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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]

            if len(modifiers[0]) >= 2:
                hole_diameter = modifiers[0][1]
            else:
                hole_diameter = None

            aperture = Circle(position=None, diameter=diameter, hole_diameter=hole_diameter, units=self.settings.units)
        elif shape == 'R':
            width = modifiers[0][0]
            height = modifiers[0][1]

            if len(modifiers[0]) >= 3:
                hole_diameter = modifiers[0][2]
            else:
                hole_diameter = None

            aperture = Rectangle(position=None, width=width, height=height, hole_diameter=hole_diameter, units=self.settings.units)
        elif shape == 'O':
            width = modifiers[0][0]
            height = modifiers[0][1]

            if len(modifiers[0]) >= 3:
                hole_diameter = modifiers[0][2]
            else:
                hole_diameter = None

            aperture = Obround(position=None, width=width, height=height, hole_diameter=hole_diameter, 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

            if len(modifiers[0]) > 3:
                hole_diameter = modifiers[0][3]
            else:
                hole_diameter = None
            aperture = Polygon(position=None, sides=number_vertices, radius=outer_diameter/2.0, hole_diameter=hole_diameter, 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))

        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
        """

        if self.quadrant_mode == 'single-quadrant':

            # The Gerber spec says single quadrant only has one possible center, and you can detect
            # 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). Find the center that makes the most sense
            sqdist_diff_min = sys.maxint
            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])

                sqdist_start = sq_distance(start, test_center)
                sqdist_end = sq_distance(end, test_center)

                if abs(sqdist_start - sqdist_end) < sqdist_diff_min:
                    center = test_center
                    sqdist_diff_min = abs(sqdist_start - sqdist_end)

            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)