def makeInterface(self):
""" create interface for ssh """
self.resetFrame()
colors = { 'center_x' : '#ff3333',
'center_y' : 'green',
'center_z' : '#00aaff',
'size_x' : '#ff3333',
'size_y' : 'green',
'size_z' : '#0099ff',
}
frame_set = { 'ring_bd' : 1, 'ring_highlightbackground' :'black', 'ring_borderwidth' : 2,
'ring_highlightcolor' : 'black', 'ring_highlightthickness' : 1, 'ring_relief' : 'flat',
'groupchildsite_bg':'white', 'groupchildsite_relief':'sunken','ring_bg':'white',
'tag_bd' : '1', 'tag_highlightbackground' :'black', 'tag_borderwidth':2,
'tag_highlightcolor' : 'black', 'tag_highlightthickness': 1}
frame_set = { 'ring_bd' : 1, 'ring_highlightbackground' :'black', 'ring_borderwidth' : 2,
'ring_highlightcolor' : 'black', 'ring_highlightthickness' : 1, 'ring_relief' : 'flat'}
frame_set = {}
bset = { 'bg' : '#95bed5', 'width' : 22, 'height': 22, 'relief' : 'raised'}
bset = { 'bg' : '#2e363b', 'width' : 22, 'height': 22, 'relief' : 'raised'}
bset = { 'bg' : '#a6abae', 'width' : 22, 'height': 22, 'relief' : 'raised'}
bset = { 'bg' : '#969b9d' } # 'width' : 22, 'height': 22, 'relief' : 'raised'}
bset = {}
bset.update(self.BORDER)
# left frame
lframe = tk.Frame(self.frame)
# button tollbar
tk.Frame(lframe, height=7).pack(expand=0, fill='x', padx=0, pady=0, side='top', anchor='n')
# minispacer
bframe = tk.Frame(lframe)
b = tk.Button(bframe, text='Load...', command = self.openConfig, image= self._ICON_open, compound='left',
height=14,**bset)
b.pack(expand=1,fill='x', anchor='w', side='left',padx=1)
b.pack(expand=1,fill='x', anchor='w', side='left',padx=1)
bframe.pack(expand=0, fill='x', padx=0, pady=0, side='top', anchor='n')
########################## center wheels
self._thumbw_array = []
c_group = Pmw.Group(lframe, tag_text='Center', tag_font=self.FONTbold, **frame_set)
for lab in ['center_x', 'center_y', 'center_z']:
cb = CallbackFunction(self.setWheelBox, lab)
tw = ThumbWheel(
c_group.interior(), labCfg={'text':lab, 'side':'left','fg':colors[lab],
'bg':'black', 'width':9 }, showLabel=1,
width=90, height=14, type=float, value=0.0,
callback=cb, continuous=True,
oneTurn=5, wheelPad=0)
tw.pack(side='top', pady=2,anchor='n')
self._thumbw_array.append(tw)
c_group.pack(side='top', anchor='n', expand=0,fill='x',ipadx=2,ipady=3, padx=1)
########################## size wheels
s_group = Pmw.Group(lframe, tag_text='Size', tag_font=self.FONTbold, **frame_set)
for lab in ['size_x', 'size_y', 'size_z']:
cb = CallbackFunction(self.setWheelBox, lab)
tw = ThumbWheel(
s_group.interior(), labCfg={'text':lab, 'side':'left','fg':colors[lab],
'bg':'black', 'width':9 }, showLabel=1,
width=90, height=14, type=float, value=0.0, min=0.0001,
callback=cb, continuous=True,
oneTurn=5, wheelPad=0)
tw.pack(side='top', pady=2,anchor='n')
self._thumbw_array.append(tw)
s_group.pack(side='top', anchor='n', expand=0,fill='x',ipadx=2,ipady=3, padx=1,pady=2)
########################## search settings
self.searchparmgroup = Pmw.Group(lframe, tag_text='Search parameters', tag_font=self.FONTbold, **frame_set)
# autodock search parms
self.buildSearchADPanel(target = self.searchparmgroup )
# vina search parms
self.buildSearchVinaPanel(target = self.searchparmgroup )
self.searchparmgroup.pack(side='top', anchor='n', expand=0,fill='x',ipadx=2,ipady=3, padx=1,pady=5)
########################## Receptors
self._receptors_group = Pmw.Group(lframe, tag_text='Receptor list', tag_font=self.FONTbold,collapsedsize=3, **frame_set)
# important
self.receptorListbox = Pmw.ScrolledListBox(self._receptors_group.interior(), listbox_highlightbackground = 'black',
# selectioncommand=self.loadreceptor,
listbox_selectbackground='yellow')
self.receptorListbox.pack(expand=1, fill='both',padx=3, pady=0)
self.receptorListbox.component('listbox').bind('<ButtonRelease-1>', self.loadreceptor)
self.receptorListbox.component('listbox').bind('<Button-3>', self._delreceptor)
tb = tk.Frame(self._receptors_group.interior())
# single-multi load buttons
self.recLoaderMode_single = tk.Radiobutton(tb, text='Single', image = self._ICON_single, indicatoron=False,
variable=self.recLoaderMultiMode, value = False, compound='left', height=16, **bset)
self.recLoaderMode_single.pack(anchor='n', side='left',pady=1,expand=1,fill='x',padx=1)
self.recLoaderMode_multi = tk.Radiobutton(tb, text='Multi', image = self._ICON_multi, indicatoron=False,
variable=self.recLoaderMultiMode, value = True, compound='left', height=16, **bset)
self.recLoaderMode_multi.pack(anchor='n', side='left',pady=1,expand=1,fill='x',padx=1)
tb.pack(expand=0, fill='x',anchor='s',side='bottom',padx=3)
self._receptors_group.pack(side='bottom', anchor='n', expand=1, fill='both',ipadx=4,ipady=4, padx=1,pady=0)
lframe.pack(side = 'left', anchor='n', expand='n', fill='y', padx=0, pady=0)
###### 3D Viewer
rframe = tk.Frame(self.frame)
spacer = tk.Frame(rframe, width=5) #, bg='red')
spacer.pack(expand=0,fill='y',side='left',anchor='w')
spacer.pack_propagate(0)
vgroup = Pmw.Group(rframe, tag_text = '3D viewer', tag_font=self.FONTbold,groupchildsite_bg='black', **frame_set)
# TOOLBAR
vtoolbar = tk.Frame(vgroup.interior())
vtoolbar.pack(side='left', anchor='w', expand=0, fill='y')
cb = CallbackFunction(self.centerView, None)
tk.Button(vtoolbar, text='Center\nall', image = self._ICON_center_all, width=22, height=22,
command=cb, **bset).pack(anchor='n', side='top')
cb = CallbackFunction(self.centerView, 'mol')
tk.Button(vtoolbar, text='Center\nmol', image = self._ICON_center_mol, width=22, height=22,
command=cb, **bset ).pack(anchor='n', side='top')
cb = CallbackFunction(self.centerView, 'box')
tk.Button(vtoolbar, text='Center\nbox', image = self._ICON_center_box, width=22, height=22,
command=cb, **bset ).pack(anchor='n', side='top',pady=1)
# 3d Viewer settings XXX TODO
#tk.Button(vtoolbar, text='Settings', image = self._ICON_sys, width=22, height=22, **bset).pack(anchor='n', side='top')
vgroup.pack(side='right', anchor='e', expand=1, fill='both', padx=0, pady=0)
# 3D viewer
self.make3Dboxviewer(vgroup.interior())
rframe.pack(side = 'right', anchor='n', expand=1, fill='both',padx=0, pady=0)
if self.app.dockengine == 'vina':
self.setSearchParmsVina()
elif self.app.dockengine == 'autodock':
self.setSearchParmsAD()
self.frame.pack(expand=1, fill='both',anchor='n', side='top')
class GraphApp:
# Initialization
def __init__(self,master=None,callback=None,continuous=1):
self.master=master
self.callback = None
self.callbacks = CallbackManager()
self.canvas=canvas = Canvas(self.master,width=345,height=320,bg='white')
self.toolbar = Frame(master) # Create Toolbar
self.toolbar.pack(side='top', expand=1, fill='both')
self.menuFrame1 = Tkinter.Frame(self.toolbar, relief='raised', borderwidth=3)
self.menuFrame1.pack(side='top', expand=1, fill='x')
self.filebutton = Tkinter.Menubutton(self.menuFrame1, text='File')
self.filebutton.pack(side='left')
self.filemenu = Tkinter.Menu(self.filebutton, {})
self.filemenu.add_command(label='Read', command=self.read_cb)
self.filemenu.add_command(label='Write', command=self.write_cb)
self.filebutton['menu'] = self.filemenu
self.editbutton = Tkinter.Menubutton(self.menuFrame1, text='Edit')
self.editbutton.pack(side='left', anchor='w')
self.editmenu = Tkinter.Menu(self.editbutton, {})
self.editmenu.add_command(label='Reset to first in history', command=self.resetAll_cb)
self.editmenu.add_command(label='Step back in history loop', command=self.stepBack_cb)
self.editmenu.add_command(label='Default Curve', command=self.defaultcurve_cb)
self.editmenu.add_command(label='Invert Curve',command=self.invertGraph)
self.histvar=IntVar()
self.histvar.set(1)
self.editmenu.add_checkbutton(label='Histogram',var=self.histvar,command=self.drawHistogram)
self.editbutton['menu'] = self.editmenu
self.optionType = IntVar()
self.updatebutton = Tkinter.Menubutton(self.menuFrame1, text='Update')
self.updatebutton.pack(side='left', anchor='w')
self.updatemenu = Tkinter.Menu(self.updatebutton,{} )
for v,s in {0:'Continuous',1:'MouseButtonUp',2:'Update'}.items():
self.updatemenu.add_radiobutton(label=s,
var=self.optionType,
value = v,command=self.calloption)
if continuous==1:
self.optionType.set(0)
self.updatebutton['menu'] = self.updatemenu
#Curve Type
self.CurveType = IntVar()
self.CurveType.set(0)
self.Smooth=1
self.curvebutton = Tkinter.Menubutton(self.menuFrame1, text='Curve')
self.curvebutton.pack(side='left', anchor='w')
self.curvemenu = Tkinter.Menu(self.curvebutton,{} )
for v,s in {0:'Smooth',1:'Freehand'}.items():
self.curvemenu.add_radiobutton(label=s,
var=self.CurveType,
value = v,command=self.curveoption)
self.curvebutton['menu'] = self.curvemenu
f1 = Tkinter.Frame(self.master)
f1.pack(side='bottom', fill='both', expand=1)
self.d1scalewheellab=Label(f1,text="Sensitivity")
self.d1scalewheellab.pack(side="left")
self.d1scalewheel=ThumbWheel(width=100, height=26,wheelPad=4,master=f1,labcfg={'fg':'black', 'side':'left', 'text':'Test:'},wheelLabcfg1={'font':(ensureFontCase('times'),14,'bold')},wheelLabcfg2={'font':(ensureFontCase('times'),14,'bold')},canvascfg={'bg':'blue'},min = 0.0,max = 1.0,precision =4,showlabel =0,value =0.013,continuous =0,oneTurn =0.01,size = 200)
self.d1scalewheel.pack(side="left")
#tooltip
self.balloon = Pmw.Balloon(f1)
self.balloon.bind(self.d1scalewheel,"cutoff value for differences in Z xoordinates,small values generate more contours")
self.Updatebutton=Button(f1,text=' Update ',command=self.Update)
self.Updatebutton.pack(side=LEFT)
self.Quitbutton=Button(f1,text=' Dismiss ',command=self.dismiss_cb)
self.Quitbutton.pack(side=RIGHT)
self.canvas.bind("<Button-1>", self.OnCanvasClicked)
self.canvas.bind("<B1-Motion>", self.OnCanvasMouseDrag)
self.canvas.bind("<ButtonRelease-1>", self.OnCanvasMouseUp)
self.canvas.config(closeenough=2.0)
self.canvas.pack(side=BOTTOM, fill=BOTH,expand=1)
self.startpoint=(px,py)=(50,275)
self.endpoint=(px1,py1)=(305,20)
self.newpoints=[(px,py),(px1,py1)]
self.canvas.create_rectangle([(px-1,py),(px1+1,py1)],fill='white',outline="black",width=1)
self.canvas.create_text(46,281,text=0,anchor=N)
#Drawing Graph Sheet
for i in range(1,6):
x=50+i*50
canvas.create_line(x,280,x,275,width=1)
canvas.create_text(x,281,text='%d' %(50*i),anchor=N)
for i in range(1,5):
x=50+i*50
canvas.create_line(x,275,x,20,width=1,fill="gray80")
for i in range(1,6):
y=275-i*50
canvas.create_line(45,y,50,y,width=1)
canvas.create_text(44,y,text='%d' %(50*i),anchor=E)
for i in range(1,5):
y=275-i*50
canvas.create_line(50,y,305,y,width=1,fill="gray80")
(x,y)=self.newpoints[0]
(x1,y1)=self.newpoints[-1]
self.curline=canvas.create_line(self.newpoints,fill='black',width=1)
#GRAY SCALE
grays=[]
for i in range(0,100,1):
grays.append("gray"+"%d" %i)
#grays.reverse()
#bottom one
x1=48
x2=51
self.canvas.create_rectangle([(50,315),(307,300)],fill='white',outline="black",width=0.5)
for a in grays:
if x1>306:
x1=x2=306
self.canvas.create_rectangle([(x1+2.5,314),(x2+2.5,301)],fill=a,outline=a,width=1)
x1=x1+2.5
x2=x2+2.5
#left one
y1=274
y2=271
self.canvas.create_rectangle([(20,275),(5,20)],fill='black',outline="black",width=0.5)
for a in grays:
if y1>275:
y1=y2=275
self.canvas.create_rectangle([(19,y1-2.5),(6,y2-2.5)],fill=a,outline=a,width=1)
y1=y1-2.5
y2=y2-2.5
self.oldpoints=[]
self.canvas.configure(cursor='cross')
self.curovals=[]
self.default_points=[(50,275),(88, 238), (101, 150), (154, 78), (75, 271),(305,20)]
# now set the constructor options correctly using the configure method
apply( self.configure, (),{'callback':callback,'continuous':continuous})
self.continuous=continuous
self.mousebuttonup=0
self.update=0
self.range_points=[]
self.history=[]
self.bars=[]
self.default_ramp=[]
self.histvalues=[]
def calloption(self):
tag=self.optionType.get()
self.continuous=0
self.mousebuttonup=0
self.update=0
if tag==0:
self.continuous=1
elif tag==1:
self.mousebuttonup=1
elif tag==2:
self.update=1
def curveoption(self):
tag=self.CurveType.get()
self.Smooth=0
self.Freehand=0
if tag==0:
self.Smooth=1
self.canvas.delete(self.curline)
self.curline=self.canvas.create_line(self.getControlPoints(),smooth=1)
elif tag==1:
self.Freehand=1
self.canvas.delete(self.curline)
self.curline=self.canvas.create_line(self.getControlPoints())
def OnCanvasClicked(self,event):
"""Appends last drag point to controlpoint list if not appended by mouseleave func.
when clicked on any controlpoint removes control point and draws line with remaining
control points."""
self.CLICK_NODRAG=1
if self.history!=[]:
if self.history[-1][1]!=self.d1scalewheel.get():
self.history[-1]=(self.history[-1][0],self.d1scalewheel.get())
if hasattr(self,"curx"):
if (self.curx,self.cury) :#not in [self.startpoint,self.endpoint]:
(self.ox,self.oy)=(self.curx,self.cury)
if (self.ox,self.oy) not in self.oldpoints:
self.oldpoints.append((self.ox,self.oy))
if hasattr(self,"curoval"):
self.curovals.append(self.curoval)
self.OrgX=event.x
self.OrgY=event.y
CtlPoints=[]
xcoords=[]
ycoords=[]
#Limiting points not to cross
self.limit_xcoord=[]
for i in range(0,10):
xcoords.append(self.OrgX-i)
ycoords.append(self.OrgY-i)
xcoords.append(self.OrgX+i)
ycoords.append(self.OrgY+i)
if xcoords!=[] and ycoords!=[]:
for x in xcoords:
for y in ycoords:
CtlPoints.append((x,y))
self.range_points=self.oldpoints
self.range_points.sort()
for c in CtlPoints:
if c in self.range_points:
index_c=self.range_points.index(c)
if index_c<len(self.range_points)-1:
self.limit_xcoord.append(self.range_points[index_c+1])
if index_c>0:
self.limit_xcoord.append(self.range_points[index_c-1])
return
else:
self.limit_xcoord.append(self.startpoint)
return
elif index_c==len(self.range_points)-1:
self.limit_xcoord.append(self.range_points[index_c-1])
self.limit_xcoord.append(self.endpoint)
return
self.newd1ramp= self.caluculate_ramp()
def OnCanvasMouseUp(self,event):
CtlPoints=[]
xcoords=[]
ycoords=[]
if hasattr(self,"curx"):
(self.ox,self.oy)=(self.curx,self.cury)
if (self.ox,self.oy) not in self.oldpoints :#not in [self.startpoint,self.endpoint] :
self.oldpoints.append((self.ox,self.oy))
if hasattr(self,"curoval"):
if self.curoval not in self.curovals:
self.curovals.append(self.curoval)
if self.CLICK_NODRAG==1:
#finding out points around the selected point
for i in range(0,10):
xcoords.append(self.OrgX-i)
ycoords.append(self.OrgY-i)
xcoords.append(self.OrgX+i)
ycoords.append(self.OrgY+i)
if xcoords!=[] and ycoords!=[]:
for x in xcoords:
for y in ycoords:
CtlPoints.append((x,y))
for c in CtlPoints:
if c in self.oldpoints:
ind=self.oldpoints.index(c)
op=self.oldpoints[ind]
if ind>0:
prev_oldpoint=self.oldpoints[ind-1]
else:
prev_oldpoint=self.endpoint
del self.oldpoints[ind]
for co in self.curovals:
ov_point1=self.canvas.coords(co)
if len(ov_point1)!=0:
ov_point=(int(ov_point1[0]+2),int(ov_point1[1]+2))
if ov_point==c and ov_point not in [self.startpoint,self.endpoint]:
self.canvas.delete(co)
self.curovals.remove(co)
if hasattr(self,"curx"):
if ov_point==(self.curx,self.cury):
(self.curx,self.cury)=prev_oldpoint
self.draw()
if self.mousebuttonup:
self.newd1ramp=self.caluculate_ramp()
self.callbacks.CallCallbacks(self.newd1ramp)
self.history.append((deepCopySeq(self.oldpoints),self.d1scalewheel.get()))
def OnCanvasMouseDrag(self,event):
self.CLICK_NODRAG=0
CtlPoints=[]
xcoords=[]
ycoords=[]
#making active clickrange to be ten points around clicked point
for i in range(0,10):
xcoords.append(self.OrgX-i)
ycoords.append(self.OrgY-i)
xcoords.append(self.OrgX+i)
ycoords.append(self.OrgY+i)
if xcoords!=[] and ycoords!=[]:
for x in xcoords:
for y in ycoords:
CtlPoints.append((x,y))
for c in CtlPoints:
if c in self.oldpoints:
ind=self.oldpoints.index(c)
op=self.oldpoints[ind]
del self.oldpoints[ind]
for co in self.curovals:
ov_point1=self.canvas.coords(co)
if len(ov_point1)!=0:
ov_point=(int(round(ov_point1[0],3))+2,int(round(ov_point1[1],3))+2)
if ov_point==c :
self.canvas.delete(co)
self.curovals.remove(co)
self.curx=dx=event.x
self.cury=dy=event.y
self.draw()
def draw(self):
"""Draws line,ovals with current controlpoints. """
new1points=[]
curve_points=[]
self.smoothened_points=[]
if self.CLICK_NODRAG==0:
dx=self.curx
dy=self.cury
else:
(dx,dy)=(self.curx,self.cury)=(self.endpoint)
###Limiting xcoords of the current point not to cross adjacent points
if hasattr(self,"limit_xcoord"):
if self.limit_xcoord!=[]:
self.limit_xcoord.sort()
if (self.curx,self.cury) not in [self.startpoint,self.endpoint]:
if (self.curx,self.cury)< self.limit_xcoord[0]:
if self.curx<=self.limit_xcoord[0][0] and self.cury<self.limit_xcoord[0][1]:
dx=self.curx=self.limit_xcoord[0][0]+1
if self.curx<=self.limit_xcoord[0][0] and self.cury>self.limit_xcoord[0][1]:
dx=self.curx=self.limit_xcoord[0][0]
if (self.curx,self.cury)> self.limit_xcoord[1]:
if self.curx>=self.limit_xcoord[1][0] and self.cury>self.limit_xcoord[1][1]:
dx=self.curx=self.limit_xcoord[1][0]-1
if self.curx>=self.limit_xcoord[1][0] and self.cury<self.limit_xcoord[1][1]:
dx=self.curx=self.limit_xcoord[1][0]
#Limit graph with in the axis
if self.curx not in range(50,305):
if self.curx<50:
self.curx=dx=50
else:
self.curx=dx=305
if self.cury not in range(20,275):
if self.cury<20:
self.cury=dy=20
else:
self.cury=dy=275
#adding start,end points
new1points.append(self.startpoint)
new1points.append(self.endpoint)
#adding current point to list
if (dx,dy) not in new1points and (dx,dy) not in [self.startpoint,self.endpoint]:
new1points.append((dx,dy))
#adding oldpoints to list
if hasattr(self,"ox"):
for op in self.oldpoints:
if op not in new1points:
new1points.append(op)
new1points.sort()
#removing oval point that is on drag
if hasattr(self,"curoval"):
if self.curoval not in self.curovals:
self.canvas.delete(self.curoval)
self.canvas.delete(self.curline)
#if points that start with 50 or 51 or 305,304 other than start ,end
#points exists remove start or end points
#remove ovals
#finding oval for start point and endpoint
for i in new1points:
if i[0]==51 or i[0]==50:
if i!=self.startpoint:
if self.startpoint in new1points:
new1points.remove(self.startpoint)
###removing start point oval
x = 50
y = 275
st_oval_1= self.canvas.find_enclosed(x-3,y-3,x+3,y+3)
if st_oval_1:
for so in st_oval_1:
if so!=[]:
st_oval=so
st_oval_coords=self.canvas.coords(st_oval)
if (int(st_oval_coords[0]+2),int(st_oval_coords[1]+2))==self.startpoint:
self.canvas.delete(st_oval)
if st_oval in self.curovals:
self.curovals.remove(st_oval)
for i in new1points:
if i[0]==304 or i[0]==305:
if i!=self.endpoint :
if self.endpoint in new1points:
new1points.remove(self.endpoint)
###removing end point oval
x = 305
y = 20
end_oval_1= self.canvas.find_enclosed(x-3,y-3,x+3,y+3)
if end_oval_1:
for eo in end_oval_1:
if eo!=[]:
end_oval=eo
end_oval_coords=self.canvas.coords(end_oval)
if (int(end_oval_coords[0]+2),int(end_oval_coords[1]+2))==self.endpoint:
self.canvas.delete(end_oval)
if end_oval in self.curovals:
self.curovals.remove(end_oval)
new1points.sort()
for (x,y) in new1points:
curve_points.append(x)
curve_points.append(y)
self.smoothened_points= self.smooth(curve_points)
#drawing line
if len(self.smoothened_points)>2:
if self.Smooth:
self.curline=self.canvas.create_line(self.smoothened_points)
else:
self.curline=self.canvas.create_line(curve_points)
else:
if curve_points[0]==50 or 51:
if self.Smooth:
self.curline=self.canvas.create_line(curve_points,smooth=1)
else:
self.curline=self.canvas.create_line(curve_points)
else:
self.curline=self.canvas.create_line(self.startpoint,self.endpoint)
##Adding oval when start or end point in new1points
coval_coords=[]
for i in self.curovals:
coval_coords.append(self.canvas.coords(i))
if self.endpoint in new1points:
co=self.canvas.create_oval(self.endpoint[0]-2,self.endpoint[-1]-2,self.endpoint[0]+2,self.endpoint[-1]+2,width=1,outline='black',fill='black')
endco_coords =self.canvas.coords(co)
if endco_coords not in coval_coords:
self.curovals.append(co)
if self.startpoint in new1points:
co=self.canvas.create_oval(self.startpoint[0]-2,self.startpoint[-1]-2,self.startpoint[0]+2,self.startpoint[-1]+2,width=1,outline='black',fill='black')
startco_coords=self.canvas.coords(co)
if startco_coords not in coval_coords:
self.curovals.append(co)
#drawing ovals
if (self.curx,self.cury)!=self.endpoint:
self.curoval=self.canvas.create_oval(self.curx-2,self.cury-2,self.curx+2,self.cury+2,width=1,outline='black',fill='black')
if (self.curx,self.cury)==self.endpoint and self.endpoint in new1points:
self.curoval=self.canvas.create_oval(self.curx-2,self.cury-2,self.curx+2,self.cury+2,width=1,outline='black',fill='black')
self.newd1ramp= self.caluculate_ramp()
if self.continuous:
self.callbacks.CallCallbacks(self.newd1ramp)
######## convert coordinates to ramp##################
def caluculate_ramp(self):
"""
"""
dramp=[]
mypoints=[]
mynewpoints=[]
self.oldpoints.sort()
calcpoints=[]
#if self.continuous :
if hasattr(self,"curx"):
if (self.curx,self.cury) not in self.oldpoints and (self.curx,self.cury) not in [self.startpoint,self.endpoint]:
calcpoints.append((self.curx,self.cury))
if len(self.oldpoints)!=0:
for o in self.oldpoints:
if o not in calcpoints:
calcpoints.append(o)
if self.startpoint not in calcpoints:
calcpoints.append(self.startpoint)
if self.endpoint not in calcpoints:
calcpoints.append(self.endpoint)
calcpoints.sort()
length=len(calcpoints)
for l in range(length):
if l+1<=length-1:
mypoints=[calcpoints[l],calcpoints[l+1]]
if calcpoints[l] not in mynewpoints:
mynewpoints.append( calcpoints[l])
(x1,y1)=calcpoints[l]
(x2,y2)=calcpoints[l+1]
if x1>x2:
dcx=x1-x2
px=x1-1
else:
dcx=x2-x1
px=x1+1
if y1>y2:
dcy=y1-y2
if dcx>=1:
py=y1-float(dcy)/float(dcx)
else:
py=y1
else:
dcy=y2-y1
if dcx>=1:
py=y1+float(dcy)/float(dcx)
else:
py=y2
mynewpoints.append( (px,int(round(py))))
for dc in range(dcx-1):
if x1>x2:
px=px-1
else:
px=px+1
if y1>y2:
if dcx>=1:
py=py-float(dcy)/float(dcx)
else:
py=y1
else:
if dcx>=1:
py=py+float(dcy)/float(dcx)
else:
py=y2
mynewpoints.append( (px,int(round(py))))
ramp=[]
for r in mynewpoints:
#scale
ra=float(275-r[1])
if ra>=256:
ra=255.0
ramp.append(ra)
dramp=Numeric.array(ramp,'f')
if len(dramp)!=0:
return dramp
else:
dramp=Numeric.arange(0,256,1,'f')
return dramp
def get(self):
if hasattr(self,"newd1ramp"):
return self.newd1ramp
else:
return self.caluculate_ramp()
def configure(self, **kw):
if 'type' in kw.keys(): # make sure type is set first
self.setType(kw['type'])
del kw['type']
for key,value in kw.items():
if key=='callback':
self.setCallbacks(value)
def setCallbacks(self, cb):
"""Set widget callback. Must be callable function. Callback is called
every time the widget value is set/modified"""
assert cb is None or callable(cb) or type(cb) is types.ListType,\
"Illegal callback: must be either None or callable. Got %s"%cb
if cb is None: return
elif type(cb) is types.ListType:
for func in cb:
assert callable(func), "Illegal callback must be callable. Got %s"%func
self.callbacks.AddCallback(func)
else:
self.callbacks.AddCallback(cb)
self.callback = cb
def invertGraph(self):
"""This function is for inverting graph by reverse computing controlpoints"""
if self.history!=[]:
if self.history[-1][1]!=self.d1scalewheel.get():
self.history[-1]=(self.history[-1][0],self.d1scalewheel.get())
invert_points=[]
#self.oldpoints=[]
points=self.getControlPoints()
if len(points)<2:
points=[self.startpoint,self.endpoint]
for p in points:
if p[1] in range(20,276):
y=275 -(p[1]-20)
invert_points.append((p[0],y))
self.reset()
###################################################
#Some times start and end points are not deleted
#So for deleting them canvas.find_enclosed points at
#startpoint and endpoint are caluculated(returns alist of
#canvas objects present there) and if the coords of
#any canvas objects matches with start or end point that gets deleted
#####################################################
x = 50
y = 275
st_oval_1= self.canvas.find_enclosed(x-3,y-3,x+3,y+3)
if st_oval_1:
for so in st_oval_1:
if so!=[]:
st_oval=so
st_oval_coords=self.canvas.coords(st_oval)
if (int(st_oval_coords[0]+2),int(st_oval_coords[1]+2))==self.startpoint:
self.canvas.delete(st_oval)
if st_oval in self.curovals:
self.curovals.remove(st_oval)
x = 305
y = 20
end_oval_1= self.canvas.find_enclosed(x-3,y-3,x+3,y+3)
if end_oval_1:
for eo in end_oval_1:
if eo!=[]:
end_oval=eo
end_oval_coords=self.canvas.coords(end_oval)
if (int(end_oval_coords[0]+2),int(end_oval_coords[1]+2))==self.endpoint:
self.canvas.delete(end_oval)
if end_oval in self.curovals:
self.curovals.remove(end_oval)
self.canvas.delete(self.curline)
if self.Smooth:
self.curline=self.canvas.create_line(invert_points,smooth=1)
else:
self.curline=self.canvas.create_line(invert_points)
self.oldpoints=invert_points
for p in invert_points:
self.curoval=self.canvas.create_oval(p[0]-2,p[1]-2,p[0]+2,p[1]+2,width=1,outline='black',fill='black')
self.curovals.append(self.curoval)
(self.curx,self.cury) =invert_points[-2]
if self.continuous or self.mousebuttonup:
self.newd1ramp=self.caluculate_ramp()
self.callbacks.CallCallbacks([self.newd1ramp])
self.history.append((deepCopySeq(self.oldpoints),self.d1scalewheel.get()))
def defaultcurve_cb(self):
"""draws curve with default points"""
if self.history!=[]:
if self.history[-1][1]!=self.d1scalewheel.get():
self.history[-1]=(self.history[-1][0],self.d1scalewheel.get())
points=[]
self.default_points=[]
self.oldpoints=[]
self.d1scalewheel.set(0.013)
self.default_points=[(50,275),(88, 238), (101, 150), (154, 78), (75, 271),(305,20)]
self.reset()
self.canvas.delete(self.curline)
self.default_points.sort()
if self.Smooth:
self.curline=self.canvas.create_line(self.default_points,smooth=1)
else:
self.curline=self.canvas.create_line(self.default_points)
self.oldpoints=self.default_points
for p in self.default_points:
self.curoval=self.canvas.create_oval(p[0]-2,p[1]-2,p[0]+2,p[1]+2,width=1,outline='black',fill='black')
self.curovals.append(self.curoval)
(self.curx,self.cury) =self.default_points[-2]
if self.continuous or self.mousebuttonup:
self.newd1ramp=self.caluculate_ramp()
self.callbacks.CallCallbacks(self.newd1ramp)
self.history.append((deepCopySeq(self.oldpoints),self.d1scalewheel.get()))
self.default_ramp= self.newd1ramp
def read_cb(self):
fileTypes = [("Graph",'*_Graph.py'), ("any file",'*.*')]
fileBrowserTitle = "Read Graph"
fileName = self.fileOpenAsk(types=fileTypes,
title=fileBrowserTitle)
if not fileName:
return
self.read(fileName)
def read( self,fileName):
if self.history!=[]:
if self.history[-1][1]!=self.d1scalewheel.get():
self.history[-1]=(self.history[-1][0],self.d1scalewheel.get())
fptr=open(fileName,"r")
data=fptr.readlines()
cpoints=data[0][:-1]
sensitivity=data[1]
self.d1scalewheel.set(eval(sensitivity))
if len(cpoints)==0:
return
else:
points=cpoints
self.oldpoints=[]
self.reset()
if hasattr(self,"curline"):
self.canvas.delete(self.curline)
for c in self.curovals:
self.canvas.delete(c)
self.curovals.remove(c)
if hasattr(self,"curoval"):
self.canvas.delete(self.curoval)
self.curovals=[]
if self.Smooth:
self.curline=self.canvas.create_line(eval(points),smooth=1)
else:
self.curline=self.canvas.create_line(eval(points))
self.readpoints=self.oldpoints=eval(points)[1:-1]
for p in eval(points)[1:-1]:
self.curoval=self.canvas.create_oval(p[0]-2,p[1]-2,p[0]+2,p[1]+2,width=1,outline='black',fill='black')
self.curovals.append(self.curoval)
(self.curx,self.cury) =eval(points)[-2]
self.history.append((deepCopySeq(self.oldpoints),self.d1scalewheel.get()))
def fileOpenAsk(self, idir=None, ifile=None, types=None,
title='Open'):
if types==None: types = [ ('All files', '*') ]
file = tkFileDialog.askopenfilename( filetypes=types,
initialdir=idir,
initialfile=ifile,
title=title)
if file=='': file = None
return file
def write_cb(self):
fileTypes = [("Graph",'*_Graph.py'), ("any file",'*.*')]
fileBrowserTitle = "Write Graph"
fileName = self.fileSaveAsk(types=fileTypes,
title=fileBrowserTitle)
if not fileName:
return
self.write(fileName)
def write(self,fileName):
fptr=open(fileName,"w")
points= self.getControlPoints()
points.sort()
fptr.write(str(points))
fptr.write("\n")
fptr.write(str(self.d1scalewheel.get()))
fptr.close()
def fileSaveAsk(self, idir=None, ifile=None, types = None,
title='Save'):
if types==None: types = [ ('All files', '*') ]
file = tkFileDialog.asksaveasfilename( filetypes=types,
initialdir=idir,
initialfile=ifile,
title=title)
if file=='': file = None
return file
def reset(self):
"""This function deletes current line removes current ovals"""
self.canvas.delete(self.curline)
self.oldpoints=[]
for c in self.curovals:
self.canvas.delete(c)
if hasattr(self,"curoval"):
self.canvas.delete(self.curoval)
self.curovals=[]
if hasattr(self,"curoval"):
delattr(self,"curoval")
if hasattr(self,"curx"):
delattr(self,"curx")
def resetAll_cb(self):
"""Resetting curve as slant line 0 to 255"""
self.reset()
self.curline=self.canvas.create_line([self.startpoint,self.endpoint],width=1,fill='black')
for p in [self.startpoint,self.endpoint]:
self.curoval=self.canvas.create_oval(p[0]-2,p[1]-2,p[0]+2,p[1]+2,width=1,outline='black',fill='black')
self.curovals.append(self.curoval)
self.oldpoints=[self.startpoint,self.endpoint]
(self.curx,self.cury)=self.endpoint
self.d1scalewheel.set(0.013)
if self.continuous or self.mousebuttonup:
self.newd1ramp=Numeric.arange(0,256,1,'f')
self.callbacks.CallCallbacks(self.newd1ramp)
#self.histvar.set(0)
self.history=[]
def stepBack_cb(self):
"""when stepBack button clicked previous step is displayed.History of
all the steps done is remembered and when stepback clicked from history
list previous step is shown and that step is removed from history list """
if self.history!=[]:
if len(self.history)==1:
self.resetAll_cb()
else:
del self.history[-1]
pns = self.history[-1][0]
#deleting
self.oldpoints=pns
self.canvas.delete(self.curline)
for c in self.curovals:
self.canvas.delete(c)
if hasattr(self,"curoval"):
self.canvas.delete(self.curoval)
self.curovals=[]
###################################################
#Some times start and end points are not deleted
#So for deleting them canvas.find_enclosed points at
#startpoint and endpoint are caluculated(returns alist of
#canvas objects present there) and if the coords of
#any canvas objects matches with start or end point that gets deleted
#####################################################
x = 50
y = 275
st_oval_1= self.canvas.find_enclosed(x-3,y-3,x+3,y+3)
if st_oval_1:
for so in st_oval_1:
if so!=[]:
st_oval=so
st_oval_coords=self.canvas.coords(st_oval)
if (int(st_oval_coords[0]+2),int(st_oval_coords[1]+2))==self.startpoint:
self.canvas.delete(st_oval)
if st_oval in self.curovals:
self.curovals.remove(st_oval)
x = 305
y = 20
end_oval_1= self.canvas.find_enclosed(x-3,y-3,x+3,y+3)
if end_oval_1:
for eo in end_oval_1:
if eo!=[]:
end_oval=eo
end_oval_coords=self.canvas.coords(end_oval)
if (int(end_oval_coords[0]+2),int(end_oval_coords[1]+2))==self.endpoint:
self.canvas.delete(end_oval)
if end_oval in self.curovals:
self.curovals.remove(end_oval)
pns.sort()
#if no start or end points
if pns[0][0]>51 :
pns.insert(0,self.startpoint)
l=len(pns)
if pns[-1][0]<304:
pns.insert(l,self.endpoint)
#if start or endpoints and points with (50or 51) or (305or305)
if self.startpoint in pns:
for p in pns:
if p!=self.startpoint:
if p[0]== 50 or p[0]==51:
pns.remove(self.startpoint)
if self.endpoint in pns:
for p in pns:
if p!=self.endpoint:
if p[0]==305 or p[0]==304:
pns.remove(self.endpoint)
print pns
if self.Smooth:
self.curline=self.canvas.create_line(pns,width=1,fill='black',smooth=1)
else:
self.curline=self.canvas.create_line(pns,width=1,fill='black')
for p in pns:
self.curoval=self.canvas.create_oval(p[0]-2,p[1]-2,p[0]+2,p[1]+2,width=1,outline='black',fill='black')
self.curovals.append(self.curoval)
self.d1scalewheel.set(self.history[-1][1])
if self.continuous or self.mousebuttonup:
self.newd1ramp=Numeric.arange(0,256,1,'f')
self.callbacks.CallCallbacks(self.newd1ramp)
(self.curx,self.cury)=self.endpoint
def getControlPoints(self):
"""fuction to get current control points of the curve"""
if not self.oldpoints==[self.startpoint,self.endpoint]:
for i in range(len(self.oldpoints)):
if self.startpoint in self.oldpoints:
self.oldpoints.remove(self.startpoint)
if self.endpoint in self.oldpoints:
self.oldpoints.remove(self.endpoint)
self.controlpoints=[]
if hasattr(self,"curoval"):
c=self.canvas.coords(self.curoval)
if len(c)!=0:
if (int(c[0]+2),int(c[1]+2)) not in self.oldpoints and (int(c[0]+2),int(c[1]+2)) not in [self.startpoint,self.endpoint]:
self.controlpoints.append((int(c[0]+2),int(c[1]+2)))
for op in self.oldpoints:
self.controlpoints.append(op)
self.controlpoints.sort()
if len(self.controlpoints)>0:
if self.controlpoints[0][0]==50 or self.controlpoints[0][0]==51 :
pass
else:
self.controlpoints.append(self.startpoint)
self.controlpoints.sort()
if self.controlpoints[-1][0]==305 or self.controlpoints[-1][0]==304:
pass
else:
self.controlpoints.append(self.endpoint)
self.controlpoints.sort()
return self.controlpoints
def setControlPoints(self,points):
"""function to set curve control points"""
assert isinstance(points, types.ListType),"Illegal type for points"
for (x,y) in points:
assert x in range(50,306),"coordinates are out of range,x should be in [50,305]"
assert y in range(20,276),"coordinates are out of range,y should be in [20,275]"
self.oldpoints=[]
self.controlpoints=[]
self.reset()
self.oldpoints=self.controlpoints=points
self.controlpoints.sort()
if self.controlpoints[0]!=self.startpoint:
self.controlpoints.append(self.startpoint)
if self.controlpoints[-1]!=self.endpoint:
self.controlpoints.append(self.endpoint)
self.canvas.delete(self.curline)
self.controlpoints.sort()
if self.Smooth:
self.curline=self.canvas.create_line( self.controlpoints,smooth=1)
else:
self.curline=self.canvas.create_line( self.controlpoints)
for p in self.controlpoints[1:-1]:
self.curoval=self.canvas.create_oval(p[0]-2,p[1]-2,p[0]+2,p[1]+2,width=1,outline='black',fill='black')
self.curovals.append(self.curoval)
(self.curx,self.cury)= self.controlpoints[-2]
self.history.append((deepCopySeq(self.oldpoints),self.d1scalewheel.get()))
if self.continuous or self.mousebuttonup:
self.newd1ramp=self.caluculate_ramp()
self.callbacks.CallCallbacks(self.newd1ramp)
def setSensitivity(self,val):
self.d1scalewheel.set(val)
def Update(self):
if self.update==1:
dramp=self.caluculate_ramp()
self.newd1ramp=dramp
self.callbacks.CallCallbacks(dramp)
def dismiss_cb(self):
try:
if self.master.winfo_ismapped():
self.master.withdraw()
except:
if self.master.master.winfo_ismapped():
self.master.master.withdraw()
#draw Histogram
def removeHistogram(self):
"""removes Histograms"""
for b in self.bars:
self.canvas.delete(b)
self.bars=[]
def drawHistogram(self):
"""This function draws histogram from list of pixel counts ,one for
each value in the source image"""
self.removeHistogram()
if self.histvar.get():
h=self.histvalues
if h==[]:
return
list_pixels_count=h
c=[]
maxc=max(list_pixels_count)
if maxc==0:
return
if list_pixels_count.index(maxc):
list_pixels_count.remove(maxc)
list_pixels_count.insert(255,0)
for i in list_pixels_count[:256]:
max_list=max(list_pixels_count)
if max_list==0:
return
val=i*200/max_list
c.append(val)
for i in range(0,len(c)):
x1=50+i
x2=50+i
y1=275-c[i]
y2=275
r=self.canvas.create_line([(x1,y1),(x2,y2)],fill="gray70",width=1)
self.bars.append(r)
#displaying line and ovals ontop
self.canvas.tkraise(self.curline)
for i in self.curovals:
self.canvas.tkraise(i)
if hasattr(self,"curoval"):
self.canvas.tkraise(self.curoval)
self.canvas.update()
##Update Histograms on Graphtool
#if self.update!=1:
# prev_option=self.optionType.get()
# self.optionType.set(2)
# self.update=1
# self.Update()
# self.optionType.set(prev_option)
# self.update=0
# return
################SMOOTHING CODE############################
def addcurve(self,out, xy, steps):
add = out.append
for i in range(1, steps+1):
t = float(i) / steps; t2 = t*t; t3 = t2*t
u = 1.0 - t; u2 = u*u; u3 = u2*u
add(xy[0]*u3 + 3*(xy[2]*t*u2 + xy[4]*t2*u) + xy[6]*t3)
add(xy[1]*u3 + 3*(xy[3]*t*u2 + xy[5]*t2*u) + xy[7]*t3)
def smooth(self,xy, steps=12):
if not xy:
return xy
closed = xy[0] == xy[-2] and xy[1] == xy[-1]
out = []
if closed:
# connect end segment to first segment
control = (
0.500*xy[-4] + 0.500*xy[0],
0.500*xy[-3] + 0.500*xy[1],
0.167*xy[-4] + 0.833*xy[0],
0.167*xy[-3] + 0.833*xy[1],
0.833*xy[0] + 0.167*xy[2],
0.833*xy[1] + 0.167*xy[3],
0.500*xy[0] + 0.500*xy[2],
0.500*xy[1] + 0.500*xy[3],
)
out = [control[0], control[1]]
self.addcurve(out, control, steps)
else:
out = [xy[0], xy[1]]
for i in range(0, len(xy)-4, 2):
if i == 0 and not closed:
control = (xy[i],xy[i+1],0.333*xy[i] + 0.667*xy[i+2],0.333*xy[i+1] + 0.667*xy[i+3],)
else:
control = (
0.500*xy[i] + 0.500*xy[i+2],
0.500*xy[i+1] + 0.500*xy[i+3],
0.167*xy[i] + 0.833*xy[i+2],
0.167*xy[i+1] + 0.833*xy[i+3],
)
if i == len(xy)-6 and not closed:
control = control + (
0.667*xy[i+2] + 0.333*xy[i+4],
0.667*xy[i+3] + 0.333*xy[i+5],
xy[i+4],
xy[i+5],
)
else:
control = control + (
0.833*xy[i+2] + 0.167*xy[i+4],
0.833*xy[i+3] + 0.167*xy[i+5],
0.500*xy[i+2] + 0.500*xy[i+4],
0.500*xy[i+3] + 0.500*xy[i+5],
)
if ((xy[i] == xy[i+2] and xy[i+1] == xy[i+3]) or
(xy[i+2] == xy[i+4] and xy[i+3] == xy[i+5])):
out.append(control[6])
out.append(control[7])
else:
self.addcurve(out, control, steps)
return out
class Gantt:
"""
Plot a simple Gant diagram for a list of tasks.
The task are specified as a list of (name, start, end) 3-tuples
"""
def __init__(self, tasks, root=None):
# create panel if needed
if root is None:
root = Tkinter.Toplevel()
root.title("Execution profile")
self.ownsMaster = True
else:
assert isinstance(root, Tkinter.Toplevel) or\
isinstance(root, Tkinter.Frame)
self.ownsMaster = False
self.root = root
self.pixelsPersecond = 100
self.yoff = 20
self.scale = 1.0
self.scrolledCanvas = Pmw.ScrolledCanvas(
root, canvas_width=600, canvas_bg='white',
vscrollmode='static', hscrollmode='static',
horizscrollbar_width=10, vertscrollbar_width=10)
self.canvas = self.scrolledCanvas.component('canvas')
self.scrollregion=[0 , 0, 4000, 4000]
self.canvas.configure(scrollregion=tuple(self.scrollregion))
self.scrolledCanvas.pack(expand=True, fill='both')
f = self.bframe = Tkinter.Frame(root)
self.scaleTimeTW = ThumbWheel(
f, showLabel=0, width=70, height=16, type=float, value=0,
callback=self.setTimeScaleFactor_cb, continuous=True, oneTurn=10,
wheelPad=2, reportDelta=True)
self.scaleTimeTW.pack(side='right', anchor='e')
f.pack(side='bottom', expand=0, fill='x')
self.relativeData = []
self.setTasks(tasks)
def setTasks(self, tasks):
self.relativeData = []
if len(tasks)==0:
return
assert len(tasks)
assert len(tasks[0])==3
off = tasks[0][1]
for node,t0,t1 in tasks:
# name, start, length
self.relativeData.append( (node.name, t0-off, t1-t0) )
self.redraw()
def setTimeScaleFactor_cb(self, value, event=None):
self.scale = self.scale * (1.1)**value
self.redraw()
def redraw(self):
pixelPerUnit = 30000 # use that many pixels to draw mini time
cury = 20
canvas = self.canvas
canvas.delete("names")
canvas.delete("lines")
for name, start, length in self.relativeData:
scale = self.scale
x0 = 10 + scale*start*pixelPerUnit
x1 = 10 + scale*(start+length)*pixelPerUnit
canvas.create_text(x0, cury, text=name, anchor='sw',
tags=('names'), fill='magenta')
canvas.create_line(x0, cury, x1, cury, width=3,
fill='black', tags=('lines',name))
canvas.create_text(x0, cury+20, text='%.4f'%length, anchor='sw',
tags=('names'), fill='orange')
cury += self.yoff
def makeInterface(self):
""" create interface for ssh """
self.resetFrame()
colors = {
"center_x": "#ff3333",
"center_y": "green",
"center_z": "#00aaff",
"size_x": "#ff3333",
"size_y": "green",
"size_z": "#0099ff",
}
frame_set = {
"ring_bd": 1,
"ring_highlightbackground": "black",
"ring_borderwidth": 2,
"ring_highlightcolor": "black",
"ring_highlightthickness": 1,
"ring_relief": "flat",
"groupchildsite_bg": "white",
"groupchildsite_relief": "sunken",
"ring_bg": "white",
"tag_bd": "1",
"tag_highlightbackground": "black",
"tag_borderwidth": 2,
"tag_highlightcolor": "black",
"tag_highlightthickness": 1,
}
frame_set = {
"ring_bd": 1,
"ring_highlightbackground": "black",
"ring_borderwidth": 2,
"ring_highlightcolor": "black",
"ring_highlightthickness": 1,
"ring_relief": "flat",
}
frame_set = {}
bset = {"bg": "#95bed5", "width": 22, "height": 22, "relief": "raised"}
bset = {"bg": "#2e363b", "width": 22, "height": 22, "relief": "raised"}
bset = {"bg": "#a6abae", "width": 22, "height": 22, "relief": "raised"}
bset = {"bg": "#969b9d"} # 'width' : 22, 'height': 22, 'relief' : 'raised'}
bset = {}
bset.update(self.BORDER)
# left frame
lframe = tk.Frame(self.frame)
# button tollbar
tk.Frame(lframe, height=7).pack(expand=0, fill="x", padx=0, pady=0, side="top", anchor="n")
# minispacer
bframe = tk.Frame(lframe)
b = tk.Button(
bframe, text="Load...", command=self.openConfig, image=self._ICON_open, compound="left", height=14, **bset
)
b.pack(expand=1, fill="x", anchor="w", side="left", padx=1)
b.pack(expand=1, fill="x", anchor="w", side="left", padx=1)
bframe.pack(expand=0, fill="x", padx=0, pady=0, side="top", anchor="n")
########################## center wheels
self._thumbw_array = []
c_group = Pmw.Group(lframe, tag_text="Center", tag_font=self.FONTbold, **frame_set)
for lab in ["center_x", "center_y", "center_z"]:
cb = CallbackFunction(self.setWheelBox, lab)
tw = ThumbWheel(
c_group.interior(),
labCfg={"text": lab, "side": "left", "fg": colors[lab], "bg": "black", "width": 9},
showLabel=1,
width=90,
height=14,
type=float,
value=0.0,
callback=cb,
continuous=True,
oneTurn=5,
wheelPad=0,
)
tw.pack(side="top", pady=2, anchor="n")
self._thumbw_array.append(tw)
c_group.pack(side="top", anchor="n", expand=0, fill="x", ipadx=2, ipady=3, padx=1)
########################## size wheels
s_group = Pmw.Group(lframe, tag_text="Size", tag_font=self.FONTbold, **frame_set)
for lab in ["size_x", "size_y", "size_z"]:
cb = CallbackFunction(self.setWheelBox, lab)
tw = ThumbWheel(
s_group.interior(),
labCfg={"text": lab, "side": "left", "fg": colors[lab], "bg": "black", "width": 9},
showLabel=1,
width=90,
height=14,
type=float,
value=0.0,
min=0.0001,
callback=cb,
continuous=True,
oneTurn=5,
wheelPad=0,
)
tw.pack(side="top", pady=2, anchor="n")
self._thumbw_array.append(tw)
s_group.pack(side="top", anchor="n", expand=0, fill="x", ipadx=2, ipady=3, padx=1, pady=2)
########################## search settings
self.searchparmgroup = Pmw.Group(lframe, tag_text="Search parameters", tag_font=self.FONTbold, **frame_set)
# autodock search parms
self.buildSearchADPanel(target=self.searchparmgroup)
# vina search parms
self.buildSearchVinaPanel(target=self.searchparmgroup)
self.searchparmgroup.pack(side="top", anchor="n", expand=0, fill="x", ipadx=2, ipady=3, padx=1, pady=5)
########################## Receptors
self._receptors_group = Pmw.Group(
lframe, tag_text="Receptor list", tag_font=self.FONTbold, collapsedsize=3, **frame_set
)
# important
self.receptorListbox = Pmw.ScrolledListBox(
self._receptors_group.interior(),
listbox_highlightbackground="black",
# selectioncommand=self.loadreceptor,
listbox_selectbackground="yellow",
)
self.receptorListbox.pack(expand=1, fill="both", padx=3, pady=0)
self.receptorListbox.component("listbox").bind("<ButtonRelease-1>", self.loadreceptor)
self.receptorListbox.component("listbox").bind("<Button-3>", self._delreceptor)
tb = tk.Frame(self._receptors_group.interior())
# single-multi load buttons
self.recLoaderMode_single = tk.Radiobutton(
tb,
text="Single",
image=self._ICON_single,
indicatoron=False,
variable=self.recLoaderMultiMode,
value=False,
compound="left",
height=16,
**bset
)
self.recLoaderMode_single.pack(anchor="n", side="left", pady=1, expand=1, fill="x", padx=1)
self.recLoaderMode_multi = tk.Radiobutton(
tb,
text="Multi",
image=self._ICON_multi,
indicatoron=False,
variable=self.recLoaderMultiMode,
value=True,
compound="left",
height=16,
**bset
)
self.recLoaderMode_multi.pack(anchor="n", side="left", pady=1, expand=1, fill="x", padx=1)
tb.pack(expand=0, fill="x", anchor="s", side="bottom", padx=3)
self._receptors_group.pack(side="bottom", anchor="n", expand=1, fill="both", ipadx=4, ipady=4, padx=1, pady=0)
lframe.pack(side="left", anchor="n", expand="n", fill="y", padx=0, pady=0)
###### 3D Viewer
rframe = tk.Frame(self.frame)
spacer = tk.Frame(rframe, width=5) # , bg='red')
spacer.pack(expand=0, fill="y", side="left", anchor="w")
spacer.pack_propagate(0)
vgroup = Pmw.Group(rframe, tag_text="3D viewer", tag_font=self.FONTbold, groupchildsite_bg="black", **frame_set)
# TOOLBAR
vtoolbar = tk.Frame(vgroup.interior())
vtoolbar.pack(side="left", anchor="w", expand=0, fill="y")
cb = CallbackFunction(self.centerView, None)
tk.Button(
vtoolbar, text="Center\nall", image=self._ICON_center_all, width=22, height=22, command=cb, **bset
).pack(anchor="n", side="top")
cb = CallbackFunction(self.centerView, "mol")
tk.Button(
vtoolbar, text="Center\nmol", image=self._ICON_center_mol, width=22, height=22, command=cb, **bset
).pack(anchor="n", side="top")
cb = CallbackFunction(self.centerView, "box")
tk.Button(
vtoolbar, text="Center\nbox", image=self._ICON_center_box, width=22, height=22, command=cb, **bset
).pack(anchor="n", side="top", pady=1)
# 3d Viewer settings XXX TODO
# tk.Button(vtoolbar, text='Settings', image = self._ICON_sys, width=22, height=22, **bset).pack(anchor='n', side='top')
vgroup.pack(side="right", anchor="e", expand=1, fill="both", padx=0, pady=0)
# 3D viewer
self.make3Dboxviewer(vgroup.interior())
rframe.pack(side="right", anchor="n", expand=1, fill="both", padx=0, pady=0)
if self.app.dockengine == "vina":
self.setSearchParmsVina()
elif self.app.dockengine == "autodock":
self.setSearchParmsAD()
self.frame.pack(expand=1, fill="both", anchor="n", side="top")
def createSpinGui(self):
#print "createSpinGui"
self.spinGui = Tkinter.Toplevel()
self.spinGui.title('Spin Settings')
self.spinGui.protocol('WM_DELETE_WINDOW', self.spinGui.withdraw )
mainFrame = Tkinter.Frame(self.spinGui, relief='ridge', borderwidth=3)
lLabelSpinBold = Tkinter.Label(mainFrame,
text="Spinning only occurs in \"Object\" transform mode",
font=(ensureFontCase('helvetica'),10,'bold'))
lLabelSpinBold.pack(side='top')
lLabelSpin = Tkinter.Label(mainFrame,
font=(ensureFontCase('helvetica'),'9'),
justify='left',
text="""start: release the middle button while the mouse is still moving
stop: left click
"""
)
lLabelSpin.pack(side='top')
anglesFrame = Tkinter.Frame(mainFrame, relief='ridge', borderwidth=3)
# off/spin/rock radio buttons
radioFrame = Tkinter.Frame(anglesFrame)#, relief='ridge', borderwidth=3)
radioOff = Tkinter.Radiobutton(
radioFrame,
text='Off',
value=0,
variable=self.spinVar,
width=8,
indicatoron=0,
command=self.resetSpinValues,
)
radioOff.grid(row=0, column=0, sticky='we')
radioSpin = Tkinter.Radiobutton(
radioFrame,
text='Spin',
value=1,
variable=self.spinVar,
width=8,
indicatoron=0,
command=self.toggleCycle,
)
radioSpin.grid(row=0, column=1, sticky='we')
radioBounce = Tkinter.Radiobutton(
radioFrame,
text='Bounce',
value=2,
variable=self.spinVar,
width=8,
indicatoron=0,
command=self.toggleCycle,
)
radioBounce.grid(row=0, column=2, sticky='we')
radioOscillate = Tkinter.Radiobutton(
radioFrame,
text='Oscillate',
value=3,
variable=self.spinVar,
width=8,
indicatoron=0,
command=self.toggleCycle,
)
radioOscillate.grid(row=0, column=3, sticky='we')
radioFrame.pack(side='top')
self.spinGui.anglePerFrameThumbwheel = ThumbWheel(
anglesFrame,
labCfg={'text':'Angular speed (degrees per frame)', 'side':'left'},
showLabel=1,
width=90,
height=14,
min=.01,
max=10.,
type=float,
value=self.spinAnglePerFrame,
callback=self.setWithSpinGui,
continuous=True,
oneTurn=5,
wheelPad=0,
)
self.spinGui.anglePerFrameThumbwheel.pack(side='top', anchor='e')
self.spinGui.rockAngleThumbwheel = ThumbWheel(
anglesFrame,
labCfg={'text':'Rock angle (degrees)', 'side':'left'},
showLabel=1,
width=90,
height=14,
min=1,
max=360,
type=int,
value=self.rockAngle,
callback=self.setWithSpinGui,
continuous=True,
oneTurn=60,
wheelPad=0,
)
self.spinGui.rockAngleThumbwheel.pack(side='top', anchor='e')
def shiftRockCenter(val):
lSpinRotMat = self.makeSpinRotationMat(self.spinAxis, -val)
c = self.camera()
c.viewer.rootObject.ConcatRotation(lSpinRotMat)
c.Redraw()
vi.afterRedraw()
shiftRockCenterThumbwheel.set(0, update=0)
shiftRockCenterThumbwheel = ThumbWheel(
anglesFrame,
labCfg={'text':'Shift rock center', 'side':'left'},
showLabel=0,
width=90,
height=14,
min=-100,
max=100,
type=int,
value=0,
callback=shiftRockCenter,
continuous=True,
oneTurn=90,
wheelPad=0,
)
shiftRockCenterThumbwheel.pack(side='top', anchor='e')
anglesFrame.pack(side='top')
self.spinGui.vectorGUI = vectorGUI(mainFrame,
size=150,
vector=self.spinAxis,
callback=self.setWithSpinGui,
)
mainFrame.pack(side='top')
class ColorMapLegend(Insert2d):
"""Class for displaying a colormap legend.
arguments for the constructor or Set method are:
ramp: Numeric array of shape Nx3 or Nx4 (default is RBGRamp())
height: height of colormap legend
width: width of colormap legend
interp: 1 or 0 to turn color interpolation on and off resp.
mini: minimum values (i.e which corresponds to the first color)
maxi: maximum values (i.e which corresponds to the last color)
If interp is set to 1 QUAD_STRIPS are used and colors are interpolated,
else one QUAD is drawn for each entry in the colormap.
If the color provide alpha values, a chechered background is drawn.
"""
keywords = Insert2d.keywords + [
'ramp',
'height',
'width',
'interp', # 1: for color interpolation, or 0
'mini', #
'maxi', #
'labelValues', # floating point numbers to be written below cml
'glfFont',
'fontScale',
'numOfLabels',
'unitsString',
'interp',
'visibleFrame',
'invertLabelsColor',
]
glfVectorFontList = [
'arial1.glf',
'courier1.glf',
'crystal1.glf',
'techno0.glf',
'techno1.glf',
'times_new1.glf',
'aksent1.glf',
'alpine1.glf',
'broadway1.glf',
'chicago1.glf',
'compact1.glf',
'cricket1.glf',
'garamond1.glf',
'gothic1.glf',
'penta1.glf',
'present_script1.glf'
]
def __init__(self, colormapgui, name='color map legend', check=1, **kw):
# GLF FONTS Initialisations
glf.glfInit()
glf.glfEnable(glf.GLF_CONSOLE_MESSAGES)
lGlfModulePath = os.path.split(glf.__file__)[-2]
lPathToFonts = lGlfModulePath+os.sep+'fonts'+os.sep
self.glfVectorFontLoadIdDict = {}
for font in self.glfVectorFontList:
self.glfVectorFontLoadIdDict[font] = glf.glfLoadFont(lPathToFonts+font)
self.fontScale = 8
self.glfFontID = 0
# other initialisations
self.colormapguiRef = ref(colormapgui)
self.resizeSpotRadius = 5
self.resizeSpot = None
self.verticalLegend = True
self.mini = None
self.maxi = None
kw['ramp'] = RGBRamp()
kw['height'] = 1.
kw['width'] = len(kw['ramp'])
kw['interp'] = 1
# kw['mini'] = None
# kw['maxi'] = None
kw['labelValues'] = []
kw['numOfLabels'] = 5
kw['unitsString'] = 'law'
kw['invertLabelsColor'] = False
kw['visibleFrame'] = True
#kw['protected'] = True
kw['immediateRendering'] = False
kw['visible'] = False
kw['transparent'] = True
kw['size'] = [12, 120] # override the default value in Insert2d
self.clickPosFromLegendBottomLeft = [0, 0]
apply( Insert2d.__init__, (self, name, check), kw)
# Insert2d initialisations
# (need to be done after the Insert2d.__init__ otherwise it overrides)
self.needsRedoDpyListOnResize = True
self.initialPosition = [1, 350] # override the default value in Insert2d
self.coord2d = deepcopy(self.initialPosition) # 2d coordinates in pixels from top left
self.animatable = False
def Set(self, check=1, redo=1, updateOwnGui=True, **kw):
"""set data for this object: add faces (polygon or lines) to this object
check=1 : verify that all the keywords present can be handle by this func
redo=1 : append self to viewer.objectsNeedingRedo
updateOwnGui=True : allow to update owngui at the end this func
"""
#print "colorMapLegend.Set"
redoFlags = apply( Insert2d.Set, (self, check, 0), kw)
ramp=kw.get('ramp')
if ramp is not None:
assert len(ramp) > 0
assert len(ramp[0])==3 or len(ramp[0])==4
self.ramp = ramp
redoFlags |= self._redoFlags['redoDisplayListFlag']
height = kw.get('height')
if height:
assert height > 0.0
self.height = height
redoFlags |= self._redoFlags['redoDisplayListFlag']
width = kw.get('width')
if width:
assert width > 0.0
self.width = width
redoFlags |= self._redoFlags['redoDisplayListFlag']
mini = kw.get('mini')
if mini is not None:
#assert isinstance(mini, types.FloatType)
self.mini = mini
redoFlags |= self._redoFlags['redoDisplayListFlag']
maxi = kw.get('maxi')
if maxi is not None:
#assert isinstance(maxi, types.FloatType)
self.maxi = maxi
redoFlags |= self._redoFlags['redoDisplayListFlag']
labelValues = kw.get('labelValues')
if labelValues is not None:
# for v in labelValues:
# assert isinstance(v, types.FloatType)
self.labelValues = labelValues
redoFlags |= self._redoFlags['updateOwnGuiFlag']
redoFlags |= self._redoFlags['redoDisplayListFlag']
glfFont = kw.get('glfFont')
if glfFont is not None:
if glfFont in self.glfVectorFontLoadIdDict.keys():
self.glfFontID = self.glfVectorFontLoadIdDict[glfFont]
redoFlags |= self._redoFlags['updateOwnGuiFlag']
redoFlags |= self._redoFlags['redoDisplayListFlag']
fontScale = kw.get('fontScale')
if fontScale is not None:
assert isinstance(fontScale, types.IntType)
self.fontScale = fontScale
redoFlags |= self._redoFlags['updateOwnGuiFlag']
redoFlags |= self._redoFlags['redoDisplayListFlag']
numOfLabels = kw.get('numOfLabels')
if numOfLabels is not None:
assert isinstance(numOfLabels, types.IntType)
self.numOfLabels = numOfLabels
redoFlags |= self._redoFlags['updateOwnGuiFlag']
redoFlags |= self._redoFlags['redoDisplayListFlag']
unitsString = kw.get('unitsString')
if unitsString is not None:
self.unitsString = unitsString
redoFlags |= self._redoFlags['updateOwnGuiFlag']
redoFlags |= self._redoFlags['redoDisplayListFlag']
interp = kw.get('interp')
if interp is not None:
assert interp in (0, 1)
self.interp = interp
redoFlags |= self._redoFlags['updateOwnGuiFlag']
redoFlags |= self._redoFlags['redoDisplayListFlag']
visibleFrame = kw.get('visibleFrame')
if visibleFrame is not None:
self.visibleFrame = visibleFrame
redoFlags |= self._redoFlags['updateOwnGuiFlag']
redoFlags |= self._redoFlags['redoDisplayListFlag']
invertLabelsColor = kw.get('invertLabelsColor')
if invertLabelsColor is not None:
self.invertLabelsColor = invertLabelsColor
redoFlags |= self._redoFlags['updateOwnGuiFlag']
redoFlags |= self._redoFlags['redoDisplayListFlag']
return self.redoNow(redo, updateOwnGui, redoFlags)
def Draw(self):
#print "colorMapLegend.Draw", self
if self.viewer.tileRender:
tile = self.getTile()
#print "tile", tile
else:
tile = None
fullWidth = self.viewer.currentCamera.width
fullHeight = self.viewer.currentCamera.height
if self.invertLabelsColor is False:
backgroundColor = (
self.viewer.currentCamera.backgroundColor[0],
self.viewer.currentCamera.backgroundColor[1],
self.viewer.currentCamera.backgroundColor[2],
.5)
else:
backgroundColor = (
1-self.viewer.currentCamera.backgroundColor[0],
1-self.viewer.currentCamera.backgroundColor[1],
1-self.viewer.currentCamera.backgroundColor[2],
.5)
from DejaVu.Legend import drawSelfOrientedLegend
self.polygonContour , self.resizeSpot , self.verticalLegend = drawSelfOrientedLegend(
fullWidth=fullWidth,
fullHeight=fullHeight,
tile=tile,
ramp=self.ramp,
mini=self.mini,
maxi=self.maxi,
name=self.name,
unit=self.unitsString,
labelValues=self.labelValues,
roomLeftToLegend=self.coord2d[0],
roomBelowLegend=fullHeight-self.coord2d[1],
legendShortSide=self.size[0],
legendLongSide=self.size[1],
significantDigits=3,
backgroundColor=backgroundColor,
interpolate=self.interp,
frame=self.visibleFrame,
selected=(self.viewer.currentObject == self),
numOfLabels=self.numOfLabels,
resizeSpotRadius=self.resizeSpotRadius,
fontScale=self.fontScale,
glfFontID=self.glfFontID,
)
return 1
def pickDraw(self):
"""called by the picking process to operate the selection
"""
#print "colorMapLegend.pickDraw", self
# we draw just flat quad of the insert2d
GL.glMatrixMode(GL.GL_PROJECTION)
GL.glPushMatrix()
#GL.glLoadIdentity()
GL.glLoadMatrixf(self.viewer.currentCamera.pickMatrix)
GL.glOrtho(0, float(self.viewer.currentCamera.width),
0, float(self.viewer.currentCamera.height), -1, 1)
GL.glMatrixMode(GL.GL_MODELVIEW)
GL.glPushMatrix()
GL.glLoadIdentity()
GL.glPolygonMode(GL.GL_FRONT, GL.GL_FILL)
#GL.glColor3f(1,0,0)
if self.resizeSpot is not None:
GL.glPushName(1)
GL.glBegin(GL.GL_QUADS)
GL.glVertex2f(float(self.resizeSpot[0]+self.resizeSpotRadius),
float(self.resizeSpot[1]-self.resizeSpotRadius))
GL.glVertex2f(float(self.resizeSpot[0]+self.resizeSpotRadius),
float(self.resizeSpot[1]+self.resizeSpotRadius))
GL.glVertex2f(float(self.resizeSpot[0]-self.resizeSpotRadius),
float(self.resizeSpot[1]+self.resizeSpotRadius))
GL.glVertex2f(float(self.resizeSpot[0]-self.resizeSpotRadius),
float(self.resizeSpot[1]-self.resizeSpotRadius))
GL.glEnd()
GL.glPopName()
GL.glPushName(0)
GL.glBegin(GL.GL_QUADS)
GL.glVertex2fv(self.polygonContour[0])
GL.glVertex2fv(self.polygonContour[1])
GL.glVertex2fv(self.polygonContour[2])
GL.glVertex2fv(self.polygonContour[3])
GL.glEnd()
GL.glPopName()
GL.glMatrixMode(GL.GL_PROJECTION)
GL.glPopMatrix()
GL.glMatrixMode(GL.GL_MODELVIEW)
GL.glPopMatrix()
def setPosition(self, event, redo=1):
"""the trackball transmit the translation info
"""
#print "colorMapLegend.setPosition", event.x, event.y
self.coord2d[0] = event.x - self.clickPosFromLegendBottomLeft[0]
self.coord2d[1] = event.y - self.clickPosFromLegendBottomLeft[1]
if self.coord2d[0] < 0:
self.coord2d[0] = 0
if self.coord2d[1] < 0:
self.coord2d[1] = 0
if self.coord2d[0] > self.viewer.currentCamera.width:
self.coord2d[0] = self.viewer.currentCamera.width
if self.coord2d[1] > self.viewer.currentCamera.height:
self.coord2d[1] = self.viewer.currentCamera.height
self.viewer.objectsNeedingRedo[self] = None
def setSize(self, event, redo=1):
"""override the Insert2d function
"""
#print "colorMapLegend.setSize", self
if self.verticalLegend is True:
self.size[0] = event.x - self.coord2d[0]
self.size[1] = self.coord2d[1] - event.y
if self.size[0] > self.viewer.currentCamera.width:
self.size[0] = self.viewer.currentCamera.width
if self.size[1] > self.viewer.currentCamera.height:
self.size[1] = self.viewer.currentCamera.height
else:
self.size[1] = event.x - self.coord2d[0]
self.size[0] = self.coord2d[1] - event.y
if self.size[1] > self.viewer.currentCamera.width:
self.size[1] = self.viewer.currentCamera.width
if self.size[0] > self.viewer.currentCamera.height:
self.size[0] = self.viewer.currentCamera.height
if self.size[0] < 1:
self.size[0] = 1
if self.size[1] < 1:
self.size[1] = 1
if self.needsRedoDpyListOnResize and self.viewer:
self.viewer.objectsNeedingRedo[self] = None
def ResetPosition(self):
self.coord2d = deepcopy(self.initialPosition)
if self.viewer:
self.viewer.objectsNeedingRedo[self] = None
def respondToDoubleClick(self, event):
"""
"""
self.showOwnGui()
if self.needsRedoDpyListOnResize and self.viewer:
self.viewer.objectsNeedingRedo[self] = None
def processHit_cb(self, pick):
#print "colorMapLegend.processHit_cb", self
#print "pick",pick
#print "pick.event",dir(pick)
#print "pick.type",pick.type
#print "pick.event",dir(pick.event)
#print "pick.event",pick.event
#print "pick.event.type",pick.event.type
#print "pick.event.state",pick.event.state
#print "pick.event.time",pick.event.time
#print "pick.hits",pick.hits
if ( len(pick.hits) == 1) and pick.hits.has_key(self):
if self.viewer.currentObject != self:
# if the only hit is the legend,
# it becomes the current object
self.viewer.SetCurrentObject(self)
self.isMoving = True
elif pick.event.time - self.lastPickEventTime < 200: #double click
self.viewer.SetCurrentObject(self.viewer.rootObject)
self.respondToDoubleClick(pick.event)
elif pick.hits[self][0][0] == 1:
# the click in inside the resize button
#print "resize"
self.isMoving = False
elif pick.hits[self][0][0] == 0:
# the click in inside the legend but outside
# the resize button
self.isMoving = True
self.clickPosFromLegendBottomLeft = [pick.event.x - self.coord2d[0],
pick.event.y - self.coord2d[1]]
#print "self.clickPosFromLegendBottomLeft", self.clickPosFromLegendBottomLeft
if self.viewer:
self.viewer.objectsNeedingRedo[self] = None
elif self.viewer.currentObject == self:
#print "the insert2d is selected, but picking is outside"
self.isMoving = None
self.viewer.SetCurrentObject(self.viewer.rootObject)
if self.needsRedoDpyListOnResize and self.viewer:
self.viewer.objectsNeedingRedo[self] = None
self.lastPickEventTime = pick.event.time
def createOwnGui(self):
self.ownGui = Tkinter.Toplevel()
self.ownGui.title(self.name)
self.ownGui.protocol('WM_DELETE_WINDOW', self.ownGui.withdraw )
frame1 = Tkinter.Frame(self.ownGui)
frame1.pack(side='top')
#unit
self.unitsEnt = Pmw.EntryField(frame1,
label_text='Units ',
labelpos='w',
value=self.unitsString,
command=self.setWithOwnGui)
self.unitsEnt.pack(side='top', fill='x')
#glf vector font
self.glfFont = Tkinter.StringVar()
self.glfFont.set('chicago1.glf')
self.glfFontCB = Pmw.ComboBox(frame1, label_text='Font ',
labelpos='w',
entryfield_value=self.glfFont.get(),
scrolledlist_items=self.glfVectorFontList,
selectioncommand=self.setWithOwnGui)
self.glfFontCB.pack(side='top', fill='x')
#fontScale
self.fontScaleThumb = ThumbWheel(frame1,
labCfg={'text':'font scale ', 'side':'left'},
showLabel=1,
width=90,
height=14,
min=0,
max=200,
type=int,
value=self.fontScale,
callback=self.setWithOwnGui,
continuous=True,
oneTurn=10,
wheelPad=0)
self.fontScaleThumb.pack(side='top')
#label
lLabelValuesString = ''
for lLabelValue in self.labelValues:
lLabelValuesString += str(lLabelValue) + ' '
self.labelValsEnt = Pmw.EntryField(
frame1,
label_text='Numeric labels ',
labelpos='w',
value=lLabelValuesString,
command=self.setWithOwnGui)
self.labelValsEnt.component('entry').config(width=6)
self.labelValsEnt.pack(side='top', fill='x')
#numOfLabel
self.numOfLabelsCtr = ThumbWheel(frame1,
labCfg={'text':'Automatic labels', 'side':'left'},
showLabel=1,
width=90,
height=14,
min=0,
max=200,
type=int,
value=self.numOfLabels,
callback=self.setWithOwnGui,
continuous=True,
oneTurn=20,
wheelPad=0)
self.numOfLabelsCtr.pack(side='top')
# Interpolate
self.interpVar = Tkinter.IntVar()
self.interpVar.set(0)
self.checkBoxFrame = Tkinter.Checkbutton(
frame1,
text='Interpolate',
variable=self.interpVar,
command=self.setWithOwnGui)
self.checkBoxFrame.pack(side='top')
# frame
self.frameVar = Tkinter.IntVar()
self.frameVar.set(1)
self.checkBoxFrame = Tkinter.Checkbutton(
frame1,
text='Frame',
variable=self.frameVar,
command=self.setWithOwnGui)
self.checkBoxFrame.pack(side='top')
# invert labels color
self.invertLabelsColorVar = Tkinter.IntVar()
self.invertLabelsColorVar.set(0)
self.checkBoxinvertLabelsColor = Tkinter.Checkbutton(
frame1,
text='Invert labels color',
variable=self.invertLabelsColorVar,
command=self.setWithOwnGui)
#self.checkBoxFrame.pack(side='top')
self.checkBoxinvertLabelsColor.pack(side='top')
# colormapguiwidget:
self.launchColormapWidget = Tkinter.Button(
frame1,
text="Show colormap settings",
command=self.colormapguiRef().showColormapSettings_cb
)
self.launchColormapWidget.pack(side='top', fill='x')
def setWithOwnGui(self, event=None):
#print "setWithOwnGui"
glfFont = self.glfFontCB.get()
fontScale = int(self.fontScaleThumb.get())
labelValues = map(float, string.split(self.labelValsEnt.get()))
unitsString = self.unitsEnt.get()
numOfLabels = int(self.numOfLabelsCtr.get())
if self.interpVar.get() == 1:
interp = True
else:
interp = False
if self.frameVar.get() == 1:
visibleFrame = True
else:
visibleFrame = False
if self.invertLabelsColorVar.get() == 1:
invertLabelsColor = True
else:
invertLabelsColor = False
self.Set(
glfFont=glfFont,
fontScale=fontScale,
labelValues=labelValues,
numOfLabels=numOfLabels,
unitsString=unitsString,
interp=interp,
visibleFrame=visibleFrame,
invertLabelsColor=invertLabelsColor,
updateOwnGui=False)
self.viewer.Redraw()
def updateOwnGui(self):
if self.ownGui is None:
return
self.ownGui.title(self.name)
self.glfFontCB.selectitem(self.glfFont.get())
self.fontScaleThumb.set(self.fontScale)
lLabelValuesString = ''
for lLabelValue in self.labelValues:
lLabelValuesString += str(lLabelValue) + ' '
self.labelValsEnt.setentry(lLabelValuesString)
self.unitsEnt.setentry(self.unitsString)
self.numOfLabelsCtr.set(self.numOfLabels)
self.interpVar.set(self.interp)
self.invertLabelsColorVar.set(self.visibleFrame)
self.invertLabelsColorVar.set(self.invertLabelsColor)
class Gantt:
"""
Plot a simple Gant diagram for a list of tasks.
The task are specified as a list of (name, start, end) 3-tuples
"""
def __init__(self, tasks, root=None):
# create panel if needed
if root is None:
root = Tkinter.Toplevel()
root.title("Execution profile")
self.ownsMaster = True
else:
assert isinstance(root, Tkinter.Toplevel) or\
isinstance(root, Tkinter.Frame)
self.ownsMaster = False
self.root = root
self.pixelsPersecond = 100
self.yoff = 20
self.scale = 1.0
self.scrolledCanvas = Pmw.ScrolledCanvas(root,
canvas_width=600,
canvas_bg='white',
vscrollmode='static',
hscrollmode='static',
horizscrollbar_width=10,
vertscrollbar_width=10)
self.canvas = self.scrolledCanvas.component('canvas')
self.scrollregion = [0, 0, 4000, 4000]
self.canvas.configure(scrollregion=tuple(self.scrollregion))
self.scrolledCanvas.pack(expand=True, fill='both')
f = self.bframe = Tkinter.Frame(root)
self.scaleTimeTW = ThumbWheel(f,
showLabel=0,
width=70,
height=16,
type=float,
value=0,
callback=self.setTimeScaleFactor_cb,
continuous=True,
oneTurn=10,
wheelPad=2,
reportDelta=True)
self.scaleTimeTW.pack(side='right', anchor='e')
f.pack(side='bottom', expand=0, fill='x')
self.relativeData = []
self.setTasks(tasks)
def setTasks(self, tasks):
self.relativeData = []
if len(tasks) == 0:
return
assert len(tasks)
assert len(tasks[0]) == 3
off = tasks[0][1]
for node, t0, t1 in tasks:
# name, start, length
self.relativeData.append((node.name, t0 - off, t1 - t0))
self.redraw()
def setTimeScaleFactor_cb(self, value, event=None):
self.scale = self.scale * (1.1)**value
self.redraw()
def redraw(self):
pixelPerUnit = 30000 # use that many pixels to draw mini time
cury = 20
canvas = self.canvas
canvas.delete("names")
canvas.delete("lines")
for name, start, length in self.relativeData:
scale = self.scale
x0 = 10 + scale * start * pixelPerUnit
x1 = 10 + scale * (start + length) * pixelPerUnit
canvas.create_text(x0,
cury,
text=name,
anchor='sw',
tags=('names'),
fill='magenta')
canvas.create_line(x0,
cury,
x1,
cury,
width=3,
fill='black',
tags=('lines', name))
canvas.create_text(x0,
cury + 20,
text='%.4f' % length,
anchor='sw',
tags=('names'),
fill='orange')
cury += self.yoff
