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#! /usr/bin/env python
# -*- coding: utf-8 -*-
# copyright 2014 Hamilton Kibbe <ham@hamiltonkib.be>
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
# http://www.apache.org/licenses/LICENSE-2.0
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import os
import re
from collections import namedtuple
from . import common
from .excellon import ExcellonFile
from .ipc356 import IPCNetlist
Hint = namedtuple('Hint', 'layer ext name')
hints = [
Hint(layer='top',
ext=['gtl', 'cmp', 'top', ],
name=['art01', 'top', 'GTL', 'layer1', 'soldcom', 'comp', 'F.Cu', ]
),
Hint(layer='bottom',
ext=['gbl', 'sld', 'bot', 'sol', 'bottom', ],
name=['art02', 'bottom', 'bot', 'GBL', 'layer2', 'soldsold', 'B.Cu', ]
),
Hint(layer='internal',
ext=['in', 'gt1', 'gt2', 'gt3', 'gt4', 'gt5', 'gt6', 'g1',
'g2', 'g3', 'g4', 'g5', 'g6', ],
name=['art', 'internal', 'pgp', 'pwr', 'gp1', 'gp2', 'gp3', 'gp4',
'gt5', 'gp6', 'gnd', 'ground', 'In1.Cu', 'In2.Cu', 'In3.Cu', 'In4.Cu']
),
Hint(layer='topsilk',
ext=['gto', 'sst', 'plc', 'ts', 'skt', 'topsilk', ],
name=['sst01', 'topsilk', 'silk', 'slk', 'sst', 'F.SilkS']
),
Hint(layer='bottomsilk',
ext=['gbo', 'ssb', 'pls', 'bs', 'skb', 'bottomsilk', 'B.SilkS'],
name=['bsilk', 'ssb', 'botsilk', ]
),
Hint(layer='topmask',
ext=['gts', 'stc', 'tmk', 'smt', 'tr', 'topmask', ],
name=['sm01', 'cmask', 'tmask', 'mask1', 'maskcom', 'topmask',
'mst', 'F.Mask',]
),
Hint(layer='bottommask',
ext=['gbs', 'sts', 'bmk', 'smb', 'br', 'bottommask', ],
name=['sm', 'bmask', 'mask2', 'masksold', 'botmask', 'msb', 'B.Mask',]
),
Hint(layer='toppaste',
ext=['gtp', 'tm', 'toppaste', ],
name=['sp01', 'toppaste', 'pst', 'F.Paste']
),
Hint(layer='bottompaste',
ext=['gbp', 'bm', 'bottompaste', ],
name=['sp02', 'botpaste', 'psb', 'B.Paste', ]
),
Hint(layer='outline',
ext=['gko', 'outline', ],
name=['BDR', 'border', 'out', 'Edge.Cuts', ]
),
Hint(layer='ipc_netlist',
ext=['ipc'],
name=[],
),
Hint(layer='drawing',
ext=['fab'],
name=['assembly drawing', 'assembly', 'fabrication', 'fab drawing']
),
]
def load_layer(filename):
return PCBLayer.from_cam(common.read(filename))
def load_layer_data(data, filename=None):
return PCBLayer.from_cam(common.loads(data, filename))
def guess_layer_class(filename):
try:
directory, name = os.path.split(filename)
name, ext = os.path.splitext(name.lower())
for hint in hints:
patterns = [r'^(\w*[.-])*{}([.-]\w*)?$'.format(x) for x in hint.name]
if ext[1:] in hint.ext or any(re.findall(p, name, re.IGNORECASE) for p in patterns):
return hint.layer
except:
pass
return 'unknown'
def sort_layers(layers, from_top=True):
layer_order = ['outline', 'toppaste', 'topsilk', 'topmask', 'top',
'internal', 'bottom', 'bottommask', 'bottomsilk',
'bottompaste']
append_after = ['drill', 'drawing']
output = []
internal_layers = list(sorted([layer for layer in layers
if layer.layer_class == 'internal']))
for layer_class in layer_order:
if layer_class == 'internal':
output += internal_layers
else:
for layer in layers:
if layer.layer_class == layer_class:
output.append(layer)
if not from_top:
output = list(reversed(output))
for layer_class in append_after:
for layer in layers:
if layer.layer_class == layer_class:
output.append(layer)
return output
class PCBLayer(object):
""" Base class for PCB Layers
Parameters
----------
source : CAMFile
CAMFile representing the layer
Attributes
----------
filename : string
Source Filename
"""
@classmethod
def from_cam(cls, camfile):
filename = camfile.filename
layer_class = guess_layer_class(filename)
if isinstance(camfile, ExcellonFile) or (layer_class == 'drill'):
return DrillLayer.from_cam(camfile)
elif layer_class == 'internal':
return InternalLayer.from_cam(camfile)
if isinstance(camfile, IPCNetlist):
layer_class = 'ipc_netlist'
return cls(filename, layer_class, camfile)
def __init__(self, filename=None, layer_class=None, cam_source=None, **kwargs):
super(PCBLayer, self).__init__(**kwargs)
self.filename = filename
self.layer_class = layer_class
self.cam_source = cam_source
self.surface = None
self.primitives = cam_source.primitives if cam_source is not None else []
@property
def bounds(self):
if self.cam_source is not None:
return self.cam_source.bounds
else:
return None
def __repr__(self):
return '<PCBLayer: {}>'.format(self.layer_class)
class DrillLayer(PCBLayer):
@classmethod
def from_cam(cls, camfile):
return cls(camfile.filename, camfile)
def __init__(self, filename=None, cam_source=None, layers=None, **kwargs):
super(DrillLayer, self).__init__(filename, 'drill', cam_source, **kwargs)
self.layers = layers if layers is not None else ['top', 'bottom']
class InternalLayer(PCBLayer):
@classmethod
def from_cam(cls, camfile):
filename = camfile.filename
try:
order = int(re.search(r'\d+', filename).group())
except AttributeError:
order = 0
return cls(filename, camfile, order)
def __init__(self, filename=None, cam_source=None, order=0, **kwargs):
super(InternalLayer, self).__init__(filename, 'internal', cam_source, **kwargs)
self.order = order
def __eq__(self, other):
if not hasattr(other, 'order'):
raise TypeError()
return (self.order == other.order)
def __ne__(self, other):
if not hasattr(other, 'order'):
raise TypeError()
return (self.order != other.order)
def __gt__(self, other):
if not hasattr(other, 'order'):
raise TypeError()
return (self.order > other.order)
def __lt__(self, other):
if not hasattr(other, 'order'):
raise TypeError()
return (self.order < other.order)
def __ge__(self, other):
if not hasattr(other, 'order'):
raise TypeError()
return (self.order >= other.order)
def __le__(self, other):
if not hasattr(other, 'order'):
raise TypeError()
return (self.order <= other.order)
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