def testDiagonalEigenVectors(self):
for i in xrange(self.ntests):
lam1 = rangen.uniform(-ranrange, ranrange)
lam2 = rangen.uniform(-ranrange, ranrange)
lam3 = rangen.uniform(-ranrange, ranrange)
A = SymTensor3d(lam1, 0.0, 0.0, 0.0, lam2, 0.0, 0.0, 0.0, lam3)
A = SymTensor3d(lam1, 0.0, 0.0, 0.0, lam2, 0.0, 0.0, 0.0, lam3)
lam0 = [(lam1, Vector3d(1, 0, 0)), (lam2, Vector3d(0, 1, 0)),
(lam3, Vector3d(0, 0, 1))]
lam0.sort()
eigenVecs0 = [x[1] for x in lam0]
eigenStruct = A.eigenVectors()
lam = [(eigenStruct.eigenValues(i),
eigenStruct.eigenVectors.getColumn(i)) for i in range(3)]
lam.sort()
eigenVecs = [x[1] for x in lam]
for (x, x0) in zip(eigenVecs, eigenVecs0):
self.failUnless(
fuzzyEqual(x.magnitude(), 1.0),
"Eigen vector %s does not equal expected value %s" %
(str(x), str(x0)))
self.failUnless(
fuzzyEqual(abs(x.dot(x0)), 1.0),
"Eigen vector %s does not equal expected value %s" %
(str(x), str(x0)))
return
def testWsumValues3d(self):
W = self.WT3
assert len(W.nperh()) == len(W.Wsum())
for nperh, Wsum in zip(W.nperh(), W.Wsum()):
deta = 1.0 / nperh
nx = int(W.kernelExtent() * nperh) + 1
testSum = 0.0
for iz in xrange(nx):
etaz = iz * deta
for iy in xrange(nx):
etay = iy * deta
for ix in xrange(nx):
etax = ix * deta
eta = sqrt(etax * etax + etay * etay + etaz * etaz)
delta = W.kernelValue(eta, 1.0)
if ix > 0:
delta *= 2.0
if iy > 0:
delta *= 2.0
if iz > 0:
delta *= 2.0
testSum += delta
self.failUnless(fuzzyEqual(Wsum, testSum, self.Wsumtol),
"Wsum failure: %g != %g: " % (Wsum, testSum))
self.failUnless(
fuzzyEqual(W.equivalentNodesPerSmoothingScale(testSum), nperh,
self.Wsumtol), "Lookup n per h failure: %g %g %g" %
(testSum, W.equivalentNodesPerSmoothingScale(testSum), nperh))
return
def testRotation(self):
R = randomRotationMatrix(self.TensorType.nDimensions)
assert fuzzyEqual(R.Determinant(), 1.0)
check = R*self.lhs*R.Transpose()
self.lhs.rotationalTransform(R)
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
assert fuzzyEqual(self.lhs(row, col), check(row, col))
return
def testDotUnitFull(self):
one = self.FullTensorType.one
resultr = one * self.rhs
resultl = self.lhs * one
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
assert fuzzyEqual(resultl(row, col), self.lhs(row, col))
assert fuzzyEqual(resultr(row, col), self.rhs(row, col))
return
def testInverse(self):
result = self.lhs.Inverse()
check = result*self.lhs
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
if row == col:
assert fuzzyEqual(check(row, col), 1.0)
else:
self.failUnless(fuzzyEqual(check(row, col), 0.0, 1.0e-5),
"Off diagonal not zero: %s" % str(check))
return
def testDoublyDegenerateEigenVectors(self):
for i in xrange(self.ntests):
lam12 = rangen.uniform(-ranrange, ranrange)
A, vlam0, vectors0 = randomSymTensor3d(lam1=lam12, lam2=lam12)
lam0 = [(vlam0(i), vectors0.getColumn(i)) for i in range(3)]
lam0.sort()
eigenVecs0 = [x[1] for x in lam0]
eigenStruct = A.eigenVectors()
lam = [(eigenStruct.eigenValues(i),
eigenStruct.eigenVectors.getColumn(i)) for i in range(3)]
lam.sort()
eigenVecs = [x[1] for x in lam]
for x in eigenVecs:
self.failUnless(
fuzzyEqual(x.magnitude(), 1.0),
"Eigen vector %s does not have unit magnitude %s" %
(str(x), str(eigenStruct.eigenVectors)))
# Identify the unique eigen value.
unique = -1
thpt = 0.0
degenerate = []
if (lam0[0][0] == lam0[1][0]):
unique = 2
degenerate = [0, 1]
thpt = abs(vlam0(2)) / (abs(vlam0(0)) + 1.0e-10)
else:
unique = 0
degenerate = [1, 2]
thpt = abs(vlam0(0)) / (abs(vlam0(1)) + 1.0e-10)
assert thpt > 0.0
if thpt > 1.0:
thpt = 1.0 / thpt
# Does the eigenvector for the unique eigen value match?
self.failUnless(
fuzzyEqual(abs(eigenVecs[unique].dot(eigenVecs0[unique])), 1.0,
degenerateFuzz(unique, [x[0] for x in lam0])),
"Eigen vector %s does not equal expected value %s for eigen values %s, %s"
% (str(eigenVecs[unique]), str(eigenVecs0[unique]), str(vlam0),
str(eigenStruct.eigenValues)))
# The remaining eigen values need only be perpendicular to each other and the unique
# value.
self.failUnless(
fuzzyEqual(eigenVecs[0].dot(eigenVecs[1]), 0.0)
and fuzzyEqual(eigenVecs[0].dot(eigenVecs[2]), 0.0)
and fuzzyEqual(eigenVecs[1].dot(eigenVecs[2]), 0.0),
"Eigen vectors (%s, %s, %s) are not orthogonal\n%s" %
(str(eigenVecs[0]), str(eigenVecs[1]), str(
eigenVecs[2]), str(eigenStruct.eigenValues)))
return
def testScalarDivision(self):
val = 44.0
result = self.lhs / val
assert isinstance(result, self.VectorType)
for i in xrange(self.VectorType.nDimensions):
assert fuzzyEqual(result(i), self.lhs(i) / val)
return
def testSelfDoubleDot(self):
result = self.lhs.selfDoubledot()
check = self.lhs.doubledot(self.lhs)
self.failUnless(
fuzzyEqual(result, check),
"selfDoubledot check failure: %f != %f" % (result, check))
return
def testSquare(self):
result = self.lhs.square()
check = self.lhs * self.lhs
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
self.failUnless(fuzzyEqual(result(row, col), check(row, col)),
"Bad value: (%i,%i), %g != %g" % (row, col, result(row, col), check(row, col)))
def testCuberoot(self):
tol = {1: 1e-5,
2: 1e-5,
3: 5e-4}[self.TensorType.nDimensions]
for t in xrange(nrandom):
st = randomSymmetricMatrix(self.TensorType.nDimensions)
st13 = st.cuberoot()
st13cube = st13*st13*st13
diff = st13cube - st
check = diff.doubledot(diff)
self.failUnless(fuzzyEqual(check, 0.0, tol),
"CUBEROOT failure %s != %s, eigen values=%s, check=%g" % (str(st13cube), str(st),
str(st.eigenValues()), check))
return
## def testPow(self):
## tol = {1: 1e-5,
## 2: 1e-5,
## 3: 1e-3}[self.TensorType.nDimensions]
## for t in xrange(nrandom):
## st = randomSymmetricMatrix(self.TensorType.nDimensions)
## p = abs(rangen.choice([rangen.uniform(-5.0, -0.5), rangen.uniform(0.5, 5.0)]))
## stp = st.pow(p)
## stpi = stp.pow(1.0/p)
## diff = stpi - st
## check = diff.doubledot(diff)
## self.failUnless(fuzzyEqual(check, 0.0, tol),
## "POW failure %s !=\n %s,\n power = %f,\n eigen values=%s\n %s,\n check=%g" % (str(stpi), str(st), p,
## str(stpi.eigenValues()),
## str(st.eigenValues()),
## check))
return
def testClosestPointOnFacets(self):
facets = self.polygon.facets
for f in facets:
p = f.position
cp = self.polygon.closestPoint(p)
self.failUnless(fuzzyEqual((cp - p).magnitude(), 0.0, 1.0e-10),
"Closest point to facet position %s : %s" % (p, cp))
def testMagnitude(self):
result = self.lhs.magnitude()
check = 0.0
for i in xrange(self.VectorType.nDimensions):
check += (self.lhs(i))**2
check = sqrt(check)
assert fuzzyEqual(result, check)
def testSquareElements(self):
result = self.lhs.squareElements()
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
self.failUnless(fuzzyEqual(result(row, col), self.lhs(row, col)**2),
"Square matrix elements failure: %g != %g" % (result(row, col), self.lhs(row, col)**2))
return
def testTriplyDegenerateEigenVectors(self):
for i in xrange(self.ntests):
lam123 = rangen.uniform(-ranrange, ranrange)
A = SymTensor3d(lam123, 0.0, 0.0, 0.0, lam123, 0.0, 0.0, 0.0,
lam123)
vlam0 = Vector3d(lam123, lam123, lam123)
vectors0 = [
Vector3d(1, 0, 0),
Vector3d(0, 1, 0),
Vector3d(0, 0, 1)
]
eigenStruct = A.eigenVectors()
for i in xrange(3):
vec = eigenStruct.eigenVectors.getColumn(i)
match = [
fuzzyEqual(abs(vec.dot(vectors0[j])), 1.0)
for j in xrange(len(vectors0))
]
assert len(match) == len(vectors0)
assert sum(match) == 1
del vectors0[match.index(True)]
self.failUnless(
len(vectors0) == 0,
"Failed triply degenerate eigen vector decomposition: %s %s." %
(str(eigenStruct.eigenVectors), str(lam123)))
return
def testScalarDivision(self):
val = 44.0
result = self.lhs / val
assert isinstance(result, self.TensorType)
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
assert fuzzyEqual(result(row, col), self.lhs(row, col) / val)
return
def testClipInternalTwoPlanes(self):
for points, neighbors, facets in self.polyData:
poly = Polyhedron(points, facets)
PCpoly = PolyClipper.Polyhedron()
PolyClipper.convertToPolyhedron(PCpoly, poly)
for i in xrange(self.ntests):
p0 = Vector(rangen.uniform(0.0, 1.0), rangen.uniform(0.0, 1.0),
rangen.uniform(0.0, 1.0))
norm1 = Vector(rangen.uniform(-1.0, 1.0),
rangen.uniform(-1.0, 1.0),
rangen.uniform(-1.0, 1.0)).unitVector()
norm2 = Vector(rangen.uniform(-1.0, 1.0),
rangen.uniform(-1.0, 1.0),
rangen.uniform(-1.0, 1.0)).unitVector()
planes1 = vector_of_PolyClipperPlane()
planes1.append(PolyClipper.PolyClipperPlane3d(p0, norm1))
planes1.append(PolyClipper.PolyClipperPlane3d(p0, norm2))
planes2 = vector_of_PolyClipperPlane()
planes2.append(PolyClipper.PolyClipperPlane3d(p0, norm1))
planes2.append(PolyClipper.PolyClipperPlane3d(p0, -norm2))
planes3 = vector_of_PolyClipperPlane()
planes3.append(PolyClipper.PolyClipperPlane3d(p0, -norm1))
planes3.append(PolyClipper.PolyClipperPlane3d(p0, norm2))
planes4 = vector_of_PolyClipperPlane()
planes4.append(PolyClipper.PolyClipperPlane3d(p0, -norm1))
planes4.append(PolyClipper.PolyClipperPlane3d(p0, -norm2))
PCchunk1 = PolyClipper.Polyhedron(PCpoly)
PCchunk2 = PolyClipper.Polyhedron(PCpoly)
PCchunk3 = PolyClipper.Polyhedron(PCpoly)
PCchunk4 = PolyClipper.Polyhedron(PCpoly)
PolyClipper.clipPolyhedron(PCchunk1, planes1)
PolyClipper.clipPolyhedron(PCchunk2, planes2)
PolyClipper.clipPolyhedron(PCchunk3, planes3)
PolyClipper.clipPolyhedron(PCchunk4, planes4)
chunk1 = Polyhedron(poly)
chunk2 = Polyhedron(poly)
chunk3 = Polyhedron(poly)
chunk4 = Polyhedron(poly)
PolyClipper.convertFromPolyhedron(chunk1, PCchunk1)
PolyClipper.convertFromPolyhedron(chunk2, PCchunk2)
PolyClipper.convertFromPolyhedron(chunk3, PCchunk3)
PolyClipper.convertFromPolyhedron(chunk4, PCchunk4)
success = fuzzyEqual(
chunk1.volume + chunk2.volume + chunk3.volume +
chunk4.volume, poly.volume)
if not success:
writePolyhedronOBJ(poly, "poly.obj")
writePolyhedronOBJ(chunk1, "chunk_1ONE_TWOPLANES.obj")
writePolyhedronOBJ(chunk2, "chunk_2TWO_TWOPLANES.obj")
writePolyhedronOBJ(chunk3, "chunk_3THREE_TWOPLANES.obj")
writePolyhedronOBJ(chunk4, "chunk_4FOUR_TWOPLANES.obj")
self.failUnless(
success,
"Two plane clipping summing to wrong volumes: %s + %s + %s + %s = %s != %s"
% (chunk1.volume, chunk2.volume, chunk3.volume,
chunk4.volume, chunk1.volume + chunk2.volume +
chunk3.volume + chunk4.volume, poly.volume))
return
def randomSymTensor3d(lam1=None, lam2=None, lam3=None):
if lam1 is None:
lam1 = rangen.uniform(-ranrange, ranrange)
if lam2 is None:
lam2 = rangen.uniform(-ranrange, ranrange)
if lam3 is None:
lam3 = rangen.uniform(-ranrange, ranrange)
# Pick random Euler angles.
theta = rangen.uniform(0.0, 2.0 * pi)
phi = rangen.uniform(0.0, pi)
psi = rangen.uniform(0.0, pi)
# Build the rotation matrix of eigen vectors.
R = Tensor3d(
cos(psi) * cos(phi) - cos(theta) * sin(phi) * sin(psi),
-sin(psi) * cos(phi) - cos(theta) * sin(phi) * cos(psi),
sin(theta) * sin(phi),
cos(psi) * sin(phi) + cos(theta) * cos(phi) * sin(psi),
-sin(psi) * sin(phi) + cos(theta) * cos(phi) * cos(psi),
-sin(theta) * cos(phi),
sin(theta) * sin(psi),
sin(theta) * cos(psi), cos(theta))
assert fuzzyEqual(R.Determinant(), 1.0)
check = R * R.Transpose()
for i in xrange(3):
for j in xrange(3):
if i == j:
assert fuzzyEqual(check(i, j), 1.0)
else:
assert fuzzyEqual(check(i, j), 0.0)
# Check the eigen vectors.
vec1 = R.getColumn(0)
vec2 = R.getColumn(1)
vec3 = R.getColumn(2)
assert fuzzyEqual(vec1.magnitude(), 1.0)
assert fuzzyEqual(vec2.magnitude(), 1.0)
assert fuzzyEqual(vec3.magnitude(), 1.0)
assert fuzzyEqual(vec1.dot(vec2), 0.0)
assert fuzzyEqual(vec3.dot(vec1), 0.0)
assert fuzzyEqual(vec3.dot(vec2), 0.0)
# Now put it all together into our final symmetric matrix.
A = SymTensor3d(lam1, 0.0, 0.0, 0.0, lam2, 0.0, 0.0, 0.0, lam3)
A.rotationalTransform(R)
# Return the tensor, it's eigen values, and the tensor of eigenvectors.
return A, Vector3d(lam1, lam2, lam3), R
def testDoubleDot(self):
result = self.lhs.doubledot(self.rhs)
check = 0
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
check += self.lhs(row, col)*self.rhs(col, row)
self.failUnless(fuzzyEqual(result, check),
"Doubledot check failure: %f != %f" % (result, check))
return
def testClosestPointAboveFacets(self):
facets = self.polygon.facets
for f in facets:
chi = rangen.uniform(0.1, 10.0)
cp0 = f.position
p = cp0 + chi*f.normal
cp = self.polygon.closestPoint(p)
self.failUnless(fuzzyEqual((cp0 - cp).magnitude(), 0.0, 1.0e-10),
"Closest point to position off of facet position %s : %s" % (cp0, cp))
def testVolume(self):
facets = self.polyhedron.facets()
c = self.polyhedron.centroid()
answer = 0.0
for f in facets:
answer += f.area * (f.normal.dot(f.point(0) - c))
answer /= 3.0
self.failUnless(fuzzyEqual(self.polyhedron.volume, answer, 1.0e-10),
"Failed volume computation: %g != %g" % (self.polyhedron.volume,
answer))
def testCube(self):
for t in xrange(nrandom):
st = randomSymmetricMatrix(self.TensorType.nDimensions)
st3 = st.cube()
check = st*st*st
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
self.failUnless(fuzzyEqual(st3(row, col), check(row, col)),
"CUBE failure %s != %s" % (str(st3), str(check)))
return
def testIntersectTouchingBox(self):
xmin = self.polygon.xmin.x
vertex = None
for v in self.polygon.vertices:
if fuzzyEqual(v.x, xmin, 1.0e-10):
vertex = v
assert not vertex is None
box = (Vector(v.x - 2.0, v.y - 2.0), v)
self.failUnless(self.polygon.intersect(box),
"Failed to intersect with a box touching on one side.")
def testOtherTensorMultiplication(self):
result = self.lhs * self.other
assert isinstance(result, self.FullTensorType)
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
check = 0.0
for i in xrange(self.TensorType.nDimensions):
check += self.lhs(row, i) * self.other(i, col)
assert fuzzyEqual(result(row, col), check)
return
def testInPlaceScalarDivision(self):
val = 44.0
result = self.TensorType(self.lhs)
result /= val
assert isinstance(result, self.TensorType)
for row in xrange(self.TensorType.nDimensions):
for col in xrange(self.TensorType.nDimensions):
self.failUnless(fuzzyEqual(result(row, col), self.lhs(row, col) / val),
"Tensor inplace division : %g != %g" % (result(row, col),
self.lhs(row, col) / val))
return
def testWlookup(self):
for W, WT in self.kernelPairs:
deta = W.kernelExtent() / (self.nsamples - 1)
for i in xrange(self.nsamples):
eta = i * deta
self.failUnless(
fuzzyEqual(WT.kernelValue(eta, 1.0),
W.kernelValue(eta, 1.0), self.W0tol),
"TableKernel value does match original within tolerance: %g %g"
% (WT.kernelValue(eta, 1.0), W.kernelValue(eta, 1.0)))
self.failUnless(
fuzzyEqual(WT.gradValue(eta, 1.0), W.gradValue(eta, 1.0),
self.W1tol),
"TableKernel grad value does match original within tolerance: %g %g"
% (WT.gradValue(eta, 1.0), W.gradValue(eta, 1.0)))
self.failUnless(
fuzzyEqual(WT.grad2Value(eta, 1.0), W.grad2Value(eta, 1.0),
self.W2tol),
"TableKernel grad2 value does match original within tolerance: %g %g"
% (WT.grad2Value(eta, 1.0), W.grad2Value(eta, 1.0)))
def testSqrt(self):
tol = {1: 1e-5, 2: 1e-5, 3: 1e-3}[self.TensorType.nDimensions]
for t in xrange(nrandom):
st = randomPositiveSymmetricMatrix(self.TensorType.nDimensions)
st12 = st.sqrt()
st12squared = st12 * st12
diff = st12squared - st
check = diff.doubledot(diff)
self.failUnless(
fuzzyEqual(check, 0.0,
tol), "SQRT failure %s != %s, eigen values=%s, %g" %
(str(st12squared), str(st), str(st.eigenValues()), check))
return
def testRandomEigenValues(self):
for i in xrange(self.ntests):
A, vlam0, vectors0 = randomSymTensor3d()
lam0 = [x for x in vlam0]
lam0.sort()
vlam = A.eigenValues()
lam = [x for x in vlam]
lam.sort()
for (x, x0) in zip(lam, lam0):
self.failUnless(
fuzzyEqual(x, x0, 1e-5),
"Eigen values %s do not equal expected values %s" %
(str(lam), str(lam0)))
return
def testClipInternalTwoPlanes(self):
for points in self.pointSets:
PCpoly = PolyClipperPolygon()
initializePolygon(PCpoly, points, vertexNeighbors(points))
poly = Polygon(points, facets(points))
for i in xrange(self.ntests):
p0 = Vector(rangen.uniform(0.0, 1.0), rangen.uniform(0.0, 1.0))
norm1 = Vector(rangen.uniform(-1.0, 1.0),
rangen.uniform(-1.0, 1.0)).unitVector()
norm2 = Vector(rangen.uniform(-1.0, 1.0),
rangen.uniform(-1.0, 1.0)).unitVector()
planes1 = []
planes1.append(PolyClipperPlane2d(p0, norm1))
planes1.append(PolyClipperPlane2d(p0, norm2))
planes2 = []
planes2.append(PolyClipperPlane2d(p0, norm1))
planes2.append(PolyClipperPlane2d(p0, -norm2))
planes3 = []
planes3.append(PolyClipperPlane2d(p0, -norm1))
planes3.append(PolyClipperPlane2d(p0, norm2))
planes4 = []
planes4.append(PolyClipperPlane2d(p0, -norm1))
planes4.append(PolyClipperPlane2d(p0, -norm2))
PCchunk1 = PolyClipperPolygon(PCpoly)
PCchunk2 = PolyClipperPolygon(PCpoly)
PCchunk3 = PolyClipperPolygon(PCpoly)
PCchunk4 = PolyClipperPolygon(PCpoly)
clipPolygon(PCchunk1, planes1)
clipPolygon(PCchunk2, planes2)
clipPolygon(PCchunk3, planes3)
clipPolygon(PCchunk4, planes4)
chunk1, clips = convertFromPolyClipper(PCchunk1)
chunk2, clips = convertFromPolyClipper(PCchunk2)
chunk3, clips = convertFromPolyClipper(PCchunk3)
chunk4, clips = convertFromPolyClipper(PCchunk4)
success = fuzzyEqual(
chunk1.volume + chunk2.volume + chunk3.volume +
chunk4.volume, poly.volume)
if not success:
writePolyhedronOBJ(poly, "poly.obj")
writePolyhedronOBJ(chunk1, "chunk_1ONE_TWOPLANES.obj")
writePolyhedronOBJ(chunk2, "chunk_2TWO_TWOPLANES.obj")
writePolyhedronOBJ(chunk3, "chunk_3THREE_TWOPLANES.obj")
writePolyhedronOBJ(chunk4, "chunk_4FOUR_TWOPLANES.obj")
self.failUnless(
success,
"Two plane clipping summing to wrong volumes: %s + %s + %s + %s = %s != %s"
% (chunk1.volume, chunk2.volume, chunk3.volume,
chunk4.volume, chunk1.volume + chunk2.volume +
chunk3.volume + chunk4.volume, poly.volume))
def testVolume(self):
verts0 = self.polygon.vertices
c = self.polygon.centroid
cmpmethod = SortCounterClockwise(c)
verts = sorted(list(verts0), cmpmethod)
p0 = verts[0]
answer = 0.0
for i in xrange(2, len(verts)):
answer += (verts[i] - p0).cross(verts[i - 1] - p0).z
answer *= 0.5
vertstring = [str(x) for x in verts]
self.failUnless(fuzzyEqual(self.polygon.volume, answer, 1.0e-10),
"Failed volume computation: %g != %g\n verts = %s" % (self.polygon.volume,
answer,
vertstring))
def testBoundingSurface(self):
mesh, void = generateLineMesh([self.nodes],
xmin=xmin,
xmax=xmax,
generateParallelConnectivity=True)
bs = mesh.boundingSurface()
assert fuzzyEqual(bs.xmin.x, x0, 1.0e-10)
assert fuzzyEqual(bs.xmax.x, x1, 1.0e-10)
# Check that all the generators are contained.
pos = self.nodes.positions()
for i in xrange(self.nodes.numInternalNodes):
self.failUnless(
bs.contains(pos[i]),
"Failed containment for generator %i @ %s" % (i, pos[i]))
# Check that all mesh nodes are contained.
for i in xrange(mesh.numNodes):
self.failUnless(
bs.contains(mesh.node(i).position),
"Failed containment for mesh node %i @ %s" %
(i, mesh.node(i).position))
return
