def coarsen_quad(self, plot=True):
cell = np.array([[0, 1, 2, 3], [1, 4, 5, 2]], dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = QuadrangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
NE = mesh.ds.NE
color = 3 * np.ones(NE * 2, dtype=np.int_)
color[1] = 1
while (color == 3).any():
red = color == 1
gre = color == 0
color[halfedge[red][:, [2, 3, 4]]] = 0
color[halfedge[gre][:, [2, 3, 4]]] = 1
colorlevel = ((color == 1) | (color == 2)).astype(np.int_)
mesh.hedgecolor = {'color': color, 'level': colorlevel}
for i in range(1):
NC = mesh.number_of_all_cells()
isMarkedCell = np.ones(NC, dtype=np.bool_)
mesh.refine_quad(isMarkedCell)
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[[3, 5, 7, 8]] = True
#isMarkedCell[[1, 3, 12,18, 20, 17, 16, 9, 7, 2, 4,6, 7, 8, 9 , 27, 15,
# 8, 23, 32, 5, 24, 16, 29, 4, 7, 28, 11, 14, 22, 31, 19]] = True
mesh.coarsen_quad(isMarkedCell)
print(np.c_[np.arange(len(mesh.ds.halfedge)), mesh.ds.halfedge])
if 0:
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[[
20, 21, 23, 22, 18, 24, 26, 11, 1, 7, 13, 3, 8, 15, 12, 17
]] = True
mesh.coarsen_quad(isMarkedCell)
for i in range(0):
print(i, '*************************************************')
NC = mesh.number_of_all_cells()
isMarkedCell = np.ones(NC, dtype=np.bool_)
mesh.refine_quad(isMarkedCell)
print(np.where(mesh.hedgecolor['color'] == 2))
#print(np.c_[np.arange(mesh.ds.NE*2), mesh.hedgecolor['color'],
# mesh.hedgecolor['level']])
#print(np.c_[np.arange(mesh.ds.NE*2), mesh.halfedgedata['level']])
if plot:
fig = plt.figure()
axes = fig.gca()
mesh.add_plot(axes)
mesh.add_halfedge_plot(axes, showindex=True)
mesh.find_node(axes, showindex=True)
mesh.find_cell(axes, showindex=True)
plt.show()
def refine_quad(self, l, plot=True):
cell = np.array([[0, 1, 2, 3], [1, 4, 5, 2]], dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = QuadrangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
NE = mesh.ds.NE
color = 3 * np.ones(NE * 2, dtype=np.int_)
color[1] = 1
while (color == 3).any():
red = color == 1
gre = color == 0
color[halfedge[red][:, [2, 3, 4]]] = 0
color[halfedge[gre][:, [2, 3, 4]]] = 1
colorlevel = ((color == 1) | (color == 2)).astype(np.int_)
mesh.hedgecolor = {'color': color, 'level': colorlevel}
c = np.array([1, 10000.5])
r = 10000
h = 1e-2
k = 0
NB = 0
fig = plt.figure()
axes = fig.gca()
plt.ion()
while k < l:
halfedge = mesh.ds.halfedge
halfedge1 = halfedge[:, 3]
node = mesh.node
flag = node - c
flag = flag[:, 0]**2 + flag[:, 1]**2
flag = flag <= r**2
flag1 = flag[halfedge[:, 0]].astype(int)
flag2 = flag[halfedge[halfedge1, 0]].astype(int)
markedge = flag1 + flag2 == 1
markedcell = halfedge[markedge, 1]
markedcell = np.unique(markedcell)
cell = np.unique(halfedge[:, 1])
nc = cell.shape[0]
markedcell1 = np.zeros(nc)
markedcell1[markedcell] = 1
print('makee', markedcell)
mesh.refine_quad(markedcell1.astype(np.bool_))
k += 1
print('循环', k, '次***************************')
print(np.c_[np.arange(mesh.ds.NE * 2), mesh.hedgecolor['color'],
mesh.hedgecolor['level']])
if plot:
plt.cla()
mesh.add_plot(axes)
plt.pause(0.001)
plt.ioff()
plt.show()
def refine_quad(self, plot=True):
cell = np.array([[0, 1, 2, 3], [1, 4, 5, 2]], dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = QuadrangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
halfedge = mesh.ds.halfedge
NE = mesh.ds.NE
color = 3 * np.ones(NE * 2, dtype=np.int_)
color[1] = 1
while (color == 3).any():
red = color == 1
gre = color == 0
color[halfedge[red][:, [2, 3, 4]]] = 0
color[halfedge[gre][:, [2, 3, 4]]] = 1
mesh.hedgecolor = color
c = np.array([0.8, 0.8])
r = 0.9
h = 1e-2
l = 10
k = 0
NB = 0
while k < l:
halfedge = mesh.ds.halfedge
halfedge1 = halfedge[:, 3]
node = mesh.node
flag = node - c
flag = flag[:, 0]**2 + flag[:, 1]**2
flag = flag <= r**2
flag1 = flag[halfedge[:, 0]].astype(int)
flag2 = flag[halfedge[halfedge1, 0]].astype(int)
markedge = flag1 + flag2 == 1
markedcell = halfedge[markedge, 1]
markedcell = np.unique(markedcell)
cell = np.unique(halfedge[:, 1])
nc = cell.shape[0]
markedcell1 = np.zeros(nc)
markedcell1[markedcell] = 1
print('makee', markedcell)
mesh.refine_quad(markedcell1.astype(np.bool_))
k += 1
print('循环', k, '次***************************')
if plot:
fig = plt.figure()
axes = fig.gca()
nindex = mesh.nodedata['level']
mesh.add_plot(axes)
#mesh.add_halfedge_plot(axes, showindex=True)
#mesh.find_node(axes, showindex=True, multiindex=nindex)
plt.show()
def quadMesh(self):
cell = np.array([[0, 1, 2, 3], [1, 4, 5, 2]], dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = QuadrangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
NE = mesh.ds.NE
color = 3 * np.ones(NE * 2, dtype=np.int_)
color[1] = 1
while (color == 3).any():
red = color == 1
gre = color == 0
color[halfedge[red][:, [2, 3, 4]]] = 0
color[halfedge[gre][:, [2, 3, 4]]] = 1
colorlevel = ((color == 1) | (color == 2)).astype(np.int_)
mesh.hedgecolor = {'color': color, 'level': colorlevel}
return mesh
def animation_plot(self, method='quad', plot=True):
if method == 'quad':
cell = np.array([[0, 1, 2, 3], [1, 4, 5, 2]], dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = QuadrangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
NE = mesh.ds.NE
color = 3 * np.ones(NE * 2, dtype=np.int_)
color[1] = 1
while (color == 3).any():
red = color == 1
gre = color == 0
color[halfedge[red][:, [2, 3, 4]]] = 0
color[halfedge[gre][:, [2, 3, 4]]] = 1
colorlevel = ((color == 1) | (color == 2)).astype(np.int_)
mesh.hedgecolor = {'color': color, 'level': colorlevel}
mesh.ds.NV = 4
elif method == 'rg':
cell = np.array([[0, 1, 2], [0, 2, 3], [1, 4, 5], [2, 1, 5]],
dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = TriangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
NE = mesh.ds.NE
color = np.zeros(NE * 2, dtype=np.int_)
mesh.hedgecolor = color
#mesh.ds.NV = 3
elif method == 'nvb':
cell = np.array([[0, 1, 2], [0, 2, 3], [1, 4, 5], [2, 1, 5]],
dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = TriangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
NE = mesh.ds.NE
color = np.zeros(NE * 2, dtype=np.int_)
color[[2, 3, 10, 11]] = 1
mesh.hedgecolor = color
elif method == 'poly':
node = np.array([
(0.0, 0.0),
(0.0, 1.0),
(1.0, 0.0),
(1.0, 1.0),
],
dtype=np.float)
cell = np.array([0, 2, 3, 0, 3, 1], dtype=np.int)
cellLocation = np.array([0, 3, 6], dtype=np.int)
mesh = PolygonMesh(node, cell, cellLocation)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
r = 0.5
h = 1e-2
k = 0
N = 19
fig = plt.figure()
axes = fig.gca()
plt.ion()
for i in range(N):
c = np.array([i * (2 / N), 0.8])
k = 0
sta1 = time.time()
while True:
halfedge = mesh.ds.halfedge
pre = halfedge[:, 3]
node = mesh.entity('node')
flag = np.linalg.norm(node - c, axis=1) < r
flag1 = flag[halfedge[:, 0]].astype(int)
flag2 = flag[halfedge[pre, 0]].astype(int)
isMarkedHEdge = flag1 + flag2 == 1
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[halfedge[isMarkedHEdge, 1]] = True
isMarkedCell[cstart:] = isMarkedCell[cstart:] & (
mesh.cell_area() > h**2)
if (~isMarkedCell[cstart:]).all():
break
if method == 'quad':
mesh.refine_quad(isMarkedCell)
elif method == 'rg':
mesh.refine_triangle_rg(isMarkedCell)
elif method == 'nvb':
mesh.refine_triangle_nvb(isMarkedCell)
elif method == 'poly':
mesh.refine_poly(isMarkedCell)
k += 1
print('加密', k, i, '次***************************')
k = 0
sta2 = time.time()
aa = 2 * i
bb = 2 * i + 1
plt.cla()
mesh.add_plot(axes, linewidths=0.4)
#fig.savefig('%f.png' %aa, dpi=600, bbox_inches='tight')
plt.pause(0.01)
while k < 10:
halfedge = mesh.ds.halfedge
pre = halfedge[:, 3]
node = mesh.entity('node')
flag = np.linalg.norm(node - c, axis=1) < r
flag1 = flag[halfedge[:, 0]].astype(int)
flag2 = flag[halfedge[pre, 0]].astype(int)
isMarkedHEdge = flag1 + flag2 == 1
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[halfedge[isMarkedHEdge, 1]] = True
isMarkedCell[cstart:] = ~isMarkedCell[cstart:] & (
mesh.cell_area() < 0.5)
if method == 'quad':
mesh.coarsen_quad(isMarkedCell)
elif method == 'rg':
mesh.coarsen_triangle_rg(isMarkedCell)
elif method == 'nvb':
mesh.coarsen_triangle_nvb(isMarkedCell)
elif method == 'poly':
mesh.coarsen_poly(isMarkedCell)
if (~isMarkedCell).all():
break
k += 1
print('循环', k, '次***************************')
plt.cla()
mesh.add_plot(axes, linewidths=0.4)
#fig.savefig('%f.png' %bb, dpi=600, bbox_inches='tight')
sta3 = time.time()
plt.pause(0.01)
print('加密时间:', sta2 - sta1)
print('粗化时间:', sta3 - sta2)
plt.ioff()
plt.show()
def animation_plot(self, method='quad', plot=True):
if method == 'quad':
cell = np.array([[0, 1, 2, 3], [1, 4, 5, 2]], dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = QuadrangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
NE = mesh.ds.NE
color = 3 * np.ones(NE * 2, dtype=np.int_)
color[1] = 1
while (color == 3).any():
red = color == 1
gre = color == 0
color[halfedge[red][:, [2, 3, 4]]] = 0
color[halfedge[gre][:, [2, 3, 4]]] = 1
colorlevel = ((color == 1) | (color == 2)).astype(np.int_)
mesh.hedgecolor = {'color': color, 'level': colorlevel}
elif method == 'rg':
cell = np.array([[0, 1, 2], [0, 2, 3], [1, 4, 5], [2, 1, 5]],
dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = TriangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
NE = mesh.ds.NE
color = np.zeros(NE * 2, dtype=np.int_)
mesh.hedgecolor = color
elif method == 'nvb':
cell = np.array([[0, 1, 2], [0, 2, 3], [1, 4, 5], [2, 1, 5]],
dtype=np.int)
node = np.array([[0, 0], [1, 0], [1, 1], [0, 1], [2, 0], [2, 1]],
dtype=np.float)
mesh = TriangleMesh(node, cell)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
NE = mesh.ds.NE
color = np.zeros(NE * 2, dtype=np.int_)
color[[2, 3, 10, 11]] = 1
mesh.hedgecolor = color
elif method == 'poly':
node = np.array([
(0.0, 0.0),
(0.0, 1.0),
(1.0, 0.0),
(1.0, 1.0),
],
dtype=np.float)
cell = np.array([0, 2, 3, 0, 3, 1], dtype=np.int)
cellLocation = np.array([0, 3, 6], dtype=np.int)
mesh = PolygonMesh(node, cell, cellLocation)
mesh = HalfEdgeMesh2d.from_mesh(mesh)
mesh.init_level_info()
halfedge = mesh.ds.halfedge
cstart = mesh.ds.cellstart
r = 0.5
h = 1e-2
k = 0
N = 30
fig = plt.figure()
axes = fig.gca()
plt.ion()
for i in range(N):
c = np.array([i * (2 / N), 0.8])
k = 0
sta1 = time.time()
while True:
halfedge = mesh.ds.halfedge
pre = halfedge[:, 3]
node = mesh.entity('node')
flag = np.linalg.norm(node - c, axis=1) < r
flag1 = flag[halfedge[:, 0]].astype(int)
flag2 = flag[halfedge[pre, 0]].astype(int)
isMarkedHEdge = flag1 + flag2 == 1
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[halfedge[isMarkedHEdge, 1]] = True
isMarkedCell[cstart:] = isMarkedCell[cstart:] & (
mesh.cell_area() > h**2)
if (~isMarkedCell[cstart:]).all():
break
if method == 'quad':
mesh.refine_quad(isMarkedCell)
elif method == 'rg':
mesh.refine_triangle_rg(isMarkedCell)
elif method == 'nvb':
mesh.refine_triangle_nvb(isMarkedCell)
elif method == 'poly':
mesh.refine_poly(isMarkedCell)
k += 1
print('加密', k, i, '次***************************')
k = 0
sta2 = time.time()
while k < 10:
halfedge = mesh.ds.halfedge
pre = halfedge[:, 3]
node = mesh.entity('node')
flag = np.linalg.norm(node - c, axis=1) < r
flag1 = flag[halfedge[:, 0]].astype(int)
flag2 = flag[halfedge[pre, 0]].astype(int)
isMarkedHEdge = flag1 + flag2 == 1
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[halfedge[isMarkedHEdge, 1]] = True
isMarkedCell[cstart:] = ~isMarkedCell[cstart:] & (
mesh.cell_area() < 0.5)
if method == 'quad':
mesh.coarsen_quad(isMarkedCell)
elif method == 'rg':
mesh.coarsen_triangle_rg(isMarkedCell, i=i)
elif method == 'nvb':
mesh.coarsen_triangle_nvb(isMarkedCell)
elif method == 'poly':
mesh.coarsen_poly(isMarkedCell)
if (~isMarkedCell).all():
break
k += 1
print('循环', k, '次***************************')
sta3 = time.time()
print('加密时间:', sta2 - sta1)
print('粗化时间:', sta3 - sta2)
if 1:
plt.cla()
mesh.add_plot(axes)
#mesh.find_node(axes, showindex = True)
#mesh.find_cell(axes, showindex = True)
#mesh.add_halfedge_plot(axes, showindex=True)
plt.pause(0.001)
if i == 10000:
break
plt.ioff()
plt.show()
if 0:
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[[20, 23, 19, 16, 4, 5, 6, 7, 24, 15]] = True
print('*************lll*********')
mesh.coarsen_poly(isMarkedCell)
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[[1, 2, 3, 20, 10, 11, 13, 16]] = True
print('*************lll*********')
mesh.coarsen_poly(isMarkedCell)
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[[1, 5, 13, 15]] = True
print('*************lll*********')
mesh.coarsen_poly(isMarkedCell)
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[[10, 11, 12]] = True
print('*************lll*********')
mesh.coarsen_poly(isMarkedCell)
NC = mesh.number_of_all_cells()
isMarkedCell = np.zeros(NC, dtype=np.bool_)
isMarkedCell[[4, 5, 6, 7]] = True
print('*************lll*********')
mesh.coarsen_poly(isMarkedCell)
#mesh.print()
#print(mesh.ds.edge_to_cell())
print(np.c_[np.arange(len(halfedge)), halfedge])
print(
np.where(
halfedge[halfedge[:, 2], 3] != np.arange(len(halfedge))))
fig = plt.figure()
axes = fig.gca()
mesh.add_plot(axes)
mesh.find_node(axes, showindex=True)
mesh.find_cell(axes, showindex=True)
mesh.add_halfedge_plot(axes, showindex=True)
plt.show()
