def setHoleInterpolatedPoints():
if CTK.t == []: return
CTK.saveTree()
depth = VARS[7].get()
depth = int(depth)
CTK.t = X.setHoleInterpolatedPoints(CTK.t, depth=depth)
CTK.TXT.insert('START', 'cellN variable modified near holes.\n')
CTK.TKTREE.updateApp()
CTK.display(CTK.t)
# - dist2WallsEikonal (pyTree) -
import Converter.PyTree as C
import Connector.PyTree as X
import Converter.Internal as Internal
import Dist2Walls.PyTree as DTW
import Geom.PyTree as D
import Generator.PyTree as G
import numpy
DEPTH = 2
snear = 0.4; vmin = 21
# Init wall
body = D.circle((0,0,0),1.,N=60)
res = G.octree([body],[snear], dfar=5., balancing=1)
res = G.octree2Struct(res, vmin=vmin, ext=DEPTH+1,merged=1)
t = C.newPyTree(['Base']); t[2][1][2] = res
# Mark solid and fluid points
t = X.applyBCOverlaps(t,depth=DEPTH,loc='nodes')
tc = Internal.copyRef(t)
tc = X.setInterpData(t,tc,loc='nodes',storage="inverse")
C._initVars(t,"cellN",1.)
t = X.blankCells(t, [[body]], numpy.array([[1]]), blankingType='node_in')
t = X.setHoleInterpolatedPoints(t,depth=1,loc='nodes')
C._initVars(t,'flag=({cellN}>1.)')
t = DTW.distance2WallsEikonal(t,body,tc=tc,DEPTH=DEPTH,nitmax=10)
C.convertPyTree2File(t, 'out.cgns')
import Initiator.PyTree as I import KCore.test as test import sys a = G.cart((-1, -1, -1), (0.04, 0.04, 1), (51, 51, 3)) s = G.cylinder((0, 0, -1), 0, 0.4, 360, 0, 4, (30, 30, 5)) s = C.convertArray2Tetra(s) s = T.join(s) s = P.exteriorFaces(s) t = C.newPyTree(['Base']) t[2][1][2] = [a] # Blanking bodies = [[s]] BM = N.array([[1]], N.int32) t = X.blankCells(t, bodies, BM, blankingType='center_in') t = X.setHoleInterpolatedPoints(t, depth=-2) # Dist2Walls t = DTW.distance2Walls(t, [s], type='ortho', loc='centers', signed=1) t = C.center2Node(t, 'centers:TurbulentDistance') # Gradient de distance localise en centres => normales t = P.computeGrad(t, 'TurbulentDistance') t = I.initConst(t, MInf=0.2, loc='centers') tc = C.node2Center(t) t = X.setIBCData(t, tc, loc='centers', storage='direct') #test avec arbre tc compact zones = Internal.getNodesFromType2(t, 'Zone_t') X.miseAPlatDonnorTree__(zones, t, procDict=None) t2 = X.setInterpTransfers(t, tc, bcType=0, varType=1) test.testT(t2, 1)
#
# Champ en noeuds non structure PENTA
#
a = G.cartPenta((-2., -1., -1.), (0.1, 0.1, 0.1), (21, 21, 21))
b = T.translate(a, (2, 0, 0))
b[0] = 'cart2'
t = C.newPyTree(['Cart'])
t[2][1][2] += [a, b]
t = C.initVars(t, 'Density', 1.)
t = C.initVars(t, 'cellN', sphere,
['CoordinateX', 'CoordinateY', 'CoordinateZ'])
nod = 1
for d in [-2, -1, 0, 1, 2, 5]:
t2 = X.setHoleInterpolatedPoints(t, depth=d)
test.testT(t2, nod)
nod += 1
# Champ cellN en centres
a = G.cartPenta((-2., -1., -1.), (0.1, 0.1, 0.1), (21, 21, 21))
b = T.translate(a, (2, 0, 0))
b[0] = 'cart2'
t = C.newPyTree(['Cart'])
t[2][1][2] += [a, b]
t = C.initVars(t, 'Density', 1.)
t = C.initVars(t, 'cellN', sphere,
['CoordinateX', 'CoordinateY', 'CoordinateZ'])
t = C.node2Center(t, 'cellN')
t = C.rmVars(t, 'cellN')
for d in [-2, -1, 0, 1, 2, 5]:
else: return 1.
#
# Champ en noeuds non structure HEXA
#
a = G.cartHexa((-2., -1., -1.), (0.1, 0.1, 0.1), (21, 21, 21))
b = T.translate(a, (2, 0, 0))
b[0] = 'cart2'
t = C.newPyTree(['Cart', a, b])
t = C.initVars(t, 'Density', 1.)
t = C.initVars(t, 'cellN', sphere,
['CoordinateX', 'CoordinateY', 'CoordinateZ'])
nod = 1
for d in [-2, -1, 0, 1, 2, 5]:
t2 = X.setHoleInterpolatedPoints(t, depth=d, loc='nodes')
test.testT(t2, nod)
nod += 1
# Champ cellN en centres
a = G.cartHexa((-2., -1., -1.), (0.1, 0.1, 0.1), (21, 21, 21))
b = T.translate(a, (2, 0, 0))
b[0] = 'cart2'
t = C.newPyTree(['Cart', a, b])
t = C.initVars(t, 'Density', 1.)
t = C.initVars(t, 'cellN', sphere,
['CoordinateX', 'CoordinateY', 'CoordinateZ'])
t = C.node2Center(t, 'cellN')
t = C.rmVars(t, 'cellN')
for d in [-2, -1, 0, 1, 2, 5]:
t2 = X.setHoleInterpolatedPoints(t, depth=d, loc='centers')
def transferCellN__(t, tc, DEPTH, loc):
if tc is None: return t
try:
import Connector.PyTree as X
except:
raise ImportError(
"Dist2Walls: Eikonal version requires Connector module.")
# POINTS EXTERIEURS
# Marquage des pts de front entre du 0 et du 1
t = X.setHoleInterpolatedPoints(t, depth=DEPTH, loc=loc)
# transfert du cellN aux raccords
if tc is not None:
C._cpVars(t, loc + ':cellN', tc, 'cellN')
for zc in Internal.getNodesFromType2(tc, "Zone_t"):
if C.getMaxValue(zc, 'cellN') == 2.:
X._setInterpTransfers(t, zc, variables=["cellN"])
if loc == 'nodes':
C._initVars(t, "cellN=({cellN}>1.5)*2.+({cellN}>0.)*({cellN}<1.5)")
C._initVars(t, 'cellN = 1-{cellN}+({cellN}>1.5)*3')
else:
C._initVars(
t,
"centers:cellN=({centers:cellN}>1.5)*2.+({centers:cellN}>0.)*({centers:cellN}<1.5)"
)
C._initVars(
t, 'centers:cellN = 1-{centers:cellN}+({centers:cellN}>1.5)*3')
t = X.setHoleInterpolatedPoints(t, depth=DEPTH, loc=loc)
if loc == 'nodes':
C._initVars(t, 'cellN = 1-{cellN}+({cellN}>1.5)*3')
C._initVars(t, 'cellN2={cellN}')
else:
C._initVars(
t, 'centers:cellN = 1-{centers:cellN}+({centers:cellN}>1.5)*3')
C._initVars(t, 'centers:cellN2={centers:cellN}')
# POINTS INTERIEURS
if loc == 'nodes': C._initVars(t, 'cellN=minimum(1.,{cellN})')
else: C._initVars(t, 'centers:cellN=minimum(1.,{centers:cellN})')
t = X.setHoleInterpolatedPoints(t, depth=-DEPTH, loc=loc)
# transfert du cellN aux raccords
if tc is not None:
C._cpVars(t, loc + ':cellN', tc, 'cellN')
for zc in Internal.getNodesFromType2(tc, "Zone_t"):
if C.getMaxValue(zc, 'cellN') == 2.:
X._setInterpTransfers(t, zc, variables=["cellN"])
if loc == 'nodes':
C._initVars(t, "cellN=({cellN}>1.5)*2.+({cellN}>0.)*({cellN}<1.5)")
C._initVars(t, 'cellN = 1-{cellN}+({cellN}>1.5)*3')
else:
C._initVars(
t,
"centers:cellN=({centers:cellN}>1.5)*2.+({centers:cellN}>0.)*({centers:cellN}<1.5)"
)
C._initVars(
t, 'centers:cellN = 1-{centers:cellN}+({centers:cellN}>1.5)*3')
t = X.setHoleInterpolatedPoints(t, depth=-DEPTH, loc=loc)
if loc == 'nodes':
C._initVars(t, 'cellN = 1-{cellN}+({cellN}>1.5)*3')
C._initVars(t, 'cellN=maximum({cellN},{cellN2})')
C._rmVars(t, ['cellN2'])
else:
C._initVars(
t, 'centers:cellN = 1-{centers:cellN}+({centers:cellN}>1.5)*3')
C._initVars(t,
'centers:cellN=maximum({centers:cellN},{centers:cellN2})')
C._rmVars(t, ['centers:cellN2'])
return t
def sphere(x,y,z):
if x*x+y*y+z*z < 0.5**2 : return 0.
else: return 1.
# Cas structure
# Champ cellN en noeud
a = G.cart((-2.,-1.,-1.),(0.1,0.1,0.1), (21,21,21))
b = T.translate(a,(2,0,0)); b[0] = 'cart2'
t = C.newPyTree(['Cart']); t[2][1][2]+=[a,b]
t = X.connectMatch(t)
t = C.fillEmptyBCWith(t,'nref','BCFarfield')
t = C.initVars(t,'Density',1.)
t = C.initVars(t,'cellN', sphere, ['CoordinateX','CoordinateY','CoordinateZ'])
nod = 1
for d in [-2,-1,0,1,2,5]:
t2 = X.setHoleInterpolatedPoints(t,depth=d,dir=1)
test.testT(t2,nod); nod+=1
#
# Champ en centres
#
a = G.cart((-2.,-1.,-1.),(0.1,0.1,0.1), (21,21,21))
b = T.translate(a,(2,0,0)); b[0] = 'cart2'
t = C.newPyTree(['Cart']); t[2][1][2]+=[a,b]
t = X.connectMatch(t)
t = C.fillEmptyBCWith(t,'nref','BCFarfield')
t = C.initVars(t,'Density',1.)
t = C.initVars(t,'cellN', sphere, ['CoordinateX','CoordinateY','CoordinateZ'])
t = C.node2Center(t,'cellN'); t = C.rmVars(t,'cellN')
for d in [-2,-1,0,1,2,5]:
t2 = X.setHoleInterpolatedPoints(t,depth=d,dir=1)
