def translate2zero():
ss=cubit.parse_cubit_list('surface','all')
box = cubit.get_total_bounding_box("surface", ss)
xmin=box[0]
ymin=box[3]
cubit.cmd('move surface all x '+str(-1*xmin)+' y '+str(-1*ymin))
return xmin,ymin
def translate2zero():
ss=cubit.parse_cubit_list('surface','all')
box = cubit.get_total_bounding_box("surface", ss)
xmin=box[0]
ymin=box[3]
cubit.cmd('move surface all x '+str(-1*xmin)+' y '+str(-1*ymin))
return xmin,ymin
def define_4side_lateral_surfaces(tres=0.0003, tol=0.000001):
list_vol = cubit.parse_cubit_list("volume", "all")
surf_xmin = []
surf_ymin = []
surf_xmax = []
surf_ymax = []
# min/max of bounding box
xmin_box = cubit.get_total_bounding_box("volume", list_vol)[0]
xmax_box = cubit.get_total_bounding_box("volume", list_vol)[1]
ymin_box = cubit.get_total_bounding_box("volume", list_vol)[3]
ymax_box = cubit.get_total_bounding_box("volume", list_vol)[4]
zmin_box = cubit.get_total_bounding_box("volume", list_vol)[6]
zmax_box = cubit.get_total_bounding_box("volume", list_vol)[7]
#print('absorbing boundary xmin:' + str(xmin_box) + ' xmax: ' + str(xmax_box))
#print('absorbing boundary ymin:' + str(ymin_box) + ' ymax: ' + str(ymax_box))
#print('absorbing boundary zmin:' + str(zmin_box) + ' zmax: ' + str(zmax_box))
for id_vol in list_vol:
surf_vertical = []
xsurf = []
ysurf = []
lsurf = cubit.get_relatives("volume", id_vol, "surface")
for k in lsurf:
normal = cubit.get_surface_normal(k)
# checks if normal is horizontal (almost 0, i.e., +/- tres)
if normal[2] >= -1 * tres and normal[2] <= tres:
# checks if surface is on minimum/maximum side of the whole model
center_point = cubit.get_center_point("surface", k)
# note: for models with smaller volumes inscribed, we want only the outermost surfaces
# as absorbing ones
#sbox = cubit.get_bounding_box('surface', k)
# xmin of surface box relative to total box xmin
if (abs(center_point[0] - xmin_box) / abs(xmax_box - xmin_box) <= tol) or \
(abs(center_point[0] - xmax_box) / abs(xmax_box - xmin_box) <= tol) or \
(abs(center_point[1] - ymin_box) / abs(ymax_box - ymin_box) <= tol) or \
(abs(center_point[1] - ymax_box) / abs(ymax_box - ymin_box) <= tol):
# adds as vertical surface
surf_vertical.append(k)
xsurf.append(center_point[0])
ysurf.append(center_point[1])
# adds surfaces when on boundary
if len(surf_vertical) > 0:
surf_xmin.append(surf_vertical[xsurf.index(min(xsurf))])
surf_ymin.append(surf_vertical[ysurf.index(min(ysurf))])
surf_xmax.append(surf_vertical[xsurf.index(max(xsurf))])
surf_ymax.append(surf_vertical[ysurf.index(max(ysurf))])
#debug
#print('define_4side_lateral_surfaces: xmin ',surf_xmin)
#print('define_4side_lateral_surfaces: xmax ',surf_xmax)
#print('define_4side_lateral_surfaces: ymin ',surf_ymin)
#print('define_4side_lateral_surfaces: ymax ',surf_ymax)
return surf_xmin, surf_ymin, surf_xmax, surf_ymax
import pickle
cubit.init(['test', '-nojournal'])
cubit.cmd('reset')
cubit.cmd('create brick x 4000 y 4000 z 645')
cubit.cmd('move volume all x 0 y 0 z +222.5')
cubit.cmd('webcut body all with general plane xy move x 0 y 0 z 0')
cubit.cmd('webcut body all with general plane xy move x 0 y 0 z 27')
cubit.cmd('webcut body all with general plane xy move x 0 y 0 z -7')
cubit.cmd('webcut body all with general plane yz move x -500 y 0 z 0')
cubit.cmd('webcut body all with general plane yz move x +500 y 0 z 0')
cubit.cmd('webcut body all with general plane xz move x 0 y -500 z 0')
cubit.cmd('webcut body all with general plane xz move x 0 y +500 z 0')
xmin = cubit.get_total_bounding_box('volume', cubit.get_entities('volume'))[0]
xmax = cubit.get_total_bounding_box('volume', cubit.get_entities('volume'))[1]
ymin = cubit.get_total_bounding_box('volume', cubit.get_entities('volume'))[3]
ymax = cubit.get_total_bounding_box('volume', cubit.get_entities('volume'))[4]
zmin = cubit.get_total_bounding_box('volume', cubit.get_entities('volume'))[6]
zmax = cubit.get_total_bounding_box('volume', cubit.get_entities('volume'))[7]
cubit.cmd('webcut volume all with cylinder radius 20.0 axis z center 0,0,0')
cubit.cmd('webcut volume all with cylinder radius 2.0 axis z center 0,0,0')
cubit.cmd('webcut volume all with cylinder radius 1.8 axis z center 0,0,0')
for icurve in cubit.get_entities('curve'):
l = cubit.get_curve_length(icurve)
r1 = 2 * math.pi * 1.8
r2 = 2 * math.pi * 2.0
r3 = 2 * math.pi * 20.0
def define_surf(ip=0,
cpuxmin=0,
cpuxmax=1,
cpuymin=0,
cpuymax=1,
cpux=1,
cpuy=1):
"""
define the absorbing surfaces for a layered topological box where boundary are surfaces parallel to the axis.
it returns absorbing_surf,absorbing_surf_xmin,absorbing_surf_xmax,absorbing_surf_ymin,absorbing_surf_ymax,absorbing_surf_bottom,topo_surf
where
absorbing_surf is the list of all the absorbing boundary surf
absorbing_surf_xmin is the list of the absorbing boundary surfaces that correnspond to x=xmin
...
absorbing_surf_bottom is the list of the absorbing boundary surfaces that correspond to z=zmin
"""
from utilities import get_v_h_list
#
from sets import Set
def product(*args, **kwds):
# product('ABCD', 'xy') --> Ax Ay Bx By Cx Cy Dx Dy
# product(range(2), repeat=3) --> 000 001 010 011 100 101 110 111
# for compatibility with python2.5
pools = map(tuple, args) * kwds.get('repeat', 1)
result = [[]]
for pool in pools:
result = [x + [y] for x in result for y in pool]
return result
absorbing_surf = []
xmin = []
xmax = []
ymin = []
ymax = []
#
top_surf = []
bottom_surf = []
list_vol = cubit.parse_cubit_list("volume", "all")
zmax_box = cubit.get_total_bounding_box("volume", list_vol)[7]
zmin_box = cubit.get_total_bounding_box(
"volume", list_vol
)[6] #it is the z_min of the box ... box= xmin,xmax,d,ymin,ymax,d,zmin...
xmin_box = cubit.get_total_bounding_box("volume", list_vol)[0]
xmax_box = cubit.get_total_bounding_box("volume", list_vol)[1]
ymin_box = cubit.get_total_bounding_box("volume", list_vol)[3]
ymax_box = cubit.get_total_bounding_box("volume", list_vol)[4]
list_surf = cubit.parse_cubit_list("surface", "all")
absorbing_surface_distance_tolerance = 0.001
topographic_surface_distance_tolerance = 0.1
topographic_surface_normal_tolerance = 0.4
lv = []
for k in list_surf:
sbox = cubit.get_bounding_box('surface', k)
if zmax_box == 0 and sbox[7] == 0:
dzmax = 0
elif zmax_box == 0 or sbox[7] == 0:
dzmax = abs(sbox[7] - zmax_box)
else:
dzmax = abs(sbox[7] - zmax_box) / max(abs(sbox[7]), abs(zmax_box))
if zmin_box == 0 and sbox[6] == 0:
dzmin = 0
elif zmin_box == 0 or sbox[6] == 0:
dzmin = abs(sbox[6] - zmin_box)
else:
dzmin = abs(sbox[6] - zmin_box) / max(abs(sbox[6]), abs(zmin_box))
normal = cubit.get_surface_normal(k)
zn = normal[2]
if dzmax <= topographic_surface_distance_tolerance and zn > topographic_surface_normal_tolerance:
top_surf.append(k)
list_vertex = cubit.get_relatives('surface', k, 'vertex')
for v in list_vertex:
valence = cubit.get_valence(v)
if valence <= 4: #valence 3 is a corner, 4 is a vertex between 2 volumes, > 4 is a vertex not in the boundaries
lv.append(v)
elif dzmin <= 0.001 and zn < -1 + topographic_surface_normal_tolerance:
bottom_surf.append(k)
if len(top_surf) == 0: #assuming that one topo surface need to be selected
_, _, _, _, _, top_surf = get_v_h_list(list_vol, chktop=False)
lp = []
labelp = []
combs = product(lv, lv)
for comb in combs:
v1 = comb[0]
v2 = comb[1]
c = Set(cubit.get_relatives("vertex", v1, "curve")) & Set(
cubit.get_relatives("vertex", v2, "curve"))
if len(c) == 1:
p = cubit.get_center_point("curve", list(c)[0])
labelp.append(list(c)[0])
labelps = Set(labelp)
for c in labelps:
p = cubit.get_center_point("curve", c)
lp.append(p)
for k in list_surf:
center_point = cubit.get_center_point("surface", k)
for p in lp:
try:
if abs((center_point[0] - p[0]) /
p[0]) <= absorbing_surface_distance_tolerance and abs(
(center_point[1] - p[1]) /
p[1]) <= absorbing_surface_distance_tolerance:
absorbing_surf.append(k)
break
except:
if -1 <= center_point[0] <= 1 and -1 <= center_point[1] <= 1:
absorbing_surf.append(k)
break
#
four_side = True
if four_side:
xmintmp, ymintmp, xmaxtmp, ymaxtmp = define_4side_lateral_surfaces()
xmin = list(Set(xmintmp) - Set(xmaxtmp))
xmax = list(Set(xmaxtmp) - Set(xmintmp))
ymin = list(Set(ymintmp) - Set(ymaxtmp))
ymax = list(Set(ymaxtmp) - Set(ymintmp))
abs_xmintmp, abs_xmaxtmp, abs_ymintmp, abs_ymaxtmp = lateral_boundary_are_absorbing(
ip, cpuxmin, cpuxmax, cpuymin, cpuymax, cpux, cpuy)
abs_xmin = list(Set(abs_xmintmp) - Set(abs_xmaxtmp))
abs_xmax = list(Set(abs_xmaxtmp) - Set(abs_xmintmp))
abs_ymin = list(Set(abs_ymintmp) - Set(abs_ymaxtmp))
abs_ymax = list(Set(abs_ymaxtmp) - Set(abs_ymintmp))
return absorbing_surf, abs_xmin, abs_xmax, abs_ymin, abs_ymax, top_surf, bottom_surf, xmin, ymin, xmax, ymax
def define_absorbing_surf():
"""
define the absorbing surfaces for a layered topological box where boundary are surfaces parallel to the axis.
it returns absorbing_surf,absorbing_surf_xmin,absorbing_surf_xmax,absorbing_surf_ymin,absorbing_surf_ymax,absorbing_surf_bottom,topo_surf
where
absorbing_surf is the list of all the absorbing boundary surf
absorbing_surf_xmin is the list of the absorbing boundary surfaces that correnspond to x=xmin
...
absorbing_surf_bottom is the list of the absorbing boundary surfaces that correspond to z=zmin
"""
try:
cubit.cmd('comment')
except:
try:
import cubit
cubit.init([""])
except:
print 'error importing cubit'
import sys
sys.exit()
absorbing_surf=[]
absorbing_surf_xmin=[]
absorbing_surf_xmax=[]
absorbing_surf_ymin=[]
absorbing_surf_ymax=[]
absorbing_surf_bottom=[]
top_surf=[]
list_vol=cubit.parse_cubit_list("volume","all")
init_n_vol=len(list_vol)
zmax_box=cubit.get_total_bounding_box("volume",list_vol)[7]
zmin_box=cubit.get_total_bounding_box("volume",list_vol)[6] #it is the z_min of the box ... box= xmin,xmax,d,ymin,ymax,d,zmin...
xmin_box=cubit.get_total_bounding_box("volume",list_vol)[0]
xmax_box=cubit.get_total_bounding_box("volume",list_vol)[1]
ymin_box=cubit.get_total_bounding_box("volume",list_vol)[3]
ymax_box=cubit.get_total_bounding_box("volume",list_vol)[4]
list_surf=cubit.parse_cubit_list("surface","all")
# for k in list_surf:
# center_point = cubit.get_center_point("surface", k)
# if abs((center_point[0] - xmin_box)/xmin_box) <= 0.005:
# absorbing_surf_xmin.append(k)
# absorbing_surf.append(k)
# elif abs((center_point[0] - xmax_box)/xmax_box) <= 0.005:
# absorbing_surf_xmax.append(k)
# absorbing_surf.append(k)
# elif abs((center_point[1] - ymin_box)/ymin_box) <= 0.005:
# absorbing_surf_ymin.append(k)
# absorbing_surf.append(k)
# elif abs((center_point[1] - ymax_box)/ymax_box) <= 0.005:
# absorbing_surf_ymax.append(k)
# absorbing_surf.append(k)
# elif abs((center_point[2] - zmin_box)/zmin_box) <= 0.005:
# absorbing_surf_bottom.append(k)
# absorbing_surf.append(k)
# else:
# sbox=cubit.get_bounding_box('surface',k)
# dz=abs((sbox[7] - zmax_box)/zmax_box)
# normal=cubit.get_surface_normal(k)
# zn=normal[2]
# dn=abs(zn-1)
# if dz <= 0.001 and dn < 0.2:
# top_surf.append(k)
#box lengths
x_len = abs( xmax_box - xmin_box)
y_len = abs( ymax_box - ymin_box)
z_len = abs( zmax_box - zmin_box)
print '##boundary box: '
print '## x length: ' + str(x_len)
print '## y length: ' + str(y_len)
print '## z length: ' + str(z_len)
# tolerance parameters
absorbing_surface_distance_tolerance=0.005
topographic_surface_distance_tolerance=0.001
topographic_surface_normal_tolerance=0.2
for k in list_surf:
center_point = cubit.get_center_point("surface", k)
if abs((center_point[0] - xmin_box)/x_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_xmin.append(k)
absorbing_surf.append(k)
elif abs((center_point[0] - xmax_box)/x_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_xmax.append(k)
absorbing_surf.append(k)
elif abs((center_point[1] - ymin_box)/y_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_ymin.append(k)
absorbing_surf.append(k)
elif abs((center_point[1] - ymax_box)/y_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_ymax.append(k)
absorbing_surf.append(k)
elif abs((center_point[2] - zmin_box)/z_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_bottom.append(k)
absorbing_surf.append(k)
else:
sbox=cubit.get_bounding_box('surface',k)
dz=abs((sbox[7] - zmax_box)/z_len)
normal=cubit.get_surface_normal(k)
zn=normal[2]
dn=abs(zn-1)
if dz <= topographic_surface_distance_tolerance and dn < topographic_surface_normal_tolerance:
top_surf.append(k)
return absorbing_surf,absorbing_surf_xmin,absorbing_surf_xmax,absorbing_surf_ymin,absorbing_surf_ymax,absorbing_surf_bottom,top_surf
def define_absorbing_surf_nopar():
"""
define the absorbing surfaces for a layered topological box where boundary surfaces are not parallel to the axis.
it returns absorbing_surf,topo_surf
where
absorbing_surf is the list of all the absorbing boundary surf
"""
try:
cubit.cmd('comment')
except:
try:
import cubit
cubit.init([""])
except:
print 'error importing cubit'
import sys
sys.exit()
from sets import Set
def product(*args, **kwds):
# product('ABCD', 'xy') --> Ax Ay Bx By Cx Cy Dx Dy
# product(range(2), repeat=3) --> 000 001 010 011 100 101 110 111
pools = map(tuple, args) * kwds.get('repeat', 1)
result = [[]]
for pool in pools:
result = [x+[y] for x in result for y in pool]
return result
absorbing_surf=[]
absorbing_surf_xmin=[]
absorbing_surf_xmax=[]
absorbing_surf_ymin=[]
absorbing_surf_ymax=[]
absorbing_surf_bottom=[]
top_surf=[]
list_vol=cubit.parse_cubit_list("volume","all")
init_n_vol=len(list_vol)
zmax_box=cubit.get_total_bounding_box("volume",list_vol)[7]
zmin_box=cubit.get_total_bounding_box("volume",list_vol)[6] #it is the z_min of the box ... box= xmin,xmax,d,ymin,ymax,d,zmin...
xmin_box=cubit.get_total_bounding_box("volume",list_vol)[0]
xmax_box=cubit.get_total_bounding_box("volume",list_vol)[1]
ymin_box=cubit.get_total_bounding_box("volume",list_vol)[3]
ymax_box=cubit.get_total_bounding_box("volume",list_vol)[4]
list_surf=cubit.parse_cubit_list("surface","all")
lv=[]
for k in list_surf:
sbox=cubit.get_bounding_box('surface',k)
dzmax=abs((sbox[7] - zmax_box)/zmax_box)
dzmin=abs((sbox[6] - zmin_box)/zmin_box)
normal=cubit.get_surface_normal(k)
zn=normal[2]
if dzmax <= 0.001 and zn > 0.7:
top_surf.append(k)
list_vertex=cubit.get_relatives('surface',k,'vertex')
for v in list_vertex:
valence=cubit.get_valence(v)
if valence <= 4: #valence 3 is a corner, 4 is a vertex between 2 volumes, > 4 is a vertex not in the boundaries
lv.append(v)
elif dzmin <= 0.001 and zn < -0.7:
absorbing_surf.append(k)
lp=[]
combs=product(lv,lv)
for comb in combs:
v1=comb[0]
v2=comb[1]
c=Set(cubit.get_relatives("vertex",v1,"curve")) & Set(cubit.get_relatives("vertex",v2,"curve"))
if len(c) == 1:
p=cubit.get_center_point("curve",list(c)[0])
lp.append(p)
for k in list_surf:
center_point = cubit.get_center_point("surface", k)
for p in lp:
if abs((center_point[0] - p[0])/p[0]) <= 0.005 and abs((center_point[1] - p[1])/p[1]) <= 0.005:
absorbing_surf.append(k)
break
return absorbing_surf,top_surf
def layercake_volume_fromacis_mpiregularmap(filename=None):
import sys
import start as start
#
mpiflag,iproc,numproc,mpi = start.start_mpi()
#
cfg = start.start_cfg(filename=filename)
#
from utilities import geo2utm, savegeometry
#
from math import sqrt
#
try:
mpi.barrier()
except:
pass
#
#
command = "comment '"+"PROC: "+str(iproc)+"/"+str(numproc)+" '"
cubit.cmd(command)
#
#get the limit of the volume considering the cpu
def xwebcut(x):
command='create planar surface with plane xplane offset '+str(x)
cubit.cmd(command)
last_surface=cubit.get_last_id("surface")
command="webcut volume all tool volume in surf "+str(last_surface)
cubit.cmd(command)
command="del surf "+str(last_surface)
cubit.cmd(command)
def ywebcut(x):
command='create planar surface with plane yplane offset '+str(x)
cubit.cmd(command)
last_surface=cubit.get_last_id("surface")
command="webcut volume all tool volume in surf "+str(last_surface)
cubit.cmd(command)
command="del surf "+str(last_surface)
cubit.cmd(command)
def translate2zero():
ss=cubit.parse_cubit_list('surface','all')
box = cubit.get_total_bounding_box("surface", ss)
xmin=box[0]
ymin=box[3]
cubit.cmd('move surface all x '+str(-1*xmin)+' y '+str(-1*ymin))
return xmin,ymin
def translate2original(xmin,ymin):
cubit.cmd('move surface all x '+str(xmin)+' y '+str(ymin))
if mpiflag:
icpux = iproc % cfg.nproc_xi
icpuy = int(iproc / cfg.nproc_xi)
else:
icpuy=int(cfg.id_proc/cfg.nproc_xi)
icpux=cfg.id_proc%cfg.nproc_xi
#
ner=cubit.get_error_count()
#
icurve=0
isurf=0
ivertex=0
#
xlength=(cfg.xmax-cfg.xmin)/float(cfg.cpux) #length of x slide for chunk
ylength=(cfg.ymax-cfg.ymin)/float(cfg.cpuy) #length of y slide for chunk
xmin_cpu=cfg.xmin+(xlength*(icpux))
ymin_cpu=cfg.ymin+(ylength*(icpuy))
xmax_cpu=xmin_cpu+xlength
ymax_cpu=ymin_cpu+ylength
#
#importing the surfaces
for inz in range(cfg.nz-2,-2,-1):
if cfg.bottomflat and inz==-1:
command = "create planar surface with plane zplane offset "+str(cfg.depth_bottom)
cubit.cmd(command)
else:
command = "import cubit '"+cfg.filename[inz]+"'"
cubit.cmd(command)
#translate
xmin,ymin=translate2zero()
print 'translate ...', -xmin,-ymin
xmin_cpu=xmin_cpu-xmin
ymin_cpu=ymin_cpu-ymin
xmax_cpu=xmax_cpu-xmin
ymax_cpu=ymax_cpu-ymin
ss=cubit.parse_cubit_list('surface','all')
box = cubit.get_total_bounding_box("surface", ss)
print 'dimension... ', box
#cutting the surfaces
xwebcut(xmin_cpu)
xwebcut(xmax_cpu)
ywebcut(ymin_cpu)
ywebcut(ymax_cpu)
#
list_surface_all=cubit.parse_cubit_list("surface","all")
#condisidering only the surfaces inside the boundaries
dict_surf={}
for isurf in list_surface_all:
p=cubit.get_center_point("surface",isurf)
if p[0] < xmin_cpu or p[0] > xmax_cpu or p[1] > ymax_cpu or p[1] < ymin_cpu:
command = "del surf "+str(isurf)
cubit.cmd(command)
else:
dict_surf[str(isurf)]=p[2]
z=dict_surf.values()
z.sort()
list_surf=[]
for val in z:
isurf=[k for k, v in dict_surf.iteritems() if v == val][0]
list_surf.append(int(isurf))
#
#lofting the volume
for i,j in zip(list_surf,list_surf[1:]):
ner=cubit.get_error_count()
create_volume(i,j,method=cfg.volumecreation_method)
#cubitcommand= 'create volume loft surface '+ str(i)+' '+str(j)
#cubit.cmd(cubitcommand)
ner2=cubit.get_error_count()
#
translate2original(xmin,ymin)
if ner == ner2:
cubitcommand= 'del surface all'
cubit.cmd(cubitcommand)
#
#
#cubitcommand= 'composite create curve in vol all'
#cubit.cmd(cubitcommand)
list_vol=cubit.parse_cubit_list("volume","all")
if len(list_vol) > 1:
cubitcommand= 'imprint volume all'
cubit.cmd(cubitcommand)
#cubit_error_stop(iproc,cubitcommand,ner)
#
cubitcommand= 'merge all'
cubit.cmd(cubitcommand)
#
savegeometry(iproc,filename=filename)
def mesh_layercake_regularmap(filename=None):
import sys,os
import start as start
mpiflag,iproc,numproc,mpi = start.start_mpi()
from utilities import importgeometry,savemesh,get_v_h_list,cubit_command_check
#
numpy = start.start_numpy()
cfg = start.start_cfg(filename=filename)
from math import sqrt
from sets import Set
#
class cubitvolume:
def __init__(self,ID,intervalv,centerpoint,dimension):
self.ID=ID
self.intervalv=intervalv
self.centerpoint=centerpoint
self.dim=dimension
def __repr__(self):
msg="(vol:%3i, vertical interval: %4i, centerpoint: %8.2f)" % (self.ID, self.intervalv,self.centerpoint)
return msg
#
def by_z(x,y):
return cmp(x.centerpoint,y.centerpoint)
#
#
#
list_vol=cubit.parse_cubit_list("volume","all")
if len(list_vol) != 0:
pass
else:
geometryfile='geometry_vol_'+str(iproc)+'.cub'
importgeometry(geometryfile,iproc=iproc)
#
command = 'composite create curve all'
cubit.cmd(command)
print '###"No valid composites can be created from the specified curves." is NOT a critical ERROR.'
#
command = "compress all"
cubit.cmd(command)
list_vol=cubit.parse_cubit_list("volume","all")
nvol=len(list_vol)
vol=[]
for id_vol in list_vol:
p=cubit.get_center_point("volume",id_vol)
vol.append(cubitvolume(id_vol,1,p[2],0))
vol.sort(by_z)
#
for id_vol in range(0,nvol):
vol[id_vol].intervalv=cfg.iv_interval[id_vol]
#
#
surf_vertical=[]
surf_or=[]
top_surface=0
top_surface_add=''
bottom_surface=0
#
zmin_box=cubit.get_total_bounding_box("volume",list_vol)[6]
xmin_box=cubit.get_total_bounding_box("volume",list_vol)[0]
xmax_box=cubit.get_total_bounding_box("volume",list_vol)[1]
ymin_box=cubit.get_total_bounding_box("volume",list_vol)[3]
ymax_box=cubit.get_total_bounding_box("volume",list_vol)[4]
#
#
#interval assignement
surf_or,surf_vertical,list_curve_or,list_curve_vertical,bottom,top = get_v_h_list(list_vol,chktop=cfg.chktop)
print 'vertical surfaces: ',surf_vertical
for k in surf_vertical:
command = "surface "+str(k)+" scheme submap"
cubit.cmd(command)
for k in surf_or:
command = "surface "+str(k)+" scheme "+cfg.or_mesh_scheme
cubit.cmd(command)
#
ucurve,vcurve=get_uv_curve(list_curve_or)
schemepave=False
#
ucurve_interval={}
for k in ucurve:
length=cubit.get_curve_length(k)
interval=int(2*round(.5*length/cfg.size,0))
ucurve_interval[k]=interval
command = "curve "+str(k)+" interval "+str(interval)
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
command = "curve "+str(k)+" scheme equal"
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
if max(ucurve_interval.values()) != min(ucurve_interval.values()):
schemepave=True
print 'mesh scheme is set to pave'
for sk in surf_or:
command = "surface "+str(sk)+" scheme pave"
cubit.cmd(command)
#
vcurve_interval={}
for k in vcurve:
length=cubit.get_curve_length(k)
interval=int(2*round(.5*length/cfg.size,0))
vcurve_interval[k]=interval
command = "curve "+str(k)+" interval "+str(interval)
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
command = "curve "+str(k)+" scheme equal"
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
if max(vcurve_interval.values()) != min(vcurve_interval.values()):
print 'mesh scheme is set to pave'
schemepave=True
for sk in surf_or:
command = "surface "+str(sk)+" scheme pave"
cubit.cmd(command)
#
for s in surf_vertical:
lcurve=cubit.get_relatives("surface",s,"curve")
interval_store=[]
for k in lcurve:
interval_curve=cubit.get_mesh_intervals('curve',k)
if k in list_curve_vertical:
volume_id = cubit.get_owning_volume("curve", k)
for idv in range(0,nvol):
if vol[idv].ID == volume_id:
int_v=vol[idv].intervalv
command = "curve "+str(k)+" interval "+str(int_v)
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
command = "curve "+str(k)+" scheme equal"
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
else:
interval_store.append((k,interval_curve))
if len(interval_store) != 0:
interval_min=min([iv[1] for iv in interval_store])
command = "curve "+' '.join(str(iv[0]) for iv in interval_store)+" interval "+str(interval_min)
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
command = "curve "+' '.join(str(iv[0]) for iv in interval_store)+" scheme equal"
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
command = "surface "+str(s)+" scheme submap"
cubit.cmd(command)
#cubit_error_stop(iproc,command,ner)
#
#meshing
if cfg.or_mesh_scheme == 'pave' or schemepave:
command='mesh surf '+' '.join(str(t) for t in top)
status=cubit_command_check(iproc,command,stop=True)
#cubit.cmd(command)
elif cfg.or_mesh_scheme == 'map':
command='mesh surf '+' '.join(str(t) for t in bottom)
status=cubit_command_check(iproc,command,stop=True)
#cubit.cmd(command)
for id_volume in range(nvol-1,-1,-1):
command = "mesh vol "+str(vol[id_volume].ID)
status=cubit_command_check(iproc,command,stop=False)
if not status:
for s in surf_vertical:
command_surf="mesh surf "+str(s)
cubit.cmd(command_surf)
command_set_meshvol='volume all redistribute nodes on\nvolume all autosmooth target off\nvolume all scheme Sweep Vector 0 0 -1\nvolume all sweep smooth Auto\n'
status=cubit_command_check(iproc,command_set_meshvol,stop=False)
status=cubit_command_check(iproc,command,stop=True)
#
#smoothing
print iproc, 'untangling...'
cmd="volume all smooth scheme untangle beta 0.02 cpu 10"
cubit.cmd(cmd)
cmd="smooth volume all"
cubit.cmd(cmd)
if cfg.smoothing:
print 'smoothing .... '+str(cfg.smoothing)
cubitcommand= 'surf all smooth scheme laplacian '
cubit.cmd(cubitcommand)
cubitcommand= 'smooth surf all'
cubit.cmd(cubitcommand)
#
cubitcommand= 'vol all smooth scheme laplacian '
cubit.cmd(cubitcommand)
cubitcommand= 'smooth vol all'
cubit.cmd(cubitcommand)
#
#
##vertical refinement
##for nvol = 3
##
##___________________________ interface 4
##
##vol 2
##___________________________ interface 3
##
##vol 1
##___________________________ interface 2
##
##vol 0
##___________________________ interface 1
##
refinement(nvol,vol,filename=filename)
#
#top layer vertical coarsening
print 'coarsening top layer... ',cfg.coarsening_top_layer
if cfg.coarsening_top_layer:
from sets import Set
cubitcommand= 'del mesh vol '+str(vol[-1].ID)+ ' propagate'
cubit.cmd(cubitcommand)
s1=Set(list_curve_vertical)
command = "group 'list_curve_tmp' add curve "+"in vol "+str(vol[-1].ID)
cubit.cmd(command)
group=cubit.get_id_from_name("list_curve_tmp")
list_curve_tmp=cubit.get_group_curves(group)
command = "delete group "+ str(group)
cubit.cmd(command)
s2=Set(list_curve_tmp)
lc=list(s1 & s2)
#
cubitcommand= 'curve '+' '.join(str(x) for x in lc)+' interval '+str(cfg.actual_vertical_interval_top_layer)
cubit.cmd(cubitcommand)
cubitcommand= 'mesh vol '+str(vol[-1].ID)
cubit.cmd(cubitcommand)
#
n=cubit.get_sideset_id_list()
if len(n) != 0:
command = "del sideset all"
cubit.cmd(command)
n=cubit.get_block_id_list()
if len(n) != 0:
command = "del block all"
cubit.cmd(command)
#
import boundary_definition
entities=['face']
print iproc, 'hex block definition...'
boundary_definition.define_bc(entities,parallel=True,cpux=cfg.cpux,cpuy=cfg.cpuy,cpuxmin=0,cpuymin=0,optionsea=False)
#save mesh
print iproc, 'untangling...'
cmd="volume all smooth scheme untangle beta 0.02 cpu 10"
cubit.cmd(cmd)
cmd="smooth volume all"
cubit.cmd(cmd)
print iproc, 'saving...'
savemesh(mpiflag,iproc=iproc,filename=filename)
def define_parallel_absorbing_surf():
"""
define the absorbing surfaces for a layered topological box where boundary are surfaces parallel to the axis.
it returns absorbing_surf,absorbing_surf_xmin,absorbing_surf_xmax,absorbing_surf_ymin,absorbing_surf_ymax,absorbing_surf_bottom,topo_surf
where
absorbing_surf is the list of all the absorbing boundary surf
absorbing_surf_xmin is the list of the absorbing boundary surfaces that correnspond to x=xmin
...
absorbing_surf_bottom is the list of the absorbing boundary surfaces that correspond to z=zmin
"""
try:
cubit.cmd('comment')
except:
try:
import cubit
cubit.init([""])
except:
print 'error importing cubit'
import sys
sys.exit()
absorbing_surf_xmin = []
absorbing_surf_xmax = []
absorbing_surf_ymin = []
absorbing_surf_ymax = []
absorbing_surf_bottom = []
top_surf = []
list_vol = cubit.parse_cubit_list("volume", "all")
init_n_vol = len(list_vol)
zmax_box = cubit.get_total_bounding_box("volume", list_vol)[7]
zmin_box = cubit.get_total_bounding_box(
"volume", list_vol
)[6] #it is the z_min of the box ... box= xmin,xmax,d,ymin,ymax,d,zmin...
xmin_box = cubit.get_total_bounding_box("volume", list_vol)[0]
xmax_box = cubit.get_total_bounding_box("volume", list_vol)[1]
ymin_box = cubit.get_total_bounding_box("volume", list_vol)[3]
ymax_box = cubit.get_total_bounding_box("volume", list_vol)[4]
list_surf = cubit.parse_cubit_list("surface", "all")
print '##boundary box: '
print '## x min: ' + str(xmin_box)
print '## y min: ' + str(ymin_box)
print '## z min: ' + str(zmin_box)
print '## x max: ' + str(xmax_box)
print '## y max: ' + str(ymax_box)
print '## z max: ' + str(zmax_box)
#box lengths
x_len = abs(xmax_box - xmin_box)
y_len = abs(ymax_box - ymin_box)
z_len = abs(zmax_box - zmin_box)
print '##boundary box: '
print '## x length: ' + str(x_len)
print '## y length: ' + str(y_len)
print '## z length: ' + str(z_len)
# tolerance parameters
absorbing_surface_distance_tolerance = 0.005
topographic_surface_distance_tolerance = 0.001
topographic_surface_normal_tolerance = 0.2
for k in list_surf:
center_point = cubit.get_center_point("surface", k)
if abs((center_point[0] - xmin_box) /
x_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_xmin.append(k)
elif abs((center_point[0] - xmax_box) /
x_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_xmax.append(k)
elif abs((center_point[1] - ymin_box) /
y_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_ymin.append(k)
elif abs((center_point[1] - ymax_box) /
y_len) <= absorbing_surface_distance_tolerance:
absorbing_surf_ymax.append(k)
elif abs((center_point[2] - zmin_box) /
z_len) <= absorbing_surface_distance_tolerance:
print 'center_point[2]' + str(center_point[2])
print 'kz:' + str(k)
absorbing_surf_bottom.append(k)
else:
sbox = cubit.get_bounding_box('surface', k)
dz = abs((sbox[7] - zmax_box) / z_len)
normal = cubit.get_surface_normal(k)
zn = normal[2]
dn = abs(zn - 1)
if dz <= topographic_surface_distance_tolerance and dn < topographic_surface_normal_tolerance:
top_surf.append(k)
return absorbing_surf_xmin, absorbing_surf_xmax, absorbing_surf_ymin, absorbing_surf_ymax, absorbing_surf_bottom, top_surf
def define_absorbing_surf_nopar():
"""
define the absorbing surfaces for a layered topological box where boundary surfaces are not parallel to the axis.
it returns absorbing_surf,topo_surf
where
absorbing_surf is the list of all the absorbing boundary surf
"""
try:
cubit.cmd('comment')
except:
try:
import cubit
cubit.init([""])
except:
print 'error importing cubit'
import sys
sys.exit()
from sets import Set
def product(*args, **kwds):
# product('ABCD', 'xy') --> Ax Ay Bx By Cx Cy Dx Dy
# product(range(2), repeat=3) --> 000 001 010 011 100 101 110 111
pools = map(tuple, args) * kwds.get('repeat', 1)
result = [[]]
for pool in pools:
result = [x + [y] for x in result for y in pool]
return result
absorbing_surf = []
absorbing_surf_xmin = []
absorbing_surf_xmax = []
absorbing_surf_ymin = []
absorbing_surf_ymax = []
absorbing_surf_bottom = []
top_surf = []
list_vol = cubit.parse_cubit_list("volume", "all")
init_n_vol = len(list_vol)
zmax_box = cubit.get_total_bounding_box("volume", list_vol)[7]
zmin_box = cubit.get_total_bounding_box(
"volume", list_vol
)[6] #it is the z_min of the box ... box= xmin,xmax,d,ymin,ymax,d,zmin...
xmin_box = cubit.get_total_bounding_box("volume", list_vol)[0]
xmax_box = cubit.get_total_bounding_box("volume", list_vol)[1]
ymin_box = cubit.get_total_bounding_box("volume", list_vol)[3]
ymax_box = cubit.get_total_bounding_box("volume", list_vol)[4]
list_surf = cubit.parse_cubit_list("surface", "all")
lv = []
for k in list_surf:
sbox = cubit.get_bounding_box('surface', k)
dzmax = abs((sbox[7] - zmax_box) / zmax_box)
dzmin = abs((sbox[6] - zmin_box) / zmin_box)
normal = cubit.get_surface_normal(k)
zn = normal[2]
if dzmax <= 0.001 and zn > 0.7:
top_surf.append(k)
list_vertex = cubit.get_relatives('surface', k, 'vertex')
for v in list_vertex:
valence = cubit.get_valence(v)
if valence <= 4: #valence 3 is a corner, 4 is a vertex between 2 volumes, > 4 is a vertex not in the boundaries
lv.append(v)
elif dzmin <= 0.001 and zn < -0.7:
absorbing_surf.append(k)
lp = []
combs = product(lv, lv)
for comb in combs:
v1 = comb[0]
v2 = comb[1]
c = Set(cubit.get_relatives("vertex", v1, "curve")) & Set(
cubit.get_relatives("vertex", v2, "curve"))
if len(c) == 1:
p = cubit.get_center_point("curve", list(c)[0])
lp.append(p)
for k in list_surf:
center_point = cubit.get_center_point("surface", k)
for p in lp:
if abs((center_point[0] - p[0]) / p[0]) <= 0.005 and abs(
(center_point[1] - p[1]) / p[1]) <= 0.005:
absorbing_surf.append(k)
break
return absorbing_surf, top_surf
def define_surf(ip=0,cpuxmin=0,cpuxmax=1,cpuymin=0,cpuymax=1,cpux=1,cpuy=1):
"""
define the absorbing surfaces for a layered topological box where boundary are surfaces parallel to the axis.
it returns absorbing_surf,absorbing_surf_xmin,absorbing_surf_xmax,absorbing_surf_ymin,absorbing_surf_ymax,absorbing_surf_bottom,topo_surf
where
absorbing_surf is the list of all the absorbing boundary surf
absorbing_surf_xmin is the list of the absorbing boundary surfaces that correnspond to x=xmin
...
absorbing_surf_bottom is the list of the absorbing boundary surfaces that correspond to z=zmin
"""
from utilities import get_v_h_list
#
from sets import Set
def product(*args, **kwds):
# product('ABCD', 'xy') --> Ax Ay Bx By Cx Cy Dx Dy
# product(range(2), repeat=3) --> 000 001 010 011 100 101 110 111
# for compatibility with python2.5
pools = map(tuple, args) * kwds.get('repeat', 1)
result = [[]]
for pool in pools:
result = [x+[y] for x in result for y in pool]
return result
absorbing_surf=[]
xmin=[]
xmax=[]
ymin=[]
ymax=[]
#
top_surf=[]
bottom_surf=[]
list_vol=cubit.parse_cubit_list("volume","all")
zmax_box=cubit.get_total_bounding_box("volume",list_vol)[7]
zmin_box=cubit.get_total_bounding_box("volume",list_vol)[6] #it is the z_min of the box ... box= xmin,xmax,d,ymin,ymax,d,zmin...
xmin_box=cubit.get_total_bounding_box("volume",list_vol)[0]
xmax_box=cubit.get_total_bounding_box("volume",list_vol)[1]
ymin_box=cubit.get_total_bounding_box("volume",list_vol)[3]
ymax_box=cubit.get_total_bounding_box("volume",list_vol)[4]
list_surf=cubit.parse_cubit_list("surface","all")
absorbing_surface_distance_tolerance=0.001
topographic_surface_distance_tolerance=0.1
topographic_surface_normal_tolerance=0.4
lv=[]
for k in list_surf:
sbox=cubit.get_bounding_box('surface',k)
if zmax_box == 0 and sbox[7] == 0:
dzmax=0
elif zmax_box == 0 or sbox[7] == 0:
dzmax=abs(sbox[7] - zmax_box)
else:
dzmax=abs(sbox[7] - zmax_box)/max(abs(sbox[7]),abs(zmax_box))
if zmin_box == 0 and sbox[6] == 0:
dzmin=0
elif zmin_box == 0 or sbox[6] == 0:
dzmin=abs(sbox[6] - zmin_box)
else:
dzmin=abs(sbox[6] - zmin_box)/max(abs(sbox[6]),abs(zmin_box))
normal=cubit.get_surface_normal(k)
zn=normal[2]
if dzmax <= topographic_surface_distance_tolerance and zn > topographic_surface_normal_tolerance:
top_surf.append(k)
list_vertex=cubit.get_relatives('surface',k,'vertex')
for v in list_vertex:
valence=cubit.get_valence(v)
if valence <= 4: #valence 3 is a corner, 4 is a vertex between 2 volumes, > 4 is a vertex not in the boundaries
lv.append(v)
elif dzmin <= 0.001 and zn < -1+topographic_surface_normal_tolerance:
bottom_surf.append(k)
if len(top_surf) ==0: #assuming that one topo surface need to be selected
_,_,_,_,_,top_surf=get_v_h_list(list_vol,chktop=False)
lp=[]
labelp=[]
combs=product(lv,lv)
for comb in combs:
v1=comb[0]
v2=comb[1]
c=Set(cubit.get_relatives("vertex",v1,"curve")) & Set(cubit.get_relatives("vertex",v2,"curve"))
if len(c) == 1:
p=cubit.get_center_point("curve",list(c)[0])
labelp.append(list(c)[0])
labelps=Set(labelp)
for c in labelps:
p=cubit.get_center_point("curve",c)
lp.append(p)
for k in list_surf:
center_point = cubit.get_center_point("surface", k)
for p in lp:
try:
if abs((center_point[0] - p[0])/p[0]) <= absorbing_surface_distance_tolerance and abs((center_point[1] - p[1])/p[1]) <= absorbing_surface_distance_tolerance:
absorbing_surf.append(k)
break
except:
if -1 <= center_point[0] <= 1 and -1 <= center_point[1] <= 1:
absorbing_surf.append(k)
break
#
four_side=True
if four_side:
xmintmp,ymintmp,xmaxtmp,ymaxtmp=define_4side_lateral_surfaces()
xmin=list(Set(xmintmp)-Set(xmaxtmp))
xmax=list(Set(xmaxtmp)-Set(xmintmp))
ymin=list(Set(ymintmp)-Set(ymaxtmp))
ymax=list(Set(ymaxtmp)-Set(ymintmp))
abs_xmintmp,abs_xmaxtmp,abs_ymintmp,abs_ymaxtmp=lateral_boundary_are_absorbing(ip,cpuxmin,cpuxmax,cpuymin,cpuymax,cpux,cpuy)
abs_xmin=list(Set(abs_xmintmp)-Set(abs_xmaxtmp))
abs_xmax=list(Set(abs_xmaxtmp)-Set(abs_xmintmp))
abs_ymin=list(Set(abs_ymintmp)-Set(abs_ymaxtmp))
abs_ymax=list(Set(abs_ymaxtmp)-Set(abs_ymintmp))
return absorbing_surf,abs_xmin,abs_xmax,abs_ymin,abs_ymax,top_surf,bottom_surf,xmin,ymin,xmax,ymax
def define_top_bottom_absorbing_surf(zmin_box, zmax_box):
"""
absorbing_surf_bottom is the list of the absorbing boundary surfaces that correspond to z=zmin
"""
try:
cubit.cmd('comment')
except:
try:
import cubit
cubit.init([""])
except:
print('error importing cubit')
import sys
sys.exit()
absorbing_surf_bottom = []
top_surf = []
list_vol = cubit.parse_cubit_list("volume", "all")
init_n_vol = len(list_vol)
# TO DO : Make zmin_box work properly.
# zmax_box=cubit.get_total_bounding_box("volume",list_vol)[7]
# zmin_box=cubit.get_total_bounding_box("volume",list_vol)[6] #it is the z_min of the box ... box= xmin,xmax,d,ymin,ymax,d,zmin...
xmin_box = cubit.get_total_bounding_box("volume", list_vol)[0]
xmax_box = cubit.get_total_bounding_box("volume", list_vol)[1]
ymin_box = cubit.get_total_bounding_box("volume", list_vol)[3]
ymax_box = cubit.get_total_bounding_box("volume", list_vol)[4]
list_surf = cubit.parse_cubit_list("surface", "all")
print('##boundary box: ')
print('## x min: ' + str(xmin_box))
print('## y min: ' + str(ymin_box))
print('## z min: ' + str(zmin_box))
print('## x max: ' + str(xmax_box))
print('## y max: ' + str(ymax_box))
print('## z max: ' + str(zmax_box))
#box lengths
x_len = abs(xmax_box - xmin_box)
y_len = abs(ymax_box - ymin_box)
z_len = abs(zmax_box - zmin_box)
print('##boundary box: ')
print('## x length: ' + str(x_len))
print('## y length: ' + str(y_len))
print('## z length: ' + str(z_len))
# tolerance parameters
absorbing_surface_distance_tolerance = 0.005
topographic_surface_distance_tolerance = 0.001
topographic_surface_normal_tolerance = 0.2
for k in list_surf:
center_point = cubit.get_center_point("surface", k)
if abs((center_point[2] - zmin_box) /
z_len) <= absorbing_surface_distance_tolerance:
print('center_point[2] ' + str(center_point[2]))
print('kz: ' + str(k))
absorbing_surf_bottom.append(k)
else:
sbox = cubit.get_bounding_box('surface', k)
dz = abs((sbox[7] - zmax_box) / z_len)
normal = cubit.get_surface_normal(k)
zn = normal[2]
dn = abs(zn - 1)
if dz <= topographic_surface_distance_tolerance and dn < topographic_surface_normal_tolerance:
top_surf.append(k)
return absorbing_surf_bottom, top_surf
def layercake_volume_fromacis_mpiregularmap(filename=None):
import sys
import start as start
#
mpiflag, iproc, numproc, mpi = start.start_mpi()
#
cfg = start.start_cfg(filename=filename)
#
from utilities import geo2utm, savegeometry
#
from math import sqrt
#
try:
mpi.barrier()
except:
pass
#
#
command = "comment '" + "PROC: " + str(iproc) + "/" + str(numproc) + " '"
cubit.cmd(command)
#
#get the limit of the volume considering the cpu
def xwebcut(x):
command = 'create planar surface with plane xplane offset ' + str(x)
cubit.cmd(command)
last_surface = cubit.get_last_id("surface")
command = "webcut volume all tool volume in surf " + str(last_surface)
cubit.cmd(command)
command = "del surf " + str(last_surface)
cubit.cmd(command)
def ywebcut(x):
command = 'create planar surface with plane yplane offset ' + str(x)
cubit.cmd(command)
last_surface = cubit.get_last_id("surface")
command = "webcut volume all tool volume in surf " + str(last_surface)
cubit.cmd(command)
command = "del surf " + str(last_surface)
cubit.cmd(command)
def translate2zero():
ss = cubit.parse_cubit_list('surface', 'all')
box = cubit.get_total_bounding_box("surface", ss)
xmin = box[0]
ymin = box[3]
cubit.cmd('move surface all x ' + str(-1 * xmin) + ' y ' +
str(-1 * ymin))
return xmin, ymin
def translate2original(xmin, ymin):
cubit.cmd('move surface all x ' + str(xmin) + ' y ' + str(ymin))
if mpiflag:
icpux = iproc % cfg.nproc_xi
icpuy = int(iproc / cfg.nproc_xi)
else:
icpuy = int(cfg.id_proc / cfg.nproc_xi)
icpux = cfg.id_proc % cfg.nproc_xi
#
ner = cubit.get_error_count()
#
icurve = 0
isurf = 0
ivertex = 0
#
xlength = (cfg.xmax - cfg.xmin) / float(
cfg.cpux) #length of x slide for chunk
ylength = (cfg.ymax - cfg.ymin) / float(
cfg.cpuy) #length of y slide for chunk
xmin_cpu = cfg.xmin + (xlength * (icpux))
ymin_cpu = cfg.ymin + (ylength * (icpuy))
xmax_cpu = xmin_cpu + xlength
ymax_cpu = ymin_cpu + ylength
#
#importing the surfaces
for inz in range(cfg.nz - 2, -2, -1):
if cfg.bottomflat and inz == -1:
command = "create planar surface with plane zplane offset " + str(
cfg.depth_bottom)
cubit.cmd(command)
else:
command = "import cubit '" + cfg.filename[inz] + "'"
cubit.cmd(command)
#translate
xmin, ymin = translate2zero()
print 'translate ...', -xmin, -ymin
xmin_cpu = xmin_cpu - xmin
ymin_cpu = ymin_cpu - ymin
xmax_cpu = xmax_cpu - xmin
ymax_cpu = ymax_cpu - ymin
ss = cubit.parse_cubit_list('surface', 'all')
box = cubit.get_total_bounding_box("surface", ss)
print 'dimension... ', box
#cutting the surfaces
xwebcut(xmin_cpu)
xwebcut(xmax_cpu)
ywebcut(ymin_cpu)
ywebcut(ymax_cpu)
#
list_surface_all = cubit.parse_cubit_list("surface", "all")
#condisidering only the surfaces inside the boundaries
dict_surf = {}
for isurf in list_surface_all:
p = cubit.get_center_point("surface", isurf)
if p[0] < xmin_cpu or p[0] > xmax_cpu or p[1] > ymax_cpu or p[
1] < ymin_cpu:
command = "del surf " + str(isurf)
cubit.cmd(command)
else:
dict_surf[str(isurf)] = p[2]
z = dict_surf.values()
z.sort()
list_surf = []
for val in z:
isurf = [k for k, v in dict_surf.iteritems() if v == val][0]
list_surf.append(int(isurf))
#
#lofting the volume
for i, j in zip(list_surf, list_surf[1:]):
ner = cubit.get_error_count()
create_volume(i, j, method=cfg.volumecreation_method)
#cubitcommand= 'create volume loft surface '+ str(i)+' '+str(j)
#cubit.cmd(cubitcommand)
ner2 = cubit.get_error_count()
#
translate2original(xmin, ymin)
if ner == ner2:
cubitcommand = 'del surface all'
cubit.cmd(cubitcommand)
#
#
#cubitcommand= 'composite create curve in vol all'
#cubit.cmd(cubitcommand)
list_vol = cubit.parse_cubit_list("volume", "all")
if len(list_vol) > 1:
cubitcommand = 'imprint volume all'
cubit.cmd(cubitcommand)
#cubit_error_stop(iproc,cubitcommand,ner)
#
cubitcommand = 'merge all'
cubit.cmd(cubitcommand)
#
savegeometry(iproc, filename=filename)
def define_top_bottom_absorbing_surf(zmin_box,zmax_box):
"""
absorbing_surf_bottom is the list of the absorbing boundary surfaces that correspond to z=zmin
"""
try:
cubit.cmd('comment')
except:
try:
import cubit
cubit.init([""])
except:
print 'error importing cubit'
import sys
sys.exit()
absorbing_surf_bottom=[]
top_surf = []
list_vol=cubit.parse_cubit_list("volume","all")
init_n_vol=len(list_vol)
# TO DO : Make zmin_box work properly.
# zmax_box=cubit.get_total_bounding_box("volume",list_vol)[7]
# zmin_box=cubit.get_total_bounding_box("volume",list_vol)[6] #it is the z_min of the box ... box= xmin,xmax,d,ymin,ymax,d,zmin...
xmin_box=cubit.get_total_bounding_box("volume",list_vol)[0]
xmax_box=cubit.get_total_bounding_box("volume",list_vol)[1]
ymin_box=cubit.get_total_bounding_box("volume",list_vol)[3]
ymax_box=cubit.get_total_bounding_box("volume",list_vol)[4]
list_surf=cubit.parse_cubit_list("surface","all")
print '##boundary box: '
print '## x min: ' + str(xmin_box)
print '## y min: ' + str(ymin_box)
print '## z min: ' + str(zmin_box)
print '## x max: ' + str(xmax_box)
print '## y max: ' + str(ymax_box)
print '## z max: ' + str(zmax_box)
#box lengths
x_len = abs( xmax_box - xmin_box)
y_len = abs( ymax_box - ymin_box)
z_len = abs( zmax_box - zmin_box)
print '##boundary box: '
print '## x length: ' + str(x_len)
print '## y length: ' + str(y_len)
print '## z length: ' + str(z_len)
# tolerance parameters
absorbing_surface_distance_tolerance=0.005
topographic_surface_distance_tolerance=0.001
topographic_surface_normal_tolerance=0.2
for k in list_surf:
center_point = cubit.get_center_point("surface", k)
if abs((center_point[2] - zmin_box)/z_len) <= absorbing_surface_distance_tolerance:
print 'center_point[2]' + str(center_point[2])
print 'kz:' + str(k)
absorbing_surf_bottom.append(k)
else:
sbox=cubit.get_bounding_box('surface',k)
dz=abs((sbox[7] - zmax_box)/z_len)
normal=cubit.get_surface_normal(k)
zn=normal[2]
dn=abs(zn-1)
if dz <= topographic_surface_distance_tolerance and dn < topographic_surface_normal_tolerance:
top_surf.append(k)
return absorbing_surf_bottom,top_surf
