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| + | {{Infobox script-repo |
| + | |type = plugin |
| + | |filename = plugins/dynoplot.py |
| + | |author = [[User:Tmwsiy|Dan Kulp]] |
| + | |license = - |
| + | }} |
| + | == Introduction == |
| This script was setup to do generic plotting, that is given a set of data and axis labels it would create a plot. Initially, I had it setup to draw the plot directly in the PyMol window (allowing for both 2D and 3D style plots), but because I couldn't figure out how to billboard CGO objects (Warren told me at the time that it couldn't be done) I took a different approach. The plot now exists in it's own window and can only do 2D plots. It is however interactive. I only have here a Rama.(phi,psi) plot, but the code can be easily extended to other types of data. For instance, I had this working for an energy vs distance data that I had generated by another script. | | This script was setup to do generic plotting, that is given a set of data and axis labels it would create a plot. Initially, I had it setup to draw the plot directly in the PyMol window (allowing for both 2D and 3D style plots), but because I couldn't figure out how to billboard CGO objects (Warren told me at the time that it couldn't be done) I took a different approach. The plot now exists in it's own window and can only do 2D plots. It is however interactive. I only have here a Rama.(phi,psi) plot, but the code can be easily extended to other types of data. For instance, I had this working for an energy vs distance data that I had generated by another script. |
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| | | |
| ===USAGE=== | | ===USAGE=== |
− | rama SELECTION | + | |
| + | rama [ sel [, name [, symbols [, filename ]]]] |
| | | |
| ===EXAMPLES=== | | ===EXAMPLES=== |
− | *load pdb file 1ENV (download it or use the PDB loader plugin)
| |
− | *select sel01, resi 129-136
| |
− | *rama sel01
| |
− | *rock # the object needs to be moving in order for the angles to be updated.
| |
| | | |
− | ===SCRIPTS (DynoPlot.py)===
| + | <source lang="python"> |
− | DynoPlot.py
| + | fetch 1ENV, async=0 # (download it or use the PDB loader plugin) |
− | <source lang="python">
| + | select sel01, resi 129-136 |
− | ###############################################
| + | rama sel01 |
− | # File: DynoPlot.py
| + | rock # the object needs to be moving in order for the angles to be updated. |
− | # Author: Dan Kulp
| + | </source> |
− | # Creation Date: 8/29/05
| |
− | #
| |
− | # Modified 2011-09-20 by Thomas Holder
| |
− | #
| |
− | # Notes:
| |
− | # Draw plots that display interactive data.
| |
− | # Phi,Psi plot shown.
| |
− | ###############################################
| |
− | | |
− | | |
− | from __future__ import division
| |
− | from __future__ import generators
| |
− | | |
− | import Tkinter
| |
− | from pymol import cmd
| |
− | | |
− | # workaround: Set to True if nothing gets drawn on canvas, for example on linux with "pymol -x"
| |
− | with_mainloop = False
| |
− | | |
− | class SimplePlot(Tkinter.Canvas):
| |
− | | |
− | # Class variables
| |
− | mark = 'Oval' # Only 'Oval' for now..
| |
− | mark_size = 4
| |
− | | |
− | def __init__(self, *args, **kwargs):
| |
− | Tkinter.Canvas.__init__(self, *args, **kwargs)
| |
− | self.xlabels = [] # axis labels
| |
− | self.ylabels = []
| |
− | self.spacingx = 0 # spacing in x direction
| |
− | self.spacingy = 0
| |
− | self.xmin = 0 # min value from each axis
| |
− | self.ymin = 0
| |
− | self.lastx = 0 # previous x,y pos of mouse
| |
− | self.lasty = 0
| |
− | self.isdown = 0 # flag for mouse pressed
| |
− | self.item = (0,) # items array used for clickable events
| |
− | self.shapes = {} # store plot data, x,y etc..
| |
− | self.idx2resn = {} # residue name mapping
| |
− | | |
− | def axis(self,xmin=40,xmax=300,ymin=10,ymax=290,xint=290,yint=40,xlabels=[],ylabels=[]):
| |
− | | |
− | # Store variables in self object
| |
− | self.xlabels = xlabels
| |
− | self.ylabels = ylabels
| |
− | self.spacingx = (xmax-xmin) / (len(xlabels) - 1)
| |
− | self.spacingy = (ymax-ymin) / (len(ylabels) - 1)
| |
− | self.xmin = xmin
| |
− | self.ymin = ymin
| |
− | | |
− | # Create axis lines
| |
− | self.create_line((xmin,xint,xmax,xint),fill="black",width=3)
| |
− | self.create_line((yint,ymin,yint,ymax),fill="black",width=3)
| |
− | | |
− | # Create tick marks and labels
| |
− | nextspot = xmin
| |
− | for label in xlabels:
| |
− | self.create_line((nextspot, xint+5,nextspot, xint-5),fill="black",width=2)
| |
− | self.create_text(nextspot, xint-15, text=label)
| |
− | if len(xlabels) == 1:
| |
− | nextspot = xmax
| |
− | else:
| |
− | nextspot += (xmax - xmin)/ (len(xlabels) - 1)
| |
− | | |
− | | |
− | nextspot = ymax
| |
− | for label in ylabels:
| |
− | self.create_line((yint+5,nextspot,yint-5,nextspot),fill="black",width=2)
| |
− | self.create_text(yint-20,nextspot,text=label)
| |
− | if len(ylabels) == 1:
| |
− | nextspot = ymin
| |
− | else:
| |
− | nextspot -= (ymax - ymin)/ (len(ylabels) - 1)
| |
− | | |
− | | |
− | # Plot a point
| |
− | def plot(self,xp,yp,meta):
| |
− | | |
− | # Convert from 'label' space to 'pixel' space
| |
− | x = self.convertToPixel("X",xp)
| |
− | y = self.convertToPixel("Y",yp)
| |
− | | |
− | resn = self.idx2resn.get(meta)
| |
− | mark = {'GLY': 'Tri', 'PRO': 'Rect'}.get(resn, self.mark)
| |
− | | |
− | if mark == 'Oval':
| |
− | create_shape = self.create_oval
| |
− | coords = [x-self.mark_size, y-self.mark_size,
| |
− | x+self.mark_size, y+self.mark_size]
| |
− | elif mark == 'Tri':
| |
− | create_shape = self.create_polygon
| |
− | coords = [x, y-self.mark_size,
| |
− | x+self.mark_size, y+self.mark_size,
| |
− | x-self.mark_size, y+self.mark_size]
| |
− | else:
| |
− | create_shape = self.create_rectangle
| |
− | coords = [x-self.mark_size, y-self.mark_size,
| |
− | x+self.mark_size, y+self.mark_size]
| |
− | | |
− | oval = create_shape(*coords,
| |
− | width=1, outline="black", fill="SkyBlue2")
| |
− | self.shapes[oval] = [x,y,0,xp,yp,meta]
| |
− | | |
− | # Convert from pixel space to label space
| |
− | def convertToLabel(self,axis, value):
| |
− | | |
− | # Defaultly use X-axis info
| |
− | label0 = self.xlabels[0]
| |
− | label1 = self.xlabels[1]
| |
− | spacing = self.spacingx
| |
− | min = self.xmin
| |
− | | |
− | # Set info for Y-axis use
| |
− | if axis == "Y":
| |
− | label0 = self.ylabels[0]
| |
− | label1 = self.ylabels[1]
| |
− | spacing = self.spacingy
| |
− | min = self.ymin
| |
− | | |
− | pixel = value - min
| |
− | label = pixel / spacing
| |
− | label = label0 + label * abs(label1 - label0)
| |
− | | |
− | if axis == "Y":
| |
− | label = - label
| |
− | | |
− | return label
| |
− | | |
− | # Converts value from 'label' space to 'pixel' space
| |
− | def convertToPixel(self,axis, value):
| |
− | | |
− | # Defaultly use X-axis info
| |
− | label0 = self.xlabels[0]
| |
− | label1 = self.xlabels[1]
| |
− | spacing = self.spacingx
| |
− | min = self.xmin
| |
− | | |
− | # Set info for Y-axis use
| |
− | if axis == "Y":
| |
− | label0 = self.ylabels[0]
| |
− | label1 = self.ylabels[1]
| |
− | spacing = self.spacingy
| |
− | min = self.ymin
| |
− | | |
− | # Get axis increment in 'label' space
| |
− | inc = abs(label1 - label0)
| |
− | | |
− | # 'Label' difference from value and smallest label (label0)
| |
− | diff = float(value - label0)
| |
− | | |
− | # Get whole number in 'label' space
| |
− | whole = int(diff / inc)
| |
− | | |
− | # Get fraction number in 'label' space
| |
− | part = float(float(diff/inc) - whole)
| |
− | | |
− | # Return 'pixel' position value
| |
− | pixel = whole * spacing + part * spacing
| |
− | | |
− | # Reverse number by subtracting total number of pixels - value pixels
| |
− | if axis == "Y":
| |
− | tot_label_diff = float(self.ylabels[-1] - label0)
| |
− | tot_label_whole = int(tot_label_diff / inc)
| |
− | tot_label_part = float(float(tot_label_diff / inc) - tot_label_whole)
| |
− | tot_label_pix = tot_label_whole * spacing + tot_label_part *spacing
| |
− | | |
− | pixel = tot_label_pix - pixel
| |
− | | |
− | # Add min edge pixels
| |
− | pixel = pixel + min
| |
− | | |
− | return pixel
| |
− | | |
− | | |
− | # Print out which data point you just clicked on..
| |
− | def pickWhich(self,event):
| |
− | | |
− | # Find closest data point
| |
− | x = event.widget.canvasx(event.x)
| |
− | y = event.widget.canvasx(event.y)
| |
− | spot = event.widget.find_closest(x,y)
| |
− | | |
− | # Print the shape's meta information corresponding with the shape that was picked
| |
− | if spot[0] in self.shapes:
| |
− | cmd.select('sele', '(%s`%d)' % self.shapes[spot[0]][5])
| |
− | cmd.iterate('sele', 'print " You clicked /%s/%s/%s/%s`%s/%s (DynoPlot)" %' + \
| |
− | ' (model, segi, chain, resn, resi, name)')
| |
− | cmd.center('byres sele', animate=1)
| |
− | | |
− | # Mouse Down Event
| |
− | def down(self,event):
| |
− | | |
− | # Store x,y position
| |
− | self.lastx = event.x
| |
− | self.lasty = event.y
| |
− | | |
− | # Find the currently selected item
| |
− | x = event.widget.canvasx(event.x)
| |
− | y = event.widget.canvasx(event.y)
| |
− | self.item = event.widget.find_closest(x,y)
| |
− | | |
− | # Identify that the mouse is down
| |
− | self.isdown = 1
| |
− | | |
− | # Mouse Up Event
| |
− | def up(self,event):
| |
− | | |
− | # Get label space version of x,y
| |
− | labelx = self.convertToLabel("X",event.x)
| |
− | labely = self.convertToLabel("Y",event.y)
| |
− | | |
− | # Convert new position into label space..
| |
− | if self.item[0] in self.shapes:
| |
− | self.shapes[self.item[0]][0] = event.x
| |
− | self.shapes[self.item[0]][1] = event.y
| |
− | self.shapes[self.item[0]][2] = 1
| |
− | self.shapes[self.item[0]][3] = labelx
| |
− | self.shapes[self.item[0]][4] = labely
| |
− | | |
− | # Reset Flags
| |
− | self.item = (0,)
| |
− | self.isdown = 0
| |
− | | |
− | # Mouse Drag(Move) Event
| |
− | def drag(self,event):
| |
− | | |
− | # Check that mouse is down and item clicked is a valid data point
| |
− | if self.isdown and self.item[0] in self.shapes:
| |
− | | |
− | self.move(self.item, event.x - self.lastx, event.y - self.lasty)
| |
− | | |
− | self.lastx = event.x
| |
− | self.lasty = event.y
| |
− | | |
− | def set_phipsi(model, index, phi, psi):
| |
− | atsele = [
| |
− | 'first ((%s`%d) extend 2 and name C)' % (model, index), # prev C
| |
− | 'first ((%s`%d) extend 1 and name N)' % (model, index), # this N
| |
− | '(%s`%d)' % (model, index), # this CA
| |
− | 'last ((%s`%d) extend 1 and name C)' % (model, index), # this C
| |
− | 'last ((%s`%d) extend 2 and name N)' % (model, index), # next N
| |
− | ]
| |
− | try:
| |
− | cmd.set_dihedral(atsele[0], atsele[1], atsele[2], atsele[3], phi)
| |
− | cmd.set_dihedral(atsele[1], atsele[2], atsele[3], atsele[4], psi)
| |
− | except:
| |
− | print ' DynoPlot Error: cmd.set_dihedral failed'
| |
− | | |
− | # New Callback object, so that we can update the structure when phi,psi points are moved.
| |
− | class DynoRamaObject:
| |
− | def __init__(self, selection=None, name=None):
| |
− | from pymol import _ext_gui as pmgapp
| |
− | if pmgapp is not None:
| |
− | import Pmw
| |
− | rootframe = Pmw.MegaToplevel(pmgapp.root)
| |
− | parent = rootframe.interior()
| |
− | else:
| |
− | rootframe = Tkinter.Tk()
| |
− | parent = rootframe
| |
− | | |
− | rootframe.title(' Dynamic Angle Plotting ')
| |
− | rootframe.protocol("WM_DELETE_WINDOW", self.close_callback)
| |
− | | |
− | canvas = SimplePlot(parent,width=320,height=320)
| |
− | canvas.bind("<Button-2>",canvas.pickWhich)
| |
− | canvas.bind("<Button-3>",canvas.pickWhich)
| |
− | canvas.pack(side=Tkinter.LEFT,fill="both",expand=1)
| |
− | canvas.axis(xint=150,
| |
− | xlabels=[-180,-120,-60,0,60,120,180],
| |
− | ylabels=[-180,-150,-120,-90,-60,-30,0,30,60,90,120,150,180])
| |
− | canvas.update()
| |
− | | |
− | if name is None:
| |
− | try:
| |
− | name = cmd.get_unused_name('DynoRama')
| |
− | except AttributeError:
| |
− | name = 'DynoRamaObject'
| |
− | | |
− | self.rootframe = rootframe
| |
− | self.canvas = canvas
| |
− | self.name = name
| |
− | self.lock = 0
| |
− | | |
− | if name != 'none':
| |
− | auto_zoom = cmd.get('auto_zoom')
| |
− | cmd.set('auto_zoom', 0)
| |
− | cmd.load_callback(self, name)
| |
− | cmd.set('auto_zoom', auto_zoom)
| |
− | canvas.bind("<ButtonPress-1>",canvas.down)
| |
− | canvas.bind("<ButtonRelease-1>",canvas.up)
| |
− | canvas.bind("<Motion>",canvas.drag)
| |
− | | |
− | if selection is not None:
| |
− | self.start(selection)
| |
| | | |
− | if with_mainloop and pmgapp is None:
| + | Don't create callback object, use symbols by secondary structure and dump canvas as postscript file: |
− | rootframe.mainloop()
| |
| | | |
− | def close_callback(self):
| + | <source lang="python"> |
− | cmd.delete(self.name)
| + | fetch 2x19, async=0 |
− | self.rootframe.destroy()
| + | color yellow, chain A |
− | | + | color forest, chain B |
− | def start(self,sel):
| + | rama polymer, none, ss, /tmp/canvasdump.ps |
− | self.lock = 1
| + | rama ss H, none, aa, /tmp/canvasdump_helix.ps |
− | cmd.iterate('(%s) and name CA' % sel, 'idx2resn[model,index] = resn',
| + | rama ss S, none, aa, /tmp/canvasdump_sheet.ps |
− | space={'idx2resn': self.canvas.idx2resn})
| |
− | for model_index, (phi,psi) in cmd.get_phipsi(sel).iteritems():
| |
− | print " Plotting Phi,Psi: %8.2f,%8.2f" % (phi, psi)
| |
− | self.canvas.plot(phi, psi, model_index)
| |
− | self.lock = 0
| |
− | | |
− | def __call__(self):
| |
− | if self.lock:
| |
− | return
| |
− | # Loop through each item on plot to see if updated
| |
− | for value in self.canvas.shapes.itervalues():
| |
− | # Look for update flag...
| |
− | if value[2]:
| |
− | # Set residue's phi,psi to new values
| |
− | model, index = value[5]
| |
− | print " Re-setting Phi,Psi: %8.2f,%8.2f" % (value[3],value[4])
| |
− | set_phipsi(model, index, value[3], value[4])
| |
− | value[2] = 0
| |
− | | |
− | def rama(sel='(all)', name=None):
| |
− | '''
| |
− | DESCRIPTION
| |
− | | |
− | Ramachandran Plot
| |
− | http://pymolwiki.org/index.php/DynoPlot
| |
− | | |
− | ARGUMENTS
| |
− | | |
− | sel = string: atom selection {default: all}
| |
− | | |
− | name = string: name of callback object which is responsible for setting
| |
− | angles when canvas points are dragged, or 'none' to not create a callback
| |
− | object {default: DynoRamaObject}
| |
− | '''
| |
− | DynoRamaObject(sel, name)
| |
− | | |
− | # Extend these commands
| |
− | cmd.extend('ramachandran', rama)
| |
− | cmd.auto_arg[0]['ramachandran'] = cmd.auto_arg[0]['zoom']
| |
− | | |
− | # Add to plugin menu
| |
− | def __init_plugin__(self):
| |
− | self.menuBar.addcascademenu('Plugin', 'PlotTools', 'Plot Tools', label='Plot Tools')
| |
− | self.menuBar.addmenuitem('PlotTools', 'command', 'Launch Rama Plot', label='Rama Plot',
| |
− | command = lambda: DynoRamaObject('(enabled)'))
| |
− | | |
− | # vi:expandtab:smarttab
| |
| </source> | | </source> |
− |
| |
− | ===ADDITIONAL RESOURCES===
| |
− |
| |
− |
| |
| | | |
| [[Category:Script_Library|DynoPlot]] | | [[Category:Script_Library|DynoPlot]] |
| [[Category:Structural_Biology_Scripts|DynoPlot]] | | [[Category:Structural_Biology_Scripts|DynoPlot]] |
| + | [[Category:Pymol-script-repo]] |