def plot_modes(files,acoef_file,quantity,quantity_replace,pic_dir="./",fc=fc_default):
f = open(acoef_file)
data = [[float(num) for num in line.split()] for line in f]
f.close
data = np.asarray(data)
amin = np.amin(data)
amax = np.amax(data)
print("min(a_coef):", amin)
print("max(a_coef):", amax)
for mode,file in enumerate(files):
plt_file = file.split("/")[-1]
plt_file = plt_file.replace(quantity+"_",quantity_replace+"_")
plt_file = plt_file.replace('h5','png')
fig = plt.figure(44)
fig.subplots_adjust(wspace=0.05,hspace=0.0)
gs1 = gs.GridSpec(nrows=6,ncols=2)
ax1 = plt.subplot(gs1[:5,0])
ax,cb,hplot = wt.plot_wabbit_file(file,cmap=fc,caxis_symmetric=True,dpi=600, \
shading='flat', \
block_edge_alpha=0.1, \
title=False, ticks=False, colorbar=False, fig=fig, ax=ax1)
ax.set_title("$\Psi_{"+str(mode+1)+"}^\epsilon(x,y)$")
# ax.set_xlabel("$x$")
#ax.set_ylabel("$y$")y
ax2 = plt.subplot(gs1[5:,0])
########################
# Do the actual plotting
#######################
ax2.plot(data[:,mode], linestyle='-',marker = ".", mfc='none', markersize=5)
ax2.set_xlabel("$i$")
ax2.set_ylabel("$a^\epsilon_{"+str(mode+1)+"}(t_i)$")
ax2.yaxis.tick_right()
ax2.set_ylim([amin,amax])
# Add the colorbar outside...
pad, width = 0.02, 0.02
fig.subplots_adjust(bottom=0.2,top=0.9)
cax = plt.subplot(gs1[:5,1])
box = ax1.get_position()
fig.colorbar(hplot, cax=cax)
cax.set_position([cax.get_position().xmin, box.ymin, width , box.height])
cax.axis('tight')
#cb.set_label("vorticity [1/s]")
print("Saving plot to: "+pic_dir+plt_file)
plt.savefig( pic_dir+plt_file, dpi=600, transparent=True, bbox_inches='tight' )
plt.show()
case = "CDF44_dealias_pacman"
#case = "CDF44_pacman"
ini = "pacman.ini"
eps_dir = "./adaptive_" + case + "_Bs17_Jmax7*eps1.0e-04_iter1/"
norm = 2
# %%
files = glob.glob(eps_dir + '/' + quantity + '*.h5')
files.sort()
for file in files:
plt_file = file.replace('h5', 'png')
if (os.path.isfile(plt_file)):
continue
fig, ax = plt.subplots()
ax,cb,hplot = wt.plot_wabbit_file(file,cmap ='bwr', dpi=300, \
shading='gouraud', caxis=[0,1],block_edge_color='w', \
block_edge_alpha=0.7, block_linewidth=0.9 ,colorbar_orientation="vertical", \
title=False, ticks=False, colorbar=True)
#ax.set_title("$\epsilon="+str(eps_list[i])+"$")
# ax.set_xlabel("$x$")
#ax.set_ylabel("$y$")
ax.set_aspect('equal')
#cb.set_label("vorticity [1/s]")
print("Saving plot to: " + plt_file)
plt.savefig(plt_file, dpi=300, transparent=True, bbox_inches='tight')
plt.show()
#tikzplotlib.clean_figure()
#tikzplotlib.save(plt_file)
##############################################################################
# %% eps vs err
files.sort()
if cmap is 'jet':
fc = 'jet'
else:
fc = farge_colormaps.farge_colormap_multi(taille=600,
limite_faible_fort=0.2,
etalement_du_zero=0.04,
type=cmap)
for file, i in zip(files[1:], range(len(files[1:]))):
wabbit_tools.plot_wabbit_file(file,
savepng=True,
cmap=fc,
ticks=False,
colorbar=True,
dpi=300,
title=True,
block_edge_color='w',
caxis_symmetric=True,
shading='gouraud')
#%% flusi cylinder
#for prefix, cmap in zip(['vorx','p','uy','uz','mask'],['vorticity','pressure','velocity','velocity','streamfunction']):
# fname = '/home/engels/dev/FLUSI/cyl/'+prefix+'_001500.h5'
#
# plt.gcf().clf()
#
# # read data
# time, box, origin, data = insect_tools.read_flusi_HDF5(fname)
#
# # colormap
def plot_vector_modes(files,acoef_file,quantity,quantity_replace,pic_dir="./",fc=fc_default, mode_names=None):
f = open(acoef_file)
data = [[float(num) for num in line.split()] for line in f]
f.close
data = np.asarray(data)
amin = np.amin(data)
amax = np.amax(data)
print("min(a_coef):", amin)
print("max(a_coef):", amax)
Ncomponents=len(files)
Nmodes = len(files[0])
mode_ax=[]
for n_mode in range(Nmodes):
fig = plt.figure(n_mode)
fig.subplots_adjust(wspace=0.05,hspace=0.05)
for k in range(Ncomponents):
file = files[k][n_mode]
plt_file = file.split("/")[-1]
plt_file = plt_file.replace(quantity+"_",quantity_replace+"_")
plt_file = plt_file.replace('h5','png')
gs1 = gs.GridSpec(nrows=Ncomponents+1,ncols=1)
ax1 = plt.subplot(gs1[k,0])
ax,cb,hplot = wt.plot_wabbit_file(file,cmap=fc,caxis_symmetric=True,dpi=600, \
shading='flat', block_linewidth=0.25, \
block_edge_alpha=0.4, block_edge_color='k', \
title=False, ticks=False, colorbar=False, fig=fig, ax=ax1)
if k==0:
ax.set_title("$\Psi_{"+str(n_mode+1)+"}^\epsilon(x,y)$")
if mode_names is not None:
ax1.set_ylabel(mode_names[k])
# ax.set_xlabel("$x$")
#ax.set_ylabel("$y$")y
mode_ax.append(ax1)
axins1 = inset_axes(ax1,
width="2%", # width = 50% of parent_bbox width
height="80%", # height : 5%
loc='right',
bbox_to_anchor=(0.03, 0., 1, 1),
bbox_transform=ax1.transAxes,
borderpad=0)
fig.colorbar(hplot, cax=axins1, orientation="vertical")
# for k,ax1 in enumerate(mode_ax):
# pad, width = 0.02, 0.02
# fig.subplots_adjust(bottom=0.2,top=0.9)
# fig.canvas.draw()
# cax = plt.subplot(gs1[np.mod(k,1),1])
# box = ax1.get_position()
# cax.set_position([cax.get_position().xmin, box.ymin, 0.01 , box.height])
# cax.axis('tight')
# fig.colorbar(hplot, cax=cax)
ax2 = plt.subplot(gs1[Ncomponents,0])
########################
# Do the actual plotting
#######################
ax2.plot(data[:,n_mode], linestyle='-',marker = ".", mfc='none', markersize=5)
ax2.set_xlabel("$i$")
ax2.set_ylabel("$a^\epsilon_{"+str(n_mode+1)+"}(t_i)$")
ax2.yaxis.tick_right()
ylim=1.2*np.max(np.abs(ax2.get_ylim()))
ax2.set_ylim([-ylim,ylim])
# Add the colorbar outside...
#cb.set_label("vorticity [1/s]")
print("Saving plot to: "+pic_dir+plt_file)
plt.savefig( pic_dir+plt_file, dpi=600, transparent=True, bbox_inches='tight' )
plt.show()
###############################################################################
# %% get the data
quantity = "vorx-sparse"
plt.close("all")
for i, eps_dir in enumerate(eps_dir_list[::5]):
files = glob.glob(eps_dir + '/' + quantity + '_*.h5')
files.sort()
for file in files:
plt_file = file.split("/")[-1]
plt_file = plt_file.replace(quantity + "_",
quantity + "-" + eps_dir_list[i] + "_")
plt_file = plt_file.replace('h5', 'png')
fig, ax = plt.subplots()
ax,cb = wt.plot_wabbit_file(file,cmap=fc,caxis_symmetric=True,dpi=300, \
shading='gouraud',caxis=[-10,10], \
block_edge_alpha=0.2,colorbar_orientation="horizontal", \
title=False, ticks=False, colorbar=True)
ax.set_title("$\epsilon=" + str(eps_list[i]) + "$")
# ax.set_xlabel("$x$")
#ax.set_ylabel("$y$")
ax.set_aspect('equal')
#cb.set_label("vorticity [1/s]")
print("Saving plot to: " + pic_dir + plt_file)
plt.savefig(pic_dir + plt_file,
dpi=300,
transparent=True,
bbox_inches='tight')
plt.show()
exit
def wabbit_adapt(dirs, params, wabbit_setup):
mpicommand = wabbit_setup["mpicommand"]
memory = wabbit_setup["memory"]
wdir = dirs["wabbit"]
work = dirs["work"]
jmax_list = params.jmax_list
# set initial gird
dim = len(params.domain.L)
x = [np.linspace(0,params.domain.L[d],params.domain.N[d]) \
for d in range(dim) ]
X = np.meshgrid(*x)
phi = params.init(X, params.domain.L)
Bs = wt.field_shape_to_bs(params.domain.N, jmax_list[-1])
# create reference file
file_ref = wt.dense_to_wabbit_hdf5(phi, work + "/phi", Bs, params.domain.L,
0)
params.Bs_list = []
l2error = np.zeros([len(params.jmax_list), len(params.eps_list)])
linferror = np.zeros_like(l2error)
compress = np.zeros_like(l2error)
for j, jmax in enumerate(params.jmax_list):
Bs = wt.field_shape_to_bs(params.domain.N, jmax)
params.Bs_list.append(Bs)
# adapt field for different eps using wabbit-post -dense-to-sparse
print(
"\n\n###################################################################"
)
print(
"###################################################################"
)
print("\t\tJmax: ", jmax, "\n\n")
for k, eps in enumerate(params.eps_list):
# create dense field and save to work
fname = "phi-j" + str(jmax) + "-eps"
file = work + "/" + fname
file = wt.dense_to_wabbit_hdf5(phi, file, Bs, params.domain.L,
eps * 100)
command = mpicommand + " " + wdir + \
"wabbit-post --dense-to-sparse --eps=" + str(eps) + " --order=CDF44 --eps-norm=Linfty " + memory + \
" --files="+ file + ">adapt.log"
# command for densing file again
dense_command = mpicommand + " " + wdir + \
"wabbit-post --sparse-to-dense " + \
" "+ file + " "+file + ">>adapt.log"
# -----------------------------
# Execute Command
# -----------------------------
print(
"\n\n###################################################################"
)
print("\t\teps =", eps)
print(
"###################################################################"
)
print("\n", command, "\n\n")
success = os.system(command) # execute command
if np.mod(k, 4) == 0:
wt.plot_wabbit_file(file, savepng=True)
compress[j, k] = sum(wt.block_level_distribution_file(file))
print("\n", dense_command, "\n\n")
success += os.system(
dense_command) # dense the file for comparison to original
if success != 0:
print("command did not execute successfully")
return
# ---------------------------
# compare to original file
# --------------------------
l2error[j, k] = wt.wabbit_error_vs_wabbit(file_ref,
file,
norm=2,
dim=2)
linferror[j, k] = wt.wabbit_error_vs_wabbit(file_ref,
file,
norm=np.inf,
dim=2)
compress[j, k] /= sum(wt.block_level_distribution_file(file))
# delete file
os.system("rm " + file)
# delete reference file
os.system("rm " + file_ref)
return l2error, linferror, compress
