Cosplay/nhf/utils.py

225 lines
6.0 KiB
Python

"""
Utility functions for cadquery objects
"""
import math
import functools
import cadquery as Cq
from nhf import Role
from typing import Union, Tuple, cast
from nhf.materials import KEY_ITEM, KEY_MATERIAL
# Bug fixes
def _subloc(self, name: str) -> Tuple[Cq.Location, str]:
"""
Calculate relative location of an object in a subassembly.
Returns the relative positions as well as the name of the top assembly.
"""
rv = Cq.Location()
obj = self.objects[name]
name_out = name
if obj not in self.children and obj is not self:
locs = []
while not obj.parent is self:
locs.append(obj.loc)
obj = cast(Cq.Assembly, obj.parent)
name_out = obj.name
rv = functools.reduce(lambda l1, l2: l2 * l1, locs)
return (rv, name_out)
Cq.Assembly._subloc = _subloc
### Vector arithmetic
def location_sub(self: Cq.Location, rhs: Cq.Location) -> Cq.Vector:
(x1, y1, z1), _ = self.toTuple()
(x2, y2, z2), _ = rhs.toTuple()
return Cq.Vector(x1 - x2, y1 - y2, z1 - z2)
Cq.Location.__sub__ = location_sub
def from2d(x: float, y: float, rotate: float=0.0) -> Cq.Location:
return Cq.Location((x, y, 0), (0, 0, 1), rotate)
Cq.Location.from2d = from2d
def rot2d(angle: float) -> Cq.Location:
return Cq.Location((0, 0, 0), (0, 0, 1), angle)
Cq.Location.rot2d = rot2d
def is2d(self: Cq.Location) -> bool:
(_, _, z), (rx, ry, _) = self.toTuple()
return z == 0 and rx == 0 and ry == 0
Cq.Location.is2d = is2d
def to2d(self: Cq.Location) -> Tuple[Tuple[float, float], float]:
"""
Returns position and angle
"""
(x, y, z), (rx, ry, rz) = self.toTuple()
assert z == 0
assert rx == 0
assert ry == 0
return (x, y), rz
Cq.Location.to2d = to2d
def to2d_pos(self: Cq.Location) -> Tuple[float, float]:
"""
Returns position and angle
"""
(x, y), _ = self.to2d()
return x, y
Cq.Location.to2d_pos = to2d_pos
def to2d_rot(self: Cq.Location) -> float:
"""
Returns position and angle
"""
_, r = self.to2d()
return r
Cq.Location.to2d_rot = to2d_rot
def with_angle_2d(self: Cq.Location, angle: float) -> Tuple[float, float]:
"""
Returns position and angle
"""
x, y = self.to2d_pos()
return Cq.Location.from2d(x, y, angle)
Cq.Location.with_angle_2d = with_angle_2d
def flip_x(self: Cq.Location) -> Cq.Location:
(x, y), a = self.to2d()
return Cq.Location.from2d(-x, y, 90 - a)
Cq.Location.flip_x = flip_x
def flip_y(self: Cq.Location) -> Cq.Location:
(x, y), a = self.to2d()
return Cq.Location.from2d(x, -y, -a)
Cq.Location.flip_y = flip_y
### Tags
def tagPoint(self, tag: str):
"""
Adds a vertex that can be used in `Point` constraints.
"""
vertex = Cq.Vertex.makeVertex(0, 0, 0)
self.eachpoint(vertex.moved, useLocalCoordinates=True).tag(tag)
Cq.Workplane.tagPoint = tagPoint
def tagPlane(self, tag: str,
direction: Union[str, Cq.Vector, Tuple[float, float, float]] = '+Z'):
"""
Adds a phantom `Cq.Edge` in the given location which can be referenced in a
`Axis`, `Point`, or `Plane` constraint.
"""
if isinstance(direction, str):
x, y, z = 0, 0, 0
assert len(direction) == 2
sign, axis = direction
if axis in ('z', 'Z'):
z = 1
elif axis in ('y', 'Y'):
y = 1
elif axis in ('x', 'X'):
x = 1
else:
assert False, "Axis must be one of x,y,z"
if sign == '+':
sign = 1
elif sign == '-':
sign = -1
else:
assert False, "Sign must be one of +/-"
v = Cq.Vector(x, y, z) * sign
else:
v = Cq.Vector(direction)
edge = Cq.Edge.makeLine(v * (-1), v)
return self.eachpoint(edge.located, useLocalCoordinates=True).tag(tag)
Cq.Workplane.tagPlane = tagPlane
def make_sphere(r: float = 2) -> Cq.Solid:
"""
Makes a full sphere. The default function makes a hemisphere
"""
return Cq.Solid.makeSphere(r, angleDegrees1=-90)
def make_arrow(size: float = 2) -> Cq.Workplane:
cone = Cq.Solid.makeCone(
radius1 = size,
radius2 = 0,
height=size)
result = (
Cq.Workplane("XY")
.cylinder(radius=size / 2, height=size, centered=(True, True, False))
.union(cone.located(Cq.Location((0, 0, size))))
)
result.faces("<Z").tag("dir_rev")
return result
def to_marker_name(tag: str) -> str:
return tag.replace("?", "__T").replace("/", "__Z") + "_marker"
COLOR_MARKER = Cq.Color(0, 1, 1, 1)
def mark_point(self: Cq.Assembly,
tag: str,
size: float = 2,
color: Cq.Color = COLOR_MARKER) -> Cq.Assembly:
"""
Adds a marker to make a point visible
"""
name = to_marker_name(tag)
return (
self
.add(make_sphere(size), name=name, color=color)
.constrain(tag, name, "Point")
)
Cq.Assembly.markPoint = mark_point
def mark_plane(self: Cq.Assembly,
tag: str,
size: float = 2,
color: Cq.Color = COLOR_MARKER) -> Cq.Assembly:
"""
Adds a marker to make a plane visible
"""
name = to_marker_name(tag)
return (
self
.add(make_arrow(size), name=name, color=color)
.constrain(tag, f"{name}?dir_rev", "Plane", param=180)
)
Cq.Assembly.markPlane = mark_plane
def get_abs_location(self: Cq.Assembly,
tag: str) -> Cq.Location:
name, shape = self._query(tag)
loc_self = shape.location()
loc_parent, _ = self._subloc(name)
loc = loc_parent * loc_self
return loc
Cq.Assembly.get_abs_location = get_abs_location
# Tallying functions
def total_mass(self: Cq.Assembly) -> float:
"""
Calculates the total mass in units of g
"""
total = 0.0
for _, a in self.traverse():
if item := a.metadata.get(KEY_ITEM):
total += item.mass
elif material := a.metadata.get(KEY_MATERIAL):
vol = a.toCompound().Volume()
total += (vol / 1000) * material.density
return total
Cq.Assembly.total_mass = total_mass