""" Boxsum Class: determine 2 rectangular area to compute the sum of pixel of a Data. """ import numpy from PyQt4 import QtGui from PyQt4 import QtCore from sas.qtgui.GuiUtils import formatNumber from BaseInteractor import _BaseInteractor from sas.sascalc.dataloader.manipulations import Boxavg from sas.sascalc.dataloader.manipulations import Boxsum from sas.qtgui.SlicerModel import SlicerModel class BoxSumCalculator(_BaseInteractor): """ Boxsum Class: determine 2 rectangular area to compute the sum of pixel of a Data. Uses PointerInteractor , VerticalDoubleLine,HorizontalDoubleLine. @param zorder: Artists with lower zorder values are drawn first. @param x_min: the minimum value of the x coordinate @param x_max: the maximum value of the x coordinate @param y_min: the minimum value of the y coordinate @param y_max: the maximum value of the y coordinate """ def __init__(self, base, axes, color='black', zorder=3): _BaseInteractor.__init__(self, base, axes, color=color) # list of Boxsmun markers self.markers = [] self.axes = axes self._model = None self.update_model = False # connect the artist for the motion self.connect = self.base.connect # when qmax is reached the selected line is reset the its previous value self.qmax = min(self.base.data.xmax, self.base.data.xmin) # Define the boxsum limits self.xmin = -1 * 0.5 * min(numpy.fabs(self.base.data.xmax), numpy.fabs(self.base.data.xmin)) self.ymin = -1 * 0.5 * min(numpy.fabs(self.base.data.xmax), numpy.fabs(self.base.data.xmin)) self.xmax = 0.5 * min(numpy.fabs(self.base.data.xmax), numpy.fabs(self.base.data.xmin)) self.ymax = 0.5 * min(numpy.fabs(self.base.data.xmax), numpy.fabs(self.base.data.xmin)) # center of the boxSum self.center_x = 0.0002 self.center_y = 0.0003 # Number of points on the plot self.nbins = 20 # Define initial result the summation self.count = 0 self.error = 0 self.total = 0 self.totalerror = 0 self.points = 0 # Flag to determine if the current figure has moved # set to False == no motion , set to True== motion self.has_move = False # Create Boxsum edges self.horizontal_lines = HorizontalDoubleLine(self, self.axes, color='blue', zorder=zorder, y=self.ymax, x=self.xmax, center_x=self.center_x, center_y=self.center_y) self.horizontal_lines.qmax = self.qmax self.vertical_lines = VerticalDoubleLine(self, self.axes, color='black', zorder=zorder, y=self.ymax, x=self.xmax, center_x=self.center_x, center_y=self.center_y) self.vertical_lines.qmax = self.qmax self.center = PointInteractor(self, self.axes, color='grey', zorder=zorder, center_x=self.center_x, center_y=self.center_y) # Save the name of the slicer panel associate with this slicer self.panel_name = "" # Update and post slicer parameters self.update_model = False self.update() self.postData() # set up the model self._model = QtGui.QStandardItemModel(1, 9) self.setModelFromParams() self.update_model = True self._model.itemChanged.connect(self.setParamsFromModel) def setModelFromParams(self): """ Set up the Qt model for data handling between controls """ parameters = self.getParams() # Crete/overwrite model items self._model.setData(self._model.index(0, 0), QtCore.QVariant(formatNumber(parameters['Height']))) self._model.setData(self._model.index(0, 1), QtCore.QVariant(formatNumber(parameters['Width']))) self._model.setData(self._model.index(0, 2), QtCore.QVariant(formatNumber(parameters['center_x']))) self._model.setData(self._model.index(0, 3), QtCore.QVariant(formatNumber(parameters['center_y']))) self.setReadOnlyParametersFromModel() def model(self): ''' model accessor ''' return self._model def setReadOnlyParametersFromModel(self): """ Cast model content onto "read-only" subset of parameters """ parameters = self.getParams() self._model.setData(self._model.index(0, 4), QtCore.QVariant(formatNumber(parameters['avg']))) self._model.setData(self._model.index(0, 5), QtCore.QVariant(formatNumber(parameters['avg_error']))) self._model.setData(self._model.index(0, 6), QtCore.QVariant(formatNumber(parameters['sum']))) self._model.setData(self._model.index(0, 7), QtCore.QVariant(formatNumber(parameters['sum_error']))) self._model.setData(self._model.index(0, 8), QtCore.QVariant(formatNumber(parameters['num_points']))) def setParamsFromModel(self): """ Cast model content onto params dict """ params = {} params["Height"] = float(self.model().item(0, 0).text()) params["Width"] = float(self.model().item(0, 1).text()) params["center_x"] = float(self.model().item(0, 2).text()) params["center_y"] = float(self.model().item(0, 3).text()) self.update_model = False self.setParams(params) self.setReadOnlyParametersFromModel() self.update_model = True def setPanelName(self, name): """ Store the name of the panel associated to this slicer @param name: the name of this panel """ self.panel_name = name def setLayer(self, n): """ Allow adding plot to the same panel :param n: the number of layer """ self.layernum = n self.update() def clear(self): """ Clear the slicer and all connected events related to this slicer """ self.clear_markers() self.horizontal_lines.clear() self.vertical_lines.clear() self.center.clear() self.base.connect.clearall() def update(self): """ Respond to changes in the model by recalculating the profiles and resetting the widgets. """ # check if the center point has moved and update the figure accordingly if self.center.has_move: self.center.update() self.horizontal_lines.update(center=self.center) self.vertical_lines.update(center=self.center) # check if the horizontal lines have moved and # update the figure accordingly if self.horizontal_lines.has_move: self.horizontal_lines.update() self.vertical_lines.update(y1=self.horizontal_lines.y1, y2=self.horizontal_lines.y2, height=self.horizontal_lines.half_height) # check if the vertical lines have moved and # update the figure accordingly if self.vertical_lines.has_move: self.vertical_lines.update() self.horizontal_lines.update(x1=self.vertical_lines.x1, x2=self.vertical_lines.x2, width=self.vertical_lines.half_width) def save(self, ev): """ Remember the roughness for this layer and the next so that we can restore on Esc. """ self.horizontal_lines.save(ev) self.vertical_lines.save(ev) self.center.save(ev) def postData(self): """ Get the limits of the boxsum and compute the sum of the pixel contained in that region and the error on that sum """ # the region of the summation x_min = self.horizontal_lines.x2 x_max = self.horizontal_lines.x1 y_min = self.vertical_lines.y2 y_max = self.vertical_lines.y1 #computation of the sum and its error box = Boxavg(x_min=x_min, x_max=x_max, y_min=y_min, y_max=y_max) self.count, self.error = box(self.base.data) # Dig out number of points summed, SMK & PDB, 04/03/2013 boxtotal = Boxsum(x_min=x_min, x_max=x_max, y_min=y_min, y_max=y_max) self.total, self.totalerror, self.points = boxtotal(self.base.data) if self.update_model: self.setModelFromParams() self.draw() def moveend(self, ev): """ After a dragging motion this function is called to compute the error and the sum of pixel of a given data 2D """ # compute error an d sum of data's pixel self.postData() def restore(self): """ Restore the roughness for this layer. """ self.horizontal_lines.restore() self.vertical_lines.restore() self.center.restore() def getParams(self): """ Store a copy of values of parameters of the slicer into a dictionary. :return params: the dictionary created """ params = {} params["Width"] = numpy.fabs(self.vertical_lines.half_width) * 2 params["Height"] = numpy.fabs(self.horizontal_lines.half_height) * 2 params["center_x"] = self.center.x params["center_y"] = self.center.y params["num_points"] = self.points params["avg"] = self.count params["avg_error"] = self.error params["sum"] = self.total params["sum_error"] = self.totalerror return params def getResult(self): """ Return the result of box summation """ result = {} result["num_points"] = self.points result["avg"] = self.count result["avg_error"] = self.error result["sum"] = self.total result["sum_error"] = self.totalerror return result def setParams(self, params): """ Receive a dictionary and reset the slicer with values contained in the values of the dictionary. :param params: a dictionary containing name of slicer parameters and values the user assigned to the slicer. """ x_max = numpy.fabs(params["Width"]) / 2 y_max = numpy.fabs(params["Height"]) / 2 self.center_x = params["center_x"] self.center_y = params["center_y"] # update the slicer given values of params self.center.update(center_x=self.center_x, center_y=self.center_y) self.horizontal_lines.update(center=self.center, width=x_max, height=y_max) self.vertical_lines.update(center=self.center, width=x_max, height=y_max) # compute the new error and sum given values of params self.postData() def draw(self): """ Redraw canvas""" self.base.draw() class PointInteractor(_BaseInteractor): """ Draw a point that can be dragged with the marker. this class controls the motion the center of the BoxSum """ def __init__(self, base, axes, color='black', zorder=5, center_x=0.0, center_y=0.0): _BaseInteractor.__init__(self, base, axes, color=color) # Initialization the class self.markers = [] self.axes = axes # center coordinates self.x = center_x self.y = center_y # saved value of the center coordinates self.save_x = center_x self.save_y = center_y # Create a marker self.center_marker = self.axes.plot([self.x], [self.y], linestyle='', marker='s', markersize=10, color=self.color, alpha=0.6, pickradius=5, label="pick", zorder=zorder, visible=True)[0] # Draw a point self.center = self.axes.plot([self.x], [self.y], linestyle='-', marker='', color=self.color, visible=True)[0] # Flag to determine the motion this point self.has_move = False # connecting the marker to allow them to move self.connect_markers([self.center_marker]) # Update the figure self.update() def setLayer(self, n): """ Allow adding plot to the same panel @param n: the number of layer """ self.layernum = n self.update() def clear(self): """ Clear this figure and its markers """ self.clear_markers() self.center.remove() self.center_marker.remove() def update(self, center_x=None, center_y=None): """ Draw the new roughness on the graph. """ if center_x != None: self.x = center_x if center_y != None: self.y = center_y self.center_marker.set(xdata=[self.x], ydata=[self.y]) self.center.set(xdata=[self.x], ydata=[self.y]) def save(self, ev): """ Remember the roughness for this layer and the next so that we can restore on Esc. """ self.save_x = self.x self.save_y = self.y def moveend(self, ev): """ """ self.has_move = False self.base.moveend(ev) def restore(self): """ Restore the roughness for this layer. """ self.y = self.save_y self.x = self.save_x def move(self, x, y, ev): """ Process move to a new position, making sure that the move is allowed. """ self.x = x self.y = y self.has_move = True self.base.base.update() def setCursor(self, x, y): """ """ self.move(x, y, None) self.update() class VerticalDoubleLine(_BaseInteractor): """ Draw 2 vertical lines moving in opposite direction and centered on a point (PointInteractor) """ def __init__(self, base, axes, color='black', zorder=5, x=0.5, y=0.5, center_x=0.0, center_y=0.0): _BaseInteractor.__init__(self, base, axes, color=color) # Initialization the class self.markers = [] self.axes = axes # Center coordinates self.center_x = center_x self.center_y = center_y # defined end points vertical lignes and their saved values self.y1 = y + self.center_y self.save_y1 = self.y1 delta = self.y1 - self.center_y self.y2 = self.center_y - delta self.save_y2 = self.y2 self.x1 = x + self.center_x self.save_x1 = self.x1 delta = self.x1 - self.center_x self.x2 = self.center_x - delta self.save_x2 = self.x2 # # save the color of the line self.color = color # the height of the rectangle self.half_height = numpy.fabs(y) self.save_half_height = numpy.fabs(y) # the with of the rectangle self.half_width = numpy.fabs(self.x1 - self.x2) / 2 self.save_half_width = numpy.fabs(self.x1 - self.x2) / 2 # Create marker self.right_marker = self.axes.plot([self.x1], [0], linestyle='', marker='s', markersize=10, color=self.color, alpha=0.6, pickradius=5, label="pick", zorder=zorder, visible=True)[0] # Define the left and right lines of the rectangle self.right_line = self.axes.plot([self.x1, self.x1], [self.y1, self.y2], linestyle='-', marker='', color=self.color, visible=True)[0] self.left_line = self.axes.plot([self.x2, self.x2], [self.y1, self.y2], linestyle='-', marker='', color=self.color, visible=True)[0] # Flag to determine if the lines have moved self.has_move = False # Connection the marker and draw the pictures self.connect_markers([self.right_marker]) self.update() def setLayer(self, n): """ Allow adding plot to the same panel :param n: the number of layer """ self.layernum = n self.update() def clear(self): """ Clear this slicer and its markers """ self.clear_markers() self.right_marker.remove() self.right_line.remove() self.left_line.remove() def update(self, x1=None, x2=None, y1=None, y2=None, width=None, height=None, center=None): """ Draw the new roughness on the graph. :param x1: new maximum value of x coordinates :param x2: new minimum value of x coordinates :param y1: new maximum value of y coordinates :param y2: new minimum value of y coordinates :param width: is the width of the new rectangle :param height: is the height of the new rectangle :param center: provided x, y coordinates of the center point """ # Save the new height, witdh of the rectangle if given as a param if width is not None: self.half_width = width if height is not None: self.half_height = height # If new center coordinates are given draw the rectangle # given these value if center is not None: self.center_x = center.x self.center_y = center.y self.x1 = self.half_width + self.center_x self.x2 = -self.half_width + self.center_x self.y1 = self.half_height + self.center_y self.y2 = -self.half_height + self.center_y self.right_marker.set(xdata=[self.x1], ydata=[self.center_y]) self.right_line.set(xdata=[self.x1, self.x1], ydata=[self.y1, self.y2]) self.left_line.set(xdata=[self.x2, self.x2], ydata=[self.y1, self.y2]) return # if x1, y1, y2, y3 are given draw the rectangle with this value if x1 is not None: self.x1 = x1 if x2 is not None: self.x2 = x2 if y1 is not None: self.y1 = y1 if y2 is not None: self.y2 = y2 # Draw 2 vertical lines and a marker self.right_marker.set(xdata=[self.x1], ydata=[self.center_y]) self.right_line.set(xdata=[self.x1, self.x1], ydata=[self.y1, self.y2]) self.left_line.set(xdata=[self.x2, self.x2], ydata=[self.y1, self.y2]) def save(self, ev): """ Remember the roughness for this layer and the next so that we can restore on Esc. """ self.save_x2 = self.x2 self.save_y2 = self.y2 self.save_x1 = self.x1 self.save_y1 = self.y1 self.save_half_height = self.half_height self.save_half_width = self.half_width def moveend(self, ev): """ After a dragging motion reset the flag self.has_move to False """ self.has_move = False self.base.moveend(ev) def restore(self): """ Restore the roughness for this layer. """ self.y2 = self.save_y2 self.x2 = self.save_x2 self.y1 = self.save_y1 self.x1 = self.save_x1 self.half_height = self.save_half_height self.half_width = self.save_half_width def move(self, x, y, ev): """ Process move to a new position, making sure that the move is allowed. """ self.x1 = x delta = self.x1 - self.center_x self.x2 = self.center_x - delta self.half_width = numpy.fabs(self.x1 - self.x2) / 2 self.has_move = True self.base.base.update() def setCursor(self, x, y): """ Update the figure given x and y """ self.move(x, y, None) self.update() class HorizontalDoubleLine(_BaseInteractor): """ Select an annulus through a 2D plot """ def __init__(self, base, axes, color='black', zorder=5, x=0.5, y=0.5, center_x=0.0, center_y=0.0): _BaseInteractor.__init__(self, base, axes, color=color) # Initialization the class self.markers = [] self.axes = axes # Center coordinates self.center_x = center_x self.center_y = center_y self.y1 = y + self.center_y self.save_y1 = self.y1 delta = self.y1 - self.center_y self.y2 = self.center_y - delta self.save_y2 = self.y2 self.x1 = x + self.center_x self.save_x1 = self.x1 delta = self.x1 - self.center_x self.x2 = self.center_x - delta self.save_x2 = self.x2 self.color = color self.half_height = numpy.fabs(y) self.save_half_height = numpy.fabs(y) self.half_width = numpy.fabs(x) self.save_half_width = numpy.fabs(x) self.top_marker = self.axes.plot([0], [self.y1], linestyle='', marker='s', markersize=10, color=self.color, alpha=0.6, pickradius=5, label="pick", zorder=zorder, visible=True)[0] # Define 2 horizotnal lines self.top_line = self.axes.plot([self.x1, -self.x1], [self.y1, self.y1], linestyle='-', marker='', color=self.color, visible=True)[0] self.bottom_line = self.axes.plot([self.x1, -self.x1], [self.y2, self.y2], linestyle='-', marker='', color=self.color, visible=True)[0] # Flag to determine if the lines have moved self.has_move = False # connection the marker and draw the pictures self.connect_markers([self.top_marker]) self.update() def setLayer(self, n): """ Allow adding plot to the same panel @param n: the number of layer """ self.layernum = n self.update() def clear(self): """ Clear this figure and its markers """ self.clear_markers() self.top_marker.remove() self.bottom_line.remove() self.top_line.remove() def update(self, x1=None, x2=None, y1=None, y2=None, width=None, height=None, center=None): """ Draw the new roughness on the graph. :param x1: new maximum value of x coordinates :param x2: new minimum value of x coordinates :param y1: new maximum value of y coordinates :param y2: new minimum value of y coordinates :param width: is the width of the new rectangle :param height: is the height of the new rectangle :param center: provided x, y coordinates of the center point """ # Save the new height, witdh of the rectangle if given as a param if width is not None: self.half_width = width if height is not None: self.half_height = height # If new center coordinates are given draw the rectangle # given these value if center is not None: self.center_x = center.x self.center_y = center.y self.x1 = self.half_width + self.center_x self.x2 = -self.half_width + self.center_x self.y1 = self.half_height + self.center_y self.y2 = -self.half_height + self.center_y self.top_marker.set(xdata=[self.center_x], ydata=[self.y1]) self.top_line.set(xdata=[self.x1, self.x2], ydata=[self.y1, self.y1]) self.bottom_line.set(xdata=[self.x1, self.x2], ydata=[self.y2, self.y2]) return # if x1, y1, y2, y3 are given draw the rectangle with this value if x1 is not None: self.x1 = x1 if x2 is not None: self.x2 = x2 if y1 is not None: self.y1 = y1 if y2 is not None: self.y2 = y2 # Draw 2 vertical lines and a marker self.top_marker.set(xdata=[self.center_x], ydata=[self.y1]) self.top_line.set(xdata=[self.x1, self.x2], ydata=[self.y1, self.y1]) self.bottom_line.set(xdata=[self.x1, self.x2], ydata=[self.y2, self.y2]) def save(self, ev): """ Remember the roughness for this layer and the next so that we can restore on Esc. """ self.save_x2 = self.x2 self.save_y2 = self.y2 self.save_x1 = self.x1 self.save_y1 = self.y1 self.save_half_height = self.half_height self.save_half_width = self.half_width def moveend(self, ev): """ After a dragging motion reset the flag self.has_move to False """ self.has_move = False self.base.moveend(ev) def restore(self): """ Restore the roughness for this layer. """ self.y2 = self.save_y2 self.x2 = self.save_x2 self.y1 = self.save_y1 self.x1 = self.save_x1 self.half_height = self.save_half_height self.half_width = self.save_half_width def move(self, x, y, ev): """ Process move to a new position, making sure that the move is allowed. """ self.y1 = y delta = self.y1 - self.center_y self.y2 = self.center_y - delta self.half_height = numpy.fabs(self.y1) - self.center_y self.has_move = True self.base.base.update() def setCursor(self, x, y): """ Update the figure given x and y """ self.move(x, y, None) self.update()