import math from dataclasses import dataclass, replace from aperture_macros.parse import GenericMacros import graphic_primitives as gp def _flash_hole(self, x, y): if self.hole_rect_h is not None: return self.primitives(x, y), Rectangle((x, y), (self.hole_dia, self.hole_rect_h), rotation=self.rotation, polarity_dark=False) else: return self.primitives(x, y), Circle((x, y), self.hole_dia, polarity_dark=False) class Aperture: @property def hole_shape(self): if self.hole_rect_h is not None: return 'rect' else: return 'circle' @property def hole_size(self): return (self.hole_dia, self.hole_rect_h) @property def params(self): return dataclasses.astuple(self) def flash(self, x, y): return self.primitives(x, y) @parameter def equivalent_width(self): raise ValueError('Non-circular aperture used in interpolation statement, line width is not properly defined.') def to_gerber(self): # Hack: The standard aperture shapes C, R, O do not have a rotation parameter. To make this API easier to use, # we emulate this parameter. Our circle, rectangle and oblong classes below have a rotation parameter. Only at # export time during to_gerber, this parameter is evaluated. actual_inst = self._rotated() params = 'X'.join(f'{par:.4}' for par in actual_inst.params) return f'{actual_inst.aperture.gerber_shape_code},{params}' def __eq__(self, other): return hasattr(other, to_gerber) and self.to_gerber() == other.to_gerber() def _rotate_hole_90(self): if self.hole_rect_h is None: return {'hole_dia': self.hole_dia, 'hole_rect_h': None} else: return {'hole_dia': self.hole_rect_h, 'hole_rect_h': self.hole_dia} @dataclass(frozen=True) class CircleAperture(Aperture): gerber_shape_code = 'C' human_readable_shape = 'circle' diameter : float hole_dia : float = 0 hole_rect_h : float = None rotation : float = 0 # radians; for rectangular hole; see hack in Aperture.to_gerber def primitives(self, x, y, rotation): return [ gp.Circle(x, y, self.diameter/2) ] def __str__(self): return f'' flash = _flash_hole @parameter def equivalent_width(self): return self.diameter def rotated(self): if math.isclose(rotation % (2*math.pi), 0) or self.hole_rect_h is None: return self else: return self.to_macro(self.rotation) def to_macro(self): return ApertureMacroInstance(GenericMacros.circle, *self.params) @dataclass(frozen=True) class RectangleAperture(Aperture): gerber_shape_code = 'R' human_readable_shape = 'rect' w : float h : float hole_dia : float = 0 hole_rect_h : float = None rotation : float = 0 # radians def primitives(self, x, y): return [ gp.Rectangle(x, y, self.w, self.h, rotation=self.rotation) ] def __str__(self): return f'' flash = _flash_hole @parameter def equivalent_width(self): return math.sqrt(self.w**2 + self.h**2) def _rotated(self): if math.isclose(self.rotation % math.pi, 0): return self elif math.isclose(self.rotation % math.pi, math.pi/2): return replace(self, w=self.h, h=self.w, **self._rotate_hole_90()) else: # odd angle return self.to_macro() def to_macro(self): return ApertureMacroInstance(GenericMacros.rect, *self.params) @dataclass(frozen=True) class ObroundAperture(Aperture): gerber_shape_code = 'O' human_readable_shape = 'obround' w : float h : float hole_dia : float = 0 hole_rect_h : float = None rotation : float = 0 def primitives(self, x, y): return [ gp.Obround(x, y, self.w, self.h, rotation=self.rotation) ] def __str__(self): return f'' flash = _flash_hole def _rotated(self): if math.isclose(self.rotation % math.pi, 0): return self elif math.isclose(self.rotation % math.pi, math.pi/2): return replace(self, w=self.h, h=self.w, **self._rotate_hole_90()) else: return self.to_macro() def to_macro(self, rotation:'radians'=0): # generic macro only supports w > h so flip x/y if h > w inst = self if self.w > self.h else replace(self, w=self.h, h=self.w, **_rotate_hole_90(self)) return ApertureMacroInstance(GenericMacros.obround, *inst.params) @dataclass(frozen=True) class PolygonAperture(Aperture): gerber_shape_code = 'P' diameter : float n_vertices : int rotation : float = 0 hole_dia : float = 0 def primitives(self, x, y): return [ gp.RegularPolygon(x, y, diameter, n_vertices, rotation=self.rotation) ] def __str__(self): return f'<{self.n_vertices}-gon aperture d={self.diameter:.3}' flash = _flash_hole def _rotated(self): self.rotation %= (2*math.pi / self.n_vertices) return self def to_macro(self): return ApertureMacroInstance(GenericMacros.polygon, *self.params) class ApertureMacroInstance(Aperture): params : [float] rotation : float = 0 def __init__(self, macro, *parameters): self.params = parameters self._primitives = macro.to_graphic_primitives(parameters) self.macro = macro @property def gerber_shape_code(self): return self.macro.name def primitives(self, x, y): # FIXME return graphical primitives not macro primitives here return [ primitive.with_offset(x, y).rotated(self.rotation, cx=0, cy=0) for primitive in self._primitives ] def _rotated(self): if math.isclose(self.rotation % (2*math.pi), 0): return self else: return self.to_macro() def to_macro(self): return type(self)(self.macro.rotated(self.rotation), self.params) def __eq__(self, other): return hasattr(other, 'macro') and self.macro == other.macro and \ hasattr(other, 'params') and self.params == other.params and \ hasattr(other, 'rotation') and self.rotation == other.rotation