Metadata-Version: 2.1
Name: pygalmesh
Version: 0.7.2
Summary: Python frontend to CGAL's mesh generation capabilities
Home-page: https://github.com/nschloe/pygalmesh
Author: Nico Schlömer
Author-email: nico.schloemer@gmail.com
License: GPL-3.0-or-later
Platform: UNKNOWN
Classifier: Development Status :: 4 - Beta
Classifier: License :: OSI Approved :: GNU General Public License v3 or later (GPLv3+)
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.6
Classifier: Programming Language :: Python :: 3.7
Classifier: Programming Language :: Python :: 3.8
Classifier: Topic :: Scientific/Engineering
Classifier: Topic :: Scientific/Engineering :: Mathematics
Classifier: Topic :: Scientific/Engineering :: Physics
Classifier: Topic :: Scientific/Engineering :: Visualization
Requires-Python: >=3.6
Description-Content-Type: text/markdown
Requires-Dist: meshio (<5.0.0,>=4.0.0)
Requires-Dist: numpy
Requires-Dist: pybind11 (>=2.2)
Requires-Dist: importlib-metadata ; python_version < "3.8"

<p align="center">
  <a href="https://github.com/nschloe/pygalmesh"><img alt="pygalmesh" src="https://nschloe.github.io/pygalmesh/pygalmesh-logo.svg" width="60%"></a>
  <p align="center">Create high-quality meshes with ease.</p>
</p>

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pygalmesh is a Python frontend to [CGAL](https://www.cgal.org/)'s
[2D](https://doc.cgal.org/latest/Mesh_2/index.html) and [3D mesh generation
capabilities](https://doc.cgal.org/latest/Mesh_3/index.html).  pygalmesh makes it easy
to create high-quality 2D, 3D volume meshes, periodic volume meshes, and surface meshes.

### Examples

#### 2D meshes
<img src="https://nschloe.github.io/pygalmesh/rect.svg" width="30%">

CGAL generates 2D meshes from linear contraints. 
```python
import numpy
import pygalmesh

points = numpy.array([[0.0, 0.0], [1.0, 0.0], [1.0, 1.0], [0.0, 1.0]])
constraints = [[0, 1], [1, 2], [2, 3], [3, 0]]

mesh = pygalmesh.generate_2d(points, constraints, cell_size=1.0e-1, num_lloyd_steps=10)
# mesh.points, mesh.cells
```
The quality of the mesh isn't very good, but can be improved with
[optimesh](https://github.com/nschloe/optimesh).

#### A simple ball
<img src="https://nschloe.github.io/pygalmesh/ball.png" width="30%">

```python
import pygalmesh

s = pygalmesh.Ball([0, 0, 0], 1.0)
mesh = pygalmesh.generate_mesh(s, cell_size=0.2)

# mesh.points, mesh.cells, ...
```
You can write the mesh with
<!--exdown-skip-->
```python
mesh.write("out.vtk")
```
You can use any format supported by [meshio](https://github.com/nschloe/meshio).

The mesh generation comes with many more options, described
[here](https://doc.cgal.org/latest/Mesh_3/). Try, for example,
<!--exdown-skip-->
```python
mesh = pygalmesh.generate_mesh(
    s, cell_size=0.2, edge_size=0.1, odt=True, lloyd=True, verbose=False
)
```

#### Other primitive shapes
<img src="https://nschloe.github.io/pygalmesh/tetra.png" width="30%">

pygalmesh provides out-of-the-box support for balls, cuboids, ellipsoids, tori, cones,
cylinders, and tetrahedra. Try for example
```python
import pygalmesh

s0 = pygalmesh.Tetrahedron(
    [0.0, 0.0, 0.0], [1.0, 0.0, 0.0], [0.0, 1.0, 0.0], [0.0, 0.0, 1.0]
)
mesh = pygalmesh.generate_mesh(s0, cell_size=0.1, edge_size=0.1)
```

#### Domain combinations
<img src="https://nschloe.github.io/pygalmesh/ball-difference.png" width="30%">

Supported are unions, intersections, and differences of all domains. As mentioned above,
however, the sharp intersections between two domains are not automatically handled. Try
for example
```python
import pygalmesh

radius = 1.0
displacement = 0.5
s0 = pygalmesh.Ball([displacement, 0, 0], radius)
s1 = pygalmesh.Ball([-displacement, 0, 0], radius)
u = pygalmesh.Difference(s0, s1)
```
To sharpen the intersection circle, add it as a feature edge polygon line, e.g.,
```python
import numpy
import pygalmesh

radius = 1.0
displacement = 0.5
s0 = pygalmesh.Ball([displacement, 0, 0], radius)
s1 = pygalmesh.Ball([-displacement, 0, 0], radius)
u = pygalmesh.Difference(s0, s1)

# add circle
a = numpy.sqrt(radius ** 2 - displacement ** 2)
edge_size = 0.15
n = int(2 * numpy.pi * a / edge_size)
circ = [
    [0.0, a * numpy.cos(i * 2 * numpy.pi / n), a * numpy.sin(i * 2 * numpy.pi / n)]
    for i in range(n)
]
circ.append(circ[0])

mesh = pygalmesh.generate_mesh(
    u,
    feature_edges=[circ],
    cell_size=0.15,
    edge_size=edge_size,
    facet_angle=25,
    facet_size=0.15,
    cell_radius_edge_ratio=2.0,
)
```
Note that the length of the polygon legs are kept in sync with the `edge_size` of the
mesh generation. This makes sure that it fits in nicely with the rest of the mesh.

#### Domain deformations
<img src="https://nschloe.github.io/pygalmesh/egg.png" width="30%">

You can of course translate, rotate, scale, and stretch any domain. Try, for example,
```python
import pygalmesh

s = pygalmesh.Stretch(pygalmesh.Ball([0, 0, 0], 1.0), [1.0, 2.0, 0.0])

mesh = pygalmesh.generate_mesh(s, cell_size=0.1)
```

#### Extrusion of 2D polygons
<img src="https://nschloe.github.io/pygalmesh/triangle-rotated.png" width="30%">

pygalmesh lets you extrude any polygon into a 3D body. It even supports rotation
alongside!
```python
import pygalmesh

p = pygalmesh.Polygon2D([[-0.5, -0.3], [0.5, -0.3], [0.0, 0.5]])
edge_size = 0.1
domain = pygalmesh.Extrude(p, [0.0, 0.0, 1.0], 0.5 * 3.14159265359, edge_size)
mesh = pygalmesh.generate_mesh(
    domain, cell_size=0.1, edge_size=edge_size, verbose=False
)
```
Feature edges are automatically preserved here, which is why an edge length needs to be
given to `pygalmesh.Extrude`.

#### Rotation bodies
<img src="https://nschloe.github.io/pygalmesh/circle-rotate-extr.png" width="30%">

Polygons in the x-z-plane can also be rotated around the z-axis to yield a rotation
body.
```python
import pygalmesh

p = pygalmesh.Polygon2D([[0.5, -0.3], [1.5, -0.3], [1.0, 0.5]])
edge_size = 0.1
domain = pygalmesh.RingExtrude(p, edge_size)
mesh = pygalmesh.generate_mesh(
    domain, cell_size=0.1, edge_size=edge_size, verbose=False
)
```

#### Your own custom level set function
<img src="https://nschloe.github.io/pygalmesh/heart.png" width="30%">

If all of the variety is not enough for you, you can define your own custom level set
function. You simply need to subclass `pygalmesh.DomainBase` and specify a function,
e.g.,
```python
import pygalmesh


class Heart(pygalmesh.DomainBase):
    def __init__(self):
        super().__init__()

    def eval(self, x):
        return (
            (x[0] ** 2 + 9.0 / 4.0 * x[1] ** 2 + x[2] ** 2 - 1) ** 3
            - x[0] ** 2 * x[2] ** 3
            - 9.0 / 80.0 * x[1] ** 2 * x[2] ** 3
        )

    def get_bounding_sphere_squared_radius(self):
        return 10.0


d = Heart()
mesh = pygalmesh.generate_mesh(d, cell_size=0.1)
```
Note that you need to specify the square of a bounding sphere radius, used as an input
to CGAL's mesh generator.


#### Local refinement
<img src="https://nschloe.github.io/pygalmesh/ball-local-refinement.png" width="30%">

Use `generate_mesh` with a `SizingFieldBase` object as `cell_size`.
```python
import numpy
import pygalmesh

# define a cell_size function
class Field(pygalmesh.SizingFieldBase):
    def eval(self, x):
        return abs(numpy.sqrt(numpy.dot(x, x)) - 0.5) / 5 + 0.025


mesh = pygalmesh.generate_mesh(
    pygalmesh.Ball([0.0, 0.0, 0.0], 1.0),
    facet_angle=30,
    facet_size=0.1,
    facet_distance=0.025,
    cell_radius_edge_ratio=2,
    cell_size=Field(),
)
```

#### Surface meshes

If you're only after the surface of a body, pygalmesh has `generate_surface_mesh` for
you. It offers fewer options (obviously, `cell_size` is gone), but otherwise works the
same way:
```python
import pygalmesh

s = pygalmesh.Ball([0, 0, 0], 1.0)
mesh = pygalmesh.generate_surface_mesh(
    s, angle_bound=30, radius_bound=0.1, distance_bound=0.1
)
```
Refer to [CGAL's
documention](https://doc.cgal.org/latest/Surface_mesher/index.html) for the
options.

#### Periodic volume meshes
<img src="https://nschloe.github.io/pygalmesh/periodic.png" width="30%">

pygalmesh also interfaces CGAL's [3D periodic
mesh generation](https://doc.cgal.org/latest/Periodic_3_mesh_3/index.html). Besides a
domain, one needs to specify a bounding box, and optionally the number of copies in the
output (1, 2, 4, or 8). Example:
```python
import numpy
import pygalmesh


class Schwarz(pygalmesh.DomainBase):
    def __init__(self):
        super().__init__()

    def eval(self, x):
        x2 = numpy.cos(x[0] * 2 * numpy.pi)
        y2 = numpy.cos(x[1] * 2 * numpy.pi)
        z2 = numpy.cos(x[2] * 2 * numpy.pi)
        return x2 + y2 + z2


mesh = pygalmesh.generate_periodic_mesh(
    Schwarz(),
    [0, 0, 0, 1, 1, 1],
    cell_size=0.05,
    facet_angle=30,
    facet_size=0.05,
    facet_distance=0.025,
    cell_radius_edge_ratio=2.0,
    number_of_copies_in_output=4,
    # odt=True,
    # lloyd=True,
    verbose=False,
)
```

#### Volume meshes from surface meshes
<img src="https://nschloe.github.io/pygalmesh/elephant.png" width="30%">

If you have a surface mesh at hand (like
[elephant.vtu](http://nschloe.github.io/pygalmesh/elephant.vtu)), pygalmesh generates a
volume mesh on the command line via
```
pygalmesh-volume-from-surface elephant.vtu out.vtk --cell-size 1.0 --odt
```
(See `pygalmesh-volume-from-surface -h` for all options.)

In Python, do
<!--exdown-skip-->
```python
import pygalmesh

mesh = pygalmesh.generate_volume_mesh_from_surface_mesh(
    "elephant.vtu",
    facet_angle=25.0,
    facet_size=0.15,
    facet_distance=0.008,
    cell_radius_edge_ratio=3.0,
    verbose=False,
)
```

#### Meshes from INR voxel files
<img src="https://nschloe.github.io/pygalmesh/liver.png" width="30%">

It is also possible to generate meshes from INR voxel files, e.g.,
[skull_2.9.inr](https://github.com/nschloe/pygalmesh/raw/gh-pages/skull_2.9.inr)
either on the command line
```
pygalmesh-from-inr skull_2.9.inr out.vtu --cell-size 5.0 --odt
```
(see `pygalmesh-from-inr -h` for all options) or from Python
<!--exdown-skip-->
```python
import pygalmesh

mesh = pygalmesh.generate_from_inr(
    "skull_2.9.inr",
    cell_size=5.0,
    verbose=False,
)
```

#### Meshes from numpy arrays representing 3D images
<img src="https://nschloe.github.io/pygalmesh/phantom.png" width="30%">

pygalmesh can help generating unstructed meshes from 3D numpy arrays.

The code below creates a mesh from the 3D breast phantom from [Lou et
al](http://biomedicaloptics.spiedigitallibrary.org/article.aspx?articleid=2600985)
available
[here](https://wustl.app.box.com/s/rqivtin0xcofjwlkz43acou8jknsbfx8/file/127108205145).
The phantom comprises four tissue types (background, fat, fibrograndular, skin, vascular
tissues). The generated mesh conforms to tissues interfaces.
<!--exdown-skip-->
```python
import pygalmesh
import meshio

Nx = 722
Ny = 411
Nz = 284
h = [0.2] * 3

with open("MergedPhantom.DAT", "rb") as fid:
    vol = np.fromfile(fid, dtype=np.uint8)

vol = vol.reshape((Nx, Ny, Nz))

mesh = pygalmesh.generate_from_array(vol, h, facet_distance=0.2, cell_size=1.0)
mesh.write("breast.vtk")
```

In addition, we can specify different mesh sizes for each tissue type. The code below
sets the mesh size to  *1 mm* for the skin tissue (label `4`), *0.5 mm* for the vascular
tissue (label `5`), and *2 mm* for all other tissues (`default`).

<!--exdown-skip-->
```python
mesh = pygalmesh.generate_from_array(
    vol, h, facet_distance=0.2, cell_size={"default": 2.0, 4: 1.0, 5: 0.5}
)
mesh.write("breast_adapted.vtk")
```

#### Surface remeshing
<img src="https://nschloe.github.io/pygalmesh/lion-head0.png" width="100%"> | <img src="https://nschloe.github.io/pygalmesh/lion-head1.png" width="100%">
:---:|:---:|

pygalmesh can help remeshing an existing surface mesh, e.g.,
[`lion-head.off`](https://github.com/nschloe/pygalmesh/raw/gh-pages/lion-head.off). On
the command line, use

```
pygalmesh-remesh-surface lion-head.off out.vtu -e 0.025 -a 25 -s 0.1 -d 0.001
```
(see `pygalmesh-remesh-surface -h` for all options) or from Python
<!--exdown-skip-->
```python
import pygalmesh

mesh = pygalmesh.remesh_surface(
    "lion-head.off",
    edge_size=0.025,
    facet_angle=25,
    facet_size=0.1,
    facet_distance=0.001,
    verbose=False,
)
```

### Installation

For installation, pygalmesh needs [CGAL](https://www.cgal.org/) and
[Eigen](http://eigen.tuxfamily.org/index.php?title=Main_Page) installed on your
system. They are typically available on your Linux distribution, e.g., on
Ubuntu
```
sudo apt install libcgal-dev libeigen3-dev
```
After that, pygalmesh can be [installed from the Python Package
Index](https://pypi.org/project/pygalmesh/), so with
```
pip install -U pygalmesh
```
you can install/upgrade.

#### Manual installation

For manual installation (if you're a developer or just really keen on getting
the bleeding edge version of pygalmesh), there are two possibilities:

 * Get the sources, type `python3 setup.py install`. This does the trick
   most the time.
 * As a fallback, there's a CMake-based installation. Simply go `cmake
   /path/to/sources/` and `make`.

### Testing

To run the pygalmesh unit tests, check out this repository and type
```
pytest
```


### Background

CGAL offers two different approaches for mesh generation:

1. Meshes defined implicitly by level sets of functions.
2. Meshes defined by a set of bounding planes.

pygalmesh provides a front-end to the first approach, which has the following advantages
and disadvantages:

* All boundary points are guaranteed to be in the level set within any specified
  residual. This results in smooth curved surfaces.
* Sharp intersections of subdomains (e.g., in unions or differences of sets) need to be
  specified manually (via feature edges, see below), which can be tedious.

On the other hand, the bounding-plane approach (realized by
[mshr](https://bitbucket.org/fenics-project/mshr)), has the following properties:

* Smooth, curved domains are approximated by a set of bounding planes, resulting in more
  of less visible edges.
* Intersections of domains can be computed automatically, so domain unions etc.  have
  sharp edges where they belong.

See [here](https://github.com/nschloe/awesome-scientific-computing#meshing) for other
mesh generation tools.


### License

pygalmesh is published under the [GPLv3 license](https://www.gnu.org/licenses/gpl-3.0.en.html).


