Exemple #1
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def salt(engine):
    cell_to_point_data = CellToPointData()
    engine.add_filter(cell_to_point_data)
    iso_surface = IsoSurface()
    engine.add_filter(iso_surface)
    module_manager = cell_to_point_data.children[0]
    module_manager.scalar_lut_manager.lut_mode = 'GnBu'
    iso_surface.contour.contours = [20, 25.0]
    iso_surface.actor.actor.position = np.array([0., 0., 1000.])
    iso_surface.actor.actor.scale = np.array([1., 1., 100.])
Exemple #2
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def contour():
    """The script itself.  We needn't have defined a function but
    having a function makes this more reusable.
    """
    # 'mayavi' is always defined on the interpreter.
    # Create a new scene.
    mayavi.new_scene()

    # Read a VTK (old style) data file.
    r = VTKFileReader()
    filename = join(mayavi2.get_data_dir(dirname(abspath(__file__))),
                    'heart.vtk')
    r.initialize(filename)
    mayavi.add_source(r)

    # Create an outline for the data.
    o = Outline()
    mayavi.add_module(o)

    # Create three simple grid plane modules.
    # First normal to 'x' axis.
    gp = GridPlane()
    mayavi.add_module(gp)
    # Second normal to 'y' axis.
    gp = GridPlane()
    mayavi.add_module(gp)
    gp.grid_plane.axis = 'y'
    # Third normal to 'z' axis.
    gp = GridPlane()
    mayavi.add_module(gp)
    gp.grid_plane.axis = 'z'

    # Create one ContourGridPlane normal to the 'x' axis.
    cgp = ContourGridPlane()
    mayavi.add_module(cgp)
    # Set the position to the middle of the data.
    cgp.grid_plane.position = 15

    # Another with filled contours normal to 'y' axis.
    cgp = ContourGridPlane()
    mayavi.add_module(cgp)
    # Set the axis and position to the middle of the data.
    cgp.grid_plane.axis = 'y'
    cgp.grid_plane.position = 15
    cgp.contour.filled_contours = True

    # An isosurface module.
    iso = IsoSurface(compute_normals=True)
    mayavi.add_module(iso)
    iso.contour.contours = [220.0]

    # An interactive scalar cut plane.
    cp = ScalarCutPlane()
    mayavi.add_module(cp)
    cp.implicit_plane.normal = 0, 0, 1
    def setUp(self):
        """Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""

        e = NullEngine()
        # Uncomment to see visualization for debugging etc.
        #e = Engine()
        e.start()
        e.new_scene()
        self.e = e

        sgrid = datasets.generateStructuredGrid()
        src = VTKDataSource(data=sgrid)
        e.add_source(src)

        # Create an outline for the data.
        o = Outline()
        e.add_module(o)

        # Create one ContourGridPlane normal to the 'x' axis.
        cgp1 = ContourGridPlane()
        e.add_module(cgp1)
        # Set the position to the middle of the data.
        cgp1.grid_plane.position = 15

        # Another with filled contours normal to 'y' axis.
        cgp2 = ContourGridPlane()
        cgp2.contour.filled_contours = True
        # Set the axis and position to the middle of the data.
        cgp2.grid_plane.axis = 'y'
        cgp2.grid_plane.position = 15
        e.add_module(cgp2)

        # An isosurface module.
        iso = IsoSurface(compute_normals=True)
        e.add_module(iso)
        iso.contour.contours = [5]

        # An interactive scalar cut plane.
        cp = ScalarCutPlane()
        e.add_module(cp)
        ip = cp.implicit_plane
        ip.normal = 0, 0, 1
        ip.origin = 0.5, 0.5, 1.0
        # Since this is running offscreen this seems necessary.
        ip.widget.origin = 0.5, 0.5, 1.0
        ip.widget.enabled = False
        self.scene = e.current_scene
        self.cgp2 = cgp2
        self.iso = iso
        self.cp = cp
        return
Exemple #4
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def streamline():
    """Sets up the mayavi pipeline for the visualization.
    """
    # Create an outline for the data.
    o = Outline()
    mayavi.add_module(o)

    s = Streamline(streamline_type='tube')
    mayavi.add_module(s)
    s.stream_tracer.integration_direction = 'both'
    s.seed.widget.center = 3.5, 0.625, 1.25
    s.module_manager.scalar_lut_manager.show_scalar_bar = True

    i = IsoSurface()
    mayavi.add_module(i)
    i.contour.contours[0] = 550
    i.actor.property.opacity = 0.5
Exemple #5
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    def do(self):
        ############################################################
        # Imports.
        script = self.script
        from mayavi.sources.vtk_file_reader import VTKFileReader
        from mayavi.modules.outline import Outline
        from mayavi.modules.iso_surface import IsoSurface
        from mayavi.modules.contour_grid_plane \
             import ContourGridPlane
        from mayavi.modules.scalar_cut_plane import ScalarCutPlane

        ############################################################
        # Create a new scene and set up the visualization.
        s = self.new_scene()

        # Read a VTK (old style) data file.
        r = VTKFileReader()
        r.initialize(get_example_data('heart.vtk'))

        script.add_source(r)

        # Create an outline for the data.
        o = Outline()
        script.add_module(o)

        # Create one ContourGridPlane normal to the 'x' axis.
        cgp1 = ContourGridPlane()
        script.add_module(cgp1)
        # Set the position to the middle of the data.
        cgp1.grid_plane.position = 15

        # Another with filled contours normal to 'y' axis.
        cgp2 = ContourGridPlane()
        cgp2.contour.filled_contours = True
        # Set the axis and position to the middle of the data.
        cgp2.grid_plane.axis = 'y'
        cgp2.grid_plane.position = 15
        script.add_module(cgp2)

        # An isosurface module.
        iso = IsoSurface(compute_normals=True)
        script.add_module(iso)
        iso.contour.contours = [200.0]

        # An interactive scalar cut plane.
        cp = ScalarCutPlane()
        script.add_module(cp)
        ip = cp.implicit_plane
        ip.normal = 0, 0, 1
        ip.origin = 0, 0, 5
        ip.widget.enabled = False

        # Set the scene to an isometric view.
        s.scene.isometric_view()

        # Now test.
        self.check()

        ############################################################
        # Test if the modules respond correctly when the components
        # are changed.
        ctr = cgp2.contour
        cgp2.contour = ctr.__class__()
        cgp2.contour = ctr
        cgp2.actor = cgp2.actor.__class__()

        iso.contour = iso.contour.__class__()
        iso.contour.contours = [200.0]
        iso.actor = iso.actor.__class__()
        iso.normals = iso.normals.__class__()

        ip = cp.implicit_plane
        cp.implicit_plane = cp.implicit_plane.__class__()
        cp.implicit_plane = ip
        ip.widget.enabled = False
        cp.contour = cp.contour.__class__()
        cp.cutter = cp.cutter.__class__()
        cp.actor = cp.actor.__class__()

        s.render()

        # Now check.
        self.check()

        ############################################################
        # Test if saving a visualization and restoring it works.

        # Save visualization.
        f = StringIO()
        f.name = abspath('test.mv2')  # We simulate a file.
        script.save_visualization(f)
        f.seek(0)  # So we can read this saved data.

        # Remove existing scene.
        engine = script.engine
        engine.close_scene(s)

        # Load visualization
        script.load_visualization(f)
        s = engine.current_scene

        self.check()

        ############################################################
        # Test if the MayaVi2 visualization can be deep-copied.

        # Pop the source object.
        source = s.children.pop()
        # Add it back to see if that works without error.
        s.children.append(source)
        # Now set the enabled status of the widget, this is impossible
        # to get correctly.
        cp = source.children[0].children[-1]
        cp.implicit_plane.widget.enabled = False

        self.check()

        # Now deepcopy the source and replace the existing one with
        # the copy.  This basically simulates cutting/copying the
        # object from the UI via the right-click menu on the tree
        # view, and pasting the copy back.
        source1 = copy.deepcopy(source)
        s.children[0] = source1
        cp = source1.children[0].children[-1]
        cp.implicit_plane.widget.enabled = False
        self.check()
Exemple #6
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except NameError:
    from mayavi.api import Engine
    engine = Engine()
    engine.start()
if len(engine.scenes) == 0:
    engine.new_scene()
# -------------------------------------------

from mayavi.modules.iso_surface import IsoSurface

#vtk_file_reader2 = engine.open(u'/home/m/spammsand/spammsand/water_to_duals/z_15.vtk')
vtk_file_reader2 = engine.open(
    u'/home/matcha/Desktop/RESEARCH/spammsand_may_21_2015/spammsand/water_to_duals/z_14.vtk'
)

iso_surface2 = IsoSurface()
engine.add_module(iso_surface2, obj=None)
iso_surface2.actor.mapper.scalar_mode = 'use_field_data'

#iso_surface2.actor.property.specular_color = (0.5019607843137255, 0.5019607843137255, 0.5019607843137255)
#iso_surface2.actor.property.diffuse_color = (0.5019607843137255, 0.5019607843137255, 0.5019607843137255)
#iso_surface2.actor.property.ambient_color = (0.5019607843137255, 0.5019607843137255, 0.5019607843137255)
#iso_surface2.actor.property.color = (0.5019607843137255, 0.5019607843137255, 0.5019607843137255)

iso_surface2.actor.property.specular_color = (1.0, 1.0, 1.0)
iso_surface2.actor.property.diffuse_color = (1.0, 1.0, 1.0)
iso_surface2.actor.property.ambient_color = (1.0, 1.0, 1.0)
iso_surface2.actor.property.color = (1.0, 1.0, 1.0)

iso_surface2.actor.property.opacity = 0.3
iso_surface2.contour.contours[0:1] = [0.01]
Exemple #7
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    def do(self):
        # Setup the source.
        self.make_data()

        from mayavi.modules.outline import Outline
        from mayavi.modules.iso_surface import IsoSurface
        from mayavi.modules.contour_grid_plane \
             import ContourGridPlane
        from mayavi.modules.scalar_cut_plane import ScalarCutPlane
        script = self.script
        s = script.engine.current_scene
        # Create an outline for the data.
        o = Outline()
        script.add_module(o)

        # Create one ContourGridPlane normal to the 'x' axis.
        cgp = ContourGridPlane()
        script.add_module(cgp)
        # Set the position to the middle of the data.
        cgp.grid_plane.position = 15

        # Another with filled contours normal to 'y' axis.
        cgp = ContourGridPlane()
        cgp.contour.filled_contours = True
        # Set the axis and position to the middle of the data.
        cgp.grid_plane.axis = 'y'
        cgp.grid_plane.position = 15
        script.add_module(cgp)

        # An isosurface module.
        iso = IsoSurface(compute_normals=True)
        script.add_module(iso)
        iso.contour.contours = [200.0]

        # An interactive scalar cut plane.
        cp = ScalarCutPlane()
        script.add_module(cp)
        ip = cp.implicit_plane
        ip.normal = 0, 0, 1
        ip.origin = 0, 0, 5
        ip.widget.enabled = False

        # Set the scene to an isometric view.
        s.scene.isometric_view()

        self.check()

        ############################################################
        # Test if saving a visualization and restoring it works.

        # Save visualization.
        f = BytesIO()
        f.name = abspath('test.mv2')  # We simulate a file.
        script.save_visualization(f)
        f.seek(0)  # So we can read this saved data.

        # Remove existing scene.
        engine = script.engine
        engine.close_scene(s)

        # Load visualization
        script.load_visualization(f)
        s = engine.current_scene

        self.check()

        ############################################################
        # Test if the MayaVi2 visualization can be deep-copied.

        # Pop the source object.
        source = s.children.pop()
        # Add it back to see if that works without error.
        s.children.append(source)
        # Now set the enabled status of the widget, this is impossible
        # to get correctly.
        cp = source.children[0].children[-1]
        cp.implicit_plane.widget.enabled = False
        self.check()

        # Now deepcopy the source and replace the existing one with
        # the copy.  This basically simulates cutting/copying the
        # object from the UI via the right-click menu on the tree
        # view, and pasting the copy back.
        source1 = copy.deepcopy(source)
        s.children[0] = source1
        cp = source1.children[0].children[-1]
        cp.implicit_plane.widget.enabled = False
        self.check()
Exemple #8
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    def view(prefix, name):
        """
        construct a generic visualization of base mesh, refined mesh,
        and potential/field/pseudopotential data in mayavi2
        requires running within mayavi2 or ipython with threads or
        something like::

            from pyface.api import GUI
            GUI().start_event_loop()

        in your script to interact with it.

        this is from a simplified macro recorded in mayavi2
        """
        """
        wwc 11/23/2018
        In both python 2.7 and 3.5, this 3D visualization with mayavi 
        works in Linux, but it's not compatible with X11 remote forwarding. 
        Install mayavi through conda channel "menpo" in python 3.5 or just 
        see environment setup of "ele35" in README. However, I haven't 
        found a mayavi version for python 3.6.
        """

        import mayavi
        try:
            from mayavi.api import Engine
            engine = Engine()
            engine.start()
        except AttributeError: # NameError:
            engine = mayavi.engine

        if len(engine.scenes) == 0:
            engine.new_scene()

        scene = engine.scenes[0]

        base_mesh_name = "%s_mesh.vtk" % prefix
        if os.access(base_mesh_name, os.R_OK):
            base_mesh = engine.open(base_mesh_name)
            surface = Surface()
            engine.add_filter(surface, base_mesh)
            surface.actor.property.representation = 'wireframe'
            surface.actor.property.line_width = 1

        mesh_name = "%s_%s_mesh.vtk" % (prefix, name)
        if os.access(mesh_name, os.R_OK):
            mesh = engine.open(mesh_name)
            mesh.cell_scalars_name = 'charge'
            surface = Surface()
            engine.add_filter(surface, mesh)
            module_manager = mesh.children[0]
            module_manager.scalar_lut_manager.lut_mode = 'RdBu'
            module_manager.scalar_lut_manager.use_default_range = False
            r = np.fabs(module_manager.scalar_lut_manager.data_range).max()
            module_manager.scalar_lut_manager.data_range = [-r, r]
            surface.actor.property.backface_culling = True

        data_name = "%s_%s.vtk" % (prefix, name)
        if os.access(data_name, os.R_OK):
            data = engine.open(data_name)
            if "pseudo_potential" in data._point_scalars_list:
                data.point_scalars_name = "pseudo_potential"
            else:
                data.point_scalars_name = "potential"
            iso_surface = IsoSurface()
            engine.add_filter(iso_surface, data)
            module_manager = data.children[0]
            module_manager.scalar_lut_manager.lut_mode = 'Greys'
            iso_surface.contour.auto_contours = True
            iso_surface.contour.number_of_contours = 5
            try:
                iso_surface.contour.maximum_contour = 1e-2
            except:
                pass

        scene.scene.isometric_view()
        scene.scene.render()
Exemple #9
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    def do(self):
        ############################################################
        # Imports.
        script = self.script
        from mayavi.sources.vtk_file_reader import VTKFileReader
        from mayavi.modules.outline import Outline
        from mayavi.modules.iso_surface import IsoSurface
        from mayavi.modules.contour_grid_plane \
             import ContourGridPlane
        from mayavi.modules.scalar_cut_plane import ScalarCutPlane

        ############################################################
        # Create a new scene and set up the visualization.
        s = self.new_scene()

        # Read a VTK (old style) data file.
        r = VTKFileReader()
        r.initialize(get_example_data('heart.vtk'))

        script.add_source(r)

        # Create an outline for the data.
        o = Outline()
        script.add_module(o)

        # Create one ContourGridPlane normal to the 'x' axis.
        cgp1 = ContourGridPlane()
        script.add_module(cgp1)
        # Set the position to the middle of the data.
        cgp1.grid_plane.position = 15

        # Another with filled contours normal to 'y' axis.
        cgp2 = ContourGridPlane()
        cgp2.contour.filled_contours = True
        # Set the axis and position to the middle of the data.
        cgp2.grid_plane.axis = 'y'
        cgp2.grid_plane.position = 15
        script.add_module(cgp2)

        # An isosurface module.
        iso = IsoSurface(compute_normals=True)
        script.add_module(iso)
        iso.contour.contours = [200.0]

        # An interactive scalar cut plane.
        cp = ScalarCutPlane()
        script.add_module(cp)
        ip = cp.implicit_plane
        ip.normal = 0,0,1
        ip.origin = 0,0,5
        ip.widget.enabled = False

        # Set the scene to an isometric view.
        s.scene.isometric_view()

        # Now test.
        self.check()

        ############################################################
        # Test if the modules respond correctly when the components
        # are changed.
        ctr = cgp2.contour
        cgp2.contour = ctr.__class__()
        cgp2.contour = ctr
        cgp2.actor = cgp2.actor.__class__()

        iso.contour = iso.contour.__class__()
        iso.contour.contours = [200.0]
        iso.actor = iso.actor.__class__()
        iso.normals = iso.normals.__class__()

        ip = cp.implicit_plane
        cp.implicit_plane = cp.implicit_plane.__class__()
        cp.implicit_plane = ip
        ip.widget.enabled = False
        cp.contour = cp.contour.__class__()
        cp.cutter = cp.cutter.__class__()
        cp.actor = cp.actor.__class__()

        s.render()

        # Now check.
        self.check()


        ############################################################
        # Test if saving a visualization and restoring it works.

        # Save visualization.
        f = StringIO()
        f.name = abspath('test.mv2') # We simulate a file.
        script.save_visualization(f)
        f.seek(0) # So we can read this saved data.

        # Remove existing scene.
        engine = script.engine
        engine.close_scene(s)

        # Load visualization
        script.load_visualization(f)
        s = engine.current_scene

        self.check()

        ############################################################
        # Test if the MayaVi2 visualization can be deep-copied.

        # Pop the source object.
        source = s.children.pop()
        # Add it back to see if that works without error.
        s.children.append(source)
        # Now set the enabled status of the widget, this is impossible
        # to get correctly.
        cp = source.children[0].children[-1]
        cp.implicit_plane.widget.enabled = False

        self.check()

        # Now deepcopy the source and replace the existing one with
        # the copy.  This basically simulates cutting/copying the
        # object from the UI via the right-click menu on the tree
        # view, and pasting the copy back.
        source1 = copy.deepcopy(source)
        s.children[0] = source1
        cp = source1.children[0].children[-1]
        cp.implicit_plane.widget.enabled = False
        self.check()
Exemple #10
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    def do_profile(self):
        ############################################################
        # Imports.
        ############################################################
        script = self.script
        from mayavi.sources.vtk_file_reader import VTKFileReader
        from mayavi.modules.outline import Outline
        from mayavi.modules.iso_surface import IsoSurface
        from mayavi.modules.contour_grid_plane \
             import ContourGridPlane
        from mayavi.modules.scalar_cut_plane import ScalarCutPlane

        ############################################################
        # Create a new scene and set up the visualization.
        ############################################################
        s = self.new_scene()

        # Read a VTK (old style) data file.
        r = VTKFileReader()
        r.initialize(get_example_data('heart.vtk'))

        script.add_source(r)

        # Create an outline for the data.
        o = Outline()
        script.add_module(o)

        # Create one ContourGridPlane normal to the 'x' axis.
        cgp1 = ContourGridPlane()
        script.add_module(cgp1)
        # Set the position to the middle of the data.
        cgp1.grid_plane.position = 15

        # Another with filled contours normal to 'y' axis.
        cgp2 = ContourGridPlane()
        cgp2.contour.filled_contours = True
        # Set the axis and position to the middle of the data.
        cgp2.grid_plane.axis = 'y'
        cgp2.grid_plane.position = 15
        script.add_module(cgp2)

        # An isosurface module.
        iso = IsoSurface(compute_normals=True)
        script.add_module(iso)
        iso.contour.contours = [200.0]

        # An interactive scalar cut plane.
        cp = ScalarCutPlane()
        script.add_module(cp)
        ip = cp.implicit_plane
        ip.normal = 0, 0, 1
        ip.origin = 0, 0, 5
        ip.widget.enabled = False

        # Set the scene to an isometric view.
        s.scene.isometric_view()

        s.render()

        # Remove existing scene.
        engine = script.engine
        engine.close_scene(s)
Exemple #11
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    def init_view_objects(self, *args):
        """Initialize (or re-initialize) all the view elements in the scene.
        This needs to be called when q-space modeled area changes (changing the outline) or
            q-resolution, etc.
        """
        #Prevent drawing all the intermediate steps
        self.scene.disable_render = True

        #First, we need to remove any data sources and modules from a previous run,
        #   if they exist.
        # (this is only needed when chaning q-space parameters)
        for x in [
                'data_src', 'point_data_src', 'iso', 'points_module_surface',
                'points_module_glyph', 'outline', 'mouse_text', 'mouse_cube'
        ]:
            if hasattr(self, x):
                getattr(self, x).remove()
        #Now the corner labels
        if hasattr(self, 'corner_text'):
            for txt in self.corner_text:
                txt.remove()

        engine = self.engine

        #We get the qspace_displayed array from experiment and make a copy of it.
        #   This object will REMAIN here and just have its data updated.
        self.data_src = ArraySource(
            scalar_data=model.experiment.exp.get_qspace_displayed().copy())
        self.data_src.scalar_name = "coverage"
        self.data_src.visible = False
        engine.add_source(self.data_src)

        # --- Text overlay for warnings ----
        txt = Text(text="(Points were thinned down)", position_in_3d=False)
        txt.x_position = 0.02
        txt.y_position = 0.98
        txt.actor.text_scale_mode = "none"
        txt.actor.text_property.font_size = 14
        txt.actor.text_property.vertical_justification = "top"
        self.warning_text = txt
        engine.add_module(self.warning_text)
        self.warning_text.visible = self.warning_text_visible

        #---- Make the isosurface object that goes with the volume coverage data -----
        iso = IsoSurface()
        self.iso = iso
        #Scale the isosurface so that the size is actually q-vector
        iso.actor.actor.scale = tuple(
            np.array([1.0, 1.0, 1.0]) * model.experiment.exp.inst.q_resolution)
        #And we offset the position so that the center is at q-space (0,0,0)
        iso.actor.actor.position = tuple(
            np.array([1.0, 1.0, 1.0]) * -model.experiment.exp.inst.qlim)
        # When set to 1, This helps them to show up right in partially transparent mode.
        iso.actor.property.backface_culling = 0
        iso.actor.property.frontface_culling = 0
        #Add the module to the data source, to make it plot that data
        self.data_src.add_module(iso)

        # ---- Now we make a point data source, for the individual reflection plot ---
        self.point_data_src = VTKDataSource(name="Reflection point positions")
        self.point_data_src.visible = False
        engine.add_source(self.point_data_src)
        self.point_data_src.data = self.make_point_data(
        )  #still needs to get set.

        # ---- Make a module of simple points, using the Surface module ----
        self.points_module_surface = Surface()
        self.points_module_surface.name = "Single reflections as pixels (Surface)"
        self.point_data_src.add_module(self.points_module_surface)
        # points representation = just plot a pixel for each vertex.
        self.points_module_surface.actor.property.set(representation='points',
                                                      point_size=3)

        # ---- Make a module of glyphs, making spheres for each point ----
        self.points_module_glyph = Glyph()
        self.points_module_glyph.name = "Single reflections as spheres (Glyph)"
        #No scaling of glyph size with scalar data
        self.points_module_glyph.glyph.scale_mode = 'data_scaling_off'
        gs = self.points_module_glyph.glyph.glyph_source
        gs.glyph_source = gs.glyph_dict['sphere_source']
        #How many vertices does each sphere have? 3 = fastest.
        gs.glyph_source.phi_resolution = 3
        gs.glyph_source.theta_resolution = 3
        #And how big does each sphere end up?
        gs.glyph_source.radius = 0.1
        #Add the module to the same point data source, to show it
        self.point_data_src.add_module(self.points_module_glyph)

        # Hide points initially
        self.points_module_surface.visible = False
        self.points_module_glyph.visible = False

        #Get the color look-up table
        self.points_lut = self.points_module_glyph.module_manager.scalar_lut_manager.lut.table.to_array(
        )
        self.points_lut_original = 1 * self.points_lut

        # ---- Simple outline for all of the data. -----
        self.outline = Outline()
        #Manually make the outline = the modeled volume, which is +- qlim = 1/d_min
        self.outline.manual_bounds = True
        self.outline.bounds = tuple(
            np.array([-1., 1., -1., 1., -1., 1.]) *
            model.experiment.exp.inst.qlim)
        #Add it to the scene directly.
        engine.add_module(self.outline)

        #--- Label the HKL of the corners ---
        if config_gui.cfg.label_corners:
            q = model.instrument.inst.qlim
            #This the reciprocal lattice vectors
            rec = model.experiment.exp.crystal.reciprocal_lattice
            self.corner_text = []
            for x in [-q, q]:
                for y in [-q, q]:
                    for z in [-q, q]:
                        (h, k, l) = model.crystal_calc.get_hkl_from_q(
                            column([x, y, z]), rec)
                        label = "%d,%d,%d" % (h, k, l)
                        txt = Text(text=label, position_in_3d=False)
                        txt.position_in_3d = True
                        txt.x_position = x
                        txt.y_position = y
                        txt.z_position = z
                        txt.actor.text_scale_mode = "none"
                        txt.actor.text_property.font_size = 14
                        txt.actor.text_property.vertical_justification = "top"
                        txt.actor.text_property.justification = "left"
                        txt.actor.property.color = (0.75, 1.0, 1.0)
                        engine.add_module(txt)
                        self.corner_text.append(txt)

        # ---- A text overlay, to show what is under the mouse -----
#        self.mouse_text = Text(text=self.MOUSE_TEXT_WITH_NO_REFLECTION, position_in_3d=False)
#        self.mouse_text.x_position=0.02
#        self.mouse_text.y_position=0.98
#        self.mouse_text.actor.text_scale_mode = "none"
#        self.mouse_text.actor.text_property.font_size = 20
#        self.mouse_text.actor.text_property.vertical_justification = "top"
#        engine.add_module(self.mouse_text)

# ---- A cube highlighting where the mouse is ----
        self.mouse_cube = Glyph()
        self.mouse_cube.name = "Cube highlighting mouse position (Glyph)"
        #No scaling of glyph size with scalar data
        self.mouse_cube.glyph.scale_mode = 'data_scaling_off'
        self.mouse_cube.glyph.color_mode = 'no_coloring'
        gs = self.mouse_cube.glyph.glyph_source
        gs.glyph_source = gs.glyph_dict['cube_source']
        self.mouse_cube.actor.property.representation = "wireframe"
        self.mouse_cube.actor.property.specular = 1.0  # to make edge always white
        self.mouse_point_data_src = VTKDataSource()
        self.mouse_point_data_src.name = "Mouse position (VTK Data)"
        self.mouse_point_data_src.visible = True
        engine.add_source(self.mouse_point_data_src)
        self.mouse_point_data_src.data = self.make_single_point_data((0, 0, 0))
        self.mouse_point_data_src.add_module(self.mouse_cube)
        self.mouse_cube.visible = False

        #        #--- Reciprocal axes 3D view ----
        #        c = model.experiment.exp.crystal #@type c Crystal
        #        (a,b,c) = (c.recip_a, c.recip_b, c.recip_c)
        #        offset = model.experiment.exp.inst.qlim
        #        self.scene.mlab.plot3d([offset, offset+a[0]], [offset, offset+a[1]], [offset, offset+a[2]], color=(1,0,0))
        #        self.scene.mlab.plot3d([offset, offset+b[0]], [offset, offset+b[1]], [offset, offset+b[2]], color=(0,1,0))
        #        self.scene.mlab.plot3d([offset, offset+c[0]], [offset, offset+c[1]], [offset, offset+c[2]], color=(0,0,1))

        #Re-enable drawing
        self.scene.disable_render = False
Exemple #12
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    def run(self):
        """This is executed once the application GUI has started.
        *Make sure all other MayaVi specific imports are made here!*
        """

        # Various imports to do different things.
        from mayavi.sources.vtk_file_reader import VTKFileReader
        from mayavi.modules.outline import Outline
        from mayavi.modules.axes import Axes
        from mayavi.modules.grid_plane import GridPlane
        from mayavi.modules.image_plane_widget import ImagePlaneWidget
        from mayavi.modules.text import Text
        from mayavi.modules.contour_grid_plane import ContourGridPlane
        from mayavi.modules.iso_surface import IsoSurface

        script = self.script

        # Create a new scene.
        script.new_scene()

        # Read a VTK (old style) data file.
        r = VTKFileReader()
        r.initialize(join(get_data_dir(abspath(__file__)), 'heart.vtk'))
        script.add_source(r)

        # Put up some text.
        t = Text(text='MayaVi rules!',
                 x_position=0.2,
                 y_position=0.9,
                 width=0.8)
        t.property.color = 1, 1, 0  # Bright yellow, yeah!
        script.add_module(t)

        # Create an outline for the data.
        o = Outline()
        script.add_module(o)

        # Create an axes for the data.
        a = Axes()
        script.add_module(a)

        # Create three simple grid plane modules.
        # First normal to 'x' axis.
        gp = GridPlane()
        script.add_module(gp)
        # Second normal to 'y' axis.
        gp = GridPlane()
        gp.grid_plane.axis = 'y'
        script.add_module(gp)
        # Third normal to 'z' axis.
        gp = GridPlane()
        script.add_module(gp)
        gp.grid_plane.axis = 'z'

        # Create one ImagePlaneWidget.
        ipw = ImagePlaneWidget()
        script.add_module(ipw)
        # Set the position to the middle of the data.
        ipw.ipw.slice_position = 16

        # Create one ContourGridPlane normal to the 'x' axis.
        cgp = ContourGridPlane()
        script.add_module(cgp)
        # Set the position to the middle of the data.
        cgp.grid_plane.axis = 'y'
        cgp.grid_plane.position = 15

        # An isosurface module.
        iso = IsoSurface(compute_normals=True)
        script.add_module(iso)
        iso.contour.contours = [200.0]

        # Set the view.
        s = script.engine.current_scene
        cam = s.scene.camera
        cam.azimuth(45)
        cam.elevation(15)
        s.render()
Exemple #13
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    def view(prefix, name):
        """
        construct a generic visualization of base mesh, refined mesh,
        and potential/field/pseudopotential data in mayavi2
        requires running within mayavi2 or ipython with threads or
        something like::

            from pyface.api import GUI
            GUI().start_event_loop()

        in your script to interact with it.

        this is from a simplified macro recorded in mayavi2
        """
        try:
            engine = mayavi.engine
        except NameError:
            from mayavi.api import Engine
            engine = Engine()
            engine.start()

        if len(engine.scenes) == 0:
            engine.new_scene()

        scene = engine.scenes[0]

        base_mesh_name = "%s_mesh.vtk" % prefix
        if os.access(base_mesh_name, os.R_OK):
            base_mesh = engine.open(base_mesh_name)
            surface = Surface()
            engine.add_filter(surface, base_mesh)
            surface.actor.property.representation = 'wireframe'
            surface.actor.property.line_width = 1

        mesh_name = "%s_%s_mesh.vtk" % (prefix, name)
        if os.access(mesh_name, os.R_OK):
            mesh = engine.open(mesh_name)
            mesh.cell_scalars_name = 'charge'
            surface = Surface()
            engine.add_filter(surface, mesh)
            module_manager = mesh.children[0]
            module_manager.scalar_lut_manager.lut_mode = 'RdBu'
            module_manager.scalar_lut_manager.use_default_range = False
            r = np.fabs(module_manager.scalar_lut_manager.data_range).max()
            module_manager.scalar_lut_manager.data_range = [-r, r]
            surface.actor.property.backface_culling = True

        data_name = "%s_%s.vtk" % (prefix, name)
        if os.access(data_name, os.R_OK):
            data = engine.open(data_name)
            if "pseudo_potential" in data._point_scalars_list:
                data.point_scalars_name = "pseudo_potential"
            else:
                data.point_scalars_name = "potential"
            iso_surface = IsoSurface()
            engine.add_filter(iso_surface, data)
            module_manager = data.children[0]
            module_manager.scalar_lut_manager.lut_mode = 'Greys'
            iso_surface.contour.auto_contours = True
            iso_surface.contour.number_of_contours = 5
            try:
                iso_surface.contour.maximum_contour = 1e-2
            except:
                pass

        scene.scene.isometric_view()
        scene.scene.render()