo = self.hexagons[weirdX][weirdY]
if hexTwo != None: vertexHexes.append(hexTwo)

if x > 0 and x < len(self.hexagons) and y/2 < len(self.hexagons[x]):
hexThree = self.hexagons[x-1][y/2]
if hexThree != None: vertexHexes.append(hexThree)

return vertexHexes
``````
• This answer is awful. You've just pasted tons of code without explaining anything (except who wrote the code). Even if that was ok here, the code itself is horrible. There are no docstrings, almost no comments, and the few comments that are included are unintelligible (Logic from thinking that this is saying getEdgesOfVertex and then for each edge getVertexEnds, taking out the three that are ==vertex). – Carl Smith Jul 10 at 16:46

I am sitting here "in my free time coding for fun" with hexes. And it goes like this... I will tell you what it looks like in words.

1. Hexagon: it has six neighbour hexagons. It can deliver the reference for each neighbouring hex tile. It can tell you what it consists of(water ,rock, dust). It can connect itself to others and vice versa. It can even automatically connect the others surrounding him to create a greater field and or making sure all fields can be adressed by its neighbours.
2. A building references up to three roads and three Hex Tiles. They can tell you which they are.
3. A road references two hexes and other roads when they are adressed by neighbouring tiles. They can tell which tiles that are and which roads or buildings they connect to.

This is just an idea how I would work on it.