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Re: Plot/Graph

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On 2016-04-04 01:04, Muhammad Ali wrote:
> On Sunday, April 3, 2016 at 2:35:58 PM UTC-7, Oscar Benjamin wrote:
>> On 3 Apr 2016 22:21, "Muhammad Ali" <muhammadaliaskari@gmail.com> wrote:
>> >
>> >  How do I convert/change/modify python script so that my data could be
>> extracted according to python script and at the end it generates another
>> single extracted data file instead of displaying/showing some graph? So
>> that, I can manually plot the newly generated file (after data extraction)
>> by some other software like origin.
>>
>> It depends what you're computing and what format origin expects the data to
>> be in. Presumably it can use CSV files so take a look at the CSV module
>> which can write these.
>>
>> (You'll get better answers to a question like this if you show us some code
>> and ask a specific question about how to change it.)
>>
>> --
>> Oscar
>
> How could the python script be modified to generate data file rather than display a plot by using matplotlib?
>
>
> def make_plot(plot):
>      indent = plot.plot_options.indent
>      args = plot.plot_options.args
>      # Creating the plot
>      print ('Generating the plot...')
>      fig = plt.figure(figsize=(plot.fig_width_inches,plot.fig_height_inches))
>      ax = fig.add_subplot(111)
>      # Defining the color schemes.
>      print (indent + '>>> Using the "' + plot.cmap_name + '" colormap.')
>      if(plot.plot_options.using_default_cmap and not args.running_from_GUI):
>          print (2 * indent + 'Tip: You can try different colormaps by either:')
>          print (2 * indent + '     * Running the plot tool with the option -icmap n, ' \
>                 'with n in the range from 0 to', len(plot.plot_options.cmaps) - 1)
>          print (2 * indent + '     * Running the plot tool with the option "-cmap cmap_name".')
>          print (2 * indent + '> Take a look at')
>          print (4 * indent + '<http://matplotlib.org/examples/color/colormaps_reference.html>')
>          print (2 * indent + '  for a list of colormaps, or run')
>          print (4 * indent + '"./plot_unfolded_EBS_BandUP.py --help".')
>
>      # Building the countour plot from the read data
>      # Defining the (ki,Ej) grid.
>      if(args.interpolation is not None):
>          ki = np.linspace(plot.kmin, plot.kmax, 2 * len(set(plot.KptsCoords)) + 1, endpoint=True)
>          Ei = np.arange(plot.emin, plot.emax + plot.dE_for_hist2d, plot.dE_for_hist2d)
>          # Interpolating
>          grid_freq = griddata((plot.KptsCoords, plot.energies), plot.delta_Ns, (ki[None,:], Ei[:,None]),
>                               method=args.interpolation, fill_value=0.0)
>      else:
>          ki = np.unique(np.clip(plot.KptsCoords, plot.kmin, plot.kmax))
>          Ei = np.unique(np.clip(plot.energies, plot.emin,  plot.emax))
>          grid_freq = griddata((plot.KptsCoords, plot.energies), plot.delta_Ns, (ki[None,:], Ei[:,None]),
>                               method='nearest', fill_value=0.0)
>
>      if(not args.skip_grid_freq_clip):
>          grid_freq = grid_freq.clip(0.0) # Values smaller than zero are just noise.
>      # Normalizing and building the countour plot
>      manually_normalize_colorbar_min_and_maxval = False
>      if((args.maxval_for_colorbar is not None) or (args.minval_for_colorbar is not None)):
>          manually_normalize_colorbar_min_and_maxval = True
>          args.disable_auto_round_vmin_and_vmax = True
>          maxval_for_colorbar = args.maxval_for_colorbar
>          minval_for_colorbar = args.minval_for_colorbar
>      else:
>          if not args.disable_auto_round_vmin_and_vmax:
>              minval_for_colorbar = float(round(np.min(grid_freq)))
>              maxval_for_colorbar = float(round(np.max(grid_freq)))
>              args.round_cb = 0
>      if(manually_normalize_colorbar_min_and_maxval or not args.disable_auto_round_vmin_and_vmax):
>          modified_vmin_or_vmax = False
>          if not args.disable_auto_round_vmin_and_vmax and not args.running_from_GUI:
>              print (plot.indent + '* Automatically renormalizing color scale '\
>                     '(you can disable this with the option --disable_auto_round_vmin_and_vmax):')
>          if manually_normalize_colorbar_min_and_maxval:
>              print (plot.indent + '* Manually renormalizing color scale')
>          if(minval_for_colorbar is not None):
>              previous_vmin = np.min(grid_freq)
>              if(abs(previous_vmin - minval_for_colorbar) >= 0.1):
>                  modified_vmin_or_vmax = True
>                  print (2 * indent + 'Previous vmin = %.1f, new vmin = %.1f' % (previous_vmin,
>                                                                                 minval_for_colorbar))
>          else:
>              minval_for_colorbar = np.min(grid_freq)
>          if(maxval_for_colorbar is not None):
>              previous_vmax = np.max(grid_freq)
>              if(abs(previous_vmax - maxval_for_colorbar) >= 0.1):
>                  modified_vmin_or_vmax = True
>                  print (2 * indent + 'Previous vmax = %.1f, new vmax = %.1f' % (previous_vmax,
>                                                                                 maxval_for_colorbar))
>          else:
>              maxval_for_colorbar = np.max(grid_freq)
>          if(modified_vmin_or_vmax):
>              print (2 * indent + 'The previous vmin and vmax might be slightly different from '
>                                  'the min and max delta_Ns '
>                                  'due to the interpolation scheme used for the plot.')
>          # values > vmax will be set to vmax, and #<vmin will be set to vmin
>          grid_freq = grid_freq.clip(minval_for_colorbar, maxval_for_colorbar)
>          v = np.linspace(minval_for_colorbar, maxval_for_colorbar, args.n_levels, endpoint=True)
>      else:
>          v = np.linspace(np.min(grid_freq), np.max(grid_freq), args.n_levels, endpoint=True)
>      print (indent + '* Drawing contour plot...')
>      print (2 * indent + '> Using %i color levels. Use the option "--n_levels" to choose a different number.' %args.n_levels)
>      image = ax.contourf(ki, Ei, grid_freq, levels=v, cmap=plot.cmap)
>
>      plot_spin_proj_requested = args.plot_spin_perp or args.plot_spin_para or args.plot_sigma_x or args.plot_sigma_y or args.plot_sigma_z
>      if(plot_spin_proj_requested and plot.spin_projections is not None):
>          print (indent + '* Drawing spin projection info')
>          cmap_for_spin_plot = [plt.cm.bwr, plt.cm.RdBu, plt.cm.seismic_r][0]
>
>          if(args.clip_spin is None):
>              vmin_spin = np.min(plot.spin_projections)
>              vmax_spin = np.max(plot.spin_projections)
>          else:
>              vmax_spin = abs(args.clip_spin)
>              vmin_spin = -1.0 * abs(args.clip_spin)
>              print (2 * indent + '* New maxval for spin: %.2f' % vmax_spin)
>              print (2 * indent + '* New minval for spin: %.2f' % vmin_spin)
>
>          spin_projections = np.clip(plot.spin_projections, vmin_spin, vmax_spin)
>          grid_freq_spin = griddata((plot.KptsCoords, plot.energies), spin_projections, (ki[None,:], Ei[:,None]),
>                                    method='nearest', fill_value=0.0)
>
>          k_for_scatter = []
>          E_for_scatter = []
>          spin_projections_for_scatter = []
>          for iener in range(len(Ei)):
>              for ikpt in range(len(ki)):
>                  if(abs(grid_freq_spin[iener, ikpt]) > 1E-3):
>                      k_for_scatter.append(ki[ikpt])
>                      E_for_scatter.append(Ei[iener])
>                      spin_projections_for_scatter.append(grid_freq_spin[iener, ikpt])
>
>          if(spin_projections_for_scatter):
>              if(args.spin_marker=='o'):
>                  image2 = ax.scatter(k_for_scatter, E_for_scatter, marker='o',
>                                      s=[10.0 * abs(item) for item in spin_projections_for_scatter],
>                                      c=spin_projections_for_scatter, cmap=cmap_for_spin_plot)
>              else:
>                  image2 = ax.scatter(k_for_scatter, E_for_scatter, marker='_',
>                                      s=[500.0 * (ki[1] - ki[0]) for item in spin_projections_for_scatter],
>                                      linewidth=[100.0 * plot.dE_for_hist2d * (item ** 2) for item in spin_projections_for_scatter],
>                                      c=spin_projections_for_scatter, cmap=cmap_for_spin_plot)
>          else:
>              print (2 * indent + '* The abs values of the spin projections were all < 1E-3.')
>
>      #Preparing the plot
>      ax.set_xlim(plot.kmin, plot.kmax)
>      ax.set_ylim(plot.emin, plot.emax)
>      ax.set_title(plot.title, fontsize=plot.title_size)
>      ax.set_ylabel(plot.y_axis_label, fontsize=plot.yaxis_labels_size)
>      plt.yticks(fontsize=plot.tick_marks_size)
>
>      # Fermi energy line
>      show_E_f = not args.no_ef
>      if(show_E_f and plot.E_f >= plot.emin and plot.E_f <= plot.emax):
>          E_f_line = plt.axhline(y=plot.E_f, c=plot.color_E_f_line(image), linestyle=plot.line_style_E_f, lw=plot.line_width_E_f)
>      # High symmetry points lines
>      if(plot.pos_high_symm_points):
>          x_tiks_positions = [kx for kx in plot.pos_high_symm_points if kx - plot.kmax <= 1E-2 and kx >= plot.kmin]
>      if(args.no_symm_labels):
>          x_tiks_labels = []
>      else:
>          x_tiks_labels = [plot.labels_high_symm_lines[i] for i in range(len(plot.labels_high_symm_lines)) if
>                           plot.pos_high_symm_points[i] in x_tiks_positions]
>          x_tiks_labels = [xlabel for xlabel in x_tiks_labels if xlabel]
>      if x_tiks_labels:
>          print (indent + '* K-point labels read from the "' + args.kpoints_file + '" file:')
>          for ilabel in range(len(x_tiks_labels)):
>              print(2 * indent + "k = {:9.5f}".format(x_tiks_positions[ilabel]) + ', label =',\
>                     x_tiks_labels[ilabel])
>          plt.xticks(x_tiks_positions, x_tiks_labels, fontsize=plot.tick_marks_size)
>      else:
>          plot.x_axis_label = '$k \hspace{0.25} (\AA^{-1})$'
>          plt.locator_params(axis = 'x', nbins = 5)
>          ax.set_xlabel(plot.x_axis_label, fontsize=plot.xaxis_labels_size)
>          plt.xticks(fontsize=plot.tick_marks_size)
>      ax.tick_params(axis='x', pad=10)
>
>      # Drawing vertical lines at the positions of the high-symmetry points
>      if(not args.no_symm_lines):
>          for line_position in [pos for pos in plot.pos_high_symm_points if float(round(pos, 3)) > float(round(plot.kmin, 3)) and
>                                                                            float(round(pos, 3)) < float(round(plot.kmax, 3))]:
>              hs_lines = plt.axvline(x=line_position, c=plot.color_high_symm_lines(image), linestyle=plot.line_style_high_symm_points,
>                                     lw=plot.line_width_high_symm_points)
>
>      # Color bar
>      show_colorbar = not args.no_cb
>      if show_colorbar:
>          if plot.cb_orientation=='vertical':
>              cb_pad=0.005
>          else:
>              cb_pad=0.06
>          if(not x_tiks_labels):
>              cb_pad += 0.08 # To prevent the cb from overlapping with the numbers.
>
>          cb_yticks = np.arange(int(image.norm.vmin), int(image.norm.vmax) + 1, 1)
>
>          cb_ytick_labels = [round(item,abs(args.round_cb)) for item in cb_yticks]
>          cb = plt.colorbar(image, ax=ax, ticks=cb_yticks, orientation=plot.cb_orientation, pad=cb_pad)
>          cb.set_ticklabels(cb_ytick_labels)
>          cb.ax.tick_params(labelsize=plot.colorbar_tick_marks_size)
>
>          color_bar_label = None
>          if args.cb_label:
>              color_bar_label = ('$Color scale: \hspace{0.5} \delta N(\\vec{k}; ' +
>                                 '\hspace{0.25} \epsilon)$ ')
>          if args.cb_label_full:
>              color_bar_label = ('$Colors cale: \hspace{0.5} \delta N(\\vec{k}; ' +
>                                 '\hspace{0.25} \epsilon);$ '+
>                                 '$\delta\epsilon=' + round(1000.0*plot.dE_for_hist2d,0) +
>                                 '\\hspace{0.25} meV.$')
>
>          if plot.cb_orientation=='vertical':
>              cb_label_rotation = 90
>          else:
>              cb_label_rotation = 0
>          if color_bar_label:
>              cb.ax.text(plot.offset_x_text_colorbar, plot.offset_y_text_colorbar,
>                         color_bar_label, rotation=cb_label_rotation, ha='center',
>                         va='center', fontsize=plot.colorbar_label_size)
>
>      # Saving/showing the results
>      plt.tick_params(which='both', bottom='off', top='off', left='off', right='off',
>                      labelbottom='on')
>
>
>      default_out_basename = "_".join([splitext(basename(args.input_file))[0], 'E_from', str(plot.emin), 'to',
>                                      str(plot.emax), 'eV_dE',
>                                      str(plot.dE_for_hist2d), 'eV'])
>      if(args.save):
>          if(args.output_file is None):
>              args.output_file = abspath(default_out_basename + '.' + args.file_format)
>
>          print ('Savig figure to file "%s" ...' % args.output_file)
>          if(args.fig_resolution[0].upper() == 'H'):
>              print (indent + '* High-resolution figure (600 dpi).')
>              fig_resolution_in_dpi = 600
>          elif (args.fig_resolution[0].upper() == 'M'):
>              print (indent + '* Medium-resolution figure (300 dpi).')
>              fig_resolution_in_dpi = 300
>          elif (args.fig_resolution[0].upper() == 'L'):
>              print (indent + '* Low-resolution figure (100 dpi).')
>              fig_resolution_in_dpi = 100
>          else:
>              print (indent + 'Assuming medium-resolution (300 dpi) for the figure.')
>              fig_resolution_in_dpi = 300
>          plt.savefig(args.output_file, dpi=fig_resolution_in_dpi, bbox_inches='tight')
>          print (indent + '* Done saving figure (%s).' % args.output_file)
>
>      if args.saveshow:
>          print ('Opening saved figure (%s)...' % default_out_basename)
>          # 'xdg-open' might fail to find the defualt program in some systems
>          # For such cases, one can try to use other alternatives (just add more to the list below)
>          image_viewer_list = ['xdg-open', 'eog']
>          for image_viewer in image_viewer_list:
>              open_saved_fig = Popen([image_viewer, args.output_file], stdout=PIPE, stderr=PIPE)
>              std_out, std_err = open_saved_fig.communicate()
>              success_opening_file = std_err.strip() == ''
>              if(success_opening_file):
>                  break
>          if(not success_opening_file):
>              print (indent + '* Failed (%s): no image viewer detected.' % default_out_basename)
>
>      if args.show:
>          print ('Showing figure (%s)...' % default_out_basename)
>          plt.show()
>          print (indent + '* Done showing figure (%s).' % default_out_basename)
>
>
> if __name__ == '__main__':
>      print_opening_message()
>      plot_options = BandUpPlotOptions()
>      plot = BandUpPlot(plot_options)
>      make_plot(plot)
>      sys.exit(0)
>
Look at the line "if(args.save):". That decides whether to save.

Where does args come from? It comes from "args = 
plot.plot_options.args". "plot" is passed into "make_plot".

Where does that object come from? It comes from "plot = 
BandUpPlot(plot_options)".

Where does "plot_options" come from? It comes from "plot_options = 
BandUpPlotOptions()".

What's "BandUpPlotOptions()"? I have no idea. It's not part of what 
you've posted.

Now, over to you to do the rest. Maybe it's mentioned in matplotlib's docs.

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Thread

Plot/Graph Muhammad Ali <muhammadaliaskari@gmail.com> - 2016-04-03 12:01 -0700
  Re: Plot/Graph Michael Selik <michael.selik@gmail.com> - 2016-04-03 21:04 +0000
    Re: Plot/Graph Muhammad Ali <muhammadaliaskari@gmail.com> - 2016-04-03 14:17 -0700
      Re: Plot/Graph Oscar Benjamin <oscar.j.benjamin@gmail.com> - 2016-04-03 22:35 +0100
        Re: Plot/Graph Muhammad Ali <muhammadaliaskari@gmail.com> - 2016-04-03 17:04 -0700
          Re: Plot/Graph MRAB <python@mrabarnett.plus.com> - 2016-04-04 01:18 +0100
            Re: Plot/Graph Muhammad Ali <muhammadaliaskari@gmail.com> - 2016-04-04 15:35 -0700
              Re: Plot/Graph MRAB <python@mrabarnett.plus.com> - 2016-04-05 01:05 +0100
            Re: Plot/Graph Steven D'Aprano <steve@pearwood.info> - 2016-04-05 11:56 +1000
        Re: Plot/Graph Muhammad Ali <muhammadaliaskari@gmail.com> - 2016-04-04 17:16 -0700
          Re: Plot/Graph Muhammad Ali <muhammadaliaskari@gmail.com> - 2016-04-04 18:17 -0700
  Re: Plot/Graph Dennis Lee Bieber <wlfraed@ix.netcom.com> - 2016-04-03 20:16 -0400

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