"""
"""
import logging
import wx
# Try a normal import first
# If it fails, try specifying a version
import matplotlib
matplotlib.interactive(False)
#Use the WxAgg back end. The Wx one takes too long to render
matplotlib.use('WXAgg')
from matplotlib.backends.backend_wxagg import FigureCanvasWxAgg
from matplotlib.figure import Figure
import os
import transform
from plottables import Data1D
#TODO: make the plottables interactive
from binder import BindArtist
from matplotlib.font_manager import FontProperties
DEBUG = False
from plottables import Graph
from plottables import Text
from TextDialog import TextDialog
from LabelDialog import LabelDialog
import operator
import math
import pylab
DEFAULT_CMAP = pylab.cm.jet
import copy
import numpy
[docs]def show_tree(obj, d=0):
"""Handy function for displaying a tree of graph objects"""
print "%s%s" % ("-"*d, obj.__class__.__name__)
if 'get_children' in dir(obj):
for a in obj.get_children(): show_tree(a, d+1)
from unitConverter import UnitConvertion as convertUnit
def _rescale(lo, hi, step, pt=None, bal=None, scale='linear'):
"""
Rescale (lo,hi) by step, returning the new (lo,hi)
The scaling is centered on pt, with positive values of step
driving lo/hi away from pt and negative values pulling them in.
If bal is given instead of point, it is already in [0,1] coordinates.
This is a helper function for step-based zooming.
"""
# Convert values into the correct scale for a linear transformation
# TODO: use proper scale transformers
loprev = lo
hiprev = hi
if scale == 'log':
assert lo > 0
if lo > 0:
lo = math.log10(lo)
if hi > 0:
hi = math.log10(hi)
if pt is not None:
pt = math.log10(pt)
# Compute delta from axis range * %, or 1-% if persent is negative
if step > 0:
delta = float(hi - lo) * step / 100
else:
delta = float(hi - lo) * step / (100 - step)
# Add scale factor proportionally to the lo and hi values,
# preserving the
# point under the mouse
if bal is None:
bal = float(pt - lo) / (hi - lo)
lo = lo - (bal * delta)
hi = hi + (1 - bal) * delta
# Convert transformed values back to the original scale
if scale == 'log':
if (lo <= -250) or (hi >= 250):
lo = loprev
hi = hiprev
else:
lo, hi = math.pow(10., lo), math.pow(10., hi)
return (lo, hi)
[docs]def CopyImage(canvas):
"""
0: matplotlib plot
1: wx.lib.plot
2: other
"""
bmp = wx.BitmapDataObject()
bmp.SetBitmap(canvas.bitmap)
wx.TheClipboard.Open()
wx.TheClipboard.SetData(bmp)
wx.TheClipboard.Close()
[docs]class PlotPanel(wx.Panel):
"""
The PlotPanel has a Figure and a Canvas. OnSize events simply set a
flag, and the actually redrawing of the
figure is triggered by an Idle event.
"""
def __init__(self, parent, id=-1, xtransform=None,
ytransform=None, scale='log_{10}',
color=None, dpi=None, **kwargs):
"""
"""
wx.Panel.__init__(self, parent, id=id, **kwargs)
self.parent = parent
if hasattr(parent, "parent"):
self.parent = self.parent.parent
self.dimension = 1
self.gotLegend = 0 # to begin, legend is not picked.
self.legend_pos_loc = None
self.legend = None
self.line_collections_list = []
self.figure = Figure(None, dpi, linewidth=2.0)
self.color = '#b3b3b3'
from canvas import FigureCanvas
self.canvas = FigureCanvas(self, -1, self.figure)
self.SetColor(color)
#self.SetBackgroundColour(parent.GetBackgroundColour())
self._resizeflag = True
self._SetSize()
self.subplot = self.figure.add_subplot(111)
self.figure.subplots_adjust(left=0.2, bottom=.2)
self.yscale = 'linear'
self.xscale = 'linear'
self.sizer = wx.BoxSizer(wx.VERTICAL)
self.sizer.Add(self.canvas, 1, wx.EXPAND)
#add toolbar
self.enable_toolbar = True
self.toolbar = None
self.add_toolbar()
self.SetSizer(self.sizer)
# Graph object to manage the plottables
self.graph = Graph()
#Boolean value to keep track of whether current legend is
#visible or not
self.legend_on = True
self.grid_on = False
#Location of legend, default is 0 or 'best'
self.legendLoc = 0
self.position = None
self._loc_labels = self.get_loc_label()
self.Bind(wx.EVT_CONTEXT_MENU, self.onContextMenu)
# Define some constants
self.colorlist = ['b','g','r','c','m','y','k']
self.symbollist = ['o','x','^','v','<','>','+',
's','d','D','h','H','p', '-']
#List of texts currently on the plot
self.textList = []
#User scale
if xtransform != None:
self.xLabel = xtransform
else:
self.xLabel = "log10(x)"
if ytransform != None:
self.yLabel = ytransform
else:
self.yLabel = "log10(y)"
self.viewModel = "--"
# keep track if the previous transformation of x
# and y in Property dialog
self.prevXtrans = "log10(x)"
self.prevYtrans = "log10(y)"
self.scroll_id = self.canvas.mpl_connect('scroll_event', self.onWheel)
#taking care of dragging
self.motion_id = self.canvas.mpl_connect('motion_notify_event',
self.onMouseMotion)
self.press_id = self.canvas.mpl_connect('button_press_event',
self.onLeftDown)
self.pick_id = self.canvas.mpl_connect('pick_event', self.onPick)
self.release_id = self.canvas.mpl_connect('button_release_event',
self.onLeftUp)
wx.EVT_RIGHT_DOWN(self, self.onLeftDown)
# to turn axis off whenn resizing the panel
self.resizing = False
self.leftdown = False
self.leftup = False
self.mousemotion = False
self.axes = [self.subplot]
## Fit dialog
self._fit_dialog = None
# Interactor
self.connect = BindArtist(self.subplot.figure)
#self.selected_plottable = None
# new data for the fit
self.fit_result = Data1D(x=[], y=[], dy=None)
self.fit_result.symbol = 13
#self.fit_result = Data1D(x=[], y=[],dx=None, dy=None)
self.fit_result.name = "Fit"
# For fit Dialog initial display
self.xmin = 0.0
self.xmax = 0.0
self.xminView = 0.0
self.xmaxView = 0.0
self._scale_xlo = None
self._scale_xhi = None
self._scale_ylo = None
self._scale_yhi = None
self.Avalue = None
self.Bvalue = None
self.ErrAvalue = None
self.ErrBvalue = None
self.Chivalue = None
# for 2D scale
if scale != 'linear':
scale = 'log_{10}'
self.scale = scale
self.data = None
self.qx_data = None
self.qy_data = None
self.xmin_2D = None
self.xmax_2D = None
self.ymin_2D = None
self.ymax_2D = None
## store reference to the current plotted vmin and vmax of plotted image
##z range in linear scale
self.zmin_2D = None
self.zmax_2D = None
#index array
self.index_x = None
self.index_y = None
#number of bins
self.x_bins = None
self.y_bins = None
## default color map
self.cmap = DEFAULT_CMAP
# Dragging info
self.begDrag = False
self.xInit = None
self.yInit = None
self.xFinal = None
self.yFinal = None
#axes properties
self.xaxis_font = None
self.xaxis_label = None
self.xaxis_unit = None
self.xaxis_color = 'black'
self.xaxis_tick = None
self.yaxis_font = None
self.yaxis_label = None
self.yaxis_unit = None
self.yaxis_color = 'black'
self.yaxis_tick = None
# check if zoomed.
self.is_zoomed = False
# Plottables
self.plots = {}
# Default locations
self._default_save_location = os.getcwd()
# let canvas know about axes
self.canvas.set_panel(self)
self.ly = None
self.q_ctrl = None
#Bind focus to change the border color
self.canvas.Bind(wx.EVT_SET_FOCUS, self.on_set_focus)
self.canvas.Bind(wx.EVT_KILL_FOCUS, self.on_kill_focus)
def _SetInitialSize(self,):
"""
"""
pixels = self.parent.GetClientSize()
self.canvas.SetSize(pixels)
self.figure.set_size_inches(pixels[0] / self.figure.get_dpi(),
pixels[1] / self.figure.get_dpi(), forward=True)
[docs] def On_Paint(self, event):
"""
"""
self.canvas.SetBackgroundColour(self.color)
[docs] def on_set_focus(self, event):
"""
Send to the parenet the current panel on focus
"""
# light blue
self.color = '#0099f7'
self.figure.set_edgecolor(self.color)
if self.parent and self.window_caption:
self.parent.send_focus_to_datapanel(self.window_caption)
self.draw()
[docs] def on_kill_focus(self, event):
"""
Reset the panel color
"""
# light grey
self.color = '#b3b3b3'
self.figure.set_edgecolor(self.color)
self.draw()
[docs] def set_resizing(self, resizing=False):
"""
Set the resizing (True/False)
"""
pass # Not implemented
[docs] def schedule_full_draw(self, func='append'):
"""
Put self in schedule to full redraw list
"""
pass # Not implemented
[docs] def onLeftDown(self, event):
"""
left button down and ready to drag
"""
# Check that the LEFT button was pressed
if event.button == 1:
self.leftdown = True
ax = event.inaxes
if ax != None:
self.xInit, self.yInit = event.xdata, event.ydata
try:
pos_x = float(event.xdata) # / size_x
pos_y = float(event.ydata) # / size_y
pos_x = "%8.3g" % pos_x
pos_y = "%8.3g" % pos_y
self.position = str(pos_x), str(pos_y)
wx.PostEvent(self.parent, StatusEvent(status=self.position))
except:
self.position = None
[docs] def onLeftUp(self, event):
"""
Dragging is done
"""
# Check that the LEFT button was released
if event.button == 1:
self.leftdown = False
self.mousemotion = False
self.leftup = True
#release the legend
if self.gotLegend == 1:
self.gotLegend = 0
self.set_legend_alpha(1)
[docs] def set_legend_alpha(self, alpha=1):
"""
Set legend alpha
"""
if self.legend != None:
self.legend.legendPatch.set_alpha(alpha)
[docs] def onPick(self, event):
"""
On pick legend
"""
legend = self.legend
if event.artist == legend:
#gets the box of the legend.
bbox = self.legend.get_window_extent()
#get mouse coordinates at time of pick.
self.mouse_x = event.mouseevent.x
self.mouse_y = event.mouseevent.y
#get legend coordinates at time of pick.
self.legend_x = bbox.xmin
self.legend_y = bbox.ymin
#indicates we picked up the legend.
self.gotLegend = 1
self.set_legend_alpha(0.5)
def _on_legend_motion(self, event):
"""
On legend in motion
"""
ax = event.inaxes
if ax == None:
return
# Event occurred inside a plotting area
lo_x, hi_x = ax.get_xlim()
lo_y, hi_y = ax.get_ylim()
# How much the mouse moved.
x = mouse_diff_x = self.mouse_x - event.x
y = mouse_diff_y = self.mouse_y - event.y
# Put back inside
if x < lo_x:
x = lo_x
if x > hi_x:
x = hi_x
if y < lo_y:
y = lo_y
if y > hi_y:
y = hi_y
# Move the legend from its previous location by that same amount
loc_in_canvas = self.legend_x - mouse_diff_x, \
self.legend_y - mouse_diff_y
# Transform into legend coordinate system
trans_axes = self.legend.parent.transAxes.inverted()
loc_in_norm_axes = trans_axes.transform_point(loc_in_canvas)
self.legend_pos_loc = tuple(loc_in_norm_axes)
self.legend._loc = self.legend_pos_loc
self.resizing = True
self.canvas.set_resizing(self.resizing)
self.canvas.draw()
[docs] def onMouseMotion(self, event):
"""
check if the left button is press and the mouse in moving.
computer delta for x and y coordinates and then calls draghelper
to perform the drag
"""
self.cusor_line(event)
if self.gotLegend == 1:
self._on_legend_motion(event)
return
if self.enable_toolbar:
#Disable dragging without the toolbar to allow zooming with toolbar
return
self.mousemotion = True
if self.leftdown == True and self.mousemotion == True:
ax = event.inaxes
if ax != None: # the dragging is perform inside the figure
self.xFinal, self.yFinal = event.xdata, event.ydata
# Check whether this is the first point
if self.xInit == None:
self.xInit = self.xFinal
self.yInit = self.yFinal
xdelta = self.xFinal - self.xInit
ydelta = self.yFinal - self.yInit
if self.xscale == 'log':
xdelta = math.log10(self.xFinal) - math.log10(self.xInit)
if self.yscale == 'log':
ydelta = math.log10(self.yFinal) - math.log10(self.yInit)
self._dragHelper(xdelta, ydelta)
else: # no dragging is perform elsewhere
self._dragHelper(0, 0)
[docs] def cusor_line(self, event):
"""
"""
pass
def _offset_graph(self):
"""
Zoom and offset the graph to the last known settings
"""
for ax in self.axes:
if self._scale_xhi is not None and self._scale_xlo is not None:
ax.set_xlim(self._scale_xlo, self._scale_xhi)
if self._scale_yhi is not None and self._scale_ylo is not None:
ax.set_ylim(self._scale_ylo, self._scale_yhi)
def _dragHelper(self, xdelta, ydelta):
"""
dragging occurs here
"""
# Event occurred inside a plotting area
for ax in self.axes:
lo, hi = ax.get_xlim()
#print "x lo %f and x hi %f"%(lo,hi)
newlo, newhi = lo - xdelta, hi - xdelta
if self.xscale == 'log':
if lo > 0:
newlo = math.log10(lo) - xdelta
if hi > 0:
newhi = math.log10(hi) - xdelta
if self.xscale == 'log':
self._scale_xlo = math.pow(10, newlo)
self._scale_xhi = math.pow(10, newhi)
ax.set_xlim(math.pow(10, newlo), math.pow(10, newhi))
else:
self._scale_xlo = newlo
self._scale_xhi = newhi
ax.set_xlim(newlo, newhi)
#print "new lo %f and new hi %f"%(newlo,newhi)
lo, hi = ax.get_ylim()
#print "y lo %f and y hi %f"%(lo,hi)
newlo, newhi = lo - ydelta, hi - ydelta
if self.yscale == 'log':
if lo > 0:
newlo = math.log10(lo) - ydelta
if hi > 0:
newhi = math.log10(hi) - ydelta
#print "new lo %f and new hi %f"%(newlo,newhi)
if self.yscale == 'log':
self._scale_ylo = math.pow(10, newlo)
self._scale_yhi = math.pow(10, newhi)
ax.set_ylim(math.pow(10, newlo), math.pow(10, newhi))
else:
self._scale_ylo = newlo
self._scale_yhi = newhi
ax.set_ylim(newlo, newhi)
self.canvas.draw_idle()
[docs] def resetFitView(self):
"""
For fit Dialog initial display
"""
self.xmin = 0.0
self.xmax = 0.0
self.xminView = 0.0
self.xmaxView = 0.0
self._scale_xlo = None
self._scale_xhi = None
self._scale_ylo = None
self._scale_yhi = None
self.Avalue = None
self.Bvalue = None
self.ErrAvalue = None
self.ErrBvalue = None
self.Chivalue = None
[docs] def onWheel(self, event):
"""
Process mouse wheel as zoom events
:param event: Wheel event
"""
ax = event.inaxes
step = event.step
if ax != None:
# Event occurred inside a plotting area
lo, hi = ax.get_xlim()
lo, hi = _rescale(lo, hi, step,
pt=event.xdata, scale=ax.get_xscale())
if not self.xscale == 'log' or lo > 0:
self._scale_xlo = lo
self._scale_xhi = hi
ax.set_xlim((lo,hi))
lo, hi = ax.get_ylim()
lo, hi = _rescale(lo, hi, step, pt=event.ydata,
scale=ax.get_yscale())
if not self.yscale == 'log' or lo > 0:
self._scale_ylo = lo
self._scale_yhi = hi
ax.set_ylim((lo, hi))
else:
# Check if zoom happens in the axes
xdata, ydata = None, None
x, y = event.x, event.y
for ax in self.axes:
insidex, _ = ax.xaxis.contains(event)
if insidex:
xdata, _ = ax.transAxes.inverted().transform_point((x, y))
insidey, _ = ax.yaxis.contains(event)
if insidey:
_, ydata = ax.transAxes.inverted().transform_point((x, y))
if xdata is not None:
lo, hi = ax.get_xlim()
lo, hi = _rescale(lo, hi, step,
bal=xdata, scale=ax.get_xscale())
if not self.xscale == 'log' or lo > 0:
self._scale_xlo = lo
self._scale_xhi = hi
ax.set_xlim((lo, hi))
if ydata is not None:
lo, hi = ax.get_ylim()
lo, hi = _rescale(lo, hi, step, bal=ydata,
scale=ax.get_yscale())
if not self.yscale == 'log' or lo > 0:
self._scale_ylo = lo
self._scale_yhi = hi
ax.set_ylim((lo, hi))
self.canvas.draw_idle()
[docs] def returnTrans(self):
"""
Return values and labels used by Fit Dialog
"""
return self.xLabel, self.yLabel, self.Avalue, self.Bvalue,\
self.ErrAvalue, self.ErrBvalue, self.Chivalue
[docs] def setTrans(self, xtrans, ytrans):
"""
:param xtrans: set x transformation on Property dialog
:param ytrans: set y transformation on Property dialog
"""
self.prevXtrans = xtrans
self.prevYtrans = ytrans
[docs] def onFitting(self, event):
"""
when clicking on linear Fit on context menu , display Fitting Dialog
"""
list = {}
menu = event.GetEventObject()
id = event.GetId()
self.set_selected_from_menu(menu, id)
plotlist = self.graph.returnPlottable()
if self.graph.selected_plottable is not None:
for item in plotlist:
if item.id == self.graph.selected_plottable:
list[item] = plotlist[item]
else:
list = plotlist
from fitDialog import LinearFit
if len(list.keys()) > 0:
first_item = list.keys()[0]
dlg = LinearFit(parent=None, plottable=first_item,
push_data=self.onFitDisplay,
transform=self.returnTrans,
title='Linear Fit')
if (self.xmin != 0.0)and (self.xmax != 0.0)\
and(self.xminView != 0.0)and (self.xmaxView != 0.0):
dlg.setFitRange(self.xminView, self.xmaxView,
self.xmin, self.xmax)
dlg.ShowModal()
[docs] def linear_plottable_fit(self, plot):
"""
when clicking on linear Fit on context menu, display Fitting Dialog
:param plot: PlotPanel owning the graph
"""
from fitDialog import LinearFit
if self._fit_dialog is not None:
return
self._fit_dialog = LinearFit(None, plot, self.onFitDisplay,
self.returnTrans, -1, 'Linear Fit')
# Set the zoom area
if self._scale_xhi is not None and self._scale_xlo is not None:
self._fit_dialog.set_fit_region(self._scale_xlo, self._scale_xhi)
# Register the close event
self._fit_dialog.register_close(self._linear_fit_close)
# Show a non-model dialog
self._fit_dialog.Show()
def _linear_fit_close(self):
"""
A fit dialog was closed
"""
self._fit_dialog = None
def _onProperties(self, event):
"""
when clicking on Properties on context menu ,
The Property dialog is displayed
The user selects a transformation for x or y value and
a new plot is displayed
"""
if self._fit_dialog is not None:
self._fit_dialog.Destroy()
self._fit_dialog = None
list = []
list = self.graph.returnPlottable()
if len(list.keys()) > 0:
first_item = list.keys()[0]
if first_item.x != []:
from PropertyDialog import Properties
dial = Properties(self, -1, 'Properties')
dial.setValues(self.prevXtrans, self.prevYtrans, self.viewModel)
if dial.ShowModal() == wx.ID_OK:
self.xLabel, self.yLabel, self.viewModel = dial.getValues()
if self.viewModel == "Linear y vs x":
self.xLabel = "x"
self.yLabel = "y"
self.viewModel = "--"
dial.setValues(self.xLabel, self.yLabel, self.viewModel)
if self.viewModel == "Guinier lny vs x^(2)":
self.xLabel = "x^(2)"
self.yLabel = "ln(y)"
self.viewModel = "--"
dial.setValues(self.xLabel, self.yLabel, self.viewModel)
if self.viewModel == "XS Guinier ln(y*x) vs x^(2)":
self.xLabel = "x^(2)"
self.yLabel = "ln(y*x)"
self.viewModel = "--"
dial.setValues(self.xLabel, self.yLabel, self.viewModel)
if self.viewModel == "Porod y*x^(4) vs x^(4)":
self.xLabel = "x^(4)"
self.yLabel = "y*x^(4)"
self.viewModel = "--"
dial.setValues(self.xLabel, self.yLabel, self.viewModel)
self._onEVT_FUNC_PROPERTY()
dial.Destroy()
[docs] def set_yscale(self, scale='linear'):
"""
Set the scale on Y-axis
:param scale: the scale of y-axis
"""
self.subplot.set_yscale(scale, nonposy='clip')
self.yscale = scale
[docs] def get_yscale(self):
"""
:return: Y-axis scale
"""
return self.yscale
[docs] def set_xscale(self, scale='linear'):
"""
Set the scale on x-axis
:param scale: the scale of x-axis
"""
self.subplot.set_xscale(scale)
self.xscale = scale
[docs] def get_xscale(self):
"""
:return: x-axis scale
"""
return self.xscale
[docs] def SetColor(self, rgbtuple):
"""
Set figure and canvas colours to be the same
"""
if not rgbtuple:
rgbtuple = wx.SystemSettings.GetColour(wx.SYS_COLOUR_BTNFACE).Get()
col = [c/255.0 for c in rgbtuple]
self.figure.set_facecolor(col)
self.figure.set_edgecolor(self.color)
self.canvas.SetBackgroundColour(wx.Colour(*rgbtuple))
def _onSize(self, event):
"""
"""
self._resizeflag = True
def _onIdle(self, evt):
"""
"""
if self._resizeflag:
self._resizeflag = False
self._SetSize()
self.draw()
def _SetSize(self, pixels=None):
"""
This method can be called to force the Plot to be a desired size,
which defaults to the ClientSize of the panel
"""
if not pixels:
pixels = tuple(self.GetClientSize())
self.canvas.SetSize(pixels)
self.figure.set_size_inches(float(pixels[0]) / self.figure.get_dpi(),
float(pixels[1]) / self.figure.get_dpi())
[docs] def draw(self):
"""
Where the actual drawing happens
"""
self.figure.canvas.draw_idle()
[docs] def legend_picker(self, legend, event):
"""
Pick up the legend patch
"""
return self.legend.legendPatch.contains(event)
[docs] def get_loc_label(self):
"""
Associates label to a specific legend location
"""
_labels = {}
i = 0
_labels['best'] = i
i += 1
_labels['upper right'] = i
i += 1
_labels['upper left'] = i
i += 1
_labels['lower left'] = i
i += 1
_labels['lower right'] = i
i += 1
_labels['right'] = i
i += 1
_labels['center left'] = i
i += 1
_labels['center right'] = i
i += 1
_labels['lower center'] = i
i += 1
_labels['upper center'] = i
i += 1
_labels['center'] = i
return _labels
[docs] def onSaveImage(self, evt):
"""
Implement save image
"""
self.toolbar.save(evt)
[docs] def onLegend(self,legOnOff):
"""
Toggles whether legend is visible/not visible
"""
self.legend_on = legOnOff
if not self.legend_on:
for ax in self.axes:
self.remove_legend(ax)
else:
# sort them by labels
handles, labels = self.subplot.get_legend_handles_labels()
hl = sorted(zip(handles, labels),
key=operator.itemgetter(1))
handles2, labels2 = zip(*hl)
self.line_collections_list = handles2
self.legend = self.subplot.legend(handles2, labels2,
prop=FontProperties(size=10),
loc=self.legendLoc)
if self.legend != None:
self.legend.set_picker(self.legend_picker)
self.legend.set_axes(self.subplot)
self.legend.set_zorder(20)
self.subplot.figure.canvas.draw_idle()
[docs] def onChangeLegendLoc(self, event):
"""
Changes legend loc based on user input
"""
menu = event.GetEventObject()
id = event.GetId()
label = menu.GetLabel(id)
self.ChangeLegendLoc(label)
[docs] def ChangeLegendLoc(self, label):
"""
Changes legend loc based on user input
"""
self.legendLoc = label
self.legend_pos_loc = None
# sort them by labels
handles, labels = self.subplot.get_legend_handles_labels()
hl = sorted(zip(handles, labels),
key=operator.itemgetter(1))
handles2, labels2 = zip(*hl)
self.line_collections_list = handles2
self.legend = self.subplot.legend(handles2, labels2,
prop=FontProperties(size=10),
loc=self.legendLoc)
if self.legend != None:
self.legend.set_picker(self.legend_picker)
self.legend.set_axes(self.subplot)
self.legend.set_zorder(20)
self.subplot.figure.canvas.draw_idle()
[docs] def remove_legend(self, ax=None):
"""
Remove legend for ax or the current axes.
"""
from pylab import gca
if ax is None:
ax = gca()
ax.legend_ = None
def _on_addtext(self, event):
"""
Allows you to add text to the plot
"""
pos_x = 0
pos_y = 0
if self.position != None:
pos_x, pos_y = self.position
else:
pos_x, pos_y = 0.01, 1.00
textdial = TextDialog(None, -1, 'Add Custom Text')
if textdial.ShowModal() == wx.ID_OK:
try:
FONT = FontProperties()
label = textdial.getText()
xpos = pos_x
ypos = pos_y
font = FONT.copy()
font.set_size(textdial.getSize())
font.set_family(textdial.getFamily())
font.set_style(textdial.getStyle())
font.set_weight(textdial.getWeight())
colour = textdial.getColor()
if len(label) > 0 and xpos > 0 and ypos > 0:
new_text = self.subplot.text(str(xpos), str(ypos), label,
fontproperties=font,
color=colour)
self.textList.append(new_text)
self.subplot.figure.canvas.draw_idle()
except:
if self.parent != None:
from sas.guiframe.events import StatusEvent
msg = "Add Text: Error. Check your property values..."
wx.PostEvent(self.parent, StatusEvent(status = msg ))
else:
raise
textdial.Destroy()
#Have a pop up box come up for user to type in the
#text that they want to add...then create text Plottable
#based on this and plot it at user designated coordinates
[docs] def onGridOnOff(self,gridon_off):
"""
Allows ON/OFF Grid
"""
self.grid_on = gridon_off
self.subplot.figure.canvas.draw_idle()
def _on_xaxis_label(self, event):
"""
Allows you to add text to the plot
"""
xaxis_label, xaxis_unit, xaxis_font, xaxis_color,\
is_ok, is_tick = self._on_axis_label(axis='x')
if not is_ok:
return
self.xaxis_label = xaxis_label
self.xaxis_unit = xaxis_unit
self.xaxis_font = xaxis_font
self.xaxis_color = xaxis_color
if is_tick:
self.xaxis_tick = xaxis_font
if self.data != None:
# 2D
self.xaxis(self.xaxis_label, self.xaxis_unit,\
self.xaxis_font, self.xaxis_color, self.xaxis_tick)
self.subplot.figure.canvas.draw_idle()
else:
# 1D
self._check_zoom_plot()
def _check_zoom_plot(self):
"""
Check the zoom range and plot (1D only)
"""
xlo, xhi = self.subplot.get_xlim()
ylo, yhi = self.subplot.get_ylim()
## Set the view scale for all plots
self._onEVT_FUNC_PROPERTY(False)
if self.is_zoomed:
# Recover the x,y limits
self.subplot.set_xlim((xlo, xhi))
self.subplot.set_ylim((ylo, yhi))
@property
def is_zoomed(self):
toolbar_zoomed = self.toolbar.GetToolEnabled(self.toolbar.wx_ids['Back'])
return self._is_zoomed or toolbar_zoomed
@is_zoomed.setter
[docs] def is_zoomed(self, value):
self._is_zoomed = value
def _on_yaxis_label(self, event):
"""
Allows you to add text to the plot
"""
yaxis_label, yaxis_unit, yaxis_font, yaxis_color,\
is_ok, is_tick = self._on_axis_label(axis='y')
if not is_ok:
return
self.yaxis_label = yaxis_label
self.yaxis_unit = yaxis_unit
self.yaxis_font = yaxis_font
self.yaxis_color = yaxis_color
if is_tick:
self.yaxis_tick = yaxis_font
if self.data != None:
# 2D
self.yaxis(self.yaxis_label, self.yaxis_unit,\
self.yaxis_font, self.yaxis_color, self.yaxis_tick)
self.subplot.figure.canvas.draw_idle()
else:
# 1D
self._check_zoom_plot()
def _on_axis_label(self, axis='x'):
"""
Modify axes labels
:param axis: x or y axis [string]
"""
is_ok = True
title = 'Modify %s axis label' % axis
font = 'serif'
colour = 'black'
if axis == 'x':
label = self.xaxis_label
unit = self.xaxis_unit
else:
label = self.yaxis_label
unit = self.yaxis_unit
textdial = TextDialog(None, -1, title, label, unit)
if textdial.ShowModal() == wx.ID_OK:
try:
FONT = FontProperties()
font = FONT.copy()
font.set_size(textdial.getSize())
font.set_family(textdial.getFamily())
font.set_style(textdial.getStyle())
font.set_weight(textdial.getWeight())
unit = textdial.getUnit()
colour = textdial.getColor()
is_tick = textdial.getTickLabel()
label_temp = textdial.getText()
if label_temp.count("\%s" % "\\") > 0:
if self.parent != None:
from sas.guiframe.events import StatusEvent
msg = "Add Label: Error. Can not use double '\\' "
msg += "characters..."
wx.PostEvent(self.parent, StatusEvent(status=msg))
else:
label = label_temp
except:
if self.parent != None:
from sas.guiframe.events import StatusEvent
msg = "Add Label: Error. Check your property values..."
wx.PostEvent(self.parent, StatusEvent(status=msg))
else:
pass
else:
is_ok = False
is_tick = True
textdial.Destroy()
return label, unit, font, colour, is_ok, is_tick
def _on_removetext(self, event):
"""
Removes all text from the plot.
Eventually, add option to remove specific text boxes
"""
num_text = len(self.textList)
if num_text < 1:
if self.parent != None:
from sas.guiframe.events import StatusEvent
msg= "Remove Text: Nothing to remove. "
wx.PostEvent(self.parent, StatusEvent(status=msg))
else:
raise
return
txt = self.textList[num_text-1]
try:
text_remove = txt.get_text()
txt.remove()
if self.parent != None:
from sas.guiframe.events import StatusEvent
msg= "Removed Text: '%s'. " % text_remove
wx.PostEvent(self.parent, StatusEvent(status=msg))
except:
if self.parent != None:
from sas.guiframe.events import StatusEvent
msg= "Remove Text: Error occurred. "
wx.PostEvent(self.parent, StatusEvent(status=msg))
else:
raise
self.textList.remove(txt)
self.subplot.figure.canvas.draw_idle()
[docs] def properties(self, prop):
"""
Set some properties of the graph.
The set of properties is not yet determined.
"""
# The particulars of how they are stored and manipulated (e.g., do
# we want an inventory internally) is not settled. I've used a
# property dictionary for now.
#
# How these properties interact with a user defined style file is
# even less clear.
# Properties defined by plot
self.subplot.set_xlabel(r"$%s$" % prop["xlabel"])
self.subplot.set_ylabel(r"$%s$" % prop["ylabel"])
self.subplot.set_title(prop["title"])
[docs] def clear(self):
"""Reset the plot"""
# TODO: Redraw is brutal. Render to a backing store and swap in
# TODO: rather than redrawing on the fly.
self.subplot.clear()
self.subplot.hold(True)
[docs] def render(self):
"""Commit the plot after all objects are drawn"""
# TODO: this is when the backing store should be swapped in.
if self.legend_on:
ax = self.subplot
ax.texts = self.textList
try:
handles, labels = ax.get_legend_handles_labels()
# sort them by labels
hl = sorted(zip(handles, labels),
key=operator.itemgetter(1))
handles2, labels2 = zip(*hl)
self.line_collections_list = handles2
self.legend = ax.legend(handles2, labels2,
prop=FontProperties(size=10),
loc=self.legendLoc)
if self.legend != None:
self.legend.set_picker(self.legend_picker)
self.legend.set_axes(self.subplot)
self.legend.set_zorder(20)
except:
self.legend = ax.legend(prop=FontProperties(size=10),
loc=self.legendLoc)
[docs] def xaxis(self, label, units, font=None, color='black', t_font=None):
"""xaxis label and units.
Axis labels know about units.
We need to do this so that we can detect when axes are not
commesurate. Currently this is ignored other than for formatting
purposes.
"""
self.xcolor = color
if units.count("{") > 0 and units.count("$") < 2:
units = '$' + units + '$'
if label.count("{") > 0 and label.count("$") < 2:
label = '$' + label + '$'
if units != "":
label = label + " (" + units + ")"
if font:
self.subplot.set_xlabel(label, fontproperties=font, color=color)
if t_font != None:
for tick in self.subplot.xaxis.get_major_ticks():
tick.label.set_fontproperties(t_font)
for line in self.subplot.xaxis.get_ticklines():
size = t_font.get_size()
line.set_markersize(size / 3)
else:
self.subplot.set_xlabel(label, color=color)
pass
[docs] def yaxis(self, label, units, font=None, color='black', t_font=None):
"""yaxis label and units."""
self.ycolor = color
if units.count("{") > 0 and units.count("$") < 2:
units = '$' + units + '$'
if label.count("{") > 0 and label.count("$") < 2:
label = '$' + label + '$'
if units != "":
label = label + " (" + units + ")"
if font:
self.subplot.set_ylabel(label, fontproperties=font, color=color)
if t_font != None:
for tick_label in self.subplot.get_yticklabels():
tick_label.set_fontproperties(t_font)
for line in self.subplot.yaxis.get_ticklines():
size = t_font.get_size()
line.set_markersize(size / 3)
else:
self.subplot.set_ylabel(label, color=color)
pass
def _connect_to_xlim(self, callback):
"""Bind the xlim change notification to the callback"""
def process_xlim(axes):
lo, hi = subplot.get_xlim()
callback(lo, hi)
self.subplot.callbacks.connect('xlim_changed', process_xlim)
[docs] def interactive_points(self, x, y, dx=None, dy=None, name='', color=0,
symbol=0, markersize=5, zorder=1, id=None,
label=None, hide_error=False):
"""Draw markers with error bars"""
self.subplot.set_yscale('linear')
self.subplot.set_xscale('linear')
if id is None:
id = name
from plottable_interactor import PointInteractor
p = PointInteractor(self, self.subplot, zorder=zorder, id=id)
if p.markersize != None:
markersize = p.markersize
p.points(x, y, dx=dx, dy=dy, color=color, symbol=symbol, zorder=zorder,
markersize=markersize, label=label, hide_error=hide_error)
self.subplot.set_yscale(self.yscale, nonposy='clip')
self.subplot.set_xscale(self.xscale)
[docs] def interactive_curve(self, x, y, dy=None, name='', color=0,
symbol=0, zorder=1, id=None, label=None):
"""Draw markers with error bars"""
self.subplot.set_yscale('linear')
self.subplot.set_xscale('linear')
if id is None:
id = name
from plottable_interactor import PointInteractor
p = PointInteractor(self, self.subplot, zorder=zorder, id=id)
p.curve(x, y, dy=dy, color=color, symbol=symbol, zorder=zorder,
label=label)
self.subplot.set_yscale(self.yscale, nonposy='clip')
self.subplot.set_xscale(self.xscale)
[docs] def plottable_selected(self, id):
"""
Called to register a plottable as selected
"""
#TODO: check that it really is in the list of plottables
self.graph.selected_plottable = id
[docs] def points(self, x, y, dx=None, dy=None,
color=0, symbol=0, marker_size=5, label=None,
id=None, hide_error=False):
"""Draw markers with error bars"""
# Convert tuple (lo,hi) to array [(x-lo),(hi-x)]
if dx != None and type(dx) == type(()):
dx = nx.vstack((x-dx[0], dx[1]-x)).transpose()
if dy != None and type(dy) == type(()):
dy = nx.vstack((y-dy[0], dy[1]-y)).transpose()
if dx == None and dy == None:
h = self.subplot.plot(x, y, color=self._color(color),
marker=self._symbol(symbol), markersize=marker_size,
linestyle='',
label=label)
else:
col = self._color(color)
if hide_error:
h = self.subplot.plot(x, y, color=col,
marker=self._symbol(symbol),
markersize=marker_size,
linestyle='',
label=label)
else:
h = self.subplot.errorbar(x, y, yerr=dy, xerr=None,
ecolor=col, capsize=2, linestyle='',
barsabove=False,
mec=col, mfc=col,
marker=self._symbol(symbol),
markersize=marker_size,
lolims=False, uplims=False,
xlolims=False, xuplims=False, label=label)
self.subplot.set_yscale(self.yscale, nonposy='clip')
self.subplot.set_xscale(self.xscale)
def _onToggleScale(self, event):
"""
toggle axis and replot image
"""
zmin_2D_temp = self.zmin_2D
zmax_2D_temp = self.zmax_2D
if self.scale == 'log_{10}':
self.scale = 'linear'
if not self.zmin_2D is None:
zmin_2D_temp = math.pow(10, self.zmin_2D)
if not self.zmax_2D is None:
zmax_2D_temp = math.pow(10, self.zmax_2D)
else:
self.scale = 'log_{10}'
if not self.zmin_2D is None:
# min log value: no log(negative)
if self.zmin_2D <= 0:
zmin_2D_temp = -32
else:
zmin_2D_temp = math.log10(self.zmin_2D)
if not self.zmax_2D is None:
zmax_2D_temp = math.log10(self.zmax_2D)
self.image(data=self.data, qx_data=self.qx_data,
qy_data=self.qy_data, xmin=self.xmin_2D,
xmax=self.xmax_2D,
ymin=self.ymin_2D, ymax=self.ymax_2D,
cmap=self.cmap, zmin=zmin_2D_temp,
zmax=zmax_2D_temp)
[docs] def image(self, data, qx_data, qy_data, xmin, xmax, ymin, ymax,
zmin, zmax, color=0, symbol=0, markersize=0,
label='data2D', cmap=DEFAULT_CMAP):
"""
Render the current data
"""
self.data = data
self.qx_data = qx_data
self.qy_data = qy_data
self.xmin_2D = xmin
self.xmax_2D = xmax
self.ymin_2D = ymin
self.ymax_2D = ymax
self.zmin_2D = zmin
self.zmax_2D = zmax
c = self._color(color)
# If we don't have any data, skip.
if self.data == None:
return
if self.data.ndim == 1:
output = self._build_matrix()
else:
output = copy.deepcopy(self.data)
# check scale
if self.scale == 'log_{10}':
try:
if self.zmin_2D <= 0 and len(output[output > 0]) > 0:
zmin_temp = self.zmin_2D
output[output>0] = numpy.log10(output[output>0])
#In log scale Negative values are not correct in general
#output[output<=0] = math.log(numpy.min(output[output>0]))
elif self.zmin_2D <= 0:
zmin_temp = self.zmin_2D
output[output>0] = numpy.zeros(len(output))
output[output<=0] = -32
else:
zmin_temp = self.zmin_2D
output[output>0] = numpy.log10(output[output>0])
#In log scale Negative values are not correct in general
#output[output<=0] = math.log(numpy.min(output[output>0]))
except:
#Too many problems in 2D plot with scale
pass
else:
zmin_temp = self.zmin_2D
self.cmap = cmap
if self.dimension != 3:
#Re-adjust colorbar
self.subplot.figure.subplots_adjust(left=0.2, right=.8, bottom=.2)
im = self.subplot.imshow(output, interpolation='nearest',
origin='lower',
vmin=zmin_temp, vmax=self.zmax_2D,
cmap=self.cmap,
extent=(self.xmin_2D, self.xmax_2D,
self.ymin_2D, self.ymax_2D))
cbax = self.subplot.figure.add_axes([0.84,0.2,0.02,0.7])
else:
# clear the previous 2D from memory
# mpl is not clf, so we do
self.subplot.figure.clear()
self.subplot.figure.subplots_adjust(left=0.1, right=.8, bottom=.1)
X = self.x_bins[0:-1]
Y = self.y_bins[0:-1]
X, Y = numpy.meshgrid(X, Y)
try:
# mpl >= 1.0.0
ax = self.subplot.figure.gca(projection='3d')
#ax.disable_mouse_rotation()
cbax = self.subplot.figure.add_axes([0.84,0.1,0.02,0.8])
if len(X) > 60:
ax.disable_mouse_rotation()
except:
# mpl < 1.0.0
try:
from mpl_toolkits.mplot3d import Axes3D
except:
logging.error("PlotPanel could not import Axes3D")
self.subplot.figure.clear()
ax = Axes3D(self.subplot.figure)
if len(X) > 60:
ax.cla()
cbax = None
self.subplot.figure.canvas.resizing = False
im = ax.plot_surface(X, Y, output, rstride=1, cstride=1, cmap=cmap,
linewidth=0, antialiased=False)
self.subplot.set_axis_off()
if cbax == None:
ax.set_frame_on(False)
cb = self.subplot.figure.colorbar(im, shrink=0.8, aspect=20)
else:
cb = self.subplot.figure.colorbar(im, cax=cbax)
cb.update_bruteforce(im)
cb.set_label('$' + self.scale + '$')
if self.dimension != 3:
self.figure.canvas.draw_idle()
else:
self.figure.canvas.draw()
def _build_matrix(self):
"""
Build a matrix for 2d plot from a vector
Returns a matrix (image) with ~ square binning
Requirement: need 1d array formats of
self.data, self.qx_data, and self.qy_data
where each one corresponds to z, x, or y axis values
"""
# No qx or qy given in a vector format
if self.qx_data == None or self.qy_data == None \
or self.qx_data.ndim != 1 or self.qy_data.ndim != 1:
# do we need deepcopy here?
return copy.deepcopy(self.data)
# maximum # of loops to fillup_pixels
# otherwise, loop could never stop depending on data
max_loop = 1
# get the x and y_bin arrays.
self._get_bins()
# set zero to None
#Note: Can not use scipy.interpolate.Rbf:
# 'cause too many data points (>10000)<=JHC.
# 1d array to use for weighting the data point averaging
#when they fall into a same bin.
weights_data = numpy.ones([self.data.size])
# get histogram of ones w/len(data); this will provide
#the weights of data on each bins
weights, xedges, yedges = numpy.histogram2d(x=self.qy_data,
y=self.qx_data,
bins=[self.y_bins, self.x_bins],
weights=weights_data)
# get histogram of data, all points into a bin in a way of summing
image, xedges, yedges = numpy.histogram2d(x=self.qy_data,
y=self.qx_data,
bins=[self.y_bins, self.x_bins],
weights=self.data)
# Now, normalize the image by weights only for weights>1:
# If weight == 1, there is only one data point in the bin so
# that no normalization is required.
image[weights > 1] = image[weights>1]/weights[weights>1]
# Set image bins w/o a data point (weight==0) as None (was set to zero
# by histogram2d.)
image[weights == 0] = None
# Fill empty bins with 8 nearest neighbors only when at least
#one None point exists
loop = 0
# do while loop until all vacant bins are filled up up
#to loop = max_loop
while(not(numpy.isfinite(image[weights == 0])).all()):
if loop >= max_loop: # this protects never-ending loop
break
image = self._fillup_pixels(image=image, weights=weights)
loop += 1
return image
def _get_bins(self):
"""
get bins
set x_bins and y_bins into self, 1d arrays of the index with
~ square binning
Requirement: need 1d array formats of
self.qx_data, and self.qy_data
where each one corresponds to x, or y axis values
"""
# No qx or qy given in a vector format
if self.qx_data == None or self.qy_data == None \
or self.qx_data.ndim != 1 or self.qy_data.ndim != 1:
# do we need deepcopy here?
return copy.deepcopy(self.data)
# find max and min values of qx and qy
xmax = self.qx_data.max()
xmin = self.qx_data.min()
ymax = self.qy_data.max()
ymin = self.qy_data.min()
# calculate the range of qx and qy: this way, it is a little
# more independent
x_size = xmax - xmin
y_size = ymax - ymin
# estimate the # of pixels on each axes
npix_y = int(math.floor(math.sqrt(len(self.qy_data))))
npix_x = int(math.floor(len(self.qy_data) / npix_y))
# bin size: x- & y-directions
xstep = x_size / (npix_x - 1)
ystep = y_size / (npix_y - 1)
# max and min taking account of the bin sizes
xmax = xmax + xstep / 2.0
xmin = xmin - xstep / 2.0
ymax = ymax + ystep / 2.0
ymin = ymin - ystep / 2.0
# store x and y bin centers in q space
x_bins = numpy.linspace(xmin, xmax, npix_x)
y_bins = numpy.linspace(ymin, ymax, npix_y)
#x_bins = numpy.arange(xmin, xmax + xstep / 10.0, xstep)
#y_bins = numpy.arange(ymin, ymax + ystep / 10.0, ystep)
#set x_bins and y_bins
self.x_bins = x_bins
self.y_bins = y_bins
def _fillup_pixels(self, image=None, weights=None):
"""
Fill z values of the empty cells of 2d image matrix
with the average over up-to next nearest neighbor points
:param image: (2d matrix with some zi = None)
:return: image (2d array )
:TODO: Find better way to do for-loop below
"""
# No image matrix given
if image == None or numpy.ndim(image) != 2 \
or numpy.isfinite(image).all() \
or weights == None:
return image
# Get bin size in y and x directions
len_y = len(image)
len_x = len(image[1])
temp_image = numpy.zeros([len_y, len_x])
weit = numpy.zeros([len_y, len_x])
# do for-loop for all pixels
for n_y in range(len(image)):
for n_x in range(len(image[1])):
# find only null pixels
if weights[n_y][n_x] > 0 or numpy.isfinite(image[n_y][n_x]):
continue
else:
# find 4 nearest neighbors
# check where or not it is at the corner
if n_y != 0 and numpy.isfinite(image[n_y-1][n_x]):
temp_image[n_y][n_x] += image[n_y-1][n_x]
weit[n_y][n_x] += 1
if n_x != 0 and numpy.isfinite(image[n_y][n_x-1]):
temp_image[n_y][n_x] += image[n_y][n_x-1]
weit[n_y][n_x] += 1
if n_y != len_y -1 and numpy.isfinite(image[n_y+1][n_x]):
temp_image[n_y][n_x] += image[n_y+1][n_x]
weit[n_y][n_x] += 1
if n_x != len_x -1 and numpy.isfinite(image[n_y][n_x+1]):
temp_image[n_y][n_x] += image[n_y][n_x+1]
weit[n_y][n_x] += 1
# go 4 next nearest neighbors when no non-zero
# neighbor exists
if n_y != 0 and n_x != 0 and\
numpy.isfinite(image[n_y-1][n_x-1]):
temp_image[n_y][n_x] += image[n_y-1][n_x-1]
weit[n_y][n_x] += 1
if n_y != len_y -1 and n_x != 0 and \
numpy.isfinite(image[n_y+1][n_x-1]):
temp_image[n_y][n_x] += image[n_y+1][n_x-1]
weit[n_y][n_x] += 1
if n_y != len_y and n_x != len_x -1 and \
numpy.isfinite(image[n_y-1][n_x+1]):
temp_image[n_y][n_x] += image[n_y-1][n_x+1]
weit[n_y][n_x] += 1
if n_y != len_y -1 and n_x != len_x -1 and \
numpy.isfinite(image[n_y+1][n_x+1]):
temp_image[n_y][n_x] += image[n_y+1][n_x+1]
weit[n_y][n_x] += 1
# get it normalized
ind = (weit > 0)
image[ind] = temp_image[ind] / weit[ind]
return image
[docs] def curve(self, x, y, dy=None, color=0, symbol=0, label=None):
"""Draw a line on a graph, possibly with confidence intervals."""
c = self._color(color)
self.subplot.set_yscale('linear')
self.subplot.set_xscale('linear')
self.subplot.plot(x, y, color=c, marker='',
linestyle='-', label=label)
self.subplot.set_yscale(self.yscale)
self.subplot.set_xscale(self.xscale)
def _color(self, c):
"""Return a particular colour"""
return self.colorlist[c % len(self.colorlist)]
def _symbol(self, s):
"""Return a particular symbol"""
return self.symbollist[s % len(self.symbollist)]
def _replot(self, remove_fit=False):
"""
Rescale the plottables according to the latest
user selection and update the plot
:param remove_fit: Fit line will be removed if True
"""
self.graph.reset_scale()
self._onEVT_FUNC_PROPERTY(remove_fit=remove_fit)
#TODO: Why do we have to have the following line?
self.fit_result.reset_view()
self.graph.render(self)
self.subplot.figure.canvas.draw_idle()
def _onEVT_FUNC_PROPERTY(self, remove_fit=True, show=True):
"""
Receive the x and y transformation from myDialog,
Transforms x and y in View
and set the scale
"""
# The logic should be in the right order
# Delete first, and then get the whole list...
if remove_fit:
self.graph.delete(self.fit_result)
self.ly = None
self.q_ctrl = None
list = []
list = self.graph.returnPlottable()
# Changing the scale might be incompatible with
# currently displayed data (for instance, going
# from ln to log when all plotted values have
# negative natural logs).
# Go linear and only change the scale at the end.
self.set_xscale("linear")
self.set_yscale("linear")
_xscale = 'linear'
_yscale = 'linear'
for item in list:
item.setLabel(self.xLabel, self.yLabel)
# control axis labels from the panel itself
yname, yunits = item.get_yaxis()
if self.yaxis_label != None:
yname = self.yaxis_label
yunits = self.yaxis_unit
else:
self.yaxis_label = yname
self.yaxis_unit = yunits
xname, xunits = item.get_xaxis()
if self.xaxis_label != None:
xname = self.xaxis_label
xunits = self.xaxis_unit
else:
self.xaxis_label = xname
self.xaxis_unit = xunits
# Goes through all possible scales
if(self.xLabel == "x"):
item.transformX(transform.toX, transform.errToX)
self.graph._xaxis_transformed("%s" % xname, "%s" % xunits)
if(self.xLabel == "x^(2)"):
item.transformX(transform.toX2, transform.errToX2)
xunits = convertUnit(2, xunits)
self.graph._xaxis_transformed("%s^{2}" % xname, "%s" % xunits)
if(self.xLabel == "x^(4)"):
item.transformX(transform.toX4, transform.errToX4)
xunits = convertUnit(4, xunits)
self.graph._xaxis_transformed("%s^{4}" % xname, "%s" % xunits)
if(self.xLabel == "ln(x)"):
item.transformX(transform.toLogX, transform.errToLogX)
self.graph._xaxis_transformed("\ln\\ %s" % xname, "%s" % xunits)
if(self.xLabel == "log10(x)"):
item.transformX(transform.toX_pos, transform.errToX_pos)
_xscale = 'log'
self.graph._xaxis_transformed("%s" % xname, "%s" % xunits)
if(self.xLabel == "log10(x^(4))"):
item.transformX(transform.toX4, transform.errToX4)
xunits = convertUnit(4, xunits)
self.graph._xaxis_transformed("%s^{4}" % xname, "%s" % xunits)
_xscale = 'log'
if(self.yLabel == "ln(y)"):
item.transformY(transform.toLogX, transform.errToLogX)
self.graph._yaxis_transformed("\ln\\ %s" % yname, "%s" % yunits)
if(self.yLabel == "y"):
item.transformY(transform.toX, transform.errToX)
self.graph._yaxis_transformed("%s" % yname, "%s" % yunits)
if(self.yLabel == "log10(y)"):
item.transformY(transform.toX_pos, transform.errToX_pos)
_yscale = 'log'
self.graph._yaxis_transformed("%s" % yname, "%s" % yunits)
if(self.yLabel == "y^(2)"):
item.transformY(transform.toX2, transform.errToX2)
yunits = convertUnit(2, yunits)
self.graph._yaxis_transformed("%s^{2}" % yname, "%s" % yunits)
if(self.yLabel == "1/y"):
item.transformY(transform.toOneOverX, transform.errOneOverX)
yunits = convertUnit(-1, yunits)
self.graph._yaxis_transformed("1/%s" % yname, "%s" % yunits)
if(self.yLabel == "y*x^(4)"):
item.transformY(transform.toYX4, transform.errToYX4)
xunits = convertUnit(4, self.xaxis_unit)
self.graph._yaxis_transformed("%s \ \ %s^{4}" % (yname, xname),
"%s%s" % (yunits, xunits))
if(self.yLabel == "1/sqrt(y)"):
item.transformY(transform.toOneOverSqrtX,
transform.errOneOverSqrtX)
yunits = convertUnit(-0.5, yunits)
self.graph._yaxis_transformed("1/\sqrt{%s}" % yname,
"%s" % yunits)
if(self.yLabel == "ln(y*x)"):
item.transformY(transform.toLogXY, transform.errToLogXY)
self.graph._yaxis_transformed("\ln (%s \ \ %s)" % (yname, xname),
"%s%s" % (yunits, self.xaxis_unit))
if(self.yLabel == "ln(y*x^(2))"):
item.transformY( transform.toLogYX2, transform.errToLogYX2)
xunits = convertUnit(2, self.xaxis_unit)
self.graph._yaxis_transformed("\ln (%s \ \ %s^{2})" % (yname, xname),
"%s%s" % (yunits, xunits))
if(self.yLabel == "ln(y*x^(4))"):
item.transformY(transform.toLogYX4, transform.errToLogYX4)
xunits = convertUnit(4, self.xaxis_unit)
self.graph._yaxis_transformed("\ln (%s \ \ %s^{4})" % (yname, xname),
"%s%s" % (yunits, xunits))
if(self.yLabel == "log10(y*x^(4))"):
item.transformY(transform.toYX4, transform.errToYX4)
xunits = convertUnit(4, self.xaxis_unit)
_yscale = 'log'
self.graph._yaxis_transformed("%s \ \ %s^{4}" % (yname, xname),
"%s%s" % (yunits, xunits))
if(self.viewModel == "Guinier lny vs x^(2)"):
item.transformX(transform.toX2, transform.errToX2)
xunits = convertUnit(2, xunits)
self.graph._xaxis_transformed("%s^{2}" % xname, "%s" % xunits)
item.transformY(transform.toLogX,transform.errToLogX)
self.graph._yaxis_transformed("\ln\ \ %s" % yname, "%s" % yunits)
if(self.viewModel == "Porod y*x^(4) vs x^(4)"):
item.transformX(transform.toX4, transform.errToX4)
xunits = convertUnit(4, self.xaxis_unit)
self.graph._xaxis_transformed("%s^{4}" % xname, "%s" % xunits)
item.transformY(transform.toYX4, transform.errToYX4)
self.graph._yaxis_transformed("%s \ \ %s^{4}" % (yname, xname),
"%s%s" % (yunits, xunits))
item.transformView()
# set new label and units
yname = self.graph.prop["ylabel"]
yunits = ''
xname = self.graph.prop["xlabel"]
xunits = ''
self.resetFitView()
self.prevXtrans = self.xLabel
self.prevYtrans = self.yLabel
self.graph.render(self)
self.set_xscale(_xscale)
self.set_yscale(_yscale)
self.xaxis(xname, xunits, self.xaxis_font,
self.xaxis_color, self.xaxis_tick)
self.yaxis(yname, yunits, self.yaxis_font,
self.yaxis_color, self.yaxis_tick)
self.subplot.texts = self.textList
if show:
self.subplot.figure.canvas.draw_idle()
[docs] def onFitDisplay(self, tempx, tempy, xminView,
xmaxView, xmin, xmax, func):
"""
Add a new plottable into the graph .In this case this plottable
will be used to fit some data
:param tempx: The x data of fit line
:param tempy: The y data of fit line
:param xminView: the lower bound of fitting range
:param xminView: the upper bound of fitting range
:param xmin: the lowest value of data to fit to the line
:param xmax: the highest value of data to fit to the line
"""
# Saving value to redisplay in Fit Dialog when it is opened again
self.Avalue, self.Bvalue, self.ErrAvalue, \
self.ErrBvalue, self.Chivalue = func
self.xminView = xminView
self.xmaxView = xmaxView
self.xmin = xmin
self.xmax = xmax
#In case need to change the range of data plotted
list = []
list = self.graph.returnPlottable()
for item in list:
#item.onFitRange(xminView,xmaxView)
item.onFitRange(None, None)
# Create new data plottable with result
self.fit_result.x = []
self.fit_result.y = []
self.fit_result.x = tempx
self.fit_result.y = tempy
self.fit_result.dx = None
self.fit_result.dy = None
#Load the view with the new values
self.fit_result.reset_view()
# Add the new plottable to the graph
self.graph.add(self.fit_result)
self.graph.render(self)
self._offset_graph()
self.subplot.figure.canvas.draw_idle()
[docs] def onChangeCaption(self, event):
"""
"""
if self.parent == None:
return
# get current caption
old_caption = self.window_caption
# Get new caption dialog
dial = LabelDialog(None, -1, 'Modify Window Title', old_caption)
if dial.ShowModal() == wx.ID_OK:
new_caption = dial.getText()
# send to guiframe to change the panel caption
caption = self.parent.on_change_caption(self.window_name,
old_caption, new_caption)
# also set new caption in plot_panels list
self.parent.plot_panels[self.uid].window_caption = caption
# set new caption
self.window_caption = caption
dial.Destroy()
[docs] def onResetGraph(self, event):
"""
Reset the graph by plotting the full range of data
"""
list = []
list = self.graph.returnPlottable()
for item in list:
item.onReset()
self.graph.render(self)
self._onEVT_FUNC_PROPERTY(False)
self.is_zoomed = False
self.toolbar.update()
[docs] def onPrinterSetup(self, event=None):
"""
"""
self.canvas.Printer_Setup(event=event)
self.Update()
[docs] def onPrinterPreview(self, event=None):
"""
"""
try:
self.canvas.Printer_Preview(event=event)
self.Update()
except:
pass
[docs] def onPrint(self, event=None):
"""
"""
try:
self.canvas.Printer_Print(event=event)
self.Update()
except:
pass
[docs]class NoRepaintCanvas(FigureCanvasWxAgg):
"""
We subclass FigureCanvasWxAgg, overriding the _onPaint method, so that
the draw method is only called for the first two paint events. After that,
the canvas will only be redrawn when it is resized.
"""
def __init__(self, *args, **kwargs):
"""
"""
FigureCanvasWxAgg.__init__(self, *args, **kwargs)
self._drawn = 0
def _onPaint(self, evt):
"""
Called when wxPaintEvt is generated
"""
if not self._isRealized:
self.realize()
if self._drawn < 2:
self.draw(repaint=False)
self._drawn += 1
self.gui_repaint(drawDC=wx.PaintDC(self))