def stellar_wind(wdir, number):
import pyPLUTO as pp
pp.nlast_info(w_dir=wdir)
D = pp.pload(number, w_dir=wdir)
print(D.rho.shape)
rho = D.rho
vx1 = D.vx1
vx2 = D.vx2
rho = np.transpose(rho)
vx1 = np.transpose(vx1)
vx2 = np.transpose(vx2)
return rho, vx1, vx2
def stellar_wind(wdir,number):
import pyPLUTO as pp
pp.nlast_info(w_dir=wdir)
D = pp.pload(number,w_dir=wdir)
print(D.rho.shape)
rho = D.rho
vx1 = D.vx1
vx2 = D.vx2
rho = np.transpose(rho)
vx1 = np.transpose(vx1)
vx2 = np.transpose(vx2)
return rho,vx1,vx2
def stellar_wind(pcdata,width,rho_constant,wdir,number,r):
import pyPLUTO as pp
nlinf = pp.nlast_info(w_dir=wdir)
D = pp.pload(number,w_dir=wdir)
print(D.rho.shape)
for i in range(width):
for j in range(width):
if (i-256)**2+(j-256)**2<r**2:
pcdata[i,j] = D.rho[i,j]
return pcdata
def stellar_wind(pcdata, width, rho_constant, wdir, number, r):
import pyPLUTO as pp
nlinf = pp.nlast_info(w_dir=wdir)
D = pp.pload(number, w_dir=wdir)
print(D.rho.shape)
for i in range(width):
for j in range(width):
if (i - 256)**2 + (j - 256)**2 < r**2:
pcdata[i, j] = D.rho[i, j]
return pcdata
def stellar_wind(wdir, number):
import pyPLUTO as pp
pp.nlast_info(w_dir=wdir)
D = pp.pload(number, w_dir=wdir)
print(D.rho.shape)
rho = D.rho
bx1 = D.bx1
bx2 = D.bx2
bx3 = D.bx3
vx1 = D.vx1
vx2 = D.vx2
vx3 = D.vx3
rho = np.transpose(rho)
bx1 = np.transpose(bx1)
bx2 = np.transpose(bx2)
bx3 = np.transpose(bx3)
vx1 = np.transpose(vx1)
vx2 = np.transpose(vx2)
vx3 = np.transpose(vx3)
return rho, bx1, bx2, bx3, vx1, vx2, vx3
def stellar_wind(wdir,number):
import pyPLUTO as pp
pp.nlast_info(w_dir=wdir)
D = pp.pload(number,w_dir=wdir)
print(D.rho.shape)
rho = D.rho
bx1 = D.bx1
bx2 = D.bx2
bx3 = D.bx3
vx1 = D.vx1
vx2 = D.vx2
vx3 = D.vx3
rho = np.transpose(rho)
bx1 = np.transpose(bx1)
bx2 = np.transpose(bx2)
bx3 = np.transpose(bx3)
vx1 = np.transpose(vx1)
vx2 = np.transpose(vx2)
vx3 = np.transpose(vx3)
return rho,bx1,bx2,bx3,vx1,vx2,vx3
def plot_jet():
set_pretty()
nlinf = pp.nlast_info()
D = pp.pload(nlinf['nlast'])
I = pp.Image()
I.pldisplay(D, D.rho,x1=D.x1,x2=D.x2,label1='$x$',label2='$y$',
title=r'Density $\rho$ [MHD jet]',cbar=(True,'vertical'),figsize=[7,12])
print (I.pldisplay.__doc__)
# Code to plot field lines. Requires 2 arrays xarr and yarr as
# the starting point of integration i.e. x and y co-ordinate of the field point.
I.myfieldlines(D,linspace(D.x1.min(),D.x1.max(),10),linspace(D.x2.min(),D.x2.min(),10),
colors='w',ls='-',lw=1.5)
savefig('jet_final.png') # Only to be saved as either .png or .jpg
def cf(temperature,plot=False):
'''
calculate cooling function lambda(T)
temperature(K), return(erg cm^-3 s^-1)
array input is accessible
'''
cooling = np.loadtxt('cooling.dat')
if plot:
plt.loglog(cooling[:,0],cooling[:,1])
plt.loglog(temperature,np.interp(temperature, cooling[:,0],cooling[:,1]),'o')
return np.interp(temperature, cooling[:,0],cooling[:,1])
wdir = './'
nlinf = pp.nlast_info(w_dir=wdir)
#D = pp.pload(nlinf['nlast'],w_dir=wdir) # Loading the data into a pload object D
D = pp.pload(2,w_dir=wdir)
T= (D.prs*un.Ba/(D.rho*un.cm**-3)/con.k_B*1.67e-6).to('K')
print cf(T.value).shape
#f=open('rho.txt','r+')
#temp=f.read()
#temp=
#imshow(T.value)
I = pp.Image()
I.pldisplay(D, cf(T.value),x1=D.x1,x2=D.x2,label1='x',label2='y',title=r'Density $\rho$ [MHD_Blast test]',cbar=(True,'vertical'))
#savefig('MHD_Blast.png') # Only to be saved as either .png or .jpg
plt.show()
I = pp.Image()
flux=D.prs*1.67e-7/D.rho/1000000/1.3806488e-23
# print flux.shape
# flux= (flux-np.mean(flux))*5+np.mean(flux)*5.3
# flux=nd.gaussian_filter(flux,sigma=(4,4),order=0)
I.pldisplay(D, flux,x1=D.x1, \
x2=D.x2,label1='l offset (pc)',label2='b offset (pc)', \
title='Temperature',
cbar=(True,'vertical'))
# savefig('MHD_Blast.png') # Only to be saved as either .png or .jpg
plt.show()
#==================================main========================================
if __name__=='__main__':
#font = {'family' : 'serif',
# 'weight' : 'normal',
# 'size' : 12,
# }
choose = 'single' #single or multiple or temp
ty = 'flux'
t = 18000
E = 1.3
rho = 0.21
sigma = 14
wdir = './'
nlinf = pp.nlast_info(w_dir=wdir)
# single(ty,t,E,rho,sigma,wdir)
analyze(ty,t,E,rho,sigma,wdir)
import os
import sys
from numpy import *
from matplotlib.pyplot import *
import pyPLUTO as pp
#To run this example it is suggested to get data in 2D using pluto_01.ini and set the data in flt datatype instead of dbl.h5
plutodir = os.environ['PLUTO_DIR']
wdir = plutodir + '/Test_Problems/HD/Stellar_Wind/'
nlinf = pp.nlast_info(w_dir=wdir, datatype='float')
D = pp.pload(nlinf['nlast'], w_dir=wdir,
datatype='float') # Loading the data into a pload object D.
I = pp.Image()
I.pldisplay(D,
log10(D.rho),
x1=D.x1,
x2=D.x2,
label1='x',
label2='y',
title=r'Log Density $\rho$ [Stellar Wind]',
cbar=(True, 'vertical'),
figsize=[8, 12])
# Code to plot arrows. --> Spacing between the arrow can be adjusted by modifying the newdims tuple of conrid function.
T = pp.Tools()
newdims = 2 * (20, )
Xmesh, Ymesh = meshgrid(D.x1.T, D.x2.T)
xcong = T.congrid(Xmesh, newdims, method='linear')
max_imy=min(abs(ty1), abs(ty2), abs(ty3))
tx1=sx/(-np.sin(phi))
tx2=sy/(np.cos(phi))
max_imx=min(abs(tx1), abs(tx2))
print("Image size; ")
print(max_imx, max_imy)
return (int(max_imx),int( max_imy))
###########################################################################################################
print("################################################################### \n Integration of emission for PLUTO data \nVersion 5.1\n ##########################################################################")
nr=pp.nlast_info(datatype="vtk") #Reading simulation information
out=[] #Creating an array to store coordinates for integration
sx=0
sy=0
sz=0
#Read parameters from input file
fp = open('paramsee.dat', 'r')
buffer=fp.read()
bufarr=buffer.splitlines()
buffer1,fr=bufarr[0].split('=')
buffer1,phi=bufarr[1].split('=')
buffer1,theta=bufarr[2].split('=')
buffer1,d_name=bufarr[3].split('=')
buffer1,lengthunit=bufarr[4].split('=')
import os
import sys
from numpy import *
from matplotlib.pyplot import *
import pyPLUTO as pp
#To run this example it is suggested to get data in 2D using pluto_01.ini and set the data in flt datatype instead of dbl.h5
plutodir = os.environ['PLUTO_DIR']
wdir = plutodir+'/Test_Problems/HD/Stellar_Wind/'
nlinf = pp.nlast_info(w_dir=wdir,datatype='float')
D = pp.pload(nlinf['nlast'],w_dir=wdir,datatype='float') # Loading the data into a pload object D.
I = pp.Image()
I.pldisplay(D, log10(D.rho),x1=D.x1,x2=D.x2,label1='x',label2='y',
title=r'Log Density $\rho$ [Stellar Wind]',cbar=(True,'vertical'),figsize=[8,12])
# Code to plot arrows. --> Spacing between the arrow can be adjusted by modifying the newdims tuple of conrid function.
T = pp.Tools()
newdims = 2*(20,)
Xmesh, Ymesh = meshgrid(D.x1.T,D.x2.T)
xcong = T.congrid(Xmesh,newdims,method='linear')
ycong = T.congrid(Ymesh,newdims,method='linear')
velxcong = T.congrid(D.vx1.T,newdims,method='linear')
velycong = T.congrid(D.vx2.T,newdims,method='linear')
gca().quiver(xcong, ycong, velxcong, velycong,color='w')
savefig('stellar_wind_1.png')
show()
def __init__(self,master):
# create toplevel window
frame = Frame(master)
frame.grid(ipadx=10,ipady=10)
try:
sys.argv[1]
except:
self.datatype = None
else:
self.datatype = sys.argv[1].split('--')[1]
self.wdir = os.getcwd() + '/'
self.I = pp.Image()
self.Tool = pp.Tools()
self.lb1=Label(frame, text="Nstep").grid(row=0,column=0)
self.enstep = Entry(frame,width=8)
self.enstep.grid(row=0,column=1)
self.enstep.insert(0, "0")
self.LoadedNstep = StringVar()
self.PresentTime = StringVar()
self.myData = self.loaddata()
self.varkeys = self.myData.get_varinfo(self.datatype)['allvars']
self.grid_dict= self.myData.grid()
if self.grid_dict["n3"] != 1:
self.Geom = '3D'
elif self.grid_dict["n3"] == 1 and self.grid_dict["n2"] != 1:
self.Geom = '2D'
else:
self.Geom = '1D'
self.ldatabutton=Button(frame,text="Load data",command=self.loaddata)
self.ldatabutton.grid(row=0,column=2)
############### MARK THE CUTS #################################
self.ex1 = Entry(frame,width=5)
self.ex1.grid(row=2,column=0)
self.ex1.insert(0, "x1")
self.ex2 = Entry(frame,width=5)
self.ex2.grid(row=2,column=1)
self.ex2.insert(0, "x2")
self.ex3 = Entry(frame,width=5)
self.ex3.grid(row=2,column=2)
self.ex3.insert(0, "x3")
if self.Geom == '2D':
self.ex3.config(state='disabled')
if self.Geom == '1D':
self.ex3.config(state='disabled')
self.ex2.config(state='disabled')
self.ex1.config(state='disabled')
# place a graph somewhere here
self.f = Figure(figsize=(7,7), dpi=100)
self.a = self.f.add_subplot(111)
self.canvas = FigureCanvasTkAgg(self.f, master=root)
self.canvas.show()
self.canvas.get_tk_widget().grid(row=0,column=3,columnspan=10,rowspan=10,sticky=E)
#self.toolbar = NavigationToolbar2TkAgg(self.canvas,tl)
#self.toolbar.update()
#self.canvas._tkcanvas.grid(row=60,column=15,sticky=E)
self.v = StringVar()
self.v.set("None")
################ VARIABLES TO PLOT #################################
for j in range(len(self.varkeys)):
self.ldata = Radiobutton(frame,text=self.varkeys[j],variable=self.v,value=self.varkeys[j],command=self.getmyvar)
self.ldata.grid(row=3+j,column=0,sticky=W)
################ SLICES CHOICE #################################
self.slvar = StringVar()
self.slvar.set("Choose Slice")
if self.Geom == '3D' :
SliceList = ("Along x1","Along x2","Along x3","Along x1-x2","Along x2-x3","Along x3-x1")
elif self.Geom == '2D' :
SliceList = ("Along x1", "Along x2", "Along x1-x2")
else:
SliceList = ()
for j in range(len(SliceList)):
self.sldata = Radiobutton(frame,text=SliceList[j],variable=self.slvar,value=SliceList[j],command=self.setslice)
self.sldata.grid(row=3+j,column=1,sticky=W)
############### PLOT PROPERTIES #################################
self.logvar = IntVar()
self.chkb = Checkbutton(frame,text="Log ",variable=self.logvar,onvalue=1,offvalue=0,command=self.logchkcall)
self.chkb.grid(row=3,column=2,sticky=W)#(row=15,column=0,sticky=W)
self.polarvar = IntVar()
self.polchkb = Checkbutton(frame,text="Polar",variable=self.polarvar,onvalue=1,offvalue=0,command=self.polchkcall)
self.polchkb.grid(row=4,column=2,sticky=W)#(row=15,column=1)
if self.Geom == '1D':
self.polchkb.config(state='disabled')
self.polarvar.set(0)
self.preaspect = IntVar()
self.aspectb = Checkbutton(frame,text="Aspect",variable=self.preaspect,onvalue=1,offvalue=0,command=self.aspchkcall)
self.aspectb.grid(row=5,column=2,sticky=W)#(row=15,column=2)
if self.Geom == '1D':
self.aspectb.config(state='disabled')
################ X and Y LABELS #################################
self.lb2=Label(frame,text="Labels").grid(row=22,column=0)
self.xlb = Entry(frame,width=15)
self.xlb.grid(row=22,column=1)
self.xlb.insert(0, "xlabel")
self.ylb = Entry(frame,width=15)
self.ylb.grid(row=22,column=2)
self.ylb.insert(0, "ylabel")
############### X and Y RANGE#######################
self.lb2a=Label(frame,text="XRange").grid(row=24,column=0)
self.lb2b=Label(frame,text="YRange").grid(row=26,column=0)
self.lb2c=Label(frame,text="VarRange").grid(row=28,column=0)
self.xrmin = Entry(frame,width=15)
self.xrmin.grid(row=24,column=1)
self.xrmin.insert(0,'')
self.xrmax = Entry(frame,width=15)
self.xrmax.grid(row=24,column=2)
self.xrmax.insert(0,'')
self.yrmin = Entry(frame,width=15)
self.yrmin.grid(row=26,column=1)
self.yrmin.insert(0,'')
self.yrmax = Entry(frame,width=15)
self.yrmax.grid(row=26,column=2)
self.yrmax.insert(0,'')
self.varmin = Entry(frame,width=15)
self.varmin.grid(row=28,column=1)
self.varmin.insert(0,'')
self.varmax = Entry(frame,width=15)
self.varmax.grid(row=28,column=2)
self.varmax.insert(0,'')
if self.Geom == '1D':
self.yrmin.config(state='disabled')
self.yrmax.config(state='disabled')
################ CONTOURS #################################
self.lb3=Label(frame,text="Contours").grid(row=16,column=0)
self.contvar = IntVar()
self.chkb = Checkbutton(frame,text="Contour",variable=self.contvar,onvalue=1,offvalue=0,command=self.contchkcall)
self.chkb.grid(row=6,column=2,sticky=W)#(row=16,column=0,sticky=W)
self.plcont = StringVar()
self.contkeys = ["None"]
if "bx1" in self.varkeys:
for item in self.varkeys:
self.contkeys.append(item)
self.contkeys.append("x1*bx3")
if "Ax3" in self.varkeys:
self.contkeys.append("x1*Ax3")
else:
for item in self.varkeys:
self.contkeys.append(item)
self.plcont.set("None")
self.contmenu = OptionMenu(frame, self.plcont,*self.contkeys)
self.contmenu.grid(row=16,column=1)
self.xlevb = Entry(frame,width=15)
self.xlevb.grid(row=16,column=2,sticky=W)
self.xlevb.insert(0, "Levels")
self.xlevb.config(state='disabled')
self.contmenu.config(state='disabled')
if self.Geom == '1D':
self.chkb.config(state = 'disabled')
################ ARROWS #################################
self.lb4=Label(frame,text="Arrows").grid(row=19,column=0)
self.arrowvar = IntVar()
self.arrowchkb = Checkbutton(frame,text="Arrows",variable=self.arrowvar,onvalue=1,offvalue=0,command=self.arrchkcall)
self.arrowchkb.grid(row=7,column=2,sticky=W)#(row=16,column=0,sticky=W)
self.arrspb = Entry(frame,width=15)
self.arrspb.grid(row=19,column=2,sticky=W)
self.arrspb.insert(0, "20")
self.plarr = StringVar()
self.arrkeys = ["None"]
self.arrkeys.append("Vp")
self.arrkeys.append("Vp_norm")
if "bx1" in self.varkeys:
self.arrkeys.append("Bp")
self.arrkeys.append("Bp_norm")
self.plarr.set("None")
self.arrmenu = OptionMenu(frame,self.plarr,*self.arrkeys)
self.arrmenu.grid(row=19,column=1)
self.arrmenu.config(state='disabled')
self.arrspb.config(state='disabled')
if self.Geom == '1D':
self.arrowchkb.config(state = 'disabled')
################ VARIOUS PLOTTING BUTTONS #################################
self.pltbutton=Button(frame,text="Plot",command=self.plotfinal)
self.pltbutton.grid(row=36,column=0)
if self.Geom == '1D':
self.pltbutton.config(state='active')
else:
self.pltbutton.config(state='disabled')
self.surfbutton=Button(frame,text="Surface",command=self.plotsurface)
self.surfbutton.grid(row=36,column=1)
self.surfbutton.config(state='disabled')
#if self.Geom == '1D':
# self.surfbutton.config(state='disabled')
self.clrbutton=Button(frame,text="Clear",command=self.plotclear)
self.clrbutton.grid(row=36,column=2)
################ INFORMATION #################################
self.lbinf0 = Label(frame,text="Information",font=("Times",12,"bold"))
self.lbinf0.grid(row=47,column=0,sticky=W,columnspan=3)
self.lbinf1a = Label(frame,text="Dir :",font=("Times",10,"bold")).grid(row=49,column=0,sticky=W,columnspan=3)
self.lbinf1 = Label(frame,text=self.wdir).grid(row=50,column=0,sticky=W,columnspan=3)
self.lbinf2a = Label(frame,text="Domain :",font=("Times",10,"bold")).grid(row=51,column=0,sticky=W,columnspan=3)
self.lbinf2 = Label(frame,text="n1 x n2 x n3 = %d x %d x %d " % (self.grid_dict.get('n1'),self.grid_dict.get('n2'),self.grid_dict.get('n3'))).grid(row=52,column=0,sticky=W,columnspan=3)
self.lbinf3a = Label(frame,text="Time Status",font=("Times",10,"bold")).grid(row=53,column=0,sticky=W,columnspan=3)
self.lbinf4 = Label(frame,text="Nlast = %d"% (pp.nlast_info(datatype=self.datatype).get('nlast'))).grid(row=54,column=0,sticky=W,columnspan=3)
self.lbinf5 = Label(frame,textvariable = self.LoadedNstep).grid(row=55,column=0,sticky=W,columnspan=3)
self.lbinf6 = Label(frame,textvariable = self.PresentTime).grid(row=56,column=0,sticky=W,columnspan=3)
import os
import sys
from numpy import *
from matplotlib.pyplot import *
import pyPLUTO as pp
plutodir = os.environ['PLUTO_DIR']
wdir = plutodir+'/Test_Problems/MHD/FARGO/Spherical_Disk/'
nlinf = pp.nlast_info(w_dir=wdir,datatype='vtk')
D = pp.pload(nlinf['nlast'],w_dir=wdir,datatype='vtk') # Loading the data into a pload object D.
I = pp.Image()
f1 = figure(figsize=[15,6],num=1)
ax1=f1.add_subplot(122)
I.pltSphData(D,w_dir=wdir,datatype='vtk',plvar='bx1',logvar=False,rphi=False,x3cut=96)
colorbar(orientation='horizontal')
ax1.set_xlabel(r'Radius')
ax1.set_ylabel(r'Height')
ax1.set_title(r'Magnetic field $B_{\rm x}$')
ax2=f1.add_subplot(121)
I.pltSphData(D,w_dir=wdir,datatype='vtk',plvar='rho',logvar=True,rphi=True,x2cut=24)
colorbar(orientation='vertical')
ax2.set_xlabel(r'x')
ax2.set_ylabel(r'y')
ax2.set_title(r'Log $\rho$')
# Code to plot arrows. --> Spacing between the arrow can be adjusted by
# modifying the newdims tuple of conrid function.
def __init__(self, master):
# create toplevel window
frame = Frame(master)
frame.grid(ipadx=10, ipady=10)
self.wdir = os.getcwd() + '/'
self.I = pp.Image()
self.Tool = pp.Tools()
self.lb1 = Label(frame, text="Nstep").grid(row=0, column=0)
self.enstep = Entry(frame, width=8)
self.enstep.grid(row=0, column=1)
self.enstep.insert(0, "0")
self.LoadedNstep = StringVar()
self.PresentTime = StringVar()
self.myData = self.loaddata()
self.varkeys = self.myData.get_varinfo()['allvars']
self.grid_dict = self.myData.grid()
if self.grid_dict["n3"] != 1:
self.Geom = '3D'
elif self.grid_dict["n3"] == 1 and self.grid_dict["n2"] != 1:
self.Geom = '2D'
else:
self.Geom = '1D'
self.ldatabutton = Button(frame,
text="Load data",
command=self.loaddata)
self.ldatabutton.grid(row=0, column=2)
############### MARK THE CUTS #################################
self.ex1 = Entry(frame, width=5)
self.ex1.grid(row=2, column=0)
self.ex1.insert(0, "x1")
self.ex2 = Entry(frame, width=5)
self.ex2.grid(row=2, column=1)
self.ex2.insert(0, "x2")
self.ex3 = Entry(frame, width=5)
self.ex3.grid(row=2, column=2)
self.ex3.insert(0, "x3")
if self.Geom == '2D':
self.ex3.config(state='disabled')
if self.Geom == '1D':
self.ex3.config(state='disabled')
self.ex2.config(state='disabled')
self.ex1.config(state='disabled')
# place a graph somewhere here
self.f = Figure(figsize=(7, 7), dpi=100)
self.a = self.f.add_subplot(111)
self.canvas = FigureCanvasTkAgg(self.f, master=root)
self.canvas.show()
self.canvas.get_tk_widget().grid(row=0,
column=3,
columnspan=10,
rowspan=10,
sticky=E)
#self.toolbar = NavigationToolbar2TkAgg(self.canvas,tl)
#self.toolbar.update()
#self.canvas._tkcanvas.grid(row=60,column=15,sticky=E)
self.v = StringVar()
self.v.set("None")
################ VARIABLES TO PLOT #################################
for j in range(len(self.varkeys)):
self.ldata = Radiobutton(frame,
text=self.varkeys[j],
variable=self.v,
value=self.varkeys[j],
command=self.getmyvar)
self.ldata.grid(row=3 + j, column=0, sticky=W)
################ SLICES CHOICE #################################
self.slvar = StringVar()
self.slvar.set("Choose Slice")
if self.Geom == '3D':
SliceList = ("Along x1", "Along x2", "Along x3", "Along x1-x2",
"Along x2-x3", "Along x3-x1")
elif self.Geom == '2D':
SliceList = ("Along x1", "Along x2", "Along x1-x2")
else:
SliceList = ()
for j in range(len(SliceList)):
self.sldata = Radiobutton(frame,
text=SliceList[j],
variable=self.slvar,
value=SliceList[j],
command=self.setslice)
self.sldata.grid(row=3 + j, column=1, sticky=W)
############### PLOT PROPERTIES #################################
self.logvar = IntVar()
self.chkb = Checkbutton(frame,
text="Log ",
variable=self.logvar,
onvalue=1,
offvalue=0,
command=self.logchkcall)
self.chkb.grid(row=3, column=2, sticky=W) #(row=15,column=0,sticky=W)
self.polarvar = IntVar()
self.polchkb = Checkbutton(frame,
text="Polar",
variable=self.polarvar,
onvalue=1,
offvalue=0,
command=self.polchkcall)
self.polchkb.grid(row=4, column=2, sticky=W) #(row=15,column=1)
if self.Geom == '1D':
self.polchkb.config(state='disabled')
self.polarvar.set(0)
self.preaspect = IntVar()
self.aspectb = Checkbutton(frame,
text="Aspect",
variable=self.preaspect,
onvalue=1,
offvalue=0,
command=self.aspchkcall)
self.aspectb.grid(row=5, column=2, sticky=W) #(row=15,column=2)
if self.Geom == '1D':
self.aspectb.config(state='disabled')
################ X and Y LABELS #################################
self.lb2 = Label(frame, text="Labels").grid(row=22, column=0)
self.xlb = Entry(frame, width=15)
self.xlb.grid(row=22, column=1)
self.xlb.insert(0, "xlabel")
self.ylb = Entry(frame, width=15)
self.ylb.grid(row=22, column=2)
self.ylb.insert(0, "ylabel")
############### X and Y RANGE#######################
self.lb2a = Label(frame, text="XRange").grid(row=24, column=0)
self.lb2b = Label(frame, text="YRange").grid(row=26, column=0)
self.lb2c = Label(frame, text="VarRange").grid(row=28, column=0)
self.xrmin = Entry(frame, width=15)
self.xrmin.grid(row=24, column=1)
self.xrmin.insert(0, '')
self.xrmax = Entry(frame, width=15)
self.xrmax.grid(row=24, column=2)
self.xrmax.insert(0, '')
self.yrmin = Entry(frame, width=15)
self.yrmin.grid(row=26, column=1)
self.yrmin.insert(0, '')
self.yrmax = Entry(frame, width=15)
self.yrmax.grid(row=26, column=2)
self.yrmax.insert(0, '')
self.varmin = Entry(frame, width=15)
self.varmin.grid(row=28, column=1)
self.varmin.insert(0, '')
self.varmax = Entry(frame, width=15)
self.varmax.grid(row=28, column=2)
self.varmax.insert(0, '')
if self.Geom == '1D':
self.yrmin.config(state='disabled')
self.yrmax.config(state='disabled')
################ CONTOURS #################################
self.lb3 = Label(frame, text="Contours").grid(row=16, column=0)
self.contvar = IntVar()
self.chkb = Checkbutton(frame,
text="Contour",
variable=self.contvar,
onvalue=1,
offvalue=0,
command=self.contchkcall)
self.chkb.grid(row=6, column=2, sticky=W) #(row=16,column=0,sticky=W)
self.plcont = StringVar()
self.contkeys = ["None"]
if "b1" in self.varkeys:
for item in self.varkeys:
self.contkeys.append(item)
self.contkeys.append("x1*b3")
self.contkeys.append("x1*A3")
else:
for item in self.varkeys:
self.contkeys.append(item)
self.plcont.set("None")
self.contmenu = OptionMenu(frame, self.plcont, *self.contkeys)
self.contmenu.grid(row=16, column=1)
self.xlevb = Entry(frame, width=15)
self.xlevb.grid(row=16, column=2, sticky=W)
self.xlevb.insert(0, "Levels")
self.xlevb.config(state='disabled')
self.contmenu.config(state='disabled')
if self.Geom == '1D':
self.chkb.config(state='disabled')
################ ARROWS #################################
self.lb4 = Label(frame, text="Arrows").grid(row=19, column=0)
self.arrowvar = IntVar()
self.arrowchkb = Checkbutton(frame,
text="Arrows",
variable=self.arrowvar,
onvalue=1,
offvalue=0,
command=self.arrchkcall)
self.arrowchkb.grid(row=7, column=2,
sticky=W) #(row=16,column=0,sticky=W)
self.arrspb = Entry(frame, width=15)
self.arrspb.grid(row=19, column=2, sticky=W)
self.arrspb.insert(0, "20")
self.plarr = StringVar()
self.arrkeys = ["None"]
self.arrkeys.append("Vp")
self.arrkeys.append("Vp_norm")
if "b1" in self.varkeys:
self.arrkeys.append("Bp")
self.arrkeys.append("Bp_norm")
self.plarr.set("None")
self.arrmenu = OptionMenu(frame, self.plarr, *self.arrkeys)
self.arrmenu.grid(row=19, column=1)
self.arrmenu.config(state='disabled')
self.arrspb.config(state='disabled')
if self.Geom == '1D':
self.arrowchkb.config(state='disabled')
################ VARIOUS PLOTTING BUTTONS #################################
self.pltbutton = Button(frame, text="Plot", command=self.plotfinal)
self.pltbutton.grid(row=36, column=0)
if self.Geom == '1D':
self.pltbutton.config(state='active')
else:
self.pltbutton.config(state='disabled')
self.surfbutton = Button(frame,
text="Surface",
command=self.plotsurface)
self.surfbutton.grid(row=36, column=1)
self.surfbutton.config(state='disabled')
#if self.Geom == '1D':
# self.surfbutton.config(state='disabled')
self.clrbutton = Button(frame, text="Clear", command=self.plotclear)
self.clrbutton.grid(row=36, column=2)
################ INFORMATION #################################
self.lbinf0 = Label(frame,
text="Information",
font=("Times", 12, "bold"))
self.lbinf0.grid(row=47, column=0, sticky=W, columnspan=3)
self.lbinf1a = Label(frame, text="Dir :",
font=("Times", 10, "bold")).grid(row=49,
column=0,
sticky=W,
columnspan=3)
self.lbinf1 = Label(frame, text=self.wdir).grid(row=50,
column=0,
sticky=W,
columnspan=3)
self.lbinf2a = Label(frame,
text="Domain :",
font=("Times", 10, "bold")).grid(row=51,
column=0,
sticky=W,
columnspan=3)
self.lbinf2 = Label(
frame,
text="n1 x n2 x n3 = %d x %d x %d " %
(self.grid_dict.get('n1'), self.grid_dict.get('n2'),
self.grid_dict.get('n3'))).grid(row=52,
column=0,
sticky=W,
columnspan=3)
self.lbinf3a = Label(frame,
text="Time Status",
font=("Times", 10, "bold")).grid(row=53,
column=0,
sticky=W,
columnspan=3)
self.lbinf4 = Label(frame,
text="Nlast = %d" %
(pp.nlast_info().get('nlast'))).grid(row=54,
column=0,
sticky=W,
columnspan=3)
self.lbinf5 = Label(frame,
textvariable=self.LoadedNstep).grid(row=55,
column=0,
sticky=W,
columnspan=3)
self.lbinf6 = Label(frame,
textvariable=self.PresentTime).grid(row=56,
column=0,
sticky=W,
columnspan=3)
