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|
#! /usr/bin/env python
# -*- coding: utf-8 -*-
# copyright 2014 Hamilton Kibbe <ham@hamiltonkib.be>
# Modified from parser.py by Paulo Henrique Silva <ph.silva@gmail.com>
#
# 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.
""" This module provides an RS-274-X class and parser.
"""
import copy
import json
import re
from .gerber_statements import *
from .primitives import *
from .cam import CamFile, FileSettings
def read(filename):
""" Read data from filename and return a GerberFile
Parameters
----------
filename : string
Filename of file to parse
Returns
-------
file : :class:`gerber.rs274x.GerberFile`
A GerberFile created from the specified file.
"""
return GerberParser().parse(filename)
class GerberFile(CamFile):
""" A class representing a single gerber file
The GerberFile class represents a single gerber file.
Parameters
----------
statements : list
list of gerber file statements
settings : dict
Dictionary of gerber file settings
filename : string
Filename of the source gerber file
Attributes
----------
comments: list of strings
List of comments contained in the gerber file.
size : tuple, (<float>, <float>)
Size in [self.units] of the layer described by the gerber file.
bounds: tuple, ((<float>, <float>), (<float>, <float>))
boundaries of the layer described by the gerber file.
`bounds` is stored as ((min x, max x), (min y, max y))
"""
def __init__(self, statements, settings, primitives, filename=None):
super(GerberFile, self).__init__(statements, settings, primitives, filename)
@property
def comments(self):
return [comment.comment for comment in self.statements
if isinstance(comment, CommentStmt)]
@property
def size(self):
xbounds, ybounds = self.bounds
return (xbounds[1] - xbounds[0], ybounds[1] - ybounds[0])
@property
def bounds(self):
xbounds = [0.0, 0.0]
ybounds = [0.0, 0.0]
for stmt in [stmt for stmt in self.statements
if isinstance(stmt, CoordStmt)]:
if stmt.x is not None:
if stmt.x < xbounds[0]:
xbounds[0] = stmt.x
elif stmt.x > xbounds[1]:
xbounds[1] = stmt.x
if stmt.y is not None:
if stmt.y < ybounds[0]:
ybounds[0] = stmt.y
elif stmt.y > ybounds[1]:
ybounds[1] = stmt.y
return (xbounds, ybounds)
def write(self, filename):
""" Write data out to a gerber file
"""
with open(filename, 'w') as f:
for statement in self.statements:
f.write(statement.to_gerber())
class GerberParser(object):
""" GerberParser
"""
NUMBER = r"[\+-]?\d+"
DECIMAL = r"[\+-]?\d+([.]?\d+)?"
STRING = r"[a-zA-Z0-9_+\-/!?<>”’(){}.\|&@# :]+"
NAME = r"[a-zA-Z_$][a-zA-Z_$0-9]+"
FUNCTION = r"G\d{2}"
COORD_OP = r"D[0]?[123]"
FS = r"(?P<param>FS)(?P<zero>(L|T))?(?P<notation>(A|I))X(?P<x>[0-7][0-7])Y(?P<y>[0-7][0-7])"
MO = r"(?P<param>MO)(?P<mo>(MM|IN))"
IP = r"(?P<param>IP)(?P<ip>(POS|NEG))"
LP = r"(?P<param>LP)(?P<lp>(D|C))"
AD_CIRCLE = r"(?P<param>AD)D(?P<d>\d+)(?P<shape>C)[,](?P<modifiers>[^,]*)"
AD_RECT = r"(?P<param>AD)D(?P<d>\d+)(?P<shape>R)[,]?(?P<modifiers>[^,]+)?"
AD_OBROUND = r"(?P<param>AD)D(?P<d>\d+)(?P<shape>O)[,](?P<modifiers>[^,]*)"
AD_POLY = r"(?P<param>AD)D(?P<d>\d+)(?P<shape>P)[,](?P<modifiers>[^,]*)"
AD_MACRO = r"(?P<param>AD)D(?P<d>\d+)(?P<shape>{name})[,]?(?P<modifiers>[^,]+)?".format(name=NAME)
AM = r"(?P<param>AM)(?P<name>{name})\*(?P<macro>.*)".format(name=NAME)
# begin deprecated
OF = r"(?P<param>OF)(A(?P<a>{decimal}))?(B(?P<b>{decimal}))?".format(decimal=DECIMAL)
IN = r"(?P<param>IN)(?P<name>.*)"
LN = r"(?P<param>LN)(?P<name>.*)"
# end deprecated
PARAMS = (FS, MO, IP, LP, AD_CIRCLE, AD_RECT, AD_OBROUND, AD_POLY, AD_MACRO, AM, OF, IN, LN)
PARAM_STMT = [re.compile(r"%{0}\*%".format(p)) for p in PARAMS]
COORD_STMT = re.compile((
r"(?P<function>{function})?"
r"(X(?P<x>{number}))?(Y(?P<y>{number}))?"
r"(I(?P<i>{number}))?(J(?P<j>{number}))?"
r"(?P<op>{op})?\*".format(number=NUMBER, function=FUNCTION, op=COORD_OP)))
APERTURE_STMT = re.compile(r"(G54)?D(?P<d>\d+)\*")
COMMENT_STMT = re.compile(r"G04(?P<comment>[^*]*)(\*)?")
EOF_STMT = re.compile(r"(?P<eof>M02)\*")
REGION_MODE_STMT = re.compile(r'(?P<mode>G3[67])\*')
QUAD_MODE_STMT = re.compile(r'(?P<mode>G7[45])\*')
def __init__(self):
self.settings = FileSettings()
self.statements = []
self.primitives = []
self.apertures = {}
self.current_region = None
self.x = 0
self.y = 0
self.aperture = 0
self.interpolation = 'linear'
self.direction = 'clockwise'
self.image_polarity = 'positive'
self.level_polarity = 'dark'
self.region_mode = 'off'
self.quadrant_mode = 'multi-quadrant'
self.step_and_repeat = (1, 1, 0, 0)
def parse(self, filename):
fp = open(filename, "r")
data = fp.readlines()
for stmt in self._parse(data):
self.evaluate(stmt)
self.statements.append(stmt)
return GerberFile(self.statements, self.settings, self.primitives, filename)
def dump_json(self):
stmts = {"statements": [stmt.__dict__ for stmt in self.statements]}
return json.dumps(stmts)
def dump_str(self):
s = ""
for stmt in self.statements:
s += str(stmt) + "\n"
return s
def _parse(self, data):
oldline = ''
for i, line in enumerate(data):
line = oldline + line.strip()
# skip empty lines
if not len(line):
continue
# deal with multi-line parameters
if line.startswith("%") and not line.endswith("%"):
oldline = line
continue
did_something = True # make sure we do at least one loop
while did_something and len(line) > 0:
did_something = False
# Region Mode
(mode, r) = _match_one(self.REGION_MODE_STMT, line)
if mode:
yield RegionModeStmt.from_gerber(line)
line = r
did_something = True
continue
# Quadrant Mode
(mode, r) = _match_one(self.QUAD_MODE_STMT, line)
if mode:
yield QuadrantModeStmt.from_gerber(line)
line = r
did_something = True
continue
# coord
(coord, r) = _match_one(self.COORD_STMT, line)
if coord:
yield CoordStmt.from_dict(coord, self.settings)
line = r
did_something = True
continue
# aperture selection
(aperture, r) = _match_one(self.APERTURE_STMT, line)
if aperture:
yield ApertureStmt(**aperture)
did_something = True
line = r
continue
# comment
(comment, r) = _match_one(self.COMMENT_STMT, line)
if comment:
yield CommentStmt(comment["comment"])
did_something = True
line = r
continue
# parameter
(param, r) = _match_one_from_many(self.PARAM_STMT, line)
if param:
if param["param"] == "FS":
stmt = FSParamStmt.from_dict(param)
self.settings.zero_suppression = stmt.zero_suppression
self.settings.format = stmt.format
self.settings.notation = stmt.notation
yield stmt
elif param["param"] == "MO":
stmt = MOParamStmt.from_dict(param)
self.settings.units = stmt.mode
yield stmt
elif param["param"] == "IP":
yield IPParamStmt.from_dict(param)
elif param["param"] == "LP":
yield LPParamStmt.from_dict(param)
elif param["param"] == "AD":
yield ADParamStmt.from_dict(param)
elif param["param"] == "AM":
yield AMParamStmt.from_dict(param)
elif param["param"] == "OF":
yield OFParamStmt.from_dict(param)
elif param["param"] == "IN":
yield INParamStmt.from_dict(param)
elif param["param"] == "LN":
yield LNParamStmt.from_dict(param)
else:
yield UnknownStmt(line)
did_something = True
line = r
continue
# eof
(eof, r) = _match_one(self.EOF_STMT, line)
if eof:
yield EofStmt()
did_something = True
line = r
continue
if False:
print self.COORD_STMT.pattern
print self.APERTURE_STMT.pattern
print self.COMMENT_STMT.pattern
print self.EOF_STMT.pattern
for i in self.PARAM_STMT:
print i.pattern
if line.find('*') > 0:
yield UnknownStmt(line)
did_something = True
line = ""
continue
oldline = line
def evaluate(self, stmt):
""" Evaluate Gerber statement and update image accordingly.
This method is called once for each statement in the file as it
is parsed.
Parameters
----------
statement : Statement
Gerber/Excellon statement to evaluate.
"""
if isinstance(stmt, CoordStmt):
self._evaluate_coord(stmt)
elif isinstance(stmt, ParamStmt):
self._evaluate_param(stmt)
elif isinstance(stmt, ApertureStmt):
self._evaluate_aperture(stmt)
elif isinstance(stmt, (RegionModeStmt, QuadrantModeStmt)):
self._evaluate_mode(stmt)
elif isinstance(stmt, (CommentStmt, UnknownStmt, EofStmt)):
return
else:
raise Exception("Invalid statement to evaluate")
def _define_aperture(self, d, shape, modifiers):
aperture = None
if shape == 'C':
diameter = float(modifiers[0][0])
aperture = Circle(position=None, diameter=diameter)
elif shape == 'R':
width = float(modifiers[0][0])
height = float(modifiers[0][1])
aperture = Rectangle(position=None, width=width, height=height)
elif shape == 'O':
width = float(modifiers[0][0])
height = float(modifiers[0][1])
aperture = Obround(position=None, width=width, height=height)
self.apertures[d] = aperture
def _evaluate_mode(self, stmt):
if stmt.type == 'RegionMode':
if self.region_mode == 'on' and stmt.mode == 'off':
self.primitives.append(Region(self.current_region, self.level_polarity))
self.current_region = None
self.region_mode = stmt.mode
elif stmt.type == 'QuadrantMode':
self.quadrant_mode = stmt.mode
def _evaluate_param(self, stmt):
if stmt.param == "FS":
self.settings.zero_suppression = stmt.zero_suppression
self.settings.format = stmt.format
self.settings.notation = stmt.notation
elif stmt.param == "MO":
self.settings.units = stmt.mode
elif stmt.param == "IP":
self.image_polarity = stmt.ip
elif stmt.param == "LP":
self.level_polarity = stmt.lp
elif stmt.param == "AD":
self._define_aperture(stmt.d, stmt.shape, stmt.modifiers)
def _evaluate_coord(self, stmt):
x = self.x if stmt.x is None else stmt.x
y = self.y if stmt.y is None else stmt.y
if stmt.function in ("G01", "G1"):
self.interpolation = 'linear'
elif stmt.function in ('G02', 'G2', 'G03', 'G3'):
self.interpolation = 'arc'
self.direction = ('clockwise' if stmt.function in ('G02', 'G2')
else 'counterclockwise')
if stmt.op == "D01":
if self.region_mode == 'on':
if self.current_region is None:
self.current_region = [(self.x, self.y), ]
self.current_region.append((x, y,))
else:
start = (self.x, self.y)
end = (x, y)
width = self.apertures[self.aperture].stroke_width
if self.interpolation == 'linear':
self.primitives.append(Line(start, end, width, self.level_polarity))
else:
center = (start[0] + stmt.i, start[1] + stmt.j)
self.primitives.append(Arc(start, end, center, self.direction, width, self.level_polarity))
elif stmt.op == "D02":
pass
elif stmt.op == "D03":
primitive = copy.deepcopy(self.apertures[self.aperture])
primitive.position = (x, y)
primitive.level_polarity = self.level_polarity
self.primitives.append(primitive)
self.x, self.y = x, y
def _evaluate_aperture(self, stmt):
self.aperture = stmt.d
def _match_one(expr, data):
match = expr.match(data)
if match is None:
return ({}, None)
else:
return (match.groupdict(), data[match.end(0):])
def _match_one_from_many(exprs, data):
for expr in exprs:
match = expr.match(data)
if match:
return (match.groupdict(), data[match.end(0):])
return ({}, None)
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