def divide_length(self, length_of_segments):
rs.EnableRedraw(False)
points = rs.DivideCurveLength(self.guid,
length_of_segments,
create_points=False,
return_points=True)
points[:] = map(list, points)
rs.EnableRedraw(True)
return points
def getDiv(srf, dist, uv, eq):
domaincrv = rs.ExtractIsoCurve(srf, [0, 0], uv)
crvLen = rs.CurveLength(domaincrv)
newdist = setDist(crvLen, dist, eq)
pts = rs.DivideCurveLength(domaincrv, newdist)
pts.pop(0)
pts.pop(-1)
rs.DeleteObject(domaincrv)
return pts
def find_point_in_curve(self, crv):
offset_points = rs.BoundingBox(crv)
diagonal = rs.AddLine(offset_points[0], offset_points[2])
test_points = rs.DivideCurveLength(diagonal,
POINT_TOL,
create_points=False,
return_points=True)
rs.DeleteObject(diagonal)
for point in test_points:
if rs.PointInPlanarClosedCurve(point, crv):
return point
return self.point
def splitVertical(St, ver_item):
ver_param = rs.DivideCurveLength(ver_item, ipHeight, False, False)
ver_Split = rs.SplitCurve(ver_item, ver_param, True)
ver_line_split = []
for ver_id in range(St, len(ver_Split), 2):
ver_item = ver_Split[ver_id]
ver_line_split.append(ver_item)
#rs.DeleteObject(ver_item)
return ver_line_split
def resample_polyline(self, length):
try:
rs_poly = rs.AddPolyline(self.polyline.points)
if length <= self.polyline.length:
a = rs.DivideCurveLength(rs_poly, length, False)
num_div = len(
rs.DivideCurveLength(rs_poly, length, False, False))
new_pts = rs.DivideCurve(rs_poly, num_div, False, True)
new_rs_poly = rs.AddPolyline(new_pts)
segs = rs.ExplodeCurves(new_rs_poly)
else:
print('it is a line!')
segs = [
rs.AddLine(rs.CurveStartPoint(rs_poly),
rs.CurveEndPoint(rs_poly))
]
print(segs)
out_pts = []
out_vec = []
for seg in segs:
new_pt = rs.CurveMidPoint(seg)
v = rs.VectorCreate(rs.CurveEndPoint(seg),
rs.CurveStartPoint(seg))
new_pt = [new_pt.X, new_pt.Y, new_pt.Z]
new_vec = [v.X, v.Y, v.Z]
new_vec = compas.geometry.normalize_vector(new_vec)
out_pts.append(new_pt)
out_vec.append(new_vec)
# print('succesfully resampled')
return out_pts, out_vec
except Exception:
print('Polyline could not be resampled.')
return None, None
def resample_curve(self, le):
try:
# rs_poly = rs.AddPolyline(self.polyline.points)
crv = rs.AddInterpCurve(self.polyline.points)
if le <= self.polyline.length:
a = rs.DivideCurveLength(crv, le, False)
div = rs.DivideCurveLength(crv, le, False, False)
new_pts = rs.DivideCurve(crv, len(div), False, True)
new_par = rs.DivideCurve(crv, len(div), False, False)
else:
print('it is a line!')
new_pts = [rs.CurveStartPoint(crv), rs.CurveEndPoint(crv)]
new_par = [0.0, rs.CurveLength(crv)]
out_pts = []
out_vec = []
for idx, pt in enumerate(new_pts):
pt = [pt.X, pt.Y, pt.Z]
v = rs.CurveTangent(crv, new_par[idx])
vec = [v.X, v.Y, v.Z]
# vec = compas.geometry.normalize_vector(vec)
out_pts.append(pt)
out_vec.append(vec)
# print('succesfully resampled')
return out_pts, out_vec
except Exception:
print('Interpolated Curve could not be resampled.')
return None, None
def multiLineCurve():
"""
--- --- --- --- --- --- --- --- --- --- ---
-------------------------------------------
--- --- --- --- --- --- --- --- --- --- ---
this script divides a curve by length and adds dashes to either side of the curve, grouped per curve / polyline
limitation: does not accomodate at corners (to avoid ccx issues)
www.studiogijs.nl
"""
curves = rs.GetObjects("select curves to change into multiline-style",4, preselect=True)
if not curves:
return
s=sc.sticky['scale'] if sc.sticky.has_key('scale') else 20
scale = rs.GetReal("scale of the multiline curve", s, 5, 100)
if not scale:
return
sc.sticky['scale']=scale
rs.EnableRedraw(False)
for curve in curves:
lines=[]
if rs.CurveLength(curve)>scale:
pts = rs.DivideCurveLength(curve, scale)
for pt in pts:
t=rs.CurveClosestPoint(curve, pt)
vec = rs.CurveTangent(curve, t)*scale/5
line = rs.AddLine(pt-vec, pt+vec)
trans = rs.VectorRotate(vec, 90, [0,0,1])
trans/=2
line_copy = rs.CopyObject(line, trans)
trans = -trans
lines.append(line_copy)
rs.MoveObject(line, trans)
lines.append(line)
group = rs.AddGroup()
rs.AddObjectsToGroup(lines, group)
rs.AddObjectsToGroup(curve, group)
rs.SelectObjects(lines)
rs.SelectObjects(curves)
rs.EnableRedraw(True)
def fenceCurve():
"""
---x---x---x---x---x---x---
this script divides a curve by length and adds 'crosses' to it, grouped per curve / polyline
www.studiogijs.nl
"""
curves = rs.GetObjects("select curves to change into fence-style",
4,
preselect=True)
if not curves:
return
s = sc.sticky['scale'] if sc.sticky.has_key('scale') else 20
scale = rs.GetReal("scale of the arrow curve", s, 5, 100)
if not scale:
return
sc.sticky['scale'] = scale
rs.EnableRedraw(False)
for curve in curves:
lines = []
if rs.CurveLength(curve) > scale:
pts = rs.DivideCurveLength(curve, scale)
for pt in pts:
t = rs.CurveClosestPoint(curve, pt)
vec = rs.CurveTangent(curve, t)
line = rs.AddLine(pt - vec * scale / 10, pt + vec * scale / 10)
rs.RotateObject(line, pt, 45)
lines.append(line)
line_copy = rs.RotateObject(line, pt, 90, copy=True)
lines.append(line_copy)
group = rs.AddGroup()
rs.AddObjectsToGroup(lines, group)
rs.AddObjectsToGroup(curve, group)
rs.SelectObjects(lines)
rs.SelectObjects(curves)
rs.EnableRedraw(True)
import math
import rhinoscriptsyntax as rs
import ghpythonlib.components as ghc
import Rhino.Geometry as rg
icurvesn = []
icurvesm = []
ipointssnm = []
ipointssmn = []
curve01 = curves[0]
curve12 = curves[1]
curve23 = curves[2]
curve30 = curves[3]
points01 = rs.DivideCurveLength(curve01, length)
points12 = rs.DivideCurveLength(curve12, length)
points23 = rs.DivideCurveLength(curve23, length)
points30 = rs.DivideCurveLength(curve30, length)
m = (len(points12) + len(points30)) / 2
n = (len(points01) + len(points23)) / 2
points01 = rs.DivideCurve(curve01, n + 1)
points12 = rs.DivideCurve(curve12, m + 1)
points23 = rs.DivideCurve(curve23, n + 1)
points30 = rs.DivideCurve(curve30, m + 1)
m = int(m)
n = int(n)
bpoints = points01 + points12 + points23 + points30
for i in range(n):
icurve = rs.ShortPath(surface, points01[i + 1], points23[-(i + 2)])
icurvesn.append(icurve)
count = 0
while (count < loop):
def _get_base_points(self, curve_id):
base_points = rs.DivideCurveLength(curve_id,
self.spacing,
create_points=False,
return_points=True)
return base_points
import rhinoscriptsyntax as rs
fp = "gcode_out.txt"
inCrv = rs.GetObjects("Select curves to draw")
subD = rs.GetReal("Input segment length", number=1.0)
with open(fp, mode='w') as outfile:
if len(inCrv) >= 1:
for crv in inCrv:
pts = rs.DivideCurveLength(crv, subD)
for i, pt in enumerate(pts):
if i == 0:
#raise pen
outfile.write("M03 S0 \n")
#go to first position
outfile.write("G00 X%.3f Y%.3f \n" %(pt.X,pt.Z) )
#drop pen
outfile.write("M03 S1024 \n")
continue
#go to next position (with pen down)
outfile.write("G00 X%.3f Y%.3f \n" %(pt.X,pt.Z) )
#lift pen
outfile.write("M03 S0 \n")
outfile.write("G00 X0 Y0 \n")
outfile.close()
def basicpoints(bplines, lengthunit):
#
basicplanepoints = [] #等分点
for u in range(len(bplines)):
basicplanepoint = rs.DivideCurveLength(bplines[u], lengthunit, True,
True)
basicplanepoints.append(basicplanepoint)
planeunit = 1
randomselectionp = [] #随机提取的点
pupoints = []
for o in range(len(basicplanepoints) - 1): #循环等分点母列表
for p in range(len(basicplanepoints[0])): #循环子列表
basicplanepointscor = [
basicplanepoints[o][p][0], basicplanepoints[o][p][1],
basicplanepoints[o][p][2]
]
pupoints.append(basicplanepointscor) #提取一条线的各个点坐标
#每组9个点,已有一个原点
pupoint1 = [
basicplanepointscor[0] + planeunit, basicplanepointscor[1],
basicplanepointscor[2]
]
pupoints.append(pupoint1) #第1个点
rs.Addpoint(pupoint1)
pupoint2 = [
basicplanepointscor[0] + planeunit,
basicplanepointscor[1] + planeunit, basicplanepointscor[2]
]
pupoints.append(pupoint2) #第2个点
rs.Addpoint(pupoint2)
pupoint3 = [
basicplanepointscor[0], basicplanepointscor[1] + planeunit,
basicplanepointscor[2]
]
pupoints.append(pupoint3) #第3个点
rs.Addpoint(pupoint3)
pupoint4 = [
basicplanepointscor[0] - planeunit,
basicplanepointscor[1] + planeunit, basicplanepointscor[2]
]
pupoints.append(pupoint4) #第4个点
rs.Addpoint(pupoint4)
pupoint5 = [
basicplanepointscor[0] - planeunit, basicplanepointscor[1],
basicplanepointscor[2]
]
pupoints.append(pupoint5) #第5个点
rs.Addpoint(pupoint5)
pupoint6 = [
basicplanepointscor[0] - planeunit,
basicplanepointscor[1] - planeunit, basicplanepointscor[2]
]
pupoints.append(pupoint6) #第6个点
rs.Addpoint(pupoint6)
pupoint7 = [
basicplanepointscor[0], basicplanepointscor[1] - planeunit,
basicplanepointscor[2]
]
pupoints.append(pupoint7) #第7个点
rs.Addpoint(pupoint7)
pupoint8 = [
basicplanepointscor[0] + planeunit,
basicplanepointscor[1] - planeunit, basicplanepointscor[2]
]
pupoints.append(pupoint8) #第8个点
rs.Addpoint(pupoint8)
randomselectionp.append(random.choice(pupoints))
pupoints = []
pupoints0 = randomselectionp[:]
elif rs.ObjectLayer(curve)=="5":
curvesByLayers[4].append(curve)
elif rs.ObjectLayer(curve)=="6":
curvesByLayers[5].append(curve)
print len(curvesByLayers[0])
for idx, pencurves in enumerate(curvesByLayers):
if not pencurves: continue
pen = idx + 1
hpglOut.write('SP'+str(pen)+';\n')
for curve in pencurves:
if rs.CurveDegree (curve) == 1: #polyline or line
points=rs.CurveEditPoints(curve) #works for polyline or line
#print 'line'
elif rs.CurveDegree (curve) == 2 or rs.CurveDegree (curve) == 3: #curvy curve
points = rs.DivideCurveLength(curve, .025)
print 'curvy'
if not points:
#print 'found one very tiny curve, which is not exported'
continue #means skip this iteration of the loop and go right to the next curve
#pen up to the first point on line
x = points[0][0]
y = points[0][1]
hpglOut.write('PU'+str(int(x*1000))+','+str(int(y*1000))+';\n')
#pen down to every subsequent point
i=1
while i<len(points):
x = points[i][0]
y = points[i][1]
hpglOut.write('PD'+str(int(x*1000))+','+str(int(y*1000))+';\n')
i=i+1
import rhinoscriptsyntax as rs
import random
point = rs.GetPoint()
for i in range(0, 10):
a = random.randint(0, 10)
b = random.randint(0, 10)
c = 0
StartPoint = (a, b, c)
NewVecEnd = (point)
NewVecStart = (0, 0, 0)
origin = StartPoint
r = random.randint(0, 255)
b = random.randint(0, 255)
g = random.randint(0, 255)
color = [r, g, b]
vector = rs.VectorCreate(NewVecEnd, NewVecStart)
line = rs.AddLine(StartPoint, vector)
#line = rs.ScaleObject(line, origin, (0.5,0.5,0.5))
rs.ObjectColor(line, color)
segments = rs.DivideCurveLength(line, 9)
rs.AddLine(StartPoint, segments[1])
print(segments[0])
import rhinoscriptsyntax as rs
fp = "gcode_out.txt"
inCrv = rs.GetObject("Select curve to draw")
subD = rs.GetReal("Input segment length", number=1.0)
pts = rs.DivideCurveLength(inCrv, subD)
with open(fp, mode='w') as outfile:
for i, pt in enumerate(pts):
if i == 0:
#raise pen
outfile.write("M03 S0 \n")
#go to first position
outfile.write("G00 X%.3f Y%.3f \n" % (pt.X, pt.Y))
#drop pen
outfile.write("M03 S1024 \n")
continue
#go to next position (with pen down)
outfile.write("G00 X%.3f Y%.3f \n" % (pt.X, pt.Y))
#lift pen
outfile.write("M03 S0 \n")
outfile.write("G00 X0 Y0 \n")
outfile.close()
