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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 os
import re
import sys
try:
from cStringIO import StringIO
except(ImportError):
from io import StringIO
from .gerber_statements import *
from .primitives import *
from .cam import CamFile, FileSettings
from .utils import sq_distance
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)
def loads(data, filename=None):
""" Generate a GerberFile object from rs274x data in memory
Parameters
----------
data : string
string containing gerber file contents
filename : string, optional
string containing the filename of the data source
Returns
-------
file : :class:`gerber.rs274x.GerberFile`
A GerberFile created from the specified file.
"""
return GerberParser().parse_raw(data, 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, apertures, filename=None):
super(GerberFile, self).__init__(statements, settings, primitives, filename)
self.apertures = apertures
@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):
min_x = min_y = 1000000
max_x = max_y = -1000000
for stmt in [stmt for stmt in self.statements if isinstance(stmt, CoordStmt)]:
if stmt.x is not None:
min_x = min(stmt.x, min_x)
max_x = max(stmt.x, max_x)
if stmt.y is not None:
min_y = min(stmt.y, min_y)
max_y = max(stmt.y, max_y)
return ((min_x, max_x), (min_y, max_y))
@property
def bounding_box(self):
min_x = min_y = 1000000
max_x = max_y = -1000000
for prim in self.primitives:
bounds = prim.bounding_box
min_x = min(bounds[0][0], min_x)
max_x = max(bounds[0][1], max_x)
min_y = min(bounds[1][0], min_y)
max_y = max(bounds[1][1], max_y)
return ((min_x, max_x), (min_y, max_y))
def write(self, filename, settings=None):
""" Write data out to a gerber file.
"""
with open(filename, 'w') as f:
for statement in self.statements:
f.write(statement.to_gerber(settings or self.settings))
f.write("\n")
def to_inch(self):
if self.units != 'inch':
self.units = 'inch'
for statement in self.statements:
statement.to_inch()
for primitive in self.primitives:
primitive.to_inch()
def to_metric(self):
if self.units != 'metric':
self.units = 'metric'
for statement in self.statements:
statement.to_metric()
for primitive in self.primitives:
primitive.to_metric()
def offset(self, x_offset=0, y_offset=0):
for statement in self.statements:
statement.offset(x_offset, y_offset)
for primitive in self.primitives:
primitive.offset(x_offset, y_offset)
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+\-]+"
FS = r"(?P<param>FS)(?P<zero>(L|T|D))?(?P<notation>(A|I))[NG0-9]*X(?P<x>[0-7][0-7])Y(?P<y>[0-7][0-7])[DM0-9]*"
MO = r"(?P<param>MO)(?P<mo>(MM|IN))"
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)
# Include File
IF = r"(?P<param>IF)(?P<filename>.*)"
# begin deprecated
AS = r"(?P<param>AS)(?P<mode>(AXBY)|(AYBX))"
IN = r"(?P<param>IN)(?P<name>.*)"
IP = r"(?P<param>IP)(?P<ip>(POS|NEG))"
IR = r"(?P<param>IR)(?P<angle>{number})".format(number=NUMBER)
MI = r"(?P<param>MI)(A(?P<a>0|1))?(B(?P<b>0|1))?"
OF = r"(?P<param>OF)(A(?P<a>{decimal}))?(B(?P<b>{decimal}))?".format(decimal=DECIMAL)
SF = r"(?P<param>SF)(?P<discarded>.*)"
LN = r"(?P<param>LN)(?P<name>.*)"
DEPRECATED_UNIT = re.compile(r'(?P<mode>G7[01])\*')
DEPRECATED_FORMAT = re.compile(r'(?P<format>G9[01])\*')
# end deprecated
PARAMS = (FS, MO, LP, AD_CIRCLE, AD_RECT, AD_OBROUND, AD_POLY,
AD_MACRO, AM, AS, IF, IN, IP, IR, MI, OF, SF, LN)
PARAM_STMT = [re.compile(r"%?{0}\*%?".format(p)) for p in PARAMS]
COORD_FUNCTION = r"G0?[123]"
COORD_OP = r"D0?[123]"
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=COORD_FUNCTION, op=COORD_OP)))
APERTURE_STMT = re.compile(r"(?P<deprecated>(G54)|(G55))?D(?P<d>\d+)\*")
COMMENT_STMT = re.compile(r"G0?4(?P<comment>[^*]*)(\*)?")
EOF_STMT = re.compile(r"(?P<eof>M[0]?[012])\*")
REGION_MODE_STMT = re.compile(r'(?P<mode>G3[67])\*')
QUAD_MODE_STMT = re.compile(r'(?P<mode>G7[45])\*')
# Keep include loop from crashing us
INCLUDE_FILE_RECURSION_LIMIT = 10
def __init__(self):
self.filename = None
self.settings = FileSettings()
self.statements = []
self.primitives = []
self.apertures = {}
self.macros = {}
self.current_region = None
self.x = 0
self.y = 0
self.op = "D02"
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)
self._recursion_depth = 0
def parse(self, filename):
self.filename = filename
with open(filename, "rU") as fp:
data = fp.read()
return self.parse_raw(data, filename)
def parse_raw(self, data, filename=None):
self.filename = filename
for stmt in self._parse(self._split_commands(data)):
self.evaluate(stmt)
self.statements.append(stmt)
# Initialize statement units
for stmt in self.statements:
stmt.units = self.settings.units
return GerberFile(self.statements, self.settings, self.primitives, self.apertures.values(), filename)
def _split_commands(self, data):
"""
Split the data into commands. Commands end with * (and also newline to help with some badly formatted files)
"""
length = len(data)
start = 0
in_header = True
for cur in range(0, length):
val = data[cur]
if val == '%' and start == cur:
in_header = True
continue
if val == '\r' or val == '\n':
if start != cur:
yield data[start:cur]
start = cur + 1
elif not in_header and val == '*':
yield data[start:cur + 1]
start = cur + 1
elif in_header and val == '%':
yield data[start:cur + 1]
start = cur + 1
in_header = False
def dump_json(self):
stmts = {"statements": [stmt.__dict__ for stmt in self.statements]}
return json.dumps(stmts)
def dump_str(self):
string = ""
for stmt in self.statements:
string += str(stmt) + "\n"
return string
def _parse(self, data):
oldline = ''
for line in 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("%") and not "%" in line[1:]:
oldline = line
continue
did_something = True # make sure we do at least one loop
while did_something and len(line) > 0:
did_something = False
# consume empty data blocks
if line[0] == '*':
line = line[1:]
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
# 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"] == "LP":
yield LPParamStmt.from_dict(param)
elif param["param"] == "AD":
yield ADParamStmt.from_dict(param)
elif param["param"] == "AM":
stmt = AMParamStmt.from_dict(param)
stmt.units = self.settings.units
yield stmt
elif param["param"] == "OF":
yield OFParamStmt.from_dict(param)
elif param["param"] == "IF":
# Don't crash on include loop
if self._recursion_depth < self.INCLUDE_FILE_RECURSION_LIMIT:
self._recursion_depth += 1
with open(os.path.join(os.path.dirname(self.filename), param["filename"]), 'r') as f:
inc_data = f.read()
for stmt in self._parse(self._split_commands(inc_data)):
yield stmt
self._recursion_depth -= 1
else:
raise IOError("Include file nesting depth limit exceeded.")
elif param["param"] == "IN":
yield INParamStmt.from_dict(param)
elif param["param"] == "LN":
yield LNParamStmt.from_dict(param)
# deprecated commands AS, IN, IP, IR, MI, OF, SF, LN
elif param["param"] == "AS":
yield ASParamStmt.from_dict(param)
elif param["param"] == "IN":
yield INParamStmt.from_dict(param)
elif param["param"] == "IP":
yield IPParamStmt.from_dict(param)
elif param["param"] == "IR":
yield IRParamStmt.from_dict(param)
elif param["param"] == "MI":
yield MIParamStmt.from_dict(param)
elif param["param"] == "OF":
yield OFParamStmt.from_dict(param)
elif param["param"] == "SF":
yield SFParamStmt.from_dict(param)
elif param["param"] == "LN":
yield LNParamStmt.from_dict(param)
else:
yield UnknownStmt(line)
did_something = True
line = r
continue
# 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
# comment
(comment, r) = _match_one(self.COMMENT_STMT, line)
if comment:
yield CommentStmt(comment["comment"])
did_something = True
line = r
continue
# deprecated codes
(deprecated_unit, r) = _match_one(self.DEPRECATED_UNIT, line)
if deprecated_unit:
stmt = MOParamStmt(param="MO", mo="inch" if "G70" in
deprecated_unit["mode"] else "metric")
self.settings.units = stmt.mode
yield stmt
line = r
did_something = True
continue
(deprecated_format, r) = _match_one(self.DEPRECATED_FORMAT, line)
if deprecated_format:
yield DeprecatedStmt.from_gerber(line)
line = r
did_something = True
continue
# eof
(eof, r) = _match_one(self.EOF_STMT, line)
if eof:
yield EofStmt()
did_something = True
line = r
continue
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, DeprecatedStmt, EofStmt)):
return
else:
raise Exception("Invalid statement to evaluate")
def _define_aperture(self, d, shape, modifiers):
aperture = None
if shape == 'C':
diameter = modifiers[0][0]
hole_diameter = 0
rectangular_hole = (0, 0)
if len(modifiers[0]) == 2:
hole_diameter = modifiers[0][1]
elif len(modifiers[0]) == 3:
rectangular_hole = modifiers[0][1:3]
aperture = Circle(position=None, diameter=diameter,
hole_diameter=hole_diameter,
hole_width=rectangular_hole[0],
hole_height=rectangular_hole[1],
units=self.settings.units)
elif shape == 'R':
width = modifiers[0][0]
height = modifiers[0][1]
hole_diameter = 0
rectangular_hole = (0, 0)
if len(modifiers[0]) == 3:
hole_diameter = modifiers[0][2]
elif len(modifiers[0]) == 4:
rectangular_hole = modifiers[0][2:4]
aperture = Rectangle(position=None, width=width, height=height,
hole_diameter=hole_diameter,
hole_width=rectangular_hole[0],
hole_height=rectangular_hole[1],
units=self.settings.units)
elif shape == 'O':
width = modifiers[0][0]
height = modifiers[0][1]
hole_diameter = 0
rectangular_hole = (0, 0)
if len(modifiers[0]) == 3:
hole_diameter = modifiers[0][2]
elif len(modifiers[0]) == 4:
rectangular_hole = modifiers[0][2:4]
aperture = Obround(position=None, width=width, height=height,
hole_diameter=hole_diameter,
hole_width=rectangular_hole[0],
hole_height=rectangular_hole[1],
units=self.settings.units)
elif shape == 'P':
outer_diameter = modifiers[0][0]
number_vertices = int(modifiers[0][1])
if len(modifiers[0]) > 2:
rotation = modifiers[0][2]
else:
rotation = 0
hole_diameter = 0
rectangular_hole = (0, 0)
if len(modifiers[0]) == 4:
hole_diameter = modifiers[0][3]
elif len(modifiers[0]) >= 5:
rectangular_hole = modifiers[0][3:5]
aperture = Polygon(position=None, sides=number_vertices,
radius=outer_diameter/2.0,
hole_diameter=hole_diameter,
hole_width=rectangular_hole[0],
hole_height=rectangular_hole[1],
rotation=rotation)
else:
aperture = self.macros[shape].build(modifiers)
aperture.units = self.settings.units
self.apertures[d] = aperture
def _evaluate_mode(self, stmt):
if stmt.type == 'RegionMode':
if self.region_mode == 'on' and stmt.mode == 'off':
# Sometimes we have regions that have no points. Skip those
if self.current_region:
self.primitives.append(Region(self.current_region,
level_polarity=self.level_polarity, units=self.settings.units))
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 == "AM":
self.macros[stmt.name] = stmt
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.only_function:
# Sometimes we get a coordinate statement
# that only sets the function. If so, don't
# try futher otherwise that might draw/flash something
return
if stmt.op:
self.op = stmt.op
else:
# no implicit op allowed, force here if coord block doesn't have it
stmt.op = self.op
if self.op == "D01" or self.op == "D1":
start = (self.x, self.y)
end = (x, y)
if self.interpolation == 'linear':
if self.region_mode == 'off':
self.primitives.append(Line(start, end,
self.apertures[self.aperture],
level_polarity=self.level_polarity,
units=self.settings.units))
else:
# from gerber spec revision J3, Section 4.5, page 55:
# The segments are not graphics objects in themselves; segments are part of region which is the graphics object. The segments have no thickness.
# The current aperture is associated with the region.
# This has no graphical effect, but allows all its attributes to
# be applied to the region.
if self.current_region is None:
self.current_region = [Line(start, end,
self.apertures.get(self.aperture,
Circle((0, 0), 0)),
level_polarity=self.level_polarity,
units=self.settings.units), ]
else:
self.current_region.append(Line(start, end,
self.apertures.get(self.aperture,
Circle((0, 0), 0)),
level_polarity=self.level_polarity,
units=self.settings.units))
else:
i = 0 if stmt.i is None else stmt.i
j = 0 if stmt.j is None else stmt.j
center = self._find_center(start, end, (i, j))
if self.region_mode == 'off':
self.primitives.append(Arc(start, end, center, self.direction,
self.apertures[self.aperture],
quadrant_mode=self.quadrant_mode,
level_polarity=self.level_polarity,
units=self.settings.units))
else:
if self.current_region is None:
self.current_region = [Arc(start, end, center, self.direction,
self.apertures.get(self.aperture, Circle((0,0), 0)),
quadrant_mode=self.quadrant_mode,
level_polarity=self.level_polarity,
units=self.settings.units),]
else:
self.current_region.append(Arc(start, end, center, self.direction,
self.apertures.get(self.aperture, Circle((0,0), 0)),
quadrant_mode=self.quadrant_mode,
level_polarity=self.level_polarity,
units=self.settings.units))
# Gerbv seems to reset interpolation mode in regions..
# TODO: Make sure this is right.
self.interpolation = 'linear'
elif self.op == "D02" or self.op == "D2":
if self.region_mode == "on":
# D02 in the middle of a region finishes that region and starts a new one
if self.current_region and len(self.current_region) > 1:
self.primitives.append(Region(self.current_region,
level_polarity=self.level_polarity,
units=self.settings.units))
self.current_region = None
elif self.op == "D03" or self.op == "D3":
primitive = copy.deepcopy(self.apertures[self.aperture])
if primitive is not None:
if not isinstance(primitive, AMParamStmt):
primitive.position = (x, y)
primitive.level_polarity = self.level_polarity
primitive.units = self.settings.units
self.primitives.append(primitive)
else:
# Aperture Macro
for am_prim in primitive.primitives:
renderable = am_prim.to_primitive((x, y),
self.level_polarity,
self.settings.units)
if renderable is not None:
self.primitives.append(renderable)
self.x, self.y = x, y
def _find_center(self, start, end, offsets):
"""
In single quadrant mode, the offsets are always positive, which means
there are 4 possible centers. The correct center is the only one that
results in an arc with sweep angle of less than or equal to 90 degrees
in the specified direction
"""
two_pi = 2 * math.pi
if self.quadrant_mode == 'single-quadrant':
# The Gerber spec says single quadrant only has one possible center,
# and you can detect it based on the angle. But for real files, this
# seems to work better - there is usually only one option that makes
# sense for the center (since the distance should be the same
# from start and end). We select the center with the least error in
# radius from all the options with a valid sweep angle.
sqdist_diff_min = sys.maxsize
center = None
for factors in [(1, 1), (1, -1), (-1, 1), (-1, -1)]:
test_center = (start[0] + offsets[0] * factors[0],
start[1] + offsets[1] * factors[1])
# Find angle from center to start and end points
start_angle = math.atan2(*reversed([_start - _center for _start, _center in zip(start, test_center)]))
end_angle = math.atan2(*reversed([_end - _center for _end, _center in zip(end, test_center)]))
# Clamp angles to 0, 2pi
theta0 = (start_angle + two_pi) % two_pi
theta1 = (end_angle + two_pi) % two_pi
# Determine sweep angle in the current arc direction
if self.direction == 'counterclockwise':
sweep_angle = abs(theta1 - theta0)
else:
theta0 += two_pi
sweep_angle = abs(theta0 - theta1) % two_pi
# Calculate the radius error
sqdist_start = sq_distance(start, test_center)
sqdist_end = sq_distance(end, test_center)
sqdist_diff = abs(sqdist_start - sqdist_end)
# Take the option with the lowest radius error from the set of
# options with a valid sweep angle
# In some rare cases, the sweep angle is numerically (10**-14) above pi/2
# So it is safer to compare the angles with some tolerance
is_lowest_radius_error = sqdist_diff < sqdist_diff_min
is_valid_sweep_angle = sweep_angle >= 0 and sweep_angle <= math.pi / 2.0 + 1e-6
if is_lowest_radius_error and is_valid_sweep_angle:
center = test_center
sqdist_diff_min = sqdist_diff
return center
else:
return (start[0] + offsets[0], start[1] + offsets[1])
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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