コード例 #1
0
    def __init__(self, fname, useRect=USE_RECT_ELEM_DEFAULT, overRefine=0):
        """
        Generates a NURBS control mesh from PetIGA geometry input data 
        (as generated, e.g., by a separate ``igakit`` script) in the 
        file with name ``fname``.  Alternatively, ``fname`` may be an 
        ``igakit`` ``NURBS`` instance, for direct construction of the 
        control mesh.  The optional parameter ``useRect`` 
        is a Boolean specifying whether or not to use rectangular FEs for 
        the extraction.
        The optional parameter ``overRefine``
        indicates how many levels of refinement to apply beyond what is
        needed to represent the spline functions; choosing a value greater
        than the default of zero may be useful for
        integrating functions with fine-scale features.
        overRefine > 0 only works for useRect=False.
        """

        # get an igakit nurbs object from the file (or, directly from an
        # existing NURBS object)
        if (isinstance(fname, NURBS_ik)):
            ikNURBS = fname
        else:
            ikNURBS = PetIGA().read(fname)

        # create a BSpline scalar space given the knot vector(s)
        self.scalarSpline = BSpline(ikNURBS.degree, ikNURBS.knots, useRect,
                                    overRefine)

        # get the control net; already in homogeneous form
        nvar = len(ikNURBS.degree)
        if (nvar == 1):
            self.bnet = ikNURBS.control
        elif (nvar == 2):
            M = ikNURBS.control.shape[0]
            N = ikNURBS.control.shape[1]
            dim = ikNURBS.control.shape[2]
            self.bnet = zeros((M * N, dim))
            for j in range(0, N):
                for i in range(0, M):
                    self.bnet[ij2dof(i,j,M),:]\
                        = ikNURBS.control[i,j,:]
        else:
            M = ikNURBS.control.shape[0]
            N = ikNURBS.control.shape[1]
            O = ikNURBS.control.shape[2]
            dim = ikNURBS.control.shape[3]
            self.bnet = zeros((M * N * O, dim))
            for k in range(0, O):
                for j in range(0, N):
                    for i in range(0, M):
                        self.bnet[ijk2dof(i,j,k,M,N),:]\
                            = ikNURBS.control[i,j,k,:]
コード例 #2
0
    def __init__(self,fname,useRect=USE_RECT_ELEM_DEFAULT):
        """
        Generates a NURBS control mesh from PetIGA geometry input data 
        (as generated, e.g., by a separate ``igakit`` script) in the 
        file with name ``fname``.  Alternatively, ``fname`` may be an 
        ``igakit`` ``NURBS`` instance, for direct construction of the 
        control mesh.  The optional parameter ``useRect`` 
        is a Boolean specifying whether or not to use rectangular FEs for 
        the extraction.
        """

        # get an igakit nurbs object from the file (or, directly from an
        # existing NURBS object)
        if(isinstance(fname,NURBS_ik)):
            ikNURBS = fname
        else:
            ikNURBS = PetIGA().read(fname)

        # create a BSpline scalar space given the knot vector(s)
        self.scalarSpline = BSpline(ikNURBS.degree,ikNURBS.knots,useRect)
        
        # get the control net; already in homogeneous form
        nvar = len(ikNURBS.degree)
        if(nvar==1):
            self.bnet = ikNURBS.control
        elif(nvar==2):
            M = ikNURBS.control.shape[0]
            N = ikNURBS.control.shape[1]
            dim = ikNURBS.control.shape[2]
            self.bnet = zeros((M*N,dim))
            for j in range(0,N):
                for i in range(0,M):
                    self.bnet[ij2dof(i,j,M),:]\
                        = ikNURBS.control[i,j,:]
        else:
            M = ikNURBS.control.shape[0]
            N = ikNURBS.control.shape[1]
            O = ikNURBS.control.shape[2]
            dim = ikNURBS.control.shape[3]
            self.bnet = zeros((M*N*O,dim))
            for k in range(0,O):
                for j in range(0,N):
                    for i in range(0,M):
                        self.bnet[ijk2dof(i,j,k,M,N),:]\
                            = ikNURBS.control[i,j,k,:]
コード例 #3
0
ファイル: poisson-nurbs.py プロジェクト: Grayson3455/My-tigar
    for i in range(0, REF_LEVEL):
        numNewKnots *= 2
    h = 2.0 / float(numNewKnots)
    numNewKnots -= 1
    knotList = []
    for i in range(0, numNewKnots):
        knotList += [
            float(i + 1) * h - 1.0,
        ]
    newKnots = array(knotList)
    ikNURBS.refine(0, newKnots)
    ikNURBS.refine(1, newKnots)

    # Output in PetIGA format
    if (mpirank == 0):
        PetIGA().write("out.dat", ikNURBS)
    MPI.barrier(worldcomm)

    ####### Preprocessing #######

    if (mpirank == 0):
        print("Generating extraction...")

    # Read in the generated geometry to create a control mesh.
    splineMesh = NURBSControlMesh("out.dat", useRect=True)

    # Alternative:  Create splineMesh directly from ikNURBS:
    #NURBSControlMesh(ikNURBS,useRect=True)

    # Create a spline generator for a spline with a single scalar field on the
    # given control mesh, where the scalar field is the same as the one used
コード例 #4
0
from igakit.io import PetIGA
from numpy import linspace

#Geometry
R = 1.0

c1 = circle(0.005 * R, (0, 0, 1))
c2 = circle(R, (0, 0, 1))
#c1 = circle(radius=R)
#c2 = circle(radius=20*R)
S = ruled(c1, c2).transpose().elevate(0, 1)

#refine along X
to_insertX = np.setdiff1d(linspace(0, 0.25, 11)[1:-1], S.knots[0])
S.refine(0, to_insertX)
#to_insertX = np.setdiff1d(linspace(0.25,1.0,5)[1:-1],S.knots[0]);
#S.refine(0,to_insertX)

#refine along Y
to_insertY = np.setdiff1d(linspace(0, 1.0, 21)[1:-1], S.knots[1])
S.refine(1, to_insertY)

#S.elevate (1,1);

#periodicity
S.unclamp(1, continuity=1)

#plt.plot(S,color='g')
#plt.show()
PetIGA().write("mesh.dat", S, nsd=3)
コード例 #5
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    vectors[l[i + 1]] = range(j, j + dim)

l = data[1].split()
nSolScalars = int(l[0])
for i in range(nSolScalars):
    scalars[l[i + 1]] = nPrjtnScalars + dim * nPrjtnVectors + i

l = data[2].split()
nSolVectors = int(l[0])
for i in range(nSolVectors):
    j = nPrjtnScalars + dim * nPrjtnVectors + nSolScalars + i * dim
    vectors[l[i + 1]] = range(j, j + dim)

data = {}
cwdir = os.getcwd()
geom = PetIGA().read('mesh.dat')
inc = 1
if (nPrjtnScalars + nPrjtnVectors > 0):
    for filename1, filename2 in zip(glob.glob('outU*.dat'),
                                    glob.glob('outE*.dat')):

        if int(filename1.split(".")[0][4:]) >= bound:
            filename2 = "outE" + filename1.split(".")[0][4:] + ".dat"
            outname = "out" + filename1.split(".")[0][4:] + ".vtk"
            sol2 = PetIGA().read_vec(filename1, geom)
            sol1 = PetIGA().read_vec(filename2, geom)
            if (sol1.ndim == dim):
                sol1 = np.expand_dims(sol1, axis=dim)
            if (sol2.ndim == dim):
                sol2 = np.expand_dims(sol2, axis=dim)
            sol = np.concatenate((sol1, sol2), axis=dim)
コード例 #6
0
ファイル: pospro2Diff.py プロジェクト: Zegpi/Defects
Lista1 = glob.glob(fileName3)
Lista2 = glob.glob(fileName4)

if len(Lista2) > 0:
    fileName2 = fileName4
else:
    fileName2 = fileName3

try:
    meshName = sys.argv[3]
except:
    meshName = "geometry"

meshName = "./" + meshName + ".dat"
# read in discretization info and potentially geometry
nrb = PetIGA().read(meshName)

Lista1 = glob.glob(fileName)
Lista2 = glob.glob(fileName2)

num1 = len(Lista1)
num2 = len(Lista2)

matA = numpy.ndarray([2, 2])
matB = numpy.ndarray([2, 2])

if num1 == num2:

    f1 = open('../../sharedResults/textSigma.txt', 'w')
    f2 = open('../../sharedResults/textExact.txt', 'w')
コード例 #7
0
C[0, 1, :] = [0, -100, 100, 1]
C[1, 1, :] = [100, -100, 100, 1]
C[0, 2, :] = [0, 0, 100, 1]
C[1, 2, :] = [100, 0, 100, 1]
C[:, 1, :] *= val

geom = NURBS([U, V], C)
geom.elevate(0, max(p - 1, 0)).elevate(1, max(p - 2, 0))

h = 1. / N
insert = np.linspace(h, 1. - h, N - 1)
geom.refine(0, insert).refine(1, insert)

if True:
    from igakit.io import PetIGA
    PetIGA().write("ClassicalShell.dat", geom, nsd=3)

if False:
    from igakit.plot import plt
    plt.figure()
    plt.cpoint(geom)
    plt.cwire(geom)
    plt.kwire(geom)
    plt.surface(geom)
    plt.show()

if False:
    from igakit.io import PetIGA, VTK
    nrb = PetIGA().read("ClassicalShell.dat")
    sol = PetIGA().read_vec("ClassicalShell.out", nrb)
    U = sol[..., :3]
コード例 #8
0
U=knots;
Curve = NURBS([U],C)
S = revolve(Curve, circleFileName, (0,0), 1)
print S.knots[0];
print S.knots[1];

#refine along X
#to_insertX = np.setdiff1d(linspace(0.25,0.5,11)[1:-1],S.knots[0]);
#S.refine(0,to_insertX)

#refine along Y
#to_insertY = np.setdiff1d(linspace(0,1.0,21)[1:-1],S.knots[1]);
#S.elevate(0,1);

#S.elevate(1,1);
#S.refine(1,kX);
#S.refine(1,kX);
#S.insert(1,0.5,1)
#S.rotate(1,0.5*Pi)
if C2Continuity:
    S.elevate(0,1); S.elevate(1,1);
    S.unclamp(1, continuity=2);
else:
    S.unclamp(1, continuity=1);

#
from igakit.io import PetIGA
PetIGA().write(outputFileName, S, nsd=3)


コード例 #9
0
def elastic_test(props):
  type = props.type()
  mode = props.mode()
  petsc_reinitialize()
  if mode=='tao':
    petsc_add_options([sys.argv[0]]+'''
      -tao_monitor -tao_converged_reason -tao_type nls
      -tao_nls_ksp_type petsc -ksp_type minres
      -tao_max_it 200 -ksp_max_it 500'''.split())
  petsc_add_options([sys.argv[0]]+props.petsc().split())
  comm = petsc_comm_world()
  d = props.dim()
  material = props.youngs_modulus(),props.poissons_ratio()
  rho_g = props.density()*props.gravity()*-axis_vector(d-1,d=d)

  # Diagnostic options
  petsc_add_options('ignored -tao_monitor -tao_converged_reason'.split())

  if type=='iga':
    assert props.model()=='neo-hookean'
    iga = NeoHookeanElasticIGA[d](comm,material,rho_g)
    geom,boundary = iga_geometry(props,iga)
    iga.set_from_options()
    iga.set_up()

    # Boundary conditions
    x = iga.read_vec(boundary.name)
    dummy = 17 # Overwritten by set_fix_table
    for axis in xrange(d):
      for side in 0,1:
        for i in xrange(d):
          if axis==0 and side==0:
            iga.set_boundary_value(axis,side,i,0)
    iga.set_fix_table(x)

    if mode=='snes':
      snes = iga.create_snes()
      snes.set_from_options()
    elif mode=='tao':
      tao = iga.create_tao()
      tao.set_from_options()

  elif type=='fe':
    dm = dm_geometry(props,comm)
    degree = props.degree()
    degree = 1
    petsc_add_options(['ignored','-petscspace_order',str(degree)])
    if 0: # Would be needed for neumann
      petsc_add_options(['ignored','-bd_petscspace_order',str(degree)])
    snes = SNES(comm)
    snes.set_dm(dm)
    fe = FE(comm,d,d),
    print('fe dofs = %s'%fe[0].dofs)
    fe_bd = fe_aux = ()
    dm.create_default_section(('x',),fe,'wall',(0,))
    start = identity_analytic(d)
    model = {'neo-hookean':NeoHookeanElasticModel,'laplace':LaplaceElasticModel}[props.model()]
    model = model[d](fe,fe_aux,fe_bd,start,material,rho_g)
    dm.set_model(model,mode=='tao') # Use a real objective for tao but not for snes
    A = dm.create_matrix()
    snes.set_jacobian(A,A)
    snes.set_from_options()
    if mode=='tao':
      tao = TaoSolver(comm)
      tao.set_snes(snes)
      tao.set_from_options()
    x = dm.create_global_vector()
    dm.project((start,),INSERT_VALUES,x)
  else:
    raise RuntimeError("unknown discretization type '%s'"%type)

  def check(*args):
    if props.check() and (mode=='snes' or type=='fe'):
      snes.consistency_test(x,1e-6,1e-3,2e-10,10)
  check()

  # Solve
  if mode=='snes':
    snes.add_monitor(check)
    snes.solve(None,x)
  elif mode=='tao':
    tao.set_initial_vector(x)
    tao.add_monitor(check)
    tao.solve()

  # View
  if props.view():
    if type=='iga':
      geom_file = named_tmpfile(prefix='geom',suffix='.nurbs')
      x_file = named_tmpfile(prefix='x',suffix='.vec')
      iga.write(geom_file.name)
      iga.write_vec(x_file.name,x)

      from igakit.io import PetIGA
      geom = PetIGA().read(geom_file.name)
      x = PetIGA().read_vec(x_file.name,nurbs=geom)
      geom.control[...,:d] = x
      from igakit.plot import plt
      plt.figure()
      plt.cwire(geom)
      plt.kwire(geom)
      plt.surface(geom)
      plt.show()
    elif type=='fe':
      name = props.output()
      if not name:
        f = named_tmpfile(prefix='elastic',suffix='.vtk')
        name = f.name
      assert name.endswith('.vtk')
      dm.write_vtk(name,x)
      cmd = ['hollow-view',name]
      print(' '.join(cmd))
      subprocess.check_call(cmd)
    else:
      raise RuntimeError("weird type '%s'"%type)
コード例 #10
0
"""
This python script shows the usage of igakit
(https://bitbucket.org/dalcinl/igakit) to post-process results
obtained using the demo code:

   ./demo/Poisson.c 

When running the C-code with the -save option, two data files are
generated. One contains the geometry and discretization information,
the other is the solution vector.
"""
from igakit.io import PetIGA, VTK
from numpy import linspace

# read in discretization info and potentially geometry
nrb = PetIGA().read("PoissonGeometry.dat")

# read in solution vector as a numpy array
sol = PetIGA().read_vec("PoissonSolution.dat", nrb)

# write a function to sample the nrbs object (100 points from beginning to end)
uniform = lambda U: linspace(U[0], U[-1], 100)

# write a binary VTK file
VTK().write(
    "PoissonVTK.vtk",  # output filename
    nrb,  # igakit NURBS object
    fields=sol,  # sol is the numpy array to plot 
    sampler=uniform,  # specify the function to sample points
    scalars={'solution': 0})  # adds a scalar plot to the VTK file
コード例 #11
0
ファイル: pospro2.py プロジェクト: Zegpi/Defects
if len(Lista2) > 0:
    fileName = fileName2
else:
    fileName = fileName1

nombre = fileNameInput.split("*")[0]

try:
    meshName = sys.argv[2]
except:
    meshName = "geometry"

meshName = "./" + meshName + ".dat"
# read in discretization info and potentially geometry
nrb = PetIGA().read(meshName)

#for infile in glob.glob("results/poisson2d*.dat"):
for infile in glob.glob(fileName):
    # read in solution vector as a numpy array
    try:
        sol = PetIGA().read_vec(infile, nrb)
    except:
        print('Mismatch in vector lengths, wrong mesh?, file=' + sys.argv[1])
        sys.exit()

    outfile = infile[:-4] + ".vtk"  #string[:-4] cuts the last 4 characters from the string, in this case ".dat"

    num = numpy.round(numpy.sqrt(sol.size / 2.0), decimals=0)
    #print(num)
コード例 #12
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# Parameter determining level of refinement
REF_LEVEL = N_LEVELS + 3

# Refinement
to_insert_u = linspace(min_uKnots, max_uKnots, 2**REF_LEVEL)[1:-1]
to_insert_v = linspace(min_vKnots, max_vKnots, 2**REF_LEVEL)[1:-1]
srf.refine(0, to_insert_u)
srf.refine(1, to_insert_v)

plt.plot(srf)
plt_fig.savefig('savings/refined_surface.png')

# Output in PetIGA format
if (mpirank == 0):
    PetIGA().write("out.dat", srf)
MPI.barrier(worldcomm)

# Creating a control mesh from the NURBS
splineMesh = NURBSControlMesh(srf, useRect=True)

# Create a spline generator for a spline with a single scalar field on the
# given control mesh, where the scalar field is the same as the one used
# to determine the mapping $\mathbf{F}:\widehat{\Omega}\to\Omega$.
splineGenerator = EqualOrderSpline(1, splineMesh)

# Set Dirichlet Boundary conditions (left temperature at 0 and right temperature at 1)
field = 0
scalarSpline = splineGenerator.getScalarSpline(field)
for parametricDirection in [0, 1]:
    for side in [0, 1]:
コード例 #13
0
if len(Lista2) > 0:
    fileName = fileName2
else:
    fileName = fileName1

nombre = fileNameInput.split("*")[0]

try:
    meshName = sys.argv[2]
except:
    meshName = "geometry"

meshName = "./" + meshName + ".dat"
# read in discretization info and potentially geometry
nrb = PetIGA().read(meshName)

# write a function to sample the nrbs object

uniform = lambda U: linspace(U[0], U[-1], 96)

for infile in glob.glob(fileName):
    # read in solution vector as a numpy array
    try:
        sol = PetIGA().read_vec(
            infile, nrb
        )  #Aqui esta el secreto, con esto puedo leer 2 archivos y quiza restarlos
    except:
        print('Mismatch in vector lengths, wrong mesh?, file=' + sys.argv[1])
        sys.exit()