kicad.py

from __future__ import (absolute_import, division,
        print_function, unicode_literals)
#from builtins import *

from collections import defaultdict
from math import sqrt, atan2, degrees, sin, cos, radians, pi, hypot
import traceback
import FreeCAD
import FreeCADGui
import Part
from FreeCAD import Console,Vector,Placement,Rotation
import DraftGeomUtils,DraftVecUtils
import Path

import sys, os
import re
sys.path.append(os.path.dirname(os.path.realpath(__file__)))
from .kicad_parser import KicadPCB,SexpList,SexpParser,parseSexp
from .kicad_parser import unquote

PY3 = sys.version_info[0] == 3
if PY3:
    string_types = str,
else:
    string_types = basestring,

_hasElementMapping = hasattr(Part, 'disableElementMapping')

def disableTopoNaming(obj, enable=True):
    if _hasElementMapping:
        if isinstance(obj, FreeCAD.DocumentObject):
            Part.disableElementMapping(obj, enable)
        else:
            obj.Tag = -1 if enable else 0
    return obj

def addObject(doc, tp, name):
    obj = doc.addObject(tp, name)
    disableTopoNaming(obj)
    try:
        obj.ValidateShape = False
        obj.FixShape = 0
    except Exception:
        pass
    return obj

def setObjectLinks(obj, links, objs):
    if not _hasElementMapping or not objs:
        setattr(obj,links,objs)
        return

    if not isinstance(objs, (list,tuple)):
        objlist = [objs,]
    else:
        objlist = objs

    color = None
    if isinstance(objlist[0], FreeCAD.DocumentObject):
        color = objlist[0].ViewObject.DiffuseColor
        for o in objlist[1:]:
            if o.ViewObject.DiffuseColor != color:
                for o in objlist:
                    # re-enable topo naming to combine colors
                    disableTopoNaming(o, False)
                disableTopoNaming(obj, False)
                colors = None
                break
    setattr(obj,links,objs)
    if color:
        obj.ViewObject.DiffuseColor = color

def updateGui():
    try:
        FreeCADGui.updateGui()
    except Exception:
        pass

class FCADLogger:
    def __init__(self, tag):
        self.tag = tag
        self.levels = { 'error':0, 'warning':1, 'info':2,
                'log':3, 'trace':4 }

    def _isEnabledFor(self,level):
        return FreeCAD.getLogLevel(self.tag) >= level

    def isEnabledFor(self,level):
        return self._isEnabledFor(self.levels[level])

    def trace(self,msg):
        if self._isEnabledFor(4):
            FreeCAD.Console.PrintLog(msg+'\n')
            updateGui()

    def log(self,msg):
        if self._isEnabledFor(3):
            FreeCAD.Console.PrintLog(msg+'\n')
            updateGui()

    def info(self,msg):
        if self._isEnabledFor(2):
            FreeCAD.Console.PrintMessage(msg+'\n')
            updateGui()

    def warning(self,msg):
        if self._isEnabledFor(1):
            FreeCAD.Console.PrintWarning(msg+'\n')
            updateGui()

    def error(self,msg):
        if self._isEnabledFor(0):
            FreeCAD.Console.PrintError(msg+'\n')
            updateGui()

logger = FCADLogger('fcad_pcb')

def getActiveDoc():
    if FreeCAD.ActiveDocument is None:
        return FreeCAD.newDocument('kicad_fcad')
    return FreeCAD.ActiveDocument

def fitView():
    try:
        FreeCADGui.ActiveDocument.ActiveView.fitAll()
    except Exception:
        pass

def isZero(f):
    return round(f,DraftGeomUtils.precision())==0

def makeColor(*color):
    if len(color)==1:
        if isinstance(color[0],string_types):
            color = int(color[0],0)
        else:
            color = color[0]
        r = float((color>>24)&0xFF)
        g = float((color>>16)&0xFF)
        b = float((color>>8)&0xFF)
    else:
        r,g,b = color
    return (r/255.0,g/255.0,b/255.0)

def makeVect(l):
    return Vector(l[0],-l[1],0)

def getAt(sexp):
    at = getattr(sexp, 'at', None)
    if not at:
        return Vector(0,0,0),0
    v = makeVect(at)
    return (v,0) if len(at)==2 else (v,at[2])

def product(v1,v2):
    return Vector(v1.x*v2.x,v1.y*v2.y,v1.z*v2.z)

def make_rect(size,params=None):
    _ = params
    return Part.makePolygon([product(size,Vector(*v))
        for v in ((-0.5,-0.5),(0.5,-0.5),(0.5,0.5),(-0.5,0.5),(-0.5,-0.5))])

def make_trapezoid(size,params):
    pts = [product(size,Vector(*v)) \
            for v in ((-0.5,0.5),(-0.5,-0.5),(0.5,-0.5),(0.5,0.5))]
    try:
        delta = params.rect_delta[0]
        if delta:
            # horizontal
            idx = 1
            length = size[1]
        else:
            # vertical
            delta = params.rect_delta[1]
            idx = 0
            length = size[0]
        if delta <= -length:
            collapse = 1
            delta = -length;
        elif delta >= length:
            collapse = -1
            delta = length
        else:
            collapse = 0
        pts[0][idx] += delta*0.5
        pts[1][idx] -= delta*0.5
        pts[2][idx] += delta*0.5
        pts[3][idx] -= delta*0.5
        if collapse:
            del pts[collapse]
    except Exception:
        logger.warning('trapezoid pad has no rect_delta')

    pts.append(pts[0])
    return Part.makePolygon(pts)

def make_circle(size,params=None):
    _ = params
    return Part.Wire(Part.makeCircle(size.x*0.5))

def make_oval(size,params=None):
    _ = params
    if size.x == size.y:
        return make_circle(size)
    if size.x < size.y:
        r = size.x*0.5
        size.y -= size.x
        s  = ((0,0.5),(-0.5,0.5),(-0.5,-0.5),(0,-0.5),(0.5,-0.5),(0.5,0.5))
        a = (0,180,180,360)
    else:
        r = size.y*0.5
        size.x -= size.y
        s = ((-0.5,0),(-0.5,-0.5),(0.5,-0.5),(0.5,0),(0.5,0.5),(-0.5,0.5))
        a = (90,270,-90,-270)
    pts = [product(size,Vector(*v)) for v in s]
    return Part.Wire([
            Part.makeCircle(r,pts[0],Vector(0,0,1),a[0],a[1]),
            Part.makeLine(pts[1],pts[2]),
            Part.makeCircle(r,pts[3],Vector(0,0,1),a[2],a[3]),
            Part.makeLine(pts[4],pts[5])])

def make_roundrect(size,params):
    rratio = 0.25
    try:
        rratio = params.roundrect_rratio
        if rratio > 0.5:
            return make_oval(size)
    except Exception:
        logger.warning('round rect pad has no rratio')

    length = min(size.x, size.y)
    r = length*rratio
    n = Vector(0,0,1)
    sx = size.x*0.5
    sy = size.y*0.5

    rounds = [(r,False)]*4

    if 'chamfer_ratio' in params and 'chamfer' in params:
        ratio = params.chamfer_ratio
        if ratio < 0.0:
            ratio = 0.0
        elif ratio > 0.5:
            ratio = 0.5
        for i,corner in enumerate(('top_right',
                                    'top_left',
                                    'bottom_left',
                                    'bottom_right')):
            if corner in params.chamfer:
                rounds[i] = (ratio*length,True)

    edges = []

    r,chamfer = rounds[0]
    pstart = Vector(sx,sy-r)
    pt = pstart
    pnext = Vector(sx-r,sy)

    if r:
        if not chamfer:
            edges.append(Part.makeCircle(r,Vector(sx-r,sy-r),n,0,90))
        else:
            edges.append(Part.makeLine(pt, pnext))

    r,chamfer = rounds[1]
    pt = pnext
    pnext = Vector(r-sx,sy)
    if pt != pnext:
        edges.append(Part.makeLine(pt,pnext))
        pt = pnext
    pnext = Vector(-sx,sy-r)

    if r:
        if not chamfer:
            edges.append(Part.makeCircle(r,Vector(r-sx,sy-r),n,90,180))
        else:
            edges.append(Part.makeLine(pt,pnext))

    r,chamfer = rounds[2]
    pt = pnext
    pnext = Vector(-sx,r-sy)
    if pt != pnext:
        edges.append(Part.makeLine(pt,pnext))
        pt = pnext
    pnext = Vector(r-sx,-sy)

    if r:
        if not chamfer:
            edges.append(Part.makeCircle(r,Vector(r-sx,r-sy),n,180,270))
        else:
            edges.append(Part.makeLine(pt,pnext))

    r,chamfer = rounds[3]
    pt = pnext
    pnext = Vector(sx-r,-sy)
    if pt != pnext:
        edges.append(Part.makeLine(pt,pnext))
        pt = pnext
    pnext = Vector(sx,r-sy)

    if r:
        if not chamfer:
            edges.append(Part.makeCircle(r,Vector(sx-r,r-sy),n,270,360))
        else:
            edges.append(Part.makeLine(pt,pnext))

    pt = pnext
    if pt != pstart:
        edges.append(Part.makeLine(pt,pstart))

    return Part.Wire(edges)

def make_gr_poly(params):
    points = SexpList(params.pts.xy)
    # close the polygon
    points._append(params.pts.xy._get(0))

    # It seems kicad's polygon has inconsistent winding. Use Path.Area
    # projection to make sure we get the counter colockwise winding, otherwise
    # it will be interpreted as a hole.
    poly = Part.makePolygon([makeVect(p) for p in reversed(points)])
    try:
        area = Path.Area(Fill=True, FitArcs=False, Coplanar=0, Outline=True)
        area.add(poly)
        return area.getShape().Wire1
    except Exception as e:
        logger.warning(f'Failed to get outline of gr_poly: {str(e)}')
        return poly

def make_gr_line(params):
    return Part.makeLine(makeVect(params.start),makeVect(params.end))

def make_gr_arc(params):
    if hasattr(params, 'angle'):
        return  makeArc(makeVect(params.start),makeVect(params.end),params.angle)
    return Part.ArcOfCircle(makeVect(params.start),
                            makeVect(params.mid),
                            makeVect(params.end)).toShape()

def make_gr_curve(params):
    return makeCurve([makeVect(p) for p in SexpList(params.pts.xy)])

def make_gr_circle(params, width=0):
    center = makeVect(params.center)
    end = makeVect(params.end)
    r = center.distanceToPoint(end)
    if not width or r <= width*0.5:
        return Part.makeCircle(r+width*0.5, center)
    return Part.makeCompound([Part.Wire(Part.makeCircle(r+width*0.5,center)),
                              Part.Wire(Part.makeCircle(r-width*0.5,center,Vector(0,0,-1)))])

def make_gr_rect(params):
    start = makeVect(params.start)
    end = makeVect(params.end)
    return Part.makePolygon([start, Vector(start.x, end.y), end, Vector(end.x, start.y), start])


def getLineWidth(param, default):
    width = getattr(param, 'width', None)
    if not width:
        if hasattr(param, 'stroke'):
            width = getattr(param.stroke, 'width', default)
        else:
            width = default
    return width


def makePrimitve(key, param):
    try:
        width = getLineWidth(param, 0)
        if width and key == 'gr_circle':
            return make_gr_circle(param, width), 0
        else:
            make_shape = globals()['make_{}'.format(key)]
            return make_shape(param), width
    except KeyError:
        logger.warning('Unknown primitive {} in custom pad'.format(key))
        return None, None

def makeThickLine(p1,p2,width):
    length = p1.distanceToPoint(p2)
    line = make_oval(Vector(length+2*width,2*width))
    p = p2.sub(p1)
    a = -degrees(DraftVecUtils.angle(p))
    line.translate(Vector(length*0.5))
    line.rotate(Vector(),Vector(0,0,1),a)
    line.translate(p1)
    return line

def makeArc(center,start,angle):
    p = start.sub(center)
    r = p.Length
    a = -degrees(DraftVecUtils.angle(p))
    # NOTE: KiCAD pcb geometry runs in clockwise, while FreeCAD is CCW. So the
    # resulting arc below is the reverse of what's specified in kicad_pcb
    if angle>0:
        arc = Part.makeCircle(r,center,Vector(0,0,1),a-angle,a)
        arc.reverse();
    else:
        arc = Part.makeCircle(r,center,Vector(0,0,1),a,a-angle)
    return arc

def makeCurve(poles):
    return Part.BSplineCurve(poles).toShape()

def findWires(edges):
    try:
        return [Part.Wire(e) for e in Part.sortEdges(edges)]
    except AttributeError:
        msg = 'Missing Part.sortEdges.'\
            'You need newer FreeCAD (0.17 git 799c43d2)'
        logger.error(msg)
        raise AttributeError(msg)

def getFaceCompound(shape,wire=False):
    objs = []
    for f in shape.Faces:
        selected = True
        for v in f.Vertexes:
            if not isZero(v.Z):
                selected = False
                break
        if not selected:
            continue

        ################################################################
        ## TODO: FreeCAD curve.normalAt is not implemented
        ################################################################
        # for e in f.Edges:
            # if isinstance(e.Curve,(Part.LineSegment,Part.Line)): continue
            # if not isZero(e.normalAt(Vector()).dot(Vector(0,0,1))):
                # selected = False
                # break
        # if not selected: continue

        if not wire:
            objs.append(f)
            continue
        for w in f.Wires:
            objs.append(w)
    if not objs:
        raise ValueError('null shape')
    return Part.makeCompound(objs)


def unpack(obj):
    if not obj:
        raise ValueError('null shape')

    if isinstance(obj,(list,tuple)) and len(obj)==1:
        return obj[0]
    return obj


def getKicadPath(env=''):
    confpath = ''
    if env:
        confpath = os.path.expanduser(os.environ.get(env,''))
        if not os.path.isdir(confpath):
            confpath=''
    if not confpath:
        if sys.platform == 'darwin':
            confpath = os.path.expanduser('~/Library/Preferences/kicad')
        elif sys.platform == 'win32':
            confpath = os.path.join(
                    os.path.abspath(os.environ['APPDATA']),'kicad')
        else:
            confpath=os.path.expanduser('~/.config/kicad')

    import re
    kicad_common = os.path.join(confpath,'kicad_common')
    if not os.path.isfile(kicad_common):
        kicad_common += ".json"
        if not os.path.isfile(kicad_common):
            subdir = None
            version = 0
            for dir in os.listdir(confpath):
                try:
                    if float(dir) > version:
                        version = float(dir)
                        subdir = dir
                except:
                    continue
            if subdir is None or version == 0:
                return None
            confpath = os.path.join(confpath, subdir)
            kicad_common = os.path.join(confpath, 'kicad_common')
            logger.info("Checking {}".format(kicad_common))
            if not os.path.isfile(kicad_common):
                kicad_common += ".json"
                if not os.path.isfile(kicad_common):
                    logger.warning('cannot find kicad_common')
                    return None
            logger.info("Found kicad_common at {}".format(kicad_common))
    with open(kicad_common,'r') as f:
        content = f.read()
    match = re.search(r'^\s*"*KISYS3DMOD"*\s*[:=]\s*([^\r\n]+)',content,re.MULTILINE)
    if not match:
        logger.warning('no KISYS3DMOD found')
        return None

    return match.group(1).rstrip(' "')

_model_cache = {}

def clearModelCache():
    _model_cache = {}

def recomputeObj(obj):
    obj.recompute()
    obj.purgeTouched()

def loadModel(filename):
    mtime = None
    try:
        mtime = os.path.getmtime(filename)
        obj = _model_cache[filename]
        if obj[2] == mtime:
            logger.info('model cache hit');
            return obj
        else:
            logger.info('model reload due to time stamp change');
    except KeyError:
        pass
    except OSError:
        return

    import ImportGui
    doc = getActiveDoc()
    if not os.path.isfile(filename):
        return
    count = len(doc.Objects)
    dobjs = []
    try:
        ImportGui.insert(filename,doc.Name)
        dobjs = doc.Objects[count:]
        obj = addObject(doc,'Part::Compound','tmp')
        setObjectLinks(obj, 'Links', dobjs)
        recomputeObj(obj)
        dobjs = [obj]+dobjs
        obj = (obj.Shape.copy(),obj.ViewObject.DiffuseColor,mtime)
        _model_cache[filename] = obj
        return obj
    except Exception as ex:
        logger.error('failed to load model: {}'.format(ex))
    finally:
        for o in dobjs:
            doc.removeObject(o.Name)

class KicadFcad:
    def __init__(self,filename=None,debug=False,**kwds):

        #############################################################
        # Beginning of user customizable parameters during construction
        self.prefix = ''
        self.indent = '  '
        self.make_sketch = False
        self.sketch_use_draft = False
        self.sketch_radius_precision = -1
        self.holes_cache = {}
        self.workplane = {}
        self.active_doc_uuid = None
        self.sketch_constraint = True
        self.sketch_align_constraint = False
        self.merge_holes = not debug
        self.merge_vias = not debug
        self.merge_tracks = not debug
        self.zone_merge_holes = not debug
        self.merge_pads = not debug
        self.castellated = False
        self.refine = False
        self.arc_fit_accuracy = 0.0005
        self.layer_thickness = 0.01
        self.copper_thickness = 0.05
        self.board_thickness = None
        self.stackup = None
        self.quote_no_parse = None

        # set -1 to disable via in pads, 0 to enable as normal, >0 to use as
        # a ratio to via radius for creating a square to simplify via
        self.via_bound = 0

        # whether to skip via hole if there is via_bound
        self.via_skip_hole = None

        self.add_feature = True
        self.part_path = None
        self.path_env = 'KICAD_CONFIG_HOME'
        self.hole_size_offset = 0.0001
        self.pad_inflate = 0
        self.zone_inflate = 0
        self.nets = []
        if filename is None:
            filename = '/home/thunder/pwr.kicad_pcb'
        if not os.path.isfile(filename):
            raise ValueError("file not found");
        self.filename = filename
        self.colors = {
                'board':makeColor("0x3A6629"),
                'pad':{0:makeColor(204,204,204)},
                'zone':{0:makeColor(0,80,0)},
                'track':{0:makeColor(0,120,0)},
                'copper':{0:makeColor(200,117,51)},
        }
        self.layer_type = 0
        self.layer_match = None
        # Ending of user customizable parameters
        #############################################################

        # checking user overridden parameters
        for key,value in kwds.items():
            if not hasattr(self,key):
                raise ValueError('unknown parameter "{}"'.format(key))
            setattr(self,key,value)

        if not self.part_path:
            self.part_path = getKicadPath(self.path_env)
        self.pcb = KicadPCB.load(self.filename, self.quote_no_parse)

        if self.pcb._key == 'footprint':
            self.pcb._key = 'module'
        if self.pcb._key == 'module':
            self.module = self.pcb

            # this is a kicad_mod file, make it look like a kicad_pcb
            board = '''(kicad_pcb
                        (general
                            (thickness 0.3)
                            (drawings 0)
                            (tracks 0)
                            (zones 0)
                            (modules 1)
                            (nets 0)
                        )
                        (layers
                            (0 F.Cu signal)
                            (31 B.Cu signal)
                            (32 B.Adhes user)
                            (33 F.Adhes user)
                            (34 B.Paste user)
                            (35 F.Paste user)
                            (36 B.SilkS user)
                            (37 F.SilkS user)
                            (38 B.Mask user)
                            (39 F.Mask user)
                            (40 Dwgs.User user)
                            (41 Cmts.User user)
                            (42 Eco1.User user)
                            (43 Eco2.User user)
                            (44 Edge.Cuts user)
                            (45 Margin user)
                            (46 B.CrtYd user)
                            (47 F.CrtYd user)
                            (48 B.Fab user)
                            (49 F.Fab user)
                        )'''
            with open(self.filename) as f:
                board += f.read() + '\n)'

            self.pcb = KicadPCB(parseSexp(board, self.quote_no_parse))
        else:
            self.module = None

        if not self.board_thickness:
            try:
                self.board_thickness = self.pcb.general.thickness
            except Exception:
                pass
            if not self.board_thickness:
                self.board_thickness = 2.0

        self._dielectric_layers = []
        self._stackup_map = {}
        self._initStackUp()

        # stores layer name as read from the file, may contain quotes depending
        # on kicad version
        self.layer_name = ''

        # stores layer name without quote
        self.layer = ''

        self.setLayer(self.layer_type)

        if self.via_skip_hole is None and self.via_bound:
            self.via_skip_hole = True

        self._nets = set()
        self.net_names = dict()
        if 'net' in self.pcb:
            for n in self.pcb.net:
                self.net_names[n[0]] = n[1]
            self.setNetFilter(*self.nets)

        self.board_face = None
        self.board_uid = None

    def findLayer(self,layer, deftype=None):
        try:
            layer = int(layer)
        except:
            for layer_type in self.pcb.layers:
                name = self.pcb.layers[layer_type][0]
                if name==layer or unquote(name)==layer:
                    return (int(layer_type),name)
            if deftype is not None:
                return deftype, layer
            raise KeyError('layer {} not found'.format(layer))
        else:
            if str(layer) not in self.pcb.layers:
                if deftype is not None:
                    return deftype, str(layer)
                raise KeyError('layer {} not found'.format(layer))
            return (layer, self.pcb.layers[str(layer)][0])

    def setLayer(self,layer):
        self.layer_type, self.layer_name = self.findLayer(layer)
        self.layer = unquote(self.layer_name)
        if self.layer_type <= 31:
            self.layer_match = '*.Cu'
        else:
            self.layer_match = '*.{}'.format(self.layer.split('.')[-1])

    def _copperLayers(self):
        coppers = [ (int(t),unquote(self.pcb.layers[t][0])) \
                        for t in self.pcb.layers if int(t)<=31]
        coppers.sort(key=lambda x : x[0])
        return coppers

    def _initStackUp(self):
        if self.stackup is None:
            self.stackup = []
            stackup = getattr(getattr(self.pcb, 'setup', None), 'stackup', None)
            if stackup:
                try:
                    # If no stackup given by user, extract stack info from setup
                    offset = 0.0
                    last_copper = 0.0
                    for layer in stackup.layer:
                        layer_type, _ = self.findLayer(layer[0], 99)
                        t = getattr(layer, 'thickness',
                                self.copper_thickness if layer_type<=32 else self.layer_thickness)
                        if layer_type <= 31:
                            last_copper = offset
                        # Some layer (e.g. dielectric) may have more than one
                        # thickness field. Add them all.
                        if isinstance(t, SexpList):
                            total = 0.0
                            for tt in t:
                                # And for some thickness field, there may be additional
                                # attribute, like (thickness, 0.05, locked).
                                if isinstance(tt, (float, int)):
                                    total += tt
                                else:
                                    total += tt[0]
                            t = total
                        elif not isinstance(t, (float, int)):
                            t = t[0]

                        offset -= t
                        self.stackup.append([unquote(layer[0]), offset, t])

                    # adjust offset to make the last copper's upper face at z = 0.
                    # In other word, make the last dielectric layer reset at z = 0.
                    # Right now, makeBoard() always assume it is at z = 0.
                    for entry in self.stackup:
                        entry[1] -= last_copper
                except Exception as e:
                    self._log('Failed parsing stackup info: {}', str(e), level='warning')

        board_thickness = 0.0
        accumulate = None
        for item in self.stackup:
            layer, name = self.findLayer(item[0], 99)
            self._stackup_map[unquote(name)] = item
            thickness = item[2]
            if layer <= 31: # is copper layer
                if accumulate is not None:
                    # counting intermediate layer(s) thickness
                    board_thickness += accumulate
                    accumulate = 0.0
                else:
                    accumulate = 0.0
                    continue
            if accumulate is not None:
                accumulate += thickness

        # only respect stackup if all copper layers are specified
        coppers = self._copperLayers()
        if self.stackup:
            for _,name in coppers:
                if unquote(name) not in self._stackup_map:
                    self._log('stackup info ignored because copper layer {} is not found',
                              name, level='warning')
                    self.stackup = []
                    self._stackup_map = {}
                    break

        if self.stackup:
            if board_thickness:
                self.board_thickness = board_thickness
        elif len(coppers) == 1:
            name = coppers[0][1]
            self._stackup_map[name] = [name, 0, self.copper_thickness]
        else:
            step = (self.board_thickness + self.copper_thickness) / (len(coppers)-1)
            offset = self.board_thickness
            for _,name in coppers:
                self._stackup_map[name] = [name, offset, self.copper_thickness]
                offset -= step

        # setup dielectric layer offset and thickness. Going backwards, because
        # makeBoard() assumes the first dielectric layer to be located at z=0
        current = 1000.0
        for _, name in reversed(coppers):
            _, offset, thickness = self._stackup_map[name]
            if offset > current:
                self._dielectric_layers.append([current, offset - current])
            current = offset + thickness

    def layerOffsets(self, thickness=None):
        coppers = self._copperLayers()
        offsets = dict()
        if not thickness or thickness == self.board_thickness:
            for _, name in coppers:
                offsets[name] = self._stackup_map[name][1]
            return offsets

        if len(coppers) == 1:
            offsets[coppers[0][1]] = 0
            return offsets
        step = (thickness + self.copper_thickness)/ (len(coppers)-1)
        offset = thickness
        for _,name in coppers:
            offsets[name] = offset
            offset -= step
        return offsets

    def setNetFilter(self,*nets):
        self._nets.clear()
        ndict = dict()
        nset = set()
        for n in self.pcb.net:
            ndict[n[1]] = n[0]
            nset.add(n[0])

        for n in nets:
            try:
                self._nets.add(ndict[str(n)])
                continue
            except Exception:
                pass
            try:
                if int(n) in nset:
                    self._nets.add(int(n))
                    continue
            except Exception:
                pass
            logger.error('net {} not found'.format(n))

    def getNet(self,p):
        n = p.net
        return n if not isinstance(n,list) else n[0]

    def filterNets(self,p):
        try:
            return self._nets and self.getNet(p) not in self._nets
        except Exception:
            return bool(self._nets)

    def filterLayer(self,p):
        layers = []
        l = getattr(p, 'layers', [])
        if unquote(l) == 'F&B.Cu':
            layers.append('F.Cu')
            layers.append('B.Cu')
        else:
            layers = [unquote(s) for s in l]
        if hasattr(p, 'layer'):
            layers.append(unquote(p.layer))
        if not layers:
            self._log('no layers specified', level='warning')
            return True
        if self.layer not in layers \
                and self.layer_match not in layers \
                and '*' not in layers:
            self._log('skip layer {}, {}, {}',
                    self.layer, self.layer_match, layers, level='trace')
            return True

    def netName(self,p):
        try:
            return unquote(self.net_names[self.getNet(p)])
        except Exception:
            return 'net?'

    def _log(self,msg,*arg,**kargs):
        level = 'info'
        if kargs:
            if 'level' in kargs:
                level = kargs['level']
        if logger.isEnabledFor(level):
            getattr(logger,level)('{}{}'.format(self.prefix,msg.format(*arg)))


    def _pushLog(self,msg=None,*arg,**kargs):
        if msg:
            self._log(msg,*arg,**kargs)
        if 'prefix' in kargs:
            prefix = kargs['prefix']
            if prefix is not None:
                self.prefix = prefix
        self.prefix += self.indent


    def _popLog(self,msg=None,*arg,**kargs):
        self.prefix = self.prefix[:-len(self.indent)]
        if msg:
            self._log(msg,*arg,**kargs)

    def _makeLabel(self,obj,label):
        if self.layer:
            obj.Label = '{}#{}'.format(obj.Name,self.layer)
        if label is not None:
            obj.Label += '#{}'.format(label)

    def _makeObject(self,otype,name,
            label=None,links=None,shape=None):
        doc = getActiveDoc()
        obj = addObject(doc,otype,name)
        self._makeLabel(obj,label)
        if links:
            setObjectLinks(obj, links, shape)
            for s in shape if isinstance(shape,(list,tuple)) else (shape,):
                if hasattr(s,'ViewObject'):
                    s.ViewObject.Visibility = False
            if hasattr(obj,'recompute'):
                recomputeObj(obj)
        return obj

    def _makeSketch(self,objs,name,label=None):
        if self.sketch_use_draft:
            import Draft
            getActiveDoc()
            nobj = Draft.makeSketch(objs,name=name,autoconstraints=True,
                delete=True,radiusPrecision=self.sketch_radius_precision)
            disableElementMapping(nobj)
            self._makeLabel(nobj,label)
            return nobj

        from Sketcher import Constraint

        StartPoint = 1
        EndPoint = 2

        doc = getActiveDoc()

        nobj = addObject(doc,"Sketcher::SketchObject", '{}_sketch'.format(name))
        self._makeLabel(nobj,label)
        nobj.ViewObject.Autoconstraints = False

        radiuses = {}
        constraints = []

        def addRadiusConstraint(edge):
            try:
                if self.sketch_radius_precision<0:
                    return
                if self.sketch_radius_precision==0:
                    constraints.append(Constraint('Radius',
                            nobj.GeometryCount-1, edge.Curve.Radius))
                    return
                r = round(edge.Curve.Radius,self.sketch_radius_precision)
                constraints.append(Constraint('Equal',
                    radiuses[r], nobj.GeometryCount-1))
            except KeyError:
                radiuses[r] = nobj.GeometryCount-1
                constraints.append(Constraint('Radius',nobj.GeometryCount-1,r))
            except AttributeError:
                pass

        for obj in objs if isinstance(objs,(list,tuple)) else (objs,):
            if isinstance(obj,Part.Shape):
                shape = obj
            else:
                shape = obj.Shape
            norm = DraftGeomUtils.getNormal(shape)
            if not self.sketch_constraint:
                for wire in shape.Wires:
                    for edge in wire.OrderedEdges:
                        nobj.addGeometry(DraftGeomUtils.orientEdge(
                            edge,norm,make_arc=True))
                continue

            for wire in shape.Wires:
                last_count = nobj.GeometryCount
                edges = wire.OrderedEdges
                for edge in edges:
                    nobj.addGeometry(DraftGeomUtils.orientEdge(
                        edge,norm,make_arc=True))

                    addRadiusConstraint(edge)

                for i,g in enumerate(nobj.Geometry[last_count:]):
                    if edges[i].Closed:
                        continue
                    seg = last_count+i
                    if self.sketch_align_constraint:
                        if DraftGeomUtils.isAligned(g,"x"):
                            constraints.append(Constraint("Vertical",seg))
                        elif DraftGeomUtils.isAligned(g,"y"):
                            constraints.append(Constraint("Horizontal",seg))

                    if seg == nobj.GeometryCount-1:
                        if not wire.isClosed():
                            break
                        g2 = nobj.Geometry[last_count]
                        seg2 = last_count
                    else:
                        seg2 = seg+1
                        g2 = nobj.Geometry[seg2]

                    end1 = g.value(g.LastParameter)
                    start2 = g2.value(g2.FirstParameter)
                    if DraftVecUtils.equals(end1,start2) :
                        constraints.append(Constraint(
                            "Coincident",seg,EndPoint,seg2,StartPoint))
                        continue
                    end2 = g2.value(g2.LastParameter)
                    start1 = g.value(g.FirstParameter)
                    if DraftVecUtils.equals(end2,start1):
                        constraints.append(Constraint(
                            "Coincident",seg,StartPoint,seg2,EndPoint))
                    elif DraftVecUtils.equals(start1,start2):
                        constraints.append(Constraint(
                            "Coincident",seg,StartPoint,seg2,StartPoint))
                    elif DraftVecUtils.equals(end1,end2):
                        constraints.append(Constraint(
                            "Coincident",seg,EndPoint,seg2,EndPoint))

            if obj.isDerivedFrom("Part::Feature"):
                objs = [obj]
                while objs:
                    obj = objs[0]
                    objs = objs[1:] + obj.OutList
                    doc.removeObject(obj.Name)

        nobj.addConstraint(constraints)
        recomputeObj(nobj)
        return nobj

    def _makeCompound(self,obj,name,label=None,fit_arcs=False,
            fuse=False,add_feature=False,force=False):

        obj = unpack(obj)
        if not isinstance(obj,(list,tuple)):
            if not force and (
               not fuse or obj.TypeId=='Path::FeatureArea'):
                return obj
            obj = [obj]

        if fuse:
            return self._makeArea(obj,name,label=label,fit_arcs=fit_arcs)

        if add_feature or self.add_feature:
            return self._makeObject('Part::Compound',
                    '{}_combo'.format(name),label,'Links',obj)

        return Part.makeCompound(obj)


    def _makeArea(self,obj,name,offset=0,op=0,fill=None,label=None,
                force=False,fit_arcs=False,reorient=False,outline=False):
        if fill is None:
            fill = 2
        elif fill:
            fill = 1
        else:
            fill = 0

        if not isinstance(obj,(list,tuple)):
            obj = (obj,)

        if isinstance(obj[0], Part.Shape):
            shape = obj[0]
        else:
            shape = Part.getShape(obj[0])
        workplane = self.getWorkPlane(shape)

        if self.add_feature and name:
            if not force and obj[0].TypeId == 'Path::FeatureArea' and (
                obj[0].Operation == op or len(obj[0].Sources)==1) and \
                obj[0].Fill == fill:

                ret = obj[0]
                if len(obj) > 1:
                    ret.Sources = list(ret.Sources) + list(obj[1:])
            else:
                ret = self._makeObject('Path::FeatureArea',
                                        '{}_area'.format(name),label)
                ret.Accuracy = self.arc_fit_accuracy
                ret.Sources = obj
                ret.Operation = op
                ret.Fill = fill
                ret.Offset = offset
                ret.Coplanar = 0
                ret.WorkPlane = workplane
                ret.FitArcs = fit_arcs
                ret.Reorient = reorient
                ret.Outline = outline
                for o in obj:
                    o.ViewObject.Visibility = False

            recomputeObj(ret)
        else:
            ret = Path.Area(Fill=fill,
                            FitArcs=fit_arcs,
                            Coplanar=0,
                            Reorient=reorient,
                            Accuracy=self.arc_fit_accuracy,
                            Offset=offset,
                            Outline=outline)
            ret.setPlane(workplane)
            for o in obj:
                ret.add(o,op=op)
            ret = ret.getShape()
        return ret

    def getWorkPlane(self, shape):
        z = shape.Vertex1.Point.z
        workplane = self.workplane.get(z, None)
        if not workplane:
            workplane = self.workplane[z] = Part.makeCircle(1, Vector(0,0,z))
        return workplane

    def _makeWires(self,obj,name,offset=0,fill=False,label=None,
                   fit_arcs=False, outline=False):
        if self.add_feature and name:
            if self.make_sketch:
                obj = self._makeSketch(obj,name,label)
            elif isinstance(obj,Part.Shape):
                obj = self._makeObject('Part::Feature', '{}_wire'.format(name),
                        label,'Shape',obj)
            elif isinstance(obj,(list,tuple)):
                objs = []
                comp = []
                for o in obj:
                    if isinstance(o,Part.Shape):
                        comp.append(o)
                    else:
                        objs.append(o)
                if comp:
                    comp = Part.makeCompound(comp)
                    objs.append(self._makeObject('Part::Feature',
                            '{}_wire'.format(name),label,'Shape',comp))
                obj = objs

        if outline or fill or offset:
            return self._makeArea(obj,name,offset=offset,fill=fill,
                    fit_arcs=fit_arcs,label=label,outline=outline)
        else:
            return self._makeCompound(obj,name,label=label)


    def _makeSolid(self,obj,name,height,label=None,fit_arcs=True):

        obj = self._makeCompound(obj,name,label=label,
                                    fuse=True,fit_arcs=fit_arcs)

        if not self.add_feature:
            return obj.extrude(Vector(0,0,height))

        nobj = self._makeObject('Part::Extrusion',
                                    '{}_solid'.format(name),label)
        nobj.Base = obj
        nobj.Dir = Vector(0,0,height)
        obj.ViewObject.Visibility = False
        recomputeObj(nobj)
        return nobj


    def _makeFuse(self,objs,name,label=None,force=False):
        obj = unpack(objs)
        if not isinstance(obj,(list,tuple)):
            if not force:
                return obj
            obj = [obj]

        name = '{}_fuse'.format(name)

        if self.add_feature:
            self._log('making fuse {}...',name)
            obj =  self._makeObject('Part::MultiFuse',name,label,'Shapes',obj)
            obj.Refine = self.refine
            self._log('fuse done')
            return obj

        solids = []
        for o in obj:
            solids += o.Solids;

        if solids:
            self._log('making fuse {}...',name)
            obj = solids[0].multiFuse(solids[1:])
            if self.refine:
                obj = obj.removeSplitter()
            self._log('fuse done')
            return obj


    def _makeCut(self,base,tool,name,label=None):
        base = self._makeFuse(base,name,label=label)
        tool = self._makeFuse(tool,'drill',label=label)
        name = '{}_drilled'.format(name)
        self._log('making cut {}...',name)
        if self.add_feature:
            cut = self._makeObject('Part::Cut',name,label=label)
            cut.Base = base
            cut.Tool = tool
            cut.Refine = self.refine
            base.ViewObject.Visibility = False
            tool.ViewObject.Visibility = False
            recomputeObj(cut)
            cut.ViewObject.ShapeColor = base.ViewObject.ShapeColor
        else:
            cut = base.cut(tool)
            if self.refine:
                cut = cut.removeSplitter()
        self._log('cut done')
        return cut


    def _place(self,obj,pos,angle=None):
        if not obj.isDerivedFrom('App::DocumentObject'):
            if angle:
                obj.rotate(Vector(),Vector(0,0,1),angle)
            obj.translate(pos)
        else:
            r = Rotation(Vector(0,0,1),angle) if angle else Rotation()
            obj.Placement = Placement(pos,r)
            obj.purgeTouched()

    def _makeEdgeCuts(self, sexp, ctx, wires, non_closed, at=None, layers=None):
        if not layers:
            # default to layer Edge.Cuts
            layers = [44]
        for l in layers:
            try:
                _,layer = self.findLayer(l)
            except Exception:
                continue
            self._makeShape(sexp, ctx, wires, non_closed, layer, at)

    def _makeShape(self, sexp, ctx, wires, non_closed=None, layer=None, at=None):
        edges = []

        if at:
            at, angle = getAt(at)
        else:
            angle = None

        for tp in 'line','arc','circle','curve','poly','rect':
            name = ctx + '_' + tp
            primitives = getattr(sexp, name, None)
            if not primitives:
                continue;
            primitives = SexpList(primitives)
            self._log('making {} {}s',len(primitives), tp)
            make_shape = globals()['make_gr_{}'.format(tp)]
            for l in primitives:
                if not layer:
                    if self.filterNets(l) or self.filterLayer(l):
                        continue
                elif l.layer != layer:
                    continue
                shape = make_shape(l)
                if angle:
                    shape.rotate(Vector(),Vector(0,0,1),angle)
                if at:
                    shape.translate(at)
                width = getLineWidth(l, 1e-7)
                edges += [[width, e] for e in shape.Edges]

        # The line width in edge cuts are important. When milling, the line
        # width can represent the diameter of the drill bits to use. The user
        # can use lines thick enough for hole cutting. In addition, the
        # endpoints of thick lines do not have to coincide to complete a loop.
        #
        # Therefore, we shall use the line width as tolerance to detect closed
        # wires. And for non-closed wires, if the shape_type is not wire, we
        # shall thicken the wire using Path.Area for hole cutting.

        for info in edges:
            w,e = info
            if w > 1e-7:
                e.fixTolerance(w)
            info += [e.firstVertex().Point,e.lastVertex().Point]

        while edges:
            w,e,pstart,pend = edges.pop(-1)
            wstart = wend = w
            elist = [(w,e)]
            if pstart.distanceToPoint(pend) <= (wstart+w)/2:
                closed = True
            else:
                closed = False
            i = 0
            while not closed and i < len(edges):
                w,e,ps,pe = edges[i]
                if pstart.distanceToPoint(ps) <= (wstart+w)/2:
                    e.reverse()
                    pstart = pe
                    wstart = w
                    elist.insert(0,(w,e))
                elif pstart.distanceToPoint(pe) <= (wstart+w)/2:
                    pstart = ps
                    wstart = w
                    elist.insert(0,(w,e))
                elif pend.distanceToPoint(ps) <= (wend+w)/2:
                    e.reverse()
                    pend = pe
                    wend = w
                    elist.append((w,e))
                elif pend.distanceToPoint(pe) <= (wend+w)/2:
                    pend = ps
                    wend = w
                    elist.append((w,e))
                else:
                    i += 1
                    continue
                edges.pop(i)
                i = 0
                if pstart.distanceToPoint(pend) <= (wstart+wend)/2:
                    closed = True
                    break

            wire = None
            try:
                #  tol = max([o[0] for o in elist])
                #  wire = Part.makeWires([disableTopoNaming(o[1]) for o in elist],'',tol,True)

                wire = Part.Wire([disableTopoNaming(o[1]) for o in elist])
                #  wire.fixWire(None,tol)
                #  wire.fix(tol,tol,tol)
            except Exception:
                pass

            if closed and (not wire or not wire.isClosed()):
                logger.warning('wire not closed')
                closed = False

            if wire and closed:
                wires.append(wire)
            elif non_closed is not None:
                for w,e in elist:
                    if w > 5e-7:
                        non_closed[w].append(e)
            else:
                for w,e in elist:
                    if w > 5e-7:
                        wires.append(self._makeWires(e, name=None, offset=w*0.5))

    def intersectBoard(self, objs, name, fit_arcs=True):
        if not objs:
            return objs
        if self.add_feature and self.board_uid != getActiveDoc().Uid:
            self.board_face = None
        if not self.board_face:
            self.board_face = self.makeBoard(shape_type='face', holes=False, single_layer=True)
            if self.add_feature:
                self.board_face.Visibility = False
                self.board_uid = self.board_face.Document.Uid

        objs = (self._makeCompound(objs,name,label='castellated'),self.board_face)
        # op=2 for intersection
        return self._makeArea(objs,name,op=2,label='castellated',fit_arcs=fit_arcs)

    def makeBoard(self,shape_type='solid',thickness=None,fit_arcs=True,
            holes=True, minHoleSize=0, ovalHole=True, prefix='', single_layer=False):

        non_closed = defaultdict(list)
        wires = []

        self._pushLog('making board...',prefix=prefix)
        self._makeEdgeCuts(self.pcb, 'gr', wires, non_closed)

        self._pushLog('checking footprints...',prefix=prefix)
        if self.module:
            # try Edge.Cuts first
            self._makeEdgeCuts(self.module, 'fp', wires, non_closed)
            # try F.CrtYd and B.CrtYd
            self._makeEdgeCuts(self.module, 'fp', wires, non_closed, layers=(46, 47))
        else:
            for m in self.pcb.module:
                self._makeEdgeCuts(m, 'fp', wires, non_closed, getattr(m, 'at', None))

        self._popLog()

        if not wires and not non_closed:
            if not wires and not non_closed:
                self._popLog('no board edges found')
                return

        def _addHoles(objs):
            h = self._cutHoles(None,holes,None,
                            minSize=minHoleSize,oval=ovalHole)
            if h:
                if isinstance(h,(tuple,list)):
                    objs += h
                elif holes:
                    objs.append(h)
            return objs

        def _wire():
            objs = []

            if wires:
                objs.append(self._makeWires(wires,'board'))

            for width,edges in non_closed.items():
                objs.append(self._makeWires(edges,'board',label=width,offset=width*0.5))

            return self._makeCompound(_addHoles(objs),'board')

        def _face():
            if not wires:
                raise RuntimeError('no closed wire')

            # Pick the wire with the largest area as outline
            areas = [ Part.Face(w).Area for w in wires ]
            outer = wires.pop(areas.index(max(areas)))

            objs = [ self._makeWires(outer,'board',label='outline') ]
            if wires:
                objs.append(self._makeWires(wires,'board',label='inner'))

            for width,elist in non_closed.items():
                wire = self._makeWires(elist,'board',label=width)
                # thicken non closed wire for hole cutting
                objs.append(self._makeArea(wire,'board',label=width,
                                           offset = width*0.5))

            return self._makeArea(_addHoles(objs),'board',
                            op=1,fill=True,fit_arcs=fit_arcs)

        base = []
        def _solid():
            base.append(_face())
            return self._makeSolid(base[0],'board',thickness,
                    fit_arcs = fit_arcs)

        if shape_type == 'solid' and not thickness and self._dielectric_layers:
            layers = self._dielectric_layers
        else:
            if not thickness:
                thickness = self.board_thickness
            layers = [(self.copper_thickness, thickness)]

        try:
            layer_save = self.layer
            self.layer = None
            try:
                func = locals()['_{}'.format(shape_type)]
            except KeyError:
                raise ValueError('invalid shape type: {}'.format(shape_type))

            thickness = layers[0][1]
            obj = func()
            if self.add_feature:
                if hasattr(obj.ViewObject,'MapFaceColor'):
                    obj.ViewObject.MapFaceColor = False
                obj.ViewObject.ShapeColor = self.colors['board']

            if len(layers) > 1 and not single_layer:
                objs = [obj]
                for offset, t in layers[1:]:
                    if abs(t - layers[0][1]) < 1e-7:
                        if self.add_feature:
                            obj = self._makeObject('Part::Feature', 'board_solid')
                            obj.Shape = objs[0].Shape
                        else:
                            obj = objs[0].copy()
                    else:
                        obj = self._makeSolid(base[0], 'board', t)
                    self._place(obj,Vector(0,0,offset))
                    if self.add_feature:
                        if hasattr(obj.ViewObject,'MapFaceColor'):
                            obj.ViewObject.MapFaceColor = False
                        obj.ViewObject.ShapeColor = self.colors['board']
                    objs.append(obj)
                obj = self._makeCompound(objs, 'board')
        finally:
            if layer_save:
                self.setLayer(layer_save)

        self._popLog('board done')
        fitView();
        return obj

    def makeHoles(self,shape_type='wire',minSize=0,maxSize=0,
            oval=False,prefix='',offset=0.0,npth=0,skip_via=False,
            board_thickness=None,extra_thickness=0.0,castellated=False):

        self._pushLog('making holes...',prefix=prefix)

        holes = defaultdict(list)
        ovals = defaultdict(list)

        width=0
        def _wire(obj,name,fill=False):
            return self._makeWires(obj,name,fill=fill,label=width)

        def _face(obj,name):
            return _wire(obj,name,True)

        def _solid(obj,name):
            return self._makeWires(obj,name,fill=True,label=width,fit_arcs=True)

        try:
            func = locals()['_{}'.format(shape_type)]
        except KeyError:
            raise ValueError('invalid shape type: {}'.format(shape_type))

        oval_count = 0
        count = 0
        skip_count = 0
        if not offset:
            offset = self.hole_size_offset;

        thickness = board_thickness
        if not thickness:
            thickness = self.board_thickness
        layer_offsets = self.layerOffsets(thickness)
        z_offset = min(layer_offsets.values())

        for m in self.pcb.module:
            m_at,m_angle = getAt(m)
            for p in m.pad:
                if 'drill' not in p:
                    continue
                if self.filterNets(p):
                    skip_count += 1
                    continue
                if p[1]=='np_thru_hole':
                    if npth<0:
                        skip_count += 1
                        continue
                    ofs = abs(offset)
                else:
                    if npth>0:
                        skip_count += 1
                        continue
                    ofs = -abs(offset)
                if p.drill.oval:
                    if not oval:
                        continue
                    size = Vector(p.drill[0],p.drill[1])
                    w = make_oval(size+Vector(ofs,ofs))
                    ovals[min(size.x,size.y)].append(w)
                    oval_count += 1
                elif 0 in p.drill and \
                        p.drill[0]>=minSize and \
                        (not maxSize or p.drill[0]<=maxSize):
                    w = make_circle(Vector(p.drill[0]+ofs))
                    holes[p.drill[0]].append(w)
                    count += 1
                else:
                    skip_count += 1
                    continue
                at,angle = getAt(p)
                angle -= m_angle;
                if not isZero(angle):
                    w.rotate(Vector(),Vector(0,0,1),angle)
                w.translate(at)
                if m_angle:
                    w.rotate(Vector(),Vector(0,0,1),m_angle)
                m_at.z = z_offset
                w.translate(m_at)
        self._log('pad holes: {}, skipped: {}',count+skip_count,skip_count)
        if oval:
            self._log('oval holes: {}',oval_count)

        blind_holes = defaultdict(list)
        if npth<=0:
            via_skip = 0
            if skip_via or self.via_bound < 0:
                via_skip = len(self.pcb.via)
            else:
                ofs = -abs(offset)
                for v in self.pcb.via:
                    if self.filterNets(v):
                        via_skip += 1
                        continue

                    if v.drill>=minSize and (not maxSize or v.drill<=maxSize):

                        z_offsets = [layer_offsets[unquote(n)] for n in v.layers]
                        pos = makeVect(v.at)
                        pos.z = min(z_offsets)
                        dist = max(z_offsets) - pos.z

                        s = v.drill+ofs
                        if self.via_bound:
                            s *= self.via_bound
                            w = make_rect(Vector(s,s))
                        else:
                            w = make_circle(Vector(s))
                        w.translate(pos)
                        if dist < thickness-0.001:
                            blind_holes[(pos.z,dist)].append(w)
                        else:
                            holes[v.drill].append(w)
                    else:
                        via_skip += 1
            skip_count += via_skip
            self._log('via holes: {}, skipped: {}',len(self.pcb.via),via_skip)

            if blind_holes and shape_type != 'solid':
                self._log('skip blind via holes: {}',len(blind_holes))
                blind_holes = None

        self._log('total holes added: {}',
                count+oval_count+len(self.pcb.via)-skip_count)

        objs = []
        if blind_holes or holes or ovals:
            if self.merge_holes:
                for o in ovals.values():
                    objs += o
                for o in holes.values():
                    objs += o
                if objs:
                    objs = func(objs,"holes")
            else:
                for r in ((ovals,'oval'),(holes,'hole')):
                    if not r[0]:
                        continue
                    for (width,rs) in r[0].items():
                        objs.append(func(rs,r[1]))

            if not npth:
                label=None
            elif npth>0:
                label='npth'
            else:
                label='th'

            if castellated:
                objs = self.intersectBoard(objs, 'holes', fit_arcs=True)

            if shape_type != 'solid':
                if not objs:
                    self._popLog('no holes')
                    return
                objs = self._makeCompound(objs,'holes',label=label)
            else:
                if board_thickness:
                    thickness = board_thickness
                else:
                    thickness = self.board_thickness
                thickness += extra_thickness
                pos = -0.01
                if npth >= -1:
                    # through the whole board, must add top copper thickness,
                    # because 'board_thickness' does not include top copper
                    # thickness.
                    thickness += self._stackup_map['F.Cu'][2]
                if objs:
                    objs = self._makeSolid(objs,'holes',thickness,label=label)
                if blind_holes:
                    if not isinstance(objs, (tuple, list)):
                        objs = [objs] if objs else []
                    for (_,d),o in blind_holes.items():
                        if npth >= -1:
                            d += extra_thickness
                        objs.append(self._makeSolid(func(o,'blind'),'blind',d,label=label))
                    objs = self._makeCompound(objs,'holes',label=label)
                self._place(objs,FreeCAD.Vector(0,0,pos))

        self._popLog('holes done')
        return objs


    def _cutHoles(self,objs,holes,name,label=None,fit_arcs=False,
                    minSize=0,maxSize=0,oval=True,npth=0,offset=0.0):
        if not holes:
            return objs

        if not isinstance(holes,(Part.Feature,Part.Shape)):
            hit = False
            if self.holes_cache is not None:
                key = '{}.{}.{}.{}.{}.{}.{}'.format(
                        self.add_feature,minSize,maxSize,oval,npth,offset,self.via_bound)
                doc = getActiveDoc();
                if self.add_feature and self.active_doc_uuid!=doc.Uid:
                    self.holes_cache.clear()
                    self.active_doc_uuid = doc.Uid

                try:
                    holes = self.holes_cache[key]
                    if self.add_feature:
                        # access the object's Name to make sure it is not
                        # deleted
                        self._log("fetch holes '{}' "
                            "from cache".format(holes.Name))
                    else:
                        self._log("fetch holes from cache")
                    hit = True
                except Exception:
                    pass

            if not hit:
                self._pushLog()
                holes = self.makeHoles(shape_type='wire',prefix=None,npth=npth,
                    minSize=minSize,maxSize=maxSize,oval=oval,offset=offset)
                self._popLog()

                if isinstance(self.holes_cache,dict):
                    self.holes_cache[key] = holes

        if not holes:
            return objs

        if not objs:
            return holes

        objs = (self._makeCompound(objs,name,label=label),holes)
        return self._makeArea(objs,name,op=1,label=label,fit_arcs=fit_arcs)

    def _makeCustomPad(self, params):
        wires = []
        anchor = getattr(getattr(params, 'options', None), 'anchor', None)
        if anchor in ('rect', 'circle'):
            w = globals()[f'make_{anchor}'](Vector(*params.size))
            wires.append(w)

        for key in params.primitives:
            primitives = SexpList(getattr(params.primitives, key))
            self._log(f'making {len(primitives)} {key}s')
            for param in primitives:
                wire,width = makePrimitve(key, param)
                if not width:
                    if isinstance(wire, Part.Edge):
                        wire = Part.Wire(wire)
                    wires.append(wire)
                else:
                    wire = self._makeWires(wire, name=None, offset=width*0.5)
                    wires += wire.Wires
        if not wires:
            return
        if len(wires) == 1:
            return wires[0]
        return Part.makeCompound(wires)

    def getTrackPoints(self):
        points = set()
        for tp,ss in (('segment',self.pcb.segment), ('arc',getattr(self.pcb, 'arc', []))):
            for s in ss:
                if self.filterNets(s):
                    continue
                if unquote(s.layer) == self.layer:
                    points.add((s.start[0], s.start[1]))
                    points.add((s.end[0], s.end[1]))
        return points

    def makePads(self,shape_type='face',thickness=0.05,holes=False,
            fit_arcs=True,prefix=''):

        self._pushLog('making pads...',prefix=prefix)

        def _wire(obj,name,label=None,fill=False):
            return self._makeWires(obj,name,fill=fill,label=label, offset=self.pad_inflate)

        def _face(obj,name,label=None):
            objs = _wire(obj,name,label,True)

            if not cut_wires and not cut_non_closed:
                return objs

            if not isinstance(objs, list):
                objs = [objs]

            inner_label = label + '_inner' if label else 'inner'
            if cut_wires:
                objs.append(self._makeWires(cut_wires,name,label=inner_label))

            for width,elist in cut_non_closed.items():
                l = '{}_{}'.format(inner_label, width)
                wire = self._makeWires(elist,name,label=l)
                # thicken non closed wire for hole cutting
                objs.append(self._makeArea(wire, name, label=l, offset = width*0.5))

            return self._makeArea(objs, name, op=1,fill=True)

        _solid = _face

        try:
            func = locals()['_{}'.format(shape_type)]
        except KeyError:
            raise ValueError('invalid shape type: {}'.format(shape_type))

        objs = []
        track_points = None

        def filter_unconnected(v, at):
            if 'remove_unused_layers' in v:
                for s in getattr(v, 'zone_layer_connections', []):
                    try:
                        if self.layer_type == self.findLayer(s)[0]:
                            return
                    except Exception:
                        pass
                nonlocal track_points
                if track_points is None:
                    track_points = self.getTrackPoints()
                if not at in track_points:
                    return True

        count = 0
        skip_count = 0
        for i,m in enumerate(self.pcb.module):
            ref = ''
            for t in m.fp_text:
                if t[0] == 'reference':
                    ref = t[1]
                    break;
            m_at,m_angle = getAt(m)
            pads = []
            count += len(m.pad)

            cut_wires = []
            cut_non_closed = defaultdict(list)

            self._pushLog('checking edge cuts')
            self._makeEdgeCuts(m, 'fp', cut_wires, cut_non_closed)
            self._popLog()

            for j,p in enumerate(m.pad):
                if self.filterNets(p) or self.filterLayer(p):
                    skip_count+=1
                    continue

                shape = p[2]

                if shape == 'custom':
                    w = self._makeCustomPad(p)
                else:
                    try:
                        make_shape = globals()['make_{}'.format(shape)]
                    except KeyError:
                        raise NotImplementedError(
                                'pad shape {} not implemented\n'.format(shape))
                    w = make_shape(Vector(*p.size),p)

                if not w:
                    continue

                # kicad put pad shape offset inside drill element? Why?
                if 'drill' in p and 'offset' in p.drill:
                    w.translate(makeVect(p.drill.offset))

                at,angle = getAt(p)
                angle -= m_angle;
                if not isZero(angle):
                    w.rotate(Vector(),Vector(0,0,1),angle)
                w.translate(at)

                if not self.merge_pads:
                    pads.append(func(w,'pad',
                        f'{i}#{j}#{p[0]}#{ref}#{self.netName(p)}#{shape}'))
                else:
                    pads.append(w)

            self._makeShape(m, 'fp', pads)

            if not pads:
                continue

            if not self.merge_pads:
                obj = self._makeCompound(pads,'pads','{}#{}'.format(i,ref))
            else:
                obj = func(pads,'pads','{}#{}'.format(i,ref))
            self._place(obj,m_at,m_angle)
            objs.append(obj)

        cut_wires = None
        cut_non_closed = None

        via_skip = 0
        via_unconnected = 0
        vias = []
        if self.via_bound < 0:
            via_skip = len(self.pcb.via)
        else:
            for i,v in enumerate(self.pcb.via):
                layers = [self.findLayer(s)[0] for s in v.layers]
                if self.layer_type < min(layers)\
                        or self.layer_type > max(layers)\
                        or self.filterNets(v):
                    via_skip += 1
                    continue

                if filter_unconnected(v, (v.at[0], v.at[1])):
                    via_unconnected += 1
                    continue

                if self.via_bound:
                    w = make_rect(Vector(v.size*self.via_bound,v.size*self.via_bound))
                else:
                    w = make_circle(Vector(v.size))
                w.translate(makeVect(v.at))
                if not self.merge_vias:
                    vias.append(func(w,'via','{}#{}'.format(i,v.size)))
                else:
                    vias.append(w)

        if vias:
            if self.merge_vias:
                objs.append(func(vias,'vias'))
            else:
                objs.append(self._makeCompound(vias,'vias'))

        self._log('footprints: {}',len(self.pcb.module))
        self._log('pads: {}, skipped: {}',count,skip_count)
        self._log('vias: {}, skipped: {}, unconnected: {}',len(self.pcb.via),via_skip,via_unconnected)
        self._log('total pads added: {}',
                count-skip_count+len(self.pcb.via)-via_skip-via_unconnected)

        if objs:
            if self.castellated:
                objs = self.intersectBoard(objs, 'pads', fit_arcs=fit_arcs)
            objs = self._cutHoles(objs,holes,'pads',fit_arcs=fit_arcs)
            if shape_type=='solid':
                objs = self._makeSolid(objs,'pads', thickness,
                                    fit_arcs = fit_arcs)
            else:
                objs = self._makeCompound(objs,'pads',
                                    fuse=True,fit_arcs=fit_arcs)
            self.setColor(objs,'pad')

        self._popLog('pads done')
        fitView();
        return objs


    def setColor(self,obj,otype):
        if not self.add_feature:
            return
        try:
            color = self.colors[otype][self.layer_type]
        except KeyError:
            color = self.colors[otype][0]
        if hasattr(obj.ViewObject,'MapFaceColor'):
            obj.ViewObject.MapFaceColor = False
        obj.ViewObject.ShapeColor = color


    def makeTracks(self,shape_type='face',fit_arcs=True,
                    thickness=0.05,holes=False,prefix=''):

        self._pushLog('making tracks...',prefix=prefix)

        width = 0
        def _line(edges,label,offset=0,fill=False):
            wires = findWires(edges)
            return self._makeWires(wires,'track', offset=offset,
                    fill=fill, label=label, fit_arcs=fit_arcs)

        def _wire(edges,label,fill=False):
            return _line(edges,label,width*0.5,fill)

        def _face(edges,label):
            return _wire(edges,label,True)

        _solid = _face

        try:
            func = locals()['_{}'.format(shape_type)]
        except KeyError:
            raise ValueError('invalid shape type: {}'.format(shape_type))

        tracks = defaultdict(lambda: defaultdict(list))
        count = 0
        for tp,ss in (('segment',self.pcb.segment), ('arc',getattr(self.pcb, 'arc', []))):
            for s in ss:
                if self.filterNets(s):
                    continue
                if unquote(s.layer) == self.layer:
                    if self.merge_tracks:
                        tracks[''][s.width].append((tp,s))
                    else:
                        tracks[self.netName(s)][s.width].append((tp,s))
                    count += 1

        objs = []
        i = 0
        for (name,sss) in tracks.items():
            for (width,ss) in sss.items():
                self._log('making {} tracks {} of width {:.2f}, ({}/{})',
                        len(ss),name,width,i,count)
                i+=len(ss)
                edges = []
                for tp,s in ss:
                    if tp == 'segment':
                        if s.start != s.end:
                            edges.append(Part.makeLine(
                                makeVect(s.start),makeVect(s.end)))
                        else:
                            self._log('Line (Track) through identical points {}',
                                    s.start, level="warning")
                    elif tp == 'arc':
                        if s.start == s.mid:
                            self._log('Arc (Track) with invalid point {}', s, level="warning")
                        elif s.start != s.end:
                            edges.append(Part.ArcOfCircle(
                                makeVect(s.end), makeVect(s.mid), makeVect(s.start)).toShape())
                        else:
                            start = makeVect(s.start)
                            middle = makeVect(s.mid)
                            r = start.distanceToPoint(middle)
                            edges.append(Part.makeCircle(r, (middle-start)/2))
                    else:
                        self._log('Unknown track type: {}', tp, level='warning')
                if self.merge_tracks:
                    label = '{}'.format(width)
                else:
                    label = '{}#{}'.format(width,name)
                objs.append(func(edges,label=label))

        if objs:
            if self.castellated:
                objs = self.intersectBoard(objs, 'tracks', fit_arcs=fit_arcs)
            objs = self._cutHoles(objs,holes,'tracks',fit_arcs=fit_arcs)

            if shape_type == 'solid':
                objs = self._makeSolid(objs,'tracks',thickness,
                                        fit_arcs=fit_arcs)
            else:
                objs = self._makeCompound(objs,'tracks',fuse=True,
                        fit_arcs=fit_arcs)

            self.setColor(objs,'track')

        self._popLog('tracks done')
        fitView();
        return objs

    def _makePolygons(self, fields, name, poly_holes,
            shape_type='face', thickness=0.05, prefix=''):

        if not fields:
            return []

        count = len(fields)
        self._pushLog(f'making {count} polygons...',prefix=prefix)

        def _wire(obj,fill=False):

            offset = self.zone_inflate + thickness*0.5

            if not poly_holes \
                    or (self.add_feature and self.make_sketch and self.zone_merge_holes):
                obj = [obj]+poly_holes
            elif poly_holes:
                obj = (self._makeWires(obj,f'{name}_outline'),
                       self._makeWires(poly_holes,f'{name}_hole'))
                return self._makeArea(obj,name,offset=offset, op=1, fill=fill)

            return self._makeWires(obj,name,fill=fill, offset=offset)


        def _face(obj):
            return _wire(obj,True)

        _solid = _face

        try:
            func = locals()['_{}'.format(shape_type)]
        except KeyError:
            raise ValueError('invalid shape type: {}'.format(shape_type))

        objs = []
        for idx,p in enumerate(fields):
            if (hasattr(p, 'layer') or hasattr(p, 'layers')) and self.filterLayer(p):
                continue
            poly_holes = []
            table = {}
            pts = SexpList(p.pts.xy)

            # close the polygon
            pts._append(p.pts.xy._get(0))

            # `table` uses a pair of vertex as the key to store the index of
            # an edge.
            for i in range(len(pts)-1):
                table[str((pts[i],pts[i+1]))] = i

            # This is how kicad represents holes in zone polygon
            #  ---------------------------
            #  |    -----      ----      |
            #  |    |   |======|  |      |
            #  |====|   |      |  |      |
            #  |    -----      ----      |
            #  |                         |
            #  ---------------------------
            # It uses a single polygon with coincide edges of oppsite
            # direction (shown with '=' above) to dig a hole. And one hole
            # can lead to another, and so forth. The following `build()`
            # function is used to recursively discover those holes, and
            # cancel out those '=' double edges, which will surely cause
            # problem if left alone. The algorithm assumes we start with a
            # point of the outer polygon.
            def build(start,end):
                results = []
                while start<end:
                    # We used the reverse edge as key to search for an
                    # identical edge of oppsite direction. NOTE: the
                    # algorithm only works if the following assumption is
                    # true, that those hole digging double edges are of
                    # equal length without any branch in the middle
                    key = str((pts[start+1],pts[start]))
                    try:
                        i = table[key]
                        del table[key]
                    except KeyError:
                        # `KeyError` means its a normal edge, add the line.
                        results.append(Part.makeLine(
                            makeVect(pts[start]),makeVect(pts[start+1])))
                        start += 1
                        continue

                    # We found the start of a double edge, treat all edges
                    # in between as holes and recurse. Both of the double
                    # edges are skipped.
                    h = build(start+1,i)
                    if h:
                        poly_holes.append(Part.Wire(h))
                    start = i+1
                return results

            edges = build(0,len(pts)-1)

            self._log('region {}/{}, holes: {}',idx+1,count,len(poly_holes))

            objs.append(func(Part.Wire(edges)))

            self._popLog()

        self._popLog(f'polygons done')
        return objs

    def makePolys(self,shape_type='face',thickness=0.05, fit_arcs=True, holes=False, prefix=''):
        '''For making outlier gr_poly as if it was zone, e.g. export from Gerber viewer
        '''
        poly_holes = []
        objs = self._makePolygons(getattr(self.pcb, 'gr_poly', None), 'poly',
                                    poly_holes, shape_type, thickness, prefix)
        if not objs:
            return

        objs = self._cutHoles(objs,holes,'polys')
        if shape_type == 'solid':
            objs = self._makeSolid(objs,'polys',thickness,fit_arcs=fit_arcs)
        else:
            objs = self._makeCompound(objs,'polys',
                            fuse=holes,fit_arcs=fit_arcs)
        self.setColor(objs,'zone')
        fitView();
        return objs

    def makeZones(self,shape_type='face',thickness=0.05, fit_arcs=True,
                    holes=False, prefix=''):

        self._pushLog('making zones...',prefix=prefix)

        z = None
        zone_holes = []
        objs = []
        for z in self.pcb.zone:
            if self.filterNets(z) or self.filterLayer(z):
                continue
            objs += self._makePolygons(z.filled_polygon, 'zone', zone_holes,
                                       shape_type, thickness, prefix)

        if objs:
            if self.castellated:
                objs = self.intersectBoard(objs, 'zones', fit_arcs=fit_arcs)
            objs = self._cutHoles(objs,holes,'zones')
            if shape_type == 'solid':
                objs = self._makeSolid(objs,'zones',thickness,fit_arcs=fit_arcs)
            else:
                objs = self._makeCompound(objs,'zones',
                                fuse=holes,fit_arcs=fit_arcs)
            self.setColor(objs,'zone')

        self._popLog('zones done')
        fitView();
        return objs


    def isBottomLayer(self):
        return self.layer_type == 31


    def makeCopper(self,shape_type='face',thickness=0.05,fit_arcs=True,
                    holes=False, z=0, prefix='',fuse=False):

        self._pushLog('making copper layer {}...',self.layer,prefix=prefix)

        holes = self._cutHoles(None,holes,None)

        objs = []

        if shape_type=='solid':
            solid = True
            sub_fit_arcs = fit_arcs
            if fuse:
                shape_type = 'face'
        else:
            solid = False
            sub_fit_arcs = False

        for (name,offset) in (('Pads',thickness),
                              ('Tracks',0.5*thickness),
                              ('Zones',0),
                              ('Polys',thickness)):

            obj = getattr(self,'make{}'.format(name))(fit_arcs=sub_fit_arcs,
                        holes=holes,shape_type=shape_type,prefix=None,
                        thickness=thickness)
            if not obj:
                continue
            if shape_type=='solid':
                ofs = offset if self.layer_type < 16 else -offset
                self._place(obj,Vector(0,0,ofs))
            objs.append(obj)

        if not objs:
            return

        if shape_type=='solid':
            self._log("making solid")
            obj = self._makeCompound(objs,'copper')
            self._log("done solid")
        else:
            obj = self._makeArea(objs,'copper',fit_arcs=fit_arcs)
            self.setColor(obj,'copper')
            if solid:
                self._log("making solid")
                obj = self._makeSolid(obj,'copper',thickness)
                self._log("done solid")
                self.setColor(obj,'copper')

        self._place(obj,Vector(0,0,z))

        self._popLog('done copper layer {}',self.layer)
        fitView();
        return obj


    def makeCoppers(self,shape_type='face',fit_arcs=True,prefix='',
            holes=False,board_thickness=None,thickness=None,fuse=False):

        self._pushLog('making all copper layers...',prefix=prefix)

        layer_save = self.layer
        objs = []
        layers = []
        thicknesses = []
        offsets = []

        if not board_thickness or not thickness:
            for layer, name in self._copperLayers():
                layers.append(layer)
                _,offset, t = self._stackup_map[name]
                offsets.append(offset)
                thicknesses.append(t)
        else:
            for layer, name in self._copperLayers():
                layers.append(layer)
                if not hasattr(thickness,'get'):
                    thicknesses.append(float(thickness))
                else:
                    for key in (layer, str(layer), name, None, ''):
                        try:
                            thicknesses.append(float(thickness.get(key)))
                            break
                        except Exception:
                            pass
                if not len(layers) == len(thicknesses):
                    raise RuntimeError('No copper thickness found for layer ' % name)

            if len(layers) == 1:
                z_step = 0
            else:
                z_step = (board_thickness+thicknesses[-1])/(len(layers)-1)
            offsets = [ board_thickness - i*z_step for i,_ in enumerate(layers) ]

        thickness = max(thicknesses)

        if not layers:
            raise ValueError('no copper layer found')

        if not holes:
            hole_shapes = None
        elif fuse:
            # make only npth holes
            hole_shapes = self._cutHoles(None,holes,None,npth=1)
        else:
            hole_shapes = self._cutHoles(None,holes,None)

        try:
            for layer,t,z in zip(layers, thicknesses, offsets):
                self.setLayer(layer)
                copper = self.makeCopper(shape_type,t,fit_arcs=fit_arcs,
                                    holes=hole_shapes,z=z,prefix=None,fuse=fuse)
                if copper:
                    objs.append(copper)
        finally:
            if layer_save:
                self.setLayer(layer_save)

        if not objs:
            self._popLog('no copper found')
            return

        if shape_type=='solid' and fuse:
            # make copper for plated through holes
            hole_coppers = self.makeHoles(shape_type='solid',prefix=None,
                oval=True,npth=-2,board_thickness=board_thickness,
                extra_thickness=thickness,castellated=self.castellated)
            if hole_coppers:
                self.setColor(hole_coppers,'copper')
                self._place(hole_coppers,FreeCAD.Vector(0,0,thickness*0.5))
                objs.append(hole_coppers);

            # connect coppers with pad with plated through holes, and fuse
            objs = self._makeFuse(objs,'coppers')
            self.setColor(objs,'copper')

            if holes:
                # make plated through holes with inward offset
                drills = self.makeHoles(shape_type='solid',prefix=None,
                        board_thickness=board_thickness,extra_thickness=1.1*thickness,
                        oval=True,npth=-1,offset=thickness,
                        skip_via=self.via_skip_hole)
                if drills:
                    self._place(drills,FreeCAD.Vector(0,0,-0.05*thickness))
                    objs = self._makeCut(objs,drills,'coppers')
                    self.setColor(objs,'copper')

        self._popLog('done making all copper layers')
        fitView();
        return objs


    def loadParts(self,z=0,combo=False,prefix=''):
        if not os.path.isdir(self.part_path):
            raise Exception('cannot find kicad package3d directory')

        self._pushLog('loading parts on layer {}...',self.layer,prefix=prefix)
        self._log('Kicad package3d path: {}',self.part_path)

        at_bottom = self.isBottomLayer()
        if z == 0:
            if at_bottom:
                z = -0.1
            else:
                z = self.pcb.general.thickness + 0.1

        if self.add_feature or combo:
            parts = []
        else:
            parts = {}

        for (module_idx,m) in enumerate(self.pcb.module):
            if unquote(m.layer) != self.layer:
                continue
            ref = '?'
            value = '?'
            for t in m.fp_text:
                if t[0] == 'reference':
                    ref = t[1]
                if t[0] == 'value':
                    value = t[1]

            m_at,m_angle = getAt(m)
            m_at += Vector(0,0,z)
            objs = []
            for (model_idx,model) in enumerate(m.model):
                path = os.path.splitext(model[0])[0]
                self._log('loading model {}/{} {} {} {}...',
                        model_idx,len(m.model), ref,value,model[0])
                for e in ('.stp','.STP','.step','.STEP'):
                    filename = os.path.join(self.part_path,path+e)
                    mobj = loadModel(filename)
                    if not mobj:
                        continue
                    at = product(Vector(*model.at.xyz),Vector(25.4,25.4,25.4))
                    rot = [-float(v) for v in reversed(model.rotate.xyz)]
                    pln = Placement(at,Rotation(*rot))
                    if not self.add_feature:
                        if combo:
                            obj = mobj[0].copy()
                            obj.Placement = pln
                        else:
                            obj = {'shape':mobj[0].copy(),'color':mobj[1]}
                            obj['shape'].Placement = pln
                        objs.append(obj)
                    else:
                        obj = self._makeObject('Part::Feature','model',
                            label='{}#{}#{}'.format(module_idx,model_idx,ref),
                            links='Shape',shape=mobj[0])
                        obj.ViewObject.DiffuseColor = mobj[1]
                        obj.Placement = pln
                        objs.append(obj)
                    self._log('loaded')
                    break

            if not objs:
                continue

            pln = Placement(m_at,Rotation(Vector(0,0,1),m_angle))
            if at_bottom:
                pln = pln.multiply(Placement(Vector(),
                                    Rotation(Vector(1,0,0),180)))

            label = '{}#{}'.format(module_idx,ref)
            if self.add_feature or combo:
                obj = self._makeCompound(objs,'part',label,force=True)
                obj.Placement = pln
                parts.append(obj)
            else:
                parts[label] = {'pos':pln, 'models':objs}

        if parts:
            if combo:
                parts = self._makeCompound(parts,'parts')
            elif self.add_feature:
                grp = self._makeObject('App::DocumentObjectGroup','parts')
                for o in parts:
                    grp.addObject(o)
                parts = grp

        self._popLog('done loading parts on layer {}',self.layer)
        fitView();
        return parts


    def loadAllParts(self,combo=False):
        logger.info("Loading parts...")
        layer = self.layer
        objs = []
        try:
            self.setLayer(0)
            objs.append(self.loadParts(combo=combo))
        except Exception as e:
            self._log('{}',e,level='error')
        try:
            self.setLayer(31)
            objs.append(self.loadParts(combo=combo))
        except Exception as e:
            self._log('{}',e,level='error')
        finally:
            self.setLayer(layer)
        fitView();
        return objs


    def make(self,copper_thickness=0.05,fit_arcs=True,load_parts=False,
            board_thickness=None, combo=True, fuseCoppers=False):

        self._pushLog('making pcb...',prefix='')

        if combo > 1:
            fuseCoppers = True

        objs = []
        board = self.makeBoard(prefix=None,thickness=board_thickness)
        if board:
            objs.append(board)

        coppers = self.makeCoppers(shape_type='solid',holes=True,prefix=None,
                fit_arcs=fit_arcs,thickness=copper_thickness,fuse=fuseCoppers,
                board_thickness=board_thickness)

        if coppers:
            if not fuseCoppers:
                objs += coppers
            else:
                objs.append(coppers)

        if load_parts:
            objs += self.loadAllParts(combo=True)

        if combo:
            layer = self.layer
            try:
                self.layer = None
                if combo > 1:
                    objs = self._makeFuse(objs,'pcb')
                else:
                    objs = self._makeCompound(objs,'pcb')
                if self.add_feature and load_parts:
                    try:
                        objs.ViewObject.SelectionStyle = 1
                    except Exception:
                        pass
            finally:
                self.setLayer(layer)

        self._popLog('all done')
        fitView();
        return objs

def getTestFile(name):
    import glob
    if not os.path.exists(name):
        path = os.path.dirname(os.path.abspath(__file__))
        path = os.path.join(path,'tests')
        if name:
            path = os.path.join(path,name)
    else:
        path = name
    if os.path.isdir(path):
        return glob.glob(os.path.join(path,'*.kicad_pcb'))
    if os.path.isfile(path):
        return [path]
    path += '.kicad_pcb'
    if os.path.isfile(path):
        return [path]
    raise RuntimeError('Cannot find {}'.format(name))

def test(names=''):
    if not isinstance(names,(tuple,list)):
        names = [names]
    files = set()
    for name in names:
        files.update(getTestFile(name))
    for f in files:
        pcb = KicadFcad(f)
        pcb.make()
        pcb.make(fuseCoppers=True)
        pcb.add_feature = False
        Part.show(pcb.make())