Tessellate your favorite 3D surfaces (technically, 2D manifolds) with triangles, hexagons, or a number of other curated tiling types!
A nascent Inkscape extension to create tiling patterns: https://github.com/cwant/inkscape-tiling-extension
You can find a Blender (3.6) pull request to add support for Tessagon in the "XYZ function" addon here: https://projects.blender.org/blender/blender-addons/pulls/104726
Check out my presentation on the creation of Tessagon as an open source Python project here: https://cwant.github.io/python-os-presentation (or watch on YouTube)
A demo of using Tessagon with Inkscape Simple Scripting can be found here.
Check out the repository and look in the demo
directory.
- Blender: you'll find a blender file and
tessagon_blender_demo.py
which creates the meshes in the demo. The demo has examples of each tessagon class, and an example that uses tessagon with one of my other projects, wire_skin. - VTK: Take a look at
tessagon_vtk_demo.py
for a script that creates all of the current tessagon classes.
This software may also be installed via pip:
python3 -m pip install tessagon
or
pip3 install tessagon
Three things are needed to use tessagon to tessellate the surface of a 2D-manifold (or more accurately, a patch on a 2D-manifold in 3-space):
-
Tessagon provides a bunch of classes (subclasses of a class called
Tessagon
) that will tessellate a portion of UV-space with mesh patterns. Parameters provide the details of the bounds in UV-space, the resolution of the tiling, whether the tiling is cyclic, whether a cyclic domain "twists" (think a topological identification space, like a Mobius strip or a Klein bottle), whether it is rotated, etc. These classes are in thetessagon.types
module. -
The programmer must provide a formula that describes the shape of surface of the 3-dimensional object to create. This function maps two-dimensional space (also known as UV-space) into 3-dimensional space. The tiling happens in the input two dimensional space, and the function maps the tiling onto the surface of the 3-dimensional shape. There are some demo functions in
tessagon.misc.shapes
, such as torii (a.k.a. donuts), spheres, cylinders, etc. -
Finally, an adaptor is chosen to create a mesh in a supported 3D software package. Currently Blender and VTK are supported applications. There is an adaptor that writes an SVG group to a string, with various options (root SVG node, style options). There is also a generic
ListAdaptor
that does not depend on any external package, and can aid in the creation of importers (and is useful for testing/debugging):- adaptor
BlenderAdaptor
from the moduletessagon.adaptors.blender_adaptor
. The output from the adaptor'sget_mesh
method is of typeBMesh
. - adaptor
VtkAdaptor
from the moduletessagon.adaptors.vtk_adaptor
. The output from the adaptor'sget_mesh
method is of typeVtkPolydata
. - adaptor
SvgAdaptor
from the moduletessagon.adaptors.svg_adaptor
. The output from the adaptor'sget_mesh
method is a string (by default, an SVG group of polygons). - adaptor
ListAdaptor
from the moduletessagon.adaptors.list_adaptor
. The output from the adaptor'sget_mesh
method is a dict with keysvert_list
,face_list
andcolor_list
, which point to lists of vertices, faces (as indices into the vertex list), and color indices for each face.
(Note that the
get_mesh
methods mentioned above are usually called indirectly through theTessagon
methodcreate_mesh
.) - adaptor
The reader should check out the demos, but here is some very basic usage using blender:
from tessagon.types.hex_tessagon import HexTessagon
from tessagon.adaptors.blender_adaptor import BlenderAdaptor
def my_func(u,v):
return [u, v, u**2 + v**2]
options = {
'function': my_func,
'u_range': [0.0, 1.0],
'v_range': [0.0, 1.0],
'u_num': 8,
'v_num': 20,
'u_cyclic': False,
'v_cyclic': False,
'adaptor_class' : BlenderAdaptor
}
tessagon = HexTessagon(**options)
bmesh = tessagon.create_mesh()
# Do something with the bmesh ...
Additional tessagon classes can be added by deconstructing how a tessellation fits within a rectangular patch in the plane (check out the ASCII art in each source file in tessagon.types
). The current Tessagon
subclasses include:
- SquareTessagon (8 color patterns)
- HexTessagon (2 color patterns)
- TriTessagon (3 color patterns)
- OctoTessagon (1 color pattern)
- HexTriTessagon (1 color pattern)
- HexSquareTriTessagon (1 color pattern)
- DodecaTessagon (1 color pattern)
- SquareTriTessagon (2 color patterns)
- SquareTri2Tessagon (1 color pattern)
- DodecaTriTessagon (1 color pattern)
- BigHexTriTessagon (1 color pattern, 1 extra parameter)
- RhombusTessagon (2 color patterns)
- FloretTessagon (3 color patterns)
- DissectedSquareTessagon (2 color patterns)
- DissectedTriangleTessagon (1 color pattern)
- DissectedHexQuadTessagon (2 color patterns)
- DissectedHexTriTessagon (1 color pattern)
- PentaTessagon (1 color pattern)
- Penta2Tessagon (1 color pattern)
- PythagoreanTessagon (1 color pattern)
- BrickTessagon (1 color pattern)
- WeaveTessagon (1 color pattern, 1 extra parameter)
- HexBigTriTessagon (2 color patterns)
- ZigZagTessagon (1 color pattern)
- ValemountTessagon (1 color pattern)
- CloverdaleTessagon (1 color pattern)
- StanleyParkTessagon (2 color patterns)
- IslamicHexStarsTessagon (1 color pattern)
- IslamicStarsCrossesTessagon (1 color pattern)
Each tessagon class is initialized with number of keyword options, e.g.:
from tessagon.types.dodeca_tessagon import DodecaTessagon
from tessagon.adaptors.vtk_adaptor import VtkAdaptor
tessagon = DodecaTessagon(function=my_func,
u_range=[0.0, 1.0],
v_range=[0.0, 1.0],
u_num=8,
v_num=20,
u_cyclic=True,
v_cyclic=False,
adaptor_class=VtkAdaptor)
poly_data = tessagon.create_mesh()
The create_mesh()
method creates a tessellated mesh using your provided function and the tile type corresponding to the tessagon class used. The chosen adaptor dictates the 3D data type the mesh will be (for the BlenderAdaptor
the output is BMesh
, for the VTKAdaptor
the output is vtkPolyData
).
Each Tessagon class may supply options that are specific to that class (they will be listed on the documentation page for each class).
Here are the options that are common to all Tessagon classes:
function
: the function to be used to generate the geometry. This is a function that takes two argumentsu, v
and returns a list of three items[x, y, z]
u_range
: a list with two items indicating the minimum and maximum values for u (the first argument to the function passed);v_range
: a list with two items indicating the minimum and maximum values for v (the second argument to the function passed);u_num
: the number of tiles to be created in the u-direction;v_num
: the number of tiles to be created in the v-direction;
As you work with the software, keep in mind the difference between a face and a tile. A tile is not a face! A tile is a four-sided region (often a rectangle) that holds one or more faces that form a repeated pattern. A tile often shares faces with neighboring tiles:
The source code files for each tessagon class usually contain some ASCII art that illustrates how the pattern of faces is arranged on a tile.
corners
: instead of usingu_range
andv_range
, you can also specify your domain in the uv plain as a quadrilateral by specifying the corners of the region you would like to map. This is a list of four tuples in the following order: bottom-left, bottom-right, top-left, top-right.
-
u_cyclic
: a boolean indicating whether the u-direction is cyclic (wraps around to the beginning again). You're function needs to be periodic in the u-direction for this to look nice. Note: the default for this isTrue
, so set it toFalse
if you don't want things to be cyclic -
v_cyclic
: a boolean indicating whether the v-direction is cyclic. Default:True
-
rot_factor
: this is an integer greater than zero that allows you to rotate the tiles in the UV-domain is such a way that the tiling can still be cyclic.The
rot_factor
specifies how many tiles you go across before you go up one unit (essentially the reciprocal of the slope of the grid lines. The image depicts arot_factor
of three, which generates 45 tiles (the purple interior and the blue boundary squares, each of which is blasted with the tessellation pattern when the function is applied). Here the meaning ofu_num
andv_num
are interpreted differently: whereas in the non-rotated case,u_num = 3
andv_num = 2
would yeild 6 tiles, here we have 45 tiles. Niether U nor V are cyclic in the picture; had they both been cyclic, 60 tiles whould have been generated. The interior tiles form groups of(rot_factor-1)**2
tiles (here each group is 2 x 2, for 24 total interior tiles), and each boundary sharesrot_factor x 1
tiles with it's neighbors (there are 7 such boundaries, so 21 boundary tiles).It hurt my brain developing this feature, so don't feel bad if it does't make any sense for you. Play around with it, and keep in mind that the number of tiles generated is somewhere between
u_num * v_num * (rot_factor - 1)**2
andu_num * v_num * (rot_factor**2 + 1)
(depending on which tiles have neighbors, due to periodicity), so you typically want to setu_num
andv_num
to be a lot lower than you would in the non-rotated case. -
parallelogram_vectors
: two vectors (e.g.,[[5, 1], [-1, 6]]
) that form a parallelogram to warp the tiles in a way that cyclic tiles can occur (this is more general thanrot_factor
, in fact therot_factor
implementation usesparallelogram_vectors
). This one will require it's own page to describe. -
u_twist
: this is used withv_cyclic
(note that saysv_cyclic
notu_cyclic
). As thev
values wrap around, theu
values reconnect in the opposite direction: the lowu
values connect to the highu
values, and vice versa. This allows you to make things like Möbius strips and Klein bottles. -
v_twist
: works withu_cyclic
, analogous to howu_twist
works. -
color_pattern
: some Tessagon types support some curated patterns (applying more than one material/color to the output shape). These are identified by a number (e.g.,color_pattern=2
). The number has no meaning other than as an identifier. Checkout the description of the Tessagon types above to see what color patterns exist. The values ofu_num
andv_num
may need to be tweaked to make a specific color pattern wrap correctly for cyclic tilings. -
simple_2d
(default:False
),multiplier_2d
,translate_2d
: these parameters (whensimple_2d
isTrue
) help with creating tilings in the XY-plane (2D). The "natural" undistorted aspect ratio of the tiling is preserved.multiplier_2d
(a number) allows you to scale such tilings, andtranslate_2d
(a tuple) places a corner of the tiling (either top-left or bottom-left, depending on how you handle the up direction). Withsimple_2d
, no function should be supplied to the Tessagon class.
All tesselations are found in the types
module, so check out the source code there for numerous examples. The source code documentation in hex_tessagon
is more verbose than the others, which hopefully will aid understanding.
Each tessellation involve two classes: a tile class (a child of Tile
) and a child of class Tessagon
. The Tessagon
subclass is easy (it just declares which tile class with be used), so writing the tile class will take most of your time.
(The FloretTessagon
is an exception because the math is more complex.)
There are five methods that you will want to write:
-
__init__
: typically you will want to call the constructor of the super-class. You can declare your tile class to be symmetric in either the u-direction or the v-direction, which will help you greatly if you have structured your vertices and faces well. -
init_verts
: here you define the structure of your verts in a nested hash. You can use any combination of keys you want as pathways to addressing your vertices. If you declared your class to be u-symmetric, then the wordsleft
andright
will have significance in your pathways. Creating a vertex with the wordleft
in it's pathway will automagically also create the symmetricright
vertex, halfing the amount of work you need to do. For v-symmetric tiles, the wordstop
andbottom
have meaning, in an analogous way. If the tile is both u-symmetric and v-symmetric, then each vert created that has a combination of bothleft
/right
andtop
/bottom
in it's pathway will actually create four symmetric vertices. -
init_faces
: here you define the structure of your faces in a nested hash. As with vertices, you can reduce your work by exploiting symmetry and usingleft
,right
,top
andbottom
when addressing your faces. -
calculate_verts
: here you define the locations of the vertices in the tiling, via theadd_vert
method. The method takes an array of keys to indicate which vertex is being defined, and a location expressed as au_ratio
and av_ratio
, both between 0 and 1. Au_ratio
of 0 isleft
and au_ratio
of 1 is right. Av_ratio
of 0 isbottom
and av_ratio
of 1 istop
. The symmetry of the tile may cause additional reflected vertices to be defined. Using the boolean keywordsu_boundary
,v_boundary
andcorner
, you can tell the system whether the vert is shared with neighboring tiles (this reduces the work that needs to be done, and can also keep the model topologically sound and water-tight). -
calculate_faces
: here you define the faces for the tiling using the previously defined vertices, via theadd_face
method. The method takes an array of face to indicate which face is being defined, and an array of vertex keys that indicate which vertices are in the face. These vertices are either on the current tile, or some of them can being on neighboring tiles (in which case the keys for the neighboring tile are also included). The symmetry of the tile may cause other reflected faces to be defined. Using the boolean keywordsu_boundary
,v_boundary
andcorner
, you can tell the system whether the face is shared with neighboring tiles.
Each Tessagon
subclass has some metadata attached to it (class TessagonMetadata
) that describes the properties of the tiling. This metadata will be expanded as needs require, but currently consists of information about how many color patterns the tiling has, what type (regular
, archimedean
, laves
, non_edge
, non_convex
), and what sorts of shapes are produced by instances of the class.
A nascent helper class tessagon.TessagonDiscovery
exists that can help you search for tilings with certain properties (for example, this could be used to create a menu for an external application that categorizes the tilings). The methods in the class are intended to support chaining of operations (e.g., they results returned are also of type TessagonDiscovery
, that can then be reified using the to_list
method). Some examples:
find_all = TessagonDiscovery()
find_all.to_list() # a list of all of the tessagons
regular = find_all.with_classification('regular')
regular.to_list() # The three regular tilings (HexTessagon, SquareTessagon, TriTessagon)
regular.inverse().to_list() # All tilings except for the regular ones
Checkout the test suite for more example usage.
The TessagonDiscovery
class also has a class method get_class
for fetching tessagon classes without having to deal with importing that looks like this:
tessagon_cls = TessagonDiscovery.get_class('TriTessagon')
tessagon = tessagon_cls(function=my_func, ...)
Check out my other project wire_skin
to add some interesting effects to the tessellated manifolds you create:
https://github.com/cwant/wire_skin
I primarily use Tessagon to create objects for 3D printing (on Shapeways). I tag my models with the keyword tessagon
. If you also use Shapeways to print models made with Tessagon, feel free to use this tag -- I'd be very interested to see what you make!