def to_inch(self): if self._units == 'metric': self._units = 'inch' self.pitch = inch(self.pitch) self.error_range = inch(self.error_range) for statement in self.statements: statement.to_inch() for path in self.paths: path.to_inch()
def to_inch(self): if self._units == 'metric': self._units = 'inch' self.pitch = inch(self.pitch) self.width = inch(self.width) self.error_range = inch(self.error_range) for path in self.open_paths: path.to_inch() for path in self.close_paths: path.to_inch()
def __init__(self, statements, units, dcode=10, draw_mode=None): if draw_mode == None: draw_mode = DxfFile.DM_LINE self._units = units self.dcode = dcode self.draw_mode = draw_mode self.pitch = inch(1) if self._units == 'inch' else 1 self.width = 0 self.error_range = inch( ACCEPTABLE_ERROR) if self._units == 'inch' else ACCEPTABLE_ERROR self.statements = statements self.paths = generate_closed_paths(self.statements, self.error_range)
def to_inch(self): for node in self.nodes: node.position = tuple(map(inch, node.position)) node.radius = inch( node.radius) if node.radius is not None else None if node.center_offset is not None: node.center_offset = tuple(map(inch, node.center_offset))
def to_inch(self): if self.units == 'metric': self.header.to_inch() self.aperture.to_inch() self.statements.to_inch() self.pitch = inch(self.pitch) self.units = 'inch'
def test_to_inch(self): o = self.c1_exp.to_inch().optimize() self.assertEqual(o.value, inch(self.c1)) o = self.v1_exp.to_inch().optimize() self.assertTrue(isinstance(o, AMOperatorExpression)) self.assertEqual(o.op, Op.DIV) o = self.op_exp.to_inch().optimize() self.assertTrue(isinstance(o, AMOperatorExpression)) self.assertEqual(o.op, Op.DIV)
def to_inch(self): if self.units == 'inch': return self.units = 'inch' if self.shape in self.GEOMETRIES: indices = self.GEOMETRIES[self.shape] self.modifiers = [tuple([ inch(self.modifiers[0][i]) if i in indices else self.modifiers[0][i] \ for i in range(len(self.modifiers[0])) ])]
def __init__(self, statements, units, dcode=10, draw_mode=None, fill_mode=None): if draw_mode is None: draw_mode = DxfFile.DM_LINE if fill_mode is None: fill_mode = DxfFile.FM_TURN_OVER self._units = units self.dcode = dcode self.draw_mode = draw_mode self.fill_mode = fill_mode self.pitch = inch(1) if self._units == 'inch' else 1 self.width = 0 self.error_range = inch(ACCEPTABLE_ERROR) if self._units == 'inch' else ACCEPTABLE_ERROR self.statements = list(filter( lambda i: not (isinstance(i, DxfLineStatement) and \ is_equal_point(i.start, i.end, self.error_range)), statements )) self.close_paths, self.open_paths = generate_paths(self.statements, self.error_range) self.sorted_close_paths = [] self.polarity = True # True means dark, False means clear
def to_inch(self): self.error_range = inch(self.error_range)
def to_inch(self): self.start = (inch(self.start[0]), inch(self.start[1])) self.end = (inch(self.end[0]), inch(self.end[1]))
def to_inch(self): self.start = (inch(self.start[0]), inch(self.start[1])) self.end = (inch(self.end[0]), inch(self.end[1])) for idx in range(0, len(self.entity.points)): self.entity.points[idx] = (inch(self.entity.points[idx][0]), inch(self.entity.points[idx][1]))
def to_inch(self): self.radius = inch(self.radius) self.center = (inch(self.center[0]), inch(self.center[1])) self.start = (inch(self.start[0]), inch(self.start[1])) self.end = (inch(self.end[0]), inch(self.end[1]))
def to_inch(self): self.radius = inch(self.radius) self.center = (inch(self.center[0]), inch(self.center[1]))
def test_rectangle_inch(self): outfile = os.path.join( self.OUTDIR, self.OUTPREFIX + 'rectangle_inch.gtl') dxf = gerberex.DxfFile.rectangle(width=inch(10), height=inch(10), units='inch') dxf.write(outfile) self._checkResult(outfile)
def to_inch(self): self.error_range = inch(self.error_range) for statement in self.statements: statement.to_inch()
def to_inch(self): if self.units == 'metric': super(ExcellonFileEx, self).to_inch() for hit in self.hits: hit.position = (inch(hit.position[0]), inch(hit.position[1]))