def createdat(spacing):
##### Down Aisle Ties
tie = dxf.block(name='tie')
dwg.blocks.add(tie)
# calculate tie length
datx = ((bays + 1) * upx) + (bays * (((bay - 1) * upgap) + (bay * maxx) + ((bay - 1) * palgap)))
blockfaces(tie, datx, daty, datz, 0, 0, 0)
# Create ties for all levels
for m in range(levels):
levelheight = datz + palz + loadz + lift
lh = levelheight * m
# Outer loop to create all the aisles
for l in range(aisles):
# Calc distance between aisles
#spacing = (2 * maxy) + aislew + backgap + (2 * (maxy + deepgap) * ydeep)
aisle2 = spacing * l
# create outer tie
blockref1 = dxf.insert(blockname='tie', layer='CLT_RAK_Pallet_Rack', insert=((0,(aislew/2)+(maxy/2)+(up2up/2)+upy+aisle2, lapproach-datz+lh)))
dwg.add(blockref1)
# create inter tie
blockref2 = dxf.insert(blockname='tie', layer='CLT_RAK_Pallet_Rack', insert=((0,(aislew/2)+(maxy/2)-(up2up/2)-upy-daty+aisle2, lapproach-datz+lh)))
dwg.add(blockref2)
# create outer tie (opposite)
blockref1 = dxf.insert(blockname='tie', layer='CLT_RAK_Pallet_Rack', insert=((0,0-(aislew/2)-(maxy/2)-(up2up/2)-upy-daty+aisle2, lapproach-datz+lh)))
dwg.add(blockref1)
# create inter tie (opposite)
blockref2 = dxf.insert(blockname='tie', layer='CLT_RAK_Pallet_Rack', insert=((0,0-(aislew/2)-(maxy/2)+(up2up/2)+upy+aisle2, lapproach-datz+lh)))
dwg.add(blockref2)
def createuprights(spacing):
##### Uprights
upright = dxf.block(name='upright')
dwg.blocks.add(upright)
# calculate upright height
upz = lapproach + (levels * (palz + loadz + lift + datz)) - datz - lift + uapproach
blockfaces(upright, upx, upy, upz, 0, 0, 0)
# Outer loop to create all the aisles
for l in range(aisles):
# Calc distance between aisles
#spacing = (2 * maxy) + aislew + backgap + (2 * (maxy + deepgap) * ydeep)
aisle2 = spacing * l
# Inner loop to create one aisle
for k in range(bays+1):
# calculate bay length
blen = upx + ((bay - 1) * upgap) + (bay * maxx) + ((bay - 1) * palgap)
blength = blen * k
# create inner upright
blockref1 = dxf.insert(blockname='upright', layer='CLT_RAK_Pallet_Rack', insert=((blength,(aislew/2)+(maxy/2)+(up2up/2)+aisle2, 0)))
dwg.add(blockref1)
# create outer upright
blockref2 = dxf.insert(blockname='upright', layer='CLT_RAK_Pallet_Rack', insert=((blength,(aislew/2)+(maxy/2)-(up2up/2)-upy+aisle2, 0)))
dwg.add(blockref2)
# create inner upright (opposite)
blockref1 = dxf.insert(blockname='upright', layer='CLT_RAK_Pallet_Rack', insert=((blength,0-(aislew/2)-(maxy/2)+(up2up/2)+aisle2, 0)))
dwg.add(blockref1)
# create outer upright (opposite)
blockref2 = dxf.insert(blockname='upright', layer='CLT_RAK_Pallet_Rack', insert=((blength,0-(aislew/2)-(maxy/2)-(up2up/2)-upy+aisle2, 0)))
dwg.add(blockref2)
def SaveDXF(self):
# Creates a dxf-file with the name written in the FileInput widget, adding the extension .dxf if it's not
# present. Then creates a polyline entity in that file resembling the planned trajectory of the list, ignoring
# all instructions in the list other than those with the 'go to: '-tag. Finally, the list of the ActionInputBox
# widget is refreshed.
filename = self._widget.FileInput.text()
l = len(filename)
if l > 3:
if filename[(l-4):l] != '.dxf':
filename = filename + '.dxf'
else:
filename = filename + '.dxf'
drawing = dxfE.drawing(self.pwd + '/src/kampala/gui/src/gui/DXFFiles/' + filename)
trajectory_points = []
for point in self.pointlist:
if point[0] == 'go to: ':
trajectory_points.append(point[1])
drawing.add(dxfE.polyline(trajectory_points))
drawing.save()
self.filelist = os.listdir(self.pwd + '/src/kampala/gui/src/gui/DXFFiles')
self._widget.DXFInputBox.clear()
self._widget.DXFInputBox.insertItems(0,self.filelist)
def ScaleBarCreation(fs, text_h, drawing):
# lenght of 1 cm scalebar
fs1 = fs / 100
drawing.add_layer('scale_bar', color=7)
# insertion point of scale bar
x0 = 10.
y0 = -20.
z0 = 0.
P0 = (x0, y0, z0)
P1 = (x0, y0 + (fs1 / 20.), z0)
P2 = ((x0 + fs1), y0, z0)
P3 = ((x0 + fs1), y0 + (fs1 / 20.), z0)
line1 = dxf.line(P0, P1)
line1['layer'] = 'scale_bar'
drawing.add(line1)
line2 = dxf.line(P0, P2)
line2['layer'] = 'scale_bar'
drawing.add(line2)
line3 = dxf.line(P2, P3)
line3['layer'] = 'scale_bar'
drawing.add(line3)
text = dxf.text('0', P1, height=text_h)
text['layer'] = 'scale_bar'
drawing.add(text)
text = dxf.text('1 cm', P3, height=text_h)
text['layer'] = 'scale_bar'
drawing.add(text)
def createpallets(spacing):
##### Pallets
pallet = dxf.block(name='pallet')
dwg.blocks.add(pallet)
blockfaces(pallet, palx, paly, palz, 0, 0, 0)
# Outermost loop for creating levels
for m in range(levels):
levelheight = datz + palz + loadz + lift
lh = levelheight * m
# Outer loop to create all the aisles
for l in range(aisles):
# Calc distance between aisles
#spacing = (2 * maxy) + aislew + backgap + (2 * (maxy + deepgap) * ydeep)
aisle2 = spacing * l
# Inner loop to create one aisle
for k in range(bays):
# calculate bay length
blen = upx + ((bay - 1) * upgap) + (bay * maxx) + ((bay - 1) * palgap)
blength = blen * k
# create first bay
for i in range(bay):
blockref = dxf.insert(blockname='pallet', layer='CLT_PLT_Pallet', insert=(upx+upgap+(maxx/2)-(palx/2)+(i*(maxx + palgap))+blength,(aislew/2)+(maxy/2)-(paly/2)+aisle2,lapproach+lh))
dwg.add(blockref)
# create opposite side
for j in range(bay):
blockref = dxf.insert(blockname='pallet', layer='CLT_PLT_Pallet', insert=(upx+upgap+(maxx/2)-(palx/2)+(j*(maxx + palgap))+blength,0-(aislew/2)-(maxy/2)-(paly/2)+aisle2,lapproach+lh))
dwg.add(blockref)
def generate_template_trophy(h1, h2, w, drawing):
"""
Generates a outline around all the tropies on the drawing given. (c) shovel
"""
drawing.add(dxf.line((0, 0), (600,0), color=255, layer='LINES', thickness=0.00))
drawing.add(dxf.line((600, 0), (600,450), color=255, layer='LINES', thickness=0.00))
drawing.add(dxf.line((600,450), (0,450), color=255, layer='LINES', thickness=0.00))
drawing.add(dxf.line((0,450), (0,0), color=255, layer='LINES', thickness=0.00))
refpoint = generate_ref_trophy(h1, h2, w)
for i in refpoint[:4]:
x,y = i
draw(x,y,x+h1,y,drawing)
draw(x,y,x,y-w,drawing)
draw(x,y-w,x+h2,y-w,drawing)
draw(x+h1,y,x+h2,y-w,drawing)
for i in refpoint[4:8]:
x,y=i
draw(x,y,x-h1,y,drawing)
draw(x,y,x,y+w,drawing)
draw(x,y+w,x-h2,y+w,drawing)
draw(x-h2,y+w,x-h1,y,drawing)
x,y = refpoint[-2]
draw(x,y,x,y+h1,drawing)
draw(x,y,x+w,y,drawing)
draw(x+w,y,x+w,y+h2,drawing)
draw(x+w,y+h2,x,y+h1,drawing)
x,y = refpoint[-1]
draw(x,y,x,y-h1,drawing)
draw(x,y,x-w,y,drawing)
draw(x-w,y,x-w,y-h2,drawing)
draw(x-w,y-h2,x,y-h1,drawing)
def color_square(x, y, color=None, bgcolor=None):
if color:
name = color_name(color)
if bgcolor:
name = color_name(bgcolor)
drawing.add(dxf.rectangle((x, y) , 2, 2, color=color, bgcolor=bgcolor))
drawing.add(dxf.text(name, (x, y-0.4), height=0.18))
def __init__(self,
wafer,
chipID,
w=40,
l=1500,
pad_extend=1000,
offset=(0, 0),
overhang=80):
m.BlankCenteredWR10.__init__(self, wafer, chipID, wafer.defaultLayer,
offset)
#put in holes to define a resistance bar
#self.add(dxf.rectangle((-pad_extend+offset[0],0),pad_extend+self.width/2-l/2,self.height,bgcolor=wafer.bg(wafer.defaultLayer)))
#self.add(dxf.rectangle((self.width/2 + l/2+offset[0],0),pad_extend+self.width/2-l/2,self.height,bgcolor=wafer.bg(wafer.defaultLayer)))
self.add(
dxf.rectangle(self.centered((0, -w / 2)),
l,
self.height / 2 - w / 2 + overhang,
halign=const.CENTER,
valign=const.BOTTOM,
bgcolor=wafer.bg(wafer.defaultLayer)))
self.add(
dxf.rectangle(self.centered((0, w / 2)),
l,
self.height / 2 - w / 2 + overhang,
halign=const.CENTER,
valign=const.TOP,
bgcolor=wafer.bg(wafer.defaultLayer)))
def SaveDXF(self):
# Creates a dxf-file with the name written in the FileInput widget, adding the extension .dxf if it's not
# present. Then creates a polyline entity in that file resembling the planned trajectory of the list, ignoring
# all instructions in the list other than those with the 'go to: '-tag. Finally, the list of the ActionInputBox
# widget is refreshed.
filename = self._widget.FileInput.text()
l = len(filename)
if l > 3:
if filename[(l - 4):l] != '.dxf':
filename = filename + '.dxf'
else:
filename = filename + '.dxf'
drawing = dxfE.drawing(self.pwd +
'/src/kampala/gui/src/gui/DXFFiles/' + filename)
trajectory_points = []
for point in self.pointlist:
if point[0] == 'go to: ':
trajectory_points.append(point[1])
drawing.add(dxfE.polyline(trajectory_points))
drawing.save()
self.filelist = os.listdir(self.pwd +
'/src/kampala/gui/src/gui/DXFFiles')
self._widget.DXFInputBox.clear()
self._widget.DXFInputBox.insertItems(0, self.filelist)
def __init__(self,
wafer,
chipID,
w=40,
l=1500,
pad_extend=1000,
offset=(0, 0)):
m.BlankCenteredWR10.__init__(self, wafer, chipID, wafer.defaultLayer,
offset)
#put in a resistance bar
self.add(
dxf.rectangle((-pad_extend + offset[0], 0),
pad_extend + self.width / 2 - l / 2,
self.height,
bgcolor=wafer.bg(wafer.defaultLayer)))
self.add(
dxf.rectangle((self.width / 2 + l / 2 + offset[0], 0),
pad_extend + self.width / 2 - l / 2,
self.height,
bgcolor=wafer.bg(wafer.defaultLayer)))
self.add(
dxf.rectangle(self.centered((-l / 2, -w / 2)),
l,
w,
bgcolor=wafer.bg(wafer.defaultLayer)))
def generate_dxf(root_path, session_id, lines_dict, sheet_length):
x_offset = int(sheet_length * 1.1)
y_offset = 30
keys = lines_dict.keys()
drawing = dxf.drawing(root_path + "/data/" + session_id + '/cutout.dxf')
drawing.add_layer('LINES')
for i in range(len(keys)):
key = keys[i]
for line in lines_dict[key]:
start = (line[0][0] + x_offset * i, line[0][1] + y_offset)
end = (line[1][0] + x_offset * i, line[1][1] + y_offset)
drawing.add(dxf.line(start, end, color=7, layer='LINES'))
drawing.add_layer('TEXTLAYER', color=2)
for i in range(len(keys)):
key = keys[i]
drawing.add(
dxf.text(key,
insert=(i * x_offset, 0),
layer='TEXTLAYER',
height=25))
drawing.add_vport('*ACTIVE',
upper_right=(100, 100),
center_point=(50, 50),
grid_spacing=(1, 1),
snap_spacing=(1, 1),
aspect_ratio=20)
drawing.save()
def std_linetypes(self):
""" Create standard linetypes.
"""
return [DXFEngine.linetype(
name, description=desc,
pattern=DXFEngine.linepattern(pat))
for name, desc, pat in std.linetypes()]
def __init__(self,
wafer,
chipID,
layer,
structures=None,
defaults=None,
FRAME_NAME='FRAME'):
self.wafer = wafer
self.width = wafer.chipX - wafer.sawWidth
self.height = wafer.chipY - wafer.sawWidth
self.chipID = chipID #string (usually)
self.ID = 'CHIP_' + str(chipID)
self.solid = wafer.solid
self.frame = wafer.frame
self.layer = layer
if defaults is None:
self.defaults = {}
else:
self.defaults = defaults.copy()
#setup centering
self.center = (self.width / 2, self.height / 2)
#initialize the block
self.chipBlock = dxf.block(self.ID)
#setup structures
if structures is not None:
self.structures = structures
#add a debug frame for actual chip area
if wafer.frame:
self.add(
dxf.rectangle((0, 0),
self.width,
self.height,
layer=wafer.lyr(FRAME_NAME)))
def arrow(bottom_point,arrow_point, length_arrow = 3):
drawing.add(dxf.line(bottom_point,arrow_point, color= 7))
vertex = arrow_point
left_pt = (arrow_point[0] - length_arrow / 6.0 , arrow_point[1] - length_arrow )
right_pt = (arrow_point[0] + length_arrow / 6.0 , arrow_point[1] - length_arrow)
drawing.add(dxf.trace([vertex, left_pt, right_pt]))
return
def create_dxf(p):
drawing = dxf.drawing('test.dxf')
drawing.add_layer('OUTLINE', color=1)
polyline = dxf.polyline(layer="OUTLINE")
polyline.add_vertices(p)
drawing.add(polyline)
drawing.save()
def color_square(x, y, color=None, bgcolor=None):
if color:
name = color_name(color)
if bgcolor:
name = color_name(bgcolor)
drawing.add(dxf.rectangle((x, y), 2, 2, color=color, bgcolor=bgcolor))
drawing.add(dxf.text(name, (x, y - 0.4), height=0.18))
def Draw(p):
lay=0
path=p['path']
n=p['nodes']
d=p['drawing']
rx=p['position'][0]
ry=p['position'][1]
if 'layer' in p.keys(): lay=p['layer']
for c in path:
if c[0]=='line':
d.add(dxf.line((rx+n[c[1]][0],ry+n[c[1]][1]),
(rx+n[c[2]][0],ry+n[c[2]][1]),layer=lay))
elif c[0]=='arc':
cr=geo.CircleFrom3Points(n[c[1]],n[c[3]],n[c[2]])
if cr['Direction']<0:
d.add(dxf.arc(center=(rx+cr['Center'][0],ry+cr['Center'][1]),
radius=cr['Radius'],
startangle=math.degrees(cr['P1Degree']),
endangle=math.degrees(cr['P3Degree']),
layer=lay))
else:
d.add(dxf.arc(center=(rx+cr['Center'][0],ry+cr['Center'][1]),
radius=cr['Radius'],
startangle=math.degrees(cr['P3Degree']),
endangle=math.degrees(cr['P1Degree']),
layer=lay))
elif c[0]=='circle':
rds=n[c[2]][0]-n[c[1]][0]
d.add(dxf.circle(rds,(rx+n[c[1]][0],ry+n[c[1]][1]),layer=lay))
def dxfmaker(Bdata, prof, rim, cup):
Bmatrix2 = [(
float(x[0]),
float(x[1]),
) for x in Bdata]
prof2 = [(
float(x[0]),
float(x[1]),
) for x in prof]
rim2 = [(
float(x[0]),
float(x[1]),
) for x in rim]
cup2 = [(
float(x[0]),
float(x[1]),
) for x in cup]
drawing = dxf.drawing('drawing.dxf')
polyline = dxf.polyline(linetype='LINE')
polyline.add_vertices(Bmatrix2)
polyline.add_vertices(prof2)
polyline.add_vertices(rim2)
polyline.add_vertices(cup2)
drawing.add(polyline)
drawing.save()
return
def save_traced_scene(self,dxf_file):
""" write geometry and traced rays to a DXF file for your viewing pleasure. It's no fun with more than a few 100 rays though.
>1000 rays look like sonic the sea urchin."""
drawing = dxf.drawing(dxf_file)
drawing.add_layer('Rays', color=3)
drawing.add_layer('Geometry', color=5)
print "Writing results as DXF file."
for res in self.results:
rays_origin = res[0]
rays_dest = res[1]
#draw rays to dxf
for (r0,rd) in zip(rays_origin,rays_dest):
drawing.add(dxf.face3d([r0[0:3],
rd[0:3],
rd[0:3]], layer="Rays"))
#draw facets
(m_v0,m_v1,m_v2)=self.geometry
for (t0,t1,t2) in zip(m_v0,m_v1,m_v2):
drawing.add(dxf.face3d([t0[0:3],
t1[0:3],
t2[0:3]], layer="Geometry"))
drawing.save()
def writeDXF(self):
fname = self.ui.lineEditOutputDXF.text()
file = open(fname, 'w')
rad = 0.25
scale = 1.0
col = 7
dec = self.ui.spinBoxDecimal.value()
dwg = dxf.drawing(fname)
# create block
scalarsymbol = dxf.block(name='symbol')
scalarsymbol.add( dxf.circle(radius=rad, color=0) )
# define some attributes
scalarsymbol.add( dxf.attdef(insert=(1.25, -1.25), tag='VAL1', height=1.25, color=0) )
# add block definition to the drawing
dwg.blocks.add(scalarsymbol)
for nID in self.points:
x = self.points[nID][0]
y = self.points[nID][1]
val1 = self.points[nID][2]
values = {'VAL1': "%.{0}f".format(dec) % val1}
dwg.add(dxf.insert2(blockdef=scalarsymbol, insert=(x, y),
attribs=values,
xscale=scale,
yscale=scale,
layer='0',
color = col))
dwg.save()
def run(fpfile, dxffile): # read the input floorplan fp = fp_io.Floorplan(fpfile) # prepare the output dxf file drawing = dxf.drawing(dxffile) # iterate over the rooms of the floor plan for room_id in range(fp.num_rooms): # make a layer for this room room_layer_name = 'room_' + str(room_id+1) room_layer = dxf.layer(room_layer_name) room_layer['color'] = 1+room_id # valid colors: [1,255] drawing.layers.add(room_layer) # generate the objects for this room obj_arr = room_to_polylines(fp, room_id) # draw each object in the room for pi in range(len(obj_arr)): # add each object to the drawing obj_arr[pi]['layer'] = room_layer_name obj_arr[pi]['color'] = 256 # color by layer obj_arr[pi]['paper_space'] = 0 # put in model space drawing.add(obj_arr[pi]) # save the drawing to file drawing.save()
def export_sections_dxf(self, graph, filename):
with self.connect() as con:
cur = con.cursor()
cur.execute("""
with hole_idx as (
select s.id as section_id, h.id as hole_id
from _albion.named_section as s
join _albion.hole as h on s.geom && h.geom and st_intersects(s.geom, st_startpoint(h.geom))
)
select st_collectionhomogenize(st_collect(ef.geom))
from albion.all_edge as e
join hole_idx as hs on hs.hole_id = e.start_
join hole_idx as he on he.hole_id = e.end_ and he.section_id = hs.section_id
join albion.edge_face as ef on ef.start_ = e.start_ and ef.end_ = e.end_ and not st_isempty(ef.geom)
where ef.graph_id='{}'
""".format(graph))
drawing = dxf.drawing(filename)
m = wkb.loads(bytes.fromhex(cur.fetchone()[0]))
for p in m:
r = p.exterior.coords
drawing.add(
dxf.face3d(
[tuple(r[0]), tuple(r[1]),
tuple(r[2])], flags=1))
drawing.save()
def toDXF(self):
output = io.StringIO()
drawing = dxf.drawing('drawing.dxf')
for id in self.Scene:
if self.Scene[id]['Class'] == 'PATH':
path = self.Scene[id]['Path']
for i in range(0, len(path.geometries)):
geo = path.geo(i)
geo.writeDXF(drawing, self.Scene[id]['Position'])
if self.Scene[id]['Class'] == 'GEO':
geo = self.Scene[id]['Geo']
geo.writeDXF(drawing, self.Scene[id]['Position'])
if self.Scene[id]['Class'] == 'TXT':
text = dxf.text(
self.Scene[id]['Txt'],
height=self.Scene[id]['Height'],
)
text['insert'] = (self.Scene[id]['Position'][0],
self.Scene[id]['Position'][1])
text['layer'] = 'TEXT'
text['color'] = 7
drawing.add(text)
drawing.save_to_fileobj(output)
dxf_result = output.getvalue()
return dxf_result
def tgates_side_mirror(layer, tgate_to_nw, tgate_tip_width, tgate_tip_height,
tgate_taper_width,
blockname): #plungers on just one side of the nanowire
block = dxf.block(blockname, layer=layer)
block.add(
dxf.rectangle((-tgate_tip_width / 2, -tgate_to_nw - tgate_taper_width),
tgate_tip_width,
tgate_taper_width,
rotation=0,
layer=layer))
block.add(
dxf.rectangle((-tgate_taper_width / 2,
-tgate_to_nw - tgate_taper_width - tgate_tip_height),
tgate_taper_width,
tgate_tip_height,
rotation=0,
layer=layer))
# block.add(dxf.rectangle((-tgate_tip_width/2,+tgate_to_nw),
# tgate_tip_width, tgate_taper_width, rotation = 0, layer = layer))
# block.add(dxf.rectangle((-tgate_taper_width/2, +tgate_to_nw+tgate_taper_width),
# tgate_taper_width, tgate_tip_height, rotation = 0, layer = layer))
return block # creating the block
def __init__(self, wafer, chipID, pad, notch, globalOffset=(0, 0)):
m.BlankCenteredWR10.__init__(self, wafer, chipID, wafer.defaultLayer,
globalOffset)
self.wr10x = 2540 + 2 * pad
self.wr10y = 1270 + 2 * pad
color = wafer.bg(wafer.defaultLayer)
#positive regions define metal
self.add(
dxf.rectangle((self.cx(-self.wr10x / 2), 0),
self.wr10x,
self.cy(-self.wr10y / 2),
bgcolor=color))
self.add(
dxf.rectangle((0, self.height),
self.width,
self.cy(self.wr10y / 2 - self.height),
bgcolor=color))
self.add(
dxf.rectangle((0, notch),
self.cx(-self.wr10x / 2),
self.cy(self.wr10y / 2 - notch),
bgcolor=color))
self.add(
dxf.rectangle((self.cx(self.wr10x / 2), 0),
-self.cx(self.wr10x / 2 - self.width),
self.cy(self.wr10y / 2),
bgcolor=color))
def draw(s, outfile):
# Create image
drawing = dxf.drawing(s.OUTFILE + outfile)
drawing.add_layer('layer', color=1)
# Draw text
if s.includeText:
text = ''
text += ''.join(map(str, s.startBand))
text += '-'
text += ''.join(map(str, s.code))
text += '-'
text += ''.join(map(str, s.stopBand))
drawing.add(dxf.text(text, height=s.unitWidth))
# Initial offset
xOffset = (s.size[0] - s.barWidth) / 2
yOffset = (s.size[1] - s.barcodeLen) / 2
# Draw notches
for d in s.digits:
newOffset = s.drawBar(drawing, d, xOffset, yOffset)
yOffset = newOffset[1]
# Draw final notch
s.drawNotch(drawing, xOffset, yOffset)
drawing.save()
def arc(self, end, center, layer=None):
if self.enable:
r = xyDist(end, center)
if self.svg is not None:
self.path.push_arc(self.scaleOffset(end), 0, r, \
large_arc=True, angle_dir='+', \
absolute=True)
if self.d is not None:
if layer is None:
layer = self.lPath
else:
if not layer in self.definedLayers:
self.definedLayers[layer] = True
self.d.add_layer(layer, color=self.color, lineweight=0)
p0 = self.last
p1 = end
if xyDist(p0, p1) < MIN_DIST:
self.d.add(dxf.circle(r, center, layer=layer))
else:
# dprt("p0 (%7.4f, %7.4f) p1 (%7.4f, %7.4f)" % \
# (p0[0], p0[1], p1[0], p1[1]))
# if orientation(p0, center, p1) == CCW:
# (p0, p1) = (p1, p0)
a0 = degrees(calcAngle(center, p0))
a1 = degrees(calcAngle(center, p1))
if a1 == 0.0:
a1 = 360.0
# dprt("a0 %5.1f a1 %5.1f" % (a0, a1))
self.d.add(dxf.arc(r, center, a0, a1, layer=layer))
self.last = end
def render_contour(self,
drawing,
contour_lines,
compute_point_fn,
layer_postfix=""):
# loop through the contour lines adding them
for contour_line in contour_lines:
line = contour_line.get("vertices")
contour_detail = {"layer": "Contour"}
# get the contour line settings and apply them
if self.settings["job"].get("contours") and self.settings["job"][
"contours"][contour_line.get("type")]:
contour_settings = self.settings["job"]["contours"][
contour_line.get("type")]
for x in ["color", "thickness", "linetype", "layer"]:
if contour_settings.get(x):
contour_detail[x] = contour_settings.get(x)
contour_detail["layer"] = self.filter_layer_name(
str(contour_detail["layer"]) + layer_postfix)
if contour_line.get("type") == "major":
drawing.add(
dxf.text(line[0][1],
compute_point_fn(line[len(line) / 2]),
height=0.5,
rotation=-90,
**contour_detail))
contour = dxf.polyline(**contour_detail)
contour.add_vertices([compute_point_fn(p) for p in line])
drawing.add(contour)
def export_elementary_volume_dxf(self,
graph_id,
cell_ids,
outdir,
closed_only=False):
with self.connect() as con:
cur = con.cursor()
cur.execute("""
select cell_id, row_number() over(partition by cell_id order by closed desc), geom, closed
from (
select cell_id, triangulation as geom, albion.is_closed_volume(triangulation) as closed
from albion.volume
where cell_id in ({}) and graph_id='{}'
) as t
""".format(','.join(["'{}'".format(c) for c in cell_ids]),
graph_id))
for cell_id, i, wkb_geom, closed in cur.fetchall():
geom = wkb.loads(bytes.fromhex(wkb_geom))
if closed_only and not closed:
continue
filename = '{}_{}_{}_{}.dxf'.format(
cell_id, graph_id, "closed" if closed else "opened", i)
path = os.path.join(outdir, filename)
drawing = dxf.drawing(path)
for p in geom:
r = p.exterior.coords
drawing.add(
dxf.face3d([tuple(r[0]),
tuple(r[1]),
tuple(r[2])],
flags=1))
drawing.save()
def create_dxf(filename):
dxf_drawing = dxf.drawing(filename)
for y in range(0, 5):
x = 0
dxf_drawing.add(dxf.circle(radius=y, center=(x, y * 2)))
dxf_drawing.save()
def four_c(A, length, rotation):
dwg.add(
dxf.clothoid(start=(2, 2),
length=length,
paramA=A,
rotation=rotation,
color=1))
dwg.add(
dxf.clothoid(start=(2, 2),
mirror='x',
length=length,
paramA=A,
rotation=rotation,
color=2))
dwg.add(
dxf.clothoid(start=(2, 2),
mirror='y',
length=length,
paramA=A,
rotation=rotation,
color=3))
dwg.add(
dxf.clothoid(start=(2, 2),
mirror='xy',
length=length,
paramA=A,
rotation=rotation,
color=4))
def getLabelDxf(self, for_prime_center=True):
x = self.getPosition()[0] - self.getWidth()/2
y = self.getPosition()[1] - self.getHeight()/2
width = self.getWidth()
height = self.getHeight()
# if self.isCoupage() and (height > width) and height <= self.getGridWidth():
# # rotate when more optimal
# width = self.getHeight()
# height = self.getWidth()
if for_prime_center == True:
x = Helper.toMillimeters(x)
y = Helper.toMillimeters(y)
width = Helper.toMillimeters(width)
height = Helper.toMillimeters(width)
text = dxf.text(str(self.getClientName()), (y, x + width), 100.0, rotation=0)
text['layer'] = 'TEXT'
text['color'] = '7'
else:
text = dxf.text(str(self.getClientName()), (x, y + height), 10.0, rotation=0)
text['layer'] = 'TEXT'
text['color'] = '7'
return text
def getRectangleDxf(self, for_prime_center=True):
x = self.getPosition()[0] - self.getWidth()/2
y = self.getPosition()[1] - self.getHeight()/2
width = self.getWidth()
height = self.getHeight()
# if self.isCoupage() and (height > width) and height <= self.getGridWidth():
# # rotate when more optimal
# width = self.getHeight()
# height = self.getWidth()
if for_prime_center == True:
x = Helper.toMillimeters(x)
y = Helper.toMillimeters(y)
width = Helper.toMillimeters(width)
height = Helper.toMillimeters(height)
bgcolor = random.randint(1,255)
return dxf.rectangle((y,x), height, width,
bgcolor=bgcolor)
else:
bgcolor = random.randint(1,255)
return dxf.rectangle((x, y), width, height,
bgcolor=bgcolor)
def raith_alignment_marker(layer, w_r, pw_r, cc_x,
cc_y): #program does nothing as written
#questions: does the layer name have to be a string?
#In this case, the alignment marker elionix block will always be called the elionix block
cc = [cc_x, cc_y]
block = dxf.block("alignmentmarker_raith",
layer=layer) # creating the block
block.add(
dxf.rectangle((cc[0] - pw_r / 2, cc[1] - w_r / 2, 0),
pw_r,
w_r,
rotation=0,
layer=layer)) # long vertical
block.add(
dxf.rectangle((cc[0] - w_r / 2, cc[1] - pw_r / 2, 0),
(w_r - 2 - pw_r) / 2,
pw_r,
rotation=0,
layer=layer)) # short horizonal left
block.add(
dxf.rectangle((cc[0] + pw_r / 2, cc[1] - pw_r / 2, 0),
(w_r - 2 - pw_r) / 2,
pw_r,
rotation=0,
layer=layer)) # short horiztonal right
# add block-definition to drawing
#drawing.blocks.add(block_name)
print("I DID IT RAITH")
return block
def arrow(bottom_point,arrow_point, length_arrow = 3):
drawing.add(dxf.line(bottom_point,arrow_point, color= 7))
vertex = arrow_point
left_pt = (arrow_point[0] - length_arrow / 6.0 , arrow_point[1] - length_arrow )
right_pt = (arrow_point[0] + length_arrow / 6.0 , arrow_point[1] - length_arrow)
drawing.add(dxf.trace([vertex, left_pt, right_pt]))
return
def plungers_side_mirror(
layer, plunger_to_nw, plunger_tip_width, plunger_tip_height,
plunger_taper_width,
blockname): #plungers on just one side of the nanowire
block = dxf.block(blockname, layer=layer)
taper = dxf.polyline(layer=layer)
taper.add_vertices([
(-plunger_tip_width / 2, -plunger_to_nw),
(plunger_tip_width / 2, -plunger_to_nw),
(plunger_taper_width / 2, -plunger_tip_height - plunger_to_nw),
(-plunger_taper_width / 2, -plunger_tip_height - plunger_to_nw)
])
taper.close(True)
block.add(taper)
taper_top = dxf.polyline(layer=layer)
taper_top.add_vertices([
(-plunger_tip_width / 2, plunger_to_nw),
(plunger_tip_width / 2, plunger_to_nw),
(plunger_taper_width / 2, plunger_tip_height + plunger_to_nw),
(-plunger_taper_width / 2, plunger_tip_height + plunger_to_nw)
])
taper_top.close(True)
block.add(taper_top)
return block
def output_dxf(box, material, cnc, filename):
""" Output the drawing """
drawing = dxf.drawing(filename)
drawing.add_layer('TOP')
top = dxf.polyline(flags=const.POLYLINE_CLOSED, layer='TOP')
top.add_vertices([(0, 0),
(box.length, 0),
(box.length, box.width),
(0, box.width)])
drawing.add(top)
drawing.add_layer('BOTTOM')
bottom = dxf.polyline(flags=const.POLYLINE_CLOSED, layer='BOTTOM')
bottom_coord = [(0, 0),
(box.length, 0),
(box.length, box.width),
(0, box.width)]
bottom_coord = [ (x + box.length + margin, y) for x,y in bottom_coord ]
bottom.add_vertices(bottom_coord)
drawing.add(bottom)
drawing.add_layer('SIDE')
side = dxf.polyline(flags=const.POLYLINE_CLOSED, layer='SIDE')
perimeter = (box.length + box.width)*2
side_coord = [(0, 0),
(perimeter, 0),
(perimeter, box.height),
(0, box.height)]
side_coord = [ (x + 2*(box.length + margin), y) for x,y in side_coord ]
side.add_vertices(side_coord)
drawing.add(side)
drawing.save()
def double_dot_etch_block(layer, starting_gap, window_length, etch_window_1,
island_1, etch_window_2, island_2, etch_window_3,
blockname):
block = dxf.block(blockname, layer=layer) # creating the block
x_etch_position = starting_gap
block.add(
dxf.rectangle((x_etch_position, -window_length / 2),
etch_window_1,
window_length,
rotation=0,
layer=layer))
x_etch_position = starting_gap + etch_window_1 + island_1
block.add(
dxf.rectangle((x_etch_position, -window_length / 2),
etch_window_2,
window_length,
rotation=0,
layer=layer))
x_etch_position = starting_gap + etch_window_1 + island_1 + etch_window_2 + island_2
block.add(
dxf.rectangle((x_etch_position, -window_length / 2),
etch_window_3,
window_length,
rotation=0,
layer=layer)) # short horiztonal right
# add block-definition to drawing
#drawing.blocks.add(block_name)
print("I DID IT ETCH BLOCK")
return block
def block(length, height, inner_height, inner_length):
block_lx = -length / 2
block_rx = length / 2
block_y = float(elem1[1])
vertical_depth = (length - inner_length) / 2
drawing.add(
dxf.line((block_lx, block_y), (block_rx, block_y),
color=75,
layer='Block'))
block_height = block_y + height
horizontal_depth = height - inner_height
inner_lx = block_lx + vertical_depth
inner_rx = block_rx - vertical_depth
inner_y = block_y + horizontal_depth
blockList = [(block_lx, block_y), (block_rx, block_y),
(block_rx, block_height), (inner_rx, block_height),
(inner_rx, inner_y), (inner_lx, inner_y),
(inner_lx, block_height), (block_lx, block_height),
(block_lx, block_y)]
drawing.add(dxf.polyline(blockList, color=75, layer='Block'))
return blockList
def material(self, xSize, ySize):
if self.svg is not None:
self.offset = 0.0
path = self.materialPath
if path is None:
self.materialPath = Path(stroke_width=.5, stroke='red', \
fill='none')
path = self.materialPath
path.push('M', (self.scaleOffset((0, 0))))
path.push('L', (self.scaleOffset((xSize, 0))))
path.push('L', (self.scaleOffset((xSize, ySize))))
path.push('L', (self.scaleOffset((0, ySize))))
path.push('L', (self.scaleOffset((0, 0))))
self.path.push('M', (self.scaleOffset((0, 0))))
# dwg = svgwrite.Drawing(name, (svg_size_width, svg_size_height), \
# debug=True)
cfg = self.cfg
if self.d is not None:
orientation = cfg.orientation
if orientation == O_UPPER_LEFT:
p0 = (0.0, 0.0)
p1 = (xSize, 0.0)
p2 = (xSize, -ySize)
p3 = (0.0, -ySize)
elif orientation == O_LOWER_LEFT:
p0 = (0.0, 0.0)
p1 = (xSize, 0.0)
p2 = (xSize, ySize)
p3 = (0.0, ySize)
elif orientation == O_UPPER_RIGHT:
p0 = (0.0, 0.0)
p1 = (-xSize, 0.0)
p2 = (-xSize, -ySize)
p3 = (0.0, -ySize)
elif orientation == O_LOWER_RIGHT:
p0 = (0.0, 0.0)
p1 = (-xSize, 0.0)
p2 = (-xSize, ySize)
p3 = (0.0, ySize)
elif orientation == O_CENTER:
p0 = (-xSize / 2, -ySize / 2)
p1 = (xSize / 2, -ySize / 2)
p2 = (xSize / 2, ySize / 2)
p3 = (-xSize / 2, ySize / 2)
elif orientation == O_POINT:
dxfInput = cfg.dxfInput
p0 = (dxfInput.xMin, dxfInput.yMin)
p1 = (dxfInput.xMin, dxfInput.yMax)
p2 = (dxfInput.xMax, dxfInput.yMax)
p3 = (dxfInput.xMax, dxfInput.yMin)
else:
ePrint("invalid orientation")
self.d.add(dxf.line(p0, p1, layer=self.lBorder))
self.d.add(dxf.line(p1, p2, layer=self.lBorder))
self.d.add(dxf.line(p2, p3, layer=self.lBorder))
self.d.add(dxf.line(p3, p0, layer=self.lBorder))
def create_dxf(self, file_path, polyline_controller, model, calib_controller):
""" Creates a DXF file at the given 'file_path' location """
if polyline_controller:
# Create a DXF object
drawing = dxf.drawing(file_path)
points = []
# Header information
self.add_header(drawing, '$ACADVER', 'AC1014')
# Add the polylines
drawing.add_layer('POLYLINES', color=2)
# DGZ 16 Aug 2012
# Bug fix for DXF y-axis flipping error
# code provided by Adam Childs
# Convert (0, 0) to bottom-left instead of upper-left for drill program
#
sY, sX = model.get_image_shape()
# Loops through all polylines
for polyline in polyline_controller.polylines:
# Loops through all verticies of each polyline
for vertex in polyline.verticies:
try:
x = int(vertex.get_xdata())
y = int(vertex.get_ydata())
except TypeError:
# This error is thrown when one of the user's polylines goes outside the coordinates of the image.
# For some reason (that I'm not sure of at the moment), the data is put into a 1 element list. So
# the fix is to just take the 0th element of the list and then cast it to an integer...
#
# Adam Childs (11/17/2012)
x = int(vertex.get_xdata()[0])
y = int(vertex.get_ydata()[0])
y = sY - y
x /= float(calib_controller.pixels_per_unit)
y /= float(calib_controller.pixels_per_unit)
# Set the units in mm
if calib_controller.unit == 'cm':
x *= 10
y *= 10
elif calib_controller.unit == 'in':
x *= 25.4
y *= 25.4
points.append((x, y))
# Adds the points to a polyline object, which is added to the DXF file
drawing.add(dxf.polyline(points))
points = [] # Reset points for the next polyline to use
drawing.save()
else:
wx.MessageBox('No polylines have been found. Please add some.', 'No polylines!', wx.OK | wx.ICON_ERROR)
return
def dxflist_example(x=0, y=0, w=1, h=1):
# dxf list can contain any dxf entity, that supports __dxf__()
rect = dxfwrite.DXFList()
rect.append(dxf.line(start=(x, y), end=(x + w, y), color=1))
rect.append(dxf.line(start=(x + w, y), end=(x + w, y + h), color=2))
rect.append(dxf.line(start=(x + w, y + h), end=(x, y + h), color=3))
rect.append(dxf.line(start=(x, y + h), end=(x, y), color=4))
return rect
def WriteDXF(filename, lines, elevations, scaler):
drawing = DXFEngine.drawing(filename)
for idx in xrange(len( lines )):
points = []
for point in lines[idx]:
points.append(scaler.inverse((point[0], point[1])))
drawing.add(DXFEngine.polyline(points, polyline_elevation = (0,0,elevations[idx])))
drawing.save()
def addToDrawing(self, drawing, layer='0'): Shape.addToDrawing(self, drawing, layer) if not self.error: if self.p.reverse: arc = dxf.arc(self.p.radius, self.p.centerPoint, self.p.endAngle, self.p.startAngle, layer = '0') else: arc = dxf.arc(self.p.radius, self.p.centerPoint, self.p.startAngle, self.p.endAngle, layer = '0') drawing.add(arc)
def dxflist_example(x=0, y=0, w=1, h=1):
# dxf list can contain any dxf entity, that supports __dxf__()
rect = dxfwrite.DXFList()
rect.append(dxf.line(start=(x, y), end=(x+w, y), color=1))
rect.append(dxf.line(start=(x+w, y), end=(x+w, y+h), color=2))
rect.append(dxf.line(start=(x+w, y+h), end=(x, y+h), color=3))
rect.append(dxf.line(start=(x, y+h), end=(x, y), color=4))
return rect
def draw_involutes(self, d):
"""draw all the involutes"""
rot = rot_matrix(self.ap)
for i in range(self.n):
d.add(dxf.polyline(self.seg_lower))
d.add(dxf.polyline(self.seg_upper))
self.seg_upper = [mult_matrix(rot, p) for p in self.seg_upper]
self.seg_lower = [mult_matrix(rot, p) for p in self.seg_lower]
def draw_radials(self, d):
"""draw all radials"""
rot = rot_matrix(self.ap)
for i in range(self.n):
d.add(dxf.polyline(self.seg_r_upper))
d.add(dxf.polyline(self.seg_r_lower))
self.seg_r_upper = [mult_matrix(rot, p) for p in self.seg_r_upper]
self.seg_r_lower = [mult_matrix(rot, p) for p in self.seg_r_lower]
def draw_crosshair(d, location, size = 0.125):
"""add a crosshair to a drawing"""
x = location[0]
y = location[1]
delta = size / 2.0
s1 = ((x-delta, y), (x+delta, y))
s2 = ((x, y-delta), (x, y+delta))
d.add(dxf.polyline(s1))
d.add(dxf.polyline(s2))
def four_c(A, length, rotation):
dwg.add(dxf.clothoid(start=(2, 2), length=length, paramA=A,
rotation=rotation, color=1))
dwg.add(dxf.clothoid(start=(2, 2), mirror='x', length=length, paramA=A,
rotation=rotation, color=2))
dwg.add(dxf.clothoid(start=(2, 2), mirror='y', length=length, paramA=A,
rotation=rotation, color=3))
dwg.add(dxf.clothoid(start=(2, 2), mirror='xy', length=length, paramA=A,
rotation=rotation, color=4))
def drawRectangle(drawing,topLeft,w,h):
dX,dY = topLeft
drawing.add(dxf.line((dX,dY),(dX + w,dY)))
drawing.add(dxf.line((dX,dY),(dX,dY + h)))
drawing.add(dxf.line((dX + w,dY),(dX + w,dY + h)))
drawing.add(dxf.line((dX,dY + h),(dX + w,dY + h)))
def main(argv):
filename = '../../ag03.dat'
chord = [300.0, 290.0, 280.0, 270.0, 260.0, 250.0]
try:
opts, args = getopt.getopt(argv, "c:f:o:", ["chord=", "filename=", "outputfilename="])
except getopt.GetoptError:
usage()
sys.exit(2)
for opt, arg in opts:
if opt in ("-c", "chord="):
chord = float(arg)
elif opt in ("-f", "filename="):
filename = str(arg)
elif opt in ("-o", "outputfilename="):
outputfilename = str(arg)
#DXF related INIT
(root, ext) = os.path.splitext(outputfilename)
saveName = root+'.dxf'
drawing = dxf.drawing(saveName)
#I found the below constant on the internet, this could use verification
chordnumber = 1.0
for c in chord:
scale = 1.0
xOffset = 45.0
yOffset = 45.0
linePoints = []
#pts = ""
line= 0
# Read airfoil data
spamReader = csv.reader(open(filename, 'rb'), delimiter=' ', quotechar='|', skipinitialspace="true")
for row in spamReader:
#Skip the first line of header information
if(line!=0):
#Format and store in a string
#p= ((float(row[0])*chord+xOffset)*scale, (float(row[1])*-chord+yOffset)*scale)
#swap the pomits around to orinetate vertically
p = ( float(row[1])*c + xOffset*chordnumber , float(row[0])*c )
linePoints.append(p)
print p,'x', (row[0],row[1])
line=1
polyline= dxf.polyline(linetype='CONTINUOUS')
polyline.add_vertices( linePoints )
drawing.add(polyline)
chordnumber = chordnumber + 1.0
drawing.save()
def triangle( cx, cy, sz):
cx0 = cx
cy0 = cy - TOP_Y * sz
cx1 = cx - sz/2
cy1 = cy + BOT_Y * sz
cx2 = cx + sz/2
cy2 = cy + BOT_Y * sz
drawing.add(dxf.line((cx0, cy0), (cx1, cy1), layer='Prova'))
drawing.add(dxf.line((cx1, cy1), (cx2, cy2), color=4))
drawing.add(dxf.line((cx2, cy2), (cx0, cy0), color=2))
def write_dxf(self,dxf_file):
""" writes geometry to a file by using the dxfwrite libs."""
drawing = dxf.drawing(dxf_file)
drawing.add_layer('0', color=2)
for tri in self.triangles:
drawing.add(dxf.face3d([self.vertices[tri[0]][0:3],
self.vertices[tri[1]][0:3],
self.vertices[tri[2]][0:3]], layer="0"))
#drawing.add(dxf.text('Test', insert=(0, 0.2), layer='TEXTLAYER'))
drawing.save()
def drawBox(drawing, topLeft, size = 0.5):
dX,dY = topLeft
drawing.add(dxf.line((dX,dY),(dX + size,dY)))
drawing.add(dxf.line((dX,dY),(dX,dY + size)))
drawing.add(dxf.line((dX + size,dY),(dX + size,dY + size)))
drawing.add(dxf.line((dX,dY + size),(dX + size,dY + size)))
def DXFWrite(edges, filename):
from dxfwrite import DXFEngine as dxf
dwg = dxf.drawing(filename)
for e in edges:
if e[2] is None:
kwargs = {"layer": "Cut"}
else:
kwargs = {"layer": repr(e[2])}
dwg.add(dxf.line((e[0][0], e[0][1]), (e[1][0], e[1][1]), **kwargs))
dwg.save()
def create_dxf(filename, polys):
drawing = dxf.drawing(filename)
drawing.add_layer('OUTLINE', color=1)
for p in polys:
polyline = dxf.polyline(layer="OUTLINE")
p = p + [p[0], p[1]] # Close the polygon to avoid a cusp
polyline.add_vertices(p)
drawing.add(polyline)
drawing.save()
def arc_dxf(self, direction=True):
radius = (self.centre - self.cutto).length()
a = self.centre - self.cutto
b = self.centre - self.cutfrom
angle0 = math.atan2(a[1], a[0])/math.pi *180+180
angle1 = math.atan2(b[1], b[0])/math.pi *180+180
if(self.direction=='ccw'):
return [dxf.arc(radius, self.centre, angle0, angle1)]
else:
return [dxf.arc(radius, self.centre, angle1, angle0)]
def comp2dxf(comp, fname, sample_interval, traverse_interval, scale, clip, layer):
"""
comp; Numpy array of shape length, width
fname; filepath to save dxf
sample_interval; distance between samples (m)
traverse_interval; distance between traverses
scale; z units/cm
clip; value to clip data at (z units)
layer; name of dxf layer (string)
"""
#Copies Comp & Flips along horizontal axis
#Copy to avoid flipping,clipping original data
#FlipUD due to positional referencing
comp = np.flipud(np.copy(comp))
#Initiates the dxf using DXFEngine
drawing = dxf.drawing(fname)
#Creates a layer for the polylines to reside
drawing.add_layer(str(layer))
#sets the first line position to be the centre of a traverse
y = 0.5*traverse_interval
#iterates through the traverses
for row in comp:
#Calculates the x position of each data point
x_pos = np.arange(len(row))
x_pos = np.multiply(x_pos,sample_interval)
#clips the magnitude according to user input
y_pos = np.clip(row,-clip,clip)
#scales the magnitude according to user input
y_pos = np.divide(np.multiply(y_pos,scale),clip*100)
#shifts the magnitude to centre on correct traverse location
y_pos = np.add(y_pos, y)
#calculates position of next traverse
y += traverse_interval
#splits traverses on Nan. Polylines cannot bridge Nan
lines = using_clump(x_pos, y_pos)
#For each traverse section (from nan splitting) creates a polyline & adds to drawing
for line in lines:
polyline = dxf.polyline(layer=str(layer))
polyline.add_vertices(line)
drawing.add(polyline)
#Saves Drawing
drawing.save()
