UIList(bpy_struct)

Basic UIList Example

This script is the UIList subclass used to show material slots, with a bunch of additional commentaries.

Notice the name of the class, this naming convention is similar as the one for panels or menus.

Note

UIList subclasses must be registered for blender to use them.

import bpy


class MATERIAL_UL_matslots_example(bpy.types.UIList):
    # The draw_item function is called for each item of the collection that is visible in the list.
    #   data is the RNA object containing the collection,
    #   item is the current drawn item of the collection,
    #   icon is the "computed" icon for the item (as an integer, because some objects like materials or textures
    #   have custom icons ID, which are not available as enum items).
    #   active_data is the RNA object containing the active property for the collection (i.e. integer pointing to the
    #   active item of the collection).
    #   active_propname is the name of the active property (use 'getattr(active_data, active_propname)').
    #   index is index of the current item in the collection.
    #   flt_flag is the result of the filtering process for this item.
    #   Note: as index and flt_flag are optional arguments, you do not have to use/declare them here if you don't
    #         need them.
    def draw_item(self, context, layout, data, item, icon, active_data, active_propname):
        ob = data
        slot = item
        ma = slot.material
        # draw_item must handle the three layout types... Usually 'DEFAULT' and 'COMPACT' can share the same code.
        if self.layout_type in {'DEFAULT', 'COMPACT'}:
            # You should always start your row layout by a label (icon + text), or a non-embossed text field,
            # this will also make the row easily selectable in the list! The later also enables ctrl-click rename.
            # We use icon_value of label, as our given icon is an integer value, not an enum ID.
            # Note "data" names should never be translated!
            if ma:
                layout.prop(ma, "name", text="", emboss=False, icon_value=icon)
            else:
                layout.label(text="", translate=False, icon_value=icon)
            # And now we can add other UI stuff...
            # Here, we add nodes info if this material uses (old!) shading nodes.
            if ma and not context.scene.render.use_shading_nodes:
                manode = ma.active_node_material
                if manode:
                    # The static method UILayout.icon returns the integer value of the icon ID "computed" for the given
                    # RNA object.
                    layout.label(text="Node %s" % manode.name, translate=False, icon_value=layout.icon(manode))
                elif ma.use_nodes:
                    layout.label(text="Node <none>", translate=False)
                else:
                    layout.label(text="")
        # 'GRID' layout type should be as compact as possible (typically a single icon!).
        elif self.layout_type in {'GRID'}:
            layout.alignment = 'CENTER'
            layout.label(text="", icon_value=icon)


# And now we can use this list everywhere in Blender. Here is a small example panel.
class UIListPanelExample(bpy.types.Panel):
    """Creates a Panel in the Object properties window"""
    bl_label = "UIList Panel"
    bl_idname = "OBJECT_PT_ui_list_example"
    bl_space_type = 'PROPERTIES'
    bl_region_type = 'WINDOW'
    bl_context = "object"

    def draw(self, context):
        layout = self.layout

        obj = context.object

        # template_list now takes two new args.
        # The first one is the identifier of the registered UIList to use (if you want only the default list,
        # with no custom draw code, use "UI_UL_list").
        layout.template_list("MATERIAL_UL_matslots_example", "", obj, "material_slots", obj, "active_material_index")

        # The second one can usually be left as an empty string.
        # It's an additional ID used to distinguish lists in case you use the same list several times in a given area.
        layout.template_list("MATERIAL_UL_matslots_example", "compact", obj, "material_slots",
                             obj, "active_material_index", type='COMPACT')


def register():
    bpy.utils.register_class(MATERIAL_UL_matslots_example)
    bpy.utils.register_class(UIListPanelExample)


def unregister():
    bpy.utils.unregister_class(MATERIAL_UL_matslots_example)
    bpy.utils.unregister_class(UIListPanelExample)


if __name__ == "__main__":
    register()

Advanced UIList Example - Filtering and Reordering

This script is an extended version of the UIList subclass used to show vertex groups. It is not used ‘as is’, because iterating over all vertices in a ‘draw’ function is a very bad idea for UI performances! However, it’s a good example of how to create/use filtering/reordering callbacks.

import bpy


class MESH_UL_vgroups_slow(bpy.types.UIList):
    # Constants (flags)
    # Be careful not to shadow FILTER_ITEM!
    VGROUP_EMPTY = 1 << 0

    # Custom properties, saved with .blend file.
    use_filter_empty = bpy.props.BoolProperty(name="Filter Empty", default=False, options=set(),
                                              description="Whether to filter empty vertex groups")
    use_filter_empty_reverse = bpy.props.BoolProperty(name="Reverse Empty", default=False, options=set(),
                                                      description="Reverse empty filtering")
    use_filter_name_reverse = bpy.props.BoolProperty(name="Reverse Name", default=False, options=set(),
                                                     description="Reverse name filtering")

    # This allows us to have mutually exclusive options, which are also all disable-able!
    def _gen_order_update(name1, name2):
        def _u(self, ctxt):
            if (getattr(self, name1)):
                setattr(self, name2, False)
        return _u
    use_order_name = bpy.props.BoolProperty(name="Name", default=False, options=set(),
                                            description="Sort groups by their name (case-insensitive)",
                                            update=_gen_order_update("use_order_name", "use_order_importance"))
    use_order_importance = bpy.props.BoolProperty(name="Importance", default=False, options=set(),
                                                  description="Sort groups by their average weight in the mesh",
                                                  update=_gen_order_update("use_order_importance", "use_order_name"))

    # Usual draw item function.
    def draw_item(self, context, layout, data, item, icon, active_data, active_propname, index, flt_flag):
        # Just in case, we do not use it here!
        self.use_filter_invert = False

        # assert(isinstance(item, bpy.types.VertexGroup)
        vgroup = item
        if self.layout_type in {'DEFAULT', 'COMPACT'}:
            # Here we use one feature of new filtering feature: it can pass data to draw_item, through flt_flag
            # parameter, which contains exactly what filter_items set in its filter list for this item!
            # In this case, we show empty groups grayed out.
            if flt_flag & self.VGROUP_EMPTY:
                col = layout.column()
                col.enabled = False
                col.alignment = 'LEFT'
                col.prop(vgroup, "name", text="", emboss=False, icon_value=icon)
            else:
                layout.prop(vgroup, "name", text="", emboss=False, icon_value=icon)
            icon = 'LOCKED' if vgroup.lock_weight else 'UNLOCKED'
            layout.prop(vgroup, "lock_weight", text="", icon=icon, emboss=False)
        elif self.layout_type in {'GRID'}:
            layout.alignment = 'CENTER'
            if flt_flag & self.VGROUP_EMPTY:
                layout.enabled = False
            layout.label(text="", icon_value=icon)

    def draw_filter(self, context, layout):
        # Nothing much to say here, it's usual UI code...
        row = layout.row()

        subrow = row.row(align=True)
        subrow.prop(self, "filter_name", text="")
        icon = 'ZOOM_OUT' if self.use_filter_name_reverse else 'ZOOM_IN'
        subrow.prop(self, "use_filter_name_reverse", text="", icon=icon)

        subrow = row.row(align=True)
        subrow.prop(self, "use_filter_empty", toggle=True)
        icon = 'ZOOM_OUT' if self.use_filter_empty_reverse else 'ZOOM_IN'
        subrow.prop(self, "use_filter_empty_reverse", text="", icon=icon)

        row = layout.row(align=True)
        row.label("Order by:")
        row.prop(self, "use_order_name", toggle=True)
        row.prop(self, "use_order_importance", toggle=True)
        icon = 'TRIA_UP' if self.use_filter_orderby_invert else 'TRIA_DOWN'
        row.prop(self, "use_filter_orderby_invert", text="", icon=icon)

    def filter_items_empty_vgroups(self, context, vgroups):
        # This helper function checks vgroups to find out whether they are empty, and what's their average weights.
        # TODO: This should be RNA helper actually (a vgroup prop like "raw_data: ((vidx, vweight), etc.)").
        #       Too slow for python!
        obj_data = context.active_object.data
        ret = {vg.index: [True, 0.0] for vg in vgroups}
        if hasattr(obj_data, "vertices"):  # Mesh data
            if obj_data.is_editmode:
                import bmesh
                bm = bmesh.from_edit_mesh(obj_data)
                # only ever one deform weight layer
                dvert_lay = bm.verts.layers.deform.active
                fact = 1 / len(bm.verts)
                if dvert_lay:
                    for v in bm.verts:
                        for vg_idx, vg_weight in v[dvert_lay].items():
                            ret[vg_idx][0] = False
                            ret[vg_idx][1] += vg_weight * fact
            else:
                fact = 1 / len(obj_data.vertices)
                for v in obj_data.vertices:
                    for vg in v.groups:
                        ret[vg.group][0] = False
                        ret[vg.group][1] += vg.weight * fact
        elif hasattr(obj_data, "points"):  # Lattice data
            # XXX no access to lattice editdata?
            fact = 1 / len(obj_data.points)
            for v in obj_data.points:
                for vg in v.groups:
                    ret[vg.group][0] = False
                    ret[vg.group][1] += vg.weight * fact
        return ret

    def filter_items(self, context, data, propname):
        # This function gets the collection property (as the usual tuple (data, propname)), and must return two lists:
        # * The first one is for filtering, it must contain 32bit integers were self.bitflag_filter_item marks the
        #   matching item as filtered (i.e. to be shown), and 31 other bits are free for custom needs. Here we use the
        #   first one to mark VGROUP_EMPTY.
        # * The second one is for reordering, it must return a list containing the new indices of the items (which
        #   gives us a mapping org_idx -> new_idx).
        # Please note that the default UI_UL_list defines helper functions for common tasks (see its doc for more info).
        # If you do not make filtering and/or ordering, return empty list(s) (this will be more efficient than
        # returning full lists doing nothing!).
        vgroups = getattr(data, propname)
        helper_funcs = bpy.types.UI_UL_list

        # Default return values.
        flt_flags = []
        flt_neworder = []

        # Pre-compute of vgroups data, CPU-intensive. :/
        vgroups_empty = self.filter_items_empty_vgroups(context, vgroups)

        # Filtering by name
        if self.filter_name:
            flt_flags = helper_funcs.filter_items_by_name(self.filter_name, self.bitflag_filter_item, vgroups, "name",
                                                          reverse=self.use_filter_name_reverse)
        if not flt_flags:
            flt_flags = [self.bitflag_filter_item] * len(vgroups)

        # Filter by emptiness.
        for idx, vg in enumerate(vgroups):
            if vgroups_empty[vg.index][0]:
                flt_flags[idx] |= self.VGROUP_EMPTY
                if self.use_filter_empty and self.use_filter_empty_reverse:
                    flt_flags[idx] &= ~self.bitflag_filter_item
            elif self.use_filter_empty and not self.use_filter_empty_reverse:
                flt_flags[idx] &= ~self.bitflag_filter_item

        # Reorder by name or average weight.
        if self.use_order_name:
            flt_neworder = helper_funcs.sort_items_by_name(vgroups, "name")
        elif self.use_order_importance:
            _sort = [(idx, vgroups_empty[vg.index][1]) for idx, vg in enumerate(vgroups)]
            flt_neworder = helper_funcs.sort_items_helper(_sort, lambda e: e[1], True)

        return flt_flags, flt_neworder

base class — bpy_struct

subclasses — CLIP_UL_tracking_objects, FILEBROWSER_UL_dir, GPENCIL_UL_brush, GPENCIL_UL_layer, GPENCIL_UL_palettecolor, MASK_UL_layers, MATERIAL_UL_matslots, MESH_UL_shape_keys, MESH_UL_uvmaps_vcols, MESH_UL_vgroups, NODE_UL_interface_sockets, PARTICLE_UL_particle_systems, PHYSICS_UL_dynapaint_surfaces, RENDERLAYER_UL_linesets, RENDERLAYER_UL_renderlayers, RENDERLAYER_UL_renderviews, SCENE_UL_keying_set_paths, TEXTURE_UL_texpaintslots, TEXTURE_UL_texslots, UI_UL_list

class bpy.types.UIList(bpy_struct)

UI list containing the elements of a collection

bitflag_filter_item

The value of the reserved bitflag ‘FILTER_ITEM’ (in filter_flags values)

Type:int in [0, inf], default 0, (readonly)
bl_idname

If this is set, the uilist gets a custom ID, otherwise it takes the name of the class used to define the uilist (for example, if the class name is “OBJECT_UL_vgroups”, and bl_idname is not set by the script, then bl_idname = “OBJECT_UL_vgroups”)

Type:string, default “”, (never None)
filter_name

Only show items matching this name (use ‘*’ as wildcard)

Type:string, default “”, (never None)
layout_type
  • DEFAULT Default Layout, Use the default, multi-rows layout.
  • COMPACT Compact Layout, Use the compact, single-row layout.
  • GRID Grid Layout, Use the grid-based layout.
Type:enum in [‘DEFAULT’, ‘COMPACT’, ‘GRID’], default ‘DEFAULT’, (readonly)
use_filter_invert

Invert filtering (show hidden items, and vice-versa)

Type:boolean, default False
use_filter_show

Show filtering options

Type:boolean, default False
use_filter_sort_alpha

Sort items by their name

Type:boolean, default False
use_filter_sort_reverse

Invert the order of shown items

Type:boolean, default False
draw_item(context, layout, data, item, icon, active_data, active_property, index=0, flt_flag=0)

Draw an item in the list (NOTE: when you define your own draw_item function, you may want to check given ‘item’ is of the right type…)

Parameters:
  • layout (UILayout, (never None)) – Layout to draw the item
  • data (AnyType) – Data from which to take Collection property
  • item (AnyType) – Item of the collection property
  • icon (int in [0, inf]) – Icon of the item in the collection
  • active_data (AnyType, (never None)) – Data from which to take property for the active element
  • active_property (string, (optional argument, never None)) – Identifier of property in active_data, for the active element
  • index (int in [0, inf], (optional)) – Index of the item in the collection
  • flt_flag (int in [0, inf], (optional)) – The filter-flag result for this item
draw_filter(context, layout)

Draw filtering options

Parameters:layout (UILayout, (never None)) – Layout to draw the item
filter_items(context, data, property)

Filter and/or re-order items of the collection (output filter results in filter_flags, and reorder results in filter_neworder arrays)

Parameters:
  • data (AnyType) – Data from which to take Collection property
  • property (string, (never None)) – Identifier of property in data, for the collection
Return (filter_flags, filter_neworder):
 

filter_flags, An array of filter flags, one for each item in the collection (NOTE: FILTER_ITEM bit is reserved, it defines whether the item is shown or not), int array of 1 items in [0, inf]

filter_neworder, An array of indices, one for each item in the collection, mapping the org index to the new one, int array of 1 items in [0, inf]

Inherited Properties

Inherited Functions