def big2littlePTS(self, fileName, foleName):
# ~~ Openning files ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
fle = open(fileName, "rb")
fole = open(foleName, "wb")
print " +> writing the volumes-file: ", foleName
# ~~ Read/Write dimensions ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
n1 = self.NPOIN3 + 1
minvol = self.minvol * np.ones(self.NPOIN3, dtype=np.float32)
# ~~ Read volumes ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
pbar = ProgressBar(maxval=self.HYDROIT).start()
for i in range(self.HYDROIT):
l, it = unpack(">ii", fle.read(4 + 4))
VOLUME = np.asarray(
unpack(">" + str(self.NPOIN3) + "f",
fle.read(4 * self.NPOIN3)))
VOLUME = np.maximum(VOLUME, minvol)
fle.seek(4, 1)
if it >= self.tfrom and it <= self.tstop:
pbar.write(" ~> read iteration: " + str(it), i)
fole.write(pack("<ii", 4 * n1, it - self.HYDRO00))
fole.write(pack("<" + str(self.NPOIN3) + "f", *(VOLUME)))
fole.write(pack("<i", 4 * n1))
else:
pbar.write(" ~> ignore iteration: " + str(it), i)
pbar.update(i)
pbar.finish()
fle.close()
fole.close()
def big2littleARE(self, fileName, foleName):
# ~~ Openning files ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
fle = open(fileName, "rb")
fole = open(foleName, "wb")
print " +> writing the areas-file: ", foleName
# ~~ Read/Write dimensions ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
NSEG2 = (3 * self.geo.NELEM3 + self.conlim.NPTFR) / 2
MBND2 = np.count_nonzero(self.conlim.BOR["lih"] != 2)
n3 = NSEG2 + MBND2
# n4 = 2*( self.geo.NPLAN-1 )*self.geo.NPOIN3
# ~~ Read volumes ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
pbar = ProgressBar(maxval=self.HYDROIT).start()
for i in range(self.HYDROIT):
l, it = unpack(">ii", fle.read(4 + 4))
AREAS = np.asarray(unpack(">" + str(n3) + "f", fle.read(4 * n3)))
fle.seek(4, 1)
if it >= self.tfrom and it <= self.tstop:
pbar.write(" ~> read iteration: " + str(it), i)
fole.write(pack("<ii", 4 * n3, it - self.HYDRO00))
fole.write(pack("<" + str(n3) + "f", *(AREAS)))
fole.write(pack("<i", 4 * n3))
else:
pbar.write(" ~> ignore iteration: " + str(it), i)
pbar.update(i)
pbar.finish()
fle.close()
fole.close()
def getSERIES( self,nodes,varsIndexes=[],showbar=True ):
f = self.file['hook']
endian = self.file['endian']
ftype,fsize = self.file['float']
if varsIndexes == []: varsIndexes = self.VARINDEX
# ~~ Ordering the nodes ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# This assumes that nodes starts at 1
onodes = np.sort(np.array( zip(range(len(nodes)),nodes), dtype=[ ('0',int),('1',int) ] ),order='1')
# ~~ Extract time profiles ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
if fsize == 4: z = np.zeros((len(varsIndexes),len(nodes),len(self.tags['cores'])),dtype=np.float32)
else: z = np.zeros((len(varsIndexes),len(nodes),len(self.tags['cores'])),dtype=np.float64)
f.seek(self.tags['cores'][0])
if showbar: pbar = ProgressBar(maxval=len(self.tags['cores'])).start()
for t in range(len(self.tags['cores'])):
f.seek(self.tags['cores'][t])
f.seek(4+fsize+4,1)
if showbar: pbar.update(t)
for ivar in range(self.NVAR):
f.seek(4,1)
if ivar in varsIndexes:
jnod = onodes[0]
f.seek(fsize*(jnod[1]-1),1)
z[varsIndexes.index(ivar),jnod[0],t] = unpack(endian+ftype,f.read(fsize))[0]
for inod in onodes[1:]:
f.seek(fsize*(inod[1]-jnod[1]-1),1)
z[varsIndexes.index(ivar),inod[0],t] = unpack(endian+ftype,f.read(fsize))[0]
jnod = inod
f.seek(fsize*self.NPOIN3-fsize*jnod[1],1)
else:
f.seek(fsize*self.NPOIN3,1)
f.seek(4,1)
if showbar: pbar.finish()
return z
def big2littleVFX(self, fileName, foleName):
# ~~ Openning files ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
fle = open(fileName, 'rb')
fole = open(foleName, 'wb')
print ' +> writing the flows-file: ', foleName
# ~~ Read/Write dimensions ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
NSEG2 = (3 * self.geo.NELEM3 + self.conlim.NPTFR) / 2
MBND2 = np.count_nonzero(self.conlim.BOR['lih'] != 2)
n3 = (NSEG2 + MBND2)
#n4 = 2*( self.geo.NPLAN-1 )*self.geo.NPOIN3
# ~~ Read volumes ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
pbar = ProgressBar(maxval=self.HYDROIT).start()
for i in range(self.HYDROIT):
l, it = unpack('>ii', fle.read(4 + 4))
VFLUXES = np.asarray(unpack('>' + str(n3) + 'f', fle.read(4 * n3)))
fle.seek(4, 1)
if it >= self.tfrom and it <= self.tstop:
pbar.write(' ~> read iteration: ' + str(it), i)
fole.write(pack('<ii', 4 * n3, it - self.HYDRO00))
fole.write(pack('<' + str(n3) + 'f', *(VFLUXES)))
fole.write(pack('<i', 4 * n3))
else:
pbar.write(' ~> ignore iteration: ' + str(it), i)
pbar.update(i)
pbar.finish()
fle.close()
fole.close()
def big2littleARE(self,fileName,foleName):
# ~~ Openning files ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
fle = open(fileName,'rb')
fole = open(foleName,'wb')
print ' +> writing the areas-file: ',foleName
# ~~ Read/Write dimensions ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
NSEG2 = ( 3*self.geo.NELEM3 + self.conlim.NPTFR )/2
MBND2 = np.count_nonzero(self.conlim.BOR['lih'] != 2)
n3 = ( NSEG2 + MBND2 )
#n4 = 2*( self.geo.NPLAN-1 )*self.geo.NPOIN3
# ~~ Read volumes ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
pbar = ProgressBar(maxval=self.HYDROIT).start()
for i in range(self.HYDROIT):
l,it = unpack('>ii',fle.read(4+4))
AREAS = np.asarray( unpack('>'+str(n3)+'f',fle.read(4*n3)) )
fle.seek(4,1)
if it >= self.tfrom and it <= self.tstop:
pbar.write(' ~> read iteration: '+str(it),i)
fole.write(pack('<ii',4*n3,it-self.HYDRO00))
fole.write(pack('<'+str(n3)+'f',*(AREAS)))
fole.write(pack('<i',4*n3))
else:
pbar.write(' ~> ignore iteration: '+str(it),i)
pbar.update(i)
pbar.finish()
fle.close()
fole.close()
def big2littlePTS(self,fileName,foleName):
# ~~ Openning files ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
fle = open(fileName,'rb')
fole = open(foleName,'wb')
print ' +> writing the volumes-file: ',foleName
# ~~ Read/Write dimensions ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
n1 = self.NPOIN3+1
minvol = self.minvol * np.ones(self.NPOIN3,dtype=np.float32)
# ~~ Read volumes ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
pbar = ProgressBar(maxval=self.HYDROIT).start()
for i in range(self.HYDROIT):
l,it = unpack('>ii',fle.read(4+4))
VOLUME = np.asarray( unpack('>'+str(self.NPOIN3)+'f',fle.read(4*self.NPOIN3)) )
VOLUME = np.maximum(VOLUME,minvol)
fle.seek(4,1)
if it >= self.tfrom and it <= self.tstop:
pbar.write(' ~> read iteration: '+str(it),i)
fole.write(pack('<ii',4*n1,it-self.HYDRO00))
fole.write(pack('<'+str(self.NPOIN3)+'f',*(VOLUME)))
fole.write(pack('<i',4*n1))
else:
pbar.write(' ~> ignore iteration: '+str(it),i)
pbar.update(i)
pbar.finish()
fle.close()
fole.close()
def putContent(self,fileName,showbar=True): # TODO: files also have to have the same header
self.slf.fole.update({ 'hook': open(fileName,'wb') })
ibar = 0
if showbar: pbar = ProgressBar(maxval=len(self.slf.tags['times'])).start()
self.slf.appendHeaderSLF()
# ~~> Time stepping
for t in range(len(self.slf.tags['times'])):
ibar += 1
self.slf.appendCoreTimeSLF(t) # Time stamps
self.slf.appendCoreVarsSLF(self.getPALUES(t))
if showbar: pbar.update(ibar)
self.slf.fole['hook'].close()
if showbar: pbar.finish()
def putContent( self,fileName,showbar=True ):
self.fole.update({ 'name': fileName })
self.fole.update({ 'hook': open(fileName,'wb') })
ibar = 0
if showbar: pbar = ProgressBar(maxval=len(self.tags['times'])).start()
self.appendHeaderSLF()
for t in range(len(self.tags['times'])):
ibar += 1
self.appendCoreTimeSLF(t)
self.appendCoreVarsSLF(self.getVALUES(t))
if showbar: pbar.update(ibar)
self.fole['hook'].close()
if showbar: pbar.finish()
def getEdgesSLF(IKLE,MESHX,MESHY,showbar=True):
try:
from matplotlib.tri import Triangulation
edges = Triangulation(MESHX,MESHY,IKLE).get_cpp_triangulation().get_edges()
except:
#print '... you are in bad luck !'
#print ' ~> without matplotlib based on python 2.7, this operation takes ages'
edges = []
ibar = 0
if showbar: pbar = ProgressBar(maxval=len(IKLE)).start()
for e in IKLE:
ibar += 1
if showbar: pbar.update(ibar)
if [e[0],e[1]] not in edges: edges.append([e[1],e[0]])
if [e[1],e[2]] not in edges: edges.append([e[2],e[1]])
if [e[2],e[0]] not in edges: edges.append([e[0],e[2]])
if showbar: pbar.finish()
return edges
def getNeighboursSLF(IKLE,MESHX,MESHY,showbar=True):
try:
from matplotlib.tri import Triangulation
neighbours = Triangulation(MESHX,MESHY,IKLE).get_cpp_triangulation().get_neighbors()
except:
#print '... you are in bad luck !'
#print ' ~> without matplotlib based on python 2.7, this operation takes a little longer'
insiders = {}; bounders = {}
#print ' +> start listing neighbours of edges'
ibar = 0
if showbar: pbar = ProgressBar(maxval=(3*len(IKLE))).start()
for e,i in zip(IKLE,range(len(IKLE))):
nk = bounders.keys()
for k in [0,1,2]:
ibar += 1
if showbar: pbar.update(ibar)
if (e[k],e[(k+1)%3]) not in nk: bounders.update({ (e[(k+1)%3],e[k]):i })
else:
j = bounders[(e[k],e[(k+1)%3])]
insiders.update({(e[k],e[(k+1)%3]):[i,j]})
del bounders[(e[k],e[(k+1)%3])]
ibar = 0
neighbours = - np.ones((len(IKLE),3),dtype=np.int)
for e,i in zip(IKLE,range(len(IKLE))):
for k in [0,1,2]:
ibar += 1
if showbar: pbar.update(ibar)
if (e[k],e[(k+1)%3]) in insiders:
a,b = insiders[(e[k],e[(k+1)%3])]
if a == i: neighbours[i][k] = b
if b == i: neighbours[i][k] = a
if (e[(k+1)%3],e[k]) in insiders:
a,b = insiders[(e[(k+1)%3],e[k])]
if a == i: neighbours[i][k] = b
if b == i: neighbours[i][k] = a
#pbar.write(' +> listing neighbours of edges completed',ibar)
if showbar: pbar.finish()
return neighbours
def putContent(self,fileName): # TODO: files also have to have the same header
if self.suite and self.merge:
if len(self.slfs) == 2: # /!\ difference only between two files
self.slf.fole.update({ 'hook': open(fileName,'wb') })
self.slf.fole['name'] = fileName
ibar = 0; pbar = ProgressBar(maxval=len(self.slf.tags['times'])).start()
self.slf.appendHeaderSLF()
for t in range(len(self.slf.tags['times'])):
ibar += 1
self.slf.appendCoreTimeSLF(t)
self.slf.appendCoreVarsSLF(self.slf.getVALUES(t)-self.slfs[1].getVALUES(t))
pbar.update(ibar)
pbar.finish()
else: self.slf.putContent(fileName) # just a copy
elif self.suite:
self.slf.fole.update({ 'hook': open(fileName,'wb') })
self.slf.fole['name'] = fileName
ibar = 0; pbar = ProgressBar(maxval=len(self.slf.tags['times'])).start()
self.slf.appendHeaderSLF()
for t in range(len(self.slf.tags['times'])):
ibar += 1
time = self.slf.tags['times'][t]
self.slf.appendCoreTimeSLF(t)
self.slf.appendCoreVarsSLF(self.slf.getVALUES(t))
pbar.update(ibar)
pbar.finish()
for slf in self.slfs:
slf.fole = self.slf.fole
ibar = 0; pbar = ProgressBar(maxval=len(slf.tags['times'])).start()
for t in range(len(slf.tags['times'])):
if slf.tags['times'][t] > time:
ibar += 1
time = slf.tags['times'][t]
slf.appendCoreTimeSLF(t)
slf.appendCoreVarsSLF(slf.getVALUES(t))
pbar.update(ibar)
pbar.finish()
self.slf.fole['hook'].close()
elif self.merge:
self.slf.fole.update({ 'hook': open(fileName,'wb') })
self.slf.fole['name'] = fileName
for slf in self.slfs[1:]:
slf.fole = self.slf.fole
idvars = []
for v in range(len(slf.VARNAMES)):
if v not in self.slf.VARNAMES:
idvars.append(v)
self.slf.VARNAMES.append(slf.VARNAMES[v])
self.slf.VARUNITS.append(slf.VARUNITS[v])
for v in range(len(slf.CLDNAMES)):
if v not in self.slf.CLDNAMES:
idvars.append(v+slf.NBV1)
self.slf.CLDNAMES.append(slf.CLDNAMES[v])
self.slf.CLDUNITS.append(slf.CLDUNITS[v])
slf.VARINDEX = idvars
self.slf.NBV1 = len(self.slf.VARNAMES)
self.slf.NBV2 = len(self.slf.CLDNAMES)
ibar = 0; pbar = ProgressBar(maxval=len(self.slf.tags['times'])).start()
self.slf.appendHeaderSLF()
for t in range(len(self.slf.tags['times'])):
ibar += 1
self.slf.appendCoreTimeSLF(t)
self.slf.appendCoreVarsSLF(self.slf.getVALUES(t))
for slf in self.slfs[1:]:
self.slf.appendCoreVarsSLF(slf.getVALUES(t))
pbar.update(ibar)
pbar.finish()
self.slf.fole['hook'].close()
elif len(self.slf.tags['times']) == 1 and len(self.slfs) == 2:
# self.slf will be distributed over the time frames of the scond other
self.slf.fole.update({ 'hook': open(fileName,'wb') })
self.slf.fole['name'] = fileName
slf = self.slfs[1]
slf.fole = self.slf.fole
idvars = []
for v in range(len(slf.VARNAMES)):
if v not in self.slf.VARNAMES:
idvars.append(v)
self.slf.VARNAMES.append(slf.VARNAMES[v])
self.slf.VARUNITS.append(slf.VARUNITS[v])
for v in range(len(slf.CLDNAMES)):
if v not in self.slf.CLDNAMES:
idvars.append(v+slf.NBV1)
self.slf.CLDNAMES.append(slf.CLDNAMES[v])
self.slf.CLDUNITS.append(slf.CLDUNITS[v])
slf.VARINDEX = idvars
self.slf.NBV1 = len(self.slf.VARNAMES)
self.slf.NBV2 = len(self.slf.CLDNAMES)
ibar = 0; pbar = ProgressBar(maxval=len(slf.tags['times'])).start()
self.slf.appendHeaderSLF()
for t in range(len(slf.tags['times'])):
ibar += 1
slf.appendCoreTimeSLF(slf,t)
self.slf.appendCoreVarsSLF(self.slf.getVALUES(0))
slf.appendCoreVarsSLF(slf.getVALUES(t))
pbar.update(ibar)
pbar.finish()
self.slf.fole['hook'].close()
else:
print "Does not know how to merge your files. Try either:"
print " + to make sure your files have the same time support"
print " + to make sure your files have the same variables"
sys.exit(1)
