def vertex():
x, y = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
outs = ' VERTEX at ({:.2f}, {:.2f})'.format(x, y)
if 42 in e:
v = math.degrees(math.atan(float(dx.bycode(e, 42))) * 4)
outs += ', curve angle {:.1f}°'.format(v)
print(outs)
def vertex():
x, y = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
outs = ' VERTEX at ({:.2f}, {:.2f})'.format(x, y)
if 42 in e:
v = math.degrees(math.atan(float(dx.bycode(e, 42))) * 4)
outs += ', curve angle {:.1f}°'.format(v)
print(outs)
def arc():
xc, yc, R = (float(dx.bycode(e, 10)), float(dx.bycode(e, 20)), float(dx.bycode(e, 40)))
sa, ea = float(dx.bycode(e, 50)), float(dx.bycode(e, 51))
sar, ear = math.radians(sa), math.radians(ea)
xs, ys = xc + R * math.cos(sar), yc + R * math.sin(sar)
xe, ye = xc + R * math.cos(ear), yc + R * math.sin(ear)
outs = ' ARC from ({:.2f}, {:.2f}) to ({:.2f}, {:.2f})'
print(outs.format(xs, ys, xe, ye))
outs = ' centered at ({:.2f}, {:.2f}), ' \
'radius {:.2f}, from {:.1f}° to {:.1f}°'
print(outs.format(xc, yc, R, sa, ea))
def arc():
xc, yc, R = (float(dx.bycode(e, 10)), float(dx.bycode(e, 20)),
float(dx.bycode(e, 40)))
sa, ea = float(dx.bycode(e, 50)), float(dx.bycode(e, 51))
sar, ear = math.radians(sa), math.radians(ea)
xs, ys = xc + R * math.cos(sar), yc + R * math.sin(sar)
xe, ye = xc + R * math.cos(ear), yc + R * math.sin(ear)
outs = ' ARC from ({:.2f}, {:.2f}) to ({:.2f}, {:.2f})'
print(outs.format(xs, ys, xe, ye))
outs = ' centered at ({:.2f}, {:.2f}), ' \
'radius {:.2f}, from {:.1f}° to {:.1f}°'
print(outs.format(xc, yc, R, sa, ea))
def arc(e):
cx, cy = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
R = fr(dx.bycode(e, 40))
sa, ea = (math.radians(float(dx.bycode(e, 50))), math.radians(float(dx.bycode(e, 51))))
if ea > sa:
da = ea - sa
else:
da = 2 * math.pi - sa + ea
if DEVLIM > R:
cnt = 1
else:
maxstep = 2 * math.acos(1 - DEVLIM / R)
if da < 0:
maxstep = -maxstep
cnt = math.ceil(da / maxstep)
step = da / cnt
angs = [sa + i * step for i in range(cnt + 1)]
pnts = [(fr(cx + R * math.cos(a)), fr(cy + R * math.sin(a))) for a in angs]
return pnts
def arc(e):
cx, cy = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
R = fr(dx.bycode(e, 40))
sa, ea = (math.radians(float(dx.bycode(e, 50))),
math.radians(float(dx.bycode(e, 51))))
if ea > sa:
da = ea - sa
else:
da = 2 * math.pi - sa + ea
if DEVLIM > R:
cnt = 1
else:
maxstep = 2 * math.acos(1 - DEVLIM / R)
if da < 0:
maxstep = -maxstep
cnt = math.ceil(da / maxstep)
step = da / cnt
angs = [sa + i * step for i in range(cnt + 1)]
pnts = [(fr(cx + R * math.cos(a)), fr(cy + R * math.sin(a)))
for a in angs]
return pnts
def printent(e, v):
"""Print a DXF entity"""
def line():
xs, ys = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
xe, ye = float(dx.bycode(e, 11)), float(dx.bycode(e, 21))
outs = ' LINE from ({:.2f}, {:.2f}) to ({:.2f}, {:.2f})'
print(outs.format(xs, ys, xe, ye))
def arc():
xc, yc, R = (float(dx.bycode(e, 10)), float(dx.bycode(e, 20)), float(dx.bycode(e, 40)))
sa, ea = float(dx.bycode(e, 50)), float(dx.bycode(e, 51))
sar, ear = math.radians(sa), math.radians(ea)
xs, ys = xc + R * math.cos(sar), yc + R * math.sin(sar)
xe, ye = xc + R * math.cos(ear), yc + R * math.sin(ear)
outs = ' ARC from ({:.2f}, {:.2f}) to ({:.2f}, {:.2f})'
print(outs.format(xs, ys, xe, ye))
outs = ' centered at ({:.2f}, {:.2f}), ' \
'radius {:.2f}, from {:.1f}° to {:.1f}°'
print(outs.format(xc, yc, R, sa, ea))
def polyline():
print(' POLYLINE')
def vertex():
x, y = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
outs = ' VERTEX at ({:.2f}, {:.2f})'.format(x, y)
if 42 in e:
v = math.degrees(math.atan(float(dx.bycode(e, 42))) * 4)
outs += ', curve angle {:.1f}°'.format(v)
print(outs)
def endseq():
print(' ENDSEQ')
printdict = {
'LINE': line,
'ARC': arc,
'POLYLINE': polyline,
'VERTEX': vertex,
'SEQEND': endseq
}
k = dx.bycode(e, 0)
try:
printdict[k]()
except KeyError:
if v:
print(' {} entity: {}'.format(k, e))
else:
print(' {} entity'.format(k))
def printent(e, v):
"""Print a DXF entity"""
def line():
xs, ys = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
xe, ye = float(dx.bycode(e, 11)), float(dx.bycode(e, 21))
outs = ' LINE from ({:.2f}, {:.2f}) to ({:.2f}, {:.2f})'
print(outs.format(xs, ys, xe, ye))
def arc():
xc, yc, R = (float(dx.bycode(e, 10)), float(dx.bycode(e, 20)),
float(dx.bycode(e, 40)))
sa, ea = float(dx.bycode(e, 50)), float(dx.bycode(e, 51))
sar, ear = math.radians(sa), math.radians(ea)
xs, ys = xc + R * math.cos(sar), yc + R * math.sin(sar)
xe, ye = xc + R * math.cos(ear), yc + R * math.sin(ear)
outs = ' ARC from ({:.2f}, {:.2f}) to ({:.2f}, {:.2f})'
print(outs.format(xs, ys, xe, ye))
outs = ' centered at ({:.2f}, {:.2f}), ' \
'radius {:.2f}, from {:.1f}° to {:.1f}°'
print(outs.format(xc, yc, R, sa, ea))
def polyline():
print(' POLYLINE')
def vertex():
x, y = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
outs = ' VERTEX at ({:.2f}, {:.2f})'.format(x, y)
if 42 in e:
v = math.degrees(math.atan(float(dx.bycode(e, 42))) * 4)
outs += ', curve angle {:.1f}°'.format(v)
print(outs)
def endseq():
print(' ENDSEQ')
printdict = {
'LINE': line,
'ARC': arc,
'POLYLINE': polyline,
'VERTEX': vertex,
'SEQEND': endseq
}
k = dx.bycode(e, 0)
try:
printdict[k]()
except KeyError:
if v:
print(' {} entity: {}'.format(k, e))
else:
print(' {} entity'.format(k))
def output(ifn, ofn, entities, args):
opts = []
if args.contours:
opts = ['contours']
if args.markers:
opts.append('markers')
sorters = {'xy': utils.bbxykey, 'yx': utils.bbyxkey, 'dist': utils.distkey}
sortkey = sorters[args.sort]
if not args.alllayers:
layers = dxf.numberedlayers(entities)
entities = [e for e in entities if dxf.bycode(e, 8) in layers]
else:
layers = dxf.layernames(entities)
num = len(entities)
if num == 0:
logging.info("no entities found! Skipping file '{}'.".format(ifn))
return
logging.info('{} entities found'.format(num))
allsegments = lines.mksegments(entities)
bboxes = [lines.bbox(s) for s in allsegments]
minx, miny, maxx, maxy = lines.merge_bbox(bboxes)
out, ctx = plot.setup(ofn, minx, miny, maxx, maxy)
plot.grid(ctx, minx, miny, maxx, maxy)
for layername in layers:
thislayer = dxf.fromlayer(entities, layername)
segments = lines.mksegments(thislayer)
ls = '{} entities found in layer "{}".'
logging.info(ls.format(len(thislayer), layername))
logging.info('plotting the entities')
if args.contours:
closedseg, openseg = lines.combine_segments(segments)
fs = '{} {} segments in layer "{}"'
for a, b in (('closed', closedseg), ('open', openseg)):
logging.info(fs.format(len(b), a, layername))
openseg.sort(key=sortkey)
plot.lines(ctx, openseg, marks=args.markers)
closedseg.sort(key=sortkey)
plot.lines(ctx, closedseg, marks=args.markers)
else:
fs = '{} segments in layer "{}"'
logging.info(fs.format(len(segments), layername))
plot.lines(ctx, segments, marks=args.markers)
plot.title(ctx, 'dxf2pdf', ofn, maxy - miny, options=opts)
out.show_page()
logging.info('writing output file "{}"'.format(ofn))
out.finish()
logging.info('file "{}" done.'.format(ifn))
def output(ifn, ofn, entities, args):
opts = []
if args.contours:
opts = ['contours']
if args.markers:
opts.append('markers')
sorters = {'xy': utils.bbxykey, 'yx': utils.bbyxkey, 'dist': utils.distkey}
sortkey = sorters[args.sort]
if not args.alllayers:
layers = dxf.numberedlayers(entities)
entities = [e for e in entities if dxf.bycode(e, 8) in layers]
else:
layers = dxf.layernames(entities)
num = len(entities)
if num == 0:
logging.info("no entities found! Skipping file '{}'.".format(ifn))
return
logging.info('{} entities found'.format(num))
allsegments = lines.mksegments(entities)
bboxes = [lines.bbox(s) for s in allsegments]
minx, miny, maxx, maxy = lines.merge_bbox(bboxes)
out, ctx = plot.setup(ofn, minx, miny, maxx, maxy)
plot.grid(ctx, minx, miny, maxx, maxy)
for layername in layers:
thislayer = dxf.fromlayer(entities, layername)
segments = lines.mksegments(thislayer)
ls = '{} entities found in layer "{}".'
logging.info(ls.format(len(thislayer), layername))
logging.info('plotting the entities')
if args.contours:
closedseg, openseg = lines.combine_segments(segments)
fs = '{} {} segments in layer "{}"'
for a, b in (('closed', closedseg), ('open', openseg)):
logging.info(fs.format(len(b), a, layername))
openseg.sort(key=sortkey)
plot.lines(ctx, openseg, marks=args.markers)
closedseg.sort(key=sortkey)
plot.lines(ctx, closedseg, marks=args.markers)
else:
fs = '{} segments in layer "{}"'
logging.info(fs.format(len(segments), layername))
plot.lines(ctx, segments, marks=args.markers)
plot.title(ctx, 'dxf2pdf', ofn, maxy - miny, options=opts)
out.show_page()
logging.info('writing output file "{}"'.format(ofn))
out.finish()
logging.info('file "{}" done.'.format(ifn))
def main():
"""
Entry point for dxf2nc.py.
"""
args = process_arguments()
sorters = {'xy': utils.bbxykey, 'yx': utils.bbyxkey, 'dist': utils.distkey}
sortkey = sorters[args.sort]
lines.epsilon = args.dist
for f in utils.xpand(args.files):
logging.info('Starting file "{}"'.format(f))
try:
ofn = utils.outname(f, extension='.nc')
data = dx.parse(f)
entities = dx.entities(data)
except ValueError as ex:
logging.info(str(ex))
fns = "error during processing. Skipping file '{}'."
logging.error(fns.format(f))
continue
except IOError as ex:
logging.info(str(ex))
logging.error("i/o error in file '{}'. Skipping it.".format(f))
continue
layers = dx.numberedlayers(entities)
entities = [e for e in entities if dx.bycode(e, 8) in layers]
num = len(entities)
if num == 0:
logging.info("no entities found! Skipping file '{}'.".format(f))
continue
logging.info('{} entities found.'.format(num))
out = gerbernc.Writer(ofn)
for layername in layers:
out.newpiece()
thislayer = dx.fromlayer(entities, layername)
ls = '{} entities found in layer "{}".'
logging.info(ls.format(len(thislayer), layername))
segments = lines.mksegments(thislayer)
fs = '{} segments in layer "{}"'
logging.info(fs.format(len(segments), layername))
if args.contours:
cut_contours(segments, out, layername, sortkey)
else:
segments.sort(key=sortkey)
cut_segments(segments, out)
out.write()
def main():
"""
Entry point for dxf2nc.py.
"""
args = process_arguments()
sorters = {'xy': utils.bbxykey, 'yx': utils.bbyxkey, 'dist': utils.distkey}
sortkey = sorters[args.sort]
lines.epsilon = args.dist
for f in utils.xpand(args.files):
logging.info('Starting file "{}"'.format(f))
try:
ofn = utils.outname(f, extension='.nc')
data = dx.parse(f)
entities = dx.entities(data)
except ValueError as ex:
logging.info(str(ex))
fns = "error during processing. Skipping file '{}'."
logging.error(fns.format(f))
continue
except IOError as ex:
logging.info(str(ex))
logging.error("i/o error in file '{}'. Skipping it.".format(f))
continue
layers = dx.numberedlayers(entities)
entities = [e for e in entities if dx.bycode(e, 8) in layers]
num = len(entities)
if num == 0:
logging.info("no entities found! Skipping file '{}'.".format(f))
continue
logging.info('{} entities found.'.format(num))
out = gerbernc.Writer(ofn)
for layername in layers:
out.newpiece()
thislayer = dx.fromlayer(entities, layername)
ls = '{} entities found in layer "{}".'
logging.info(ls.format(len(thislayer), layername))
segments = lines.mksegments(thislayer)
fs = '{} segments in layer "{}"'
logging.info(fs.format(len(segments), layername))
if args.contours:
cut_contours(segments, out, layername, sortkey)
else:
segments.sort(key=sortkey)
cut_segments(segments, out)
out.write()
def main():
"""
Entry point for dxfgerber.py.
"""
args = process_arguments()
sorters = {'xy': utils.bbxykey, 'yx': utils.bbyxkey, 'dist': utils.distkey}
sortkey = sorters[args.sort]
lines.epsilon = args.dist
for f in utils.xpand(args.files):
logging.info('starting file "{}"'.format(f))
try:
ofn = utils.outname(f, extension='.dxf', addenum='_mod')
data = dx.parse(f)
entities = dx.entities(data)
except ValueError as ex:
logging.info(str(ex))
fns = "error during processing. Skipping file '{}'."
logging.error(fns.format(f))
continue
except IOError as ex:
logging.info(str(ex))
logging.error("i/o error in file '{}'. Skipping it.".format(f))
continue
layers = dx.numberedlayers(entities)
entities = [e for e in entities if dx.bycode(e, 8) in layers]
num = len(entities)
if num == 0:
logging.info("no entities found! Skipping file '{}'.".format(f))
continue
logging.info('{} entities found.'.format(num))
with open(ofn, 'w') as out:
out.write(dxfheader)
for layername in layers:
thislayer = dx.fromlayer(entities, layername)
ls = '{} entities found in layer "{}".'
logging.info(ls.format(num, layername))
segments = lines.mksegments(thislayer)
fs = '{} segments in layer "{}"'
logging.info(fs.format(len(segments), layername))
write_allseg(segments, out, layername, sortkey)
out.write(dxffooter)
def main():
"""
Entry point for dxfgerber.py.
"""
args = process_arguments()
sorters = {'xy': utils.bbxykey, 'yx': utils.bbyxkey, 'dist': utils.distkey}
sortkey = sorters[args.sort]
lines.epsilon = args.dist
for f in utils.xpand(args.files):
logging.info('starting file "{}"'.format(f))
try:
ofn = utils.outname(f, extension='.dxf', addenum='_mod')
data = dx.parse(f)
entities = dx.entities(data)
except ValueError as ex:
logging.info(str(ex))
fns = "error during processing. Skipping file '{}'."
logging.error(fns.format(f))
continue
except IOError as ex:
logging.info(str(ex))
logging.error("i/o error in file '{}'. Skipping it.".format(f))
continue
layers = dx.numberedlayers(entities)
entities = [e for e in entities if dx.bycode(e, 8) in layers]
num = len(entities)
if num == 0:
logging.info("no entities found! Skipping file '{}'.".format(f))
continue
logging.info('{} entities found.'.format(num))
with open(ofn, 'w') as out:
out.write(dxfheader)
for layername in layers:
thislayer = dx.fromlayer(entities, layername)
ls = '{} entities found in layer "{}".'
logging.info(ls.format(num, layername))
segments = lines.mksegments(thislayer)
fs = '{} segments in layer "{}"'
logging.info(fs.format(len(segments), layername))
write_allseg(segments, out, layername, sortkey)
out.write(dxffooter)
def line(e):
return [(fr(dx.bycode(e, 10)), fr(dx.bycode(e, 20))),
(fr(dx.bycode(e, 11)), fr(dx.bycode(e, 21)))]
def line():
xs, ys = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
xe, ye = float(dx.bycode(e, 11)), float(dx.bycode(e, 21))
outs = ' LINE from ({:.2f}, {:.2f}) to ({:.2f}, {:.2f})'
print(outs.format(xs, ys, xe, ye))
def line(e):
return [
(fr(dx.bycode(e, 10)), fr(dx.bycode(e, 20))),
(fr(dx.bycode(e, 11)), fr(dx.bycode(e, 21)))
]
def mksegments(entities, ndigits=3):
"""
Convert an iterable of entities to a list of line segments.
Arguments:
entities: An iterable if dictionaries, each containing a DXF entity.
ndigits: Rounds to ndigits after the decimal point.
Returns:
A list of line segments. Line segments are lists of ≥2 (x,y) tuples.
"""
def fr(n):
return round(float(n), ndigits)
def line(e):
return [
(fr(dx.bycode(e, 10)), fr(dx.bycode(e, 20))),
(fr(dx.bycode(e, 11)), fr(dx.bycode(e, 21)))
]
def arc(e):
cx, cy = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
R = fr(dx.bycode(e, 40))
sa, ea = (math.radians(float(dx.bycode(e, 50))), math.radians(float(dx.bycode(e, 51))))
if ea > sa:
da = ea - sa
else:
da = 2 * math.pi - sa + ea
if DEVLIM > R:
cnt = 1
else:
maxstep = 2 * math.acos(1 - DEVLIM / R)
if da < 0:
maxstep = -maxstep
cnt = math.ceil(da / maxstep)
step = da / cnt
angs = [sa + i * step for i in range(cnt + 1)]
pnts = [(fr(cx + R * math.cos(a)), fr(cy + R * math.sin(a))) for a in angs]
return pnts
# Convert lines
lines = [line(e) for e in entities if dx.bycode(e, 0) == 'LINE']
# Convert arcs
lines += [arc(e) for e in entities if dx.bycode(e, 0) == 'ARC']
# Convert polylines
pi = [n for n, e in enumerate(entities) if dx.bycode(e, 0) == 'POLYLINE']
se = [n for n, e in enumerate(entities) if dx.bycode(e, 0) == 'SEQEND']
for start in pi:
end = [n for n in se if n > start][0]
poly = entities[start:end]
points = [(fr(dx.bycode(e, 10)), fr(dx.bycode(e, 20))) for e in poly[1:]]
angles = [math.atan(float(dx.bycode(e, 42))) * 4 if 42 in e else None for e in poly[1:]]
if 70 in poly[0] and (int(dx.bycode(poly[0], 70)) & 1): # closed
points.append(points[0])
ends = zip(points, points[1:], angles)
addition = [points[0]]
for sp, ep, a in ends:
if a:
arcent = _arcdata(sp, ep, a)
addition += arc(arcent)[1:]
else:
addition.append(ep)
lines += [addition]
# Convert lwpolylines
return lines
def mksegments(entities, ndigits=3):
"""
Convert an iterable of entities to a list of line segments.
Arguments:
entities: An iterable if dictionaries, each containing a DXF entity.
ndigits: Rounds to ndigits after the decimal point.
Returns:
A list of line segments. Line segments are lists of ≥2 (x,y) tuples.
"""
def fr(n):
return round(float(n), ndigits)
def line(e):
return [(fr(dx.bycode(e, 10)), fr(dx.bycode(e, 20))),
(fr(dx.bycode(e, 11)), fr(dx.bycode(e, 21)))]
def arc(e):
cx, cy = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
R = fr(dx.bycode(e, 40))
sa, ea = (math.radians(float(dx.bycode(e, 50))),
math.radians(float(dx.bycode(e, 51))))
if ea > sa:
da = ea - sa
else:
da = 2 * math.pi - sa + ea
if DEVLIM > R:
cnt = 1
else:
maxstep = 2 * math.acos(1 - DEVLIM / R)
if da < 0:
maxstep = -maxstep
cnt = math.ceil(da / maxstep)
step = da / cnt
angs = [sa + i * step for i in range(cnt + 1)]
pnts = [(fr(cx + R * math.cos(a)), fr(cy + R * math.sin(a)))
for a in angs]
return pnts
# Convert lines
lines = [line(e) for e in entities if dx.bycode(e, 0) == 'LINE']
# Convert arcs
lines += [arc(e) for e in entities if dx.bycode(e, 0) == 'ARC']
# Convert polylines
pi = [n for n, e in enumerate(entities) if dx.bycode(e, 0) == 'POLYLINE']
se = [n for n, e in enumerate(entities) if dx.bycode(e, 0) == 'SEQEND']
for start in pi:
end = [n for n in se if n > start][0]
poly = entities[start:end]
points = [(fr(dx.bycode(e, 10)), fr(dx.bycode(e, 20)))
for e in poly[1:]]
angles = [
math.atan(float(dx.bycode(e, 42))) * 4 if 42 in e else None
for e in poly[1:]
]
if 70 in poly[0] and (int(dx.bycode(poly[0], 70)) & 1): # closed
points.append(points[0])
ends = zip(points, points[1:], angles)
addition = [points[0]]
for sp, ep, a in ends:
if a:
arcent = _arcdata(sp, ep, a)
addition += arc(arcent)[1:]
else:
addition.append(ep)
lines += [addition]
# Convert lwpolylines
return lines
def line():
xs, ys = float(dx.bycode(e, 10)), float(dx.bycode(e, 20))
xe, ye = float(dx.bycode(e, 11)), float(dx.bycode(e, 21))
outs = ' LINE from ({:.2f}, {:.2f}) to ({:.2f}, {:.2f})'
print(outs.format(xs, ys, xe, ye))
