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plant2dxf/lib/plant2dxf.py
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"""
placeblocks.py
Erzeugt DXF-Elemente aus einer RuleDesigner-CSV.
"""
import os
import sys
import csv
import json
import re
import argparse
import configparser
import ezdxf
from ezdxf import units
from ezdxf.entities import Line
from ezdxf.math import Matrix44, X_AXIS,Y_AXIS,Z_AXIS
from pathlib import Path
import math
from utils import check_environment_var, setup_logger
# --------------------------------------------------------- CFG-Leser für shapes.cfg
def get_shape_cfg(teileart, cfg_path, logger=None):
parser = configparser.ConfigParser()
try:
with open(cfg_path, encoding='utf-8') as f:
parser.read_file(f)
except Exception as e:
msg = f"Fehler beim Lesen der Config-Datei {cfg_path}: {e}"
if logger:
logger.error(msg)
else:
print(msg)
return []
section = teileart
if section not in parser:
return []
# Blöcke
items = parser.get(section, "items", fallback="").replace('"', '').split(",")
blocks = [item.strip() for item in items if item.strip()]
symbols = []
for i, name in enumerate(blocks):
# Offset
offset_key = f"offset_symb{i+1}"
offset_str = parser.get(section, offset_key, fallback="0,0")
try:
ox, oy = [float(x) for x in offset_str.split(",")]
except Exception:
ox, oy = 0.0, 0.0
# Rotation
rot_key = f"rot_symb{i+1}"
rot_str = parser.get(section, rot_key, fallback="0.0")
try:
rot = float(rot_str)
except Exception:
rot = 0.0
symbols.append({
"name": name,
"offset": (ox, oy),
"rotation": rot
})
return symbols
# --------------------------------------------------------- Konstante Parameter
ATTR_TAG = "TeileId" # Attributtag im Block
RADIUS = 400 # Radius der Kreiselkreise (mm)
# --------------------------------------------------------- Hilfsfunktionen
def extract_coords(planquadrat: str) -> tuple[float, float]:
"""Extrahiert X/Y Koordinaten aus PlanquadratString."""
m = re.search(r"X:(\d+[\.,]?\d*)\s+Y:(\d+[\.,]?\d*)", planquadrat)
if not m:
raise ValueError(f"Koordinaten nicht gefunden in: '{planquadrat}'")
x, y = m.groups()
return float(x.replace(",", ".")), float(y.replace(",", "."))
def parse_merkmale(merkmale_str: str) -> dict:
"""Parst Merkmale-JSON-String in dict; bei Fehler → leeres Dict."""
try:
return json.loads(merkmale_str)
except json.JSONDecodeError:
return {}
def import_block(block_name: str, from_doc, to_doc, winkel = None) -> None:
"""Importiert Blockdefinition block_name von from_doc nach to_doc.
- Kopiert alle Entities des Blocks
- Stellt sicher, dass benutzte Layer im Ziel existieren (mit Eigenschaften)
- Übernimmt Basis­punkt und Block-Layer, falls vorhanden
"""
if (block_name in to_doc.blocks):
return
if block_name not in from_doc.blocks:
raise ValueError(f"Block '{block_name}' nicht in Bibliothek gefunden.")
src = from_doc.blocks[block_name]
# Sicherstellen, dass alle verwendeten Layer existieren
try:
used_layer_names = {e.dxf.layer for e in src if hasattr(e.dxf, "layer")}
for layer_name in used_layer_names:
if layer_name and layer_name not in to_doc.layers:
try:
src_layer = from_doc.layers.get(layer_name)
to_doc.layers.add(
name=layer_name,
color=getattr(src_layer.dxf, "color", None),
linetype=getattr(src_layer.dxf, "linetype", None),
lineweight=getattr(src_layer.dxf, "lineweight", None),
)
except Exception:
# Fallback: Layer mit Standardwerten anlegen
to_doc.layers.add(name=layer_name)
except Exception:
pass
tgt = to_doc.blocks.new(name=block_name)
# Basis­punkt/Layer des Blocks übernehmen, wenn vorhanden
try:
tgt.block.dxf.base_point = src.block.dxf.base_point
except Exception:
pass
try:
tgt.block.dxf.layer = src.block.dxf.layer
except Exception:
pass
for ent in src:
if winkel != None:
rotation_matrix = Matrix44.axis_rotate(Y_AXIS, winkel)
ent.transform(rotation_matrix)
if ent.dxftype() == "INSERT":
import_block(ent.dxf.name,from_doc, to_doc,None)
tgt.add_entity(ent.copy())
def berechne_hoehe(csv_path, logger=None):
y_werte = []
try:
with csv_path.open(newline="", encoding="utf-8") as fh:
reader = csv.DictReader(fh, delimiter=';')
for row in reader:
planquadrat = row.get("Planquadrat", "")
try:
_, y = extract_coords(planquadrat)
y_werte.append(y)
except Exception as e:
if logger:
logger.warning(f"Fehler beim Extrahieren der Koordinate aus '{planquadrat}': {e}")
except Exception as e:
if logger:
logger.error(f"Fehler beim Lesen der CSV-Datei {csv_path}: {e}")
else:
print(f"Fehler beim Lesen der CSV-Datei {csv_path}: {e}")
return 0
if not y_werte:
msg = "Keine Y-Koordinaten in der CSV gefunden!"
if logger:
logger.error(msg)
else:
print(msg)
raise ValueError(msg)
return max(y_werte)
def transform_coords(x: float, y: float, height: float) -> tuple[float, float]:
"""Transformiert Bildschirmkoordinaten (0,0 oben links) ins DXF-KoSy (0,0 unten links)."""
return x, y
def handle_ils_2_0_kreisel(msp, teileid, merkmale, x, y, doc, lib_doc, verbose, symbols,strecken_nachbarn,config):
abstand_m = merkmale.get(
"Abstand (Kreiselachse A - Kreiselachse) in Meter", "20"
).replace(",", ".")
try:
abstand = float(abstand_m) * 1000 # Meter → mm
except ValueError:
abstand = 10000 # Fallback 10m
# Drehung (Winkel in Grad, Standard 0) aus Merkmale
try:
winkel = float(merkmale.get("Drehung", 90))
except (ValueError, TypeError):
winkel = 0.0
winkel_rad = math.radians(winkel)
# Die Koordinaten (x, y) sind die Mitte zwischen den beiden Blöcken (bereits transformiert)
halbabstand = abstand / 2
dx = halbabstand * math.cos(winkel_rad)
dy = halbabstand * math.sin(winkel_rad)
pos1 = (x - dx, y - dy,float(merkmale.get("Höhe in m"))* 1000)
pos2 = (x + dx, y + dy, float(merkmale.get("Höhe in m"))* 1000)
positions = [pos1, pos2]
for i, sym in enumerate(symbols):
blockname = sym["name"]
offset = sym["offset"]
rotation = sym["rotation"]
if i < len(positions):
pos = (positions[i][0] + offset[0], positions[i][1] + offset[1],float(merkmale.get("Höhe in m"))*1000)
import_block(blockname, lib_doc, doc)
blockref_layer = get_layer(doc, lib_doc, blockname)
bref = msp.add_blockref(blockname, pos, dxfattribs={"rotation": merkmale.get("Drehung"), "layer" : blockref_layer})
bref.add_auto_attribs({ATTR_TAG: teileid})
if verbose:
print(f"[INFO] Block '{blockname}' (Kreisel) → {teileid} "
f"({pos[0]:.1f}, {pos[1]:.1f}), rot={rotation}")
# Linien zeichnen
draw_kreisel_lines(msp, pos1, pos2)
draw_kreisel_drehrichtung_markierung(msp, pos1, pos2, merkmale, lib_doc, doc, verbose)
def draw_kreisel_lines(msp, pos1, pos2):
"""Zeichnet tangentiale Linien zwischen zwei Kreiselblöcken, unabhängig vom Winkel."""
x1, y1, z1 = pos1
x2, y2, z1 = pos2
# Verbindungsvektor
dx = x2 - x1
dy = y2 - y1
# Länge
length = math.hypot(dx, dy)
if length == 0:
return # keine Linie bei identischen Punkten
# Normalenvektor (senkrecht, normiert, Länge = RADIUS)
nx = -dy / length * RADIUS
ny = dx / length * RADIUS
# Tangentialpunkte
p1a = (x1 + nx, y1 + ny,z1)
p1b = (x1 - nx, y1 - ny,z1)
p2a = (x2 + nx, y2 + ny,z1)
p2b = (x2 - nx, y2 - ny,z1)
# Linien zeichnen
msp.add_line(p1a, p2a)
msp.add_line(p1b, p2b)
def draw_kreisel_drehrichtung_markierung(msp, pos1, pos2, merkmale, lib_doc, doc, verbose):
drehrichtung = merkmale.get("Drehrichtung", "").upper()
if drehrichtung not in ("UZS", "GUZS"):
return
x1, y1,z1= pos1
x2, y2,z2 = pos2
dx = x2 - x1
dy = y2 - y1
length = math.hypot(dx, dy)
if length == 0:
return
# Normalenvektor (senkrecht, normiert, Länge = RADIUS)
nx = -dy / length * RADIUS
ny = dx / length * RADIUS
# Obere Linie
p1_oben = (x1 + nx, y1 + ny)
p2_oben = (x2 + nx, y2 + ny)
# Untere Linie
p1_unten = (x1 - nx, y1 - ny)
p2_unten = (x2 - nx, y2 - ny)
# S-LP auf oberer Linie (Drehrichtung wie angegeben)
for i in range(1, 4):
t = i / 4 # 1/4, 2/4, 3/4
px = p1_oben[0] + t * (p2_oben[0] - p1_oben[0])
py = p1_oben[1] + t * (p2_oben[1] - p1_oben[1])
rotation = math.degrees(math.atan2(p2_oben[1] - p1_oben[1], p2_oben[0] - p1_oben[0]))
if drehrichtung == "GUZS":
rotation += 180
import_block("S-LP", lib_doc, doc)
blockref_layer = get_layer(doc, lib_doc, "S-LP")
bref = msp.add_blockref("S-LP", (px, py,z1), dxfattribs={"rotation": rotation,"layer": blockref_layer})
if verbose:
print(f"[INFO] Drehrichtung '{drehrichtung}': S-LP oben bei ({px:.1f}, {py:.1f}), rot={rotation:.1f}")
# S-LP auf unterer Linie (Drehrichtung invertiert)
for i in range(1, 4):
t = i / 4
px = p1_unten[0] + t * (p2_unten[0] - p1_unten[0])
py = p1_unten[1] + t * (p2_unten[1] - p1_unten[1])
rotation = math.degrees(math.atan2(p2_unten[1] - p1_unten[1], p2_unten[0] - p1_unten[0]))
if drehrichtung == "UZS":
rotation += 180
import_block("S-LP", lib_doc, doc)
blockref_layer = get_layer(doc, lib_doc, "S-LP")
bref = msp.add_blockref("S-LP", (px, py, z1), dxfattribs={"rotation": rotation , "layer": blockref_layer})
if verbose:
print(f"[INFO] Drehrichtung '{drehrichtung}': S-LP unten bei ({px:.1f}, {py:.1f}), rot={rotation:.1f}")
def handle_standard(msp, blocknames, teileid, x, y, lib_doc, doc, verbose):
for blockname in blocknames:
import_block(blockname, lib_doc, doc)
blockref_layer = get_layer(doc, lib_doc, blockname)
bref = msp.add_blockref(blockname, (x, y), dxfattribs={"layer": blockref_layer})
bref.add_auto_attribs({ATTR_TAG: teileid})
if verbose:
print(f"[INFO] Block '{blockname}' (Standard) → {teileid} "
f"({x:.1f}, {y:.1f})")
def handle_ils_2_0_gefaellestrecke(msp, teileid, merkmale, x, y, doc, lib_doc, verbose, symbols, strecken_nachbarn,config):
#Vorbereitung der attributen
if "6-SP" not in doc.layers:
doc.layers.add(name="6-SP", color=7)
verbunden_am_einen = False
am_kreisel = 0
richtung2 ="DEFAULT"
unterschiedlich = False
asoffset = float(config.get("ILS 2.0 Gefällestrecke", "asoffset"))
esoffset = float(config.get("ILS 2.0 Gefällestrecke", "esoffset"))
upper_hoehe_gefaehlle= float(merkmale.get("Höhe oben")) *1000
lower_hoehe_gefaehlle = float(merkmale.get("Höhe unten")) * 1000
hoehe_gefaehlle = (upper_hoehe_gefaehlle + lower_hoehe_gefaehlle)/2
for nachbarn in strecken_nachbarn:
if teileid == nachbarn.get("Id"):
gefaellestrecke_nachbarn = nachbarn
break
if "Drehung0" in gefaellestrecke_nachbarn and "Drehung1" not in gefaellestrecke_nachbarn:
drehung0 =gefaellestrecke_nachbarn.get("Drehung0")
x0_kreisel = float(gefaellestrecke_nachbarn.get("x0"))
y0_kreisel = float(gefaellestrecke_nachbarn.get("y0"))
hoehe0 = float(gefaellestrecke_nachbarn.get("Hoehe0"))
richtung0 = float(gefaellestrecke_nachbarn.get("rotation0"))
richtung_rad0= math.radians(richtung0)
abstand0 = float(gefaellestrecke_nachbarn.get("abstand0")) * 1000
laenge_m = merkmale.get("Länge in Meter", "10").replace(",", ".")
try:
laenge = float(laenge_m) * 1000 # Meter → mm
except ValueError:
laenge = 10000
halbabstand0 = abstand0 / 2
dx0 = halbabstand0 * math.cos(richtung_rad0)
dy0 = halbabstand0 * math.sin(richtung_rad0)
pos0_0_floor= (math.floor(x0_kreisel + dx0),math.floor( y0_kreisel + dy0),hoehe0)
pos0_1_floor = (math.floor(x0_kreisel- dx0),math.floor( y0_kreisel- dy0), hoehe0)
pos0_0_round= (round(x0_kreisel + dx0),round( y0_kreisel + dy0),hoehe0)
pos0_1_round = (round(x0_kreisel- dx0),round( y0_kreisel- dy0), hoehe0)
halbe_laenge = laenge / 2
winkel = math.radians(float(merkmale.get("Drehung")))
dx = halbe_laenge *math.sin(winkel * -1)
dy = halbe_laenge * math.cos(winkel)
if upper_hoehe_gefaehlle < lower_hoehe_gefaehlle:
hoehe2 = upper_hoehe_gefaehlle
upper_hoehe_gefaehlle = lower_hoehe_gefaehlle
lower_hoehe_gefaehlle = hoehe2
if upper_hoehe_gefaehlle == hoehe0:
hight = "higher"
if richtung0 == 90.0 or richtung0 ==270:
richtung0= "Vertikal"
if x0_kreisel < x:
start_floor = (math.floor(x +dx ), math.floor(y + dy ),lower_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,upper_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),lower_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,upper_hoehe_gefaehlle)
gefaelle = "links"
else:
start_floor = (math.floor(x +dx ), math.floor(y + dy ),upper_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,lower_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),upper_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,lower_hoehe_gefaehlle)
gefaelle = "rechts"
else:
richtung0 = "Horinzontal"
if y0_kreisel < y:
start_floor = (math.floor(x +dx ), math.floor(y + dy ),lower_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,upper_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),lower_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,upper_hoehe_gefaehlle)
gefaelle = "links"
gefaelle = "unten"
else:
start_floor = (math.floor(x +dx ), math.floor(y + dy ),upper_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,lower_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),upper_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,lower_hoehe_gefaehlle)
gefaelle = "links"
gefaelle = "oben"
else:
hight = "lower"
if richtung0 == 90.0 or richtung0 ==270:
richtung0= "Vertikal"
if x0_kreisel < x:
start_floor = (math.floor(x +dx ), math.floor(y + dy ),upper_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,lower_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),upper_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,lower_hoehe_gefaehlle)
gefaelle = "rechts"
else:
start_floor = (math.floor(x +dx ), math.floor(y + dy ),lower_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,upper_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),lower_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,upper_hoehe_gefaehlle)
gefaelle = "links"
else:
richtung0 = "Horinzontal"
if y0_kreisel < y:
start_floor = (math.floor(x +dx ), math.floor(y + dy ),upper_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,lower_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),upper_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,lower_hoehe_gefaehlle)
gefaelle = "links"
gefaelle = "oben"
else:
start_floor = (math.floor(x +dx ), math.floor(y + dy ),lower_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,upper_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),lower_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,upper_hoehe_gefaehlle)
gefaelle = "links"
gefaelle = "unten"
abstand_fuer_kreis_start_x_floor = start_floor[0] +RADIUS, start_floor[1]
abstand_gegen_kreis_start_x_floor = start_floor[0] -RADIUS, start_floor[1]
abstand_fuer_kreis_start_y_floor = start_floor[0], start_floor[1] + RADIUS
abstand_gegen_kreis_start_y_floor = start_floor[0], start_floor[1] - RADIUS
abstand_fuer_kreis_ende_x_floor= ende_floor[0] + RADIUS, ende_floor[1]
abstand_gegen_kreis_ende_x_floor= ende_floor[0] - RADIUS, ende_floor[1]
abstand_fuer_kreis_ende_y_floor = ende_floor[0] , ende_floor[1] + RADIUS
abstand_gegen_kreis_ende_y_floor = ende_floor[0] , ende_floor[1] - RADIUS
abstand_fuer_kreis_start_x_round= start_round[0] +RADIUS, start_round[1]
abstand_gegen_kreis_start_x_round = start_round[0] -RADIUS, start_round[1]
abstand_fuer_kreis_start_y_round = start_round[0], start_round[1] + RADIUS
abstand_gegen_kreis_start_y_round = start_round[0], start_round[1] - RADIUS
abstand_fuer_kreis_ende_x_round= ende_round[0] + RADIUS, ende_round[1]
abstand_gegen_kreis_ende_x_round= ende_round[0] - RADIUS, ende_round[1]
abstand_fuer_kreis_ende_y_round = ende_round[0] , ende_round[1] + RADIUS
abstand_gegen_kreis_ende_y_round = ende_round[0] , ende_round[1] - RADIUS
if( (abstand_fuer_kreis_start_x_floor == pos0_0_floor) or
(abstand_fuer_kreis_start_x_floor == pos0_1_floor) or
(abstand_gegen_kreis_start_x_floor == pos0_0_floor) or
(abstand_gegen_kreis_start_x_floor == pos0_1_floor) or
(abstand_fuer_kreis_ende_x_floor == pos0_0_floor) or
(abstand_fuer_kreis_ende_x_floor == pos0_1_floor) or
(abstand_gegen_kreis_ende_x_floor == pos0_0_floor) or
(abstand_gegen_kreis_ende_x_floor == pos0_1_floor) or
(abstand_fuer_kreis_start_y_floor == pos0_0_floor) or
(abstand_fuer_kreis_start_y_floor == pos0_1_floor) or
(abstand_gegen_kreis_start_y_floor == pos0_0_floor) or
(abstand_gegen_kreis_start_y_floor == pos0_1_floor) or
(abstand_fuer_kreis_ende_y_floor == pos0_0_floor) or
(abstand_fuer_kreis_ende_y_floor == pos0_1_floor) or
(abstand_gegen_kreis_ende_y_floor == pos0_0_floor) or
(abstand_gegen_kreis_ende_y_floor == pos0_1_floor) or
(abstand_fuer_kreis_start_x_round == pos0_0_round) or
(abstand_fuer_kreis_start_x_round == pos0_1_round) or
(abstand_gegen_kreis_start_x_round == pos0_0_round) or
(abstand_gegen_kreis_start_x_round == pos0_1_round) or
(abstand_fuer_kreis_ende_x_round == pos0_0_round) or
(abstand_fuer_kreis_ende_x_round == pos0_1_round) or
(abstand_gegen_kreis_ende_x_round == pos0_0_round) or
(abstand_gegen_kreis_ende_x_round == pos0_1_round) or
(abstand_fuer_kreis_start_y_round == pos0_0_round) or
(abstand_fuer_kreis_start_y_round == pos0_1_round) or
(abstand_gegen_kreis_start_y_round == pos0_0_round) or
(abstand_gegen_kreis_start_y_round == pos0_1_round) or
(abstand_fuer_kreis_ende_y_round == pos0_0_round) or
(abstand_fuer_kreis_ende_y_round == pos0_1_round) or
(abstand_gegen_kreis_ende_y_round == pos0_0_round) or
(abstand_gegen_kreis_ende_y_round == pos0_1_round)
):
kreisel_verbunden = kreisel_verbunden +1
# setzung auf kreisel 1 für spätere ausrechnung der geraden form
am_kreisel = 1
start = x +dx, y + dy,start_floor[2]
ende = x -dx, y - dy,ende_floor[2]
line =msp.add_line(start,ende)
line.dxf.layer = "6-SP"
return
verbunden_am_einen = True
blockname = f"Ils_2.0_Gefaellestrecke_{laenge}_{drehung0}_{gefaelle}_{verbunden_am_einen}_{hight}"
if gefaelle == "oben":
rotation = 0
elif gefaelle == "unten" :
rotation = 180
elif gefaelle == "links" :
rotation = 90
elif gefaelle == "rechts" :
rotation = 270
erstellung_gefaelle_block_verbunenden_am_einen(x, y, doc, lib_doc, asoffset, esoffset, upper_hoehe_gefaehlle, lower_hoehe_gefaehlle, hoehe_gefaehlle, drehung0, laenge, blockname,hight)
blockref_layer = get_layer(doc, lib_doc, blockname)
bref =msp.add_blockref(blockname,(x,y,hoehe_gefaehlle),dxfattribs={"rotation": rotation, "layer": blockref_layer})
a =bref.add_attrib(
tag= "NAME",
text= merkmale.get("bezeichner"),
insert = (x,y)
)
a.is_invisible = True
elif "Drehung0" in gefaellestrecke_nachbarn and "Drehung1" in gefaellestrecke_nachbarn:
drehung0 =gefaellestrecke_nachbarn.get("Drehung0")
drehung1 = gefaellestrecke_nachbarn.get("Drehung1")
hoehe0 = gefaellestrecke_nachbarn.get("Hoehe0")
hoehe1 = gefaellestrecke_nachbarn.get("Hoehe1")
x0_kreisel = float(gefaellestrecke_nachbarn.get("x0"))
y0_kreisel = float(gefaellestrecke_nachbarn.get("y0"))
x1_kreisel = float(gefaellestrecke_nachbarn.get("x1"))
y1_kreisel = float(gefaellestrecke_nachbarn.get("y1"))
richtung0 = float(gefaellestrecke_nachbarn.get("rotation0"))
richtung1 = float(gefaellestrecke_nachbarn.get("rotation1"))
richtung2 ="DEFAULT"
richtung_rad0= math.radians(richtung0)
richtung_rad1 = math.radians(richtung1)
abstand0 = float(gefaellestrecke_nachbarn.get("abstand0")) * 1000
abstand1 = float(gefaellestrecke_nachbarn.get("abstand1")) * 1000
kreisel_verbunden = 0
laenge_m = merkmale.get("Länge in Meter", "10").replace(",", ".")
try:
laenge = float(laenge_m) * 1000 # Meter → mm
except ValueError:
laenge = 10000
#ausrechnung position kreisel
halbabstand0 = abstand0 / 2
dx0 = halbabstand0 * math.cos(richtung_rad0)
dy0 = halbabstand0 * math.sin(richtung_rad0)
pos0_0_floor= (math.floor(x0_kreisel + dx0),math.floor( y0_kreisel + dy0))
pos0_1_floor = (math.floor(x0_kreisel- dx0),math.floor( y0_kreisel- dy0))
pos0_0_round= (round(x0_kreisel + dx0),round( y0_kreisel + dy0))
pos0_1_round = (round(x0_kreisel- dx0),round( y0_kreisel- dy0))
halbabstand1 = abstand1 / 2
dx1 = halbabstand1 * math.cos(richtung_rad1 )
dy1 = halbabstand1 * math.sin(richtung_rad1)
pos1_0_floor = (math.floor(x1_kreisel + dx1), math.floor(y1_kreisel + dy1))
pos1_1_floor = (math.floor(x1_kreisel - dx1), math.floor(y1_kreisel - dy1))
pos1_0_round = (round(x1_kreisel + dx1), round(y1_kreisel + dy1))
pos1_1_round = (round(x1_kreisel - dx1), round(y1_kreisel - dy1))
winkel = math.radians(float(merkmale.get("Drehung")))
# berechnung der geraden einmal abgerunden und einmal gerunden zur negirung des offsets
halbe_laenge = laenge / 2
dx = halbe_laenge *math.sin(winkel * -1)
dy = halbe_laenge * math.cos(winkel)
start_floor = (math.floor(x +dx ), math.floor(y + dy ),upper_hoehe_gefaehlle)
ende_floor = (math.floor(x -dx), math.floor(y - dy ) ,lower_hoehe_gefaehlle)
start_round = (round(x +dx ), round(y + dy ),upper_hoehe_gefaehlle)
ende_round= (round(x -dx), round(y - dy ) ,lower_hoehe_gefaehlle)
# verschiebund der endpunkte der gerade in richtung von dem potentiellen Kreisel für den vergleich wieder mit floor und rundung
abstand_fuer_kreis_start_x_floor = start_floor[0] +RADIUS, start_floor[1]
abstand_gegen_kreis_start_x_floor = start_floor[0] -RADIUS, start_floor[1]
abstand_fuer_kreis_start_y_floor = start_floor[0], start_floor[1] + RADIUS
abstand_gegen_kreis_start_y_floor = start_floor[0], start_floor[1] - RADIUS
abstand_fuer_kreis_ende_x_floor= ende_floor[0] + RADIUS, ende_floor[1]
abstand_gegen_kreis_ende_x_floor= ende_floor[0] - RADIUS, ende_floor[1]
abstand_fuer_kreis_ende_y_floor = ende_floor[0] , ende_floor[1] + RADIUS
abstand_gegen_kreis_ende_y_floor = ende_floor[0] , ende_floor[1] - RADIUS
abstand_fuer_kreis_start_x_round= start_round[0] +RADIUS, start_round[1]
abstand_gegen_kreis_start_x_round = start_round[0] -RADIUS, start_round[1]
abstand_fuer_kreis_start_y_round = start_round[0], start_round[1] + RADIUS
abstand_gegen_kreis_start_y_round = start_round[0], start_round[1] - RADIUS
abstand_fuer_kreis_ende_x_round= ende_round[0] + RADIUS, ende_round[1]
abstand_gegen_kreis_ende_x_round= ende_round[0] - RADIUS, ende_round[1]
abstand_fuer_kreis_ende_y_round = ende_round[0] , ende_round[1] + RADIUS
abstand_gegen_kreis_ende_y_round = ende_round[0] , ende_round[1] - RADIUS
# vergleich mit einem kreisel von zwei
if( (abstand_fuer_kreis_start_x_floor == pos0_0_floor) or
(abstand_fuer_kreis_start_x_floor == pos0_1_floor) or
(abstand_gegen_kreis_start_x_floor == pos0_0_floor) or
(abstand_gegen_kreis_start_x_floor == pos0_1_floor) or
(abstand_fuer_kreis_ende_x_floor == pos0_0_floor) or
(abstand_fuer_kreis_ende_x_floor == pos0_1_floor) or
(abstand_gegen_kreis_ende_x_floor == pos0_0_floor) or
(abstand_gegen_kreis_ende_x_floor == pos0_1_floor) or
(abstand_fuer_kreis_start_y_floor == pos0_0_floor) or
(abstand_fuer_kreis_start_y_floor == pos0_1_floor) or
(abstand_gegen_kreis_start_y_floor == pos0_0_floor) or
(abstand_gegen_kreis_start_y_floor == pos0_1_floor) or
(abstand_fuer_kreis_ende_y_floor == pos0_0_floor) or
(abstand_fuer_kreis_ende_y_floor == pos0_1_floor) or
(abstand_gegen_kreis_ende_y_floor == pos0_0_floor) or
(abstand_gegen_kreis_ende_y_floor == pos0_1_floor) or
(abstand_fuer_kreis_start_x_round == pos0_0_round ) or
(abstand_fuer_kreis_start_x_round == pos0_1_round) or
(abstand_gegen_kreis_start_x_round == pos0_0_round) or
(abstand_gegen_kreis_start_x_round == pos0_1_round) or
(abstand_fuer_kreis_ende_x_round == pos0_0_round) or
(abstand_fuer_kreis_ende_x_round == pos0_1_round) or
(abstand_gegen_kreis_ende_x_round == pos0_0_round) or
(abstand_gegen_kreis_ende_x_round == pos0_1_round) or
(abstand_fuer_kreis_start_y_round == pos0_0_round) or
(abstand_fuer_kreis_start_y_round == pos0_1_round) or
(abstand_gegen_kreis_start_y_round == pos0_0_round) or
(abstand_gegen_kreis_start_y_round == pos0_1_round) or
(abstand_fuer_kreis_ende_y_round == pos0_0_round) or
(abstand_fuer_kreis_ende_y_round == pos0_1_round) or
(abstand_gegen_kreis_ende_y_round == pos0_0_round) or
(abstand_gegen_kreis_ende_y_round == pos0_1_round)
):
kreisel_verbunden = kreisel_verbunden +1
# setzung auf kreisel 1 für spätere ausrechnung der geraden form
am_kreisel = 1
if( (abstand_fuer_kreis_start_x_floor == pos1_0_floor )or
(abstand_fuer_kreis_start_x_floor == pos1_1_floor) or
(abstand_gegen_kreis_start_x_floor == pos1_0_floor) or
(abstand_gegen_kreis_start_x_floor == pos1_1_floor) or
(abstand_fuer_kreis_ende_x_floor == pos1_0_floor) or
(abstand_fuer_kreis_ende_x_floor == pos1_1_floor) or
(abstand_gegen_kreis_ende_x_floor == pos1_0_floor) or
(abstand_gegen_kreis_ende_x_floor == pos1_1_floor) or
(abstand_fuer_kreis_start_y_floor == pos1_0_floor ) or
(abstand_fuer_kreis_start_y_floor == pos1_1_floor) or
(abstand_gegen_kreis_start_y_floor == pos1_0_floor) or
(abstand_gegen_kreis_start_y_floor == pos1_1_floor) or
(abstand_fuer_kreis_ende_y_floor == pos1_0_floor ) or
(abstand_fuer_kreis_ende_y_floor == pos1_1_floor) or
(abstand_gegen_kreis_ende_y_floor == pos1_0_floor) or
(abstand_gegen_kreis_ende_y_floor == pos1_1_floor) or
(abstand_fuer_kreis_start_x_round == pos1_0_round ) or
(abstand_fuer_kreis_start_x_round == pos1_1_round) or
(abstand_gegen_kreis_start_x_round == pos1_0_round) or
(abstand_gegen_kreis_start_x_round == pos1_1_round) or
(abstand_fuer_kreis_ende_x_round == pos1_0_round) or
(abstand_fuer_kreis_ende_x_round == pos1_1_round) or
(abstand_gegen_kreis_ende_x_round == pos1_0_round) or
(abstand_gegen_kreis_ende_x_round == pos1_1_round) or
(abstand_fuer_kreis_start_y_round == pos1_0_round) or
(abstand_fuer_kreis_start_y_round == pos1_1_round) or
(abstand_gegen_kreis_start_y_round == pos1_0_round) or
(abstand_gegen_kreis_start_y_round == pos1_1_round) or
(abstand_fuer_kreis_ende_y_round == pos1_0_round) or
(abstand_fuer_kreis_ende_y_round == pos1_1_round) or
(abstand_gegen_kreis_ende_y_round == pos1_0_round) or
(abstand_gegen_kreis_ende_y_round == pos1_1_round)
):
kreisel_verbunden = kreisel_verbunden +1
am_kreisel = 2
# falls gefälle strecke mit zwei kreiseln verbunden zeichne eine einfache linie (später braucht man hier auch eine logik sobald man die richtigen es und as elemente hat)
if kreisel_verbunden == 2:
start = x +dx, y + dy,upper_hoehe_gefaehlle
ende = x -dx, y - dy,lower_hoehe_gefaehlle
line = msp.add_line(start,ende)
line.dxf.layer = "6-SP"
return
#umbezeichnung von den geraden zu strings ob es Vertikal oder Horizontal ist
if richtung0 == 90.0 or richtung0 ==270:
richtung0= "Vertikal"
else:
richtung0 = "Horinzontal"
if richtung1 == 90.0 or richtung1 ==270:
richtung1= "Vertikal"
else:
richtung1 = "Horinzontal"
# setzung von richtung2 auf vertikal oder horizontal je nach dem welche orientierung der kreisel hat mit dem man am kreisel verbunden ist
if (richtung0 != richtung1 and kreisel_verbunden ==1):
if(
(abstand_fuer_kreis_start_y_floor == pos0_0_floor)or
(abstand_fuer_kreis_start_y_floor == pos0_1_floor) or
(abstand_gegen_kreis_start_y_floor == pos0_0_floor) or
(abstand_gegen_kreis_start_y_floor == pos0_1_floor) or
(abstand_fuer_kreis_ende_y_floor == pos0_0_floor) or
(abstand_fuer_kreis_ende_y_floor == pos0_1_floor) or
(abstand_gegen_kreis_ende_y_floor == pos0_0_floor) or
(abstand_gegen_kreis_ende_y_floor == pos0_1_floor) or
(abstand_fuer_kreis_start_y_round == pos0_0_round)or
(abstand_fuer_kreis_start_y_round == pos0_1_round) or
(abstand_gegen_kreis_start_y_round == pos0_0_round) or
(abstand_gegen_kreis_start_y_round == pos0_1_round) or
(abstand_fuer_kreis_ende_y_round == pos0_0_round) or
(abstand_fuer_kreis_ende_y_round == pos0_1_round) or
(abstand_gegen_kreis_ende_y_round == pos0_0_round) or
(abstand_gegen_kreis_ende_y_round == pos0_1_round) or
(abstand_fuer_kreis_start_y_floor == pos1_0_floor) or
(abstand_fuer_kreis_start_y_floor == pos1_1_floor) or
(abstand_gegen_kreis_start_y_floor == pos1_0_floor) or
(abstand_gegen_kreis_start_y_floor == pos1_1_floor) or
(abstand_fuer_kreis_ende_y_floor == pos1_0_floor) or
(abstand_fuer_kreis_ende_y_floor == pos1_1_floor) or
(abstand_gegen_kreis_ende_y_floor == pos1_0_floor) or
(abstand_gegen_kreis_ende_y_floor == pos1_1_floor) or
(abstand_fuer_kreis_start_y_round == pos1_0_round) or
(abstand_fuer_kreis_start_y_round == pos1_1_round) or
(abstand_gegen_kreis_start_y_round == pos1_0_round) or
(abstand_gegen_kreis_start_y_round == pos1_1_round) or
(abstand_fuer_kreis_ende_y_round == pos1_0_round) or
(abstand_fuer_kreis_ende_y_round == pos1_1_round) or
(abstand_gegen_kreis_ende_y_round == pos1_0_round) or
(abstand_gegen_kreis_ende_y_round == pos1_1_round)
):
richtung2= "Vertikal"
else:
richtung2 = "Horinzontal"
unterschiedlich = True
#Berechnung des Gefälles
if hoehe0 > hoehe1:
hight_position = "higher"
else:
hight_position = "lower"
if richtung2 == "DEFAULT":
if richtung0 == "Vertikal":
if x0_kreisel < x1_kreisel:
position = hight_position + "_links"
else:
position = hight_position + "_rechts"
else:
if y0_kreisel > y1_kreisel:
position = hight_position + "_higher"
else:
position = hight_position + "_lower"
if richtung0 == "Vertikal":
if position == "lower_rechts" or position == "higher_links":
gefaelle = "links"
else:
gefaelle = "rechts"
elif richtung0 == "Horinzontal":
if position == "lower_lower" or position == "higher_higher":
gefaelle = "oben"
else:
gefaelle = "unten"
# vertausch der drehung und der höhe für die namens gebung des blockes
if (position == "higher_rechts" or position == "lower_rechts" or position=="higher_lower" or position== "lower_lower") and drehung0 != drehung1 and am_kreisel == 0:
drehung_2 = drehung0
drehung0 = drehung1
drehung1= drehung_2
if hight_position == "higher":
hight_position = "lower"
else:
hight_position = "higher"
# austausch der werte damit immer davon ausgehen dass der 1 kreisel in unserer Liste am Kreisel verbuden ist
if kreisel_verbunden == 1 and am_kreisel ==2:
am_kreisel == 1
drehung_2 = drehung0
drehung0 = drehung1
drehung1= drehung_2
if hight_position == "higher":
hight_position = "lower"
else:
hight_position = "higher"
else:
if richtung2 == "Vertikal":
if x0_kreisel < x1_kreisel:
position = hight_position + "_links"
else:
position = hight_position + "_rechts"
else:
if y0_kreisel > y1_kreisel:
position = hight_position + "_higher"
else:
position = hight_position + "_lower"
if richtung2 == "Vertikal":
if position == "lower_rechts" or position == "higher_links":
gefaelle = "links"
else:
gefaelle = "rechts"
elif richtung2 == "Horinzontal":
if position == "lower_lower" or position == "higher_higher":
gefaelle = "oben"
else:
gefaelle = "unten"
# austausch der werte damit immer davon ausgehen dass der 1 kreisel in unserer Liste am Kreisel verbuden ist
if am_kreisel == 2:
am_kreisel = 1
drehung_2 = drehung0
drehung0 = drehung1
drehung1= drehung_2
if hight_position == "higher":
hight_position = "lower"
else:
hight_position = "higher"
if gefaelle == "oben":
rotation = 0
elif gefaelle == "unten" :
rotation = 180
elif gefaelle == "links" :
rotation = 90
elif gefaelle == "rechts" :
rotation = 270
#geben der richtung2 eines wertes außer default wenn beide kreisel die gleiche richung haben
if (kreisel_verbunden == 1 and richtung2 =="DEFAULT"):
richtung2 = richtung0
if richtung2 == "DEFAULT":
blockname = f"Ils_2.0_Gefaellestrecke_{laenge}_{hoehe_gefaehlle}_{drehung0}_{drehung1}_{hight_position}_{verbunden_am_einen}"
else:
blockname = f"Ils_2.0_Gefaellestrecke_{laenge}_{hoehe_gefaehlle}_{drehung0}_{drehung1}_{hight_position}_{unterschiedlich}_{richtung2}_{verbunden_am_einen}"
gefaellegerade_erstellung(x, y, doc, lib_doc, asoffset, esoffset, upper_hoehe_gefaehlle, lower_hoehe_gefaehlle, hoehe_gefaehlle,richtung2,drehung0, drehung1, laenge, hight_position,blockname)
blockref_layer = get_layer(doc, lib_doc, blockname)
bref =msp.add_blockref(blockname,(x,y,hoehe_gefaehlle),dxfattribs={"rotation": rotation, "layer": blockref_layer })
a = bref.add_attrib(
tag= "NAME",
text= merkmale.get("bezeichner"),
insert = (x,y)
)
a.is_invisible = True
#falls eine gefällestrecke nicht mit einem kreisel verbunden ist
else:
laenge_m = merkmale.get("Länge in Meter", "10").replace(",", ".")
try:
laenge = float(laenge_m) * 1000 # Meter → mm
except ValueError:
laenge = 10000
winkel = math.radians(float(merkmale.get("Drehung")))
halbe_laenge = laenge / 2
dx = halbe_laenge *math.sin(winkel * -1)
dy = halbe_laenge * math.cos(winkel)
start = x +dx, y + dy,upper_hoehe_gefaehlle
ende = x -dx, y - dy,lower_hoehe_gefaehlle
line = msp.add_line(start,ende)
line.dxf.layer = "6-SP"
def handle_ils_2_0_variofoerderer(msp, teileid, merkmale, x, y, doc, lib_doc, verbose, symbols, strecken_nachbarn,config):
if "VARIO" not in doc.layers:
doc.layers.add(name="VARIO", color=3)
voerder_richtung = merkmale.get("Förderrichtung")
winkel = int(merkmale.get("Winkel"))
verbunden_am_einen = False
am_kreisel = 0
ein_kreisel_höher = False
richtung2 ="DEFAULT"
unterschiedlich = False
asoffset = float(config.get("ILS 2.0 Gefällestrecke", "asoffset"))
esoffset = float(config.get("ILS 2.0 Gefällestrecke", "esoffset"))
umlenk_motor_offset = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Umlenkstation")).split(","))
block_Vario_Umlenkstation_500mm ="Vario_Umlenkstation_500mm"
block_Vario_Motorstation_500mm = "Vario_Motorstation_500mm"
import_block( block_Vario_Motorstation_500mm, lib_doc, doc,math.radians(3))
import_block( block_Vario_Umlenkstation_500mm , lib_doc, doc,math.radians(3))
upper_hoehe_vario= float(merkmale.get("Höhe Ende")) *1000
lower_hoehe_vario = float(merkmale.get("Höhe Anfang")) *1000
if upper_hoehe_vario< lower_hoehe_vario:
hight = upper_hoehe_vario
upper_hoehe_vario = lower_hoehe_vario
lower_hoehe_vario = hight
rotation = rotation -180
hoehe_vario= (upper_hoehe_vario + lower_hoehe_vario)/2
rotation = float(merkmale.get("Drehung"))
for nachbarn in strecken_nachbarn:
if teileid == nachbarn.get("Id"):
gefaellestrecke_vario = nachbarn
break
laenge = float(merkmale.get("Länge in Meter")) *1000
if "Drehung0" in gefaellestrecke_vario and "Drehung1" not in gefaellestrecke_vario:
drehung0 = gefaellestrecke_vario.get("Drehung0")
if upper_hoehe_vario == gefaellestrecke_vario.get("Hoehe0"):
ein_kreisel_höher = True
blockname = (f"Vario_Foerderer_{winkel}_{voerder_richtung}_{laenge}_{hoehe_vario}_rechts_{ein_kreisel_höher}_{drehung0}")
block_name_links = (f"Vario_Foerderer_{winkel}_{voerder_richtung}_{laenge}_{hoehe_vario}_links_{ein_kreisel_höher}_{drehung0}")
if blockname in doc.blocks:
if merkmale.get("Motorseite")== "links":
msp.add_blockref(block_name_links,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
return
elif merkmale.get("Motorseite")== "rechts":
msp.add_blockref(blockname,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
return
block_vario = doc.blocks.new(blockname, base_point=(0,0,0))
start, ende =erstellung_gefaelle_block_verbunenden_am_einen(x, y, doc, lib_doc, asoffset, esoffset, upper_hoehe_vario, lower_hoehe_vario, hoehe_vario, drehung0, laenge, blockname,None ,block_vario, voerder_richtung, ein_kreisel_höher)
if blockname not in doc.blocks or block_name_links not in doc.blocks:
vario_erstellung(merkmale, x, y, doc, lib_doc, config, winkel, umlenk_motor_offset, block_Vario_Umlenkstation_500mm, block_Vario_Motorstation_500mm, hoehe_vario, laenge, block_vario,block_name_links, start, ende)
if merkmale.get("Motorseite")== "links":
msp.add_blockref(block_name_links,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
if merkmale.get("Motorseite")== "rechts":
msp.add_blockref(blockname,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
elif "Drehung0" in gefaellestrecke_vario and "Drehung1" in gefaellestrecke_vario:
drehung0 = gefaellestrecke_vario.get("Drehung0")
drehung1 = gefaellestrecke_vario.get("Drehung1")
kreisel_hoehe0 =float(gefaellestrecke_vario.get("Hoehe0"))
kreisel_hoehe1= float(gefaellestrecke_vario.get("Hoehe1"))
if float(gefaellestrecke_vario.get("Hoehe0"))< float(gefaellestrecke_vario.get("Hoehe1")):
drehung2 = drehung0
drehung0 = drehung1
drehung1 = drehung2
blockname = (f"Vario_Foerderer_{winkel}_{voerder_richtung}_{laenge}_{hoehe_vario}_rechts_{drehung0}_{drehung1}")
block_name_links = (f"Vario_Foerderer_{winkel}_{voerder_richtung}_{laenge}_{hoehe_vario}_links_{drehung0}_{drehung1}")
if blockname in doc.blocks:
if merkmale.get("Motorseite")== "links":
msp.add_blockref(block_name_links,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
return
elif merkmale.get("Motorseite")== "rechts":
msp.add_blockref(blockname,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
return
block_vario = doc.blocks.new(blockname, base_point=(0,0,0))
start, ende =gefaellegerade_erstellung(x, y, doc, lib_doc, asoffset, esoffset, upper_hoehe_vario, lower_hoehe_vario, hoehe_vario,richtung2, drehung0, drehung1, laenge, None, blockname,block_vario,voerder_richtung)
if blockname not in doc.blocks or block_name_links not in doc.blocks:
vario_erstellung(merkmale, x, y, doc, lib_doc, config, winkel, umlenk_motor_offset, block_Vario_Umlenkstation_500mm, block_Vario_Motorstation_500mm, hoehe_vario, laenge, block_vario,block_name_links, start, ende)
if merkmale.get("Motorseite")== "links":
msp.add_blockref(block_name_links,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
elif merkmale.get("Motorseite")== "rechts":
msp.add_blockref(blockname,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
else:
halbe_laenge = laenge/2
dy = halbe_laenge * math.cos(0)
blockname = (f"Vario_Foerderer_{winkel}_{voerder_richtung}_{laenge}_{hoehe_vario}_rechts")
block_name_links =(f"Vario_Foerderer_{winkel}_{voerder_richtung}_{laenge}_{hoehe_vario}_links")
if blockname in doc.blocks:
if merkmale.get("Motorseite")== "links":
msp.add_blockref(block_name_links,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
return
elif merkmale.get("Motorseite")== "rechts":
msp.add_blockref(blockname,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
return
block = doc.blocks.new(blockname, base_point=(0,0,0))
start = (x,y +dy, upper_hoehe_vario)
ende = (x ,y -dy, lower_hoehe_vario)
if blockname not in doc.blocks or block_name_links not in doc.blocks:
vario_erstellung(merkmale, x, y, doc, lib_doc, config, winkel, umlenk_motor_offset, block_Vario_Umlenkstation_500mm, block_Vario_Motorstation_500mm, hoehe_vario, laenge, block,block_name_links, start, ende)
if merkmale.get("Motorseite")== "links":
msp.add_blockref(block_name_links,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
if merkmale.get("Motorseite")== "rechts":
msp.add_blockref(blockname,(x,y,hoehe_vario),dxfattribs={"rotation": rotation})
def vario_erstellung(merkmale, x, y, doc, lib_doc, config, winkel, umlenk_motor_offset, block_Vario_Umlenkstation_500mm, block_Vario_Motorstation_500mm, hoehe_vario, laenge, block,block_name_links, start, ende):
if merkmale.get("Förderrichtung") == "Auf":
block.add_blockref(block_Vario_Umlenkstation_500mm,(ende[0] -x,ende[1] -y + umlenk_motor_offset[0]/2,ende[2] - hoehe_vario -umlenk_motor_offset[2]/2 ),dxfattribs={"rotation": 90})
ende = (ende[0] ,ende[1] + umlenk_motor_offset[0],ende[2] -umlenk_motor_offset[2])
block.add_blockref(block_Vario_Motorstation_500mm, (start[0]-x , start[1] - umlenk_motor_offset[0]/2 -y ,start[2] - hoehe_vario +umlenk_motor_offset[2]/2),dxfattribs={"rotation": 90})
start = start[0] , start[1] - umlenk_motor_offset[0],start[2] +umlenk_motor_offset[2]
if winkel == 48:
block_Vario_Bogen_auf_51 = "Vario_Bogen_auf_51°"
block_Vario_Bogen_ab_51 = "Vario_Bogen_ab_51°"
Vario_Bogen_auf_51_Delta_SP_0_aufwaerts = tuple(float(x)for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_51_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_auf_51_Delta_SP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_51_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_ab_51_Delta_SP_0_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_51_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_ab_51_Delta_SP_1_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_51_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_auf_51_Delta_VP_1_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_51_Delta_VP_1_aufwaerts")).split(","))
Vario_Bogen_ab_51_Delta_VP_0_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_51_Delta_VP_0_aufwaerts")).split(","))
import_block(block_Vario_Bogen_auf_51, lib_doc, doc,math.radians(3))
import_block(block_Vario_Bogen_ab_51, lib_doc, doc,math.radians(-48))
block.add_blockref(block_Vario_Bogen_auf_51,(ende[0] -x ,ende[1] +Vario_Bogen_auf_51_Delta_SP_0_aufwaerts[0] -y ,ende[2] - Vario_Bogen_auf_51_Delta_SP_0_aufwaerts[2]- hoehe_vario ),dxfattribs={"rotation": 90})
ende = (ende[0] ,ende[1] +Vario_Bogen_auf_51_Delta_SP_1_aufwaerts[0] + Vario_Bogen_auf_51_Delta_SP_0_aufwaerts[0] ,ende[2] + Vario_Bogen_auf_51_Delta_SP_1_aufwaerts[2] - Vario_Bogen_auf_51_Delta_SP_0_aufwaerts[2])
ende_VP = (ende[0] +Vario_Bogen_auf_51_Delta_VP_1_aufwaerts[1], ende[1]-Vario_Bogen_auf_51_Delta_VP_1_aufwaerts[0],ende[2] + Vario_Bogen_auf_51_Delta_VP_1_aufwaerts[2])
block.add_blockref(block_Vario_Bogen_ab_51 ,(start[0]-x,start[1] - Vario_Bogen_ab_51_Delta_SP_1_aufwaerts[0] -y ,start[2] - hoehe_vario+Vario_Bogen_ab_51_Delta_SP_1_aufwaerts[2]),dxfattribs={"rotation": 90})
start = start[0] ,start[1] - Vario_Bogen_ab_51_Delta_SP_0_aufwaerts[0] - Vario_Bogen_ab_51_Delta_SP_1_aufwaerts[0],start[2] + Vario_Bogen_ab_51_Delta_SP_1_aufwaerts[2]- Vario_Bogen_ab_51_Delta_SP_0_aufwaerts[2]
start_VP = start[0] +Vario_Bogen_ab_51_Delta_VP_0_aufwaerts[1],start[1]+Vario_Bogen_ab_51_Delta_VP_0_aufwaerts[0] ,start[2]-Vario_Bogen_ab_51_Delta_VP_0_aufwaerts[2]
line_VP = Line.new(dxfattribs={"start":start_VP,"end": ende_VP})
line_VP.dxf.layer = "VARIO"
copy_VP = line_VP.copy()
copy_VP.translate(-x,-y,-hoehe_vario)
block.add_entity(copy_VP)
line = Line.new(dxfattribs={"start": start, "end": ende})
copy= line.copy()
copy.translate(-x,-y,-hoehe_vario)
block.add_entity(copy)
elif winkel == 36:
block_Vario_Bogen_auf_39 = "Vario_Bogen_auf_39°"
block_Vario_Bogen_ab_39 = "Vario_Bogen_ab_39°"
Vario_Bogen_auf_39_Delta_SP_0_aufwaerts = tuple(float(x)for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_39_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_auf_39_Delta_SP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_39_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_ab_39_Delta_SP_0_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_39_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_ab_39_Delta_SP_1_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_39_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_auf_39_Delta_VP_1_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_39_Delta_VP_1_aufwaerts")).split(","))
Vario_Bogen_ab_39_Delta_VP_0_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_39_Delta_VP_0_aufwaerts")).split(","))
import_block(block_Vario_Bogen_auf_39, lib_doc, doc,math.radians(3))
import_block(block_Vario_Bogen_ab_39, lib_doc, doc,math.radians(-36))
block.add_blockref(block_Vario_Bogen_auf_39,(ende[0] -x ,ende[1] +Vario_Bogen_auf_39_Delta_SP_0_aufwaerts[0] -y ,ende[2] - Vario_Bogen_auf_39_Delta_SP_0_aufwaerts[2]- hoehe_vario ),dxfattribs={"rotation": 90})
ende = (ende[0] ,ende[1] +Vario_Bogen_auf_39_Delta_SP_1_aufwaerts[0] + Vario_Bogen_auf_39_Delta_SP_0_aufwaerts[0] ,ende[2] + Vario_Bogen_auf_39_Delta_SP_1_aufwaerts[2] - Vario_Bogen_auf_39_Delta_SP_0_aufwaerts[2])
ende_VP = (ende[0] +Vario_Bogen_auf_39_Delta_VP_1_aufwaerts[1], ende[1] +Vario_Bogen_auf_39_Delta_SP_1_aufwaerts[0]-Vario_Bogen_auf_39_Delta_VP_1_aufwaerts[0],ende[2] - Vario_Bogen_auf_39_Delta_VP_1_aufwaerts[2])
block.add_blockref(block_Vario_Bogen_ab_39 ,(start[0]-x,start[1] - Vario_Bogen_ab_39_Delta_SP_1_aufwaerts[0] -y ,start[2] - hoehe_vario+Vario_Bogen_ab_39_Delta_SP_1_aufwaerts[2]),dxfattribs={"rotation": 90})
start = start[0] ,start[1] - Vario_Bogen_ab_39_Delta_SP_0_aufwaerts[0] - Vario_Bogen_ab_39_Delta_SP_1_aufwaerts[0],start[2] -Vario_Bogen_ab_39_Delta_SP_0_aufwaerts[2] + Vario_Bogen_ab_39_Delta_SP_1_aufwaerts[2]
start_VP = start[0] +Vario_Bogen_ab_39_Delta_VP_0_aufwaerts[1],start[1]+Vario_Bogen_ab_39_Delta_VP_0_aufwaerts[0] - Vario_Bogen_ab_39_Delta_SP_0_aufwaerts[0],start[2]-Vario_Bogen_ab_39_Delta_VP_0_aufwaerts[2]
line_VP = Line.new(dxfattribs={"start":start_VP,"end": ende_VP})
line_VP.dxf.layer = "VARIO"
copy_VP = line_VP.copy()
copy_VP.translate(-x,-y,-hoehe_vario)
block.add_entity(copy_VP)
line = Line.new(dxfattribs={"start": start, "end": ende})
copy= line.copy()
copy.translate(-x,-y,-hoehe_vario)
block.add_entity(copy)
elif winkel == 24:
block_Vario_Bogen_auf_27 = "Vario_Bogen_auf_27°"
block_Vario_Bogen_ab_27 = "Vario_Bogen_ab_27°"
Vario_Bogen_auf_27_Delta_SP_0_aufwaerts = tuple(float(x)for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_27_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_auf_27_Delta_SP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_27_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_ab_27_Delta_SP_0_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_27_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_ab_27_Delta_SP_1_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_27_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_auf_27_Delta_VP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_27_Delta_VP_1_aufwaerts")).split(","))
Vario_Bogen_ab_27_Delta_VP_0_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_27_Delta_VP_0_aufwaerts")).split(","))
import_block(block_Vario_Bogen_auf_27, lib_doc, doc,math.radians(3))
import_block(block_Vario_Bogen_ab_27, lib_doc, doc,math.radians(-24))
block.add_blockref(block_Vario_Bogen_auf_27,(ende[0] -x ,ende[1] +Vario_Bogen_auf_27_Delta_SP_0_aufwaerts[0] -y ,ende[2] - Vario_Bogen_auf_27_Delta_SP_0_aufwaerts[2]- hoehe_vario ),dxfattribs={"rotation": 90})
ende = (ende[0] ,ende[1] +Vario_Bogen_auf_27_Delta_SP_1_aufwaerts[0] + Vario_Bogen_auf_27_Delta_SP_0_aufwaerts[0] ,ende[2] + Vario_Bogen_auf_27_Delta_SP_1_aufwaerts[2] - Vario_Bogen_auf_27_Delta_SP_0_aufwaerts[2])
ende_VP = (ende[0] +Vario_Bogen_auf_27_Delta_VP_1_aufwaerts[1], ende[1] +Vario_Bogen_auf_27_Delta_VP_1_aufwaerts[0],ende[2] - Vario_Bogen_auf_27_Delta_VP_1_aufwaerts[2])
block.add_blockref(block_Vario_Bogen_ab_27 ,(start[0]-x,start[1] - Vario_Bogen_ab_27_Delta_SP_1_aufwaerts[0] -y ,start[2] - hoehe_vario + Vario_Bogen_ab_27_Delta_SP_1_aufwaerts[2]),dxfattribs={"rotation": 90})
start = start[0] ,start[1] - Vario_Bogen_ab_27_Delta_SP_0_aufwaerts[0] - Vario_Bogen_ab_27_Delta_SP_1_aufwaerts[0],start[2] -Vario_Bogen_ab_27_Delta_SP_0_aufwaerts[2] + Vario_Bogen_ab_27_Delta_SP_1_aufwaerts[2]
start_VP = start[0] +Vario_Bogen_ab_27_Delta_VP_0_aufwaerts[1],start[1]+Vario_Bogen_ab_27_Delta_VP_0_aufwaerts[0] ,start[2]-Vario_Bogen_ab_27_Delta_VP_0_aufwaerts[2]
line_VP = Line.new(dxfattribs={"start":start_VP,"end": ende_VP})
line_VP.dxf.layer = "VARIO"
copy_VP = line_VP.copy()
copy_VP.translate(-x,-y,-hoehe_vario)
block.add_entity(copy_VP)
line = Line.new(dxfattribs={"start": start, "end": ende})
copy= line.copy()
copy.translate(-x,-y,-hoehe_vario)
block.add_entity(copy)
elif winkel == 15:
block_Vario_Bogen_ab_18 = "Vario_Bogen_ab_18°"
block_Vario_Bogen_auf_18 = "Vario_Bogen_auf_18°"
Vario_Bogen_auf_18_Delta_SP_0_aufwaerts = tuple(float(x)for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_18_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_auf_18_Delta_SP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_18_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_ab_18_Delta_SP_0_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_18_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_ab_18_Delta_SP_1_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_18_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_auf_18_Delta_VP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_18_Delta_VP_1_aufwaerts")).split(","))
Vario_Bogen_ab_18_Delta_VP_0_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_18_Delta_VP_0_aufwaerts")).split(","))
import_block(block_Vario_Bogen_auf_18, lib_doc, doc,math.radians(3))
import_block(block_Vario_Bogen_ab_18, lib_doc, doc,math.radians(-15))
block.add_blockref(block_Vario_Bogen_auf_18,(ende[0] -x ,ende[1] +Vario_Bogen_auf_18_Delta_SP_0_aufwaerts[0] -y ,ende[2] - Vario_Bogen_auf_18_Delta_SP_0_aufwaerts[2]- hoehe_vario ),dxfattribs={"rotation": 90})
ende = (ende[0] ,ende[1] +Vario_Bogen_auf_18_Delta_SP_1_aufwaerts[0] + Vario_Bogen_auf_18_Delta_SP_0_aufwaerts[0] ,ende[2] + Vario_Bogen_auf_18_Delta_SP_1_aufwaerts[2] - Vario_Bogen_auf_18_Delta_SP_0_aufwaerts[2])
ende_VP = (ende[0] +Vario_Bogen_auf_18_Delta_VP_1_aufwaerts[1], ende[1] +Vario_Bogen_auf_18_Delta_VP_1_aufwaerts[0],ende[2] - Vario_Bogen_auf_18_Delta_VP_1_aufwaerts[2])
block.add_blockref(block_Vario_Bogen_ab_18 ,(start[0]-x,start[1] - Vario_Bogen_ab_18_Delta_SP_1_aufwaerts[0] -y ,start[2] - hoehe_vario+Vario_Bogen_ab_18_Delta_SP_1_aufwaerts[2]),dxfattribs={"rotation": 90})
start = start[0] ,start[1] - Vario_Bogen_ab_18_Delta_SP_0_aufwaerts[0] - Vario_Bogen_ab_18_Delta_SP_1_aufwaerts[0],start[2] -Vario_Bogen_ab_18_Delta_SP_0_aufwaerts[2] + Vario_Bogen_ab_18_Delta_SP_1_aufwaerts[2]
start_VP = start[0] +Vario_Bogen_ab_18_Delta_VP_0_aufwaerts[1],start[1]+Vario_Bogen_ab_18_Delta_VP_0_aufwaerts[0] ,start[2]-Vario_Bogen_ab_18_Delta_VP_0_aufwaerts[2]
line_VP = Line.new(dxfattribs={"start":start_VP,"end": ende_VP})
line_VP.dxf.layer = "VARIO"
copy_VP = line_VP.copy()
copy_VP.translate(-x,-y,-hoehe_vario)
block.add_entity(copy_VP)
line = Line.new(dxfattribs={"start": start, "end": ende})
copy= line.copy()
copy.translate(-x,-y,-hoehe_vario)
block.add_entity(copy)
elif winkel == 12:
block_Vario_Bogen_ab_15 = "Vario_Bogen_ab_15°"
block_Vario_Bogen_auf_15 = "Vario_Bogen_auf_15°"
Vario_Bogen_auf_15_Delta_SP_0_aufwaerts = tuple(float(x)for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_15_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_auf_15_Delta_SP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_15_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_ab_15_Delta_SP_0_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_15_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_ab_15_Delta_SP_1_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_15_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_auf_15_Delta_VP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_15_Delta_VP_1_aufwaerts")).split(","))
Vario_Bogen_ab_15_Delta_VP_0_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_15_Delta_VP_0_aufwaerts")).split(","))
import_block(block_Vario_Bogen_auf_15, lib_doc, doc,math.radians(3))
import_block(block_Vario_Bogen_ab_15, lib_doc, doc,math.radians(-12))
block.add_blockref(block_Vario_Bogen_auf_15,(ende[0] -x ,ende[1] +Vario_Bogen_auf_15_Delta_SP_0_aufwaerts[0] -y ,ende[2] - Vario_Bogen_auf_15_Delta_SP_0_aufwaerts[2]- hoehe_vario ),dxfattribs={"rotation": 90})
ende = (ende[0] ,ende[1] +Vario_Bogen_auf_15_Delta_SP_1_aufwaerts[0] + Vario_Bogen_auf_15_Delta_SP_0_aufwaerts[0] ,ende[2] + Vario_Bogen_auf_15_Delta_SP_1_aufwaerts[2] - Vario_Bogen_auf_15_Delta_SP_0_aufwaerts[2])
ende_VP = (ende[0] +Vario_Bogen_auf_15_Delta_VP_1_aufwaerts[1], ende[1] +Vario_Bogen_auf_15_Delta_VP_1_aufwaerts[0],ende[2] - Vario_Bogen_auf_15_Delta_VP_1_aufwaerts[2])
block.add_blockref(block_Vario_Bogen_ab_15 ,(start[0]-x,start[1] - Vario_Bogen_ab_15_Delta_SP_1_aufwaerts[0] -y ,start[2] - hoehe_vario+Vario_Bogen_ab_15_Delta_SP_1_aufwaerts[2]),dxfattribs={"rotation": 90})
start = start[0] ,start[1] - Vario_Bogen_ab_15_Delta_SP_0_aufwaerts[0] - Vario_Bogen_ab_15_Delta_SP_1_aufwaerts[0],start[2] -Vario_Bogen_ab_15_Delta_SP_0_aufwaerts[2] + Vario_Bogen_ab_15_Delta_SP_1_aufwaerts[2]
start_VP = start[0] +Vario_Bogen_ab_15_Delta_VP_0_aufwaerts[1],start[1]+Vario_Bogen_ab_15_Delta_VP_0_aufwaerts[0] ,start[2]-Vario_Bogen_ab_15_Delta_VP_0_aufwaerts[2]
line_VP = Line.new(dxfattribs={"start":start_VP,"end": ende_VP})
line_VP.dxf.layer = "VARIO"
copy_VP = line_VP.copy()
copy_VP.translate(-x,-y,-hoehe_vario)
block.add_entity(copy_VP)
line = Line.new(dxfattribs={"start": start, "end": ende})
copy= line.copy()
copy.translate(-x,-y,-hoehe_vario)
block.add_entity(copy)
elif winkel == 9:
block_Vario_Bogen_ab_12 = "Vario_Bogen_ab_12°"
block_Vario_Bogen_auf_12 = "Vario_Bogen_auf_12°"
Vario_Bogen_auf_12_Delta_SP_0_aufwaerts = tuple(float(x)for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_12_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_auf_12_Delta_SP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_12_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_ab_12_Delta_SP_0_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_12_Delta_SP_0_aufwaerts")).split(","))
Vario_Bogen_ab_12_Delta_SP_1_aufwaerts = tuple(float(x) for x in(config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_12_Delta_SP_1_aufwaerts")).split(","))
Vario_Bogen_auf_12_Delta_VP_1_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_auf_12_Delta_VP_1_aufwaerts")).split(","))
Vario_Bogen_ab_12_Delta_VP_0_aufwaerts = tuple(float(x) for x in (config.get("ILS 2.0 Variofoerderer","Vario_Bogen_ab_12_Delta_VP_0_aufwaerts")).split(","))
import_block(block_Vario_Bogen_auf_12, lib_doc, doc,math.radians(3))
import_block(block_Vario_Bogen_ab_12, lib_doc, doc,math.radians(-9))
block.add_blockref(block_Vario_Bogen_auf_12,(ende[0] -x ,ende[1] +Vario_Bogen_auf_12_Delta_SP_0_aufwaerts[0] -y ,ende[2] - Vario_Bogen_auf_12_Delta_SP_0_aufwaerts[2]- hoehe_vario ),dxfattribs={"rotation": 90})
ende = (ende[0] ,ende[1] +Vario_Bogen_auf_12_Delta_SP_1_aufwaerts[0] + Vario_Bogen_auf_12_Delta_SP_0_aufwaerts[0] ,ende[2] + Vario_Bogen_auf_12_Delta_SP_1_aufwaerts[2] - Vario_Bogen_auf_12_Delta_SP_0_aufwaerts[2])
ende_VP = (ende[0] +Vario_Bogen_auf_12_Delta_VP_1_aufwaerts[1], ende[1] +Vario_Bogen_auf_12_Delta_VP_1_aufwaerts[0],ende[2] - Vario_Bogen_auf_12_Delta_VP_1_aufwaerts[2])
block.add_blockref(block_Vario_Bogen_ab_12 ,(start[0]-x,start[1] - Vario_Bogen_ab_12_Delta_SP_1_aufwaerts[0] -y ,start[2] - hoehe_vario+Vario_Bogen_ab_12_Delta_SP_1_aufwaerts[2]),dxfattribs={"rotation": 90})
start = start[0] ,start[1] - Vario_Bogen_ab_12_Delta_SP_0_aufwaerts[0] - Vario_Bogen_ab_12_Delta_SP_1_aufwaerts[0],start[2] -Vario_Bogen_ab_12_Delta_SP_0_aufwaerts[2] + Vario_Bogen_ab_12_Delta_SP_1_aufwaerts[2]
start_VP = start[0] +Vario_Bogen_ab_12_Delta_VP_0_aufwaerts[1],start[1]+Vario_Bogen_ab_12_Delta_VP_0_aufwaerts[0] ,start[2]-Vario_Bogen_ab_12_Delta_VP_0_aufwaerts[2]
line_VP = Line.new(dxfattribs={"start":start_VP,"end": ende_VP})
line_VP.dxf.layer = "VARIO"
copy_VP = line_VP.copy()
copy_VP.translate(-x,-y,-hoehe_vario)
block.add_entity(copy_VP)
line = Line.new(dxfattribs={"start": start, "end": ende})
copy= line.copy()
copy.translate(-x,-y,-hoehe_vario)
block.add_entity(copy)
elif winkel == 3:
line = Line.new(dxfattribs={"start": start, "end": ende})
copy= line.copy()
copy.translate(-x,-y,-hoehe_vario)
block.add_entity(copy)
matrix = Matrix44.scale(-1,1,1)
block_links = doc.blocks.new(block_name_links, base_point=(0,0,0))
for entity in block:
clone= entity.copy()
if entity.dxftype() == "INSERT":
if (entity.dxf.name == "400102632_ES-Element_90_links" or entity.dxf.name == "200000146_ES-Element_90_rechts" or
entity.dxf.name == "200000241_AS-Element_90_rechts" or entity.dxf.name == "200000217_AS-Element_90_links"
):
block_links.add_entity(clone)
else:
clone.transform(matrix)
block_links.add_entity(clone)
else:
clone.transform(matrix)
block_links.add_entity(clone)
def handle_omniflo(msp, teileid, merkmale, x, y, doc, lib_doc, verbose, symbols, strecken_nachbarn,config):
"""
Für Omniflo Gerade: zeichnet eine Linie (Mitte = Koordinate, Länge und Winkel aus Merkmale).
Für alle anderen Omniflo-Typen: Block mit SivasNummer an den Koordinaten.
"""
# Prüfen, ob es sich um eine Gerade handelt
if merkmale.get("Länge in Meter") is not None and merkmale.get("Winkel") is not None:
try:
laenge = float(merkmale.get("Länge in Meter", "0").replace(",", ".")) * 1000 # Meter → mm
except Exception:
laenge = 0
try:
winkel = float(merkmale.get("Drehung"))
except Exception:
winkel = 0.0
winkel_rad = math.radians(winkel)
halbe_laenge = laenge / 2
# Man muss bei sin -1 machen wegen des links koordinaten system
dx = halbe_laenge * math.sin(winkel_rad * -1)
dy = halbe_laenge * math.cos(winkel_rad)
start = (x + dx, y + dy, float(merkmale.get("Höhe oben")) )
ende = (x - dx, y - dy, float(merkmale.get("Höhe unten")))
if "A-2" not in doc.layers:
doc.layers.add(name="A-2", color=2)
linie=msp.add_line(start, ende)
linie.dxf.layer = "A-2"
if verbose:
print(f"[INFO] Omniflo Gerade → {teileid} Linie von ({start[0]:.1f}, {start[1]:.1f}) nach ({ende[0]:.1f}, {ende[1]:.1f})")
return
# Sonst wie gehabt: Block mit SivasNummer
if not lib_doc:
print("[WARN] lib_doc nicht verfügbar, Block wird nicht eingefügt.")
return
blockname = merkmale.get("SivasNummer")
if not blockname:
print(f"[WARN] Keine SivasNummer für {teileid}, überspringe.")
return
if blockname not in lib_doc.blocks:
print(f"[WARN] Omniflo-Block '{blockname}' nicht in Bibliothek {lib_doc.filename}. Überspringe {teileid}.")
return
import_block(blockname, lib_doc, doc)
blockref_layer = get_layer(doc, lib_doc, blockname)
drehung = merkmale.get("Drehung")
bref = msp.add_blockref(blockname, (x, y,float(merkmale.get("Höhe"))), dxfattribs={"xscale": 1.0, "yscale":1.0,"rotation": drehung, "layer": blockref_layer})
a =bref.add_attrib(
tag= "NAME",
text= merkmale.get("bezeichner"),
insert = (x,y)
)
a.is_invisible = True
bref.add_auto_attribs({ATTR_TAG: teileid})
if verbose:
print(f"[INFO] Block '{blockname}' (Omniflo) → {teileid} ({x:.1f}, {y:.1f})")
def erstellung_gefaelle_block_verbunenden_am_einen(x, y, doc, lib_doc, asoffset, esoffset, upper_hoehe_gefaehlle, lower_hoehe_gefaehlle, hoehe_gefaehlle, drehung0, laenge,blockname, hight = None, block_vario = None, vario_richtung = None, verbungden_höher = None):
if ((blockname not in doc.blocks and hight == "higher" and drehung0 == "GUZS" )or (vario_richtung == "Auf"and verbungden_höher == False and drehung0 == "GUZS")or (vario_richtung == "Ab" and verbungden_höher == True and drehung0 == "GUZS") ):
if hight != None:
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
block_as = "200000241_AS-Element_90_rechts"
import_block(block_as,lib_doc,doc)
dy = halbe_laenge * math.cos(0)
if vario_richtung != None:
start = (x , y + dy ,upper_hoehe_gefaehlle)
ende = (x , y - dy + asoffset ,lower_hoehe_gefaehlle)
block_vario.add_blockref(block_as,(ende[0]-x ,ende[1]-asoffset -y,ende[2] -hoehe_gefaehlle),dxfattribs={"rotation": 180})
return start, ende
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy ,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] -hoehe_gefaehlle))
elif ((blockname not in doc.blocks and hight == "lower" and drehung0 == "GUZS") or (vario_richtung == "Auf"and verbungden_höher == True and drehung0 == "GUZS") or (vario_richtung == "Ab" and verbungden_höher == False and drehung0 == "GUZS")):
block_es = "200000146_ES-Element_90_rechts"
import_block(block_es,lib_doc,doc)
if hight != None:
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
if vario_richtung != None:
start = (x , y + dy-esoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy ,lower_hoehe_gefaehlle)
block_vario.add_blockref(block_es, (start[0]-x ,start[1]+esoffset-y ,start[2] -hoehe_gefaehlle),dxfattribs={"rotation": 180})
return start, ende
start = (x , y + dy,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block.add_blockref(block_es, (ende[0]-x ,ende[1]-esoffset-y ,ende[2] -hoehe_gefaehlle))
elif ((blockname not in doc.blocks and hight == "higher" and drehung0 == "UZS")or (vario_richtung == "Auf"and verbungden_höher == False and drehung0 == "UZS") or (vario_richtung == "Ab" and verbungden_höher == True and drehung0 == "UZS")):
block_as = "200000217_AS-Element_90_links"
import_block(block_as,lib_doc,doc)
if hight != None:
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
if vario_richtung != None:
start = (x , y + dy ,upper_hoehe_gefaehlle)
ende = (x , y - dy + asoffset,lower_hoehe_gefaehlle)
block_vario.add_blockref(block_as,(ende[0]-x ,ende[1]-asoffset -y,ende[2] - hoehe_gefaehlle))
return start, ende
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy ,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x ,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
elif (( blockname not in doc.blocks and hight == "lower" and drehung0 == "UZS") or (vario_richtung == "Auf" and verbungden_höher == True and drehung0 == "UZS") or (vario_richtung == "Ab" and verbungden_höher == False and drehung0 == "UZS")):
if hight != None:
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
block_es = "400102632_ES-Element_90_links"
import_block(block_es,lib_doc,doc)
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
if vario_richtung != None:
start = (x , y + dy-esoffset ,upper_hoehe_gefaehlle)
ende = (x , y - dy,lower_hoehe_gefaehlle)
block_vario.add_blockref(block_es, (start[0]-x ,start[1]+esoffset -y,start[2] - hoehe_gefaehlle))
return start, ende
start = (x , y + dy ,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x ,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block.add_blockref(block_es, (ende[0]-x ,ende[1]-esoffset -y,ende[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
def gefaellegerade_erstellung(x, y, doc, lib_doc, asoffset, esoffset, upper_hoehe_gefaehlle, lower_hoehe_gefaehlle, hoehe_gefaehlle,richtung2, drehung0, drehung1, laenge, hight_position, blockname, block_vario = None,voerder_richtung = None):
#erstellung des blockes falls die gefaelle strecke mit einem kreisel verbunden ist, mehrere variation von selben weil diese nötig sind sobald man die richtigen inserts bekommen
if upper_hoehe_gefaehlle < lower_hoehe_gefaehlle:
middle_hoehe = upper_hoehe_gefaehlle
upper_hoehe_gefaehlle = lower_hoehe_gefaehlle
lower_hoehe_gefaehlle = middle_hoehe
if richtung2!= "DEFAULT":
if blockname not in doc.blocks and drehung0 == "GUZS" and drehung1 == "GUZS" and hight_position == "higher" :
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
start = (x , y + dy,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_es = "200000146_ES-Element_90_rechts"
import_block(block_es,lib_doc,doc)
block.add_blockref(block_es, (ende[0]-x ,ende[1]-esoffset-y ,ende[2] -hoehe_gefaehlle))
elif blockname not in doc.blocks and drehung0 == "GUZS" and drehung1 == "GUZS":
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy ,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_as = "200000241_AS-Element_90_rechts"
import_block(block_as,lib_doc,doc)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] -hoehe_gefaehlle))
elif blockname not in doc.blocks and ((drehung0 == "GUZS" and drehung1 == "UZS" and hight_position == "higher")):
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
start = (x , y + dy ,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_es = "400102632_ES-Element_90_links"
import_block(block_es,lib_doc,doc)
block.add_blockref(block_es,(ende[0]-x ,ende[1]-esoffset -y,ende[2] - hoehe_gefaehlle), dxfattribs={"rotation": 180})
elif blockname not in doc.blocks and (drehung0 == "UZS" and drehung1 == "GUZS" and hight_position == "lower"):
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy ,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_as = "200000241_AS-Element_90_rechts"
import_block(block_as,lib_doc,doc)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] - hoehe_gefaehlle))
elif blockname not in doc.blocks and drehung0 == "UZS" and drehung1 == "UZS" and hight_position == "higher":
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
start = (x , y + dy ,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x ,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_es = "400102632_ES-Element_90_links"
import_block(block_es,lib_doc,doc)
block.add_blockref(block_es, (ende[0]-x ,ende[1]-esoffset -y,ende[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
elif blockname not in doc.blocks and drehung0 == "UZS" and drehung1 == "UZS":
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy ,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x ,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_as = "200000217_AS-Element_90_links"
import_block(block_as,lib_doc,doc)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
elif blockname not in doc.blocks and ((drehung0 == "UZS" and drehung1 == "GUZS" and hight_position== "higher")):
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
start = (x , y + dy,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x ,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_es = "200000146_ES-Element_90_rechts"
import_block(block_es,lib_doc,doc)
block.add_blockref(block_es, (ende[0]-x ,ende[1]-esoffset -y,ende[2] - hoehe_gefaehlle))
elif blockname not in doc.blocks and (drehung0 == "GUZS" and drehung1 == "UZS" and hight_position == "lower"):
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy ,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x ,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_as = "200000217_AS-Element_90_links"
import_block(block_as,lib_doc,doc)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
#erstellung von den normalen gefällestrecken
else:
if ((blockname not in doc.blocks and drehung0 == "GUZS" and drehung1 == "GUZS") or (voerder_richtung != None and drehung0 == "GUZS" and drehung1 == "GUZS")):
block_as = "200000241_AS-Element_90_rechts"
import_block(block_as,lib_doc,doc)
block_es = "200000146_ES-Element_90_rechts"
import_block(block_es,lib_doc,doc)
if hight_position != None:
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
if hight_position == None:
start = (x , y + dy - esoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy + asoffset,lower_hoehe_gefaehlle)
block_vario.add_blockref(block_es,(start[0]-x ,start[1]+esoffset -y,start[2] -hoehe_gefaehlle), dxfattribs={"rotation": 180})
block_vario.add_blockref(block_as, (ende[0]-x ,ende[1]-asoffset-y ,ende[2] -hoehe_gefaehlle), dxfattribs={"rotation": 180})
return start,ende
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block_as = "200000241_AS-Element_90_rechts"
import_block(block_as,lib_doc,doc)
block_es = "200000146_ES-Element_90_rechts"
import_block(block_es,lib_doc,doc)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] -hoehe_gefaehlle))
block.add_blockref(block_es, (ende[0]-x ,ende[1]-esoffset-y ,ende[2] -hoehe_gefaehlle))
elif (blockname not in doc.blocks and((drehung0 == "GUZS" and drehung1 == "UZS" and hight_position == "higher")or (drehung0 == "UZS" and drehung1 == "GUZS" and hight_position == "lower")) or
voerder_richtung != None and drehung0 == "UZS"and drehung1 == "GUZS"):
block_as = "200000241_AS-Element_90_rechts"
import_block(block_as,lib_doc,doc)
block_es = "400102632_ES-Element_90_links"
import_block(block_es,lib_doc,doc)
if hight_position != None:
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
if hight_position == None:
start = (x , y + dy - esoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy + asoffset,lower_hoehe_gefaehlle)
block_vario.add_blockref(block_es,(start[0]-x ,start[1]+ esoffset -y,start[2] - hoehe_gefaehlle))
block_vario.add_blockref(block_as, (ende[0]-x ,ende[1]- asoffset-y,ende[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
return start, ende
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] - hoehe_gefaehlle))
block.add_blockref(block_es, (ende[0]-x ,ende[1]- esoffset-y,ende[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
elif ((blockname not in doc.blocks and drehung0 == "UZS" and drehung1 == "UZS") or (voerder_richtung != None and drehung0 == "UZS" and drehung1 == "UZS")):
block_as = "200000217_AS-Element_90_links"
import_block(block_as,lib_doc,doc)
block_es = "400102632_ES-Element_90_links"
import_block(block_es,lib_doc,doc)
if hight_position !=None:
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
if hight_position == None:
start = (x , y + dy - esoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy + asoffset,lower_hoehe_gefaehlle)
block_vario.add_blockref(block_es,(start[0]-x ,start[1]+esoffset -y,start[2] - hoehe_gefaehlle))
block_vario.add_blockref(block_as, (ende[0]-x ,ende[1]-asoffset -y,ende[2] - hoehe_gefaehlle))
return start, ende
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x ,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
block.add_blockref(block_es, (ende[0]-x ,ende[1]-esoffset -y,ende[2] - hoehe_gefaehlle) ,dxfattribs={"rotation": 180})
elif ((blockname not in doc.blocks and ((drehung0 == "UZS" and drehung1 == "GUZS" and hight_position== "higher")or (drehung0 == "GUZS" and drehung1 == "UZS" and hight_position == "lower")))or
voerder_richtung != None and drehung0 == "GUZS" and drehung1 == "UZS"):
block_as = "200000217_AS-Element_90_links"
import_block(block_as,lib_doc,doc)
block_es = "200000146_ES-Element_90_rechts"
import_block(block_es,lib_doc,doc)
if hight_position != None:
block = doc.blocks.new(name=blockname, base_point=(0,0,0))
halbe_laenge = laenge / 2
dy = halbe_laenge * math.cos(0)
if hight_position == None:
start = (x , y + dy - esoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy + asoffset,lower_hoehe_gefaehlle)
block_vario.add_blockref(block_es,(start[0]-x ,start[1]+esoffset -y,start[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
block_vario.add_blockref(block_as, (ende[0]-x ,ende[1]-asoffset -y,ende[2] - hoehe_gefaehlle))
return start,ende
start = (x , y + dy - asoffset,upper_hoehe_gefaehlle)
ende = (x , y - dy + esoffset,lower_hoehe_gefaehlle)
line = Line.new(dxfattribs={"start": start, "end": ende})
line.dxf.layer = "6-SP"
copy= line.copy()
copy.translate(-x ,-y,-hoehe_gefaehlle)
block.add_entity(copy)
block.add_blockref(block_as,(start[0]-x ,start[1]+asoffset -y,start[2] - hoehe_gefaehlle),dxfattribs={"rotation": 180})
block.add_blockref(block_es, (ende[0]-x ,ende[1]-esoffset -y,ende[2] - hoehe_gefaehlle))
def get_layer(doc, lib_doc, blockname):
if blockname in lib_doc.blocks:
src = lib_doc.blocks[blockname]
else:
src = doc.blocks[blockname]
try:
used_layer_names = {e.dxf.layer for e in src if hasattr(e.dxf, "layer")}
for layer_name in used_layer_names:
if layer_name and layer_name not in doc.layers:
try:
src_layer = lib_doc.layers.get(layer_name)
doc.layers.add(
name=layer_name,
color=getattr(src_layer.dxf, "color", None),
linetype=getattr(src_layer.dxf, "linetype", None),
lineweight=getattr(src_layer.dxf, "lineweight", None),
)
except Exception:
# Fallback: Layer mit Standardwerten anlegen
doc.layers.add(name=layer_name)
except Exception:
pass
layer_counts = {}
for e in src:
ln = getattr(e.dxf, "layer", None)
if not ln:
continue
if ln != "BOUNDING_BOX":
layer_counts[ln] = layer_counts.get(ln, 0) + 1
if layer_counts:
blockref_layer = max(layer_counts.items(), key=lambda kv: kv[1])[0]
return blockref_layer
def normalize_func_name(name):
return (
name.replace('ä', 'ae')
.replace('ö', 'oe')
.replace('ü', 'ue')
.replace('ß', 'ss')
.replace(' ', '_')
.replace('.', '_')
.lower()
)
def get_libfile_cfg(teileart, cfg_path):
"""Liest den Bibliotheksdateinamen für eine TeileArt aus der allgemein.cfg."""
parser = configparser.ConfigParser()
with open(cfg_path, encoding='utf-8') as f:
parser.read_file(f)
# Teileart kann z.B. "ILS 2.0 Kreisel" sein, wir nehmen den ersten Teil vor erstem Leerzeichen oder Punkt
# oder suchen iterativ nach Sektionen, die im Teileart-Namen vorkommen
for section in parser.sections():
if section in teileart:
return parser.get(section, "libfile", fallback=None)
return None
def get_rotations_of_strecken(csv_path:Path) -> dict:
geraden = []
kreisel =[]
strecken_nachbarn = []
anweisungen = 0
"""Gib für jede gefällestrecke zurück welche Drehrichtung die benachbarten Kreisel haben """
with csv_path.open(newline="", encoding="utf-8") as fh:
reader = csv.DictReader(fh, delimiter=';')
for row in reader:
bezeichner = row["TeileArt"].strip()
if bezeichner == "ILS 2.0 Gefällestrecke" or bezeichner =="ILS 2.0 VarioFoerderer":
Id = row["TeileId"].strip()
NachbarIds = row["NachbarIds"].strip()
geraden.append({"Id": Id, "NachbarIds": NachbarIds})
if bezeichner == "ILS 2.0 Kreisel":
Id = row["TeileId"].strip()
planquadrat = row["Planquadrat"]
x, y = extract_coords(planquadrat)
merkmale = parse_merkmale(row.get("Merkmale", ""))
drehung = merkmale.get("Drehrichtung")
rotation = merkmale.get("Drehung")
hight = float(merkmale.get("Höhe in m")) *1000
abstand_m = merkmale.get(
"Abstand (Kreiselachse A - Kreiselachse) in Meter", "20"
).replace(",", ".")
kreisel.append({"Id":Id, "drehung":drehung, "höhe":hight,"x": x, "y": y, "rotation": rotation,"abstand":abstand_m})
for gerade in geraden:
anweisungen = 0
eintrag = {"Id": gerade["Id"]}
for kreis in kreisel:
if kreis["Id"] in gerade["NachbarIds"]:
if anweisungen == 0:
eintrag["Drehung0"] = kreis.get("drehung")
eintrag["Hoehe0"] = kreis.get("höhe")
eintrag["x0"] = kreis.get("x")
eintrag["y0"] = kreis.get("y")
eintrag["rotation0"] = kreis.get("rotation")
eintrag["abstand0"] = kreis.get("abstand")
anweisungen = 1
elif anweisungen == 1:
eintrag["Drehung1"] = kreis.get("drehung")
eintrag["Hoehe1"] = kreis.get("höhe")
eintrag["x1"] = kreis.get("x")
eintrag["y1"] = kreis.get("y")
eintrag["rotation1"] = kreis.get("rotation")
eintrag["abstand1"] = kreis.get("abstand")
break
strecken_nachbarn.append(eintrag)
return strecken_nachbarn
# --------------------------------------------------------- Hauptfunktion
def main(csv_path: Path, lib_path: Path, cfg_path: Path,
output_path: Path, verbose=False, logger=None):
# Bibliothek nur laden, wenn Datei existiert
check_dxflibrary_path(lib_path, verbose, logger)
parser = configparser.ConfigParser()
try:
with open(cfg_path, encoding='utf-8') as f:
parser.read_file(f)
except Exception as e:
msg = f"Fehler beim Lesen der Config-Datei {cfg_path}: {e}"
# Neue Ziel­zeichnung (DXF R2018)
config =parser
doc = ezdxf.new(dxfversion="R2018")
doc.units = units.M
doc.header['$INSUNITS'] = 4 # Millimeter
msp = doc.modelspace()
# Höhe bestimmen für Koordinaten-Transformation
try:
height = berechne_hoehe(csv_path, logger=logger)
except Exception as e:
msg = f"Fehler bei der Höhenberechnung: {e}"
if logger:
logger.error(msg)
else:
print(msg)
sys.exit(1)
blocklib_dir = data_dir / "block_libraries"
lib_docs = dict()
strecken_nachbarn = get_rotations_of_strecken(csv_path)
# gibt zu jeder ShapeId einer Gefällestrecke zurück, ob sich der jeweilige Kreisel im UZ oder GUZ dreht
# rot_of_gf["shape_3ae53a7b-efb8-f66b-eadc-20b99f949ef1"] = ('UZ', 'GUZ')
# Verarbeitung der Blöcke
with csv_path.open(newline="", encoding="utf-8") as fh:
reader = csv.DictReader(fh, delimiter=';')
for row in reader:
bezeichner = row["Bezeichnung"].strip()
teileart = row["TeileArt"].strip()
teileid = row["TeileId"].strip()
planquadrat = row["Planquadrat"]
merkmale = parse_merkmale(row.get("Merkmale", ""))
merkmale["bezeichner"] = bezeichner
try:
x_screen, y_screen = extract_coords(planquadrat)
x, y = transform_coords(x_screen, y_screen, height)
except Exception as e:
msg = f"[WARN] {teileid}: {e}"
if logger:
logger.warning(msg)
else:
print(msg)
continue
# Bibliotheksdatei bestimmen
libfile = get_libfile_cfg(teileart, allgemein_cfg_path)
if libfile:
lib_path = blocklib_dir / libfile
else:
lib_path = default_lib_path
# Bibliothek laden (mit Cache)
lib_doc = None
if lib_path in lib_docs:
lib_doc = lib_docs[lib_path]
elif lib_path.exists():
try:
lib_doc = ezdxf.readfile(lib_path)
lib_docs[lib_path] = lib_doc
if verbose:
print(f"[INFO] Bibliothek geladen: {lib_path}")
except Exception as e:
print(f"[WARN] Fehler beim Lesen der Bibliothek '{lib_path}': {e}")
else:
print(f"[INFO] Keine Bibliothek gefunden unter {lib_path}. Komplexe Formen werden übersprungen.")
# Funktions-Dispatch: handle_<teileart> (mit _ statt Leerzeichen und Punkten, alles klein)
func_name = f'handle_{normalize_func_name(teileart)}'
handler = globals().get(func_name)
symbols = get_shape_cfg(teileart, cfg_path, logger=logger)
# Mapping für Omniflo-Typen
if func_name.startswith('handle_omniflo'):
handler = globals().get('handle_omniflo')
if handler:
handler(msp, teileid, merkmale, x, y, doc, lib_doc, verbose, symbols, strecken_nachbarn, config)
else:
msg = f"[WARN] Keine Routine für TeileArt '{teileart}'. Überspringe '{teileid}'."
if logger:
logger.warning(msg)
else:
print(msg)
continue
# DXF speichern
doc.saveas(output_path)
if logger:
logger.info(f"[DONE] DXF gespeichert unter: {output_path}")
else:
print(f"[DONE] DXF gespeichert unter: {output_path}")
def check_dxflibrary_path(lib_path, verbose, logger):
lib_doc = None
if lib_path.exists():
try:
lib_doc = ezdxf.readfile(lib_path)
if verbose:
logger.info(f"[INFO] Bibliothek geladen: {lib_path}") if logger else print(f"[INFO] Bibliothek geladen: {lib_path}")
except Exception as e:
msg = f"Fehler beim Lesen der Bibliothek '{lib_path}': {e}"
if logger:
logger.error(msg)
else:
print(msg)
sys.exit(1)
else:
msg = f"[INFO] Keine Bibliothek gefunden unter {lib_path}."
if logger:
logger.error(msg)
else:
print(msg)
sys.exit(1)
if __name__ == "__main__":
parser = argparse.ArgumentParser(
description="Plaziert Anlagenkomponenten aus RuleDesigner CSV.")
parser.add_argument("-f", "--file", required=True, help="CSV-Datei (Name oder Pfad)", metavar="input.csv")
parser.add_argument("-c", "--config", help="CFG mit einfachen Formen", metavar="shapes.cfg")
parser.add_argument("-l", "--lib", help="DXF-Bibliothek mit Blöcken", metavar="bibliothek.dxf")
parser.add_argument("-o", "--output", help="Ziel-DXF (Standard: PROJECT_WORK/anlage.dxf)", metavar="anlage.dxf")
parser.add_argument("-v", "--verbose", action="store_true", help="mehr Ausgaben anzeigen")
args = parser.parse_args()
# Verzeichnisse aus Umgebungs­variablen
log_dir = check_environment_var("PROJECT_LOG")
data_dir = check_environment_var("PROJECT_DATA")
work_dir = check_environment_var("PROJECT_WORK")
config_dir = check_environment_var("PROJECT_CFG")
logger = setup_logger(log_dir, name='plant2dxf')
logger.info("=== plant2dxf Verarbeitung gestartet ===")
# CSVPfad: nur Dateiname → im WORKOrdner suchen
if os.sep not in args.file and "/" not in args.file:
csv_path = work_dir / args.file
else:
csv_path = Path(args.file)
cfg_path = Path(args.config) if args.config else config_dir / "shapes.cfg"
allgemein_cfg_path = config_dir / "allgemein.cfg"
default_lib_path = Path(args.lib) if args.lib else data_dir / "blocks.dxf"
output_path = Path(args.output) if args.output else (work_dir / f"{csv_path.stem}.dxf")
main(csv_path, default_lib_path, cfg_path, output_path, verbose=args.verbose, logger=logger)
logger.info("=== plant2dxf Verarbeitung abgeschlossen ===")