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Changeset e61a9b1 in sasview for src/sas

Timestamp:

Aug 17, 2017 10:01:11 AM (7 years ago)

Author:

Paul Kienzle <pkienzle@…>

Branches:

master, ESS_GUI, ESS_GUI_Docs, ESS_GUI_batch_fitting, ESS_GUI_bumps_abstraction, ESS_GUI_iss1116, ESS_GUI_iss879, ESS_GUI_iss959, ESS_GUI_opencl, ESS_GUI_ordering, ESS_GUI_sync_sascalc, costrafo411, magnetic_scatt, release-4.2.2, ticket-1009, ticket-1094-headless, ticket-1242-2d-resolution, ticket-1243, ticket-1249, ticket885, unittest-saveload

Children:

d24e41d

Parents:

fc6651c (diff), bc04647 (diff)
Note: this is a merge changeset, the changes displayed below correspond to the merge itself.
Use the (diff) links above to see all the changes relative to each parent.

Message:

Merge branch 'master' into FixingTicket741

Location:

src/sas

Files:

: 1 added
: 1 deleted
: 10 edited
: 1 moved

sascalc/data_util/nxsunit.py (modified) (2 diffs)
sascalc/data_util/qsmearing.py (modified) (1 diff)
sascalc/dataloader/manipulations.py (modified) (27 diffs)
sascalc/dataloader/readers/sesans_reader.py (modified) (3 diffs)
sasgui/guiframe/local_perspectives/plotting/Plotter2D.py (modified) (9 diffs)
sasgui/guiframe/local_perspectives/plotting/SectorSlicer.py (modified) (4 diffs)
sasgui/guiframe/local_perspectives/plotting/SlicerParameters.py (deleted)
sasgui/guiframe/local_perspectives/plotting/parameters_panel_boxsum.py (moved) (moved from src/sas/sasgui/guiframe/local_perspectives/plotting/slicerpanel.py) (11 diffs)
sasgui/guiframe/local_perspectives/plotting/parameters_panel_slicer.py (added)
sasgui/perspectives/fitting/basepage.py (modified) (1 diff)
sasgui/perspectives/fitting/fitting.py (modified) (4 diffs)
sasgui/perspectives/fitting/models.py (modified) (5 diffs)
sasgui/perspectives/fitting/model_thread.py (modified) (3 diffs)

Legend:

: Unmodified
: Added
: Removed

src/sas/sascalc/data_util/nxsunit.py

-                      rb699768
+                      r8e9536f
     sld = { '10^-6 Angstrom^-2': 1e-6, 'Angstrom^-2': 1 }
     Q = { 'invA': 1, 'invAng': 1, 'invAngstroms': 1, '1/A': 1,
           '10^-3 Angstrom^-1': 1e-3, '1/cm': 1e-8,
+          '10^-3 Angstrom^-1': 1e-3, '1/cm': 1e-8, '1/m': 1e-10,
           'nm^-1': 0.1, '1/nm': 0.1, 'n_m^-1': 0.1 }
 …
     _check(1,Converter('n_m^-1')(10,'invA')) # 10 nm^-1 = 1 inv Angstroms
     _check(2,Converter('mm')(2000,'m')) # 2000 mm -> 2 m
+    _check(2.011e10,Converter('1/A')(2.011,"1/m")) # 2.011 1/A -> 2.011 * 10^10 1/m
     _check(0.003,Converter('microseconds')(3,units='ms')) # 3 us -> 0.003 ms
     _check(45,Converter('nanokelvin')(45))  # 45 nK -> 45 nK

src/sas/sascalc/data_util/qsmearing.py

-                      r235f514
+                      r8938502
             raise ValueError('one or more of your dx values are negative, please check the data file!')
+    if _found_sesans == True:
+        #Pre-compute the Hankel matrix (H)
+        qmax, qunits = data.sample.zacceptance
+    if _found_sesans:
+        # Pre-compute the Hankel matrix (H)
         SElength = Converter(data._xunit)(data.x, "A")
+        zaccept = Converter(qunits)(qmax, "1/A"),
+        theta_max = Converter("radians")(data.sample.zacceptance)[0]
+        q_max = 2 * np.pi / np.max(data.source.wavelength) * np.sin(theta_max)
+        zaccept = Converter("1/A")(q_max, "1/" + data.source.wavelength_unit),
         Rmax = 10000000
+        hankel = SesansTransform(data.x, SElength, zaccept, Rmax)
+        hankel = SesansTransform(data.x, SElength,
+                                 data.source.wavelength,
+                                 zaccept, Rmax)
         # Then return the actual transform, as if it were a smearing function
         return PySmear(hankel, model, offset=0)

src/sas/sascalc/dataloader/manipulations.py

-                      r7432acb
+                      r324e0bf
+from __future__ import division
 """
 Data manipulations for 2D data sets.
 Using the meta data information, various types of averaging
 are performed in Q-space
+To test this module use:
+```
+cd test
+PYTHONPATH=../src/ python2  -m sasdataloader.test.utest_averaging DataInfoTests.test_sectorphi_quarter
+```
 """
 #####################################################################
 #This software was developed by the University of Tennessee as part of the
 #Distributed Data Analysis of Neutron Scattering Experiments (DANSE)
 #project funded by the US National Science Foundation.
 #See the license text in license.txt
 #copyright 2008, University of Tennessee
+# This software was developed by the University of Tennessee as part of the
+# Distributed Data Analysis of Neutron Scattering Experiments (DANSE)
+# project funded by the US National Science Foundation.
+# See the license text in license.txt
+# copyright 2008, University of Tennessee
 ######################################################################
+#TODO: copy the meta data from the 2D object to the resulting 1D object
+# TODO: copy the meta data from the 2D object to the resulting 1D object
 import math
+import numpy
+import numpy as np
+import sys
 #from data_info import plottable_2D
 …
     return phi_out
-def reader2D_converter(data2d=None):
-    """
-    convert old 2d format opened by IhorReader or danse_reader
-    to new Data2D format
-    :param data2d: 2d array of Data2D object
-    :return: 1d arrays of Data2D object
-    """
-    if data2d.data is None or data2d.x_bins is None or data2d.y_bins is None:
-        raise ValueError, "Can't convert this data: data=None..."
-    new_x = numpy.tile(data2d.x_bins, (len(data2d.y_bins), 1))
-    new_y = numpy.tile(data2d.y_bins, (len(data2d.x_bins), 1))
-    new_y = new_y.swapaxes(0, 1)
-    new_data = data2d.data.flatten()
-    qx_data = new_x.flatten()
-    qy_data = new_y.flatten()
-    q_data = numpy.sqrt(qx_data * qx_data + qy_data * qy_data)
-    if data2d.err_data is None or numpy.any(data2d.err_data <= 0):
-        new_err_data = numpy.sqrt(numpy.abs(new_data))
-    else:
-        new_err_data = data2d.err_data.flatten()
-    mask = numpy.ones(len(new_data), dtype=bool)
-    #TODO: make sense of the following two lines...
-    #from sas.sascalc.dataloader.data_info import Data2D
-    #output = Data2D()
-    output = data2d
-    output.data = new_data
-    output.err_data = new_err_data
-    output.qx_data = qx_data
-    output.qy_data = qy_data
-    output.q_data = q_data
-    output.mask = mask
-    return output
-class _Slab(object):
-    """
-    Compute average I(Q) for a region of interest
-    """
-    def __init__(self, x_min=0.0, x_max=0.0, y_min=0.0,
-                 y_max=0.0, bin_width=0.001):
-        # Minimum Qx value [A-1]
-        self.x_min = x_min
-        # Maximum Qx value [A-1]
-        self.x_max = x_max
-        # Minimum Qy value [A-1]
-        self.y_min = y_min
-        # Maximum Qy value [A-1]
-        self.y_max = y_max
-        # Bin width (step size) [A-1]
-        self.bin_width = bin_width
-        # If True, I(|Q|) will be return, otherwise,
-        # negative q-values are allowed
-        self.fold = False
-    def __call__(self, data2D):
-        return NotImplemented
-    def _avg(self, data2D, maj):
-        """
-        Compute average I(Q_maj) for a region of interest.
-        The major axis is defined as the axis of Q_maj.
-        The minor axis is the axis that we average over.
-        :param data2D: Data2D object
-        :param maj_min: min value on the major axis
-        :return: Data1D object
-        """
-        if len(data2D.detector) > 1:
-            msg = "_Slab._avg: invalid number of "
-            msg += " detectors: %g" % len(data2D.detector)
-            raise RuntimeError, msg
-        # Get data
-        data = data2D.data[numpy.isfinite(data2D.data)]
-        err_data = data2D.err_data[numpy.isfinite(data2D.data)]
-        qx_data = data2D.qx_data[numpy.isfinite(data2D.data)]
-        qy_data = data2D.qy_data[numpy.isfinite(data2D.data)]
-        # Build array of Q intervals
-        if maj == 'x':
-            if self.fold:
-                x_min = 0
-            else:
-                x_min = self.x_min
-            nbins = int(math.ceil((self.x_max - x_min) / self.bin_width))
-        elif maj == 'y':
-            if self.fold:
-                y_min = 0
-            else:
-                y_min = self.y_min
-            nbins = int(math.ceil((self.y_max - y_min) / self.bin_width))
-        else:
-            raise RuntimeError, "_Slab._avg: unrecognized axis %s" % str(maj)
-        x = numpy.zeros(nbins)
-        y = numpy.zeros(nbins)
-        err_y = numpy.zeros(nbins)
-        y_counts = numpy.zeros(nbins)
-        # Average pixelsize in q space
-        for npts in range(len(data)):
-            # default frac
-            frac_x = 0
-            frac_y = 0
-            # get ROI
-            if self.x_min <= qx_data[npts] and self.x_max > qx_data[npts]:
-                frac_x = 1
-            if self.y_min <= qy_data[npts] and self.y_max > qy_data[npts]:
-                frac_y = 1
-            frac = frac_x * frac_y
-            if frac == 0:
-                continue
-            # binning: find axis of q
-            if maj == 'x':
-                q_value = qx_data[npts]
-                min_value = x_min
-            if maj == 'y':
-                q_value = qy_data[npts]
-                min_value = y_min
-            if self.fold and q_value < 0:
-                q_value = -q_value
-            # bin
-            i_q = int(math.ceil((q_value - min_value) / self.bin_width)) - 1
-            # skip outside of max bins
-            if i_q < 0 or i_q >= nbins:
-                continue
-            #TODO: find better definition of x[i_q] based on q_data
-            # min_value + (i_q + 1) * self.bin_width / 2.0
-            x[i_q] += frac * q_value
-            y[i_q] += frac * data[npts]
-            if err_data is None or err_data[npts] == 0.0:
-                if data[npts] < 0:
-                    data[npts] = -data[npts]
-                err_y[i_q] += frac * frac * data[npts]
-            else:
-                err_y[i_q] += frac * frac * err_data[npts] * err_data[npts]
-            y_counts[i_q] += frac
-        # Average the sums
-        for n in range(nbins):
-            err_y[n] = math.sqrt(err_y[n])
-        err_y = err_y / y_counts
-        y = y / y_counts
-        x = x / y_counts
-        idx = (numpy.isfinite(y) & numpy.isfinite(x))
-        if not idx.any():
-            msg = "Average Error: No points inside ROI to average..."
-            raise ValueError, msg
-        return Data1D(x=x[idx], y=y[idx], dy=err_y[idx])
-class SlabY(_Slab):
-    """
-    Compute average I(Qy) for a region of interest
-    """
-    def __call__(self, data2D):
-        """
-        Compute average I(Qy) for a region of interest
-        :param data2D: Data2D object
-        :return: Data1D object
-        """
-        return self._avg(data2D, 'y')
-class SlabX(_Slab):
-    """
-    Compute average I(Qx) for a region of interest
-    """
-    def __call__(self, data2D):
-        """
-        Compute average I(Qx) for a region of interest
-        :param data2D: Data2D object
-        :return: Data1D object
-        """
-        return self._avg(data2D, 'x')
-class Boxsum(object):
-    """
-    Perform the sum of counts in a 2D region of interest.
-    """
-    def __init__(self, x_min=0.0, x_max=0.0, y_min=0.0, y_max=0.0):
-        # Minimum Qx value [A-1]
-        self.x_min = x_min
-        # Maximum Qx value [A-1]
-        self.x_max = x_max
-        # Minimum Qy value [A-1]
-        self.y_min = y_min
-        # Maximum Qy value [A-1]
-        self.y_max = y_max
-    def __call__(self, data2D):
-        """
-        Perform the sum in the region of interest
-        :param data2D: Data2D object
-        :return: number of counts, error on number of counts,
-            number of points summed
-        """
-        y, err_y, y_counts = self._sum(data2D)
-        # Average the sums
-        counts = 0 if y_counts == 0 else y
-        error = 0 if y_counts == 0 else math.sqrt(err_y)
-        # Added y_counts to return, SMK & PDB, 04/03/2013
-        return counts, error, y_counts
-    def _sum(self, data2D):
-        """
-        Perform the sum in the region of interest
-        :param data2D: Data2D object
-        :return: number of counts,
-            error on number of counts, number of entries summed
-        """
-        if len(data2D.detector) > 1:
-            msg = "Circular averaging: invalid number "
-            msg += "of detectors: %g" % len(data2D.detector)
-            raise RuntimeError, msg
-        # Get data
-        data = data2D.data[numpy.isfinite(data2D.data)]
-        err_data = data2D.err_data[numpy.isfinite(data2D.data)]
-        qx_data = data2D.qx_data[numpy.isfinite(data2D.data)]
-        qy_data = data2D.qy_data[numpy.isfinite(data2D.data)]
-        y = 0.0
-        err_y = 0.0
-        y_counts = 0.0
-        # Average pixelsize in q space
-        for npts in range(len(data)):
-            # default frac
-            frac_x = 0
-            frac_y = 0
-            # get min and max at each points
-            qx = qx_data[npts]
-            qy = qy_data[npts]
-            # get the ROI
-            if self.x_min <= qx and self.x_max > qx:
-                frac_x = 1
-            if self.y_min <= qy and self.y_max > qy:
-                frac_y = 1
-            #Find the fraction along each directions
-            frac = frac_x * frac_y
-            if frac == 0:
-                continue
-            y += frac * data[npts]
-            if err_data is None or err_data[npts] == 0.0:
-                if data[npts] < 0:
-                    data[npts] = -data[npts]
-                err_y += frac * frac * data[npts]
-            else:
-                err_y += frac * frac * err_data[npts] * err_data[npts]
-            y_counts += frac
-        return y, err_y, y_counts
-class Boxavg(Boxsum):
-    """
-    Perform the average of counts in a 2D region of interest.
-    """
-    def __init__(self, x_min=0.0, x_max=0.0, y_min=0.0, y_max=0.0):
-        super(Boxavg, self).__init__(x_min=x_min, x_max=x_max,
-                                     y_min=y_min, y_max=y_max)
-    def __call__(self, data2D):
-        """
-        Perform the sum in the region of interest
-        :param data2D: Data2D object
-        :return: average counts, error on average counts
-        """
-        y, err_y, y_counts = self._sum(data2D)
-        # Average the sums
-        counts = 0 if y_counts == 0 else y / y_counts
-        error = 0 if y_counts == 0 else math.sqrt(err_y) / y_counts
-        return counts, error
 def get_pixel_fraction_square(x, xmin, xmax):
     """
 …
         return 1.0
+class CircularAverage(object):
+    """
+    Perform circular averaging on 2D data
+    The data returned is the distribution of counts
+    as a function of Q
+    """
+    def __init__(self, r_min=0.0, r_max=0.0, bin_width=0.0005):
+        # Minimum radius included in the average [A-1]
+        self.r_min = r_min
+        # Maximum radius included in the average [A-1]
+        self.r_max = r_max
+        # Bin width (step size) [A-1]
+        self.bin_width = bin_width
+    def __call__(self, data2D, ismask=False):
+        """
+        Perform circular averaging on the data
+        :param data2D: Data2D object
+        :return: Data1D object
+        """
+        # Get data W/ finite values
+        data = data2D.data[numpy.isfinite(data2D.data)]
+        q_data = data2D.q_data[numpy.isfinite(data2D.data)]
+        err_data = data2D.err_data[numpy.isfinite(data2D.data)]
+        mask_data = data2D.mask[numpy.isfinite(data2D.data)]
+        dq_data = None
+        # Get the dq for resolution averaging
+        if data2D.dqx_data is not None and data2D.dqy_data is not None:
+            # The pinholes and det. pix contribution present
+            # in both direction of the 2D which must be subtracted when
+            # converting to 1D: dq_overlap should calculated ideally at
+            # q = 0. Note This method works on only pinhole geometry.
+            # Extrapolate dqx(r) and dqy(phi) at q = 0, and take an average.
+            z_max = max(data2D.q_data)
+            z_min = min(data2D.q_data)
+            x_max = data2D.dqx_data[data2D.q_data[z_max]]
+            x_min = data2D.dqx_data[data2D.q_data[z_min]]
+            y_max = data2D.dqy_data[data2D.q_data[z_max]]
+            y_min = data2D.dqy_data[data2D.q_data[z_min]]
+            # Find qdx at q = 0
+            dq_overlap_x = (x_min * z_max - x_max * z_min) / (z_max - z_min)
+            # when extrapolation goes wrong
+            if dq_overlap_x > min(data2D.dqx_data):
+                dq_overlap_x = min(data2D.dqx_data)
+            dq_overlap_x *= dq_overlap_x
+            # Find qdx at q = 0
+            dq_overlap_y = (y_min * z_max - y_max * z_min) / (z_max - z_min)
+            # when extrapolation goes wrong
+            if dq_overlap_y > min(data2D.dqy_data):
+                dq_overlap_y = min(data2D.dqy_data)
+            # get dq at q=0.
+            dq_overlap_y *= dq_overlap_y
+            dq_overlap = numpy.sqrt((dq_overlap_x + dq_overlap_y) / 2.0)
+            # Final protection of dq
+            if dq_overlap < 0:
+                dq_overlap = y_min
+            dqx_data = data2D.dqx_data[numpy.isfinite(data2D.data)]
+            dqy_data = data2D.dqy_data[numpy.isfinite(data2D.data)] - dq_overlap
+            # def; dqx_data = dq_r dqy_data = dq_phi
+            # Convert dq 2D to 1D here
+            dqx = dqx_data * dqx_data
+            dqy = dqy_data * dqy_data
+            dq_data = numpy.add(dqx, dqy)
+            dq_data = numpy.sqrt(dq_data)
+        #q_data_max = numpy.max(q_data)
+        if len(data2D.q_data) is None:
+            msg = "Circular averaging: invalid q_data: %g" % data2D.q_data
+            raise RuntimeError, msg
+        # Build array of Q intervals
+        nbins = int(math.ceil((self.r_max - self.r_min) / self.bin_width))
+        x = numpy.zeros(nbins)
+        y = numpy.zeros(nbins)
+        err_y = numpy.zeros(nbins)
+        err_x = numpy.zeros(nbins)
+        y_counts = numpy.zeros(nbins)
+        for npt in range(len(data)):
+            if ismask and not mask_data[npt]:
+                continue
+            frac = 0
+            # q-value at the pixel (j,i)
+            q_value = q_data[npt]
+            data_n = data[npt]
+            ## No need to calculate the frac when all data are within range
+            if self.r_min >= self.r_max:
+                raise ValueError, "Limit Error: min > max"
+            if self.r_min <= q_value and q_value <= self.r_max:
+                frac = 1
+            if frac == 0:
+                continue
+            i_q = int(math.floor((q_value - self.r_min) / self.bin_width))
+            # Take care of the edge case at phi = 2pi.
+            if i_q == nbins:
+                i_q = nbins - 1
+            y[i_q] += frac * data_n
+            # Take dqs from data to get the q_average
+            x[i_q] += frac * q_value
+            if err_data is None or err_data[npt] == 0.0:
+                if data_n < 0:
+                    data_n = -data_n
+                err_y[i_q] += frac * frac * data_n
+            else:
+                err_y[i_q] += frac * frac * err_data[npt] * err_data[npt]
+            if dq_data is not None:
+                # To be consistent with dq calculation in 1d reduction,
+                # we need just the averages (not quadratures) because
+                # it should not depend on the number of the q points
+                # in the qr bins.
+                err_x[i_q] += frac * dq_data[npt]
+            else:
+                err_x = None
+            y_counts[i_q] += frac
+        # Average the sums
+        for n in range(nbins):
+            if err_y[n] < 0:
+                err_y[n] = -err_y[n]
+            err_y[n] = math.sqrt(err_y[n])
+            #if err_x is not None:
+            #    err_x[n] = math.sqrt(err_x[n])
+        err_y = err_y / y_counts
+        err_y[err_y == 0] = numpy.average(err_y)
+        y = y / y_counts
+        x = x / y_counts
+        idx = (numpy.isfinite(y)) & (numpy.isfinite(x))
+        if err_x is not None:
+            d_x = err_x[idx] / y_counts[idx]
+        else:
+            d_x = None
+        if not idx.any():
+            msg = "Average Error: No points inside ROI to average..."
+            raise ValueError, msg
+        return Data1D(x=x[idx], y=y[idx], dy=err_y[idx], dx=d_x)
+class Ring(object):
+    """
+    Defines a ring on a 2D data set.
+    The ring is defined by r_min, r_max, and
+    the position of the center of the ring.
+    The data returned is the distribution of counts
+    around the ring as a function of phi.
+    Phi_min and phi_max should be defined between 0 and 2*pi
+    in anti-clockwise starting from the x- axis on the left-hand side
+    """
+    #Todo: remove center.
+    def __init__(self, r_min=0, r_max=0, center_x=0, center_y=0, nbins=36):
+        # Minimum radius
+        self.r_min = r_min
+        # Maximum radius
+        self.r_max = r_max
+        # Center of the ring in x
+        self.center_x = center_x
+        # Center of the ring in y
+        self.center_y = center_y
+        # Number of angular bins
+        self.nbins_phi = nbins
+    def __call__(self, data2D):
+        """
+        Apply the ring to the data set.
+        Returns the angular distribution for a given q range
+        :param data2D: Data2D object
+        :return: Data1D object
+        """
+        if data2D.__class__.__name__ not in ["Data2D", "plottable_2D"]:
+            raise RuntimeError, "Ring averaging only take plottable_2D objects"
+        Pi = math.pi
+        # Get data
+        data = data2D.data[numpy.isfinite(data2D.data)]
+        q_data = data2D.q_data[numpy.isfinite(data2D.data)]
+        err_data = data2D.err_data[numpy.isfinite(data2D.data)]
+        qx_data = data2D.qx_data[numpy.isfinite(data2D.data)]
+        qy_data = data2D.qy_data[numpy.isfinite(data2D.data)]
+        # Set space for 1d outputs
+        phi_bins = numpy.zeros(self.nbins_phi)
+        phi_counts = numpy.zeros(self.nbins_phi)
+        phi_values = numpy.zeros(self.nbins_phi)
+        phi_err = numpy.zeros(self.nbins_phi)
+        # Shift to apply to calculated phi values in order
+        # to center first bin at zero
+        phi_shift = Pi / self.nbins_phi
+        for npt in range(len(data)):
+            frac = 0
+            # q-value at the point (npt)
+            q_value = q_data[npt]
+            data_n = data[npt]
+            # phi-value at the point (npt)
+            phi_value = math.atan2(qy_data[npt], qx_data[npt]) + Pi
+            if self.r_min <= q_value and q_value <= self.r_max:
+                frac = 1
+            if frac == 0:
+                continue
+            # binning
+            i_phi = int(math.floor((self.nbins_phi) * \
+                                   (phi_value + phi_shift) / (2 * Pi)))
+            # Take care of the edge case at phi = 2pi.
+            if i_phi >= self.nbins_phi:
+                i_phi = 0
+            phi_bins[i_phi] += frac * data[npt]
+            if err_data is None or err_data[npt] == 0.0:
+                if data_n < 0:
+                    data_n = -data_n
+                phi_err[i_phi] += frac * frac * math.fabs(data_n)
+            else:
+                phi_err[i_phi] += frac * frac * err_data[npt] * err_data[npt]
+            phi_counts[i_phi] += frac
+        for i in range(self.nbins_phi):
+            phi_bins[i] = phi_bins[i] / phi_counts[i]
+            phi_err[i] = math.sqrt(phi_err[i]) / phi_counts[i]
+            phi_values[i] = 2.0 * math.pi / self.nbins_phi * (1.0 * i)
+        idx = (numpy.isfinite(phi_bins))
+        if not idx.any():
+            msg = "Average Error: No points inside ROI to average..."
+            raise ValueError, msg
+        #elif len(phi_bins[idx])!= self.nbins_phi:
+        #    print "resulted",self.nbins_phi- len(phi_bins[idx])
+        #,"empty bin(s) due to tight binning..."
+        return Data1D(x=phi_values[idx], y=phi_bins[idx], dy=phi_err[idx])
+def get_intercept(q, q_0, q_1):
+    """
+    Returns the fraction of the side at which the
+    q-value intercept the pixel, None otherwise.
+    The values returned is the fraction ON THE SIDE
+    OF THE LOWEST Q. ::
+            A           B
+        +-----------+--------+    <--- pixel size
+                    1
+        Q_0 -------- Q ----- Q_1   <--- equivalent Q range
+        if Q_1 > Q_0, A is returned
+        if Q_1 < Q_0, B is returned
+        if Q is outside the range of [Q_0, Q_1], None is returned
+    """
+    if q_1 > q_0:
+        if q > q_0 and q <= q_1:
+            return (q - q_0) / (q_1 - q_0)
+    else:
+        if q > q_1 and q <= q_0:
+            return (q - q_1) / (q_0 - q_1)
+    return None
 def get_pixel_fraction(qmax, q_00, q_01, q_10, q_11):
 …
     return frac_max
+def get_intercept(q, q_0, q_1):
+    """
+    Returns the fraction of the side at which the
+    q-value intercept the pixel, None otherwise.
+    The values returned is the fraction ON THE SIDE
+    OF THE LOWEST Q. ::
+            A           B
+        +-----------+--------+    <--- pixel size
+                    1
+        Q_0 -------- Q ----- Q_1   <--- equivalent Q range
+        if Q_1 > Q_0, A is returned
+        if Q_1 < Q_0, B is returned
+        if Q is outside the range of [Q_0, Q_1], None is returned
+    """
+    if q_1 > q_0:
+        if q > q_0 and q <= q_1:
+            return (q - q_0) / (q_1 - q_0)
+def get_dq_data(data2D):
+    '''
+    Get the dq for resolution averaging
+    The pinholes and det. pix contribution present
+    in both direction of the 2D which must be subtracted when
+    converting to 1D: dq_overlap should calculated ideally at
+    q = 0. Note This method works on only pinhole geometry.
+    Extrapolate dqx(r) and dqy(phi) at q = 0, and take an average.
+    '''
+    z_max = max(data2D.q_data)
+    z_min = min(data2D.q_data)
+    dqx_at_z_max = data2D.dqx_data[np.argmax(data2D.q_data)]
+    dqx_at_z_min = data2D.dqx_data[np.argmin(data2D.q_data)]
+    dqy_at_z_max = data2D.dqy_data[np.argmax(data2D.q_data)]
+    dqy_at_z_min = data2D.dqy_data[np.argmin(data2D.q_data)]
+    # Find qdx at q = 0
+    dq_overlap_x = (dqx_at_z_min * z_max - dqx_at_z_max * z_min) / (z_max - z_min)
+    # when extrapolation goes wrong
+    if dq_overlap_x > min(data2D.dqx_data):
+        dq_overlap_x = min(data2D.dqx_data)
+    dq_overlap_x *= dq_overlap_x
+    # Find qdx at q = 0
+    dq_overlap_y = (dqy_at_z_min * z_max - dqy_at_z_max * z_min) / (z_max - z_min)
+    # when extrapolation goes wrong
+    if dq_overlap_y > min(data2D.dqy_data):
+        dq_overlap_y = min(data2D.dqy_data)
+    # get dq at q=0.
+    dq_overlap_y *= dq_overlap_y
+    dq_overlap = np.sqrt((dq_overlap_x + dq_overlap_y) / 2.0)
+    # Final protection of dq
+    if dq_overlap < 0:
+        dq_overlap = dqy_at_z_min
+    dqx_data = data2D.dqx_data[np.isfinite(data2D.data)]
+    dqy_data = data2D.dqy_data[np.isfinite(
+        data2D.data)] - dq_overlap
+    # def; dqx_data = dq_r dqy_data = dq_phi
+    # Convert dq 2D to 1D here
+    dq_data = np.sqrt(dqx_data**2 + dqx_data**2)
+    return dq_data
+################################################################################
+def reader2D_converter(data2d=None):
+    """
+    convert old 2d format opened by IhorReader or danse_reader
+    to new Data2D format
+    This is mainly used by the Readers
+    :param data2d: 2d array of Data2D object
+    :return: 1d arrays of Data2D object
+    """
+    if data2d.data is None or data2d.x_bins is None or data2d.y_bins is None:
+        raise ValueError("Can't convert this data: data=None...")
+    new_x = np.tile(data2d.x_bins, (len(data2d.y_bins), 1))
+    new_y = np.tile(data2d.y_bins, (len(data2d.x_bins), 1))
+    new_y = new_y.swapaxes(0, 1)
+    new_data = data2d.data.flatten()
+    qx_data = new_x.flatten()
+    qy_data = new_y.flatten()
+    q_data = np.sqrt(qx_data * qx_data + qy_data * qy_data)
+    if data2d.err_data is None or np.any(data2d.err_data <= 0):
+        new_err_data = np.sqrt(np.abs(new_data))
     else:
+        if q > q_1 and q <= q_0:
+            return (q - q_1) / (q_0 - q_1)
+    return None
+        new_err_data = data2d.err_data.flatten()
+    mask = np.ones(len(new_data), dtype=bool)
+    # TODO: make sense of the following two lines...
+    #from sas.sascalc.dataloader.data_info import Data2D
+    #output = Data2D()
+    output = data2d
+    output.data = new_data
+    output.err_data = new_err_data
+    output.qx_data = qx_data
+    output.qy_data = qy_data
+    output.q_data = q_data
+    output.mask = mask
+    return output
+################################################################################
+class Binning(object):
+    '''
+    This class just creates a binning object
+    either linear or log
+    '''
+    def __init__(self, min_value, max_value, n_bins, base=None):
+        '''
+        if base is None: Linear binning
+        '''
+        self.min = min_value if min_value > 0 else 0.0001
+        self.max = max_value
+        self.n_bins = n_bins
+        self.base = base
+    def get_bin_index(self, value):
+        '''
+        The general formula logarithm binning is:
+        bin = floor(N * (log(x) - log(min)) / (log(max) - log(min)))
+        '''
+        if self.base:
+            temp_x = self.n_bins * (math.log(value, self.base) - math.log(self.min, self.base))
+            temp_y = math.log(self.max, self.base) - math.log(self.min, self.base)
+        else:
+            temp_x = self.n_bins * (value - self.min)
+            temp_y = self.max - self.min
+        # Bin index calulation
+        return int(math.floor(temp_x / temp_y))
+################################################################################
+class _Slab(object):
+    """
+    Compute average I(Q) for a region of interest
+    """
+    def __init__(self, x_min=0.0, x_max=0.0, y_min=0.0,
+                 y_max=0.0, bin_width=0.001):
+        # Minimum Qx value [A-1]
+        self.x_min = x_min
+        # Maximum Qx value [A-1]
+        self.x_max = x_max
+        # Minimum Qy value [A-1]
+        self.y_min = y_min
+        # Maximum Qy value [A-1]
+        self.y_max = y_max
+        # Bin width (step size) [A-1]
+        self.bin_width = bin_width
+        # If True, I(|Q|) will be return, otherwise,
+        # negative q-values are allowed
+        self.fold = False
+    def __call__(self, data2D):
+        return NotImplemented
+    def _avg(self, data2D, maj):
+        """
+        Compute average I(Q_maj) for a region of interest.
+        The major axis is defined as the axis of Q_maj.
+        The minor axis is the axis that we average over.
+        :param data2D: Data2D object
+        :param maj_min: min value on the major axis
+        :return: Data1D object
+        """
+        if len(data2D.detector) > 1:
+            msg = "_Slab._avg: invalid number of "
+            msg += " detectors: %g" % len(data2D.detector)
+            raise RuntimeError(msg)
+        # Get data
+        data = data2D.data[np.isfinite(data2D.data)]
+        err_data = data2D.err_data[np.isfinite(data2D.data)]
+        qx_data = data2D.qx_data[np.isfinite(data2D.data)]
+        qy_data = data2D.qy_data[np.isfinite(data2D.data)]
+        # Build array of Q intervals
+        if maj == 'x':
+            if self.fold:
+                x_min = 0
+            else:
+                x_min = self.x_min
+            nbins = int(math.ceil((self.x_max - x_min) / self.bin_width))
+        elif maj == 'y':
+            if self.fold:
+                y_min = 0
+            else:
+                y_min = self.y_min
+            nbins = int(math.ceil((self.y_max - y_min) / self.bin_width))
+        else:
+            raise RuntimeError("_Slab._avg: unrecognized axis %s" % str(maj))
+        x = np.zeros(nbins)
+        y = np.zeros(nbins)
+        err_y = np.zeros(nbins)
+        y_counts = np.zeros(nbins)
+        # Average pixelsize in q space
+        for npts in range(len(data)):
+            # default frac
+            frac_x = 0
+            frac_y = 0
+            # get ROI
+            if self.x_min <= qx_data[npts] and self.x_max > qx_data[npts]:
+                frac_x = 1
+            if self.y_min <= qy_data[npts] and self.y_max > qy_data[npts]:
+                frac_y = 1
+            frac = frac_x * frac_y
+            if frac == 0:
+                continue
+            # binning: find axis of q
+            if maj == 'x':
+                q_value = qx_data[npts]
+                min_value = x_min
+            if maj == 'y':
+                q_value = qy_data[npts]
+                min_value = y_min
+            if self.fold and q_value < 0:
+                q_value = -q_value
+            # bin
+            i_q = int(math.ceil((q_value - min_value) / self.bin_width)) - 1
+            # skip outside of max bins
+            if i_q < 0 or i_q >= nbins:
+                continue
+            # TODO: find better definition of x[i_q] based on q_data
+            # min_value + (i_q + 1) * self.bin_width / 2.0
+            x[i_q] += frac * q_value
+            y[i_q] += frac * data[npts]
+            if err_data is None or err_data[npts] == 0.0:
+                if data[npts] < 0:
+                    data[npts] = -data[npts]
+                err_y[i_q] += frac * frac * data[npts]
+            else:
+                err_y[i_q] += frac * frac * err_data[npts] * err_data[npts]
+            y_counts[i_q] += frac
+        # Average the sums
+        for n in range(nbins):
+            err_y[n] = math.sqrt(err_y[n])
+        err_y = err_y / y_counts
+        y = y / y_counts
+        x = x / y_counts
+        idx = (np.isfinite(y) & np.isfinite(x))
+        if not idx.any():
+            msg = "Average Error: No points inside ROI to average..."
+            raise ValueError(msg)
+        return Data1D(x=x[idx], y=y[idx], dy=err_y[idx])
+class SlabY(_Slab):
+    """
+    Compute average I(Qy) for a region of interest
+    """
+    def __call__(self, data2D):
+        """
+        Compute average I(Qy) for a region of interest
+        :param data2D: Data2D object
+        :return: Data1D object
+        """
+        return self._avg(data2D, 'y')
+class SlabX(_Slab):
+    """
+    Compute average I(Qx) for a region of interest
+    """
+    def __call__(self, data2D):
+        """
+        Compute average I(Qx) for a region of interest
+        :param data2D: Data2D object
+        :return: Data1D object
+        """
+        return self._avg(data2D, 'x')
+################################################################################
+class Boxsum(object):
+    """
+    Perform the sum of counts in a 2D region of interest.
+    """
+    def __init__(self, x_min=0.0, x_max=0.0, y_min=0.0, y_max=0.0):
+        # Minimum Qx value [A-1]
+        self.x_min = x_min
+        # Maximum Qx value [A-1]
+        self.x_max = x_max
+        # Minimum Qy value [A-1]
+        self.y_min = y_min
+        # Maximum Qy value [A-1]
+        self.y_max = y_max
+    def __call__(self, data2D):
+        """
+        Perform the sum in the region of interest
+        :param data2D: Data2D object
+        :return: number of counts, error on number of counts,
+            number of points summed
+        """
+        y, err_y, y_counts = self._sum(data2D)
+        # Average the sums
+        counts = 0 if y_counts == 0 else y
+        error = 0 if y_counts == 0 else math.sqrt(err_y)
+        # Added y_counts to return, SMK & PDB, 04/03/2013
+        return counts, error, y_counts
+    def _sum(self, data2D):
+        """
+        Perform the sum in the region of interest
+        :param data2D: Data2D object
+        :return: number of counts,
+            error on number of counts, number of entries summed
+        """
+        if len(data2D.detector) > 1:
+            msg = "Circular averaging: invalid number "
+            msg += "of detectors: %g" % len(data2D.detector)
+            raise RuntimeError(msg)
+        # Get data
+        data = data2D.data[np.isfinite(data2D.data)]
+        err_data = data2D.err_data[np.isfinite(data2D.data)]
+        qx_data = data2D.qx_data[np.isfinite(data2D.data)]
+        qy_data = data2D.qy_data[np.isfinite(data2D.data)]
+        y = 0.0
+        err_y = 0.0
+        y_counts = 0.0
+        # Average pixelsize in q space
+        for npts in range(len(data)):
+            # default frac
+            frac_x = 0
+            frac_y = 0
+            # get min and max at each points
+            qx = qx_data[npts]
+            qy = qy_data[npts]
+            # get the ROI
+            if self.x_min <= qx and self.x_max > qx:
+                frac_x = 1
+            if self.y_min <= qy and self.y_max > qy:
+                frac_y = 1
+            # Find the fraction along each directions
+            frac = frac_x * frac_y
+            if frac == 0:
+                continue
+            y += frac * data[npts]
+            if err_data is None or err_data[npts] == 0.0:
+                if data[npts] < 0:
+                    data[npts] = -data[npts]
+                err_y += frac * frac * data[npts]
+            else:
+                err_y += frac * frac * err_data[npts] * err_data[npts]
+            y_counts += frac
+        return y, err_y, y_counts
+class Boxavg(Boxsum):
+    """
+    Perform the average of counts in a 2D region of interest.
+    """
+    def __init__(self, x_min=0.0, x_max=0.0, y_min=0.0, y_max=0.0):
+        super(Boxavg, self).__init__(x_min=x_min, x_max=x_max,
+                                     y_min=y_min, y_max=y_max)
+    def __call__(self, data2D):
+        """
+        Perform the sum in the region of interest
+        :param data2D: Data2D object
+        :return: average counts, error on average counts
+        """
+        y, err_y, y_counts = self._sum(data2D)
+        # Average the sums
+        counts = 0 if y_counts == 0 else y / y_counts
+        error = 0 if y_counts == 0 else math.sqrt(err_y) / y_counts
+        return counts, error
+################################################################################
+class CircularAverage(object):
+    """
+    Perform circular averaging on 2D data
+    The data returned is the distribution of counts
+    as a function of Q
+    """
+    def __init__(self, r_min=0.0, r_max=0.0, bin_width=0.0005):
+        # Minimum radius included in the average [A-1]
+        self.r_min = r_min
+        # Maximum radius included in the average [A-1]
+        self.r_max = r_max
+        # Bin width (step size) [A-1]
+        self.bin_width = bin_width
+    def __call__(self, data2D, ismask=False):
+        """
+        Perform circular averaging on the data
+        :param data2D: Data2D object
+        :return: Data1D object
+        """
+        # Get data W/ finite values
+        data = data2D.data[np.isfinite(data2D.data)]
+        q_data = data2D.q_data[np.isfinite(data2D.data)]
+        err_data = data2D.err_data[np.isfinite(data2D.data)]
+        mask_data = data2D.mask[np.isfinite(data2D.data)]
+        dq_data = None
+        if data2D.dqx_data is not None and data2D.dqy_data is not None:
+            dq_data = get_dq_data(data2D)
+        if len(q_data) == 0:
+            msg = "Circular averaging: invalid q_data: %g" % data2D.q_data
+            raise RuntimeError(msg)
+        # Build array of Q intervals
+        nbins = int(math.ceil((self.r_max - self.r_min) / self.bin_width))
+        x = np.zeros(nbins)
+        y = np.zeros(nbins)
+        err_y = np.zeros(nbins)
+        err_x = np.zeros(nbins)
+        y_counts = np.zeros(nbins)
+        for npt in range(len(data)):
+            if ismask and not mask_data[npt]:
+                continue
+            frac = 0
+            # q-value at the pixel (j,i)
+            q_value = q_data[npt]
+            data_n = data[npt]
+            # No need to calculate the frac when all data are within range
+            if self.r_min >= self.r_max:
+                raise ValueError("Limit Error: min > max")
+            if self.r_min <= q_value and q_value <= self.r_max:
+                frac = 1
+            if frac == 0:
+                continue
+            i_q = int(math.floor((q_value - self.r_min) / self.bin_width))
+            # Take care of the edge case at phi = 2pi.
+            if i_q == nbins:
+                i_q = nbins - 1
+            y[i_q] += frac * data_n
+            # Take dqs from data to get the q_average
+            x[i_q] += frac * q_value
+            if err_data is None or err_data[npt] == 0.0:
+                if data_n < 0:
+                    data_n = -data_n
+                err_y[i_q] += frac * frac * data_n
+            else:
+                err_y[i_q] += frac * frac * err_data[npt] * err_data[npt]
+            if dq_data is not None:
+                # To be consistent with dq calculation in 1d reduction,
+                # we need just the averages (not quadratures) because
+                # it should not depend on the number of the q points
+                # in the qr bins.
+                err_x[i_q] += frac * dq_data[npt]
+            else:
+                err_x = None
+            y_counts[i_q] += frac
+        # Average the sums
+        for n in range(nbins):
+            if err_y[n] < 0:
+                err_y[n] = -err_y[n]
+            err_y[n] = math.sqrt(err_y[n])
+            # if err_x is not None:
+            #    err_x[n] = math.sqrt(err_x[n])
+        err_y = err_y / y_counts
+        err_y[err_y == 0] = np.average(err_y)
+        y = y / y_counts
+        x = x / y_counts
+        idx = (np.isfinite(y)) & (np.isfinite(x))
+        if err_x is not None:
+            d_x = err_x[idx] / y_counts[idx]
+        else:
+            d_x = None
+        if not idx.any():
+            msg = "Average Error: No points inside ROI to average..."
+            raise ValueError(msg)
+        return Data1D(x=x[idx], y=y[idx], dy=err_y[idx], dx=d_x)
+################################################################################
+class Ring(object):
+    """
+    Defines a ring on a 2D data set.
+    The ring is defined by r_min, r_max, and
+    the position of the center of the ring.
+    The data returned is the distribution of counts
+    around the ring as a function of phi.
+    Phi_min and phi_max should be defined between 0 and 2*pi
+    in anti-clockwise starting from the x- axis on the left-hand side
+    """
+    # Todo: remove center.
+    def __init__(self, r_min=0, r_max=0, center_x=0, center_y=0, nbins=36):
+        # Minimum radius
+        self.r_min = r_min
+        # Maximum radius
+        self.r_max = r_max
+        # Center of the ring in x
+        self.center_x = center_x
+        # Center of the ring in y
+        self.center_y = center_y
+        # Number of angular bins
+        self.nbins_phi = nbins
+    def __call__(self, data2D):
+        """
+        Apply the ring to the data set.
+        Returns the angular distribution for a given q range
+        :param data2D: Data2D object
+        :return: Data1D object
+        """
+        if data2D.__class__.__name__ not in ["Data2D", "plottable_2D"]:
+            raise RuntimeError("Ring averaging only take plottable_2D objects")
+        Pi = math.pi
+        # Get data
+        data = data2D.data[np.isfinite(data2D.data)]
+        q_data = data2D.q_data[np.isfinite(data2D.data)]
+        err_data = data2D.err_data[np.isfinite(data2D.data)]
+        qx_data = data2D.qx_data[np.isfinite(data2D.data)]
+        qy_data = data2D.qy_data[np.isfinite(data2D.data)]
+        # Set space for 1d outputs
+        phi_bins = np.zeros(self.nbins_phi)
+        phi_counts = np.zeros(self.nbins_phi)
+        phi_values = np.zeros(self.nbins_phi)
+        phi_err = np.zeros(self.nbins_phi)
+        # Shift to apply to calculated phi values in order
+        # to center first bin at zero
+        phi_shift = Pi / self.nbins_phi
+        for npt in range(len(data)):
+            frac = 0
+            # q-value at the point (npt)
+            q_value = q_data[npt]
+            data_n = data[npt]
+            # phi-value at the point (npt)
+            phi_value = math.atan2(qy_data[npt], qx_data[npt]) + Pi
+            if self.r_min <= q_value and q_value <= self.r_max:
+                frac = 1
+            if frac == 0:
+                continue
+            # binning
+            i_phi = int(math.floor((self.nbins_phi) *
+                                   (phi_value + phi_shift) / (2 * Pi)))
+            # Take care of the edge case at phi = 2pi.
+            if i_phi >= self.nbins_phi:
+                i_phi = 0
+            phi_bins[i_phi] += frac * data[npt]
+            if err_data is None or err_data[npt] == 0.0:
+                if data_n < 0:
+                    data_n = -data_n
+                phi_err[i_phi] += frac * frac * math.fabs(data_n)
+            else:
+                phi_err[i_phi] += frac * frac * err_data[npt] * err_data[npt]
+            phi_counts[i_phi] += frac
+        for i in range(self.nbins_phi):
+            phi_bins[i] = phi_bins[i] / phi_counts[i]
+            phi_err[i] = math.sqrt(phi_err[i]) / phi_counts[i]
+            phi_values[i] = 2.0 * math.pi / self.nbins_phi * (1.0 * i)
+        idx = (np.isfinite(phi_bins))
+        if not idx.any():
+            msg = "Average Error: No points inside ROI to average..."
+            raise ValueError(msg)
+        # elif len(phi_bins[idx])!= self.nbins_phi:
+        #    print "resulted",self.nbins_phi- len(phi_bins[idx])
+        #,"empty bin(s) due to tight binning..."
+        return Data1D(x=phi_values[idx], y=phi_bins[idx], dy=phi_err[idx])
 …
     starting from the x- axis on the left-hand side
     """
+    def __init__(self, r_min, r_max, phi_min=0, phi_max=2 * math.pi, nbins=20):
+    def __init__(self, r_min, r_max, phi_min=0, phi_max=2 * math.pi, nbins=20,
+                 base=None):
+        '''
+        :param base: must be a valid base for an algorithm, i.e.,
+        a positive number
+        '''
         self.r_min = r_min
         self.r_max = r_max
 …
         self.phi_max = phi_max
         self.nbins = nbins
+        self.base = base
     def _agv(self, data2D, run='phi'):
 …
         """
         if data2D.__class__.__name__ not in ["Data2D", "plottable_2D"]:
+            raise RuntimeError, "Ring averaging only take plottable_2D objects"
+        Pi = math.pi
+            raise RuntimeError("Ring averaging only take plottable_2D objects")
         # Get the all data & info
+        data = data2D.data[numpy.isfinite(data2D.data)]
+        q_data = data2D.q_data[numpy.isfinite(data2D.data)]
+        err_data = data2D.err_data[numpy.isfinite(data2D.data)]
+        qx_data = data2D.qx_data[numpy.isfinite(data2D.data)]
+        qy_data = data2D.qy_data[numpy.isfinite(data2D.data)]
+        data = data2D.data[np.isfinite(data2D.data)]
+        q_data = data2D.q_data[np.isfinite(data2D.data)]
+        err_data = data2D.err_data[np.isfinite(data2D.data)]
+        qx_data = data2D.qx_data[np.isfinite(data2D.data)]
+        qy_data = data2D.qy_data[np.isfinite(data2D.data)]
         dq_data = None
-        # Get the dq for resolution averaging
         if data2D.dqx_data is not None and data2D.dqy_data is not None:
+            # The pinholes and det. pix contribution present
+            # in both direction of the 2D which must be subtracted when
+            # converting to 1D: dq_overlap should calculated ideally at
+            # q = 0.
+            # Extrapolate dqy(perp) at q = 0
+            z_max = max(data2D.q_data)
+            z_min = min(data2D.q_data)
+            x_max = data2D.dqx_data[data2D.q_data[z_max]]
+            x_min = data2D.dqx_data[data2D.q_data[z_min]]
+            y_max = data2D.dqy_data[data2D.q_data[z_max]]
+            y_min = data2D.dqy_data[data2D.q_data[z_min]]
+            # Find qdx at q = 0
+            dq_overlap_x = (x_min * z_max - x_max * z_min) / (z_max - z_min)
+            # when extrapolation goes wrong
+            if dq_overlap_x > min(data2D.dqx_data):
+                dq_overlap_x = min(data2D.dqx_data)
+            dq_overlap_x *= dq_overlap_x
+            # Find qdx at q = 0
+            dq_overlap_y = (y_min * z_max - y_max * z_min) / (z_max - z_min)
+            # when extrapolation goes wrong
+            if dq_overlap_y > min(data2D.dqy_data):
+                dq_overlap_y = min(data2D.dqy_data)
+            # get dq at q=0.
+            dq_overlap_y *= dq_overlap_y
+            dq_overlap = numpy.sqrt((dq_overlap_x + dq_overlap_y) / 2.0)
+            if dq_overlap < 0:
+                dq_overlap = y_min
+            dqx_data = data2D.dqx_data[numpy.isfinite(data2D.data)]
+            dqy_data = data2D.dqy_data[numpy.isfinite(data2D.data)] - dq_overlap
+            # def; dqx_data = dq_r dqy_data = dq_phi
+            # Convert dq 2D to 1D here
+            dqx = dqx_data * dqx_data
+            dqy = dqy_data * dqy_data
+            dq_data = numpy.add(dqx, dqy)
+            dq_data = numpy.sqrt(dq_data)
+        #set space for 1d outputs
+        x = numpy.zeros(self.nbins)
+        y = numpy.zeros(self.nbins)
+        y_err = numpy.zeros(self.nbins)
+        x_err = numpy.zeros(self.nbins)
+        y_counts = numpy.zeros(self.nbins)
+            dq_data = get_dq_data(data2D)
+        # set space for 1d outputs
+        x = np.zeros(self.nbins)
+        y = np.zeros(self.nbins)
+        y_err = np.zeros(self.nbins)
+        x_err = np.zeros(self.nbins)
+        y_counts = np.zeros(self.nbins)  # Cycle counts (for the mean)
         # Get the min and max into the region: 0 <= phi < 2Pi
 …
         phi_max = flip_phi(self.phi_max)
+        #  binning object
+        if run.lower() == 'phi':
+            binning = Binning(self.phi_min, self.phi_max, self.nbins, self.base)
+        else:
+            binning = Binning(self.r_min, self.r_max, self.nbins, self.base)
         for n in range(len(data)):
-            frac = 0
             # q-value at the pixel (j,i)
 …
             # phi-value of the pixel (j,i)
+            phi_value = math.atan2(qy_data[n], qx_data[n]) + Pi
+            ## No need to calculate the frac when all data are within range
+            if self.r_min <= q_value and q_value <= self.r_max:
+                frac = 1
+            if frac == 0:
+            phi_value = math.atan2(qy_data[n], qx_data[n]) + math.pi
+            # No need to calculate: data outside of the radius
+            if self.r_min > q_value or q_value > self.r_max:
                 continue
+            #In case of two ROIs (symmetric major and minor regions)(for 'q2')
+            # In case of two ROIs (symmetric major and minor regions)(for 'q2')
             if run.lower() == 'q2':
                 ## For minor sector wing
+                # For minor sector wing
                 # Calculate the minor wing phis
                 phi_min_minor = flip_phi(phi_min - Pi)
                 phi_max_minor = flip_phi(phi_max - Pi)
+                phi_min_minor = flip_phi(phi_min - math.pi)
+                phi_max_minor = flip_phi(phi_max - math.pi)
                 # Check if phis of the minor ring is within 0 to 2pi
                 if phi_min_minor > phi_max_minor:
                     is_in = (phi_value > phi_min_minor or \
                               phi_value < phi_max_minor)
+                    is_in = (phi_value > phi_min_minor or
+                             phi_value < phi_max_minor)
                 else:
                     is_in = (phi_value > phi_min_minor and \
                               phi_value < phi_max_minor)
             #For all cases(i.e.,for 'q', 'q2', and 'phi')
             #Find pixels within ROI
+                    is_in = (phi_value > phi_min_minor and
+                             phi_value < phi_max_minor)
+            # For all cases(i.e.,for 'q', 'q2', and 'phi')
+            # Find pixels within ROI
             if phi_min > phi_max:
                 is_in = is_in or (phi_value > phi_min or \
                                    phi_value < phi_max)
+                is_in = is_in or (phi_value > phi_min or
+                                  phi_value < phi_max)
             else:
+                is_in = is_in or (phi_value >= phi_min  and \
+                                    phi_value < phi_max)
+                is_in = is_in or (phi_value >= phi_min and
+                                  phi_value < phi_max)
+            # data oustide of the phi range
             if not is_in:
-                frac = 0
-            if frac == 0:
                 continue
+            # Check which type of averaging we need
+            # Get the binning index
             if run.lower() == 'phi':
+                temp_x = (self.nbins) * (phi_value - self.phi_min)
+                temp_y = (self.phi_max - self.phi_min)
+                i_bin = int(math.floor(temp_x / temp_y))
+                i_bin = binning.get_bin_index(phi_value)
             else:
+                temp_x = (self.nbins) * (q_value - self.r_min)
+                temp_y = (self.r_max - self.r_min)
+                i_bin = int(math.floor(temp_x / temp_y))
+                i_bin = binning.get_bin_index(q_value)
             # Take care of the edge case at phi = 2pi.
 …
                 i_bin = self.nbins - 1
             ## Get the total y
             y[i_bin] += frac * data_n
             x[i_bin] += frac * q_value
+            # Get the total y
+            y[i_bin] += data_n
+            x[i_bin] += q_value
             if err_data[n] is None or err_data[n] == 0.0:
                 if data_n < 0:
                     data_n = -data_n
                 y_err[i_bin] += frac * frac * data_n
+                y_err[i_bin] += data_n
             else:
                 y_err[i_bin] += frac * frac * err_data[n] * err_data[n]
+                y_err[i_bin] += err_data[n]**2
             if dq_data is not None:
 …
                 # it should not depend on the number of the q points
                 # in the qr bins.
                 x_err[i_bin] += frac * dq_data[n]
+                x_err[i_bin] += dq_data[n]
             else:
                 x_err = None
             y_counts[i_bin] += frac
+            y_counts[i_bin] += 1
         # Organize the results
 …
                 # We take the center of ring area, not radius.
                 # This is more accurate than taking the radial center of ring.
                 #delta_r = (self.r_max - self.r_min) / self.nbins
                 #r_inner = self.r_min + delta_r * i
                 #r_outer = r_inner + delta_r
                 #x[i] = math.sqrt((r_inner * r_inner + r_outer * r_outer) / 2)
+                # delta_r = (self.r_max - self.r_min) / self.nbins
+                # r_inner = self.r_min + delta_r * i
+                # r_outer = r_inner + delta_r
+                # x[i] = math.sqrt((r_inner * r_inner + r_outer * r_outer) / 2)
                 x[i] = x[i] / y_counts[i]
         y_err[y_err == 0] = numpy.average(y_err)
         idx = (numpy.isfinite(y) & numpy.isfinite(y_err))
+        y_err[y_err == 0] = np.average(y_err)
+        idx = (np.isfinite(y) & np.isfinite(y_err))
         if x_err is not None:
             d_x = x_err[idx] / y_counts[idx]
 …
         if not idx.any():
             msg = "Average Error: No points inside sector of ROI to average..."
             raise ValueError, msg
         #elif len(y[idx])!= self.nbins:
+            raise ValueError(msg)
+        # elif len(y[idx])!= self.nbins:
         #    print "resulted",self.nbins- len(y[idx]),
         #"empty bin(s) due to tight binning..."
+        # "empty bin(s) due to tight binning..."
         return Data1D(x=x[idx], y=y[idx], dy=y_err[idx], dx=d_x)
 …
     The number of bin in phi also has to be defined.
     """
     def __call__(self, data2D):
         """
 …
     The number of bin in Q also has to be defined.
     """
     def __call__(self, data2D):
         """
 …
         return self._agv(data2D, 'q2')
+################################################################################
 class Ringcut(object):
 …
     in anti-clockwise starting from the x- axis on the left-hand side
     """
     def __init__(self, r_min=0, r_max=0, center_x=0, center_y=0):
         # Minimum radius
 …
         """
         if data2D.__class__.__name__ not in ["Data2D", "plottable_2D"]:
             raise RuntimeError, "Ring cut only take plottable_2D objects"
+            raise RuntimeError("Ring cut only take plottable_2D objects")
         # Get data
         qx_data = data2D.qx_data
         qy_data = data2D.qy_data
         q_data = numpy.sqrt(qx_data * qx_data + qy_data * qy_data)
+        q_data = np.sqrt(qx_data * qx_data + qy_data * qy_data)
         # check whether or not the data point is inside ROI
 …
         return out
+################################################################################
 class Boxcut(object):
 …
     Find a rectangular 2D region of interest.
     """
     def __init__(self, x_min=0.0, x_max=0.0, y_min=0.0, y_max=0.0):
         # Minimum Qx value [A-1]
 …
         """
         if data2D.__class__.__name__ not in ["Data2D", "plottable_2D"]:
             raise RuntimeError, "Boxcut take only plottable_2D objects"
+            raise RuntimeError("Boxcut take only plottable_2D objects")
         # Get qx_ and qy_data
         qx_data = data2D.qx_data
 …
         return outx & outy
+################################################################################
 class Sectorcut(object):
 …
     and (phi_max-phi_min) should not be larger than pi
     """
     def __init__(self, phi_min=0, phi_max=math.pi):
         self.phi_min = phi_min
 …
         """
         if data2D.__class__.__name__ not in ["Data2D", "plottable_2D"]:
             raise RuntimeError, "Sectorcut take only plottable_2D objects"
+            raise RuntimeError("Sectorcut take only plottable_2D objects")
         Pi = math.pi
         # Get data
 …
         # get phi from data
         phi_data = numpy.arctan2(qy_data, qx_data)
+        phi_data = np.arctan2(qy_data, qx_data)
         # Get the min and max into the region: -pi <= phi < Pi
 …
         # check for major sector
         if phi_min_major > phi_max_major:
+            out_major = (phi_min_major <= phi_data) + (phi_max_major > phi_data)
+            out_major = (phi_min_major <= phi_data) + \
+                (phi_max_major > phi_data)
         else:
+            out_major = (phi_min_major <= phi_data) & (phi_max_major > phi_data)
+            out_major = (phi_min_major <= phi_data) & (
+                phi_max_major > phi_data)
         # minor sector
 …
         if phi_min_minor > phi_max_minor:
             out_minor = (phi_min_minor <= phi_data) + \
                             (phi_max_minor >= phi_data)
+                (phi_max_minor >= phi_data)
         else:
             out_minor = (phi_min_minor <= phi_data) & \
                             (phi_max_minor >= phi_data)
+                (phi_max_minor >= phi_data)
         out = out_major + out_minor

src/sas/sascalc/dataloader/readers/sesans_reader.py

-                      r9a5097c
+                      r149b8f6
 """
     SESANS reader (based on ASCII reader)
     Reader for .ses or .sesans file format
     Jurrian Bakker
+    Jurrian Bakker
 """
 import numpy as np
 …
 _ZERO = 1e-16
 class Reader:
     """
     Class to load sesans files (6 columns).
     """
     ## File type
+    # File type
     type_name = "SESANS"
     ## Wildcards
+    # Wildcards
     type = ["SESANS files (*.ses)|*.ses",
             "SESANS files (*..sesans)|*.sesans"]
     ## List of allowed extensions
+    # List of allowed extensions
     ext = ['.ses', '.SES', '.sesans', '.SESANS']
     ## Flag to bypass extension check
+    # Flag to bypass extension check
     allow_all = True
     def read(self, path):
-#        print "reader triggered"
         """
         Load data file
         :param path: file path
         :return: SESANSData1D object, or None
         :raise RuntimeError: when the file can't be opened
         :raise ValueError: when the length of the data vectors are inconsistent
 …
             basename = os.path.basename(path)
             _, extension = os.path.splitext(basename)
+            if self.allow_all or extension.lower() in self.ext:
+                try:
+                    # Read in binary mode since GRASP frequently has no-ascii
+                    # characters that brakes the open operation
+                    input_f = open(path,'rb')
+                except:
+                    raise  RuntimeError, "sesans_reader: cannot open %s" % path
+                buff = input_f.read()
+                lines = buff.splitlines()
+                x  = np.zeros(0)
+                y  = np.zeros(0)
+                dy = np.zeros(0)
+                lam  = np.zeros(0)
+                dlam = np.zeros(0)
+                dx = np.zeros(0)
+               #temp. space to sort data
+                tx  = np.zeros(0)
+                ty  = np.zeros(0)
+                tdy = np.zeros(0)
+                tlam  = np.zeros(0)
+                tdlam = np.zeros(0)
+                tdx = np.zeros(0)
+                output = Data1D(x=x, y=y, lam=lam, dy=dy, dx=dx, dlam=dlam, isSesans=True)
+                self.filename = output.filename = basename
+            if not (self.allow_all or extension.lower() in self.ext):
+                raise RuntimeError(
+                    "{} has an unrecognized file extension".format(path))
+        else:
+            raise RuntimeError("{} is not a file".format(path))
+        with open(path, 'r') as input_f:
+            line = input_f.readline()
+            params = {}
+            while not line.startswith("BEGIN_DATA"):
+                terms = line.split()
+                if len(terms) >= 2:
+                    params[terms[0]] = " ".join(terms[1:])
+                line = input_f.readline()
+            self.params = params
+                paramnames=[]
+                paramvals=[]
+                zvals=[]
+                dzvals=[]
+                lamvals=[]
+                dlamvals=[]
+                Pvals=[]
+                dPvals=[]
+            if "FileFormatVersion" not in self.params:
+                raise RuntimeError("SES file missing FileFormatVersion")
+            if float(self.params["FileFormatVersion"]) >= 2.0:
+                raise RuntimeError("SASView only supports SES version 1")
+                for line in lines:
+                    # Initial try for CSV (split on ,)
+                    line=line.strip()
+                    toks = line.split('\t')
+                    if len(toks)==2:
+                        paramnames.append(toks[0])
+                        paramvals.append(toks[1])
+                    if len(toks)>5:
+                        zvals.append(toks[0])
+                        dzvals.append(toks[3])
+                        lamvals.append(toks[4])
+                        dlamvals.append(toks[5])
+                        Pvals.append(toks[1])
+                        dPvals.append(toks[2])
+                    else:
+                        continue
+            if "SpinEchoLength_unit" not in self.params:
+                raise RuntimeError("SpinEchoLength has no units")
+            if "Wavelength_unit" not in self.params:
+                raise RuntimeError("Wavelength has no units")
+            if params["SpinEchoLength_unit"] != params["Wavelength_unit"]:
+                raise RuntimeError("The spin echo data has rudely used "
+                                   "different units for the spin echo length "
+                                   "and the wavelength.  While sasview could "
+                                   "handle this instance, it is a violation "
+                                   "of the file format and will not be "
+                                   "handled by other software.")
+                x=[]
+                y=[]
+                lam=[]
+                dx=[]
+                dy=[]
+                dlam=[]
+                lam_header = lamvals[0].split()
+                data_conv_z = None
+                default_z_unit = "A"
+                data_conv_P = None
+                default_p_unit = " " # Adjust unit for axis (L^-3)
+                lam_unit = lam_header[1].replace("[","").replace("]","")
+                if lam_unit == 'AA':
+                    lam_unit = 'A'
+                varheader=[zvals[0],dzvals[0],lamvals[0],dlamvals[0],Pvals[0],dPvals[0]]
+                valrange=range(1, len(zvals))
+                for i in valrange:
+                    x.append(float(zvals[i]))
+                    y.append(float(Pvals[i]))
+                    lam.append(float(lamvals[i]))
+                    dy.append(float(dPvals[i]))
+                    dx.append(float(dzvals[i]))
+                    dlam.append(float(dlamvals[i]))
+            headers = input_f.readline().split()
                 x,y,lam,dy,dx,dlam = [
                     np.asarray(v, 'double')
                    for v in (x,y,lam,dy,dx,dlam)
+                ]
+            self._insist_header(headers, "SpinEchoLength")
+            self._insist_header(headers, "Depolarisation")
+            self._insist_header(headers, "Depolarisation_error")
+            self._insist_header(headers, "Wavelength")
                 input_f.close()
+            data = np.loadtxt(input_f)
+                output.x, output.x_unit = self._unit_conversion(x, lam_unit, default_z_unit)
+                output.y = y
+                output.y_unit = r'\AA^{-2} cm^{-1}'  # output y_unit added
+                output.dx, output.dx_unit = self._unit_conversion(dx, lam_unit, default_z_unit)
+                output.dy = dy
+                output.lam, output.lam_unit = self._unit_conversion(lam, lam_unit, default_z_unit)
+                output.dlam, output.dlam_unit = self._unit_conversion(dlam, lam_unit, default_z_unit)
+                output.xaxis(r"\rm{z}", output.x_unit)
+                output.yaxis(r"\rm{ln(P)/(t \lambda^2)}", output.y_unit)  # Adjust label to ln P/(lam^2 t), remove lam column refs
+            if data.shape[1] != len(headers):
+                raise RuntimeError(
+                    "File has {} headers, but {} columns".format(
+                        len(headers),
+                        data.shape[1]))
+                # Store loading process information
+                output.meta_data['loader'] = self.type_name
+                #output.sample.thickness = float(paramvals[6])
+                output.sample.name = paramvals[1]
+                output.sample.ID = paramvals[0]
+                zaccept_unit_split = paramnames[7].split("[")
+                zaccept_unit = zaccept_unit_split[1].replace("]","")
+                if zaccept_unit.strip() == r'\AA^-1' or zaccept_unit.strip() == r'\A^-1':
+                    zaccept_unit = "1/A"
+                output.sample.zacceptance=(float(paramvals[7]),zaccept_unit)
+                output.vars = varheader
+            if not data.size:
+                raise RuntimeError("{} is empty".format(path))
+            x = data[:, headers.index("SpinEchoLength")]
+            if "SpinEchoLength_error" in headers:
+                dx = data[:, headers.index("SpinEchoLength_error")]
+            else:
+                dx = x * 0.05
+            lam = data[:, headers.index("Wavelength")]
+            if "Wavelength_error" in headers:
+                dlam = data[:, headers.index("Wavelength_error")]
+            else:
+                dlam = lam * 0.05
+            y = data[:, headers.index("Depolarisation")]
+            dy = data[:, headers.index("Depolarisation_error")]
+                if len(output.x) < 1:
+                    raise RuntimeError, "%s is empty" % path
+                return output
+            lam_unit = self._unit_fetch("Wavelength")
+            x, x_unit = self._unit_conversion(x, "A",
+                                              self._unit_fetch(
+                                                  "SpinEchoLength"))
+            dx, dx_unit = self._unit_conversion(
+                dx, lam_unit,
+                self._unit_fetch("SpinEchoLength"))
+            dlam, dlam_unit = self._unit_conversion(
+                dlam, lam_unit,
+                self._unit_fetch("Wavelength"))
+            y_unit = self._unit_fetch("Depolarisation")
+        else:
+            raise RuntimeError, "%s is not a file" % path
+        return None
+            output = Data1D(x=x, y=y, lam=lam, dy=dy, dx=dx, dlam=dlam,
+                            isSesans=True)
+    def _unit_conversion(self, value, value_unit, default_unit):
+        if has_converter == True and value_unit != default_unit:
+            data_conv_q = Converter(value_unit)
+            value = data_conv_q(value, units=default_unit)
+            output.y_unit = y_unit
+            output.x_unit = x_unit
+            output.source.wavelength_unit = lam_unit
+            output.source.wavelength = lam
+            self.filename = output.filename = basename
+            output.xaxis(r"\rm{z}", x_unit)
+            # Adjust label to ln P/(lam^2 t), remove lam column refs
+            output.yaxis(r"\rm{ln(P)/(t \lambda^2)}", y_unit)
+            # Store loading process information
+            output.meta_data['loader'] = self.type_name
+            output.sample.name = params["Sample"]
+            output.sample.ID = params["DataFileTitle"]
+            output.sample.thickness = self._unit_conversion(
+                float(params["Thickness"]), "cm",
+                self._unit_fetch("Thickness"))[0]
+            output.sample.zacceptance = (
+                float(params["Theta_zmax"]),
+                self._unit_fetch("Theta_zmax"))
+            output.sample.yacceptance = (
+                float(params["Theta_ymax"]),
+                self._unit_fetch("Theta_ymax"))
+            return output
+    @staticmethod
+    def _insist_header(headers, name):
+        if name not in headers:
+            raise RuntimeError(
+                "Missing {} column in spin echo data".format(name))
+    @staticmethod
+    def _unit_conversion(value, value_unit, default_unit):
+        """
+        Performs unit conversion on a measurement.
+        :param value: The magnitude of the measurement
+        :param value_unit: a string containing the final desired unit
+        :param default_unit: string with the units of the original measurement
+        :return: The magnitude of the measurement in the new units
+        """
+        # (float, string, string) -> float
+        if has_converter and value_unit != default_unit:
+            data_conv_q = Converter(default_unit)
+            value = data_conv_q(value, units=value_unit)
             new_unit = default_unit
         else:
             new_unit = value_unit
         return value, new_unit
+    def _unit_fetch(self, unit):
+        return self.params[unit+"_unit"]

src/sas/sasgui/guiframe/local_perspectives/plotting/Plotter2D.py

-                      r7432acb
+                      r3e5648b
                 if self.slicer.__class__.__name__ != "BoxSum":
                     wx_id = ids.next()
+                    slicerpop.Append(wx_id, '&Edit Slicer Parameters')
+                    name = '&Edit Slicer Parameters and Batch Slicing'
+                    slicerpop.Append(wx_id, name)
                     wx.EVT_MENU(self, wx_id, self._onEditSlicer)
             slicerpop.AppendSeparator()
 …
         """
         ## Clear current slicer
+        # Clear current slicer
         if self.slicer is not None:
             self.slicer.clear()
         ## Create a new slicer
+        # Create a new slicer
         self.slicer_z += 1
         self.slicer = slicer(self, self.subplot, zorder=self.slicer_z)
         self.subplot.set_ylim(self.data2D.ymin, self.data2D.ymax)
         self.subplot.set_xlim(self.data2D.xmin, self.data2D.xmax)
         ## Draw slicer
+        # Draw slicer
         self.update()
         self.slicer.update()
 …
         npt = math.floor(npt)
         from sas.sascalc.dataloader.manipulations import CircularAverage
         ## compute the maximum radius of data2D
+        # compute the maximum radius of data2D
         self.qmax = max(math.fabs(self.data2D.xmax),
                         math.fabs(self.data2D.xmin))
 …
                         math.fabs(self.data2D.ymin))
         self.radius = math.sqrt(math.pow(self.qmax, 2) + math.pow(self.ymax, 2))
         ##Compute beam width
+        # Compute beam width
         bin_width = (self.qmax + self.qmax) / npt
         ## Create data1D circular average of data2D
+        # Create data1D circular average of data2D
         Circle = CircularAverage(r_min=0, r_max=self.radius,
                                  bin_width=bin_width)
 …
         new_plot.name = "Circ avg " + self.data2D.name
         new_plot.source = self.data2D.source
         #new_plot.info = self.data2D.info
+        # new_plot.info = self.data2D.info
         new_plot.interactive = True
         new_plot.detector = self.data2D.detector
         ## If the data file does not tell us what the axes are, just assume...
+        # If the data file does not tell us what the axes are, just assume...
         new_plot.xaxis("\\rm{Q}", "A^{-1}")
         if hasattr(self.data2D, "scale") and \
 …
         new_plot.id = "Circ avg " + self.data2D.name
         new_plot.is_data = True
+        self.parent.update_theory(data_id=self.data2D.id, \
+                                       theory=new_plot)
+        self.parent.update_theory(data_id=self.data2D.id, theory=new_plot)
         wx.PostEvent(self.parent,
                      NewPlotEvent(plot=new_plot, title=new_plot.name))
 …
         """
         if self.slicer is not None:
             from SlicerParameters import SlicerParameterPanel
+            from parameters_panel_slicer import SlicerParameterPanel
             dialog = SlicerParameterPanel(self, -1, "Slicer Parameters")
             dialog.set_slicer(self.slicer.__class__.__name__,
 …
         params = self.slicer.get_params()
         ## Create a new panel to display results of summation of Data2D
         from slicerpanel import SlicerPanel
+        from parameters_panel_boxsum import SlicerPanel
         win = MDIFrame(self.parent, None, 'None', (100, 200))
         new_panel = SlicerPanel(parent=win, id=-1,
 …
         if default_name.count('.') > 0:
             default_name = default_name.split('.')[0]
-        #default_name += "_out"
         if self.parent is not None:
             self.parent.show_data2d(data, default_name)
     def modifyGraphAppearance(self, e):
+        self.graphApp = graphAppearance(self, 'Modify graph appearance', legend=False)
+        self.graphApp = graphAppearance(self, 'Modify graph appearance',
+                                        legend=False)
         self.graphApp.setDefaults(self.grid_on, self.legend_on,
                                   self.xaxis_label, self.yaxis_label,

src/sas/sasgui/guiframe/local_perspectives/plotting/SectorSlicer.py

-                      r7432acb
+                      r8de66b6
         ## Absolute value of the Angle between the middle line and any side line
         self.phi = math.pi / 12
+        # Binning base for log/lin binning
+        self.bin_base = 0
         ## Middle line
         self.main_line = LineInteractor(self, self.base.subplot, color='blue',
 …
         phimin = -self.left_line.phi + self.main_line.theta
         phimax = self.left_line.phi + self.main_line.theta
+        bin_base = self.bin_base
         if nbins is None:
             nbins = 20
         sect = SectorQ(r_min=0.0, r_max=radius,
                        phi_min=phimin + math.pi,
                        phi_max=phimax + math.pi, nbins=nbins)
+                       phi_max=phimax + math.pi, nbins=nbins, base=bin_base)
         sector = sect(self.base.data2D)
 …
         params["Delta_Phi [deg]"] = math.fabs(self.left_line.phi * 180 / math.pi)
         params["nbins"] = self.nbins
+        params["binning base"] = self.bin_base
         return params
 …
         phi = math.fabs(params["Delta_Phi [deg]"] * math.pi / 180)
         self.nbins = int(params["nbins"])
+        self.bin_base = params["binning base"]
         self.main_line.theta = main
         ## Reset the slicer parameters

src/sas/sasgui/guiframe/local_perspectives/plotting/parameters_panel_boxsum.py

-                      r7432acb
+                      r37d461c
 import wx
 import wx.lib.newevent
+#from copy import deepcopy
+from parameters_panel_slicer import SlicerParameterPanel
 from sas.sasgui.guiframe.utils import format_number
 from sas.sasgui.guiframe.events import SlicerParameterEvent
 from sas.sasgui.guiframe.events import EVT_SLICER_PARS
+from sas.sasgui.guiframe.events import EVT_SLICER
+from sas.sasgui.guiframe.panel_base import PanelBase
+from sas.sasgui.guiframe.events import (SlicerParameterEvent, EVT_SLICER_PARS,
+                                        EVT_SLICER)
-from sas.sasgui.guiframe.panel_base import PanelBase
 class SlicerPanel(wx.Panel, PanelBase):
 …
     Panel class to show the slicer parameters
     """
+    #TODO: show units
+    #TODO: order parameters properly
+    ## Internal name for the AUI manager
+    # Internal name for the AUI manager
     window_name = "Slicer panel"
     ## Title to appear on top of the window
+    # Title to appear on top of the window
     window_caption = "Slicer Panel"
     CENTER_PANE = False
 …
         wx.Panel.__init__(self, parent, id, *args, **kwargs)
         PanelBase.__init__(self)
         ##  Initialization of the class
+        # Initialization of the class
         self.base = base
         if params is None:
 …
         else:
             self.set_slicer(type, params)
+        ## Bindings
+        self.parent.Bind(EVT_SLICER, self.onEVT_SLICER)
+        self.parent.Bind(EVT_SLICER_PARS, self.onParamChange)
+    def onEVT_SLICER(self, event):
+        """
+        Process EVT_SLICER events
+        When the slicer changes, update the panel
+        :param event: EVT_SLICER event
+        """
+        event.Skip()
+        if event.obj_class is None:
+            self.set_slicer(None, None)
+        else:
+            self.set_slicer(event.type, event.params)
+        # Bindings
+        self.parent.Bind(EVT_SLICER, SlicerParameterPanel.on_evt_slicer)
+        self.parent.Bind(EVT_SLICER_PARS, SlicerParameterPanel.on_param_change)
     def set_slicer(self, type, params):
 …
             keys.sort()
             for item in keys:
+                if not item.lower() in ["num_points", "avg", "avg_error", "sum", "sum_error"]:
+                if not item.lower() in ["num_points", "avg", "avg_error", "sum",
+                                        "sum_error"]:
                     n += 1
                     text = wx.StaticText(self, -1, item, style=wx.ALIGN_LEFT)
                     self.bck.Add(text, (n - 1, 0),
+                                 flag=wx.LEFT | wx.ALIGN_CENTER_VERTICAL, border=15)
+                                 flag=wx.LEFT | wx.ALIGN_CENTER_VERTICAL,
+                                 border=15)
                     ctl = wx.TextCtrl(self, -1, size=(80, 20),
                                       style=wx.TE_PROCESS_ENTER)
 …
                     ctl.SetToolTipString(hint_msg)
                     ctl.SetValue(str(format_number(params[item])))
                     self.Bind(wx.EVT_TEXT_ENTER, self.onTextEnter)
                     ctl.Bind(wx.EVT_SET_FOCUS, self.onSetFocus)
                     ctl.Bind(wx.EVT_KILL_FOCUS, self.onTextEnter)
+                    self.Bind(wx.EVT_TEXT_ENTER, self.on_text_enter)
+                    ctl.Bind(wx.EVT_SET_FOCUS, self.on_set_focus)
+                    ctl.Bind(wx.EVT_KILL_FOCUS, self.on_text_enter)
                     self.parameters.append([item, ctl])
+                    self.bck.Add(ctl, (n - 1, 1), flag=wx.TOP | wx.BOTTOM, border=0)
+                    self.bck.Add(ctl, (n - 1, 1), flag=wx.TOP | wx.BOTTOM,
+                                 border=0)
             for item in keys:
+                if  item.lower() in ["num_points", "avg", "avg_error", "sum", "sum_error"]:
+                if item.lower() in ["num_points", "avg", "avg_error", "sum",
+                                    "sum_error"]:
                     n += 1
+                    text = wx.StaticText(self, -1, item + ": ", style=wx.ALIGN_LEFT)
+                    self.bck.Add(text, (n - 1, 0), flag=wx.LEFT | wx.ALIGN_CENTER_VERTICAL,
+                    text = wx.StaticText(self, -1, item + ": ",
+                                         style=wx.ALIGN_LEFT)
+                    self.bck.Add(text, (n - 1, 0),
+                                 flag=wx.LEFT | wx.ALIGN_CENTER_VERTICAL,
                                  border=15)
                     ctl = wx.StaticText(self, -1,
 …
                                         style=wx.ALIGN_LEFT)
                     ctl.SetToolTipString("Result %s" % item)
+                    self.bck.Add(ctl, (n - 1, 1), flag=wx.TOP | wx.BOTTOM, border=0)
+                    self.bck.Add(ctl, (n - 1, 1), flag=wx.TOP | wx.BOTTOM,
+                                 border=0)
         self.bck.Layout()
         self.Layout()
         psizer = self.parent.GetSizer()
         if psizer is not None:
             psizer.Layout()
+        p_sizer = self.parent.GetSizer()
+        if p_sizer is not None:
+            p_sizer.Layout()
     def onSetFocus(self, evt):
+    def on_set_focus(self, evt):
         """
         Highlight the txtcrtl
 …
         # Select the whole control, after this event resolves
         wx.CallAfter(widget.SetSelection, -1, -1)
-        return
+    def onParamChange(self, evt):
+        """
+        Receive and event and reset the text field contained in self.parameters
+        """
+        evt.Skip()
+        for item in self.parameters:
+            if item[0] in evt.params:
+                item[1].SetValue(format_number(evt.params[item[0]]))
+                item[1].Refresh()
+    def onTextEnter(self, evt):
+    def on_text_enter(self, evt):
         """
         Parameters have changed
 …
             try:
                 params[item[0]] = float(item[1].GetValue())
+                item[1].SetBackgroundColour(wx.SystemSettings_GetColour(wx.SYS_COLOUR_WINDOW))
+                item[1].SetBackgroundColour(wx.SystemSettings_GetColour(
+                    wx.SYS_COLOUR_WINDOW))
                 item[1].Refresh()
             except:
 …
                 item[1].SetBackgroundColour("pink")
                 item[1].Refresh()
+        if has_error == False:
+        if not has_error:
             # Post parameter event
             ## base is guiframe is this case
+            # base is guiframe is this case
             event = SlicerParameterEvent(type=self.type, params=params)
             wx.PostEvent(self.base, event)
 …
         On Close Event
         """
         ID = self.uid
         self.parent.delete_panel(ID)
+        uid = self.uid
+        self.parent.delete_panel(uid)
         self.frame.Destroy()

src/sas/sasgui/perspectives/fitting/basepage.py

ra1b8fee	r914c49d5
254	254	if not hasattr(self, "model_view"):
255	255	return
256		toggle_mode_on = self.model_view.IsEnabled()
	256	toggle_mode_on = self.model_view.IsEnabled() or self.data is None
257	257	if toggle_mode_on:
258	258	if self.enable2D and not check_data_validity(self.data):

src/sas/sasgui/perspectives/fitting/fitting.py

-                      rfc6651c
+                      re61a9b1
           '(Re)Load all models present in user plugin_models folder')
         wx.EVT_MENU(owner, wx_id, self.load_plugin_models)
     def set_edit_menu_helper(self, owner=None, menu=None):
         """
 …
             @param unsmeared_error: data error, rescaled to unsmeared model
         """
+        try:
+            np.nan_to_num(y)
+            new_plot = self.create_theory_1D(x, y, page_id, model, data, state,
+                                             data_description=model.name,
+                                             data_id=str(page_id) + " " + data.name)
+            if unsmeared_model is not None:
+                self.create_theory_1D(x, unsmeared_model, page_id, model, data, state,
+                                      data_description=model.name + " unsmeared",
+                                      data_id=str(page_id) + " " + data.name + " unsmeared")
+                if unsmeared_data is not None and unsmeared_error is not None:
+                    self.create_theory_1D(x, unsmeared_data, page_id, model, data, state,
+                                          data_description="Data unsmeared",
+                                          data_id="Data  " + data.name + " unsmeared",
+                                          dy=unsmeared_error)
+            if sq_model is not None and pq_model is not None:
+                self.create_theory_1D(x, sq_model, page_id, model, data, state,
+                                      data_description=model.name + " S(q)",
+                                      data_id=str(page_id) + " " + data.name + " S(q)")
+                self.create_theory_1D(x, pq_model, page_id, model, data, state,
+                                      data_description=model.name + " P(q)",
+                                      data_id=str(page_id) + " " + data.name + " P(q)")
+            current_pg = self.fit_panel.get_page_by_id(page_id)
+            title = new_plot.title
+            batch_on = self.fit_panel.get_page_by_id(page_id).batch_on
+            if not batch_on:
+                wx.PostEvent(self.parent, NewPlotEvent(plot=new_plot,
+                                            title=str(title)))
+            elif plot_result:
+                top_data_id = self.fit_panel.get_page_by_id(page_id).data.id
+                if data.id == top_data_id:
+                    wx.PostEvent(self.parent, NewPlotEvent(plot=new_plot,
+                                            title=str(title)))
+            caption = current_pg.window_caption
+            self.page_finder[page_id].set_fit_tab_caption(caption=caption)
+            self.page_finder[page_id].set_theory_data(data=new_plot,
+        number_finite = np.count_nonzero(np.isfinite(y))
+        np.nan_to_num(y)
+        new_plot = self.create_theory_1D(x, y, page_id, model, data, state,
+                                         data_description=model.name,
+                                         data_id=str(page_id) + " " + data.name)
+        if unsmeared_model is not None:
+            self.create_theory_1D(x, unsmeared_model, page_id, model, data, state,
+                                  data_description=model.name + " unsmeared",
+                                  data_id=str(page_id) + " " + data.name + " unsmeared")
+            if unsmeared_data is not None and unsmeared_error is not None:
+                self.create_theory_1D(x, unsmeared_data, page_id, model, data, state,
+                                      data_description="Data unsmeared",
+                                      data_id="Data  " + data.name + " unsmeared",
+                                      dy=unsmeared_error)
+        # Comment this out until we can get P*S models with correctly populated parameters
+        if sq_model is not None and pq_model is not None:
+            self.create_theory_1D(x, sq_model, page_id, model, data, state,
+                                  data_description=model.name + " S(q)",
+                                  data_id=str(page_id) + " " + data.name + " S(q)")
+            self.create_theory_1D(x, pq_model, page_id, model, data, state,
+                                  data_description=model.name + " P(q)",
+                                  data_id=str(page_id) + " " + data.name + " P(q)")
+        current_pg = self.fit_panel.get_page_by_id(page_id)
+        title = new_plot.title
+        batch_on = self.fit_panel.get_page_by_id(page_id).batch_on
+        if not batch_on:
+            wx.PostEvent(self.parent, NewPlotEvent(plot=new_plot, title=str(title)))
+        elif plot_result:
+            top_data_id = self.fit_panel.get_page_by_id(page_id).data.id
+            if data.id == top_data_id:
+                wx.PostEvent(self.parent, NewPlotEvent(plot=new_plot, title=str(title)))
+        caption = current_pg.window_caption
+        self.page_finder[page_id].set_fit_tab_caption(caption=caption)
+        self.page_finder[page_id].set_theory_data(data=new_plot,
                                                       fid=data.id)
             if toggle_mode_on:
                 wx.PostEvent(self.parent,
                              NewPlotEvent(group_id=str(page_id) + " Model2D",
+        if toggle_mode_on:
+            wx.PostEvent(self.parent,
+                         NewPlotEvent(group_id=str(page_id) + " Model2D",
                                           action="Hide"))
             else:
                 if update_chisqr:
                     wx.PostEvent(current_pg,
                                  Chi2UpdateEvent(output=self._cal_chisqr(
+        else:
+            if update_chisqr:
+                wx.PostEvent(current_pg,
+                             Chi2UpdateEvent(output=self._cal_chisqr(
                                                                 data=data,
                                                                 fid=fid,
                                                                 weight=weight,
+                                                            page_id=page_id,
+                                                            index=index)))
+                else:
+                    self._plot_residuals(page_id=page_id, data=data, fid=fid,
+                                         index=index, weight=weight)
+                                                                page_id=page_id,
+                                                                index=index)))
+            else:
+                self._plot_residuals(page_id=page_id, data=data, fid=fid,
+                                     index=index, weight=weight)
+        if not number_finite:
+            logger.error("Using the present parameters the model does not return any finite value. ")
+            msg = "Computing Error: Model did not return any finite value."
+            wx.PostEvent(self.parent, StatusEvent(status = msg, info="error"))
+        else:
             msg = "Computation  completed!"
+            if number_finite != y.size:
+                msg += ' PROBLEM: For some Q values the model returns non finite intensities!'
+                logger.error("For some Q values the model returns non finite intensities.")
             wx.PostEvent(self.parent, StatusEvent(status=msg, type="stop"))
-        except:
-            raise
     def _calc_exception(self, etype, value, tb):
 …
         that can be plot.
         """
+        number_finite = np.count_nonzero(np.isfinite(image))
         np.nan_to_num(image)
         new_plot = Data2D(image=image, err_image=data.err_data)
 …
                 self._plot_residuals(page_id=page_id, data=data, fid=fid,
                                       index=index, weight=weight)
+        msg = "Computation  completed!"
+        wx.PostEvent(self.parent, StatusEvent(status=msg, type="stop"))
+        if not number_finite:
+            logger.error("Using the present parameters the model does not return any finite value. ")
+            msg = "Computing Error: Model did not return any finite value."
+            wx.PostEvent(self.parent, StatusEvent(status = msg, info="error"))
+        else:
+            msg = "Computation  completed!"
+            if number_finite != image.size:
+                msg += ' PROBLEM: For some Qx,Qy values the model returns non finite intensities!'
+                logger.error("For some Qx,Qy values the model returns non finite intensities.")
+            wx.PostEvent(self.parent, StatusEvent(status=msg, type="stop"))
     def _draw_model2D(self, model, page_id, qmin,

src/sas/sasgui/perspectives/fitting/models.py

-                      ra1b8fee
+                      r8cec26b
     try:
         import compileall
         compileall.compile_dir(dir=dir, ddir=dir, force=1,
+        compileall.compile_dir(dir=dir, ddir=dir, force=0,
                                quiet=report_problem)
     except:
 …
 def _findModels(dir):
+def _find_models():
     """
     Find custom models
     """
     # List of plugin objects
     dir = find_plugins_dir()
+    directory = find_plugins_dir()
     # Go through files in plug-in directory
     if not os.path.isdir(dir):
         msg = "SasView couldn't locate Model plugin folder %r." % dir
+    if not os.path.isdir(directory):
+        msg = "SasView couldn't locate Model plugin folder %r." % directory
         logger.warning(msg)
         return {}
     plugin_log("looking for models in: %s" % str(dir))
     #compile_file(dir)  #always recompile the folder plugin
     logger.info("plugin model dir: %s" % str(dir))
+    plugin_log("looking for models in: %s" % str(directory))
+    # compile_file(directory)  #always recompile the folder plugin
+    logger.info("plugin model dir: %s" % str(directory))
     plugins = {}
     for filename in os.listdir(dir):
+    for filename in os.listdir(directory):
         name, ext = os.path.splitext(filename)
         if ext == '.py' and not name == '__init__':
             path = os.path.abspath(os.path.join(dir, filename))
+            path = os.path.abspath(os.path.join(directory, filename))
             try:
                 model = load_custom_model(path)
 …
                 plugin_log(msg)
                 logger.warning("Failed to load plugin %r. See %s for details"
                                 % (path, PLUGIN_LOG))
+                               % (path, PLUGIN_LOG))
     return plugins
 …
         temp = {}
         if self.is_changed():
             return  _findModels(dir)
+            return  _find_models()
         logger.info("plugin model : %s" % str(temp))
         return temp
 …
         """
         self.plugins = []
         new_plugins = _findModels(dir)
+        new_plugins = _find_models()
         for name, plug in  new_plugins.iteritems():
             for stored_name, stored_plug in self.stored_plugins.iteritems():

src/sas/sasgui/perspectives/fitting/model_thread.py

-                      r7432acb
+                      r426df2e
                     (self.data.qy_data * self.data.qy_data))
         # For theory, qmax is based on 1d qmax
+        # For theory, qmax is based on 1d qmax
         # so that must be mulitified by sqrt(2) to get actual max for 2d
         index_model = (self.qmin <= radius) & (radius <= self.qmax)
 …
                 self.data.qy_data[index_model]
             ])
+        output = np.zeros(len(self.data.qx_data))
+        # Initialize output to NaN so masked elements do not get plotted.
+        output = np.empty_like(self.data.qx_data)
         # output default is None
         # This method is to distinguish between masked
         #point(nan) and data point = 0.
         output = output / output
+        output[:] = np.NaN
         # set value for self.mask==True, else still None to Plottools
         output[index_model] = value
 …
             output[index] = self.model.evalDistribution(self.data.x[index])
+        x=self.data.x[index]
+        y=output[index]
         sq_values = None
         pq_values = None
-        s_model = None
-        p_model = None
         if isinstance(self.model, MultiplicationModel):
             s_model = self.model.s_model
             p_model = self.model.p_model
         elif hasattr(self.model, "get_composition_models"):
             p_model, s_model = self.model.get_composition_models()
         if p_model is not None and s_model is not None:
             sq_values = np.zeros((len(self.data.x)))
             pq_values = np.zeros((len(self.data.x)))
             sq_values[index] = s_model.evalDistribution(self.data.x[index])
+            pq_values[index] = p_model.evalDistribution(self.data.x[index])
+            sq_values = s_model.evalDistribution(x)
+            pq_values = p_model.evalDistribution(x)
+        elif hasattr(self.model, "calc_composition_models"):
+            results = self.model.calc_composition_models(x)
+            if results is not None:
+                sq_values = results[0]
+                pq_values = results[1]
         elapsed = time.time() - self.starttime
         self.complete(x=self.data.x[index], y=output[index],
+        self.complete(x=x, y=y,
                       page_id=self.page_id,
                       state=self.state,

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Changeset e61a9b1 in sasview for src/sas

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