Exemplo n.º 1
0
 def setUp(self):
     super(TestScalarFieldView, self).setUp()
     self.scalarFieldView = ScalarFieldView()
     self.scalarFieldView.resize(300, 300)
     self.scalarFieldView.show()
     self.statsWidget = BasicStatsWidget()
     self.statsWidget.setPlot(self.scalarFieldView)
    def __init__(self, parent=None):
        """

        :param parent: Parent QWidget
        """
        super(ArrayVolumePlot, self).__init__(parent)

        self.__signal = None
        self.__signal_name = None
        # the Z, Y, X axes apply to the last three dimensions of the signal
        # (in that order)
        self.__z_axis = None
        self.__z_axis_name = None
        self.__y_axis = None
        self.__y_axis_name = None
        self.__x_axis = None
        self.__x_axis_name = None

        from silx.gui.plot3d.ScalarFieldView import ScalarFieldView
        from silx.gui.plot3d import SFViewParamTree

        self._view = ScalarFieldView(self)

        def computeIsolevel(data):
            data = data[numpy.isfinite(data)]
            if len(data) == 0:
                return 0
            else:
                return numpy.mean(data) + numpy.std(data)

        self._view.addIsosurface(computeIsolevel, '#FF0000FF')

        # Create a parameter tree for the scalar field view
        options = SFViewParamTree.TreeView(self._view)
        options.setSfView(self._view)

        # Add the parameter tree to the main window in a dock widget
        dock = qt.QDockWidget()
        dock.setWidget(options)
        self._view.addDockWidget(qt.Qt.RightDockWidgetArea, dock)

        self._hline = qt.QFrame(self)
        self._hline.setFrameStyle(qt.QFrame.HLine)
        self._hline.setFrameShadow(qt.QFrame.Sunken)
        self._legend = qt.QLabel(self)
        self._selector = NumpyAxesSelector(self)
        self._selector.setNamedAxesSelectorVisibility(False)
        self.__selector_is_connected = False

        layout = qt.QVBoxLayout()
        layout.addWidget(self._view)
        layout.addWidget(self._hline)
        layout.addWidget(self._legend)
        layout.addWidget(self._selector)

        self.setLayout(layout)
    def setUp(self):
        super(TestScalarFieldView, self).setUp()
        self.widget = ScalarFieldView()
        self.widget.show()

        paramTreeWidget = TreeView()
        paramTreeWidget.setSfView(self.widget)

        dock = qt.QDockWidget()
        dock.setWidget(paramTreeWidget)
        self.widget.addDockWidget(qt.Qt.BottomDockWidgetArea, dock)
Exemplo n.º 4
0
    def setUp(self):
        super(TestScalarFieldView, self).setUp()
        self.widget = ScalarFieldView()
        self.widget.show()

        # Create a parameter tree for the scalar field view
        self.treeView = TreeView()
        self.treeView.setSfView(
            self.widget)  # Attach the parameter tree to the view
        self.treeView.show()

        # Add the parameter tree to the main window in a dock widget
        dock = qt.QDockWidget()
        dock.setWindowTitle('Parameters')
        dock.setWidget(self.treeView)
        self.widget.addDockWidget(qt.Qt.RightDockWidgetArea, dock)
Exemplo n.º 5
0
 def setUp(self):
     super(TestScalarFieldView, self).setUp()
     self.scalarFieldView = ScalarFieldView()
     self.scalarFieldView.resize(300, 300)
     self.scalarFieldView.show()
     self.statsWidget = BasicStatsWidget()
     self.statsWidget.setPlot(self.scalarFieldView)
Exemplo n.º 6
0
    def setUp(self):
        super(TestScalarFieldView, self).setUp()
        self.widget = ScalarFieldView()
        self.widget.show()

        paramTreeWidget = TreeView()
        paramTreeWidget.setSfView(self.widget)

        dock = qt.QDockWidget()
        dock.setWidget(paramTreeWidget)
        self.widget.addDockWidget(qt.Qt.BottomDockWidgetArea, dock)
Exemplo n.º 7
0
class TestScalarFieldView(TestCaseQt, ParametricTestCase):
    """Tests of ScalarFieldView widget."""

    def setUp(self):
        super(TestScalarFieldView, self).setUp()
        self.widget = ScalarFieldView()
        self.widget.show()

        paramTreeWidget = TreeView()
        paramTreeWidget.setSfView(self.widget)

        dock = qt.QDockWidget()
        dock.setWidget(paramTreeWidget)
        self.widget.addDockWidget(qt.Qt.BottomDockWidgetArea, dock)

        # Commented as it slows down the tests
        # self.qWaitForWindowExposed(self.widget)

    def tearDown(self):
        self.qapp.processEvents()
        self.widget.setAttribute(qt.Qt.WA_DeleteOnClose)
        self.widget.close()
        del self.widget
        super(TestScalarFieldView, self).tearDown()

    @staticmethod
    def _buildData(size):
        """Make a 3D dataset"""
        coords = numpy.linspace(-10, 10, size)
        z = coords.reshape(-1, 1, 1)
        y = coords.reshape(1, -1, 1)
        x = coords.reshape(1, 1, -1)
        return numpy.sin(x * y * z) / (x * y * z)

    def testSimple(self):
        """Set the data and an isosurface"""
        data = self._buildData(size=32)

        self.widget.setData(data)
        self.widget.addIsosurface(0.5, (1., 0., 0., 0.5))
        self.widget.addIsosurface(0.7, qt.QColor('green'))
        self.qapp.processEvents()

    def testNotFinite(self):
        """Test with NaN and inf in data set"""

        # Some NaNs and inf
        data = self._buildData(size=32)
        data[8, :, :] = numpy.nan
        data[16, :, :] = numpy.inf
        data[24, :, :] = - numpy.inf

        self.widget.addIsosurface(0.5, 'red')
        self.widget.setData(data, copy=True)
        self.qapp.processEvents()
        self.widget.setData(None)

        # All NaNs or inf
        data = numpy.empty((4, 4, 4), dtype=numpy.float32)
        for value in (numpy.nan, numpy.inf):
            with self.subTest(value=str(value)):
                data[:] = value
                self.widget.setData(data, copy=True)
                self.qapp.processEvents()

    def testIsoSliderNormalization(self):
        """Test set TreeView with a different isoslider normalization"""
        data = self._buildData(size=32)

        self.widget.setData(data)
        self.widget.addIsosurface(0.5, (1., 0., 0., 0.5))
        self.widget.addIsosurface(0.7, qt.QColor('green'))
        self.qapp.processEvents()

        # Add a second TreeView
        paramTreeWidget = TreeView(self.widget)
        paramTreeWidget.setIsoLevelSliderNormalization('arcsinh')
        paramTreeWidget.setSfView(self.widget)

        dock = qt.QDockWidget()
        dock.setWidget(paramTreeWidget)
        self.widget.addDockWidget(qt.Qt.BottomDockWidgetArea, dock)
Exemplo n.º 8
0
class TestScalarFieldView(TestCaseQt):
    """Tests StatsWidget combined with ScalarFieldView"""
    def setUp(self):
        super(TestScalarFieldView, self).setUp()
        self.scalarFieldView = ScalarFieldView()
        self.scalarFieldView.resize(300, 300)
        self.scalarFieldView.show()
        self.statsWidget = BasicStatsWidget()
        self.statsWidget.setPlot(self.scalarFieldView)
        # self.qWaitForWindowExposed(self.sceneWidget)

    def tearDown(self):
        Stats._getContext.cache_clear()
        self.qapp.processEvents()
        self.scalarFieldView.setAttribute(qt.Qt.WA_DeleteOnClose)
        self.scalarFieldView.close()
        del self.scalarFieldView
        self.statsWidget.setAttribute(qt.Qt.WA_DeleteOnClose)
        self.statsWidget.close()
        del self.statsWidget
        super(TestScalarFieldView, self).tearDown()

    def _getTextFor(self, row, name):
        """Returns text in table at given row for column name

        :param int row: Row number in the table
        :param str name: Column id
        :rtype: Union[str,None]
        """
        statsTable = self.statsWidget._getStatsTable()

        for column in range(statsTable.columnCount()):
            headerItem = statsTable.horizontalHeaderItem(column)
            if headerItem.data(qt.Qt.UserRole) == name:
                tableItem = statsTable.item(row, column)
                return tableItem.text()

        return None

    def test(self):
        """Test StatsWidget with ScalarFieldView"""
        data = numpy.arange(64**3, dtype=numpy.float64).reshape(64, 64, 64)
        self.scalarFieldView.setData(data)

        statsTable = self.statsWidget._getStatsTable()

        # Test selection only
        self.statsWidget.setDisplayOnlyActiveItem(True)
        self.assertEqual(statsTable.rowCount(), 1)

        # Test all data
        self.statsWidget.setDisplayOnlyActiveItem(False)
        self.assertEqual(statsTable.rowCount(), 1)

        for column in range(statsTable.columnCount()):
            self.assertEqual(float(self._getTextFor(0, 'min')),
                             numpy.min(data))
            self.assertEqual(float(self._getTextFor(0, 'max')),
                             numpy.max(data))
            sum_ = numpy.sum(data)
            comz = numpy.sum(
                numpy.arange(data.shape[0]) *
                numpy.sum(data, axis=(1, 2))) / sum_
            comy = numpy.sum(
                numpy.arange(data.shape[1]) *
                numpy.sum(data, axis=(0, 2))) / sum_
            comx = numpy.sum(
                numpy.arange(data.shape[2]) *
                numpy.sum(data, axis=(0, 1))) / sum_
            self.assertEqual(self._getTextFor(0, 'COM'), str(
                (comx, comy, comz)))
class ArrayVolumePlot(qt.QWidget):
    """
    Widget for plotting a n-D array (n >= 3) as a 3D scalar field.
    Three axis arrays can be provided to calibrate the axes.

    The signal array can have an arbitrary number of dimensions, the only
    limitation being that the last 3 dimensions must have the same length as
    the axes arrays.

    Sliders are provided to select indices on the first (n - 3) dimensions of
    the signal array, and the plot is updated to load the stack corresponding
    to the selection.
    """
    def __init__(self, parent=None):
        """

        :param parent: Parent QWidget
        """
        super(ArrayVolumePlot, self).__init__(parent)

        self.__signal = None
        self.__signal_name = None
        # the Z, Y, X axes apply to the last three dimensions of the signal
        # (in that order)
        self.__z_axis = None
        self.__z_axis_name = None
        self.__y_axis = None
        self.__y_axis_name = None
        self.__x_axis = None
        self.__x_axis_name = None

        from silx.gui.plot3d.ScalarFieldView import ScalarFieldView
        from silx.gui.plot3d import SFViewParamTree

        self._view = ScalarFieldView(self)

        def computeIsolevel(data):
            data = data[numpy.isfinite(data)]
            if len(data) == 0:
                return 0
            else:
                return numpy.mean(data) + numpy.std(data)

        self._view.addIsosurface(computeIsolevel, '#FF0000FF')

        # Create a parameter tree for the scalar field view
        options = SFViewParamTree.TreeView(self._view)
        options.setSfView(self._view)

        # Add the parameter tree to the main window in a dock widget
        dock = qt.QDockWidget()
        dock.setWidget(options)
        self._view.addDockWidget(qt.Qt.RightDockWidgetArea, dock)

        self._hline = qt.QFrame(self)
        self._hline.setFrameStyle(qt.QFrame.HLine)
        self._hline.setFrameShadow(qt.QFrame.Sunken)
        self._legend = qt.QLabel(self)
        self._selector = NumpyAxesSelector(self)
        self._selector.setNamedAxesSelectorVisibility(False)
        self.__selector_is_connected = False

        layout = qt.QVBoxLayout()
        layout.addWidget(self._view)
        layout.addWidget(self._hline)
        layout.addWidget(self._legend)
        layout.addWidget(self._selector)

        self.setLayout(layout)

    def getVolumeView(self):
        """Returns the plot used for the display

        :rtype: ScalarFieldView
        """
        return self._view

    def normalizeComplexData(self, data):
        """
        Converts a complex data array to its amplitude, if necessary.
        :param data: the data to normalize
        :return:
        """
        if hasattr(data, "dtype"):
            isComplex = numpy.issubdtype(data.dtype, numpy.complexfloating)
        else:
            isComplex = isinstance(data, numbers.Complex)
        if isComplex:
            data = numpy.absolute(data)
        return data

    def setData(self,
                signal,
                x_axis=None,
                y_axis=None,
                z_axis=None,
                signal_name=None,
                xlabel=None,
                ylabel=None,
                zlabel=None,
                title=None):
        """

        :param signal: n-D dataset, whose last 3 dimensions are used as the
            3D stack values.
        :param x_axis: 1-D dataset used as the image's x coordinates. If
            provided, its lengths must be equal to the length of the last
            dimension of ``signal``.
        :param y_axis: 1-D dataset used as the image's y. If provided,
            its lengths must be equal to the length of the 2nd to last
            dimension of ``signal``.
        :param z_axis: 1-D dataset used as the image's z. If provided,
            its lengths must be equal to the length of the 3rd to last
            dimension of ``signal``.
        :param signal_name: Label used in the legend
        :param xlabel: Label for X axis
        :param ylabel: Label for Y axis
        :param zlabel: Label for Z axis
        :param title: Graph title
        """
        signal = self.normalizeComplexData(signal)
        if self.__selector_is_connected:
            self._selector.selectionChanged.disconnect(self._updateVolume)
            self.__selector_is_connected = False

        self.__signal = signal
        self.__signal_name = signal_name or ""
        self.__x_axis = x_axis
        self.__x_axis_name = xlabel
        self.__y_axis = y_axis
        self.__y_axis_name = ylabel
        self.__z_axis = z_axis
        self.__z_axis_name = zlabel

        self._selector.setData(signal)
        self._selector.setAxisNames(["Y", "X", "Z"])

        self._view.setAxesLabels(self.__x_axis_name or 'X', self.__y_axis_name
                                 or 'Y', self.__z_axis_name or 'Z')
        self._updateVolume()

        # the legend label shows the selection slice producing the volume
        # (only interesting for ndim > 3)
        if signal.ndim > 3:
            self._selector.setVisible(True)
            self._legend.setVisible(True)
            self._hline.setVisible(True)
        else:
            self._selector.setVisible(False)
            self._legend.setVisible(False)
            self._hline.setVisible(False)

        if not self.__selector_is_connected:
            self._selector.selectionChanged.connect(self._updateVolume)
            self.__selector_is_connected = True

    def _updateVolume(self):
        """Update displayed stack according to the current axes selector
        data."""
        data = self._selector.selectedData()
        x_axis = self.__x_axis
        y_axis = self.__y_axis
        z_axis = self.__z_axis

        offset = []
        scale = []
        for axis in [x_axis, y_axis, z_axis]:
            if axis is None:
                calibration = NoCalibration()
            elif len(axis) == 2:
                calibration = LinearCalibration(y_intercept=axis[0],
                                                slope=axis[1])
            else:
                calibration = ArrayCalibration(axis)
            if not calibration.is_affine():
                _logger.warning("Axis has not linear values, ignored")
                offset.append(0.)
                scale.append(1.)
            else:
                offset.append(calibration(0))
                scale.append(calibration.get_slope())

        legend = self.__signal_name + "["
        for sl in self._selector.selection():
            if sl == slice(None):
                legend += ":, "
            else:
                legend += str(sl) + ", "
        legend = legend[:-2] + "]"
        self._legend.setText("Displayed data: " + legend)

        self._view.setData(data, copy=False)
        self._view.setScale(*scale)
        self._view.setTranslation(*offset)
        self._view.setAxesLabels(self.__x_axis_name, self.__y_axis_name,
                                 self.__z_axis_name)

    def clear(self):
        old = self._selector.blockSignals(True)
        self._selector.clear()
        self._selector.blockSignals(old)
        self._view.setData(None)
Exemplo n.º 10
0
    Pjlk[:, :, k] = np.roll(Pjlk[:, :, k], prerolls[k], axis=1)

# load the truths
dct = np.load('data.npz')
phi = dct['rolls']
theta = dct['offsets']

# make some plots
fig, ax = plt.subplots(nrows=2, ncols=2)
ax[0, 0].plot(theta)
ax[0, 1].plot(phi)
ax[1, 0].imshow(np.flip(Pjlk.sum(axis=1), axis=0), aspect='auto', vmax=.5)
ax[1, 1].imshow(Pjlk.sum(axis=0), aspect='auto', vmax=.5)

# show the intensity
app = qt.QApplication([])
window = ScalarFieldView()
window.setData(W[6:-6])
window.setScale(1, 1, 1)  # voxel sizes
window.addIsosurface(W.max() / 500, '#FF0000AA')

cut = CutPlane(window)
cut.setVisible(True)
cut.setPoint((20, 20, 20), constraint=False)
cut.setNormal((1, 0, 0))
cut.moveToCenter()
print(cut.isValid())

window.show()
app.exec_()
Exemplo n.º 11
0
    It also support nD data set (n>=3) stored in a HDF5 file.
    For HDF5, provide the filename and path as: <filename>::<path_in_file>.
    If the data set has more than 3 dimensions, it is possible to choose a
    3D data set as a subset by providing the indices along the first n-3
    dimensions with '#':
    <filename>::<path_in_file>#<1st_dim_index>...#<n-3th_dim_index>

    E.g.: data.h5::/data_5D#1#1
    """)
args = parser.parse_args(args=sys.argv[1:])

# Start GUI
app = qt.QApplication([])

# Create the viewer main window
window = ScalarFieldView()

# Create a parameter tree for the scalar field view
treeView = SFViewParamTree.TreeView(window)
treeView.setSfView(window)  # Attach the parameter tree to the view

# Add the parameter tree to the main window in a dock widget
dock = qt.QDockWidget()
dock.setWindowTitle('Parameters')
dock.setWidget(treeView)
window.addDockWidget(qt.Qt.RightDockWidgetArea, dock)

# Load data from file
if args.filename is not None:
    data = load(args.filename)
    _logger.info('Data:\n\tShape: %s\n\tRange: [%f, %f]', str(data.shape),
Exemplo n.º 12
0
def main(argv=None):
    # Parse input arguments
    parser = argparse.ArgumentParser(description=__doc__)
    parser.add_argument('-l',
                        '--level',
                        nargs='?',
                        type=float,
                        default=float('nan'),
                        help="The value at which to generate the iso-surface")
    parser.add_argument('-sx',
                        '--xscale',
                        nargs='?',
                        type=float,
                        default=1.,
                        help="The scale of the data on the X axis")
    parser.add_argument('-sy',
                        '--yscale',
                        nargs='?',
                        type=float,
                        default=1.,
                        help="The scale of the data on the Y axis")
    parser.add_argument('-sz',
                        '--zscale',
                        nargs='?',
                        type=float,
                        default=1.,
                        help="The scale of the data on the Z axis")
    parser.add_argument('-ox',
                        '--xoffset',
                        nargs='?',
                        type=float,
                        default=0.,
                        help="The offset of the data on the X axis")
    parser.add_argument('-oy',
                        '--yoffset',
                        nargs='?',
                        type=float,
                        default=0.,
                        help="The offset of the data on the Y axis")
    parser.add_argument('-oz',
                        '--zoffset',
                        nargs='?',
                        type=float,
                        default=0.,
                        help="The offset of the data on the Z axis")
    parser.add_argument('filename',
                        nargs='?',
                        default=None,
                        help="""Filename to open.

        It supports 3D volume saved as .npy or in .h5 files.

        It also support nD data set (n>=3) stored in a HDF5 file.
        For HDF5, provide the filename and path as: <filename>::<path_in_file>.
        If the data set has more than 3 dimensions, it is possible to choose a
        3D data set as a subset by providing the indices along the first n-3
        dimensions with '#':
        <filename>::<path_in_file>#<1st_dim_index>...#<n-3th_dim_index>

        E.g.: data.h5::/data_5D#1#1
        """)
    args = parser.parse_args(args=argv)

    # Start GUI
    global app  # QApplication must be global to avoid seg fault on quit
    app = qt.QApplication([])

    # Create the viewer main window
    window = ScalarFieldView()
    window.setAttribute(qt.Qt.WA_DeleteOnClose)

    # Create a parameter tree for the scalar field view
    treeView = SFViewParamTree.TreeView(window)
    treeView.setSfView(window)  # Attach the parameter tree to the view

    # Add the parameter tree to the main window in a dock widget
    dock = qt.QDockWidget()
    dock.setWindowTitle('Parameters')
    dock.setWidget(treeView)
    window.addDockWidget(qt.Qt.RightDockWidgetArea, dock)

    # Load data from file
    if args.filename is not None:
        data = load(args.filename)
        _logger.info('Data:\n\tShape: %s\n\tRange: [%f, %f]', str(data.shape),
                     data.min(), data.max())
    else:
        # Create dummy data
        _logger.warning('Not data file provided, creating dummy data')
        coords = numpy.linspace(-10, 10, 64)
        z = coords.reshape(-1, 1, 1)
        y = coords.reshape(1, -1, 1)
        x = coords.reshape(1, 1, -1)
        data = numpy.sin(x * y * z) / (x * y * z)

    # Set ScalarFieldView data
    window.setData(data)

    # Set scale of the data
    window.setScale(args.xscale, args.yscale, args.zscale)

    # Set offset of the data
    window.setTranslation(args.xoffset, args.yoffset, args.zoffset)

    # Set axes labels
    window.setAxesLabels('X', 'Y', 'Z')

    # Add an iso-surface
    if not numpy.isnan(args.level):
        # Add an iso-surface at the given iso-level
        window.addIsosurface(args.level, '#FF0000FF')
    else:
        # Add an iso-surface from a function
        window.addIsosurface(default_isolevel, '#FF0000FF')

    window.show()
    return app.exec_()
Exemplo n.º 13
0
class TestScalarFieldView(TestCaseQt):
    """Tests StatsWidget combined with ScalarFieldView"""

    def setUp(self):
        super(TestScalarFieldView, self).setUp()
        self.scalarFieldView = ScalarFieldView()
        self.scalarFieldView.resize(300, 300)
        self.scalarFieldView.show()
        self.statsWidget = BasicStatsWidget()
        self.statsWidget.setPlot(self.scalarFieldView)
        # self.qWaitForWindowExposed(self.sceneWidget)

    def tearDown(self):
        self.qapp.processEvents()
        self.scalarFieldView.setAttribute(qt.Qt.WA_DeleteOnClose)
        self.scalarFieldView.close()
        del self.scalarFieldView
        self.statsWidget.setAttribute(qt.Qt.WA_DeleteOnClose)
        self.statsWidget.close()
        del self.statsWidget
        super(TestScalarFieldView, self).tearDown()

    def _getTextFor(self, row, name):
        """Returns text in table at given row for column name

        :param int row: Row number in the table
        :param str name: Column id
        :rtype: Union[str,None]
        """
        statsTable = self.statsWidget._getStatsTable()

        for column in range(statsTable.columnCount()):
            headerItem = statsTable.horizontalHeaderItem(column)
            if headerItem.data(qt.Qt.UserRole) == name:
                tableItem = statsTable.item(row, column)
                return tableItem.text()

        return None

    def test(self):
        """Test StatsWidget with ScalarFieldView"""
        data = numpy.arange(64**3, dtype=numpy.float64).reshape(64, 64, 64)
        self.scalarFieldView.setData(data)

        statsTable = self.statsWidget._getStatsTable()

        # Test selection only
        self.statsWidget.setDisplayOnlyActiveItem(True)
        self.assertEqual(statsTable.rowCount(), 1)

        # Test all data
        self.statsWidget.setDisplayOnlyActiveItem(False)
        self.assertEqual(statsTable.rowCount(), 1)

        for column in range(statsTable.columnCount()):
            self.assertEqual(float(self._getTextFor(0, 'min')), numpy.min(data))
            self.assertEqual(float(self._getTextFor(0, 'max')), numpy.max(data))
            sum_ = numpy.sum(data)
            comz = numpy.sum(numpy.arange(data.shape[0]) * numpy.sum(data, axis=(1, 2))) / sum_
            comy = numpy.sum(numpy.arange(data.shape[1]) * numpy.sum(data, axis=(0, 2))) / sum_
            comx = numpy.sum(numpy.arange(data.shape[2]) * numpy.sum(data, axis=(0, 1))) / sum_
            self.assertEqual(self._getTextFor(0, 'COM'), str((comx, comy, comz)))
Exemplo n.º 14
0
    It also support nD data set (n>=3) stored in a HDF5 file.
    For HDF5, provide the filename and path as: <filename>::<path_in_file>.
    If the data set has more than 3 dimensions, it is possible to choose a
    3D data set as a subset by providing the indices along the first n-3
    dimensions with '#':
    <filename>::<path_in_file>#<1st_dim_index>...#<n-3th_dim_index>

    E.g.: data.h5::/data_5D#1#1
    """)
args = parser.parse_args(args=sys.argv[1:])

# Start GUI
app = qt.QApplication([])

# Create the viewer main window
window = ScalarFieldView()

# Create a parameter tree for the scalar field view
treeView = SFViewParamTree.TreeView(window)
treeView.setSfView(window)  # Attach the parameter tree to the view

# Add the parameter tree to the main window in a dock widget
dock = qt.QDockWidget()
dock.setWindowTitle('Parameters')
dock.setWidget(treeView)
window.addDockWidget(qt.Qt.RightDockWidgetArea, dock)

# Load data from file
if args.filename is not None:
    data = load(args.filename)
    _logger.info('Data:\n\tShape: %s\n\tRange: [%f, %f]',
Exemplo n.º 15
0
class TestScalarFieldView(TestCaseQt, ParametricTestCase):
    """Tests of ScalarFieldView widget."""
    def setUp(self):
        super(TestScalarFieldView, self).setUp()
        self.widget = ScalarFieldView()
        self.widget.show()

        # Commented as it slows down the tests
        # self.qWaitForWindowExposed(self.widget)

    def tearDown(self):
        self.qapp.processEvents()
        self.widget.setAttribute(qt.Qt.WA_DeleteOnClose)
        self.widget.close()
        del self.widget
        super(TestScalarFieldView, self).tearDown()

    @staticmethod
    def _buildData(size):
        """Make a 3D dataset"""
        coords = numpy.linspace(-10, 10, size)
        z = coords.reshape(-1, 1, 1)
        y = coords.reshape(1, -1, 1)
        x = coords.reshape(1, 1, -1)
        return numpy.sin(x * y * z) / (x * y * z)

    def testSimple(self):
        """Set the data and an isosurface"""
        data = self._buildData(size=32)

        self.widget.setData(data)
        self.widget.addIsosurface(0.5, (1., 0., 0., 0.5))
        self.widget.addIsosurface(0.7, qt.QColor('green'))
        self.qapp.processEvents()

    def testNotFinite(self):
        """Test with NaN and inf in data set"""

        # Some NaNs and inf
        data = self._buildData(size=32)
        data[8, :, :] = numpy.nan
        data[16, :, :] = numpy.inf
        data[24, :, :] = -numpy.inf

        self.widget.addIsosurface(0.5, 'red')
        self.widget.setData(data, copy=True)
        self.qapp.processEvents()
        self.widget.setData(None)

        # All NaNs or inf
        data = numpy.empty((4, 4, 4), dtype=numpy.float32)
        for value in (numpy.nan, numpy.inf):
            with self.subTest(value=str(value)):
                data[:] = value
                self.widget.setData(data, copy=True)
                self.qapp.processEvents()
Exemplo n.º 16
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 def setUp(self):
     super(TestScalarFieldView, self).setUp()
     self.widget = ScalarFieldView()
     self.widget.show()
Exemplo n.º 17
0
 def setUp(self):
     super(TestScalarFieldView, self).setUp()
     self.widget = ScalarFieldView()
     self.widget.show()